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Catharanthus terpenoid indole alkaloids: biosynthesis and regulation PDF

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Preview Catharanthus terpenoid indole alkaloids: biosynthesis and regulation

PhytochemRev(2007)6:277–305 DOI10.1007/s11101-006-9047-8 Catharanthus terpenoid indole alkaloids: biosynthesis and regulation Magdi El-Sayed Æ Rob Verpoorte Received:29August2005/Accepted:23October2006/Publishedonline:10March2007 (cid:1)SpringerScience+BusinessMediaB.V.2007 Abstract Catharanthus roseus is still the only localization and regulation are discussed. Much source for the powerful antitumour drugs vin- progress has been made at alkaloid regulatory blastine and vincristine. Some other pharmaceu- level.Feedingprecursors,growthregulatorstreat- tical compounds from this plant, ajmalicine and ments and metabolic engineering are good tools serpentine are also of economical importance. to increase productivity of terpenoid indole alka- Although C. roseus has been studied extensively loids. But still our knowledge of the late steps in and was subject of numerous publications, a full the Catharanthus alkaloid pathway and the genes characterizationof its alkaloidpathway is not yet involved is limited. achieved. Here we review some of the recent work done on this plant. Most of the work Keywords Indole alkaloids (cid:1) Biosynthesis (cid:1) focussed on early steps of the pathway, particu- Catharanthus (cid:1) Indole pathway (cid:1) MEP pathway (cid:1) larly the discovery of the 2-C-methyl-D-erythritol Regulation (cid:1) Terpenoids 4-phosphate (MEP)-pathway leading to terpe- noids. Both mevalonate and MEP pathways are Abbreviations utilized by plants with apparent cross-talk be- AACT Acetoacetyl-CoA thiolase tweenthemacrossdifferentcompartments.Many ABA Abscisic acid genes of the early steps in Catharanthus alkaloid AS Anthranilate synthase pathway have been cloned and overexpressed to AVLB Anhydrovinblastine improve the biosynthesis. Research on the late CMS 4-Cytidyl diphospho-2 C-methyl-D- stepsinthepathwayresultedincloningofseveral erythritol synthase genes. Enzymes and genes involved in indole CPR Cytochrome P450 reductase alkaloid biosynthesis and various aspects of their CR Cathenamine reductase DAT Acetyl CoA:deacetylvindoline 17- O-acetyltransferease M.El-Sayed(cid:1)R.Verpoorte(&) D4H Desacetoxyvindoline 4-hydroxylase DepartmentofPharmacognosy,Sectionof DMAPP Dimethylallyl diphosphate Metabolomics,InstituteofBiologyLeiden,Leiden University,Leiden,TheNetherlands DXP 1-Deoxy-D-xylulose-5-phosphate e-mail:[email protected] DXR 1-Deoxy-D-xylulose-5-phosphate reducto isomerase M.El-Sayed DepartmentofBotany,AswanFacultyofScience, DXS 1-Deoxy-D-xylulose-5-phosphate SouthValleyUniversity,Aswan,Egypt synthase 123 278 PhytochemRev(2007)6:277–305 GAP Glyceraldehyde-3-phosphate predators, as messengers, attractants, repellents G10H Geraniol 10-hydroxylase or as camouflage (Verpoorte 1998). GPP Geranyl diphosphate Alkaloids are one of the largest classes of HMG-CoA 3-Hydroxy-3-methylglutaryl-CoA secondary metabolites. They contain a heterocy- HMGS 3-Hydroxy-3-methylglutaryl-CoA clic nitrogen usually with basic properties that synthase makes them particularly pharmacologically HMGR 3-Hydroxy-3-methylglutaryl-CoA active. Among them are the indole alkaloids reductase whicharefoundmainlyinplantsbelongingtothe IPP Isopentenyl diphosphate families: Apocynaceae, Loganiaceae, Rubiaceae K Michaelis–Menten constant and Nyssaceae (Verpoorte et al. 1997). m LAMT Loganic acid methyltransferase Catharanthus roseus (L.) G. Don (Madagascar MCS 2-C-Methyl-D-erythritol Periwinkle) is one of the most extensively inves- 2,4-cyclodiphosphate synthase tigated medicinal plants. The importance of this