Farnesyl Diphosphate Synthase. A Paradigm for Understanding Structure and Function Relationships in E-polyprenyl Diphosphate Synthases

The chain elongation reaction catalyzed by polyprenyl diphosphate synthases is the fundamental building reaction in the isoprenoid pathway. During chain elongation, the hydrocarbon moiety in an allylic isoprenoid diphosphate is added to the carbon–carbon double bond of isopentenyl diphosphate (IPP). The chain elongation enzymes can be divided into two genetically different families depending on whether the stereochemistry of the newly formed double bond during each cycle of chain elongation is E or Z. Farnesyl diphosphate (FPP) synthase, a member of the E-double bond family, is the best studied of the chain elongation enzymes and serves as a paradigm for understanding the reactions catalyzed by E-polyprenyl diphosphate synthases. The mechanism for chain elongation is a stereoselective electrophilic alkylation of the carbon–carbon double bond in IPP by the allylic substrate. X-ray structures of avian and E. coli FPP synthases have provided important insights about the mechanism for chain elongation and a structural basis for understanding the stereochemistry of the reaction.This review is dedicated to Professor Rodney Croteau on the occasion of his 60th birthday.     

青钱柳法呢基焦磷酸合成酶基因的克隆及功能研究

青钱柳是集药用、材用和观赏等多种价值于一身的珍贵树种。法呢基焦磷酸合成酶(FPS)催化=牛儿基焦磷酸(GPP)与异戊烯基焦磷酸(IPP)缩合成法呢基焦磷酸(FPP),FPP是植物次生代谢产物倍半萜,三萜,甾醇等的前体。本研究通过RACE方法首次从青钱柳中扩增了法呢基焦磷酸合成酶的全长cDNA序列,序列命名为CpF-PS(Genbank登录号为GU121224),序列长度为1 420 bp,包含1 029 bp的开放阅读框,编码342个氨基酸残基,预测蛋白分子量为39.60 kDa。通过BlASTP分析,推断的青钱柳FPS蛋白序列与木本棉(Gossypium arboreum)(CAA72793.1)、橡胶树(Hevea brasiliensis)(BAF98301)等的FPS蛋白相似度较高。蛋白质保守区、特征区以及进化树分析初步证实扩增到的全长cDNA序列为青钱柳的FPS基因。将该基因连入酵母表达载体并转入麦角甾醇缺陷型酵母菌株CC25(MATa/MATalpha,deltaERG20/+),发现该基因可弥补营养缺陷使得CC25菌株在高温中正常生长,证明所得到的青钱柳CpFPS基因编码的蛋白是有功能的蛋白。     

Chrysanthemyl Diphosphate Synthase Operates in Planta as a Bifunctional Enzyme with Chrysanthemol Synthase Activity

Chrysanthemyl diphosphate synthase (CDS) is the first pathway-specific enzyme in the biosynthesis of pyrethrins, the most widely used plant-derived pesticide. CDS catalyzes c1′-2-3 cyclopropanation reactions of two molecules of dimethylallyl diphosphate (DMAPP) to yield chrysanthemyl diphosphate (CPP). Three proteins are known to catalyze this cyclopropanation reaction of terpene precursors. Two of them, phytoene and squalene synthase, are bifunctional enzymes with both prenyltransferase and terpene synthase activity. CDS, the other member, has been reported to perform only the prenyltransferase step. Here we show that the NDXXD catalytic motif of CDS, under the lower substrate conditions prevalent in plants, also catalyzes the next step, converting CPP into chrysanthemol by hydrolyzing the diphosphate moiety. The enzymatic hydrolysis reaction followed conventional Michaelis-Menten kinetics, with a K_m value for CPP of 196 μm. For the chrysanthemol synthase activity, DMAPP competed with CPP as substrate. The DMAPP concentration required for half-maximal activity to produce chrysanthemol was ∼100 μm, and significant substrate inhibition was observed at elevated DMAPP concentrations. The N-terminal peptide of CDS was identified as a plastid-targeting peptide. Transgenic tobacco plants overexpressing CDS emitted chrysanthemol at a rate of 0.12–0.16 μg h⁻¹ g⁻¹ fresh weight. We propose that CDS should be renamed a chrysanthemol synthase utilizing DMAPP as substrate.     

