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Lecture8
Modification of gene expression Genetic strategies To take into consideration: Means: 9/11-2010 - transcription - promoters - translation - terminators - localization - RBS strength - number of gene copies - protein stability - gene fusions - metabolic conditions - gene sequence (codon usage) - purification process etc - etc Promoter strength affects the protein expression level Promoter (Escherichia coli) Recombinant protein production: Prokaryotes II Start of RNA synthesis -35 Start of coding sequence -10 CCGGTTGACAGATAGTCGTGTATGCGATATAATCAGCCCGTAGTCGGAGGGTCCTGACATG… GGCCAACTGTCTATCAGCACATACGCTATATTAGTCGGGCATCAGCCTCCCAGGACTGTAC… "Pribnow box" P Gene for protein 5´ Produced mRNA molecule Translation Figure 6-3 Molecular Biology of the Cell (© Garland Science 2008) Commonly used promoters Promoter Inductiona Strength lac tac -35 trp -10 lac trc trp T7 PL(λ) lac(TS) PSPA PBAD IPTG IPTG IPTG Trp-depletion/β-IAA IPTG Heat Heat Constitutive L-arabinose rel. weak rel. strong rel. strong Test of promoter strength His6ABPGFP Trc very strong very strong T7 LacUV5 SPA Negative control weak rel. strong amost frequently used means of induction. Abbrev.: SPA, Staphylococcus aureus protein A; IPTG, isopropyl-β-D-thiogalactopyranoside; β-IAA, β-indoleacrylic acid. Fluorescence intensity Red = T7 Green = Trc Blue = LacUV5 Yellow = SPA H. Tegel, unpublished 1 CAP -10 Lac I S.D. 5´ mRNA-start RNA-pol. -35 DNA -10 cAMP/CAPbinding region Operatorsequence S.D. 5´ 3´ Lac-repressor (Lac I) Lactose or IPTG (synthetic analogue) Lac Z Lac I mRNA Lac I Promoter= ”Landing spot” for RNA polymerase repressor Catabolite Activator Protein (CAP) Promoter -35 Cyclic AMP (cAMP) Lac Z Lac Y S.D. Lac Y Lac A S.D. mRNA Lac A 3´ promoter Trp Trp-operon Regulation of the lactose operon (E. coli) operator trpL trpE trpD trpC trpB trpA β-galactosidase: Lactose permease: Thio-galactoside-acetylase: Turns lactose into Regulates the lactose Degrades non-cleavable galactose and glucose uptake lactose analogues In the absence of lactose: • Lac-repressor binds to the operator sequence • Transcriptionen is blocked; no β-galactosidase (or any of the other enzymers) is producced Tryptophan depletion repressor Lactose (or IPTG) present: • Lac-repressor cannot bind to the operator sequence • Transcription is allowed; β-galactosidase (and all the other enzymes) is produced trpL Presence of lactose (or IPTG) and low concentrations of glucose: • cAMP concentration rises • cAMP-CAP-complex formed that can bind upstream of the promoter • cAMP-CAP-complex promotes transcription (“guides” the RNA polymerase) • More β-galactosidase is produced trpE trpD trpC trpB trpA mRNA T7-system & PL pET protein expression system T7-system Lac-promoter LacT7 RNAoperator polymerase gene T7-promoter gene of interest mRNA mRNA T7 RNA-polymerase PL-promoter Repressor protein from bacteriophage λ Growth at 28-30°C: active repressor Induction at 42°C : repressor is inactivated, result in transcription PBAD promoter FIGURE 10.4 Replicons (ori) carried by plasmid vectors Plasmid Replicon Copy nr. References pBR322 pUC pMOB45 pACYC pSC101 colE1 pMB1 pMB1 deriv. pKN402 p15A pSC101 colE1 15-20 500-700 15-118 18-22 ~5 15-20 Bolivar et al. (1977) Viera & Messing (1982, 1987) Bittner & Vapnek (1981) Chang & Cohen (1978) Stoker et al. (1982) Kahn et al. (1979) Incompatibility groups: colE1, pMB1 IncFII, pT181 P1, F, R6K, pSC101, p15A FIGURE 10.5 2 Plasmids - a burden for the host cell • Plasmids are lost • Strategy: plasmid encoded protein that is crucial for survival in the cell culture • Usually antibiotics or essential metabolite has to be added (expensive!) • Risk of gene transfer (e.g., MRSA) • Solution: Integration of the DNA on chromosome Expression optimization: translational level Expression optimization:transcriptional level • Promoter strength: - degree of ”consensus” sequence • Sigma factor availability: - growth condition dependent • Positive/negative regulation • Enhancer/silencer regions Heterologous protein expression in E. coli • Common problems • Solutions - protein aggregation - decreased synthesis rate • RBS-sequence dependent - protein misfolding - inactive protein - low yield UAAGGAGG mRNA AUUCCUCC 16S-RNA • Distance: RBS-ATG • Secondary structure of the mRNA • ”Codon usage” Expression of a eukaryotic gene in bacteria (weaker promoter, reduce conc. of inducer, low temperature) - co-expression of folding modulators - fusion tags - protein engineering of target - host engineering Codon usage: E. coli FIGURE 10.1 3 Codon usage: H. sapiens Codon usage affects the translation rate FIGURE 10.3 Problems due to rare codons • reduced translational