MEP 2-C-methyl-D-erythritol plant is due to the presence of two antitumour 4-phosphate alkaloids, vinblastine and vincristine found in the MVAK Mevalonate kinase leaves, and ajmalicine, an alkaloid found in the MJ Methyljasmonates roots. All parts of this plant contain a variety of M Relative molecular weight alkaloids, even seeds that were thought to have r MVA Mevalonic acid no alkaloids until Jossang et al. (1998) isolated MVAPK 5-Diphosphomevalonate kinase two binsidole alkaloides from the seeds, vingr- NMT-SAM Methoxy 2,16-dihydro-16- amine and methylvingramine. Cell suspension hydroxytabersonine cultures of C. roseus are an alternative means N-methyltransferase for the production of economically important OMT O-Methyltransferase terpenoid indole alkaloids (TIAs). However, the ORCA Octadecanoid-responsive yields are too low to allow commercial applica- Catharanthus AP2/ERF-domain tion. The more than 100 C. roseus alkaloids that SAM S-Adenosyl-L-methionine have been identified share many biosynthetic SGD Strictosidine b-D-glucosidase steps. The early stages of alkaloid biosynthesis SLS Secologanin synthase in C. roseus involve the formation of secologanin STR Strictosidine synthase derived from the terpenoid (isoprenoid) biosyn- T16H Tabersonine 16-hydroxylase thesis and its condensation with tryptamine to THAS Tetrahydroalstonine synthase producethecentralintermediatestrictosidine,the TIA Terpenoid indole alkaloids; common precursor for the monoterpenoid indole TDC Tryptophan decarboxylase alkaloids (Fig. 1). The terpenoid pathway Terpenoids are the largest family of natural Introduction products with over 30,000 compounds. They are known to have many biological and physiological Plant cells are considered to be excellent produc- functions. Formation of terpenoids proceeds via ers of a broad variety of chemical compounds. two different pathways, the classical mevalonate Many of these compounds are of high economic andthenewlydiscovered2-C-methyl-D-erythritol value such as various drugs, flavours, dyes, 4-phosphate (MEP) pathway leading to isopente- fragrances and insecticides. These compounds nyl diphosphate (IPP). In higher plants, the usually play a role in the interaction of the plant mevalonate pathway operates mainly in the cyto- with its environment, e.g. as toxins to defend plasm and mitochondria. The MEP pathway the plant against micro-organisms or various operates in the plastids with a cross-talk between 123 PhytochemRev(2007)6:277–305 279 H O tryptamine N NH2 H OGlc H H O H3COOC secologanin N+ N H HN N+ H CH3 NHH NH OGlc H3HCOOHC OCH3 H O H O alstonine H3COOC serpentine H3COOC strictosidine HNH N H CH3 HNH N CH3 HNH N+ NHH N CH3 HNH N H CH3 H3COOHC O H3COOHC O H3COOHC OH H3COOHC O H3COOHC O ajmalicine cathenamine 4,21-dehydrogeissoschizine epicathenamine tetrahydroalstonine N H N H3COOC CH2OH N N N H H H H NH H N N stemmadHe3CnOinOeC CH2OH COtOaCbHe3rsonine H akuammidine secodine N N H N H3COOC N H catharanthiHne COOCH3CH2CH3 CH3O N H OH OCOCH3 NH CH3COOCH3 NHO NH CH3 +N vindoline perivine COOCH3 vindolinine H N COOCH3 H N OH H3CO N H OCOCH3 H3C COOCH3 OH iminium N N O H H N COOCH3 N NH COOCH3 N H OH N H3CO N H OH OCOCH3 H3CO H3CN vHiCnObOlaCsHOt3inCeOCH3 NH CHOOCH3 N H3C COOCH3 leurosine OH N OH H3CO H3NC H COOCHO3COCH3 3',4'-anhydrovinblastine H N COOCH3 N H OH H3CO N H OCOCH3 OHC COOCH3 vincristine Fig.1 DifferentCatharanthusindolealkaloidsbiosyntheticpathways 123 280 PhytochemRev(2007)6:277–305 the two pathways where at least one metabolite Lange and Croteau 1999). The second pathway can be exchanged. is mevalonate-independent (MEP pathway) and leads to the formation of monoterpenes, diterp- enes, tetraterpenes (carotenoids) and the prenyl Formation of IPP side chains of chlorophyll (Eisenreich et al. 1996, 