Isopentenyl diphosphate and dimethylallyl diphosphate/isopentenyl diphosphate ratio measured with recombinant isopentenyl diphosphate isomerase and isoprene synthase

Isopentenyl diphosphate (IDP) and its isomer dimethylallyl diphosphate (DMADP) are building units for all isoprenoids; thus, intracellular pool sizes of IDP and DMADP play important roles in living organisms. Several methods have been used to quantify the amount of DMADP or the combined amount of IDP plus DMADP, but measuring the DMADP/IDP ratio has been difficult. In this study, a method was developed to measure the ratio of DMADP/IDP. Catalyzed by a recombinant IDP isomerase (IDI) together with a recombinant isoprene synthase (IspS), IDP was converted to isoprene, which was then detected by chemiluminescence. With this method, the in vitro equilibrium ratio of DMADP/IDP was found to be 2.11:1. IDP and DMADP pools were significantly increased in Escherichia coli transformed with methylerythritol 4-phosphate pathway genes; the ratio of DMADP/IDP was 3.85. An E. coli strain transformed with IspS but no additional IDI had a lower DMADP level and a DMADP/IDP ratio of 1.05. Approximately 90% of the IDP and DMADP pools in light-adapted kudzu leaves were light dependent and so presumably were located in the chloroplasts; the DMADP/IDP ratios in chloroplasts and cytosol were the same as the in vitro ratio (2.04 in the light and 2.32 in the dark).     

Crystal structure of isopentenyl diphosphate:dimethylallyl diphosphate isomerase

Isopentenyl diphosphate:dimethylallyl diphosphate (IPP:DMAPP) isomerase catalyses a crucial activation step in the isoprenoid biosynthesis pathway. This enzyme is responsible for the isomerization of the carbon-carbon double bond of IPP to create the potent electrophile DMAPP. DMAPP then alkylates other molecules, including IPP, to initiate the extraordinary variety of isoprenoid compounds found in nature. The crystal structures of free and metal-bound Escherichia coli IPP isomerase reveal critical active site features underlying its catalytic mechanism. The enzyme requires one Mn(2+) or Mg(2+) ion to fold in its active conformation, forming a distorted octahedral metal coordination site composed of three histidines and two glutamates and located in the active site. Two critical residues, C67 and E116, face each other within the active site, close to the metal-binding site. The structures are compatible with a mechanism in which the cysteine initiates the reaction by protonating the carbon-carbon double bond, with the antarafacial rearrangement ultimately achieved by one of the glutamates involved in the metal coordination sphere. W161 may stabilize the highly reactive carbocation generated during the reaction through quadrupole- charge interaction.     

Isoprenyl diphosphate synthases

Isoprenyl diphosphate synthases catalyze consecutive condensations of isopentenyl diphosphates with allylic primer substrates to form linear backbones for all isoprenoid compounds including cholesterol. These synthases are classified according to the final chain length of their end products and the stereochemistry of the newly formed double bonds. Mutagenesis and X-ray crystallography data have uncovered the basic catalytic and chain length determination mechanisms of E-isoprenyl diphosphate synthases and shed light on their possible evolutionary course. Although much less is known about the Z-isoprenyl diphosphate synthase family, successful cloning and subsequent crystallizations in the near future will no doubt bring more insight as researchers begin to unravel the essential components and precise reaction mechanisms of this cellular machinery.     

Temperature-dependent modulation of farnesyl diphosphate/geranylgeranyl diphosphate synthase from hyperthermophilic archaea

Enzyme characteristics of trans-prenyl diphosphate synthase (Tk-IdsA) from Thermococcus kodakaraensis, which catalyzes the consecutive trans-condensation of isopentenyl diphosphate (C(5)) units with allylic diphosphate, were examined. Product analysis revealed that Tk-IdsA is a bifunctional enzyme, farnesyl diphosphate (FPP, C(15))/geranylgeranyl diphosphate (GGPP, C(20)) synthase, and mainly yields both C(15) and C(20). The FPP/GGPP product ratio increases with the rise of the reaction temperature. The kinetic parameters obtained at 70 and 90 degrees C demonstrated that the rise of the temperature elevates the k(0) value for the C(10) allylic substrate to more than those for the C(5) and C(15) allylic substrates. These data suggest that Tk-IdsA contributes to adjust the membrane composition to the cell growth temperature by modulating its substrate and product specificities. Mutation study indicated that the aromatic side chain of Tyr-81 acts as a steric hindrance to terminate the chain elongation and defines the final product length.     