Overexpression of Farnesyl Diphosphate Synthase in Arabidopsis Mitochondria Triggers Light-dependent Lesion Formation and Alters Cytokinin Homeostasis

To investigate the role of mitochondrial farnesyl diphosphate synthase (FPS) in plant isoprenoid biosynthesis we characterized transgenic Arabidopsis thaliana plants overexpressing FPS1L isoform. This overexpressed protein was properly targeted to mitochondria yielding a mature and active form of the enzyme of 40 kDa. Leaves from transgenic plants grown under continuous light exhibited symptoms of chlorosis and cell death correlating to H₂O₂ accumulation, and leaves detached from the same plants displayed accelerated senescence. Overexpression of FPS in mitochondria also led to altered leaf cytokinin profile, with a reduction in the contents of physiologically active trans-zeatin- and isopentenyladenine-type cytokinins and their corresponding riboside monophosphates as well as enhanced levels of cis-zeatin 7-glucoside and storage cytokinin O-glucosides. Overexpression of 3-hydroxy-3-methylglutaryl coenzyme A reductase did not prevent chlorosis in plants overexpressing FPS1L, but did rescue accelerated senescence of detached leaves and restored wild-type levels of cytokinins. We propose that the overexpression of FPS1L leads to an enhanced uptake and metabolism of mevalonic acid-derived isopentenyl diphosphate and/or dimethylallyl diphosphate by mitochondria, thereby altering cytokinin homeostasis and causing a mitochondrial dysfunction that renders plants more sensitive to the oxidative stress induced by continuous light.     

Effects of Overexpression of the Endogenous Farnesyl Diphosphate Synthase on the Artemisinin Content in Artemisia annua L.

Artemisinin is a novel effective antimalarial drug extracted from the medicinal plant Artemisia annua L. Owing to the tight market and low yield of artemisinin, there is great interest in enhancing the production of artemisinin. In the present study, farnesyi diphosphate synthase （FPS） was overexpressed in high-yield A. annua to Increase the artemisinin content. The FPS activity in transgenic A. ennue was twoto threefold greater than that In non-transgenic A. annua. The highest artemisinin content in transgenic A. annua was approximately 0.9% （dry weight）, which was 34.4% higher than that in non-transgenic A. annua. The results demonstrate the regulatory role of FPS in artemisinin biosynthesis.     

Refolding and Characterization of a Yeast Dehydrodolichyl Diphosphate Synthase Overexpressed in Escherichia coli

Dehydrodolichyl diphosphate synthase (DDPPs) catalyzes the sequential condensation of isopentenyl diphosphate with farnesyl diphosphate to synthesize long-chain dehydrodolichyl diphosphate, which serves as a precursor of glycosyl carrier in glycoprotein biosynthesis in eukaryotes. To perform kinetic and structural studies of DDPPs, we have expressed yeast DDPPs using Escherichia coli as the host cell. Thioredoxin and His tag were utilized to increase the solubility of the recombinant protein and facilitate its purification using Ni-nitrilotriacetic acid (NTA) column. The protein was overexpressed in E. coli but mostly existed in pellet in the absence of detergent. The low quantity of soluble DDPPs was purified using Ni-NTA, Mono Q anion-exchange, and size-column chromatographies. The protein in the pellet was solubilized with 7 M urea and purified using Ni-NTA under denaturing condition. The protein refolding was achieved via the stepwise dialysis to remove the denaturant in the presence of 6 mM β-mercaptoethanol. Detergent n-octyl-β- -glucopyranoside and Triton X-100 increased the solubility of the DDPPs so that refolding can be performed at higher protein concentration. Alternatively, on-column refolding was carried out in a single step to obtain the active protein in large quantities. β-Mercaptoethanol and Triton were both required in this quick refolding process. The kinetic studies indicated that the soluble and refolded DDPPs have comparable activities (k_cat = 2 × 10⁻⁴ s⁻¹). Unlike its bacterial homologue, undecaprenyl diphosphate synthase, yeast DDPPs activity was not enhanced by Triton.     