1997; Arigoni et al. 1997; Rohmer 1999). The mevalonate pathway The discovery of the MEP pathway for iso- prenoid biosynthesis was reviewed by Rohmer The early steps in the isoprenoid pathway com- (1999), Lichtenthaler (1999), Rohdich et al. prise the enzymatic conversions involved in the (2001), Rodriguez-Concepcion and Boronat synthesis of IPP. The mevalonate pathway starts (2002) and Dubey et al. (2003). The pathway withthecouplingoftwomoleculesofacetyl-CoA was first discovered in studies of the biosynthesis toformacetoacetyl-CoA.Thisstepiscatalysedby of bacterial hopanoids that are similar to sterols the enzyme acetoacetyl-CoA thiolase (AACT). produced by eukaryotes and act as membrane Condensation of acetoacetyl-CoA with another stabilizers. As hopanoids are chemically stable molecule of acetyl-CoA to form 3-hydroxy-3- and easily isolated, they are very suited for methylglutaryl-CoA (HMG-COA), is catalysed labelling experiments using stable isotopes fol- by HMG-CoA synthase (HMGS). Reduction of lowed by NMR to determine the sites of incor- HMG-CoA by HMG-CoA reductase (HMGR) poration in the molecules. Through the labelling leads to the formation of mevalonate. Phosphor- experiments, it was thought to be trivial to ylation of mevalonate to 5-diphosphomevalonate identify the isoprenoid units resulting from the is catalysed by mevalonate kinase (MVAK) and mevalonic acid (MVA) route but, the pattern of 5-diphosphomevalonate kinase (MVAPK), then thelabelswascompletelydifferentanddidnotfit 5-diphosphomevalonate is decarboxylated by 5- the classical MVA pathway. diphosphomevalonate decarboxylase to IPP. Sprenger (1996), in his labelling experiments Isopentenyl diphosphate is considered as a on bacteria that utilize only hexoses, and espe- building block of isoprenoids. The isomerization cially glucose as a carbon source, determined the of IPP to form dimethylallyl diphosphate origin of isoprenic units of hopanoids as derived (DMAPP) is a key step in the biosynthesis of from glucose. The labelling pattern was in accor- isoprenoids. This step is catalysed by IPP isom- dancewithpyruvateasaprecursorofaC subunit 2 erase (E.C. 5.3.3.2; Ramos-Valdivia et al. 1997; and a triose phosphate derivative as precursor of Verpoorte et al. 1997). DMAPP is condensed a C subunit. 3 with one IPP in a head-to-tail fashion generating For the MEP pathway, the biosynthetic geranyl diphosphate(GPP), theprecursorforthe sequence leading to the formation of IPP in monoterpenes including iridoids such as secolog- plants is still not completely identified (Fig. 2). anin (Verpoorte et al. 1997; Contin 1999). The The complete pathway has been elucidated, coupling reaction is catalysed by a prenyltrans- including the late steps in bacteria (for review ferase while the enzymatic cyclization of GPP is see Rodriguez-Concepcion and Boronat 2002). catalysed by a monoterpene synthase, GPP syn- The initial step of the pathway involves a thase (Chappell 1995). condensation of pyruvate (C2 and C3) with D- glyceraldehyde 3-phosphate to yield 1-deoxy-D- Themevalonate-independentpathwayleading xylulose-5-phosphate (DXP). Chahed et al. to the formation of IPP (MEP pathway) (2000) isolated and characterized the cDNA (crdxs) encoding for 1-deoxy-D-xylulose-5-phos- The biosynthesis of IPP, the central precursor of phate synthase (DXS) from C. roseus. The all isoprenoids, proceeds via two separate path- enzyme that catalyses this reaction belongs to a ways in plants. The mevalonate pathway leads to familyoftransketolases.Inthesecondstepofthis the formation of triterpenes (sterols) and certain pathway,rearrangementandreductionofDXPto sesquiterpenes (Newman and Chappell 1999; MEPtakesplace.Theenzymecatalysingthisstep 123 PhytochemRev(2007)6:277–305 281 I. Mevalonate pathway II. MEP