YERSINIA ENTEROCOLITICA

Transcription

YERSINIA ENTEROCOLITICA
YERSINIA ENTEROCOLITICA
Hin-chung Wong
Department of Microbiology
Soochow University
_____________________________________________________________
1. INTRODUCTION
2. TAXONOMY AND GENERAL CHARACTERISTICS
2.1. Biofilm
2.2. Antibiotic Resistance
3. BIOTYPING AND SEROTYPING
4. PHAGE TYPING
5. GROWTH AND SURVIVAL
5.1. Nutritional Requirements
5.2. Acidity
5.3. Temperature
5.4. Sodium Chloride
5.5. Organic Acids and Salts
5.6. Radiation
5.7. Competitive Microorganisms
5.8. Controlled atmosphere
5.9. Essential oils
5.10. Physiology
6. OCCURRENCE IN FOODS AND ENVIRONMENT
6.1. Animal
6.2. Water and Soil
6.3. Isolation from Foods
7. ISOLATION AND IDENTIFICATION
7.1. Selective Enrichments
7.2. Selective Differential Platings
7.3. Identification
7.4. Membrane Filter Method
7.5. DNA Hybridization Method
7.6. Commercial Rapid Detection Kit
1
7.7. DNA microarray
7.8. Real-time PCR
8. PATHOGENICITY AND VIRULENCE FACTORS
8.1. Clinical Manifestations
8.2. Effects of Sublethal Stresses on Virulence
8.3. Enterotoxin
8.4. Autoagglutination
8.5. Invasiveness
8.6. Congo Red and Crystal Violet Binding
8.7. Calcium Requirement
8.8. Surface Hydrophobicity
8.9. Mouse Lethality
8.10. Requirement of Iron
8.11. Phospholipase
8.12. Type III secretion system
8.13. A three-dimensional collagen gel model
9. ROLE OF PLASMIDS IN VIRULENCE
9.1. Proteins Encoded by Virulence-associated Plasmids
9.1.1. Excreted Proteins versus Surface Proteins
9.1.2. Proteins Associated with Fibrillae,
Adhesion and Autoagglutination
9.1.3. Proteins Associated with Serum Resistance
9.2. Molecular Manipulation of Plasmids
10. MOLECULAR STUDY OF INVASIVENESS
10.1. Flagellar master regulator
11. CONCLUSIONS
12. REFERENCES
________________________________________________________________
1. INTRODUCTION
Yersinia enterocolitica was discovered by Schleifstein and Coleman in 1939
in USA. Most of the reports about this bacterium were published since the early
1960s. In the last four decades, it is popularly known as an important foodborne
pathogen. In fact, Y. enterocolitica and Campylobacter jejuni can be regarded as
the "pathogenic bacteria of the 1980s" (Swaminathan et al., 1982).
2
Since Y. enterocolitica is one of the few pathogenic bacteria which can grow
at refrigerating temperature, foods contaminated initially with even low levels
of this pathogen may serve as medium for proliferation and vehicle of disease.
2. TAXONOMY AND GENERAL CHARACTERISTICS
The Genus Yersinia currently placed in the family Enterobacteriaceae
comprises three major pathogenic bacteria, namely, Y. pestis, Y.
pseudotuberculosis, and Y. enterocolitica. The species Y. enterocolitica is
characterized by Gram negative rods (0.99-3.54 μm x 0.52-1.27 μm), arranged
singly or in short chains or heaps. Coccoid forms predominate in old cultures
grown at 22-25C on selective differential media used for the isolation or enteric
organisms (Swaminathan et al., 1982).
Strains of Y. enterocolitica are biochemically heterogeneous. Typical strains
of Y. enterocolitica ferment sucrose but cannot utilize rhamnose, citrate,
α-methyl glucose or melibiose. Although most strains of Y. enterocolitica are
o-nitrophenyl β-D-galactopyranoside (ONPG)-positive they do not possess
β-galactosidase, except for those strains which contain the plasmid lac+.
Atypical strains of Y. enterocolitica may be divided into four major groups, two
of which are sucrose negative and two of which are rhamnose positive (Table 1)
(Swaminathan et al., 1982).
3
4
On the basis of DNA hybridization studies, it is concluded that the
biochemically viariant strains (rhamnose positive, sucrose negative, etc.) are
more closely related to Yersinia than any other Genus in the Enterobacteriaceae.
Different names like Y. enteritidis, Y. frederiksenii, Y. kristensenii, Y. intermedia,
Y. rhamnophilica etc. are suggested for the atypical strains (Table 2)(Bissett et
al., 1990; Swaminathan et al., 1982). Y. enterocolitica, Y. intermedia, Y. aldovae,
Y. frederiksenii, Y. kristensenii and Y. pseudotuberculosis were differentiated by
the electrophoretic polymorpism of acid phosphatase, esterases, and glutamate
and malate dehydrogenases (Goullet and Picard, 1988).
5
By cross-streaking method, three clinical isolates of Y. enterocolitica produced
inhibitory substances (bacteriocin-like material) at room temperature, and these
substances were active against a variety of clinical isolates and their
plasmid-cured derivatives at both room temperature and 37C (Cafferkey et al.,
1989).
Methodology
Cross-streaking Method
The strain to be tested is inoculated as a 1.5-cm-wide steak across
tryptone soya blood agar plates and incubated overnight at room temperature.
The inoculum is removed with a glass slide and the remaining viable cells are
killed by exposure to UV for 30 min. The indicator strains are streaked singly at
right angles to the original inoculum and incubated at 37C overnight. Inhibition
zones are observed (Cafferkey et al., 1989).
The first restriction endonuclease YenI was indentified in Y. enterocolitica
(only in O8 strains) with or without the virulence-associated plasmid. YenI was
very stable during the purification and storage at 4C or lower temperatures. YenI
required 10 mM Mg2+ for cleavage of lambda DNA with the highest activity at
pH 7.5 to 8.1 in the presence of 50 mM NaCl. Cleavage patterns with YenI and
PstI were identical, showing that YenI is an isoschizomer of PstI, the cutting site
is CTGCA/G. YenI has high activity at low temperature (Miyahara et al., 1988).
Some Y. enterocolitica strains produce hemagglutinins. Production of the
mannose-resistant hemagglutinin (MRHA) was affected by the culture media,
e.g. none of the autoagglutination-positive strains produced MRHA in either
nutrient broth or on colonization factor agar. In contrast a distinct
autoagglutination-associated MRHA was detected after growth in Eagle
minimal essential medium (Kapperud and Lassen, 1983).
Enterobacterial common antigen (ECA) was found in the outer membrane
and also in the cytoplasm of Y. enterocolitica by electron microscopy with the
use of ECA specific antibodies and secondary antibody labelled with gold
6
(Acker et al., 1986), or by the immunoferritin technique (Acker et al., 1981).
ECA is a surface antigen common to almost all Enterobacteriaceae and consists
of an amino sugar heteropolymer. The ECA on the cell surface of Y.
enterocolitica Ye75S (smooth cell) is covered by O-specific chains of the
lipopolysaccharide if grown at 22C and is therefore not accessible to ECA
antibodies. It becomes accessible, however, when O-chains are lacking (R
mutants) or when they are reduced in size or amount (growth at 40C) (Acker et
al., 1981).
2.1. Biofilm
Y. enterocolitica biovar 1B is one of a number of strains pathogenic to humans
in the genus Yersinia. It has three different type III secretion systems, Ysc, Ysa,
and the flagella.The effect of flagella on biofilm formation was evaluated. In a
panel of 31 mutant Y. enterocolitica strains, the mutations that abolish the
structure or rotation of the flagella greatly reduce biofilm formation when the
bacteria are grown under static conditions (Table 3). These results were further
evaluated by assessing biofilm formation under continuous culture using a flow
cell chamber. The results confirmed the important contribution of flagella to the
initiation of biofilm production but indicated that there are differences in the
progression of biofilm development between static growth and flow conditions
(Kim et al., 2008).
7
2.2. Antibiotic Resistance
To obtain basic data for future resistance monitoring programs, 386 Y.
enterocolitica strains from human patients, raw retail pork and pig feces were
tested for their susceptibilities to 16 antimicrobial agents and two antimicrobial
growth promoters (carbadox and olaquindox). No strains were resistant to
ceftriaxone, cefuroxime, ciprofloxacine, gentamicin, kanamycin, neomycin or
polymyxin. Although in Switzerland carbadox and olaquindox were used as
growth promoters for pigs for over 25 years, all strains were susceptible to them.
In contrast, there were high levels of resistance to ampicillin, cefalothin and
amoxicillin/clavulanic acid. Less than 10% of clinical isolates and strains from
pig feces were resistant to streptomycin, sulfonamide, trimethoprim/
sulfamethoxazole, tetracyclin, trimethoprim and chloramphenicol, but strains
from retail pork were all susceptible to these antimicrobial agents. This finding
suggested that pork is probably not a major source of Y. enterocolitica that
cause human infections in Switzerland (Baumgartner et al., 2007).
3. BIOTYPING AND SEROTYPING
Different biotyping schemes are proposed for the Y. enterocolitica strains
(Table 4) (Stern and Pierson, 1979; Swaminathan et al., 1982).
8
The commonly used biotyping scheme is adopted from Wauters (Table 5)
(FDA).
Table 5. Biotype scheme(a) for Y. enterocolitica
Reaction for biotypes(b)
Biochemical test
1A
1B
2
3
4
5
Lipase
+
+
Esculin/salicin (24 h)
+/Indole
+
+
(+)
Xylose
+
+
+
+
V
Trehalose
+
+
+
+
+
Pyrazinamidase
+
β -D-Glucosidase
+
Voges-Proskauer
+
+
+ +/-(c) +
(+)
6
+
+
+
-
a
Based on Wauters.
( ) = Delayed reaction; V = variable reactions.
c
Biotype of serotype O:3 found in Japan.
b
9
Y. enterocolitica is represented by six biovars viz. 1A, 1B and 2-5. Some
biovar 1A strains, despite lacking virulence plasmid (pYV) and chromosomal
virulence genes, have been reported to cause symptoms similar to that produced
by isolates belonging to known pathogenic biovars.
Y. enterocolitica possess lipopolysaccharide O-antigens similar to other Gram
negative bacteria. Specific antigens are found in strains of this species. A total of
34 O factors and 19 H factors were identified. The strains of Y. enterocolitica
are grouped into 11 serotypes, mainly based on somatic antigens, and H
antigens do not appear to be important in typing of strains. Serotype 5 is divided
into two subgroups (Table 6) (Swaminathan et al., 1982). A revision of the
original Wauters et al. serotyping scheme for Y. enterocolitica was proposed by
Aleksic and Bockemuhl, with the exlusion of those O and H antigens which are
not associated with the typical Y. enterocolitica, and contained 18 serogroups
containing 20 O factors (Aleksi:c and Bockem:uhl, 1984).
Y. enterocolitica serogroups O:1,2a,3, O:3, O:5,27, O:8, and O:9 have been
10
commonly associated with disease. Throughout most of the world (Europe,
Japan, some part of Canada), the disease-causing O:3 strains predominate, along
with the O:9 serotype strains. In the U.S., the O:8 serotype is most frequently
incriminated, with the O:5,27 and O:6,30 strains less frequently seen. The O:3
and O:9 strains are rarely observed within the U.S. The O:8 strains are seldom
found outside the U.S. and in western Canada (Schiemann et al., 1981; Stern,
1982). Bissett et al. studied over 300 strains of Yersinia spp. excluding Y. pestis
and Y. pseudotuberculosis in U.S. and found that O:3 predominated increasing
dramatically during 1984 to 1989 (Fig. 1). Of the remaining Y. enterocolitica
isolates, over 40% were identified as belonging to serogroups generally
considered to be nonpathogenic (Bissett et al., 1990).
4. PHAGE TYPING
Twenty four bacteriophages were isolated from raw sewage and chosen as
being the most useful for differentiating strains within the four Yersinia species
(Y. enterocolitica, Y. kristensenii, Y. intermedia, and Y. frederiksenii). This set of
phages typed 92% of Y. enterocolitica, 100% of Y. kristensenii strains, 97% of
Y. frederiksenii strains, and 90% of Y. intermedia strains (Table 7) (Baker and
Farmer, III, 1982).
11
Methodology
Phage Typing
Bacterial lawns are prepared, and the phages are dropped (104 PFU/drop)
onto the lawns with the applicator, 60 drops per plate (Fig. 2, 3). After the drops
have dried for about 15 min at room temperature, the plates are incubated
overnight and examined for lysis.
12
5. GROWTH AND SURVIVAL
5.1. Nutritional Requirements
13
Y. enterocolitica is not a nutritionally fastidious organism when grown at
28C but some strains may require additional nutritional factors for growth, for
example thiamine, alanine, methionine, cysteine, glutamic acid, pantothenic
acid, and niacin. Y. enterocolitica usually grows in minimum glucose medium at
28C, but not at 37C (Swaminathan et al., 1982).
5.2. Acidity
The pH range for the survival and growth of Y. enterocolitica appears to be
4.6-9.0 (Stern et al., 1980b) with the optimum range being pH 7.0-8.0. When
incubated at 4C, strains of Y. enterocolitica grow slowly at pH values of 5.2 and
5.4 and show heavy growth at pH 5.6-7.6 (Swaminathan et al., 1982).
5.3. Temperature
The growth range of Y. enterocolitica in nutrient broth is about 1-44 C. Most
strains grow at 25-39 C, but not at 43C. Significant growth was obtained in meat
extract broth or in sterile milk at 4C, and raw or cooked meat at 7C for several
days (Olsvik and Kapperud, 1982; Swaminathan et al., 1982).
Toxin production by this pathogen is affected by growth temperature and the
composition of culture medium. Toxigenic Y. enterocolitica produced
heat-stable enterotoxin in milk at 25C, but not at 4C (Francis et al., 1980).
Strains which grew well at 4C in milk did not produce significant amount of
toxin to be detected by infant mouse assay (Olsvik and Kapperud, 1982).
Most Y. enterocolitica cells will be killed or injured when being stored during
frozen storage at -20C. When ground beef inoculated with Y. enterocolitica was
stored at -20C for 30 days, approximately 83% of the inoculated cells were
destroyed and 24% of the survivors were sublethally injured (Swaminathan et
al., 1982). In phosphate buffer, freezing at -18 and -75C for 1 h and followed by
ambient thawing resulted in 7 and 42% cell inactivation (killing) and 55 and
83% cell injury, respectively (Table 8) (El-Zawahry and Grecz, 1981).
14
Y. enterocolitica could be injured by sublethal heat treatment. When the O:3,
O:8, and O:17 cultures were thermally stressed in 0.1 M phosphate buffer, pH
7.0, at 47C for 70, 60, and 12 min, respectively, greater than 99% of the total
viable cell population was injured. The injured cell could form colony on brain
heart infusion agar, but not on trypticase soy agar plus bile salt (Table 9)
(Restaino et al., 1980).
15
Y. enterocolitica is not heat resistant bacteria, with D value at 62.8C for 15
enterotoxigenic and 6 non-enterotoxigenic cultures ranged from 0.7 to 17.8 sec
in sterile whole milk, the heat-treated cells were counted on tryticase soy agar
with yeast extract (Francis et al., 1980), it indicates that it does not survive
pasteurization. In another report (Lovett et al., 1982), three raw milk isolates of
Y. enterocolitica had D values at 62.8C from 0.24 to 0.96 min in sterile whole
milk (Table 10). However, if the initial level of Y. enterocolitica is very high,
complete destruction may not occur during pasteurilization (Swaminathan et al.,
1982). Sublethal injury of Y. enterocolitica may occur when the cells are treated
at 47C for 12-70 min (Swaminathan et al., 1982).
16
5.4. Sodium Chloride
Y. enterocolitica strains can grow in Brain Heart Infusion broth containing
5% sodium chloride at 3 or 25C (Stern et al., 1980b). It suggests that this
pathogen may be resistant to some common methods of food preservation.
5.5. Organic Acids and Salts
Trypticase soy broth with 0.1 or 0.2% sorbate adjusted to pH 5.5 with any of
the acids was bacteriostatic to Y. enterocolitica, and the organic acids,
specifically citric and lactic, potentiate the antimicrobial action of the potassium
sorbate (Restaino et al., 1982).
5.6. Radiation
Y. enterocolitica were found to be among the most radiation sensitive of
foodborne microorganisms with D values in trypticase soy broth in the range
0.7-11.8 krad, and the D value doubled in ground beef (Swaminathan et al.,
1982). In phosphate buffer, D value of Y. enterocolitica was 10, 14.3, and 24
17
krad when irradiation was carried out at 0-2, -18, and -75C, respectively, and 32,
42 and 54%, respectively, of cells were injured (inability to form colonies in
agar containing 2.5% NaCl) (Fig. 4, Table 11)(El-Zawahry and Grecz, 1981).
Under low dose (60 krad), Y. enterocolitica were sublethally
injured (Swaminathan et al., 1982).
Y. enterocolitica is more sensitive to UV than many of the pathogens
associated with waterborne disease outbreaks. The UV dose required for a 3-log
18
reduction (99.9% inactivation) of Y. enterocolitica O:3 was 2.7 mWs/cm2. No
association was found between the sensitivity of Y. enterocolitica to UV and the
presence of a 40- to 50-Mdal virulence plasmid (Butler et al., 1987).
