Modeling studies with Helicobacter pylori octaprenyl pyrophosphate synthase reveal the enzymatic mechanism of trans-prenyltransferases

Octaprenyl pyrophosphate synthase (OPPs), an enzyme belonging to the trans-prenyltransferases family, is involved in the synthesis of C40 octaprenyl pyrophosphate (OPP) by reacting farnesyl pyrophosphate (FPP) with five isopentenyl pyrophosphates (IPP). It has been reported that OPPs is essential for bacteria's normal growth and is a potential target for novel antibacterial drug design. Here we report the crystal structure of OPPs from Helicobacter pylori, determined by MAD method at 2.8 Å resolution and refined to 2.0 Å resolution. The substrate IPP was docked into HpOPPs structure and residues involved in IPP recognition were identified. The other substrate FPP, the intermediate GGPP and a nitrogen-containing bisphosphonate drug were also modeled into the structure. The resulting model shed some lights on the enzymatic mechanism, including (1) residues Arg87, Lys36 and Arg39 are essential for IPP binding; (2) residues Lys162, Lys224 and Gln197 are involved in FPP binding; (3) the second DDXXD motif may involve in FPP binding by Mg²⁺ mediated interactions; (4) Leu127 is probably involved in product chain length determination in HpOPPs and (5) the intermediate products such as GGPP need a rearrange to occupy the binding site of FPP and then IPP is reloaded. Our results also indicate that the nitrogen-containing bisphosphonate drugs are potential inhibitors of FPPs and other trans-prenyltransferases aiming at blocking the binding of FPP.     

Crystal structure of octaprenyl pyrophosphate synthase from hyperthermophilic Thermotoga maritima and mechanism of product chain length determination

Octaprenyl pyrophosphate synthase (OPPs) catalyzes consecutive condensation reactions of farnesyl pyrophosphate (FPP) with isopentenyl pyrophosphate (IPP) to generate C40 octaprenyl pyrophosphate (OPP), which constitutes the side chain of bacterial ubiquinone or menaquinone. In this study, the first structure of long chain C40-OPPs from Thermotoga maritima has been determined to 2.28-A resolution. OPPs is composed entirely of alpha-helices joined by connecting loops and is arranged with nine core helices around a large central cavity. An elongated hydrophobic tunnel between D and F alpha-helices contains two DDXXD motifs on the top for substrate binding and is occupied at the bottom with two large residues Phe-52 and Phe-132. The products of the mutant F132A OPPs are predominantly C50, longer than the C40 synthesized by the wild-type and F52A mutant OPPs, suggesting that Phe-132 is the key residue for determining the product chain length. Ala-76 and Ser-77 located close to the FPP binding site and Val-73 positioned further down the tunnel were individually mutated to larger amino acids. A76Y and S77F mainly produce C20 indicating that the mutated large residues in the vicinity of the FPP site limit the substrate chain elongation. Ala-76 is the fifth amino acid upstream from the first DDXXD motif on helix D of OPPs, and its corresponding amino acid in FPPs is Tyr. In contrast, V73Y mutation led to additional accumulation of C30 intermediate. The new structure of the trans-type OPPs, together with the recently determined cis-type UPPs, significantly extends our understanding on the biosynthesis of long chain polyprenyl molecules.     

Rubber elongation by farnesyl pyrophosphate synthases involves a novel switch in enzyme stereospecificity