pathway O O O COOH SCoA + H OP OH acetyl CoA pyruvate glyceraldehyde 3-phsophate O acetoacetyl-CoA DXS CO thiolase SCoA 2 OH O O O OP SCoA OH acetoacetyl-CoA 1-deoxy-D-xylulose 5-phosphate O NADPH HMG-CoA DXR synthase SCoA NADP+ HO O HO SCoA OP COOH OH OH hydroxymethyl-glutaryl-CoA 2-C-methyl-D-erythritol 4-phosphate CTP HMG-CoA NADPH Mg2+ CMS NH2 reductase PPi N HO O HO O O N O O P O P O O OH OH OH OH OH COOH OHOH mevalonate 4-cytidyl diphospho-2C-methyl-D-erythritol ATP MVA kinase ATP CMK NH 2 ADP O N HO O HO P O O O N O OH O P O P O O OP OH OH OH OH COOH OHOH mevalonate phosphate 4-cytidyl diphospho-2C-methyl-D-erythritol 2-phosphate MVAP kinase ATP MCS CMP O OH HO O O O P O OP P P O OH COOH OH OH mevalonate diphosphate 2-C-methyl-D-erythritol 2,4-cyclodiphosphate MVAPP ATP O O decarboxylase O P O P OH OH OH OH 1-hydroxy-2-methyl 2(E) butenyl 4 diphosphate OP P IPP isomerase OP P IPP isomerase OP IPP DMAPP IPP Fig.2 ThebiosynthesisofIPPviamevalonatepathwayandMEPpathwaywithinvolvedenzymes 123 282 PhytochemRev(2007)6:277–305 is DXP reducto isomerase (DXR). Grolle et al. ring of loganin forms the secologanin (Fig. 3). (2000) cloned the gene encoding this enzyme Conversion of loganin to secologanin is of partic- from the bacterium Zymomonas mobilis. Veau ular interest, the enzyme catalysing this reaction et al. (2000) reported the cloning and expression is secologanin synthase (SLS). In C. roseus, of cDNAs encoding crdxr and crmecs (reducto Contin (1999) attempted to identify the enzyme isomerase and 2-C-methyl-D-erythritol-2,4-cyc- involved in bioconversion of loganin to secolog- lodiphosphate synthase) from C. roseus. The anin with no success. She reported that the IPPisformedfinallyinlowratefromisopentenyl conversion probably involves a cytochrome P450 monophosphate via a step catalysed by the enzyme. This enzyme was finally detected and enzymeisopentenylmonophosphatekinase.Con- characterized in a cell suspension culture of tin et al. (1998) proved that the terpenoid moiety Lonicera japonica (Yamamoto et al. 2000). It is of the TIAs, secologanin is not derived from the a membrane-associated enzyme belonging to the mevalonate pathway but instead from the MEP group of cytochrome P450 monooxygenases and pathway using a cell suspension culture of its reaction requires NADPH and oxygen. Irmler C. roseus. The late steps are not characterized et al. (2000) reported that the activities of yetinC.roseus.4-Cytidyldiphospho-2C-methyl- CYP72A1 from C. roseus expressed in E. coli D-erythritol synthase was first cloned from Ara- converts loganin into secologanin and confirmed bidopsis thaliana and expressed in Escherichia it as SLS. This enzyme was previously purified coli(Rohdichetal.2000).Althoughtherearefew from C. roseus by Mangold et al. (1994) and radiotracer studies in plants which demonstrated thought to have G10H activity but did not show the possible phophorylation role of 4-diphospho- any hydroxylase activity with 11 substrates for cytidyl-2-C-methyl-D-erythritol kinase (CMK) in cytochrome P450 reactions. the pathway, the complete enzymology and its molecular analysis is not available in a plant Characterized enzymes involved in the system. The gene encoding 2-C-methyl-D-erythr- biosyntheticpathwayleadingtotheformation itol 2,4-cyclodiphosphate synthase has been dem- of secologanin onstrated in Arabidopsis but the enzyme was not fully characterized. AACT (E.C. 2.3.1.9) and HMGS (E.C. 4.1.3.5) The iridoid pathway Both AACT and HMGS activities were found to be present in C. roseus by using an HPLC The first steps in the pathway leading to the method specially developed to determine HMG- formation of secologanin are the formation of CoA metabolizing enzyme activities. Using this geraniol followed by hydroxylation into 10- method, three HMG-CoA catabolizing activities hydroxylgeraniol, catalysed by the cytochrome were discovered in C. roseus suspension cultured P450enzymegeraniol10-hydroxylase(G10H).In cells in addition to HMGR (Van der Heijden the presence of NAD+ or NADP+, 10-hydroxy- et al. 1994). These enzymes are instable and geraniol is oxidized into 10-oxogeranial. The sensitive to high salt concentrations. AACT and enzyme responsible for this step is an oxido HMGS were partially purified from a cell reductase (Madyastha and Coscia 1979). 