Evaluation of an Alkyne-containing Analogue of Farnesyl Diphosphate as a Dual Substrate for Protein-prenyltransferases

The development of tools for proteomic analysis is an active area of research. Here, we report on the synthesis of 12-propargoxyfarnesyl diphosphate (1), an alkyne-containing analogue of farnesyl diphosphate (FPP), and its enzymatic incorporation into peptide substrates by both protein-farnesyltransferase (PFTase) and protein-geranylgeranyltransferase type I (PGGTase-I). Compound 1 was prepared from farnesol in 6 steps. Kinetic analyses indicate that 1 is incorporated into cognate peptide substrates by PFTase or PGGTase at concentrations and rates comparable to those of the natural lipid substrates for these enzymes, and mass spectrometric analyses proved the structures of the prenylated peptide products. Incubation of 1 in the presence of PFTase and PGGTase peptide substrates, and the cognate transferases, results in the simultaneous prenylation of both peptides emphasizing the dual substrate nature of 1. Thus, because 1 is a substrate for both enzymes, it can be used to introduce alkyne functionality into proteins that are normally either farnesylated or geranylgeranylated. This approach should be useful for a broad range of applications ranging from selective protein labeling to proteomic analysis. This paper is dedicated to the memory of Bruce Merrifield (1921–2006) for his pioneering development of solid-phase peptide synthesis, which has made possible myriad advances in chemical biology. For the present study, we used SPPS to prepare protein fragments that incorporate spectroscopic probes to reveal critical features in enzyme substrate recognition that have implications for human health.     

The Identification of Wild Yeast Colonies on Lysine Agar

The most common wild yeasts infecting pressed baker's yeast in Great Britain are Candida tropicalis, C. krusei, C. mycoderma, Trichosporon cutaneum, Torulopsis candida and Rhodotorula mucilaginosa. Wild yeasts are readily detected and quantitatively estimated by plating infected baker's yeast on lysine agar, which permits of only limited growth of baker's yeast.
Morphology of wild yeast colonies on lysine agar is affected by duration of incubation, location in the agar plate, and sometimes by temperature of incubation, density of infection and numbers of baker's yeast cells present. It is therefore possible to identify each species by at least one characteristic type of colony produced under specified conditions. Ability to grow at 30° and 37° serves to distinguish further between certain species.     

In Silico and In Vitro Analyses Identified Three Amino Acid Residues Critical to the Catalysis of Two Aphid Farnesyl Diphosphate Synthase

Farnesyl diphosphate synthase (FPPS) plays an essential role in the isoprenoid biosynthetic pathway of microbes, plants and animals. In the present study, we first cloned two FPPSs from the bird cherry-oat aphid (RpFPPS1 and RpFPPS2), and activity assay by gas chromatography-mass spectrometry showed that both RpFPPS1 and RpFPPS2 were active in vitro. They were then subjected to homology modeling and molecular docking. Molecular interaction analysis indicated that three amino acid residues (R120, R121 and K266) might play key roles in the catalysis of the two aphid FPPSs by forming hydrogen bonds with the diphosphate moiety of the allylic substrate. These in silico results were subsequently confirmed by site-directed mutagenesis and in vitro activity assay of the mutant enzymes, in which each of the single mutations R120G, R121G and K266I abolished the activities of the two FPPSs. This study contributes to our understanding of the catalytic mechanism of farnesyl diphosphate synthases.     

Identification of a Residue Affecting Fatty Alcohol Selectivity in Wax Ester Synthase

The terminal enzyme in the bacterial wax ester biosynthetic pathway is the bifunctional wax ester synthase/acyl-coenzyme A:diacylglycerol acyltransferase (WS/DGAT), which utilizes a fatty alcohol and a fatty acyl-coenzyme A (CoA) to synthesize the corresponding wax ester. In this report, we identify a specific residue in WS/DGAT enzymes obtained from Marinobacter aquaeolei VT8 and Acinetobacter baylyi that alters fatty alcohol selectivity and kinetic parameters when modified to alternative residues.     