A prenyltransferase purified from the commercial rubber tree, Hevea brasiliensis, that elongates existing cis-polyisoprene rubber molecules also catalyzes the formation of all trans-farnesyl pyrophosphate (t,t-FPP) from dimethylallyl pyrophosphate (DMAPP) and isopentenyl pyrophosphate (IPP). In assays of the latter activity trans-geranyl pyrophosphate is the only other product identified. In contrast to this limited addition of IPP to DMAPP, we measured 7000 additions of isoprene per rubber molecule in a previous titration of active allylic ends of rubber molecules by purified prenyltransferase (Light, D. R., and Dennis, M. S. (1989) J. Biol. Chem. 264, 18589-18597). In order to confirm that purified prenyltransferase extensively elongates rubber molecules, doubly labeled [1-14C]isopentenyl [U-32P]pyrophosphate ([14C,32P]IPP) was synthesized. Using this reagent we show that both prenyltransferase purified from H. brasiliensis and prenyltransferase purified from avian liver (FPP synthase) add greater than 15 isoprene units to existing rubber molecules, consistent with the previous titration data. For confirmation that the prenyltransferase purified from H. brasiliensis adds isoprene units to rubber to make cis-polyisoprene, chirally tritiated [14C]IPP ([14C,2S-3H]IPP) was synthesized. Retention of the tritium label in FPP synthesized from [14C,2S-3H]IPP and DMAPP, geranyl pyrophosphate, or neryl pyrophosphate by prenyltransferase from H. brasiliensis or avian liver confirms trans addition to these substrates. In contrast, when [14C,2S-3H]IPP is incubated with serum-free rubber particles and prenyltransferase purified from H. brasiliensis, avian liver, or yeast, no tritium is incorporated into the rubber particles indicating cis addition. Thus, rubber particles have the ability to alter the stereoselective removal of the 2R-prochiral proton in favor of the removal of the 2S-prochiral proton. This apparent inversion of carbon 2 of IPP during the proton abstraction step by rubber particles represents a novel example of a switch in enzyme stereospecificity. In addition to being enzymatically similar to other prenyltransferases, rubber transferase also appears to be related immunologically to FPP synthases, since polyclonal antibodies to the H. brasiliensis prenyltransferase cross-react with the purified yeast prenyltransferase. In order to investigate potential primers of greater molecular weight than that of FPP, cis-undecaprenyl pyrophosphate (C55PP) was synthesized. C55PP stimulates the incorporation of [14C]IPP into rubber particles suggesting that it may prime new rubber molecules. However, in contrast to DMAPP, C55PP is not incorporated into any detectable products when incubated with prenyltransferase and [14C]IPP in the absence of rubber particles.(ABSTRACT TRUNCATED AT 400 WORDS)     

Reaction kinetic pathway of the recombinant octaprenyl pyrophosphate synthase from Thermotoga maritima: how is it different from that of the mesophilic enzyme

Octaprenyl pyrophosphate synthase (OPPs) catalyzes the chain elongation of farnesyl pyrophosphate (FPP) via consecutive condensation reactions with five molecules of isopentenyl pyrophosphate (IPP) to generate all-trans C40-octaprenyl pyrophosphate. The polymer forms the side chain of ubiquinone that is involved in electron transport system to produce ATP. Our previous study has demonstrated that Escherichia coli OPPs catalyzes IPP condensation with a rate of 2 s(-1) but product release limits the steady-state rate at 0.02 s(-1) [Biochim. Biophys. Acta 1594 (2002) 64]. In the present studies, a putative gene encoding for OPPs from Thermotoga maritima, an anaerobic and thermophilic bacterium, was expressed, purified, and its kinetic pathway was determined. The enzyme activity at 25 degrees C was 0.005 s(-1) under steady-state condition and was exponentially increased with elevated temperature. In contrast to E. coli OPPs, IPP condensation rather than product release was rate limiting in enzyme reaction. The product of chain elongation catalyzed by T. maritima OPPs was C40 and the rate of its conversion to C45 was negligible. Under single-turnover condition with 10 microM OPPs-FPP complex and 1 microM IPP, only the C20 was formed rather than C20-C40 observed for E. coli enzyme. Together, our data suggest that the thermophilic OPPs from T. maritima has lower enzyme activity at 25 degrees C, higher product specificity, higher thermal stability and lower structural flexibility than its mesophilic counterpart from E. coli.     