10- suspension culture of C. roseus (Van der Heijden Oxogeraniol is converted to iridodial by and Verpoorte 1995). cyclization. NADPH:cytochrome P450 reductase (CPR) is essential for the G10H catalysed reac- 3-Hydroxy-3-methylglutaryl-CoA reductase tion.Intheformationof7-deoxyloganicacidfrom (E.C. 1.1.1.34) iridodial, so far, no enzymes have been described (Contin 1999). Methylation of loganic acid to The HMG reductase has been purified from a form loganin is catalysed by S-adenosyl-L- number of species besides C. roseus and its methionine:loganic acid methyltransferase characteristics and regulation mechanisms have (LAMT).Finallythecleavageofthecyclopentane been the subject of extensive reviews (Chappell 123 PhytochemRev(2007)6:277–305 283 OH OH OH CHO CHO 10--hydroxy geranial G10H OH OHC CHO OH geraniol 10-hydroxy geraniol 10-oxogeraniol 10-oxogeranial cyclase CH3 HO CH3 CH3 H H H OGlc OGlc H H LAMT H O HOOC O CHO HOOC H loganic acid 7-deoxyloganic acid HO CH3 iridodial H OGlc CHO H O SLS H OGlc CH3OOC H O loganin CH3OOC secoloanin Fig.3 The biosynthesis of secologanin from geraniol. G10H geraniol 10-hydroxylase, LAMT loganic acid methyltrans- ferase,SLSsecologaninsynthase 1995; Bach 1995; Stermer et al. 1994; Verpoorte quite stable. It is strongly inhibited by farnesyl et al. 1997; Schulte 1998). Overexpression of the diphosphate. MVAK activity depends on the hmgr gene in C. roseus hairy roots resulted in an presence of the divalent ions, Mg2+ and Mn2+ increase in alkaloid levels. A clone with high which are effective in sustaining the activity. It hybridization signal produced more ajmalicine also has a broad pH optimum between 7 and and catharanthine than the control, whereas the 10withamaximumactivityaroundpH9(Schulte clone with low hybridization signal increased the et al. 2000). MVAPK from C. roseus was also productionofserpentineuptosevenfold(Ayora- purified and characterized (Schulte et al. 1999). Talavera et al. 2002). 5-Diphosphomevalonate decarboxylase (MVAPP MVAK(E.C.2.7.1.36)andMVAPK(E.C.2.7.4.2) decarboxylase, E.C. 4.1.1.33) The phosphorylation of MVA to the mono- and The MVAPP decarboxylase that forms IPP from di-phosphate ester (MVAP and MVAPP) has MVAPP has not yet been given much attention been extensively studied in C. roseus plants and and has only been characterized in a few plant cell cultures (Schulte 1998). MVAK from C. species (Verpoorte et al. 1997; Contin 1999). The roseus cell cultures was purified to homogeneity formation of IPP was reviewed by Ramos-Valdi- and characterized. The enzyme showed to be via et al. (1997). 123 284 PhytochemRev(2007)6:277–305 IPP isomerase (E.C. 5.3.3.2) fiedfromC.roseusplants(MadyasthaandCoscia 1979)andfromcellcultures(Meijeretal.1993b). Isopentenyl diphosphate isomerase was partially The protein showed a M of 79,000 and the r purified from C. roseus cultures (Ramos-Valdivia activityisdependentonNADPH,FADandFMN et al. 1998). IPP-isomerase activity was also ascofactors.InC.roseustheCPRmRNAlevelis determined in 5-day-old C. roseus suspension enhanced by fungal elicitor treatments (Meijer cultured cells, treated with Pythium aphanider- et al. 1993a, b, Lopes Cardoso et al.,1997). Like matum elicitor preparation. A slight inhibition of the yeast and animal