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OPP OPP
Regra do isopreno - Wallach (1887) 2-metilbuta-1,3-dieno (isopreno) O nome terpeno deriva da terebentina (turpentine) de onde foram isolados a cânfora e o a-pineno. As estruturas foram elucidadas em torno de 1894. Terpenes • Terpenes are natural products that are structurally related to isoprene. CH3 H2C C CH CH2 or Isoprene (2-methyl-1,3-butadiene) Terpenes • Myrcene (isolated from oil of bayberry) is a typical terpene. CH3 CH3C CH2 CHCH2CH2CCH or CH2 The Isoprene Unit • An isoprene unit is the carbon skeleton of isoprene (ignoring the double bonds) Myrcene contains two isoprene units. The Isoprene Unit • The isoprene units of myrcene are joined "head-to-tail." head tail tail head Isoprene Head Tail Isoprene Head Tail Head Tail Isoprene Head Tail • • • • • • • Classe Monoterpeno Sesquiterpeno Diterpeno Sesterpeno Triterpeno Tetraterpeno Número de átomos de Carbono 10 15 20 25 30 40 • C10 terpenoids (monoterpenes) components of volatile essences, essential oils • C15 (sesquiterpenes) components of essential oils, phytoalexins (self defense) • C20 (diterpenes) gibberellins, resin acids, phytol (chlorophyll side chain) • C30 (triterpenes) phytosterols, brassinosteroids • C40 (tetraterpenes) carotenoids OH O H a-Phellandrene Menthol (eucalyptus) (peppermint) Citral (lemon grass) OH O H a-Phellandrene Menthol (eucalyptus) (peppermint) Citral (lemon grass) a-Phellandrene Menthol (eucalyptus) (peppermint) Citral (lemon grass) H a-Selinene (celery) H a-Selinene (celery) a-Selinene (celery) OH Vitamin A OH Vitamin A Vitamin A tail-to-tail linkage of isoprene units Squalene (shark liver oil) MONOTERPENOS OH O O CHO cânfora carvona O citronelal linalol (óleo de pau-rosa) eucaliptol (1,8-cineol) SESQUITERPENOS H H H O O H O HO HO nerolidol O cariofileno artemisinina ISOPENTENYL PYROPHOSPHATE: THE BIOLOGICAL ISOPRENE UNIT The Biological Isoprene Unit • The isoprene units in terpenes do not come from isoprene. • They come from isopentenyl pyrophosphate. Isopentenyl Pyrophosphate CH3 H2C O O CCH2CH2OPOPOH Isopentenyl pyrophosphate or OPP Isopentenyl and Dimethylallyl Pyrophosphate Isopentenyl pyrophosphate is interconvertible with 2-methylallyl pyrophosphate. OPP Isopentenyl pyrophosphate OPP Dimethylallyl pyrophosphate • Dimethylallyl pyrophosphate has a leaving group (pyrophosphate) at an allylic carbon; it is reactive toward nucleophilic substitution at this position. First specific step in the biosynthesis of terpenoids - isomerization of IPP into DMAPP- H + W CH 3 H OP H H R IP P H S H H H CH 3 w CH OP H R H 3 OP H 3C S H H S + R D M A P P IPP-Isomerase mechanism Cys138 Cys139 S H HH S H H O Glu 207 IPP Cys139 S H H OPP H HS O C Cys138 S HH H H H OPP HS O C H HS OH Glu 207 DMAPP THE PATHWAY FROM ACETATE TO ISOPENTENYL PYROPHOSPHATE The Biological Isoprene Unit O O 3 CH3COH CH3 HOCCH2CCH2CH2OH OH Mevalonic acid CH3 H2C O O CCH2CH2OPOPOH Isopentenyl pyrophosphate Biosynthesis of Mevalonic Acid • In a sequence analogous to the early steps of fatty acid biosynthesis, acetyl coenzyme A is converted to Sacetoacetyl coenzyme A. O O CH3CCH2CSCoA S-Acetoacetyl coenzyme A Biosynthesis of Mevalonic Acid O O O CH3CCH2CSCoA + CH3CSCoA • In the next step, S-acetoacetyl coenzyme A reacts with acetyl coenzyme A. • Nucleophilic addition of acetyl coenzyme A (probably via its enol) to the ketone carbonyl of S-acetoacetyl coenzyme A occurs. Biosynthesis of Mevalonic Acid O O O CH3CCH2CSCoA + CH3CSCoA HO O CH3CCH2CSCoA CH2COH O Biosynthesis of Mevalonic Acid • Next, the acyl coenzyme A function is reduced. • The product of this reduction is mevalonic acid. HO O CH3CCH2CSCoA CH2COH O HO CH3CCH2CH2OH CH2COH O HO O CH3CCH2CSCoA CH2COH O Mevalonic acid Conversion of Mevalonic Acid to