Different reaction mechanisms for cis- and trans-prenyltransferases

Octaprenyl diphosphate synthase (OPPs) and undecaprenyl diphosphate synthases (UPPs) catalyze consecutive condensation reactions of farnesyl diphosphate (FPP) with 5 and 8 isopentenyl diphosphate (IPP) to generate C₄₀ and C₅₅ products with trans- and cis-double bonds, respectively. In this study, we used IPP analogue, 3-bromo-3-butenyl diphosphate (Br-IPP), in conjunction with radiolabeled FPP, to probe the reaction mechanisms of the two prenyltransferases. Using this alternative substrate with electron-withdrawing bromo group at the C3 position to slow down the condensation step, trapping of farnesol in the OPPs reaction from radiolabeled FPP under basic condition was observed, consistent with a sequential mechanism. In contrast, UPPs reaction yielded no farnesyl carbocation intermediate under the same condition with radiolabeled FPP and Br-IPP, indicating a concerted mechanism. Our data demonstrate the different reaction mechanisms for cis- and tran-prenyltransferases although they share the same substrates.     

Undecaprenyl diphosphate synthase,a cis-prenyltransferase synthesizing lipid carrier for bacterial cell wall biosynthesis

Abstract

A group of prenyltransferases produce linear lipids by catalyzing consecutive condensation reactions of farnesyl diphosphate (FPP) with specific numbers of isopentenyl diphosphate (IPP), a common building block of isoprenoid compounds. Depending on the stereochemistry of the double bonds formed during IPP condensation, these prenyltransferases are categorized as cis- and trans-types. Undecaprenyl diphosphate synthase (UPPS) that catalyzes chain elongation of FPP by consecutive condensation reactions with eight IPP, to form C₅₅ lipid carrier for bacterial cell wall biosynthesis, serves as a model for understanding cis-prenyltransferases. In this review, the current knowledge in UPPS kinetics, mechanisms, structures, and inhibitors is summarized.     

Discovery and structural characterization of an allosteric inhibitor of bacterial cis‐prenyltransferase

Undecaprenyl pyrophosphate synthase (UPPs) is an essential enzyme in a key bacterial cell wall synthesis pathway. It catalyzes the consecutive condensations of isopentenyl pyrophosphate (IPP) groups on to a trans-farnesyl pyrophosphate (FPP) to produce a C55 isoprenoid, undecaprenyl pyrophosphate (UPP). Here we report the discovery and co-crystal structures of a drug-like UPPs inhibitor in complex with Streptococcus pneumoniae UPPs, with and without substrate FPP, at resolutions of 2.2 and 2.1 Å, respectively. The UPPs inhibitor has a low molecular weight (355 Da), but displays potent inhibition of UPP synthesis in vitro (IC₅₀ 50 nM) that translates into excellent whole cell antimicrobial activity against pathogenic strains of Streptococcal species (MIC₉₀ 0.4 µg mL⁻¹). Interestingly, the inhibitor does not compete with the substrates but rather binds at a site adjacent to the FPP binding site and interacts with the tail of the substrate. Based on the structures, an allosteric inhibition mechanism of UPPs is proposed for this inhibitor. This inhibition mechanism is supported by biochemical and biophysical experiments, and provides a basis for the development of novel antibiotics targeting Streptococcus pneumoniae.     

A molecular ruler for chain elongation catalyzed by octaprenyl pyrophosphate synthase and its structure-based engineering to produce unprecedented long chain trans-prenyl products

Octaprenyl pyrophosphate synthase (OPPs) catalyzes consecutive condensation reactions of farnesyl pyrophosphate (FPP) with five molecules of isopentenyl pyrophosphate (IPP) to generate C(40) octaprenyl pyrophosphate (OPP) which constitutes the side chain of menaquinone. We have previously reported the X-ray structure of OPPs from Thermotoga maritima, which is composed entirely of alpha-helices joined by connecting loops and is arranged with nine core helices around a large central cavity [Guo, R. T., Kuo, C. J., Ko, T. P., Chou, C. C., Shr, R. L., Liang, P. H., and Wang, A. H.-J. (2004) J. Biol. Chem. 279, 4903-4912]. A76 and S77 are located on top of the active site close to where FPP is bound. A76Y and A76Y/S77F OPPs mutants produce C(20), indicating that the substituted larger residues interfere with the substrate chain elongation. Surprisingly, the A76Y/S77F mutant synthesizes a larger amount of C(20) than the A76Y mutant. In the crystal structure of the A76Y/S77F mutant, F77 is pushed away by Y76, thereby creating more space between those two large amino acids to accommodate the C(20) product. A large F132 residue at the bottom of the tunnel-shaped active site serves as the "floor" and determines the final product chain length. The substitution of F132 with a small Ala, thereby removing the blockade, led to the synthesis of a C(50) product larger than that produced by the wild-type enzyme. On the basis of the structure, we have sequentially mutated the large amino acids, including F132, L128, I123, and D62, to Ala underneath the tunnel. The products of the F132A/L128A/I123A/D62A mutant reach C(95), beyond the largest chain length generated by all known trans-prenyltransferases. Further modifications of the enzyme reaction conditions, including new IPP derivatives, may allow the preparation of high-molecular weight polyprenyl products resembling the rubber molecule.     