CPRs, C. roseus protein the enzyme was observed during the first 120 h contains a hydrophobic domain close to the after elicitor treatment (Moreno et al. 1996). N-terminus which serves as a membrane anchor. Steady-state mRNA levels observed in C. roseus Geranyl diphosphate synthase (E.C. 5.1.1.1) plants were higher in flowers and much lower in leaves and stems while intermediate in the roots. The enzyme GPP synthase is not yetinvestigated in C. roseus (Contin 1999). Cyclase Geraniol 10-hydroxylase The dialdehyde (10-oxogeranial/10-oxoneral) is cyclized to iridodial. The enzyme responsible for This enzyme is a cytochrome P450 monooxygen- the cyclization has not yet been purified from C. ase dependent on NADPH. G10H is regarded as roseus but was obtained from Rauwolfia serpen- a potential site for regulatory control in the tina (Uesato et al. 1986, 1987; Verpoorte et al. biosynthesis of secologanin. Studies by Schiel 1997). etal.(1987)showedthatG10Hactivityisinduced when C. roseus cell cultures are transferred to an Loganic acid methyltransferase (E.C. 2.1.1.50) induction medium known to enhance alkaloid accumulationandthatthereisacloserelationship In the formation of 7-deoxyloganic acid from between G10H activity and alkaloid accumula- iridodial, so far no enzymes have been described tion. Also McFarlane et al. (1975) demonstrated (Contin 1999). The 7-hydroxylation to afford that G10H is feedback inhibited by the TIAs loganic acid must precede its methylation, as catharanthine, vinblastine and vindoline. The K suggested byenzymatic studies with the S-adeno- i ofcatharanthineinhibition(1 mM)isintherange syl-L-methionine:LAMT partially purified from of alkaloid concentration in C. roseus (0.3– C. roseus seedlings (Madyastha et al. 1973). This 1 mM). Madyastha et al. (1976) partially purified enzyme catalyses the transfer of a methyl group G10H from C. roseus seedlings. Meijer et al. to loganic acid to form loganin. Contin (1999) (1993a)purifiedG10H from C.roseus suspension measured the activity of LAMT in C.roseus cells cultured cells in a four-step procedure after cultured on three different media and found that solublization with cholate. The protein showed a the activity is restricted to the early period of M of 56,000 and a K of 5.5 lM geraniol and growth similarly to the results obtained by Guar- r m 11 lMnerol.Also,Colluetal.(2001)purifiedthis naccia et al. (1974) and Madyastha and Coscia enzymefrom C.roseus cell cultures followingthe (1979) in C. roseus seedlings where maximum method developed by Meijer et al. (1993a) with activity of the enzyme was recorded just after some modifications. germination. NADPH:cytochrome P450 reductase Secologanin synthase (E.C. 1.3.3.9) (E.C. 1.6.2.4) Secologanin synthase belongs also to the cyto- Cytochrome P450 reductase functions in electron chrome P450 family. This gene was cloned 12 transfer from NADPH and is essential for all years ago from C. roseus and was first thought to cytochrome P450 monooxygenases. It was puri- encode G10H (Vetter et al. 1992) but recently it 123 PhytochemRev(2007)6:277–305 285 was shown that it encodes the enzyme that 2-C-methyl-D-erythrose and the reduction of this converts loganin to secologanin (Irmler et al. aldose to MEP. The free aldose phosphate was 2000).ThiscytochromeP450enzymeacceptsonly notdetectedandthepresenceofthe5-phosphate loganin as substrate with an optimum catalysing group on DXP was required for the enzymatic reaction at a pH of 7.5 (Yamamoto et al. 2000). conversion. Enzymes involved in the MEP pathway Isopentenyl monophosphate kinase (E.C. 2.7.1.) leading to the formation of IPP LangeandCroteau(1999)reportedthecloningof 1-Deoxy-D-xylulose 5-phosphate synthase (E.C. the gene encoding IPK from peppermint and E. 4.1.3.37) coli. This kinase