Isopentenyl Pyrophosphate 2– HO OPO3 CH3CCH2CH2OH CH3CCH2CH2OPP CH2COH CH2COH O O • The two hydroxyl groups of mevalonic acid undergo phosphorylation. Conversion of Mevalonic Acid to Isopentenyl Pyrophosphate 3– 2– OPO3 OPO3 CH3CCH2CH2OPP CH2 O CH3CCH2CH2OPP CH2 C O C O • Phosphorylation is followed by a novel elimination involving loss of CO2 and PO43–. •• – O •• •• Conversion of Mevalonic Acid to Isopentenyl Pyrophosphate CH3CCH2CH2OPP CH2 • The product of this elimination is isopentenyl pyrophosphate. Biosynthetic pathway is based on experiments with 14C-labeled acetate O O CH3COH CH3 HOCCH2CCH2CH2OH OH Mevalonic acid CH3 H2C O O CCH2CH2OPOPOH Isopentenyl pyrophosphate Biosynthetic pathway is based on experiments with 14C-labeled acetate • Citronellal biosynthesized using 14C-labeled acetate as the carbon source had the labeled carbons in the positions indicated. CH3 O CH3COH H2C • • • • • CCH2CH2OPOPOH O • O O H Inibidores da biossíntese de colesterol (produtos que mimetizam o ácido mevalônico) HO R1 HO H3C CO2 OH OH O CH3 CO2 mevalonate O CH3 R2 R1 = H R1 = CH3 R1 = H R1 = H R2 = H R2 = CH3 R2 = OH R2 = CH3 Compactin Simvastatin (Zocov) Pravastatin (Precavol) Lovastatin (Mevacor) Rohmer & coworkers, Braunschweig (1980s) eubacterial sterol (hopanoids) synthesis metabolic profiling with 13C-NMR fed [13C]acetate and looked at label in endproducts and intermediates pattern did not match that of mevalonate pathway also mevilonin insensitive substrates glyceraldehyde 3P and pyruvate efficiently incorporated phosphorylated 5C sugar is intermediate 1-deoxyxylulose-5P (DXP) The Non-mevalonate or DXP pathway H O H OH HO HO HO H H HOOC H OH OH [1- C]-glucose HO S S TPP pyruvate 13 N N O H HO H OH HO PO N S glyceraldehyde-3-P O -CO2 O HO HO PO 1-deoxy-xylulose-5-P O N -TPP HO HO S OH OP HO OP O OH OPP IPP OPP IPP originated from HMG-CoA Pyruvate 2 x Acetyl CoA Glyceraldehyde 3-phosphate Deoxy xylulose 5-phosphate Methyl erythritol 4-phosphate HMG CoA MVA MVA pathway (cytoplasm) IPP Non-MVA pathway (plastids) Sources of Isoprenoids in Higher Plants • Higher plants like red (and brown) algae • Cytosolic mevalonate pathway • sterols (C30), ubiquinone • certain sesquiterpenoid (C15) phytoalexins • plastidic DXP pathway • carotenoids, phytol, PQ • mono- and di-terpenes (C10 & C20), and other sesquiterpenes Subcellular Location of Isoprenoid synthesis Mitochondrion Sterols, Rubber Haem a UQ PQ Chloroplast ER Carotenoids CHLOROPHYLL Also Gibberellins, ABA, CKs tRNAs phytoalexins volatile oils Feed IPP to cps, mitos or ER incorporated into organelle-specific isoprenoids CARBON-CARBON BOND FORMATION IN TERPENE BIOSYNTHESIS Carbon-Carbon Bond Formation OPP + OPP • The key process involves the double bond of isopentenyl pyrophosphate acting as a nucleophile toward the allylic carbon of dimethylallyl pyrophosphate. SN1 Reaction OPP DMAPP Head-tail condensation CH3 CH3 OPP H3C HS DMAPP HR HS IPP OPP OPP HR HS OPP Geranyl diphosphate (GPP) FORMATION OF THE MONOTERPENE SKELETONS Carbon-Carbon Bond Formation OPP + OPP – OPP + OPP After C—C Bond Formation... OPP • The carbocation can lose a proton to give a double bond. –H + + OPP After C—C Bond Formation... OPP • This compound is called geranyl pyrophosphate. It can undergo hydrolysis of its pyrophosphate to give geraniol (rose oil). After C—C Bond Formation... OPP H2 O OH Geraniol Cyclization • Rings form by intramolecular carbon-carbon bond formation. + OPP OPP E double bond Z double bond –H + + OH H2O H H 1,2-hydride shift Wagner-Meerwein Rearrangements H H secondary carbocation H tertiary carbocation 1,2-methyl shift secondary carbocation H tertiary carbocation 1,3-hydride shift H H H H tertiary carbocation ressonance-stabilized allylic cation Wagner-Meerwein Rearrangements cont. 1,2-alkyl