Mechanism of cis-prenyltransferase reaction probed by substrate analogues

Undecaprenyl pyrophosphate synthase (UPPS) is a cis-type prenyltransferases which catalyzes condensation reactions of farnesyl diphosphate (FPP) with eight isopentenyl pyrophosphate (IPP) units to generate C₅₅ product. In this study, we used two analogues of FPP, 2-fluoro-FPP and [1,1-²H₂]FPP, to probe the reaction mechanism of Escherichia coli UPPS. The reaction rate of 2-fluoro-FPP with IPP under single-turnover condition is similar to that of FPP, consistent with the mechanism without forming a farnesyl carbocation intermediate. Moreover, the deuterium secondary KIE of 0.985 ± 0.022 measured for UPPS reaction using [1,1-²H₂]FPP supports the associative transition state. Unlike the sequential mechanism used by trans-prenyltransferases, our data demonstrate E. coli UPPS utilizes the concerted mechanism.     

Farnesol production from Escherichia coli by harnessing the exogenous mevalonate pathway

Farnesol (FOH) production has been carried out in metabolically engineered Escherichia coli. FOH is formed through the depyrophosphorylation of farnesyl pyrophosphate (FPP), which is synthesized from isopentenyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP) by FPP synthase. In order to increase FPP synthesis, E. coli was metabolically engineered to overexpress ispA and to utilize the foreign mevalonate (MVA) pathway for the efficient synthesis of IPP and DMAPP. Two‐phase culture using a decane overlay of the culture broth was applied to reduce volatile loss of FOH produced during culture and to extract FOH from the culture broth. A FOH production of 135.5 mg/L was obtained from the recombinant E. coli harboring the pTispA and pSNA plasmids for ispA overexpression and MVA pathway utilization, respectively. It is interesting to observe that a large amount of FOH could be produced from E. coli without FOH synthase by the augmentation of FPP synthesis. Introduction of the exogenous MVA pathway enabled the dramatic production of FOH by E. coli while no detectable FOH production was observed in the endogenous MEP pathway‐only control. Biotechnol. Bioeng. 2010;107: 421–429. © 2010 Wiley Periodicals, Inc.     

Probing the conformational change of Escherichia coli undecaprenyl pyrophosphate synthase during catalysis using an inhibitor and tryptophan mutants.

Undecaprenyl pyrophosphate synthase (UPPS) catalyzes the consecutive condensation reactions of eight isopentenyl pyrophosphate (IPP) with farnesyl pyrophosphate (FPP) to generate C(55) undecaprenyl pyrophosphate (UPP). In the present study, site-directed mutagenesis, fluorescence quenching, and stopped-flow methods were utilized to examine the substrate binding and the protein conformational change. (S)-Farnesyl thiopyrophosphate (FsPP), a FPP analogue, was synthesized to probe the enzyme inhibition and events associated with the protein fluorescence change. This compound with a much less labile thiopyrophosphate shows K(i) value of 0.2 microm in the inhibition of Escherichia coli UPPS and serves as a poor substrate, with the k(cat) value (3.1 x 10(-7) s(-1)) 10(7) times smaller than using FPP as the substrate. Reduction of protein intrinsic fluorescence was observed upon addition of FPP (or FsPP) to the UPPS solution. Moreover, fluorescence studies carried out using W91F and other mutant UPPS with Trp replaced by Phe indicate that FPP binding mainly quenches the fluorescence of Trp-91, a residue in the alpha3 helix that moves toward the active site during substrate binding. Using stopped-flow apparatus, a three-phase protein fluorescence change with time was observed by mixing the E.FPP complex with IPP in the presence of Mg(2+). However, during the binding of E.FsPP with IPP, only the fastest phase was observed. These results suggest that the first phase is due to the IPP binding to E.FPP complex, and the other two slow phases are originated from the protein conformational change. The two slow phases coincide with the time course of FPP chain elongation from C(15) to C(55) and product release.     