catalyses the phosphorylation of isopentenylmonophosphateasthelaststepofthe Bacteria, fungi, yeasts and plants are capable of biosynthetic sequence to IPP. This enzyme synthesizing 1-deoxy-D-xylulose (DX) or its belongstoaconservedclassoftheGHMPfamily 5-phosphate (DXP) from pyruvate and from of kinases that includes galactokinase, homoser- D-glyceraldehyde or from its phosphate (GAP). ine kinase, MVAK and phosphomevalonate The enzymatic activity in this step is thiamine kinase. This enzyme was thought to catalyse the diphosphate dependent and probably related to last step in the MEP pathway, however Rohdich pyruvate dehydrogenase. As the reaction is not etal.(2000)showedthattheoverexpressedCMK specific,thesystemcanacceptacyloinsinplaceof protein from tomato does not have any IPK pyruvate as acetyl donor and also different activity, even if very high concentrations of aldoses, yielding 1-deoxyketoses with C , C or 5 6 recombinant enzyme were used. The detected C skeletons. 7 IPK activity could not be metabolically relevant The enzyme catalyses the concomitant decar- and cannot confirm the final steps leading to IPP boxylation of pyruvate and the condensation of synthesis. the resulting (hydroxyethyl) thiamine on free GAP, yielding deoxyxylulose or its phosphate (DXP). As free glyceraldehyde is not a usual cellularmetabolite,GAPandDXParethoughtto Localization of the enzymes involved in the be the normal substrate and product of the pathwaysleadingto theformation ofsecologanin synthase. In the mevalonate pathway, the enzymes are 1-Deoxy-D-xylulose 5-phosphate reducto localizedinthecytosolandproducetheprecursor isomerase (E.C. 1.1.1.267) of triterpenes and sesquiterpenes. Nothing has been reported on the localization of AACT/ The rearrangement of DX or DXP yields 2-C- HMGS enzymes in C. roseus although they were methyl-D-erythrose or its 4-phosphate and the purified from a cell suspension cultures (Van der reduction of these products yields 2-C-methyl-D- Heijden et al. 1994; Van der Heijden and erythritol(ME)orits4-phosphate(MEP;Duvold Verpoorte 1995). The radish AACT and HMGS et al. 1997a,b, Sagner et al. 1998). have been reported as membrane-associated UsingE.colimutantsthatwereauxotrophicto enzymes (Weber and Bach 1994; Bach et al. ME, a gene that complemented in these mutants 1994). It has been suggested that HMGR might theregioncodingforIPPbiosynthesiswascloned be located in mitochondria and plastids of plants and led to the identification of the enzyme (Gary 1987; Stermer et al. 1994). The regulated responsible for the conversion of DXP into degradation of HMGR has been indicated to be MEP (Takahashi et al. 1998). This reducto- completely localized in the endoplasmic reticu- isomerase enzyme is NADPH-dependent and luminyeast(HamptonandRine1994).Evidence requires Mn2+ as cofactor. It catalyses two con- that HMGR is located within endoplasmic retic- secutive steps: the rearrangement of DXP into ulum as well as in spherical, vesicular structures 123 286 PhytochemRev(2007)6:277–305 derived from endoplasmic reticulum has been Localization of the non-mevalonate pathway recently given (Leivar et al. 2005). leading to the formation of IPP The plant enzymesMVAK andMVAPK were presumedtobepredominantlycytosolicbuthave Thebiosynthesisofmono-,di-andtetraterpenoids been proven to be present in plastids as well in plants seems to occur in plastids, where the (McKaskill and Croteau 1995; Albrecht and MEP pathway is localized (Rohmer 1999; Lange Sandmann 1994). The subcellular localization of and Croteau 1999).In plastids, theDXPpathway MVAK and MVAPK was studied in suspension operates to supply IPP for the synthesis of mon- cultured cells of C. roseus and it was shown that oterpenes, diterpenes and carotenoids. Table 1 most of the activity