5.7. Competitive Microorganisms
When competitive microorganisms (Micrococcus varians, Alcaligenes
faecalis, Achromobacter pestifer, and Bacillus cereus) and Y. enterocolitica
were added to pasteurized milk and held at 3C, these common spoilage
competitive organisms were isolated, while Y. enterocolitica was not present
among the colonies randomly picked (Stern et al., 1980c). It shows that Y.
enterocolitica is a poor competitor.
5.8. Controlled atmosphere
The influence on Y. enterocolitica counts of a gradual increase of carbon
dioxide concentrations (percentage by volume in air) during packaging and
storage of ground pork meat artificially contaminated with this pathogen was
evaluated. Ground meat was packaged under customary conditions using
modified atmospheres with various carbon dioxide percentages (0, 30, 50, 70,
and 100% CO2 by volume; for atmospheres of less than 100% CO2, the rest of
the gas was O2). The packs were stored at 2C for 12 days. Y. enterocolitica
counts were not significantly different (P > or = 0.05) in the ground pork
packaged under the various CO2-enriched atmospheres. The growth of Y.
enterocolitica was nearly entirely inhibited in all tested modified atmospheres
containing the protective CO2. However, in ground pork packaged with 100%
oxygen, there was a significant decrease (P < or = 0.05) for Y. enterocolitica
from 4.30 log CFU/g (day 0) to 3.09 log CFU/g at the end of the storage time
(day 12). The decrease was presumably due to the marked increase in aerobic
plate count seen only in those packages stored under 100% O2. Packaging with
high CO2 concentrations had significant inhibitory effect (P < or = 0.05) on the
growth of mesophilic aerobic bacteria (Strotmann et al., 2008).
5.9. Essential oils
Experiments were conducted to determine the effectiveness of oregano and
nutmeg essential oils (Eos) on the growth and survival of Y. enterocolitica and
Listeria monocytogenes in broth culture and in Iranian barbecued chicken.
19
Ready-to-cook Iranian barbecued chicken was prepared according to the
common practice with 1, 2, and 3 microl/g of oregano and nutmeg EOs. The test
and control (without EOs) samples were inoculated with Y. enterocolitica and L.
monocytogenes to a final concentration of 6 to 7 log CFU/g and stored at 3, 8,
and 20C. Microorganisms were counted just before and at 24, 48, and 72 h after
storage. In the broth culture system, the nutmeg EO had a greater effect on L.
monocytogenes (MIC = 0.20 nicrol/ml) than did the oregano EO (MIC = 0.26
microl/ml). However, the oregano EO had a greater effect on Y. enterocolitica
(MIC = 0.16 microl/ml) than did the nutmeg EO (MIC = 0.25 microl/ml). In
ready-to-cook Iranian barbecued chicken, the log CFU per gram of both bacteria
after up to 72 h of incubation was not decreased significantly by various
combinations of oregano and nutmeg EOs (1, 2, and 3 microl/g) and storage
temperatures (3, 8, and 20C) when compared with control samples (without
EOs). Although examination of spices in culture media can yield accurate
microbiological data, without complementary tests in foods these data are of
limited value for assessing food safety (Firouzi et al., 2007).
5.10. Physiology
Y. enterocolitica tolerates osmotic stress by intracellular accumulation of
osmolytes, such as betaine. The proP gene and proU operon of Y. enterocolitica
were sequenced, and single (ProP- ProU+ and ProP+ ProU-) and double (ProPProU-) mutants were generated. Upon exposure to osmotic or chill stress, the
single and double mutants demonstrated a reduction in betaine uptake compared
to that in the wild type (Fig. 5), suggesting that proP and proU play a role in
betaine uptake during osmotic and chill stress responses of Y. enterocolitica
(Annamalai and Venkitanarayanan, 2009).
20
6. OCCURRENCE IN FOODS AND ENVIRONMENT
6.1. Animals
The evidence is not yet complete as to whether humans serve as reservoirs of
Y. enterocolitica. It is isolated from low percentage of asymptomatic humans.
However, it appears that the animal kingdom is a significant reservoir. Some
members of the animal kingdom harbor unique serotypes of Y. enterocolitica
which have not been implicated in human infections.
The swine has been implicated as a major reservoir of Y. enterocolitica
seotypes involved in human infections although a definite connection between
the isolation of Y. enterocolitica from the swine and human illness remains to be
21
established. The incidence of Y. enterocolitica in swine varies not only from
country to country but also within a country. The rate of isolation of Y.
enterocolitica from tonsils and tongues of pigs is generally greater than the rate
of isolation from cecal or fecal materials. Y. enterocolitica serotype O:3 has
been almost exclusively isolated from swine in some European countries, like
Denmark, Belgium and Sweden. Some investigators concluded that O:3 strain is
a normal inhabitant of the oral cavity of swine, and also involved in human
infection.
Examination of the throat flora from swine in Ontario for Y. enterocolitica
found the incidence of serotype O:3 to vary from 20% for tonsils to 50% for
throat swabs and 55% for tongues. In contrast, there were no isolations of
serotype O:3 from throat swabs taken from swine in the western provinces of
Canada. This incidence of serotype O:3 in swine correlates well with the human
incidence of the same serotype which is 81% for all human isolations of Y.
enterocolitica in the eastern provinces and 4% in the western provinces of
Canada. The opposite relationship is true for serotype O:5,27. Majority of O:3,
O:5,27 were positive for autoagglutination, a test which has been associated
with virulence. The results suggest that swine are an important source of human
infections with both O:3 and O5,27 (Table 12) (Schiemann and Fleming, 1981).
In Guangxi, mainland China, Y. enterocolitica were isolated from 48.4% of
the swine with diarrhea, most of the isolates were O:3 with two isolates
22
belonged to serotype O:9 (Zheng, 1987). These two serotypes are considered to
be pathogenic for humans.
In another study in China, Y. enterocolitica (1,295 strains) was isolated from
diarrhea patients, livestock, poultry, wild animals, insect vectors, food, and the
environment. They were studied for epidemiology distribution using bacterial
biochemical metabolism tests, their virulence genes, and pulsed-field gel
electrophoresis (PFGE) sub-typing. The data showed that 416 of the 1,295
strains were pathogenic, where the pathogenic Chinese isolates were of
serotypes O:3 and O:9. These two serotypes were found in livestock and poultry,
with swine serving as the major reservoir. The geographic distribution of
pathogenic isolates was significantly different, where most of the strains were
isolated from the cold northern areas, whereas some serotype O:3 strains were
recovered from the warm southern areas. By the analysis of the data of the
Ningxia Hui Autonomous Region, the phenomenon of 'concentric circle
distribution' was found around animal reservoirs and human habitation. The
clustering of PFGE showed that the patterns of the pathogenic strains isolated
from diarrhea patients were identical compared to those from the animals in the
same area, thus, suggesting that the human infection originated from the animals
(Wang et al., 2009).
In many years of surveillance in China for Y. enterocolitica, no pathogenic
O:8 strains have been found where the isolated O:8 serotypes lacked the major
virulence genes and in contrast to O:3 and O:9 strains, none of the O:8 isolates
were from humans. These O:8 isolates lack ail, ystA, yadA and virF genes but
possess the ystB gene and all belong to Biotype 1A. These O:8 strains did not
kill mice and could protect immunized mice against challenge with a pathogenic
O:8 strain. Compared to the Chinese pathogenic O:3 and O:9 strains which have
similar pulsed-field gel electrophoresis patterns, the 39 Chinese O:8 animal and
food isolates were different from the pathogenic O:8 reference strains. This
suggests the O:8 strains lacking virulence determinants may not disseminate
rapidly in humans and are maintained in animal reservoirs; and therefore exhibit
higher variance and divergence from the virulent type (Wang et al., 2008).
Sixteen different isolates of Y. enterocolitica were recovered from porcine
tongues, including six O:8, four O:6,30, two O:3, and one each of O:13,7, O:18,
and O:46 (Doyle et al., 1981). All the serotype O:8 isolates were virulent to
mice, causing the death of adults after oral challenge (Doyle et al., 1981).
23
In a cross-sectional study, individual pigs on eight swine operations were
sampled for the presence of Y. enterocolitica. On each farm, both feces and
oral-pharyngeal swabs were collected from pigs in five different production
phases: gestating, farrowing, suckling, nursery, and finishing. A pig was
considered positive if either sample tested positive. Of the 2,349 pigs sampled,
120 (5.1%) tested positive, and of those, 51 were ail positive (42.5% of Y.
enterocolitica isolates). On all farms, there was a trend of increasing prevalence
as pigs mature. Less than 1% of suckling piglets tested positive for Y.
enterocolitica. Only 1.4% (44.4% of which were ail positive) of nursery pigs
tested positive, but 10.7% (48.1% of which were ail positive) of finishing pigs
harbored Y. enterocolitica. Interestingly, gestating sows had the second highest
prevalence of Y. enterocolitica at 9.1% (26.7% of which were ail positive), yet Y.
enterocolitica was never detected from the farrowing sows (Bowman et al.,
2007).
Dogs have also been incriminated as potential reservoirs. Isolation of Y.
enterocolitica from small rodents, cows, horses, sheep, monkeys, deer and snails
have also been reported. Y. enterocolitica or related species were isolated from
50% of cows in Scotland, and the isolates varied in serotypes (Davey et al.,
1983).
Y. enterocolitica were isolated from wild animals (Kaneko and Hashimoto,
1981; Kato et al., 1985), e.g. from 16 of 495 small wild animals (mainly mice)
and from 1 of 38 foxes (Kaneko and Hashimoto, 1981). The Y. enterocolitica
isolates were O:6, O:5A, O:4, and O:9.
6.2. Water and Soil
Y. enterocolitica has been isolated from water by a number of investigators
and note that water may be a reservoir for this pathogen. In general, isolates of Y.
enterocolitica from water differ from those implicated in human disease. One
investigator reported that a strain isolated from well water was capable of
survival and proliferation in sterile water at 4, 25 or 37C. However, other
investigators have reported that Y. enterocolitica does not survive or multiply in
water at low temperatures in the absence of organic matter. Chao et al. reported
that population of Y. enterocolitica decreased rapidly in river water and it is
chiefly regulated by predators and toxin producers (Chao et al., 1988).
24
When it was introduced into soils and air dried slowly, only 0.1% of the
original population added still remained viable by day 10 (Chao et al., 1988).
6.3. Isolation from Foods
Y. enterocolitica has been isolated from milk and milk products, egg
products, raw meats (beef, pork, lamb) and poultry, vegetables and
miscellaneous prepared food products. However, most of these isolates are
atypical strains and usually non-serotypable. Most of these isolates lack any
pathological significance in humans (Table 13) (Prpic et al., 1985). Therefore,
isolation of Y. enterocolitica from a food is insufficient to ascribe any
pathogenic significance to such isolation (Swaminathan et al., 1982).
From Milk and Milk Products
Y. enterocolitica has been isolated from raw milk in many countries, like
Australia, Canada, Czedhoslovakia, and USA. There were also a few reports on
the isolation of this pathogen from pasteurized milk. It may be due to the
malfunction in the pasteurization process leading to inadequate treatment or
post-process contamination, or it may be due to the contamination of
heat-resistant strains of Y. enterocolitica. However, heat-resistant strains have
not been reported.
25
Stern reported that Y. enterocolitica could grow in whole milk at 3C (Stern,
1982). Also the reduction of psychrotrophic bacteria in milk after pasteurization
would enable a poor competitor and opportunistic pathogen such as Y.
enterocolitica to grow better in pasteurized than in raw milk. So, the presence of
this pathogen in pasteurized milk should be a cause for concern.
Y. enterocolitica was isolated from 9.2% of cheese curd samples in Canada
(Swaminathan et al., 1982).
From Meat and Poultry Products
Y. enterocolitica are commonly detected in meat and poultry products (Table
14). The level of this pathogen was found consistently in high numbers on
vacuum-packed meats with a pH above 6 held at low temperature (Swaminathan
et al., 1982). Growth of this pathogen is enhanced in cooked meats or at low
temperature whereas competitive microorganisms are inactivated.
Table 14. Incidence of Y. enterocolitica in meats
Food item
Pork
Incidence rate %
34.5
49
Investigators
Leistner et al. 1975
Schiemann 1980
Swine carcass
tongue & trim
Swine throat
Swine throat
Pig tonsils
Pork tongues
Pork,ground
Pork, processed
18.6
9
53
29.6
65
60
7
(Harmon et al., 1984)
(Stern, 1981)
Wauters & Janssens 1976
Hanna et al 1980
Schiemann 1980
Schiemann 1980
Schiemann 1980
Chicken
28.9
Leistner et al. 1975
Beef
10.8
Leistner et al. 1975
14.6
Inoue & Kurose 1975
From (Swaminathan et al., 1982) and (Stern, 1981).
26
Prevalence of pathogenic Y. enterocolitica in different sources in Bavaria is
presented. The highest isolation rate of pathogenic Y. enterocolitica (67%) was
found in tonsils of slaughter pigs. No pathogenic strains were isolated from
cattle, sheep, turkey, and horses. ail-Positive Y. enterocolitica was detected in
dogs (5%), cats (3%), and rodents (3%) by real-time PCR. Pathogenic Y.
enterocolitica was isolated only from raw pork, especially from edible offal
(51%). All pathogenic Y. enterocolitica isolates from nonhuman sources were
belonging to bioserotype 4/O:3. All Y. enterocolitica 4/O:3 strains were
susceptible to most of the tested antibacterial agents (Bucher et al., 2008).
From Other Foods
Strains of Y. enterocolitica have been isolated from oysters, mussels, shrimp,
blue crab, fish, chicken salad and stewed mushrooms, and cabbage, celery and
carrots (Swaminathan et al., 1982).
7. ISOLATION AND IDENTIFICATION
At present, there are no completely reliable methods for recovering
pathogenic Y. enterocolitica from foods and environmental samples. Procedures
used may be different from country to country.
7.1. Selective Enrichments
The food sample is usually blended for 2 min, or a surface swab is shaken, in
a phosphate buffered saline (PBS) solution. Aliquot is usually cold enriched at
4C for up to 4 weeks. Enrichment in phosphate buffered saline at 4C was an
ineffective method for the recovery of Y. enterocolitica from food sample and it
takes a long time. Cold enrichment in PBS is useful for clinical samples for the
isolation of O:3 strains.
A number of selective enrichment media have been formulated, but each
medium may not suitable for all the isolates of Y. enterocolitica. Addition of 1%
sorbitol and 0.15% bile salts No.3 to PBS resulted in the enhanced recovery of Y.
27
enterocolitica from meats, and addition of hemoglobin (0.1%) and potassium
oxalate (0.2%) to the sorbitol-bile salts-PBS medium has been recommended for
vegetable products (Swaminathan et al., 1982).
A modified Rappaport's medium, termed magnesium chloride-malachite
green-carbenicillin (MMC) medium was reported to increase the number of
isolations of Y. enterocolitica O:3 and O:9 from clinical specimens (incubated at
22C). However, it was shown to be inhibitory to many isolates. Two modified
selenite media, prepared by supplementing PBS (pH 7.5) with malachite green
(20 μg/ml), carbenicillin (10 μg/ml) and sodium selenite (150 mg or 250 mg/100
ml) were reported to be effective in recoverying Y. enterocolitica from meat
samples when incubated at 22C for 2-3 days (Swaminathan et al., 1982).
A two-step enrichment procedure for recovery of Y. enterocolitica was
developed (Schiemann, 1982). The first step is a preenrichment at 4C or 10C in
yeast extract-rose Bengal broth for 3 days. The second step is a selective
enrichment in bile-oxalate-sorbose broth with/without NaCl incubated at 22C
for 3 days. This procedure showed improved and more rapid recovery of human
strains of Y. enterocolitica from inoculated foods as compared to modified
Rappaport broth and cold enrichment (Table 15) (Schiemann, 1982). The
bile-oxalate-sorbose broth was modified by adding peptone (5 g/L) for water
(fresh and marine) and other nonfood samples. Sample enriched in this modified
medium at 22C for 48 h resulted in higher recovery (Weagant and Kaysner,
1983).
28
Walker and Gilmour reported that pre-enrichment in trypticase soy broth for
24 h at 22C followed by selective enrichment in bile-oxalate-sorbose medium
for 5 days at 22C allowed highest yield of Y. enterocolitica (Walker and Gilmour,
1986).
Y. enterocolitica tolerates short exposures to weak alkali better than other
members of the Enterobacteriaceae (Schiemann, 1983). So, the cold enriched
cultures could be mixed with a solution of 0.5% potassium hydroxide in 0.5%
sodium chloride before streaking for isolation on selective agars (Swaminathan
et al., 1982). The alkalotolerance of Y. enterocolitica is affected by the phase of
growth, temperature and medium of treatment. The addition of peptones to
potassium hydroxide provided a protective effect. Log-phase cells were less
alkalotolerant than cells in the stationary phase of growth. The rate of cell
destruction was five times greater at 30C than at 20C(Schiemann, 1983).
A new enrichment broth was derived from the modified Rappaport base by
supplementing with Irgasan, ticarcillin, and potassium chlorate (ITC). Sample
was inoculated into this medium and incubated at 24C for 2-3 days, and this
medium was shown to be good for Y. enterocolitica O:3 (Wauters et al., 1988).
29
7.2. Selective Differential Plating
Y. enterocolitica can grow on many selective media commonly used for the
isolation of enteric pathogens. Serotypes O:3, O:8 and O:9 grow well and form
colonies on bismuth sulphite, endo, eosin methylene blue, MacConkey,
desoxycholate-citrate, Salmonella-Shigella media, etc. However, some serotypes
of Y. enterocolitica may not grow on all of these media, or they grow slowly and
form tiny colonies and can be easily overlooked.