Fluorescent substrate analog for monitoring chain elongation by undecaprenyl pyrophosphate synthase in real time

Farnesyl pyrophosphate (FPP) is a common substrate for a variety of prenyltransferases for synthesizing isoprenoid compounds. In this study, (2E,6E)-8-O-(N-methyl-2-aminobenzoyl)-3,7-dimethyl-2,6-octandien-1-pyrophosphate (MANT-O-GPP), a fluorescent analog of FPP, was synthesized and demonstrated as a satisfactory substrate for Escherichia coli undecaprenyl pyrophosphate synthase (UPPS) with a K_m of 1.5 μM and a k_cat of 1.2 s⁻¹ based on [¹⁴C]IPP consumption. Interesting, we found that its emission fluorescence intensity at 420 nm increased remarkably during chain elongation, thereby useful for real-time monitoring kinetics of UPPS to yield a K_m of 1.1 μM and a k_cat of 1.0 s⁻¹, consistent with those measured using radiolabeled substrate. Using this assay, the IC₅₀ of a known UPPS inhibitor farnesyl thiopyrophosphate (FsPP) was confirmed. Our studies provide a convenient and environmentally friendly alternative for kinetics and inhibition studies on UPPS drug target.     

Insight into the activation mechanism of Escherichia coli octaprenyl pyrophosphate synthase derived from pre-steady-state kinetic analysis

Octaprenyl pyrophosphate synthase (OPPs) catalyzes the sequential condensation of five molecules of isopentenyl pyrophosphate with farnesyl pyrophosphate to generate all-trans C40-octaprenyl pyrophosphate, which constitutes the side chain of ubiquinone. Due to the slow product release, a long-chain polyprenyl pyrophosphate synthase often requires detergent or another factor for optimal activity. Our previous studies in examining the activity enhancement of Escherichia coli undecaprenyl pyrophosphate synthase have demonstrated a switch of the rate-determining step from product release to isopentenyl pyrophosphate (IPP) condensation reaction in the presence of Triton [12]. In order to understand the mechanism of enzyme activation for E. coli OPPs, a single-turnover reaction was performed and the measured IPP condensation rate (2 s(-1)) was 100 times larger than the steady-state rate (0.02 s(-1)). The high molecular weight fractions and Triton could accelerate the steady-state rate by 3-fold (0.06 s(-1)) but insufficient to cause full activation (100-fold). A burst product formation was observed in enzyme multiple turnovers indicating a slow product release.     

Substrate binding mode and reaction mechanism of undecaprenyl pyrophosphate synthase deduced from crystallographic studies

Undecaprenyl pyrophosphate synthase (UPPs) catalyzes eight consecutive condensation reactions of farnesyl pyrophosphate (FPP) with isopentenyl pyrophosphate (IPP) to form a 55-carbon long-chain product. We previously reported the crystal structure of the apo-enzyme from Escherichia coli and the structure of UPPs in complex with sulfate ions (resembling pyrophosphate of substrate), Mg(2+), and two Triton molecules (product-like). In the present study, FPP substrate was soaked into the UPPs crystals, and the complex structure was solved. Based on the crystal structure, the pyrophosphate head group of FPP is bound to the backbone NHs of Gly29 and Arg30 as well as the side chains of Asn28, Arg30, and Arg39 through hydrogen bonds. His43 is close to the C2 carbon of FPP and may stabilize the farnesyl cation intermediate during catalysis. The hydrocarbon moiety of FPP is bound with hydrophobic amino acids including Leu85, Leu88, and Phe89, located on the alpha3 helix. The binding mode of FPP in cis-type UPPs is apparently different from that of trans-type and many other prenyltransferases which utilize Asprich motifs for substrate binding via Mg(2+). The new structure provides a plausible mechanism for the catalysis of UPPs.     