of both enzymes was located summarizes the information about the known in thecytosolic fraction. MVAK activity was also enzymesinvolvedinTIAbiosynthesisinC.roseus. recovered from an organellar and microsomal fraction. MVAPK activity was detected in the organelle fraction (Schulte et al. 1999, 2000). Genes-encoding enzymes involved in the The localization of IPP isomerase in C. roseus biosynthesis of secologanin has not been determined yet butin Castor beans, a mitochondrial and proplastidial IPP isomerase AcDNAcloneforradishAACThasbeencloned have been detected (Green et al. 1975). In by complementation in yeast (Vollack and Bach glandular trichomes of peppermint, it was found 1995). Using the radish cDNA as a probe to that the cytoplasmic MVA pathway was blocked screenanA.thalianacDNAlibrary,fourpositive at the level of HMGR and that the IPP utilized clones have been isolated of which three were for both plastidial monoterpene and cytosolic identical and the fourth shown to be an antisense sesquiterpene biosynthesis is synthesized exclu- (Pin˜as et al. 1997). The presence of antisense sivelyintheplastids.Aconnectionofthepathway mRNAcould indicate aregulatorymechanismof was proposed at the level of IPP that requires controlling translation of AACT mRNA. translocation of IPP to the different compart- A cDNA encoding the A. thaliana HMGS ments and the presence of an isoform of IPP has been cloned (Montamat et al. 1995) and isomerase in each compartment (McKaskill and expressedinE.coli(Diezetal.1997).Inaddition Croteau 1995). Ramos-Valdivia et al. (1997) to the A. thaliana HMGS gene, also the HMGS extensively reviewed the IPP isomerase. gene has been cloned from Schizosaccharomyces In Lithospermum erythrorhizon, the enzyme pombe (Katayama et al. 1995). GPP synthase involved in the biosynthesis of Plants have a small gene-family of HMGR naphthoquinones was found to be present in the isoenzymes that are differentially expressed and cytosol (Sommer et al. 1995). respond to a variety of developmental and envi- TheenzymeG10Hisassociatedwith(pro)vac- ronmental signals (Stermer et al. 1994; Enjuto uolar membranes (Madyastha et al. 1977) rather et al. 1994; Weissenborn et al. 1995; Korth et al. than with endoplasmic reticulum where many 1997). HMGR genes have been well studied in P450s are found (Nebert 1979). Collu (1999), Solanaceaespecies.FourHMGRgeneshavebeen studied the localization of G10H in C. roseus cell isolated from tomato. One of them, the hmg1 suspension cultures and confirmed that this gene has been found to be involved in aspects enzyme is localized in vacuolar membranes. The related to primary metabolism like sterol biosyn- CPRcatalysingcytochromeP450monooxygenase thesis and cell growth. The activation pattern of reactions is a membrane-bound flavoprotein, the second HMGR gene hmg2 by wounding and closelylinkedtotheP450protein.Theexpression elicitation has suggested a role in the plant’s of the three identified C. roseus MEP pathway defence (Weissenborn et al. 1995). Also potato, genes and the G10H genes was found to be in has at least three HMGR genes (Stermer et al. internalphloemparenchyma,i.e.incellsdifferent 1994). A C. roseus hmg cDNA has been cloned than the other known alkaloid biosynthesis (Maldonada-Mendosa et al. 1992). In C. roseus related genes (Burlat et al. 2004). cell suspensions, methyl jasmonate has been 123

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Abstract Catharanthus roseus is still the only source for the powerful antitumour drugs vin- blastine and vincristine. Some other pharmaceu- tical compounds from this plant, ajmalicine and serpentine are also of economical importance. Although C. roseus has been studied extensively and was subject
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