A number of selective media have been formulated and compared:
MT agar: a modified MacConkey agar containing Tween 80 and calcium
chloride. Colony is about 2 mm, flat, wrinkled, surrounded by a sheen.
DST agar: a modified DNAase agar and contains Tween 80, sorbitol, sodium
lauryl sulphate and calcium chloride. Colony is translucent, colorless or pink
with little or no lipolytic reaction or nuclease reaction.
Modified Salmonella-Shigella agar with 2% deoxycholate.
Y medium: contains sodium oxalate, sodium desoxycholate and bile salts and
with peptone and casein hydrolysate.
CIN agar: contains the selective agents celsulodin (4 or 15 mg/L), irgasan (4
mg/L), and novobiocin (2.5 mg/L). It is a widely accepted medium.
CAL medium: contains cellobiose, arginine and lysine. Y. enterocolitica
ferments cellobiose to produce acid and the resultant change in pH and the
presence of neutral red in the medium impart a burgundy or red color to the
colony (Swaminathan et al., 1982).
DYS medium: like Y medium. It contains bile salts, sodium deoxycholate,
sodium chloride, arabinose, arginine, lysine, neutral red in addition to peptone
and casein hydrolysate. It was shown to be better than Y medium, MacConkey,
Salmonella-Shigella medium (Agbonlahor et al., 1982).
Nine selective media were compared (Walker and Gilmour, 1986). CIN agar,
incubated for 48 h at 25C, allowed a high recovery of all the Yersinia spp. and
30
was the most selective medium. Two different kinds of CIN agar, containing 4
mg (Difco) or 15 mg (Oxoid) of cefsulodin per liter, are commercially available.
Seven selective differential plating media were also evaluated by Harmon et al.
(Harmon et al., 1983). CIN agar was the most effective medium for the recovery
of Y. enterocolitica. However, Y. enterocolitica O:12,25 was slightly inhibited on
CIN agar. As evaluated by Head et al., CIN is the most effective medium for the
recovery of Y. enterocolitica (Table 16) (Head et al., 1982).
However, CIN media inhibited the growth of Y. pseudotuberculosis and Y.
enterocolitica biotype 3B serotype O:3 but not the growth of the other Yersinia
organisms. Since the Y. enterocolitica 3B/O3 strains were resistant to cefulodin,
Irgasan, and novobiocin at the concentrations used in these CIN media, it
suggests that growth inhibition of Y. enterocolitica 3B/O3 is related to a
component of the CIN base (Fukushima and Gomyoda, 1986).
Direct KOH treatment of meat samples could be a valuable rapid method for
direct isolation of Yersinia from meat contaminated with more than 100 cells per
g. In another study, ground pork with artificially contaminated Y. enterocolitica
was homogenized in 0.85% NaCl, treated/not treated with 0.72% KOH in 0.5%
NaCl, and plated on CIN or MacConkey agar. The sample was also cold
enriched in phosphate buffer for 1-14 days. All Yersinia strains were recovered
from the pork samples contaminated with more than 100 cells per g after direct
KOH treatment, without enrichment. However, virulent Yersinia isolates in pork
31
samples contaminated with less than 104 cells per g were never recovered by
using KOH postenrichment treatment (Fukushima, 1985).
Another selective agar medium for direct isolation of virulent Y.
enterocolitica was formulated (Fukushima, 1985). This VYE agar consists of
sodium deoxycholate, mannitol, esculin, ferric citrate, sodium chloride, neutral
red, crystal violet, irgasan, cefsulodin, oleandomycin, and josamycin in addition
to peptone and agar. This VYE agar proveded a quantitative recovery of 51
different strains of virulent Y. enterocolitica at 32C after incubation for 24 h.
Virulent Y. enterocolitica formed red colonies is easily differentiated from most
environmental Yersinia spp. and other gran-negative bacteria, which form dark
colonies with dark peripheral zone as a result of esculin hydrolysis (Fukushima,
1987).
The selective agars most commonly used to isolate Y. enterocolitica in
clinical, food and environmental samples, cefsulodin–irgasan–novobiocin (CIN)
and MacConkey (MAC) agars, lack the ability to differentiate potentially
virulent Y. enterocolitica from other Yersinia that may be present as well as
some other bacterial species. A new agar medium, Y. enterocolitica chromogenic
medium (YeCM), for isolation of potentially virulent Y. enterocolitica was
developed. This agar contains cellobiose as the fermentable sugar, a
chromogenic substrate and selective inhibitors for suppression of colony
formation by many competing bacteria. All strains of potentially virulent
Yersinia of biotypes 1B, and biotypes 2-5 formed convex, red bulls-eye colonies
on YeCM that were very similar to those described for CIN agar. However, Y.
enterocolitica biotype 1A and other related Yersinia formed colonies that were
purple/blue on YeCM while they formed typical red bulls-eye colonies on CIN
agar. When a mixture of potentially virulent Y. enterocolitica biotype 1B, Y.
enterocolitica biotype 1A and 5 other bacterial species was used to artificially
contaminate tofu and then spread-plated on three selective agars, Y.
enterocolitica biotype 1B colonies were easily distinguished from other strains
on YeCM. However, Y. enterocolitica biotype 1B colonies were
indistinguishable from many other colonies on CIN and only distinguishable
from those of C. freundii on MAC. When colonies were picked and identified
from these agars, typical colonies from YeCM were confirmed only as Y.
enterocolitica biotype 1B. Typical colonies on CIN and MAC were found to
belong to several competing species and biotypes (Weagant, 2008).
32
7.3. Identification
For selective plates, colonies with characteristic appearances are screened
through the triple sugar iron (TSI) or Kligler iron agar (KIA) slant. Presumptive
Y. enterocolitica should present an acid-slant, acid-butt, no-gas, and no-H2S TSI
test. KIA should yield an alkaline slant and acid butt with no gas or H2S
production. Then the presumptive siolate should yield a positive urease test and
a negative phenylalanine-deaminase test. Confirmation of a Y. enterocolitica
isolate can be made through the use of a rapid bacterial identification kit such as
the API 20E.
A medium, lysine-arginine-iron agar (LAIA), was developed for the
presumptive identification of Y. enterocolitica (Weagant, 1983). In this medium,
lysine-iron agar is modified by the addition of 1% L-arginine, and allows for the
testing of five biochemical characteristics in a single tube medium. Typical
reactions of Yersinia spp. on LAIA are alkaline slant (purple), acid butt (yellow),
no H2S (darkening of butt), or gas formation (no gas).
PathoTec Test strips for ornithine decarboxylase (OD), Voges-Proskauer (VP),
and urease test (UR) (General Diagnostics, Morris Plains, NJ) could be used for
rapid confirming the identification Y. enterocolitica isolated from food
enrichments on CIN agar (Devenish and Schiemann, 1981). Test strips are put
into bacterial suspensions in phosphate-buffered saline and incubated at 22 or
35C for 6-24 h. The Y. enterocolitica are VP (22C), OD (22C), and UR (35C)
positive. The most convenient method for accurate testing was the growth of the
organism on blood agar at 35C for 22 h and incubation of the three PathoTec
test strips at 22C for 24 h (Devenish and Schiemann, 1981).
Also, virulence potential should be tested. There are a number of tests for
virulence, e.g. enterotoxin, invasiveness, plasmid analysis, calcium dependency,
hydrophobicity, autoagglutination, production of V and W antigens and other
outer membrane proteins etc (Prpic et al., 1985). The most simple assay is
autoagglutination. Two tubes of tissue culture medium are inoculated, and one is
incubated at 23C and the second at 35C. If after overnight incubation the
content of the tube at 35C has autoagglutinated while the tube held at 23C is
turbid, the strain shows potential for virulence to humans (Stern, 1982).
Discussion on the virulence factors is given in the following section.
33
An Enzyme Immunoassay (EIA) for the detection of pathogenic Y.
enterocolitica and Y. pseudotuberculosis was developed(Kaneko and Maruyama,
1989). Antiserum against plasmid-encoded proteins of serotype O:3 was
prepared by immuning rabbit with formalinized-fixied cells which were grown
at 37C for 24 h and the antiserum was absorbed with cells of plasmid-cured Y.
enterocolitica cells grown at 37C. The antisera developed reacted with proteins
released from O:3, O:5,27, O;8, and O:9 and strains of Y. pseudotuberculosis.
Plasmid-cured Yersinia strains did not react in this EIA system (Kaneko and
Maruyama, 1989).
An objective Pyrolysis gas-liquid chromatography (PGLC) was used to
differentiate between HeLa cell-invasive and noninvasive strains of Y.
enterocolitica and between Sereny-positive and -negative strains, and the groups
were separated by stepwise linear discriminate analysis (SLDA) and the results
showed good correlation in prediction of the HeLa cell invasivity test (Stern et
al., 1980a). However, it is not simple in a microbiology laboratory.
7.4. Membrane Filter Method
For determining the low level of Y. enterocolitica in water sample, a
membrane filter method is developed by Bartley et al. (Fig. 6) (Bartley et al.,
1982). Bacteria collected on membrane are placed on Mye recovery broth
containing deoxycholate as the selective agents and incubated at 25C for 48 h.
The membrane is then placed on mYE lysine-arginine agar and incubated
anaerobically at 35C for one h. The vivid yellow to yellow orange colonies
(sorb+ lys- arg-) are marked. Then the membrane is placed on mYE urease
broth, incubated at 25C for 5-10 min, and the deep blue marked colonies
(urease+) are picked as presumptive Y. enterocolitica. The presumptive
identification of Y. enterocolitica was accomplished in 50 h, and the rate of
identity confirmation of typical colonies was 88%. The mean recovery rate of 15
strains from phosphate buffer suspensions was 91%, and quantitative recovery
was demonstrated for low populations of organism in both laboratory-prepared
and naturally occurring mixed cultures.
34
7.5. DNA Hybridization Method
The DNA colony hybridization method has two useful features: neither pure
cultures nor physiologically stressful enrichments are necessary.
The virulence determinants of Y. enterocolitica show a correlation with the
presence of plasmids of 42 to 48 Mdal. So, virulent Y. enterocolitica can be
detected by colony hybridization using a probe derived from such virulent
plasmid. Hill et al. developed such DNA hybridization method for Y.
enterocolitica (Hill et al., 1983; Jagow and Hill, 1986). The virulent plasmid
pYV8081, 44 Mdal, was purified from Y. enterocolitica 8081 and digested with
the BamHI and three fragments with molecular size 3.8, 4.3, and 5.0 kb were
eluted, pooled and labeled with 32P and used as probe. The use of whole plasmid
as a probe is not entirely satisfactory, possibly because of some genetic
homology shown by pYV8081 and the host chromosomal DNA. The results of
the colony hybridization test for virulence were the same as those obtained by
the autoagglutination and suckling mouse tests (Hill et al., 1983).
Later, Jagow and Hill tested the efficiency of enumeration of this colony
hybridization method. Testing 11 artificially contaminated foods, the colonies
observed ranged from 66 to 100% (average, 86%) and was influenced by the
35
number of indigenous bacteria. The use of nitrocellulose filters and agar
medium had little effect on efficiency of enumeration. For high indigenous
bacteria (over 107 cfu/g), exposure of the sample for a few seconds to a 1:25
dilution of 0.5% KOH-0.5% NaCl before plating on nitrocellulose filters
enhanced the selection of Y. enterocolitica (Jagow and Hill, 1986).
7.6. Commercial Rapid Detection Kit
In 1982, the API Z system (France) was introduced as a screen for Salmonella
and Shigella spp. The API Z system was subsequently renamed as Rapid SYS
and extended the screening claim to include Y. enterocolitica. However, a
evaluation test showed that this Rapid SYS system cannot be used in US for the
detection of Y. enterocolitica. All the biotype 1 isolates produce lipase and could
be potentially eliminated by the Rapid SYS system as nonpathogens. Pathogenic
strains of Y. enterocolitica biotype 1 are rarely encountered in Europe, but they
have been encountered frequently in the US (Mele et al., 1987).
7.7. DNA microarray
Four different food matrices (alfalfa, cilantro, mamey sapote, and mung bean)
were contaminated with three different dilutions 106, 104, and 103 CFU/g of Y.
enterocolitica. DNA was isolated from each food mix and used in chromosomal
amplifications. The amplified DNA was used as templates in single PCR
reactions of the four genes (virF, ail, yst, and blaA) followed by mixing the four
reactions for one PCR primer extension reaction. The presence and the limit of
detection of four genes in four food matrices were established by microarray
hybridization. Data revealed the diversity of signal intensities. Neither the
microarray chip hybridization nor the single PCR amplification could detect
virF's presence located on a plasmid. Ail was detected in 103 CFU/g, whereas
blaA and yst were detected from 105 to 106 CFU/g in all food matrices (Fig. 7,
Table 17). Therefore, the ail gene could be the gene of choice in identifying Y.
enterocolitica in alfalfa, cilantro, mamey, and mung bean. Other genes--blaA,
yst, virF--exhibited wide variability in hybridization signals, highlighting the
need of a better DNA purification step prior to DNA microarray hybridization
(Siddique et al., 2009).
36
37
7.8. Real-time PCR
A TaqMan probe-based real-time PCR method for the detection of Y.
enterocolitica was developed. The complete method comprises overnight
enrichment, DNA extraction, and real-time PCR amplification. Also included in
the method is an internal amplification control. The selected primer-probe set
was designed to use a 163-bp amplicon from the chromosomally located gene
ail (attachment and invasion locus). The selectivity of the PCR method was
tested with a diverse range (n = 152) of related and unrelated strains, and no
false-negative or false-positive PCR results were obtained (Table 18). The
sensitivity of the PCR amplification was 85 fg purified genomic DNA,
equivalent to 10 cells per PCR tube. Following the enrichment of 10 g of
various food samples (milk, minced beef, cold-smoked sausage, fish, and
carrots), the sensitivity ranged from 0.5 to 55 CFU Y. enterocolitica. In addition,
the method was tested on naturally contaminated food; in all, 18 out of 125
samples were positive for the ail gene (Lambertz et al., 2008).
38
8. PATHOGENICITY AND VIRULENCE FACTORS
8.1. Clinical Manifestations
Gastroenteritis in humans is the major expression of the pathogenic Y.
enterocolitica. Frequently reported sympotoms include: diarrhea, fever,
vomiting, abdominal pain, nausea and headaches. Although relatively rare,
fatality due to Y. enterocolitica does occur, but the patient's recovery is generally
complete within 1 to 2 days (Stern, 1982; Stern and Pierson, 1979).
In a human volunteer study, one individual took an oral dose of 3.5x109 cells
of Y. enterocolitica, and the results were similar to those reported in other food
and water-borne bacterial infections; the organism caused enterocolitis, darrhea
and a fever. The acute symptoms ceased after 2 days of discomfort. Tenderness
in the stomach and liver region lasted 4 weeks (Stern and Pierson, 1979). The
organism must proliferate under favorable growth conditions and must be
present in sufficient numbers to cause infectivity.
Y. enterocolitica has been implicated in certain acute human diseases, such
as enteritis, pseudoappendecitis, mesenteric lymphadenitis, terminal ileitis, and
arthritis (Stern and Pierson, 1979). Y. enterocolitica accounted for 3.8% of the
appendectomies performed becaused of the similarities in Y. enterocolitica
enteritis and appendicitis. Indeed appendectomies were performed on 16
children after they contracted Y. enterocolitica enteritis in the New York
chocolate milk outbreak (Stern and Pierson, 1979; Swaminathan et al., 1982).
Y. enterocolitica has been isolated from the cerebrospinal fluid, blood, urine, and
eyes of infected patients (Stern and Pierson, 1979). Y. enterocolitica has been
occasionally occurring in donor blood from healthy donors or donors with a
diarrhea history, such contaminated blood sometimes caused Yersinia
bacteremia and death of the recipients (Table 19) (Jacobs et al., 1989).
39
Tests on the pathogenicity of the species for mice and other laboratory
animals have been studied. Intraperitoneal administration of Y. enterocolitica
O:3 at a level of 3x109 cells caused the death of guinea pigs in 24-48 h while
subcutaneous administration of the same organism at the same level had no
observable effect on guinea pigs. Intravenous administration of Y. enterocolitica
O:3 to rabbits caused death in 5-11 days. Marked inflammation was noted in the
liver of the animals and a hemorrhagic-necrotic inflammation with ulceration
was observed in the appendix. After intravenous administration of Y.
enterocolitica O:8, a systemic, pyogenic infection involving the spleen, the liver
and the lungs was observed in mice. The initial site of infection in mice after
intragastric challenge with Y. enterocolitica O:8 was reported to be the Peyer's
patches of the distal ileum. The primary lesions were found to appear as
abscesses in the Peyer's patches and as caseous necrosis of the mesenteric lymph
node (Swaminathan et al., 1982).
Oral administration of Vwa plasmid (70-kDa) positive strains of Y.
enterocolitica to mice resulted in systemic infection while the Vwa-negative
strains did not (Bakour et al., 1985). After feeding Y. enterocolitica suspension
for one day, these pathogenic bacteria were found in the spleen of the test
animal next day.