Structures,mechanisms and inhibitors of undecaprenyl diphosphate synthase: A cis-prenyltransferase for bacterial peptidoglycan biosynthesis

Isoprenoids are an intensive group of compounds made from isopentenyl diphosphate (IPP), catalyzed by prenyltransferases such as farnesyl diphosphate (FPP) cyclases, squalene synthase, protein farnesyltransferases and geranylgeranyltransferases, aromatic prenyltransferases as well as a group of prenyltransferases (cis- and trans-types) catalyzing consecutive condensation reactions of FPP with specific numbers of IPP to generate linear products with designate chain lengths. These prenyltransferases play significant biological functions and some of them are drug targets. In this review, structures, mechanisms, and inhibitors of a cis-prenyltransferase, undecaprenyl diphosphate synthase (UPPS) that mediates bacterial peptidoglycan biosynthesis, are summarized for comparison with the most related trans-prenyltransferases and other prenyltransferases.     

Structure, mechanism and function of prenyltransferases.

In this review, we summarize recent progress in studying three main classes of prenyltransferases: (a) isoprenyl pyrophosphate synthases (IPPSs), which catalyze chain elongation of allylic pyrophosphate substrates via consecutive condensation reactions with isopentenyl pyrophosphate (IPP) to generate linear polymers with defined chain lengths; (b) protein prenyltransferases, which catalyze the transfer of an isoprenyl pyrophosphate (e.g. farnesyl pyrophosphate) to a protein or a peptide; (c) prenyltransferases, which catalyze the cyclization of isoprenyl pyrophosphates. The prenyltransferase products are widely distributed in nature and serve a variety of important biological functions. The catalytic mechanism deduced from the 3D structure and other biochemical studies of these prenyltransferases as well as how the protein functions are related to their reaction mechanism and structure are discussed. In the IPPS reaction, we focus on the mechanism that controls product chain length and the reaction kinetics of IPP condensation in the cis-type and trans-type enzymes. For protein prenyltransferases, the structures of Ras farnesyltransferase and Rab geranylgeranyltransferase are used to elucidate the reaction mechanism of this group of enzymes. For the enzymes involved in cyclic terpene biosynthesis, the structures and mechanisms of squalene cyclase, 5-epi-aristolochene synthase, pentalenene synthase, and trichodiene synthase are summarized.     

Molecular cloning and expression of Chimonanthus praecox farnesyl pyrophosphate synthase gene and its possible involvement in the biosynthesis of floral volatile sesquiterpenoids

Farnesyl pyrophosphate (FPP) synthase catalyzes the biosynthesis of FPP, which is the precursors of sesquiterpenoids such as floral scent volatiles, from isopentenyl pyrophosphate (IPP) and dimethylallyl pyrophosphate (DMAPP). cDNA encoding wintersweet (Chimonanthus praecox L.) FPP synthase was isolated by the RT-PCR and RACE methods. The deduced amino acid sequence showed a high identity to plant FPP synthases. Expression of the gene in Escherichia coli yielded FPPS activity that catalyzed the synthesis of FPP as a main product. Tissue-specific and developmental analyses of the mRNA levels of CpFPPS and volatile sesquiterpenoids levels in C. praecox flowers revealed that the FPPS may play a regulatory role in floral volatile sesquiterpenoids of wintersweet.     