rate • low expression levels • amino acid misincorporations Solutions to problems caused by rare codons • exchange the rare codon/s for a more frequently used codon • introduce extra copies of the “limiting” tRNA genes • truncated or amino acid-deleted proteins • frame-shifted proteins Chaperone-assisted protein folding (cytoplasm) Role of DnaK and GroE chaperone machines in nascent protein folding Georgopoulos, C. Genetics 2006;174:1699-1707 Baneyx F et al, Nature Biotechnology (2004), 22: 1399-1407 Copyright © 2007 by the Genetics Society of America 4 Effect of co-expression of GroEL/ES Cytoplasmic chaperones Family Name Hsp100 Clp Cofactors Function Substrate specificity Disaggregase Regions rich in aromatic and bacic aa + Hsp90 HtpG Hsp70 DnaK DnaJ, GrpE Folding/secretory chap.? Unknown + Folding chaperone Segm. of four to five hydrophobic aa, enriched in leucine and flanked by basic residues + Hsp60 GroEL GroES Folding chap. α/β folds enriched in hudrophobic and basic residues + Hp33 DJ-1 superfam. Hsp33 Holding chap. Unknown - Hsp31 Holding chap. Unknown - Small Hsps IbpA, IbpB Holding chap. Unknown - PPIase TF Hold. chap., PPIase Eight aa motif enriched in aromatic and basic residues - SecB SecB Secretory chap. Nine aa motif enriched in aromatic and basic residues - P ATP requirement HSD1 EGFP time: 4 h DH5alpha/11b-HSD1-eGFP DH5alpha/11b-HSD1-eGFP/GroELES Export and periplasmic folding pathways Periplasmic chaperones Classification Protein Substrates Generic chaperones Skp (OmpH) FkpA Outer membr. proteins and misfolded periplasmic proteins Broad substrate range Specialized chap. SurA LolA PapD FimC Outer membrane proteins Outer membrane lipoproteins Proteins involved in P Pili biosynthesis Proteins involved in type 1 pili biosynthesis PPIases SurA PpiD FkpA PpiA Outer membrane beta-barrel proteins Outer membrane beta-barrel proteins Broad substrate range Unknown Proteins involved in disulfide bond formation DsbA DsbB DsbC DsbG DsbD DsbE (CcmG) CcmH Reduces cell-envelope proteins Reduces DsbA Proteins with nonnative disulfides Proteins with nonnative disulfides Oxidised DsbC, DsbG and CcmG Cytochrome c biogenesis Cytochrome c biogenesis Baneyx F et al, Nature Biotechnology (2004), 22: 1399-1407 E. coli: periplasm Folding in the bacterial periplasm: protein disulphide-isomerases • DsbA, a generic dithiol oxidase in the periplasm of E. coli E. coli: periplasm Folding in the bacterial periplasm: protein disulphide-isomerases • DsbC catalyzes disulphide bond exchange reactions 5 E. coli: periplasm Known components of the thioredoxin system and glutaredoxin system. Folding in the bacterial periplasm: peptidyl-prolyl cis/trans-isomerases • • • polypeptide bonds are synthesized in trans configuration 5% cis peptidyl-prolyl bonds in native proteins Ea = 20 kcal/mol for peptidylprolyl-isomerisation Rate-determining step of protein folding Prinz W A et al. J. Biol. Chem. 1997;272:15661-15667 ©1997 by American Society for Biochemistry and Molecular Biology trxB/gor mutants allow disulfide formation in the cytoplasm Prinz W A et al. J. Biol. Chem. 1997;272:15661-15667 ©1997 by American Society for Biochemistry and Molecular Biology Urokinase becomes active in the cytoplasm of WP759 and WP778 Prinz W A et al. J. Biol. Chem. 1997;272:15661-15667 ©1997 by American Society for Biochemistry and Molecular Biology Low temperature adaptation Metabolic load • Plasmids with high copy-number • Oxygen limitations •Overexpression of foreign proteins may lead to shortage of tRNAs • Export machinery can become blocked. The export of endogenous host cell proteins is then obstructed. • Metabolic properties way be changed in a negative way. • Foreign proteins can be detrimental to the host cell, e.g. toxic properties Ferrer M et al, Nature Biotechnology (2003) 21: 1266-67 6 Oxygen limitations • Decreased growth rate, changed metabolism • Stress response is activated; protease expression is upregulated Solutions: • • Protease negative strains will result in less-pronounced protein degradation. However, faulty (mis-folded, truncated etc) proteins cannot be degraded. What happens to the cell? • Cell growth decreases, low cell densities • Shape and size changes • Stress response. Proteases are expressed • Reduced stringency in DNA-proof reading • Wrong amino acid can be incorporated due to insufficient amounts of tRNA or amino acids. Expression of a bacterial haemoglobin can improve intracellular oxygen binding. How can we reduce the metabolic load? • Use other codons (synonymous) • Use tightly regulated promoters (they should not ”leak”) • Reduced expression level may result in higher cell density in the culture, and thereby better productivity. 7