40
The course of bacterial penetration and spreading was determined by
immunohistochemical staining and electron microscopy of mice after oral
administration of Y. enterocolitica (Hanski et al., 1989). The bacteria entered
Peyer's patches, which were about 1,000 times more heavily colonized than the
surrounding epithelium of a comparable surface area. The number of bacteria in
a single Peyer's patch was comparable to that in the rest of the ileal mucosa,
nevertheless, the epithelial surface of the ileum is estimated to be 750 to 12,000
times greater than the surface of a single Peyer's patch (Fig. 8). The bacteria
proliferated in the follicles, from which they spread into the lamina propria of
the villi. At either site most of the bacteria multiplied extracellularly (Fig. 9),
with only a small percentage observed to be present within the pahgocytes. The
bacteria did not appear to be able to pass the intact basement membrane; hence,
the integrity of the basement membrane is likely to play a role in derermining
the route of entry and limit of spread of Y. enterocolitica infection (Hanski et al.,
1989).
41
Sereny test is commonly conducted to determine pathogenicity of Y.
enterocolitica. The bacteria were inoculated into the conjunctival sac of guinea
pig and observe keratoconjunctivitis for 7 days. Not all the pathogenic strains
showed positive Sereny test (Swaminathan et al., 1982).
Y. enterocolitica O:3, O:5B, O:8 and O:9 were found to be highly virulent in
mice, rabbits, and monkeys, regardless of the origin of the strains. These strains
caused lesions in the spleen, the liver and the intestine of these animals
(Swaminathan et al., 1982). Generally no single current assay correlates with
virulence in Y. enterocolitica. Among the isolates from human, two strains
caused conjunctivitis in guinea pigs, 7 were lethal for mice, 54 invaded HEp-2
cells, 18 produced a heat-stable enterotoxin, 9 were calcium dependent, and 20
autoagglutinatied (Kay et al., 1983).
42
Animals can be protected against Y. enterocolitica by pre-administration of Y.
enterocolitica or Y. pseudotuberculosis. Mice given orally either the O:3, O:9 or
O:5B of viable Y. enterocolitica showed protection upon subsequent oral
challenge with another of these strains. Excretion of serovar O:3 in the feces
was inhibited in mice surviving oral challenge with Y. pseudotuberculosis
(Uchida et al., 1982). Mice vaccinated orally with heat-killed cells of O:3 of Y.
enterocolitica were protected only against fecal excretion of the homologous
serovar, whereas Formalin-killed cells provided cross-protection against O:9
and vice versa. Formalin-killed Y. pseudotuberculosis also provided
cross-protection against Y. enterocolitica (Kaneko and Hashimoto, 1983).
Virulence genes
Clinical isolates of pathogenic Y. enterocolitica in China cultured from the
culture method were examined for virulence genes (inv, ail, ystA, ystB, ystC,
yadA, virF) by PCR and for the presence of plasmid by four phenotypic tests.
The positive rate of virulence genes tested in 160 isolates was inv (100%), ail
(94%), ystA (93%), ystB (7.5%), ystC (5%), yadA (89%) and virF (82%) while
the phenotypic test included autoagglutination (87%), binding of crystal violet
(89%), calcium-dependent growth (74%) and Congo red absorption (78%),
respectively. Not all pathogenic Y. enterocolitica necessarily carry all traditional
virulence genes in both chromosomes and plasmids to cause illness. Perhaps,
some of them, lacking some traditional virulence genes, contain other unknown
virulence markers that interact with each other and play an important role in the
diverse pathogenesis of pathogenic Y. enterocolitica (Zheng et al., 2008).
Virulence-associated genes viz. ail, virF, inv, myfA, ystA, ystB, ystC, tccC,
hreP, fepA, fepD, fes, ymoA and sat were studied in 81 clinical and nonclinical
strains of Y. enterocolitica biovar 1A by PCR amplification (Table 20). All
strains lacked ail, virF, ystA and ystC genes. The distribution of other genes
with respect to clonal groups revealed that four genes viz. ystB, hreP, myfA and
sat were associated exclusively with strains belonging to clonal group. The
distribution of virulence-associated genes, however, did not differ significantly
between clinical and nonclinical strains (Table 21). In strains of Y.
enterocolitica biovar 1A, clonal groups seem to reflect virulence potential better
than the source (clinical vs. nonclinical) of isolation (Bhagat and Virdi, 2007).
43
44
8.2. Effects of Sublethal Stresses on Virulence
In aquatic environments copper and other elements, even in trace amounts,
present potentially important causes of bacterial injury. Extent of injury is
usually determined by the numbers of differential CFU on nonselective tryptic
lactose yeast extract agar (TLY) and a selective agar (TLY supplemented with
0.1% sodium deoxycholate). A sublethal concentration of copper (0.75 mg/L)
caused substantial injury (87 to 95%) of Y. enterocolitica O:8 cells in 72 h at 4C
without producing extensive cell death (Fig. 10, 11). Copper-injured cells had a
higher LD50 dose in mice than uninjured cells (Table 22). This reduced virulence
correlated with more rapid clearance of the injured cells from the blood of mice
after intravenous inoculation (Fig. 12). A possibe role of the liver in this process
was shown by significant cell accumulation in mouse livers when
copper-injured Y. enterocolitica cells were administered, compared with
uninjured bacteria. In vitro studies with isolated mouse liver membranes showed
higher titers of aggregation with copper injured cells than control cells. The in
vitro aggregation reaction and blood clearance activity in vivo were abolished
by sugars that are known to interact with a hepatic lectin (Fig. 13). It suggested
that copper-induced injury reduces the virulence of Y. enterocolitica and that the
liver may be involved in nonimmune rapid clearance of the injured cells,
probably by interaction with a hepatic lectin(s) (Singh et al., 1985).
45
46
47
Both copper and chlorine caused injury of Y. enterocolitica. Injury of the
exposed cells was further enhanced in the gastric environment of mice. The low
gastric pH caused extensive loss of viability in copper-injured cells, and the
lethality in the chlorine-injured cells was less extensive. The virulence of
chlorine-injured Y. enterocolitica in orally inoculated mice was similar to that of
the control culture (Singh and McFeters, 1987).
8.3. Enterotoxin
Production of a heat-stable enterotoxin (ST) by Y. enterocolitica has been
demonstrated (Stable at 100C for 20 min and at 120C for 15 min) (Okamoto et
al., 1982; Swaminathan et al., 1982; Verma and Misra, 1984), and it is
controlled by a chromosomal gene (Robins-Browne et al., 1985). Serotypes O:3,
O:8 and O:9 are almost always enterotoxigenic. Production of heat-labile
enterotoxin by Y. enterocolitica has not been demonstrated (Swaminathan et al.,
1982). ST of Y. enterocolitica is excreted into the culture supernatant of the
late-log phase of growth and increased lineally during the stationary phase of
48
growth. The ST level becomes maximum at the decline phase of growth, and the
ST is not detected in the lysate of bacteria obtained from the decline phase of
growth (Okamoto et al., 1982).
The heat-stable enterotoxin of Y. enterocolitica was purified by ultrafiltration
with an Amicon HIP-10 hollow fiber, ethanol fractionation, protamine sulfate
treatment, DEAE-Sephacel and hydroxylapatite column chromatographies,
Sephacryl S-200 superfine gel filtration, and Bio-Gel P-10 filtration. The heat
stability was also demonstrated (Okamoto et al., 1981).
The molecular weight of purified ST was 9,000 by Sephadex G-100 superfine
gel filtration. The purified ST was separated by isoelectric focusing into two
active fractions, with pI's of 3.29 (ST-1) and 3.00 (ST-2), respectively (Okamoto
et al., 1981). The ST produced by Y. enterocolitica was further purified, with
molecular weight 97,000 by Sephadex G-75 gel filtration (Okamoto et al.,
1982).
The purified ST was stable to heating (100C for 20 min, 121C for 20 min)
and did not lose its toxicity after treatment with protease, trypsin, lipase,
phopholipase C, ribonuclease, deoxyribonuclease, β-glucosidase, and
neuraminidase (Okamoto et al., 1981).
The further purified ST was heat stable at 100C for 10 min between pH 2.2
and 8.0, but not at pH values greater than 9.0 or in 2N HCl (Okamoto et al.,
1982). The biological activity of the purified ST was lost by treatment with
2-mercaptoethanol, suggesting that the ST contained disulfide bridges in the
molecule which were required for the development of toxic activity (Okamoto
et al., 1982).
The crude enterotoxin of Y. enterocolitica is reported to be resistant to
treatment at 121C for 30 min or storage at 4C for 7 months, and is stable in the
pH range 1-11. Thus, enterotoxin of Y. enterocolitica may survive normal food
processing and storage operations and the acid pH of the stomach and it is
conceivable that illness may occur as a result of consumption of the preformed
enterotoxin (Swaminathan et al., 1982).
The minimal effective dose of purified ST was about 110 ng in the suckling
mouse assay. Antiserum from guinea pigs immunized with the purified ST
49
neutralized the activity of both Y. enterocolitica ST and E. coli ST (Okamoto et
al., 1981). The minimal effective dose of the further purified ST was
approximately 25 ng in the suckling mouse assay (Okamoto et al., 1982).
Enterotoxin of Y. enterocolitica may not be related to the pathogenicity of this
pathogen (Schiemann, 1981; Schiemann and Devenish, 1982). A strain of Y.
enterocolitica O:3 that consistently produced ST at 22 but not at 37C and
another strain of the same serotype which did not produce enterotoxin at 22
were both positive for autoagglutination at 35C. Both strains were infective for
HeLa cells and pathogenic to guinea pig and mice. A control strain of O:3
positive for enterotoxin and HeLa cell infectivity but negative for
autoagglutination was avirulent (Schiemann, 1981).
As shown by Robins-Browne et al., enterotoxin has no role in the
pathogenesis of yersiniosis, but there was eveidence that enterotoxin may
promote intra-intestinal proliferation of Y. enterocolitica, thus favouring
increased shedding of bacteria and encouraging their spread between hosts
(Robins-Browne et al., 1985).
8.4. Autoagglutination
The autoagglutination is mostly associated with clinical isolates while the
hemagglutinin production is not (Kapperud and Lassen, 1983). The
autoagglutination of Y. enterocolitica was dependent on the presence of the
virulence plasmid and on the active growth of bacteria in tissue culture media at
37C. Synthesis of new virulence plasmid-associated surface factors was
essential for autoagglutination (Skurnik et al., 1984). The autoagglutination
associated protein is a 240,000 polypeptide, designated P1, and it could be
dissociated under strongly reducing conditions into subunits of 52,500 Dal.
Immunological related factor also occurred in Y. pseudotuberculosis (Skurnik et
al., 1984).
The motility of Y. enterocolitica at 22-25C and 35-37C can also be assayed on
motility agar media, such as GI medium, motility medium S (Difco), motility
test medium, motility indole ornithine medium and SIM medium (BBL) and
confirmed by flagella stain or direct wet mount observation (D'Amato and
Tomfohrde, 1981).
50
8.5. Invasiveness
Virulent Y. enterocolitica was reported to be invasive to HeLa and human
epithelial (HEp-2) cell systems. Some investigators speculated that the infection
of HeLa cells by Y. enterocolitica may be just an indication of the capacity of
the bacteria to attach physically to the cultured mannalian cells: ingestion is
probably an endocytic process initiated by the Hela cells (Swaminathan et al.,
1982).
However, LeChevallier et al. showed that invasion was more than simple
association of the bacterium with the epithelial cell and involved a specific
trigger to stimulate engulfment (LeChevallier et al., 1987). Inhibition of RNA
synthesis by rifampin and protein synthesis by antibiotics inhibited the
invasiveness but not the attachment of Y. enterocolitica to epithelial cells. Cell
membrane from untreated as well as antibiotic (tetracycline and rifampin)
treated cells added to the invasion assay blocked the invasiveness of virulent Y.
enterocolitica, whereas membranes from chlorinated cells were unable to block
invasiveness (Fig. 14, 15). The injury of Y. enterocolitica by chlorine inhibited
invasiveness of this pathogen. Chlorine did not change the hydrophobicity or
surface charge of injured Y. enterocolitica (LeChevallier et al., 1987).
51
Also demonstrated by Schiemann and Nelson that surface protein structure
may be important in mediating cell invasion by Y. enterocolitica. Coating of the
bacteria with antibody (against formalized bacteria) did not greatly alter
adhesion to HeLa cells; however, antibody against formalized bacteria inhibited
HeLa cell invasion. Antibody against heat-killed bacteria had no inhibitory
activity. Adsorption of the antiserum with lipopolysaccharide removed
anti-lipopolysaccharide antibody but did not remove the inhibitory activity
(Schiemann and Nelson, 1988).
Yersinia species (Y. pseudotuberculosis, Y. enterocolitica) are highly infective
for HEp-2 cells but were unable to replicate extensively intracellularly as
compare to enteroinvasive E. coli and Salmonella typhimurium (Fig. 16).
However, Yersinia cells maintained intracellularly for prolonged periods without
damage to the monolayer of cell culture (Small et al., 1987).
52
Devenish and Schiemann reported on the development of a roller tube system
for quantitative comparisons of in vitro infectivity of HeLa cells by Y.
enterocolitica. Non-infective strains of Y. enterocolitica were reported to show a
relative infectivity index of 3.0 or less while infective strains yielded a relative
infectivity index of 3.7-5.0 by the roller tube technique (Schiemann and
Devenish, 1982).
Methodology
Roller Tube System for Bacterial Invasion
Cells of adjusted density are added to plastic tissue culture tubes. Bacterial
suspension is added. The prepared tubes are placed on a roller apparatus and
incubated at 35C for 30 min. After this infection period, 0.1 ml of gentamicin
solution (2.5 mg/ml) is added to each tube, and then the tubes were
53
incubated for 1 h. The supernatant is removed by centrifugation. Cells are
sonicated within the tubes and then the invaded bacteria are enumerated
(Schiemann and Devenish, 1982).
The ability to associate with cultured cells is exhibited by all human
pathogenic strains, regardless of carriage of the virulence plasmid, whereas most
nonclinical isolates are unable to interact (Lassen and Kapperud, 1986). They
found that (i) in serotype O:3, resistance to internalization was dependent upon
prior growth at 37C and carriage of the virulence plasmid; (ii) in serotype O:9,
this property was plasmid dependent but not temperature dependent; (iii) in
serotype O:8, it was constitutive (not affected by growth temperature and
plasmid). The ability of serotype O:3 to resist internalization was correlated
with the expression of plasmid-associated fibrillae on the bacterial surface. No
relationship between fibrillation and HEp-2 cell interaction was apparent for
serotype O:8 or O:9. Serotype O:8 and O:9, unlike the O:3 strains studied,
associated with HEp-2 cells in greater number after cultivation at 22C than after
cultivation at 37C.
Two chromosomal genes are involved in the invasiveness of Y. enterocolitica.
The inv locus allows a uniformly high level of invasion in several tissue culture
lines and is homologous to the inv gene of Y. pseudotuberculosis. The second
locus, ail, shows more host specificity than inv. In Y. pseudotuberculosis, the inv
encodes a surface protein of about 103,000 dal that promotes adherence to and
invasion of tissue culture by these bacteria (Isberg et al., 1987; Miller and
Falkow, 1988).
8.6. Congo Red and Crystal Violet Binding
Binding of Congo Red is associated with virulent Y. enterocolitica containing
40-50 Mdal plasmid (Prpic et al., 1983; Prpic et al., 1985). Bacteria were
suspended in buffer containing Congo red and incubated for 12 h, and the
decrease of Congo red in the buffer was determined by spectophotometry. It was
found that strains of Y. enterocolitica containing virulence plasmid and positive
for several virulence assays could bind Congo red, while the plasmidless
derivatives were avirulent and could not bind to Congo red (Table 23) (Prpic et
al., 1983).
54
Congo red acid-morpholinepropanesulfonic acid pigmentation agar (CRAMP)
can be used to assay Congo red binding activity (Prpic et al., 1985). The Congo
red could also be incoorporated into selective agar to form Congo
red-magnesium oxalate agar (CRMOX) and virulent strains will form small red
colonies (CRMOX+), while avirulent strains will form large colorless colonies
(CRMOX-). As reported by Riley and Toma, 75.8% of the pathogenic serotypes
of Y. enterocolitica were positive in this agar medium showing the presence of
virulent plasmid in these strains, while 98% of nonpathogenic serotypes and
strains of three other Yersinia species were negative (Riley and Toma, 1989).
Virulence-plasmid-bearing strains of Y. enterocolitica can also be
differentiated from their plasmidless derivatives by the binding of crystal violet
(Table 24). The bacteria are plated on Brain Heart Infusion Agar (Difco) and
incubated at 25 or 37C for 30 h, and flooded with crystal violet solution (85
g/ml) for two minutes. Dark violet virulent and white avirulent colonies were
55
detected (Fig. 17). As with other plasmid-mediated properties of this organism,
the binding of crystal violet occurs at 37C but not at 25C (Bhaduri et al., 1987).
Virulent (plasmid-associated) strains of Y. enterocolitica grown on RPMI 1640
agar (Flow Lab.) with 40 mM HEPES and 1.5% purified agar dissociated into
small and large colonies. The autoagglutination test is regularly positive with
small colonies and negative with large colonies. Avirulent Y. enterocolitica
strains gave only large colonies on RPMI agar (Mazigh et al., 1983).
8.7. Calcium Requirement
56
Higly virulent strains of Y. enterocolitica have an in vitro requirement for
calcium at 37C but not at 26C. Avirulent wild strains of Y. enterocolitica do not
have this calcium dependence. When grown on calcium-depleted media at 37C,
the highly virulent strains yielded 0.5-6% large calcium non-requiring avirulent
colonies; the remaining colonies were slow growing, calcium dependent and
highly virulent. These slow growing calcium dependent colonies were highly
virulent on intravenous inoculation, growing rapidly in the liver, spleen and
lungs to produce multiple abscesses (Berche and Carter, 1982).