Prenyl transferases from Micrococcus luteus: Characterization of undecaprenyl pyrophosphate synthetase

Three prenyl transferases in Micrococcus luteus were recovered in the soluble fraction following cell disruption. Undecaprenyl pyrophosphate (C₅₅-PP) synthetase chromatographed on DEAE-cellulose independently from geranylgeranyl-PP and octaprenyl-PP synthetases. Further purification of C₅₅-PP synthetase resulted in an approximate 250-fold purification over the crude lysate. The molecular weight of the synthetase was estimated to be between 47,000 and 49,000 by Sephadex G-100 chromatography. The enzyme had a broad specificity toward the allylic pyrophosphate substrate. The reactivities of the allylic substrates increased with chain length, C₁₀ < C₁₅ < C₂₀, except for trans-solanesyl-PP, which was unreactive. Moreover, the enzyme was active on allylic substrates having both cis- and trans-stereochemistry. Although C₅₅-PP and C₅₀-PP were the major products, some shorter chain products were also produced, when t,t-farnesyl pyrophosphate and Δ³sopentenyl pyrophosphate (IPP) were used as substrates. The stereochemistries of the products formed with C₅₅-PP synthetase were established, using [¹⁴C]IPP and 2R-[2-³H] and 2S-[2-³H]IPP. Each new isoprene unit added had a cis-configuration. The enzyme was inactive in the absence of added effectors. It was stimulated by Triton X-100, egg lecithin, and a whole phospholipid extract from M. luteus. Cardiolipin and deoxycholate were poor activators of the enzyme. The product chain length distribution observed with the phospholipid-activated enzyme showed highly favored production of the C₅₅-PP product over the C₅₀-PP product.     

Formation of terpenoid products in Ginkgo biloba L. cultivated cells

Ginkgolides are diterpenes arising from the terpenoid precursor: geranylgeranyl pyrophosphate (GGPP). Incorporation of [1-¹⁴C] isopentenylpyrophosphate ([1-¹⁴C]IPP) into GGPP was monitored throughout the cultivation cycle of G. biloba L. cultivated cells. Because incorporation of [1-¹⁴C]IPP into GGPP had never been monitored in G. biloba, in either the whole plant or cultivated cell system, modifications to existing protocols were necessary. Modifications consisted of extracting the cells with an extraction buffer supplemented with Triton-X-100. Farnesylpyrophosphate (FPP) was the major product formed. The amount of GGPP detected was about one tenth that of FPP.Abbreviations CHAPS 3-[(3-cholamidopropyl) dimethyl ammonio]-1-propane-sulphonate - DTT [1-4 dithiothreitol] - FPP farnesylpyrophosphate - GGPP geranylgeranylpyrophosphate - IPP [1-¹⁴C] isopentenylpyrophosphate - PVPP polyvinylpolypyrrolidone - Tris Tris(hydroxymethyl)aminomethane     

Product distribution and pre-steady-state kinetic analysis of Escherichia coli undecaprenyl pyrophosphate synthase reaction

Undecaprenyl pyrophosphate synthase (UPPs) catalyzes the condensation of eight molecules of isopentenyl pyrophosphate (IPP) with farnesyl pyrophosphate (FPP) to generate C(55) undecaprenyl pyrophosphate. We investigated the kinetics and mechanism of this reaction pathway using Escherichia coli UPPs. With a variety of different ratios of enzyme to substrate and FPP to IPP in the presence or absence of Triton, different product distributions were found. In the presence of excess FPP, the intermediates (C(25)-C(50)) accumulated. Under a condition with enzyme and FPP in excess of IPP, instead of C(20)-geranylgeranyl pyrophosphate, C(20), C(25), and C(30) were the major products. The UPPs steady-state k(cat) value (2.5 s(-1)) in the presence of 0.1% Triton was 190-fold larger than in the absence of Triton (0.013 s(-1)). The k(cat) value matched the rate constant of each IPP condensation obtained from the enzyme single-turnover experiments. This suggested that the IPP condensation rather than product release was the rate-limiting step in the presence of Triton. In the absence of Triton, the intermediates formed and disappeared in a similar manner under enzyme single turnover in contrast to the slow steady-state rate, which indicated a step after product generation was rate limiting. This was further supported by a burst product formation. Judging from the accumulation level of C(55), C(60), and C(65), their dissociation from the enzyme cannot be too slow and an even slower enzyme conformational change with a rate of 0.001 s(-1) might govern the UPPs reaction rate under the steady-state condition in the absence of Triton.