shift tertiary carbocation, but strained 4-membered ring secondary carbocation. but reduced ring strain in 5-membered ring H H H H a series of concerted 1,2 hydride and methyl shifts Bicyclic Terpenes + + + a-Pineno -Pineno + OPP E OPP OPP OPP Z OPP OPP Geranyl-PP linalyl-PP Geranyl cation (ressonance stabilized allylic cation) neryl-PP neryl cation (ressonance stabilized allylic cation) FORMATION OF THE SESQUITERPENE SKELETONS • Probably substrate specific • ie different ones to make GPP, FPP, GGPP • GPP synthase in peppermint (Burke et al, 1999) • heterodimer of 28 & 37 kDa • plastid located • GGPP synthases in Arabidopsis (Okada et al, 2000) • 1 & 3 go to cps, 2 & 4 go to ER and 6 is in mitos • 1 & 6 ubiquitously expressed • 2, 3 & 4 in flower, root and flower respectively Cyclases or Terpene Synthases • Responsible for cyclization of isoprenoid • C10 to monoterpenes • C15 to sesquiterpenes • C20 to diterpenes • Similar reaction to prenyltransferases • loss of PP group produces carbocation • this attacks a double bond • multiple double bonds mean alternative products • Plant cyclases have sequence similarity • differ from fungal or animal enzymes From 10 Carbons to 15 OPP + OPP Geranyl pyrophosphate + OPP From 10 Carbons to 15 OPP –H + + OPP From 10 Carbons to 15 OPP • This compound is called farnesyl pyrophosphate. • Hydrolysis of the pyrophosphate ester gives the alcohol farnesol Pathways for cyclization of farnesyl-PP H E H guaiyl cation germacryl cation E E,E-farnesyl cation eudesmyl cation humulyl cation caryophyllyl cation bisabolyl cation a E a a carotyl cation Z b b E,Z-farnesyl cation b H cis-germacryl cation cis-humulyl cation cadinyl cation Formation of the Diterpene Skeletons From 15 Carbons to 20 OPP OPP • Farnesyl pyrophosphate is extended by another isoprene forming the geranylgeranyl diphostate (GGPP) H H H H H OPP OPP H OPP H H Copalil-pp OPP OPP H H H H H H OPP H H labdadienil -pp TRITERPENOS & ESTERÓIDES HO HO eufol lupeol R R HO HO R=COOH (ácido oleanólico) R=CH3 (-amirina) R=COOH (ácido ursólico) R=CH3 (a-amirina) O O O H O H H H H H HO HO H Diosgenina Digitoxigenina H H HO Colesterol H OH PPO farnesol-PP farnesol-PP OPP H H H H OPP H H H H H (NADPH) H H Squalene Enz -OPP OPP OPP pirofosfato de farnesila pirofosfato de farnesila OPP OPP H Enz *H NADP*H esqualeno Um processo idêntico ocorre na formação de tetraterpenos a partir de diterpenos Coupling Enzymes • Head-to-head condensation • Squalene synthase for sterols (C30), phytoene synthase for carotenoids (C40) OPP OPP phytoene PSY and SqS share domain in common Arab PSY Syn. PSY Arab SqS prenyltransferase domain Biosynthesis of Cholesterol • Cholesterol is biosynthesized from the triterpene squalene. In the first step, squalene is converted to its 2,3-epoxide. O2, NADH, enzyme O Biosynthesis of Cholesterol O • To understand the second step, we need to look at squalene oxide in a different conformation, one that is in a geometry suitable for cyclization. O Chair-boat-chair-boat conformation Biosynthesis of Cholesterol HO + H • Cyclization is triggered by epoxide ring opening. H+ O Biosynthesis of Cholesterol HO + H • The five-membered ring expands to a six-membered one. H HO H Biosynthesis of Cholesterol H HO protosteryl cation H • Cyclization to form a tetracyclic carbocation. H HO H Biosynthesis of••Cholesterol •• OH 2 HO H • Deprotonation and multiple migrations. H H HO H Biossíntese de Esteróides Sequence od W-M 1,2-hydride and 1,2 methyl shifts H H H H H H HO O H H H HO H protosteryl cation squalene oxide plants animals fungi loss of a proton gives alkene H H H HO H lanosterol HO H cycloartenol loss of proton leads to cyclopropane Biossíntese de Triterpenos H Chair-chair-chair-boat conformation H+ H O HO H H H H H HO H HO a-amirina H