The calcium dependency assay could be simplified by using a low-calcium,
agarose-based medium of brain heart infusion with added magnesium. This
medium effectively differentiated plasmid-bearing and plasmidless isolates
(Bhaduri et al., 1990).
Ca-independent mutants can be isolated by streaking the cultures onto
magnesium oxalate agar (20 mM MgCl2, and 20 mM sodium oxalate) which
consisted of blood agar base (BBL). Ca-dependent clones cannot form colony
on this agar (Portnoy and Falkow, 1981) or formed small colonies on this MOX
agar (Chang et al., 1984). A calcium-deficient brain heart infusion agarose was
also used to differentiate Calcium-dependent strains which appeared to have
small colonies (Fig. 18, Table 25) (Bhaduri et al., 1990).
57
8.8. Surface Hydrophobicity
Hydrophobicity was first indicated by the adherence of bacteria to
polystyrene surface (polystyrene plate adherence, PSA). The plasmid-bearing
cells of Y. enterocolitica from colonies grown at 37C on brain heart infusion
agar plates adhered tenaciously to the plastic surface. On the other hand, the
plasmidless cells were easily displaced from the surface by washing. The
hydrophobicity can be determined by the partitioning method, nitrocellulose
filter method, hydroxyapatite method, etc. (Lachica and Zink, 1984a). The
adherence is affected by growth media (Lachica and Zink, 1984b).
Plasmid-bearing cells grown on tryptic soy agar or at 22C were easily dislodged
from the polystyrene surface (Lachica and Zink, 1984a).
Xylene or some other water-immiscible solvent is mixed with an aqueous
suspension of cells, the cells exhibited an affinity for one of the two phases upon
partitioning, and can be quantitated by spectophotometry (Lachica and Zink,
1984a).
Hydrophobicity of Y. enterocolitica can also be assayed by a Latex particle
agglutination test (LPA) (Lachica and Zink, 1984b). Equal volume of latex
58
suspension (about 108 particles/ml in 0.9% saline, 5.7 μm in diameter) and cell
suspension were mixed and agglutination observed. A positive test was
indicated by an immediate strong agglutination reaction which was easy to
discern (Lachica and Zink, 1984b).
A partial smooth-rough transition occurs in Y. enterocolitica grown at 37C. A
rabbit antiserum prepared against 25C-grown bacteria contained antibodies
directed mainly against the O-antigenic polysaccharide portion and to a smaller
extent against the lipopolysaccharide (LPS). By contrast, a rabbit antiserum
against 37C-grown bacteria contained antibodies directed mainly against the
LPS. As demonstrated by immunodiffusion and hemagglutination inhibition
tests, the immunogenicity of the LPS of Y. enterocolitica in vivo was similar to
that of the bacteria grown in vitro at 25C (Kawaoka et al., 1983).
8.9. Mouse Lethality
Virulence of Y. enterocolitica could be assayed by inoculating 107 cells
intraperitoneally into pairs of BALB/c adult female mice pretreated with 5 mg
of iron-dextran and 5 mg of desferrioxamine, and the mice are examined daily
for up to 21 days (Prpic et al., 1985).
Most mouse strains (C3H/HeN, BALB/c, BALB.B, DBA/2, A, Swiss, and
SWR) were highly susceptible to infection (LD50, 2x102 to 6x102 administered
intravenously) (Hancock et al., 1986).
8.10. Requirement of Iron
Iron is an essential growth factor for nearly all bacteria, and the concentration
of iron required is generally 0.4 to 4 μM. High-affinity iron chelators, known as
siderophores, are produced by most pathogenic bacteria to survive in low-iron
environment. Desferrioxamine B (Desferal) is a trihydroxamate siderophore,
and it markedly increased the susceptibility of animals to yersiniosis (Fig. 19)
(Robins-Browne and Prpic, 1985). In mice, iron-dextran reduced the median
lethal dose of intraperitoneally administered Y. enterocolitica O:3 and O:9 (all
with virulence plasmid) about 10-fold, whereas Desferal reduced this value
more than 105-fold (Table 26) (Robins-Browne and Prpic, 1985). In vitro
experiments indicated that Desferal promoted growth of Y. enterocolitica under
iron-limiting conditions (Robins-Browne and Prpic, 1985). Clinically, it has
59
been reported that overdose of iron and treatment with Desferal will result in Y.
enterocolitica septicemia, since Y. enterocolitica does not produce siderophores
but has receptors for the iron siderophore complex (Mofenson et al., 1987).
Desferrioxamine- treated mouse was used as sensitive animal assay for the
virulence of Y. enterocolitica (Mulder et al., 1989).
60
Activity of Desferal as a siderophore can be demonstrated by a transferrin
agar method (Fig. 20) (Robins-Browne and Prpic, 1985).
However, hydroxamate was detected in some Yersinia spp. other than Y.
enterocolitica, and this siderophore is identical to aerobactin (from Enterobacter
aerogenes). None of 50 Y. enterocolitica nor any of 5 Y. pseudotuberculosis
isolates produced hydroxamates (Table 27) (Stuart et al., 1986).
61
Under iron-starvation conditions, the different Yersinia species expressed
various iron-regulated proteins (total cell proteins samples). Two
high-molecular-weight outer membrane proteins (HMWPs) were synthesized in
high-virulence-phenotype Y. pestis, Y. pseudotuberculosis, and Y. enterocolitica
but were absent in either low-virulence phenotypes or avirulent environmental
strains (Carniel et al., 1987). These two HMWPs (about 190,000 and 240,000)
were purified. They were synthesized de novo during iron starvation and that
they were found essentially in the bacterial outer membrane fractions, although
the majority of the molecules were not exposed on the cell surface (Carniel et al.,
1989a).
Gene coding for the 190,000-dal iron-regulated HMWP was cloned and
screened by HMWP-specific antibodies. It is conserved among all highly
pathogenic Yersinia species studied, but is missing in the low-virulence and
nonvirulenct strains. The transcription of the HMWP gene is induced by iron
starvation (Carniel et al., 1989b).
8.11. Phospholipase
Analysis of the Y. pseudotuberculosis and Y. pestis genomes indicates that both
species carry an identical copy of a gene that is predicted to encode a protein
which shares 80% similarity to the Y. enterocolitica YplA, a secreted
phospholipase that has been shown to contribute to virulence. In contrast to well
tolerated production of the Y. enterocolitica YplA in E. coli, Y.
pseudotuberculosis YplA expression was found to be toxic; however, cell
viability could be restored if the Y. pseudotuberculosis YplA was expressed in
the presence of its accessory protein YplB. In vitro, Y. pseudotuberculosis YplB
was shown to reduce the activity of its cognate phospholipase in a
dose-dependent manner. To determine whether the Y. pseudotuberculosis and Y.
enterocolitica YplAs were secreted and regulated in a similar manner, secretion
and promoter activity assays were performed. Unlike the situation apparent in Y.
enterocolitica, expression of the Y. pseudotuberculosis yplA gene did not appear
to be controlled by the flagellar regulon, nor did the phospholipase appear to be
efficiently exported through the flagellar apparatus. These results indicate that
the Yersinia YplAs vary in many of their attributes despite their high degree of
amino acid homology (Meysick et al., 2009).
8.12. Type III secretion system
62
Y. enterocolitica has three type three secretion systems, the flagellar, the
plasmid Ysc type III secretion system (T3SS), and the chromosomal Ysa T3SS.
A newly identified Ysa type III secreted protein, YspM, was identified.
Expression of yspM is regulated by temperature, NaCl concentration, and other
known regulators of the ysa system. In addition, YspM is translocated into host
cells via the Ysa T3SS. YspM is homologous to proteins classified as GDSL
bacterial lipases, which possess a catalytic triad of amino acids (Ser, Asp, and
His) located in three of five blocks of amino acid identity. Sequence analysis of
the JB580v strain of Y. enterocolitica shows that, due to a premature stop codon,
it no longer encodes the fifth block of amino acid identity containing the
predicted catalytic histidine. However, seven other biotype 1B strains sequenced
did possess the domain. A functional difference between the forms was revealed
when YspM was expressed in Saccharomyces cerevisiae. Yeast growth was
uninhibited when YspM from JB580v was expressed but greatly inhibited when
YspM from Y295 (YspM(Y295)) was expressed. Site-directed mutagenesis of
the histidine of YspM(Y295) ablated the toxic effects. These results indicate
that YspM is secreted by the Ysa T3SS and that, possibly due to lipase activity,
it targets eukaryotic cellular component(s) (Witowski et al., 2008).
The Y. enterocolitica Ysa T3SS is such a system, where the apparatus genes,
some regulatory genes, and four genes encoding secreted proteins (ysp genes)
are contained in a single locus (Fig. 21). The remaining ysp genes and at least
one additional regulator are found elsewhere on the chromosome. Expression of
ysa genes requires conditions of high ionic strength, neutral/basic pH, and low
temperatures (26C) and is stimulated by exposure to solid surfaces. The
AraC-like regulator YsaE and the dual-function chaperone/regulator SycB are
required to stimulate the sycB promoter, which transcribes sycB and probably
yspBCDA as well. The putative phosphorelay proteins YsrRS (located at the
distal end of the ysa locus) and RcsB, the response regulator of the RcsBCD
phosphorelay system, are required to initiate transcription at the ysaE promoter,
which drives transcription of many apparatus genes. Six unlinked ysp genes
responded to NaCl and required YsaE/SycB, YsrRS, and RcsB for expression.
Three ysp genes had unique patterns, one of which was unaffected by all
elements tested except NaCl. Thus, while the ysp genes were likely to have been
acquired independently, most have acquired a synchronous regulatory pattern
(Walker and Miller, 2009).
63
The Y. enterocolitica YtxR protein is a LysR-type transcriptional regulator that
induces expression of the ytxAB locus, which encodes a putative
ADP-ribosylating toxin. The ytxR and ytxAB genes are not closely linked in the
Y. enterocolitica chromosome, and whereas ytxR is present in all sequenced
Yersinia spp., the ytxAB locus is not. These observations suggested that there
might be other YtxR-regulon members besides ytxAB. Microarray and reverse
transcription-PCR analysis showed that YtxR strongly activates expression of
the yts2 locus, which encodes a putative type 2 secretion system, as well as
several uncharacterized genes predicted to encode extracytoplasmic proteins.
Strikingly, under Ysc-Yop type 3 secretion system-inducing conditions, YtxR
prevented the appearance of Yop proteins in the culture supernatant. Microarray
and lacZ operon fusion analysis showed that this was due to specific repression
of ysc-yop gene expression. YtxR was also able to repress VirF-dependent
Φ(yopE-lacZ) and Φ(yopH-lacZ) expression in a strain lacking the virulence
plasmid, which suggested a direct repression mechanism. This was supported by
DNase I footprinting, which showed that YtxR interacted with the yopE and
yopH control regions. Therefore, YtxR is a newly identified regulator of the
ysc-yop genes that can act as an overriding off switch for this critical virulence
system (xler-DiPerte et al., 2009).
The Ysc T3SS, through the proteins it secretes (Yops), prevents phagocytosis of
Y. enterocolitica and is required for disease processes in the mouse host. A role
for the Ysa T3SS during initial colonization of the mouse via secretion of Ysps
(Yersinia secreted proteins) was demonstrated.
Pathogenic yersiniae (Y. pestis, Y. pseudotuberculosis, Y. enterocolitica)
share the virulence plasmid encoding a type three secretion system (T3SS). This
T3SS comprises more than 40 constituents. Among these are the transport
substrates called Yops (Yersinia outer proteins), the specific Yop chaperones
(Sycs), and the Ysc (Yop secretion) proteins which form the transport
machinery. The effectors YopO and YopP are encoded on an operon together
64
with SycO, the chaperone of YopO. Y. enterocolitica SycO forms homodimers
which is typical for Syc chaperones. SycO overproduction in Y. enterocolitica
decreases secretion of Yops into the culture supernatant suggesting a regulatory
role of SycO in type III secretion. In vitro SycO interacts with YscM1, a
negative regulator of Yop expression in Y. enterocolitica. However, the SycO
overproduction phenotype was not mediated by YscM1, YscM2, YopO or YopP
as revealed by analysis of isogenic deletion mutants. SycO is integrated into the
regulatory network of the Yersinia T3SS (Dittmann et al., 2007).
8.13. A three-dimensional collagen gel model
A three-dimensional culture infection model (3D-CoG) was developed as the
first step to a more complex level of in vitro infection models that mimic living
tissue, enabling us to study the dynamics of pathogen-host cell interactions. In
this model, 105 Yersinia cells were suspended in liquid collagen solution
containing bovine type I collagen at a final concentration of 1.7 mg/ml in RPMI
1640 medium adjusted to pH 7.4 (total volume, 66 μl). This solution was placed
into a small self-constructed chamber (a tracking chamber) built by a hollowed
coverslip on a glass slide and allowed to polymerize for 45 min (37°C; 5% CO2).
The depth of the resulting collagen gel was about 400 μm. The remaining space
in the tracking chamber was filled with RPMI 1640 medium, and thereafter, the
chamber was sealed with wax (1:2, paraffin to vaseline) and incubated at 37°C
in a cell culture incubator (Freund et al., 2008).
Growth was checked microscopically (phase contrast) after different time points
(with a conventional microscope) or followed by time-lapse video microscopy.
To determine bacterial growth rates, yersiniae were released from the 3DCoG
by using collagenase (Clostridium histolyticum collagenase) at a concentration
of 1,000 U/ml in phosphate-buffered saline at 37°C. After digestion of the
collagen gel, bacteria were washed with phosphate-buffered saline, and serial
dilutions of the cell suspension (bacterial clusters and aggregates were
dissociated, as checked by microscopy) were plated onto LB agar plates. CFU
were counted after 48 h of incubation at 27°C. Collagenase treatment of
yersiniae did not impair viability.
Surprisingly, plasmidless Y. enterocolitica was motile in the 3D-CoG in contrast
to its growth in traditional motility agar at 37C. Motility at 37 C was abrogated
65
in the presence of the virulence plasmid pYV or the exclusive expression of the
pYV-located Yersinia adhesion gene yadA. YadA-producing yersiniae formed
densely packed (dp) microcolonies, whereas pYVDelta yadA-carrying yersiniae
formed loosely packed microcolonies at 37C in 3D-CoG (Fig. 22). Furthermore,
the packing density of the microcolonies was dependent on the head domain of
YadA. Moreover, dp microcolony formation did not depend on the capacity of
YadA to bind to collagen fibers, as demonstrated by the use of yersiniae
producing collagen nonbinding YadA. By using a yopE-gfp reporter,
Ca2+-dependent expression of this pYV-localized virulence gene by yersiniae in
3D-CoG (Freund et al., 2008).
9. ROLE OF PLASMIDS IN VIRULENCE
In 1980, Zink et al. discovered a virulence plasmid with a molecular weight
of 41x106 in Y. enterocolitica O:8. This plasmid associated with tissue
invasiveness as determined by Sereny keratoconjuntivitis test (Table 28) (Zink
et al., 1980).
66
Portnoy and Falkow demonstrated that 44-Mdal and 47-Mdal plasmid
(designated as pYV plasmids) is present in virulent Y. enterocolitica and Y.
pestis, respectively and associated with the Ca dependence phenotype (Portnoy
and Falkow, 1981). The plasmids were found to share 55% DNA sequence
homology. Mutants of Y. pestis that could grow on calcium-free medium were
mostly cured of their 47-Mdal plasmid or with major deletion or insertion
(Portnoy and Falkow, 1981). This virulenc associated plasmid was further
characterized. It is associated with HEp-2 cell invasiveness, lethality for gerbils,
production of three major outer membrane polypeptides (during growth at 37
but not at 25C) (Portnoy et al., 1981). The plasmid species associated with these
properties ranged in molecular mass from 40 Mdal to 48 Mdal and comprised a
family of related plasmids (Portnoy et al., 1981).
In a study of 103 strains of Y. enterocolitica, Kay et al. found 10 strains to be
lethal for mice and to possess 42- and 82-Mdal plasmid. A spontaneous
derivative of one strain contained only the 82-Mdal plasmid and was lethal for
mice. This 82-Mdal plasmid may be a new virulence-associated plasmid (Kay et
al., 1982).
67
V and W are antigens associated with virulence and were first known in Y.
pestis and Y. pseudotuberculosis. Identical V and W antigens were speculated to
occur in Y. enterocolitica accounting for both virulence and growth dependency.
The virulence plasmids are associated with a number of temperature-inducible
features of the bacteria: Ca2+-dependent growth at 37C (low calcium response),
production of V and W antigens, autoagglutination, and the expression of outer
membrane proteins (YOPs). The YOPs of Y. pseudotuberculosis and Y.
enterocolitica can be separated into seven polypeptides (YOP1, YOP2a, YOP2b,
YOP3, YOP4a, YOP4b, YOP5) with molecular weight 26,000 to 47,000 (Bo:lin
et al., 1988).
9.1. Proteins Encoded by Virulence-associated Plasmids
9.1.1. Excreted Proteins versus Surface Proteins
Y. enterocolitica with virulence-associated plasmid produce low to high
molecular weight surface proteins associaed with adhesion, autoagglutination
and invasion.