Arabidopsis thaliana isoprenyl diphosphate synthases produce the C25 intermediate geranylfarnesyl diphosphate

Isoprenyl diphosphate synthases (IDSs) catalyze some of the most basic steps in terpene biosynthesis by producing the prenyl diphosphate precursors of each of the various terpenoid classes. Most plants investigated have distinct enzymes that produce the short‐chain all‐trans (E) prenyl diphosphates geranyl diphosphate (GDP, C₁₀), farnesyl diphosphate (FDP, C₁₅) or geranylgeranyl diphosphate (GGDP, C₂₀). In the genome of Arabidopsis thaliana, 15 trans‐product‐forming IDSs are present. Ten of these have recently been shown to produce GGDP by genetic complementation of a carotenoid pathway engineered into Escherichia coli. When verifying the product pattern of IDSs producing GGDP by a new LC‐MS/MS procedure, we found that five of these IDSs produce geranylfarnesyl diphosphate (GFDP, C₂₅) instead of GGDP as their major product in enzyme assays performed in vitro. Over‐expression of one of the GFDP synthases in A. thaliana confirmed the production of GFDP in vivo. Enzyme assays with A. thaliana protein extracts from roots but not other organs showed formation of GFDP. Furthermore, GFDP itself was detected in root extracts. Subcellular localization studies in leaves indicated that four of the GFDP synthases were targeted to the plastoglobules of the chloroplast and one was targeted to the mitochondria. Sequence comparison and mutational studies showed that the size of the R group of the 5th amino acid residue N‐terminal to the first aspartate‐rich motif is responsible for C₂₅ versus C₂₀ product formation, with smaller R groups (Ala and Ser) resulting in GGDP (C₂₀) as a product and a larger R group (Met) resulting in GFDP (C₂₅).     

Inhibition of monoterpene cyclases by inert analogues of geranyl diphosphate and linalyl diphosphate

The tightly coupled nature of the reaction sequence catalyzed by monoterpene synthases has prevented direct observation of the topologically required isomerization step leading from geranyl diphosphate to the enzyme-bound, tertiary allylic intermediate linalyl diphosphate, which then cyclizes to the various monoterpene skeletons. X-ray crystal structures of these enzymes complexed with suitable analogues of the substrate and intermediate could provide a clearer view of this universal, but cryptic, step of monoterpenoid cyclase catalysis. Toward this end, the functionally inert analogues 2-fluorogeranyl diphosphate, (±)-2-fluorolinalyl diphosphate, and (3R)- and (3S)-homolinalyl diphosphates (2,6-dimethyl-2-vinyl-5-heptenyl diphosphates) were prepared, and compared to the previously described substrate analogue 3-azageranyl diphosphate (3-aza-2,3-dihydrogeranyl diphosphate) as inhibitors and potential crystallization aids with two representative monoterpenoid cyclases, (-)-limonene synthase and (+)-bornyl diphosphate synthase. Although these enantioselective synthases readily distinguished between (3R)- and (3S)-homolinalyl diphosphates, both of which were more effective inhibitors than was 3-azageranyl diphosphate, the fluorinated analogues proved to be the most potent competitive inhibitors and have recently yielded informative liganded structures with limonene synthase.     

Interactions of urdine diphosphate glucose dehydrogenase with the inhibitor urdine diphosphate xylose.

1. UDP-xylose and UDP-glucose both bind to UDP-glucose dehydrogenase in the absence of NAD+, causing an enhancement of protein fluorescence. 2. The binding of UDP-xylose is pH-dependent, tighter binding being observed at pH8.2 than at pH8.7. 3. At low protein concentrations sigmiodal profiles of fluorescence enhancement are obtained on titration of the enzyme with UDP-xylose. As the protein concentration is increased the titration profiles become progressively more hypebolic in shape. 4. The markedly different titration profiles obtained on titrating enzyme and the enzyme-NAD+ complex with UDP-xylose suggests a conformational difference between these two species 5. NAD+ lowere the apparent affinity of the enzyme for UDP-xylose. 6. There is no change in the apparent moleculare weight of UDP-glucose dehydrogenase on binging UDP-xylose. 7. Protein modification by either diethyl pyrocarbonate or 5, 5'-dithiobis-(2-nitrobenzoate) does not "desensitize" the enzyme with respect to the inhibition by UDP-xylose. 8. UDP-xylose lowers the affinity of the enzyme for NADG. 9. It is suggested that UDP-xylose is acting as a substrate analogue of UDP-glucose and causes protein-conformational changes on binding to the enzyme.