Skurnik demonstrated that at least 16 polypeptides were apparently specified
by the virulence plasmid when plasmid-bearing bacteria were grown at 37C or
intraperitoneally in semipeable capsules. The different growth media used were
also with added calcium. Also two chromosomally encoded polypeptides were
expressed only at 37C, whereas the expression of eight polypeptides expressed
at 22C was repressed at 37C (Skurnik, 1985). Chang and Doyle also
demonstrated that the production of these specific outer membrane polypeptides
is highly temperature dependent and only slightly affected by the inclusion of 10
mM Ca2+ (Chang and Doyle, 1984). Expression of the antigenic determinants(s)
was temperature dependent, agglutination titers were lowest for cultures grown
at 20C and highest for cultures grown at 35 to 40C (Doyle et al., 1982).
Y. enterocolitica containing such plasmid also excreted proteins in calcium
deficient medium. Heesemann et al. showed that strains harboring the virulence
plasmids or the cointegrates apparently release about 10 proteins of discrete
molecular weights. Protein release strongly increased after changing the
medium from BHI to BHI-Magnesium Oxalate (MOX) medium. Five major
68
proteins could be identified, with molecular masses of about 24, 32, 35, 46, and
49 kdal (Heesemann et al., 1984).
Monoclonal antibodies directed against these plasmid-encoded released
proteins were prepared and their activity among pathogenic Yersinia spp. were
assayed (Heesemann et al., 1986). The monoclonal antibodies directed to a
36-kDa or a 46-kDa released protein of O:9 recognized also the corresponding
proteins of other serotypes on Western blot analysis. However, a monoclonal
antibody elicited against the 25-kDa protein of O:9 was species-specific, only
reacted with the corresponding protein of Y. enterocolitica of serotypes O:3, O:8,
O:9 and O:5,27 (Heesemann et al., 1986).
An exocellular antigen (protein) is associated with enterocolitis but absent
from other serotypes or from other Yersinia spp. Both virulent Ca2+-dependent
and avirulent Ca2+- independent isogenic pairs derived from the enterocolitisassociated serotypes synthesized the common antigen. Synthesis of this
24,000-dalton protein depended on the presence of metabolizable sugars and
growth on solid medium at 37C (D:iaz et al., 1985).
9.1.2. Proteins Associated with Fibrillae, Adhesion and Autoagglutination
Virulence-associated plasmid of Y. enterocolitica is correlated to
autoagglutination and adherence to HEp-2 cell cultures, and these properties
were lost by culturing at 37C in the absence of calcium (Vesikari et al., 1981).
By insertional inactivation of genes located on the virulence plasmid, Kapperud
et al. identified four plasmid-dependent, temperature-inducible properties
related to the bacterial surface: (i) a fibrillar matrix covering the outer
membrane, (ii) outer membrane protein YOP1 which is a structural component
of the fibrillae, (iii) spontaneous autoagglutination, which is related to the
fibrillae, and (iv) mannose-ressitant hemagglutination of guinea pig erythrocytes
(Kapperud et al., 1987).
Adhesion
When the plasmid-containing strain was grown at 26C, the bacteria adhered
to HeLa cells to a high degree. In contrast, when this strain was incubated at
37C in the same calcium-containing medium, it attached to the HeLa cells at a
69
reduced level. When the pathogenic strain grown at 26C was given orally to
Swiss albino mice, an infection was rapidly established and the mice died in
short time. The culture grown at 37C was less virulent. These results suggest
that the adherence properties of the bacteria may be of importance in the process
of infection (B:olin et al., 1982).
Also demonstrated by Martinez that the expression of the plasmid-mediated
proteins on the outer membrane do not favor adherence of the bacteria to
intestinal epithelial cells in vitro. Cultures grown at 25C adhered to Henle cell
monolayers, whereas those grown at 37C did so much less effectively (Martinez,
1983).
On the other hand, Schiemann et al. studied the surface properties of Yersinia
species and epithelial cell interactions. They divided the process into three
phenomena, association, attachment and invasion (intracellular) (Schiemann et
al., 1987). Y. enterocolitica was more hydrophobic when grown at 35C than at
25C according to partitioning in a biphasic system, and attached strongly to both
polystyrene and epithelial-cell monolayers. Attachment of Y. enterocolitica to
epithelial cells probably involves non-specific surface properties that are not
entirely explicable by hydrophobic and electrostatic interactions, whereas
invasion of epithelial cells appears to resemble "receptor- mediated
endocytosis".
These are possibly low molecular-weight outer membrane proteins (YOPs).
Fibrillae Mattrix
Also from Y. enterocolitica O:3 that had host the virulence-associated
46-Mdal plasmid, one major outer membrane protein (47 kdal) was expressed
when grown at 37C and not present in the plasmidless strain or in either strain
grown at room temperature. A 200-kd protein also seen in the same preparations
was shown to be an oligomer of the 47-kd protein by immunoblotting. As
determined by electron microscopy and immulogical techniques, this major
protein is probably the tack-like projections appeared on cells grown at 37C
(Zaleska et al., 1985). Similar protein (Sarkosyl-insoluble) of 180 kdal was also
demonstrated in pathogenic Y. pseudotuberculosis and Y. enterocolitica
(Kapperud et al., 1985). This protein formed nonflagellar surface appendages,
70
which appeared as a lawn of fine fibrillae (Fig.23), each having a diameter of
1.5 to 2.0 nm and a length of 50 to 70 nm (Kapperud et al., 1985; Lachica et al.,
1984). This surface structure appeared to mediate autoagglutination of
pathogenic Y. enterocolitica. Antibody of this protein inhibited hemagglutination
(Kapperud et al., 1987; Lachica et al., 1984). This surface fibrillae structure is
different from the rigid appendages (fimbriae) of Yersinia (Lachica et al., 1984).
The production of fimbriae by Y. enterocolitica and Y. pseudotuberculosis was
not correlated with the presence or absence of plasmids (Skurnik, 1984).
Insertional inactivation of the gene coding for YOP1, with resultant loss of
the ability to express fibrillae, led to a signification reduction in the capacity of
Y. enterocolitica, but not Y. pseudotuberculosis, to colonize the ileum of infected
mice. In both Y. enterocolitica and Y. pseudotuberculosis, inactivation of the
genes coding for Calcium dependency reduced the ability to maintain intestinal
colonization, regardless of the ability to express fibrillae. Both surface fibrillae
and Calcium dependency seem to reflect pathogenic determinants which are
required for the establishment of Y. enterocolitica infection (Kapperud et al.,
1987).
9.1.3. Proteins Associated with Serum Resistance
The presence of the proteins on the bacterial surface appears to be involved in
71
rendering the cells resistant to the bactericidal effects of serum, i.e., 37C-grown
cells were resistant to serum killing and such resistance is associated with the
virulence plasmid, and removal of the outer membrane proteins with pronase
rendered them sensitive (Martinez, 1983).
The surface protein P1 was demonstrated to be associated with the serum
resistance of pathogenic Yersinia (B:olin et al., 1982; Balligand et al., 1985). A
30kb segment encoding the P1 protein of the virulence plasmid was cloned to E.
coli expressing a 160-kdal YOP1 protein and proved to be related to the high
degree of hydrophobicity, autoagglutinability, and resistance to serum killing
(Martinez, 1989). However, by itself is not sufficient to specify the serum
resistance property (Balligand et al., 1985). As shown by Bolin et al., YOP1 of
molecular weight 140-kdal associated with the virulence plasmid of Y.
pseudotuberculosis. This protein was induced within 2 min after a temperature
shift from 26 to 37C. Similar protein occurred in Y. Enterocolitica (B:olin et al.,
1982). This protein was also related to serum resistance.
By transposon mutagenesis, Balligand et al. demonstrated that the largest outer
membrane protein P1 is associated with the autoagglutination and resistance to
human serum. However, the P1 was not sufficient by itself to specify the serum
resistance property and a rapid autoagglutination of the host (Balligand et al.,
1985).
The binding ability to type I, II, and IV collagens is associated with the YOP1
protein. Curing of the virulence plasmid or Tn5 insertion in the gene encoding
the YOP1 abolished the binding of all three collagen types to Y. enterocolitica
and type I and II collagens to Y. pseudotuberculosis (Em:ody et al., 1989).
As demonstrated by Lian et al. that Y. enterocolitica cells with expressed
plasmid-mediated surface structure were much less sensitive to ingestion by
human neutrophils (polymorphonuclear leukocytes, PMN) than those without it,
and the resistance to phagocytosis was readily eliminated in a dose-dependent
fashion by pronase treatment of whole cells, which was shown to remove
plasmid-encoded outer membrane proteins (Lian et al., 1987). Ingestion and
intracellular killing of E. coli were inhibited significantly in the presence of
isolated outer membrane fragments derived from plasmid-bearing Y.
enterocolitica cells. By injecting the bacteria into the backs of rabbits, the
plasmidless strain was found almost entirely in PMNs or mononuclear cells. In
72
contrast, the plasmid-bearing strain was found to be surrounded by, or
interspersed with, PMNs and mononuclear cells; but most bacteria were
extracellular, with little evidence of phagocytosis (Lian et al., 1987).
9.2. Molecular Manipulation of Plasmids
The virulence plasmids of Y. enterocolitica cointegrated with a mobilizable
vector were mobilized into other Y. enterocolitica strains, and found that the
animal virulence functions (mouse lethality and conjuctivitis provocation) were
only transferable to plasmid-cured derivatives of virulent parent strains, and
other plasmid-mediated traits (calcium dependency, surface agglutinogens, cell
adherence, etc.) were transferable to all Y. enterocolitica strains (Heesemann et
al., 1984; Heesemann and Laufs, 1983). It shows that certain virulence factor is
associated with chromosomal DNA.
The structural genes of YOPs of Yersinia spp. and the V antigen of Y.
pseudotuberculosis were cloned and mapped. Fragments of the virulence
plasmids were cloned and the proteins expressed were determined by minicells
and identified by immunoassay with specific antibody. The corresponding genes
(for different YOPs and V antigen) were localized on pYV019 and pYV8081 of
Y. pestis and Y. enterocolitica, respectively (Bo:lin et al., 1988).
The virulence plasmids inY. pestis (pYV019), Y. pseudotuberculosis (pIB1)
and Y. enterocolitica (pYV8081) are homologous to some extent. Genes are
sometimes conserved in all these virulence plasmids (Bo:lin et al., 1988). No
obvious differences were observed on comparison of pIB1 and pYV019,
whereas pYV8081 showed intragenic as well as extragenic changes. However,
one region of plasmid pYV8081, which coded for the V antigen, YOP3, and
YOP4a, was essentially conserved among the three plasmids. Since this region
is connected with the Ca2+ region, it is suggested that the conserved region of
the virulence plasmids of Yersinia spp. be extended to include both of these
regions.
The gene encoding YOP5 protein encoded by pIB1 (of Y. pseudotuberculosis)
was cloned on a mobilizable vector and introduced in Y. enterocolitica
containing virulence plasmid with mutation in the homologous gene, the
recombinant Y. enterocolitica secreted YOP5 and it showed that these systems
73
are interchangeable (Bo:lin et al., 1988).
By using transposon Tn2507 (with cat gene, chloramphenicol acetyltransferase) mutagenesis of Y. enterocolitica W22703 (O:9), Mulder et al. (Mulder et
al., 1989) identified an additional YOP protein called YOP20 and the mapping
of genes encoding for YOP20, YOP44, YOP48, and V antigen. The V gene
appeared to be part of an operon that also may contain yop37 and yop44. The
transcription activity of the mutants was determined by assaying the activity of
the cat gene. Transcription of this operon was activated by a temperature shift
from 25 to 37C. At 37C, Ca2+ had a small decreasing effect but transcription still
occurs. However, Yops were not released in those conditions. At 37C, mutants
affected in this operon grew poorly, irrespective of the presence of Ca2+, or they
even died in the presence of Ca2+. This operon was thus involved in the
regulation by Ca2+, and it is then called car, for Ca2+ regulation. YOP20 or
YOP48 were involved in virulence, since mutants affecting these two gene were
markedly less virulent in desferrioxamine-treated mouse. Also by using
transposon mutagenesis, Balligand et al. also determined the location of Ca2+
regulation (Balligand et al., 1985).
By transposon mutagenesis, two mutants were affected in the properties of
autoaggultination and resistance to human serum. Analysis of the OMP pattern
of these two mutants revealed the absence of the YOP1. Complementation of
one of these mutations with the cloned structural gene of YOP1 restored the
wild-type phenotype (Balligand et al., 1985).
Restriction fragment analysis of 18 virulence plasmids by using BamH1
digestion showed two types of plasmids, with a deletion of 4.4-kb BamH1
fragment in type II. However, no function differences between the strains
bearing type I or type II plasmid were observed (Pulkkinen et al., 1986).
The replication genes (rep) and the plasmid-stabilization system (par) of the
virulence plasmid of Y. enterocolitica were determined by restriction
endonuclease analysis and the replication function is thermosensitive. At 28C
for 25-30 generations, the E. coli C600 losses the mini-derivatives of the
virulence plasmid at frequenceies ranging from 10-18%, while at 40C, it was
greater than 99% (Biot and Cornelis, 1988).
Strains of Salmonella typhimurium harbouring stable aroA (encoding
74
5-enolpyruvylshikimate 3-phosphate synthase) mutations are attenuated and
excellent oral vaccines in mice and other animals. The aroA mutant of Y.
enterocolitica failed to kill mice (Bowe et al., 1989). Attenuation is probably
due to a requirement for one or more aromatic compounds, including
para-aminobenzoic acid and dihydroxybenzoic acid, which are not readily
available in mammalian tissues. The aroA genes from E. coli and S.
typhimurium have been identified as the distal genes in an operon with serC
(which encodes 3-phosphoserine aminotransferase). The aroA and serC genes of
Y. enterocolitica have been sequenced with high (78% and 81%) homology with
E. coli genes. Comparisons of serC and aroA of Y. enterocolitica, S.
typhimurium, E. coli and Bordetella pertussis were done (O'Gaora et al., 1989).
A new mercury-resistance transposon (Tn3926) from Y. enterocolitica was
studied (Lett et al., 1985). This transposon has a size of 7.8 kb and transposes to
conjugative plasmids belonging to different incompatibility groups. By
comparing the restriction fragments with other transposon, the Tn3926 has high
homology to Tn501 and Tn21, especially the fragment encoding the mercuryresistance, with low homology in regions encoding transposition functions (Lett
et al., 1985).
Yersinia strains frequently harbor plasmids, of which the virulence plasmid
pYV, indigenous in pathogenic strains, has been thoroughly characterized. The
conjugative plasmids pYE854 (95.5 kb)(Fig. 24) and pYE966 (70 kb) from a
nonpathogenic and a pathogenic Y. enterocolitica strain, respectively, and
demonstrate that both plasmids are able to mobilize pYV (Table 29). The
complete sequence of pYE854 has been determined. The transfer proteins and
oriT of the plasmid reveal similarities to the F factor. However, the pYE854
replicon does not belong to the IncF group and is more closely related to a
plasmid of gram-positive bacteria. Plasmid pYE966 is very similar to pYE854
but lacks two DNA regions of the larger plasmid that are dispensable for
conjugation (Hammerl et al., 2008).
75
10. MOLECULAR STUDY OF INVASIVENESS
Recently, two chromosomal loci, inv and ail, which confers an invasive
phenotype of Y. enterocolitica have been cloned and studied. A tissue culture
76
invasion (TCI) model was used in assaying the invasiveness. In this assay,
HEp-2 tissue culture cells are cultured in 24-well plates. After application of
bacteria, the wells are washed with phosphate-buffered saline. The extracellular
bacteria are killed by the use of gentamicin (100 μg/ml). The cells are lysed by
Triton X-100 and the intracellular bacteria (invaded) are counted (Miller et al.,
1989).
These two genes were cloned into E. coli HB101 and these clones showed
tissue invasiveness (Miller and Falkow, 1988). By hybridization with probes
derived from these clones, Pierson and Falkow demonstrated that 35
nonpathogenic, noninvasive isolates similarly studied had no ail homology but
carried inv-homologous sequences. The inv-homologous sequences in these
nonpathogenic strains are probably nonfunctional (Pierson and Falkow, 1989).
The cloning of inv gene into these nonpathogenic strains yielded invasive
strains.
The ail gene is associated with the invasiveness of all the pathogenic
strains(TCI+), with certain restriction fragment-linked polymorphisms (Miller et
al., 1989). Nucleotide sequence of ail gene was determined in a region of 650
bp. The ail gene product determined by maxicells was a 17-kdal
membrane-associated protein. The nucleotide sequence of the ail gene revealed
a single unique open reading frame of 178 amino acids. A 23 amino acids signal
sequence was identified by comparing the amino acid sequences deduced from
the gene and the analysis of the purified protein (Miller et al., 1990).
10.1. Flagellar master regulator
The Y. enterocolitica flagellar master regulator FlhD/FlhC affects the expression
levels of non-flagellar genes, including 21 genes that are involved in central
metabolism. The sigma factor of the flagellar system, FliA, has a negative effect
on the expression levels of seven plasmid-encoded virulence genes in addition
to its positive effect on the expression levels of eight of the flagellar operons.
Phenotypes of flhD and fliA mutants that result from the complex gene
regulation were investigated with Phenotype MicroArrays (Biology). Compared
to the wild-type strain, isogenic flhD and fliA mutants exhibited increased
growth on purines and reduced growth on N-acetyl-D-glucosamine and
D-mannose, when used as a sole carbon source. Both mutants grew more poorly
on pyrimidines and L-histidine as sole nitrogen source. Several intermediates of
77
the tricarboxylic acid and the urea cycle, as well as several dipeptides, provided
differential growth conditions for the two mutants (Fig. 25). Gene expression
was determined for selected genes and correlated with the observed phenotypes.
Phenotypes relating to virulence were determined with the chicken embryo
lethality assay. The flhD mutant caused reduced chicken embryo lethality when
compared to wild-type bacteria. In contrast, the fliA mutant caused wild-type
lethality. This indicates that the virulence phenotype of the flhD mutant might
be due to genes that are regulated by FlhD/FlhC but not FliA, such as those that
encode the flagellar type III secretion system. Phenotypes of flhD and fliA
mutants are related to central metabolism and virulence and correlate with gene
regulation (Fig. 26, 27) (Townsend et al., 2008).
78
79
11. CONCLUSIONS
Y. enterocolitica may be an important food-pathogen in Taiwan:
(A) It is prinipally a zoonotic organism that has been isolated from a variety of
animals, especially with swine. Swine raising is an important agricultural
business in Taiwan and pollution of swine waste widely occurs. However,
outbreak of yersinosis has not been directly associated with pork.
(B) Symptoms of infection caused by Y. enterocolitica are often quite severe.
However, fatality from gastroenteritis is rare.
(C) High growth rate at low temperature. Y. enterocolitica is sensitive to heat,
sodium chloride, and acidity and will generally be inactivated by environmental
conditions that will kill salmonellae. It is important to eliminate the organism
from foods (especially pork, milk, and foods that may have direct or indirect
contact with porcine waste) by pasteurization or cooking. Care should be taken
to avoid cross-contamination of processed, ready-to-eat foods with pork and
porcine wastes, as well as animal and human fecal contaminations.
80
References
Acker,G., Bitter-Suermann,D., Meier-Dieter,U., Peters,H., Mayer,H. 1986.
Immunocytochemical localization of enterobacterial common antigen in
Escherichia coli and Yersinia enterocolitica cells. Journal of Bacteriology 168,
348-356.
Acker,G., Knapp,W., Wartenberg,K., Mayer,H. 1981. Localization of
enterobacterial common antigen in Yersinia enterocolitica by the immunoferritin
technique. Journal of Bacteriology 147, 602-611.
Agbonlahor,D.E., Odugbemi,T., Dosunmu-Ogunbi,O. 1982. Differential and
selective medium for isolation of Yersinia enterocolitica from stools. Journal of
Clinical Microbiology 15, 599-602.
Aleksi:c,S.,Bockem:uhl,J. 1984. Proposed revision of the Wauters et al.
antigenic scheme for serotyping of Yersinia enterocolitica. Journal of Clinical
Microbiology 20, 99-102.
Annamalai,T.,Venkitanarayanan,K. 2009. Role of proP and proU in betaine
uptake by Yersinia enterocolitica under cold and osmotic stress conditions.
Applied and Environmental Microbiology 75, 1471-1477.
B:olin,I., Norlander,L., Wolf-Watz,H. 1982. Temperature-inducible outer
membrane protein of Yersinia pseudotuberculosis and Yersinia enterocolitica is
associated with the virulence plasmid. Infection & Immunity 37, 506-512.
Baker,P.M.,Farmer,J., III 1982. New bacteriophage typing system for Yersinia
enterocolitica, Yersinia kristensenii, Yersinia frederiksenii, and Yersinia
intermedia: correlation with serotyping, biotyping, and antibiotic susceptibility.
Journal of Clinical Microbiology 15, 491-502.
Bakour,R., Balligand,G., Laroche,Y., Cornelis,G., Wauters,G. 1985. A simple
adult-mouse test for tissue invasiveness in Yersinia enterocolitica strains of low
experimental virulence. Journal of Medical Microbiology 19, 237-246.
Balligand,G., Laroche,Y., Cornelis,G. 1985. Genetic analysis of virulence
plasmid from a serogroup 9 Yersinia enterocolitica strain: role of outer
membrane protein P1 in resistance to human serum and autoagglutination.
81
Infection & Immunity 48, 782-786.
Bartley,T.D., Quan,T.J., Collins,M.T., Morrison,S.M. 1982. Membrane filter
technique for the isolation of Yersinia enterocolitica. Applied and
Environmental Microbiology 43, 829-834.
Baumgartner,A., Kuffer,M., Suter,D., Jemmi,T., Rohner,P. 2007. Antimicrobial
resistance of Yersinia enterocolitica strains from human patients, pigs and retail
pork in Switzerland. International Journal of Food Microbiology 115, 110-114.
Berche,P.A.,Carter,P.B. 1982. Calcium requirement and virulence of Yersinia
enterocolitica. Journal of Medical Microbiology 15, 277-284.
Bhaduri,S., Conway,L.K., Lachica,R.V. 1987. Assay of crystal violet binding for
rapid identification of virulent plasmid-bearing clones of Yersinia enterocolitica.
Journal of Clinical Microbiology 25, 1039-1042.
Bhaduri,S., Turner-Jones,C., Taylor,M.M., Lachica,R.V. 1990. Simple assay of
calcium dependency for virulent plasmid-bearing clones of Yersinia
enterocolitica. Journal of Clinical Microbiology 28, 798-800.
Bhagat,N.,Virdi,J.S. 2007. Distribution of virulence-associated genes in Yersinia
enterocolitica biovar 1A correlates with clonal groups and not the source of
isolation. FEMS Microbiology Letters 266, 177-183.
Biot,T.,Cornelis,G.R. 1988. The replication, partition and yop regulation of the
pYV plasmids are highly conserved in Yersinia enterocolitica and Y.
pseudotuberculosis. Journal of Geneeral Microbiology 134, 1525-1534.
Bissett,M.L., Powers,C., Abbott,S.L., Janda,J.M. 1990. Epidemiologic
investigations of Yersinia enterocolitica and related species: sources, frequency,
and serogroup distribution. Journal of Clinical Microbiology 28, 910-912.
Bo:lin,I., Forsberg,A., Norlander,L., Skurnik,M., Wolf-Watz,H. 1988.
Identification and mapping of the temperature-inducible, plasmid-encoded
proteins of Yersinia spp. Infection & Immunity 56, 343-348.
Bowe,F., O'Gaora,P., Maskell,D., Cafferkey,M., Dougan,G. 1989. Virulence,
persistence, and immunogenicity of Yersinia enterocolitica O:8 aroA mutants.
Infection & Immunity 57, 3234-3236.
Bowman,A.S., Glendening,C., Wittum,T.E., LeJeune,J.T., Stich,R.W., Funk,J.A.
82
2007. Prevalence of Yersinia enterocolitica in different phases of production on
swine farms. JOURNAL OF FOOD PROTECTION 70, 11-16.
Bucher,M., Meyer,C., Grotzbach,B., Wacheck,S., Stolle,A.,
Fredriksson-Ahomaa,M. 2008. Epidemiological data on pathogenic Yersinia
enterocolitica in Southern Germany during 2000-2006. Foodborne Pathogenic
Diseases 5, 273-280.
Butler,R.C., Lund,V., Carlson,D.A. 1987. Susceptibility of Campylobacter
jejuni and Yersinia enterocolitica to UV radiation. Applied and Environmental
Microbiology 53, 375-378.
Cafferkey,M.T., McClean,K., Drumm,M.E. 1989. Production of bacteriocin-like
antagonism by clinical isolates of Yersinia enterocolitica. Journal of Clinical
Microbiology 27, 677-680.
Carniel,E., Antoine,J.-C., Guiyoule,A., Guiso,N., Mollaret,H.H. 1989a.
Purification, location, and immunological characterization of the iron-regulated
high-molecular-weight proteins of the highly pathogenic yersiniae. Infection &
Immunity 57, 540-545.
Carniel,E., Mazigh,D., Mollaret,H.H. 1987. Expression of iron-regulated
proteins in Yersinia species and their relation to virulence. Infection &
Immunity 55, 277-280.
Carniel,E., Mercereau-Puijalon,O., Bonnefoy,S. 1989b. The gene coding for the
190,000-dalton iron-regulated protein of Yersinia species is present only in the
highly pathogenic strains. Infection & Immunity 57, 1211-1217.
Chang,M.T.,Doyle,M.P. 1984. Identification of specific outer membrane
polypeptides associated with virulent Yersinia enterocolitica. Infection &
Immunity 43, 472-476.
Chang,M.T., Schink,J., Shimaoka,J., Doyle,M.P. 1984. Comparison of three
tests for virulent Yersinia enterocolitica. Journal of Clinical Microbiology 20,
589-591.
Chao,W.L., Ding,R.J., Chen,R.S. 1988. Survival of Yersinia enterocolitica in the
environment. Canadian Journal of Microbiology. 34, 753-756.
D'Amato,R.F.,Tomfohrde,K.M. 1981. Influence of media on
temperature-dependent motility test for Yersinia enterocolitica. Journal of
83
Clinical Microbiology 14, 347-348.
D:iaz,R., Urra,E., Toyos,J., Moriyon,I. 1985. Characterization of a Yersinia
enterocolitica antigen common to enterocolitis-associated serotypes. Journal of
Clinical Microbiology 22, 1035-1039.
Davey,G.M., Bruce,J., Drysdale,E.M. 1983. Isolation of Yersinia enterocolitica
and related species from the faeces of cows. Journal of Applied Bacteriology 55,
439-443.
Devenish,J.A.,Schiemann,D.A. 1981. An abbreviated scheme for identification
of Yersinia enterocolitica isolated from food enrichments on CIN
(cefsulodin-irgasan-novobiocin) agar. Canadian Journal of Microbiology. 27,
937-941.
Dittmann,S., Schmid,A., Richter,S., Trulzsch,K., Heesemann,J., Wilharm,G.
2007. The Yersinia enterocolitica type three secretion chaperone SycO is
integrated into the Yop regulatory network and binds to the Yop secretion
protein YscM1. BMC Microbiology 7, 67.
Doyle,M.P., Hugdahl,M.B., Chang,M.T., Beery,J.T. 1982. Serological
relatedness of mouse-virulent Yersinia enterocolitica. Infection & Immunity 37,
1234-1240.
Doyle,M.P., Hugdahl,M.B., Taylor,S.L. 1981. Isolation of virulent Yersinia
enterocolitica from porcine tongues. Applied and Environmental Microbiology
42, 661-666.
El-Zawahry,Y.A.,Grecz,N. 1981. Inactivation and injury of Yersinia
enterocolitica by radiation and freezing. Applied and Environmental
Microbiology 42, 464-468.
Em:ody,L., Heesemann,J., Wolf-Watz,H., Skurnik,M., Kapperud,G., O'Toole,P.,
Wadstr:om,T. 1989. Binding to collagen by Yersinia enterocolitica and Yersinia
pseudotuberculosis: evidence for yopA-mediated and chromosomally encoded
mechanisms. Journal of Bacteriology 171, 6674-6679.
Firouzi,R., Shekarforoush,S.S., Nazer,A.H., Borumand,Z., Jooyandeh,A.R.
2007. Effects of essential oils of oregano and nutmeg on growth and survival of
Yersinia enterocolitica and Listeria monocytogenes in barbecued chicken.
Journal of Food Protection 70, 2626-2630.
84
Francis,D.W., Spaulding,P.L., Lovett,J. 1980. Enterotoxin production and
thermal resistance of Yersinia enterocolitica in milk. Applied and Environmental
Microbiology 40, 174-176.
Freund,S., Czech,B., Trulzsch,K., Ackermann,N., Heesemann,J. 2008. Unusual,
virulence plasmid-dependent growth behavior of Yersinia enterocolitica in
three-dimensional collagen gels. Journal of Bacteriology 190, 4111-4120.
Fukushima,H. 1985. Direct isolation of Yersinia enterocolitica and Yersinia
pseudotuberculosis from meat. Applied and Environmental Microbiology 50,
710-712.
Fukushima,H. 1987. New selective agar medium for isolation of virulent
Yersinia enterocolitica. Journal of Clinical Microbiology 25, 1068-1073.
Fukushima,H.,Gomyoda,M. 1986. Growth of Yersinia pseudotuberculosis and
Yersinia enterocolitica biotype 3B serotype O3 inhibited on
cefsulodin-Irgasan-novobiocin agar. Journal of Clinical Microbiology 24,
116-120.
Goullet,P.,Picard,B. 1988. Characterization of Yersinia enterocolitica, Y.
intermedia, Y. aldovae, Y frederiksenii, Y. kristensenii and Y. pseudotuberculosis
by electrophoretic polymorphism of acid phosphatase, esterases, and glutamate
and malate dehydrogenases. Journal of Geneeral Microbiology 134, 317-325.
Hammerl,J.A., Klein,I., Lanka,E., Appel,B., Hertwig,S. 2008. Genetic and
functional properties of the self-transmissible Yersinia enterocolitica plasmid
pYE854, which mobilizes the virulence plasmid pYV. Journal of Bacteriology
190, 991-1010.
Hancock,G.E., Schaedler,R.W., MacDonald,T.T. 1986. Yersinia enterocolitica
infection in resistant and susceptible strains of mice. Infection & Immunity 53,
26-31.
Hanski,C., Kutschka,U., Schmoranzer,H.P., Naumann,M., Stallmach,A.,
Hahn,H., Menge,H., Riecken,E.O. 1989. Immunohistochemical and electron
microscopic study of interaction of Yersinia enterocolitica serotype O8 with
intestinal mucosa during experimental enteritis. Infection & Immunity 57,
673-678.
Harmon,M.C., Swaminathan,B., Forrest,J.C. 1984. Isolation of Yersinia
85
enterocolitica and related species from porcine samples obtained from an
abattoir. Journal of Applied Bacteriology 56, 421-427.
Harmon,M.C., Yu,C.L., Swaminathan,B. 1983. An evaluation of selective
differential plating media for the isolation of Yersinia enterocolitica from
experimentally inoculated fresh ground pork homogenate. Journal of Food
Science 48, 6-9.
Head,C.B., Whitty,D.A., Ratnam,S. 1982. Comparative study of selective media
for recovery of Yersinia enterocolitica. Journal of Clinical Microbiology 16,
615-621.
Heesemann,J., Algermissen,B., Laufs,R. 1984. Genetically manipulated
virulence of Yersinia enterocolitica. Infection & Immunity 46, 105-110.
Heesemann,J., Kalthoff,H., Koch,F. 1986. Monoclonal antibodies directed
against plasmid-encoded released proteins of enteropathogenic Yersinia. FEMS
Microbiology Letters 36, 15-19.
Heesemann,J.,Laufs,R. 1983. Construction of a mobilizable Yersinia
enterocolitica virulence plasmid. Journal of Bacteriology 155, 761-767.
Hill,W.E., Payne,W.L., Aulisio,C.C. 1983. Detection and enumeration of
virulent Yersinia enterocolitica in food by DNA colony hybridization. Applied
and Environmental Microbiology 46, 636-641.
Isberg,R.R., Voorhis,D.L., Falkow,S. 1987. Identification of invasin: a protein
that allows enteric bacteria to penetrate cultured mammalian cells. Cell 50,
769-778.
Jacobs,J., Jamaer,D., Vandeven,J., Wouters,M., Vermylen,C., Vandepitte,J. 1989.
Yersinia enterocolitica in donor blood: a case report and review. Journal of
Clinical Microbiology 27, 1119-1121.
Jagow,J.,Hill,W.E. 1986. Enumeration by DNA colony hybridization of virulent
Yersinia enterocolitica colonies in artificially contaminated food. Applied and
Environmental Microbiology 51, 441-443.
Kaneko,K.,Hashimoto,N. 1981. Occurrence of Yersinia enterocolitica in wild
animals. Applied and Environmental Microbiology 41, 635-638.
Kaneko,K.,Hashimoto,N. 1983. Cross-resistance to fecal excretion of Yersinia
86
enterocolitica in mice by oral vaccination of killed cells. Infection & Immunity
40, 1223-1225.
Kaneko,S.,Maruyama,T. 1989. Evaluation of enzyme immunoassay for the
detection of pathogenic Yersinia enterocolitica and Yersinia pseudotuberculosis
strains. Journal of Clinical Microbiology 27, 748-751.
Kapperud,G.,Lassen,J. 1983. Relationship of virulence-associated
autoagglutination to hemagglutinin production in Yersinia enterocolitica and
Yersinia enterocolitica-like bacteria. Infection & Immunity 42, 163-169.
Kapperud,G., Namork,E., Skarpeid,H.J. 1985. Temperature-inducible surface
fibrillae associated with the virulence plasmid of Yersinia enterocolitica and
Yersinia pseudotuberculosis. Infection & Immunity 47, 561-566.
Kapperud,G., Namork,E., Skurnik,M., Nesbakken,T. 1987. Plasmid-mediated
surface fibrillae of Yersinia pseudotuberculosis and Yersinia enterocolitica:
relationship to the outer membrane protein YOP1 and possible importance for
pathogenesis. Infection & Immunity 55, 2247-2254.
Kato,Y., Ito,K., Kubokura,Y., Maruyama,T., Kaneko,K., Ogawa,M. 1985.
Occurrence of Yersinia enterocolitica in wild-living birds and Japanese serows.
Applied and Environmental Microbiology 49, 198-200.
Kawaoka,Y., Otsuki,K., Tsubokura,M. 1983. Serological evidence that Yersinia
enterocolitica lipopolysaccharide produced during growth in vivo resembles
that produced during growth in vitro at 25oC. Journal of Geneeral Microbiology
129, 2749-2751.
Kay,B.A., Wachsmuth,K., Gemski,P. 1982. New virulence-associated plasmid in
Yersinia enterocolitica. Journal of Clinical Microbiology 15, 1161-1163.
Kay,B.A., Wachsmuth,K., Gemski,P., Feeley,J.C., Quan,T.J., Brenner,D.J. 1983.
Virulence and phenotypic characterization of Yersinia enterocolitica isolated
from humans in the United States. Journal of Clinical Microbiology 17,
128-138.
Kim,T.J., Young,B.M., Young,G.M. 2008. Effect of flagellar mutations on
Yersinia enterocolitica biofilm formation. Applied and Environmental
Microbiology 74, 5466-5474.
Lachica,R.V.,Zink,D.L. 1984b. Determination of plasmid-associated
87
hydrophobicity of Yersinia enterocolitica by a latex particle agglutination test.
Journal of Clinical Microbiology 19, 660-663.
Lachica,R.V.,Zink,D.L. 1984a. Plasmid-associated cell surface charge and
hydrophobicity of Yersinia enterocolitica. Infection & Immunity 44, 540-543.
Lachica,R.V., Zink,D.L., Ferris,W.R. 1984. Association of fibril structure
formation with cell surface properties of Yersinia enterocolitica. Infection &
Immunity 46, 272-275.
Lambertz,S.T., Nilsson,C., Hallanvuo,S., Lindblad,M. 2008. Real-time PCR
method for detection of pathogenic Yersinia enterocolitica in food. Applied and
Environmental Microbiology 74, 6060-6067.
Lassen,J.,Kapperud,G. 1986. Serotype-related HEp-2 cell interaction of Yersinia
enterocolitica. Infection & Immunity 52, 85-89.
LeChevallier,M.W., Schiemann,D.A., McFeters,G.A. 1987. Factors contributing
to the reduced invasiveness of chlorine-injured Yersinia enterocolitica. Applied
and Environmental Microbiology 53, 1358-1364.
Lett,M.C., Bennett,P.M., Vidon,D.J. 1985. Characterization of Tn3926, a new
mercury-resistance transposon from Yersinia enterocolitica. Gene 40, 79-91.
Lian,C.J., Hwang,W.S., Pai,C.H. 1987. Plasmid-mediated resistance to
phagocytosis in Yersinia enterocolitica. Infection & Immunity 55, 1176-1183.
Lovett,J., Bradshaw,J.G., Peeler,J.T. 1982. Thermal inactivation of Yersinia
enterocolitica in milk. Applied and Environmental Microbiology 44, 517-519.
Martinez,R.J. 1983. Plasmid-mediated and temperature-regulated surface
properties of Yersinia enterocolitica. Infection & Immunity 41, 921-930.
Martinez,R.J. 1989. Thermoregulation-dependent expression of Yersinia
enterocolitica protein 1 imparts serum resistance to Escherichia coli K-12.
Journal of Bacteriology 171, 3732-3739.
Mazigh,D., Alonso,J.M., Mollaret,H.H. 1983. Simple method for demonstration
of differential colony morphology of plasmid-associated virulent clones of
Yersinia enterocolitica. Journal of Clinical Microbiology 17, 555-557.
Mele,L., Nadler,H., Gomez,S. 1987. Evaluation of rapid SYS system as screen
88
for Yersinia enterocolitica in the United States. Journal of Clinical Microbiology
25, 2422-2423.
Meysick,K.C., Seidman,J., Falconio,J.R. 2009. The Yersinia pseudotuberculosis
YplA phospholipase differs in its activity, regulation and secretion from that of
the Yersinia enterocolitica YplA. Microbial Pathogenesis 47, 24-32.
Miller,V.L., Bliska,J.B., Falkow,S. 1990. Nucleotide sequence of the Yersinia
enterocolitica ail gene and characterization of the Ail protein product. Journal of
Bacteriology 172, 1062-1069.
Miller,V.L.,Falkow,S. 1988. Evidence for two genetic loci in Yersinia
enterocolitica that can promote invasion of epithelial cells. Infection &
Immunity 56, 1242-1248.
Miller,V.L., Farmer,J., III, Hill,W.E., Falkow,S. 1989. The ail locus is found
uniquely in Yersinia enterocolitica serotypes commonly associated with disease.
Infection & Immunity 57, 121-131.
Miyahara,M., Maruyama,T., Wake,A., Mise,K. 1988. Widespread occurrence of
the restriction endonuclease YenI, an isoschizomer of PstI, in Yersinia
enterocolitica serotype O8. Applied and Environmental Microbiology 54,
577-580.
Mofenson,H.C., Caraccio,T.R., Sharieff,N. 1987. Iron sepsis: Yersinia
enterocolitica septicemia possibly caused by an overdose of iron. N. Eng. J.
Med. 316, 1092-1093.
Mulder,B., Michiels,T., Simonet,M., Sory,M.P., Cornelis,G. 1989. Identification
of additional virulence determinants on the pYV plasmid of Yersinia
enterocolitica W227. Infection & Immunity 57, 2534-2541.
O'Gaora,P., Maskel,D., Coleman,D., Cafferkey,M., Dougan,G. 1989. Cloning
and characterisation of the serC and aroA genes of Yersinia enterocolitica, and
construction of an aroA mutant. Gene 84, 23-30.
Okamoto,K., Inoue,T., Ichikawa,H., Kawamoto,Y., Miyama,A. 1981. Partial
purification and characterization of heat-stable enterotoxin produced by Yersinia
enterocolitica. Infection & Immunity 31, 554-559.
Okamoto,K., Inoue,T., Shimizu,K., Hara,S., Miyama,A. 1982. Further
purification and characterization of heat-stable enterotoxin produced by Yersinia
89
enterocolitica. Infection & Immunity 35, 958-964.
Olsvik,O.,Kapperud,G. 1982. Enterotoxin production in milk at 22 and 4
degrees C by Escherichia coli and Yersinia enterocolitica. Applied and
Environmental Microbiology 43, 997-1000.
Pierson,D.E.,Falkow,S. 1989. Nonpathogenic isolates of Yersinia enterocolitica
do not contain function inv-homologous sequences. Infection & Immunity 57,
1059-1064.
Portnoy,D.A.,Falkow,S. 1981. Virulence-associated plasmids from Yersinia
enterocolitica and Yersinia pestis. Journal of Bacteriology 148, 877-883.
Portnoy,D.A., Moseley,S.L., Falkow,S. 1981. Characterization of plasmids and
plasmid-associated determinants of Yersinia enterocolitica pathogenesis.
Infection & Immunity 31, 775-782.
Prpic,J.K., Robins-Browne,R.M., Davey,R.B. 1985. In vitro assessment of
virulence in Yersinia enterocolitica and related species. Journal of Clinical
Microbiology 22, 105-110.
Prpic,J.K., Robins-Browne,R.M., Davey,R.B. 1983. Differentation between
virulent and avirulent Yersinia enterocolitica isolates by using Congo Red Agar.
Journal of Clinical Microbiology 18, 468-490.
Pulkkinen,L., Granberg,I., Granfors,K., Toivanen,A. 1986. Restriction map of
virulence plasmid in Yersinia enterocolitica O:3. Plasmid 16, 225-227.
Restaino,L., Jeter,W.S., Hill,W.M. 1980. Thermal injury of Yersinia
enterocolitica. Applied and Environmental Microbiology 40, 939-949.
Restaino,L., Komatsu,K.K., Syracuse,M.J. 1982. Effects of acids on potasium
sorbate inhibition of food-related microorganisms in culture media. Journal of
Food Science 47, 134-143.
Riley,G.,Toma,S. 1989. Detection of pathogenic Yersinia enterocolitica by using
congo red-magnesium oxalate agar medium. Journal of Clinical Microbiology
27, 213-214.
Robins-Browne,R.M.,Prpic,J.K. 1985. Effects of iron and desferrioxamine on
infections with Yersinia enterocolitica. Infection & Immunity 47, 774-779.
90
Robins-Browne,R.M., Tzipori,S., Gonis,G., Hayes,J., Withers,M., Prpic,J.K.
1985. The pathogenesis of Yersinia enterocolitica infection in gnotobiotic
piglets. Journal of Medical Microbiology 19, 297-308.
Schiemann,D.A. 1981. An enterotoxin-negative strain of Yersinia enterocolitica
serotype O:3 is capable of producing diarrhea in mice. Infection & Immunity 32,
571-574.
Schiemann,D.A. 1982. Development of a two-step enrichment procedure for
recovery of Yersinia enterocolitica from food. Applied and Environmental
Microbiology 43, 14-27.
Schiemann,D.A. 1983. Alkalotolerance of Yersinia enterocolitica as a basis for
selective isolation from food enrichments. Applied and Environmental
Microbiology 46, 22-27.
Schiemann,D.A., Crane,M.R., Swanz,P.J. 1987. Surface properties of Yersinia
species and epithelial cell interactions in vitro by a method measuring total
associated, attached and intracellular bacteria. Journal of Medical Microbiology
24, 205-218.
Schiemann,D.A.,Devenish,J.A. 1982. Relationship of HeLa cell infectivity to
biochemical, serological, and virulence characteristics of Yersinia enterocolitica.
Infection & Immunity 35, 497-506.
Schiemann,D.A., Devenish,J.A., Toma,S. 1981. Characteristics of virulence in
human isolates of Yersinia enterocolitica. Infection & Immunity 32, 400-403.
Schiemann,D.A.,Fleming,C.A. 1981. Yersinia enterocolitica isolated from
throats of swine in eastern and western Canada. Canadian Journal of
Microbiology. 27, 1326-1333.
Schiemann,D.A.,Nelson,C.M. 1988. Antibody inhibition of HeLa cell invasion
by Yersinia enterocolitica. Canadian Journal of Microbiology. 34, 52-57.
Siddique,N., Sharma,D., Al-Khaldi,S.F. 2009. Detection of Yersinia
enterocolitica in alfalfa, mung bean, cilantro, and mamey sapote (Pouteria
sapota) food matrices using DNA microarray chip hybridization. Curr.
Microbiol. 59, 233-239.
Singh,A., LeChevallier,M.W., McFeters,G.A. 1985. Reduced virulence of
Yersinia enterocolitica by copper-induced injury. Applied and Environmental
91
Microbiology 50, 406-411.
Singh,A.,McFeters,G.A. 1987. Survival and virulence of copper- and
chlorine-stressed Yersinia enterocolitica in experimentally infected mice.
Applied and Environmental Microbiology 53, 1768-1774.
Skurnik,M. 1984. Lack of correlation between the presence of plasmids and
fimbriae in Yersinia enterocolitica and Yersinia pseudotuberculosis. Journal of
Applied Bacteriology 56, 355-363.
Skurnik,M. 1985. Expression of antigens encoded by the virulence plasmid of
Yersinia enterocolitica under different growth conditions. Infection & Immunity
47, 183-190.
Skurnik,M., Bolin,I., Heikkinen,H., Piha,S., Wolf-Watz,H. 1984. Virulence
plasmid-associated autoagglutination in Yersinia spp. Journal of Bacteriology
158, 1033-1036.
Small,P.L., Isberg,R.R., Falkow,S. 1987. Comparison of the ability of
enteroinvasive Escherichia coli, Salmonella typhimurium, Yersinia
pseudotuberculosis, and Yersinia enterocolitica to enter and replicate within
HEp-2 cells. Infection & Immunity 55, 1674-1679.
Stern,N.J. 1982. Yersinia enterocolitica: recovery from foods and virulence
characterization. Food Technology 36(3), 84-88.
Stern,N.J. 1981. Isolation of potentially virulent Yersinia enterocolitica. Journal
of Food Science 46, 41-42.
Stern,N.J., Kotula,A.W., Pierson,M.D. 1980a. Virulence prediction of Yersinia
enterocolitica by pyrolysis gas-liquid chromatography. Applied and
Environmental Microbiology 40, 646-650.
Stern,N.J.,Pierson,M.D. 1979. Yersinia enterocolitica: a review of the
psychrotrophic water and foodborne pathogen. Journal of Food Science 44,
1736-1742.
Stern,N.J., Pierson,M.D., Kotula,A.W. 1980c. Growth and competitive nature of
Yersinia enterocolitica in whole milk. Journal of Food Science 45, 972-974.
Stern,N.J., Pierson,M.D., Kotula,A.W. 1980b. Effects of pH and sodium
chloride on Yersinia enterocolitica growth at room and refrigeration
92
temperatures. Journal of Food Science 45, 64-67.
Strotmann,C., von,M.T., Klein,G., Nowak,B. 2008. Effect of different
concentrations of carbon dioxide and oxygen on the growth of pathogenic
Yersinia enterocolitica 4/O:3 in ground pork packaged under modified
atmospheres. Journal of Food Protection 71, 845-849.
Stuart,S.J., Prpic,J.K., Robins-Browne,R.M. 1986. Production of aerobactin by
some species of the genus Yersinia. Journal of Bacteriology 166, 1131-1133.
Swaminathan,B., Harmon,M.C., Mehlman,I.J. 1982. Yersinia enterocolitica.
Journal of Applied Bacteriology 52, 151-183.
Townsend,M.K., Carr,N.J., Iyer,J.G., Horne,S.M., Gibbs,P.S., Pruss,B.M. 2008.
Pleiotropic phenotypes of a Yersinia enterocolitica flhD mutant include reduced
lethality in a chicken embryo model. BMC Microbiology 8, 12.
Uchida,I., Kaneko,K., Hashimoto,N. 1982. Cross-protection against fecal
excretion of Yersinia enterocolitica and Yersinia pseudotuberculosis in mice by
oral vaccination of viable cells. Infection & Immunity 36, 837-840.
Verma,N.K.,Misra,D.S. 1984. Characterization of enterotoxin produced by four
Yersinia enterocolitica strains of pig origin. Antonie Van Leeuwenhoek Journal
of Microbiology 50, 361-368.
Vesikari,T., Nurmi,T., Maki,M., Skurnik,M., Sundqvist,C., Granfors,K.,
Gronroos,P. 1981. Plasmids in Yersinia enterocolitica serotypes O:3 and O:9
correlation with epithelial cell adherence in vitro. Infection & Immunity 33,
870-876.
Walker,K.A.,Miller,V.L. 2009. Synchronous gene expression of the Yersinia
enterocolitica Ysa type III secretion system and its effectors. Journal of
Bacteriology 191, 1816-1826.
Walker,S.J.,Gilmour,A. 1986. A comparison of media and methods for the
recovery of Yersinia enterocolitica and Yersinia enterocolitica-like bacteria from
milk containing simulated raw milk microfloras. Journal of Applied
Bacteriology 60, 175-183.
Wang,X., Cui,Z., Jin,D., Tang,L., Xia,S., Wang,H., Xiao,Y., Qiu,H., Hao,Q.,
Kan,B., Xu,J., Jing,H. 2009. Distribution of pathogenic Yersinia enterocolitica
in China. European Journal of Clinical Microbiology and Infectious Diseases
93
Wang,X., Qiu,H., Jin,D., Cui,Z., Kan,B., Xiao,Y., Xu,Y., Xia,S., Wang,H.,
Yang,J., Wang,X., Hu,W., Xu,J., Jing,H. 2008. O:8 serotype Yersinia
enterocolitica strains in China. International Journal of Food Microbiology 125,
259-266.
Wauters,G., Goossens,V., Janssens,M., Vandepitte,J. 1988. New enrichment
method for isolation of pathogenic Yersinia enterocolitica serogroup O:3 from
pork. Applied and Environmental Microbiology 54, 851-854.
Weagant,S.D. 1983. Medium for presumptive identification of Yersinia
enterocolitica. Applied and Environmental Microbiology 45, 472-473.
Weagant,S.D. 2008. A new chromogenic agar medium for detection of
potentially virulent Yersinia enterocolitica. Journal of Microbiological Methods
72, 185-190.
Weagant,S.D.,Kaysner,C.A. 1983. Modified enrichment broth for isolation of
Yersinia enterocolitica from nonfood sources. Applied and Environmental
Microbiology 45, 468-471.
Witowski,S.E., Walker,K.A., Miller,V.L. 2008. YspM, a newly identified Ysa
type III secreted protein of Yersinia enterocolitica. Journal of Bacteriology 190,
7315-7325.
xler-DiPerte,G.L., Hinchliffe,S.J., Wren,B.W., Darwin,A.J. 2009. YtxR acts as
an overriding transcriptional off switch for the Yersinia enterocolitica Ysc-Yop
type 3 secretion system. Journal of Bacteriology 191, 514-524.
Zaleska,M., Lounatmaa,K., Nurminen,M., Wahlstr:om,E., M:akel:a,P.H. 1985. A
novel virulence-associated cell surface structure composed of 47-kd protein
subunits in Yersinia enterocolitica. Embo Journal 4, 1013-1018.
Zheng,H., Sun,Y., Mao,Z., Jiang,B. 2008. Investigation of virulence genes in
clinical isolates of Yersinia enterocolitica. FEMS Immunology and Medical
Microbiology 53, 368-374.
Zheng,X.B. 1987. Isolation of Yersinia enterocolitica from the faeces of
diarrhoeic swine. Journal of Applied Bacteriology 62, 521-525.
Zink,D.L., Feeley,J.C., Wells,J.G., Vanderzant,C., Vickery,J.C., Roof,W.D.,
O'Donovan,G.A. 1980. Plasmid-mediated tissue invasiveness in Yersinia
enterocolitica. Nature 283, 224-226.
94