The Small Subunit of Snapdragon Geranyl Diphosphate Synthase Modifies the Chain Length Specificity of Tobacco Geranylgeranyl Diphosphate Synthase in Planta

Geranyl diphosphate (GPP), the precursor of many monoterpene end products, is synthesized in plastids by a condensation of dimethylallyl diphosphate and isopentenyl diphosphate (IPP) in a reaction catalyzed by homodimeric or heterodimeric GPP synthase (GPPS). In the heterodimeric enzymes, a noncatalytic small subunit (GPPS.SSU) determines the product specificity of the catalytic large subunit, which may be either an active geranylgeranyl diphosphate synthase (GGPPS) or an inactive GGPPS-like protein. Here, we show that expression of snapdragon (Antirrhinum majus) GPPS.SSU in tobacco (Nicotiana tabacum) plants increased the total GPPS activity and monoterpene emission from leaves and flowers, indicating that the introduced catalytically inactive GPPS.SSU found endogenous large subunit partner(s) and formed an active snapdragon/tobacco GPPS in planta. Bimolecular fluorescence complementation and in vitro enzyme analysis of individual and hybrid proteins revealed that two of four GGPPS-like candidates from tobacco EST databases encode bona fide GGPPS that can interact with snapdragon GPPS.SSU and form a functional GPPS enzyme in plastids. The formation of chimeric GPPS in transgenic plants also resulted in leaf chlorosis, increased light sensitivity, and dwarfism due to decreased levels of chlorophylls, carotenoids, and gibberellins. In addition, these transgenic plants had reduced levels of sesquiterpene emission, suggesting that the export of isoprenoid intermediates from the plastids into the cytosol was decreased. These results provide genetic evidence that GPPS.SSU modifies the chain length specificity of phylogenetically distant GGPPS and can modulate IPP flux distribution between GPP and GGPP synthesis in planta.     

Identification of Residues Surrounding the Active Site of Type A Botulinum Neurotoxin Important for Substrate Recognition and Catalytic Activity

Type A botulinum neurotoxin is one of the most lethal of the seven serotypes and is increasingly used as a therapeutic agent in neuromuscular dysfunctions. Its toxic function is related to zinc-endopeptidase activity of the N-terminal light chain (LC) on synaptosome-associated protein-25 kDa (SNAP-25) of the SNARE complex. To understand the determinants of substrate specificity and assist the development of strategies for effective inhibitors, we used site-directed mutagenesis to investigate the effects of 13 polar residues of the LC on substrate binding and catalysis. Selection of the residues for mutation was based on a computational analysis of the three-dimensional structure of the LC modeled with a 17-residue substrate fragment of SNAP-25. Steady-state kinetic parameters for proteolysis of the substrate fragment were determined for a set of 16 single mutants. Of the mutated residues non-conserved among the serotypes, replacement of Arg-230 and Asp-369 by polar or apolar residues resulted in drastic lowering of the catalytic rate constant (k _cat), but had less effect on substrate affinity (K _m). Substitution of Arg-230 with Lys decreased the catalytic efficiency (k _cat/K _m) by 50-fold, whereas replacement by Leu yielded an inactive protein. Removal of the electrostatic charge at Asp-369 by mutation to Asn resulted in 140-fold decrease in k _cat/K _m. Replacement of other variable residues surrounding the catalytic cleft (Glu-54, Glu-63, Asn-66, Asp-130, Asn-161, Glu-163, Glu-170, Glu-256), had only marginal effect on decreasing the catalytic efficiency, but unexpectedly the substitution of Lys-165 with Leu resulted in fourfold increase in k _cat/K _m. For comparison purposes, two conserved residues Arg-362 and Tyr-365 were investigated with substitutions of Leu and Phe, respectively, and their catalytic efficiency decreased 140- and 10-fold, respectively, whereas substitution of the tyrosine ring with Asn abolished activity. The altered catalytic efficiencies of the mutants were not due to any significant changes in secondary or tertiary structures, or in zinc content and thermal stability. We suggest that, despite the large minimal substrate size for catalysis, only a few non-conserved residues surrounding the active site are important to render the LC competent for catalysis or provide conformational selection of the substrate.     

Residue Histidine 669 Is Essential for the Catalytic Activity of Bacillus anthracis Lethal Factor

The lethal factor (LF) of Bacillus anthracis is a Zn²⁺-dependent metalloprotease which plays an important role in anthrax virulence. This study was aimed at identifying the histidine residues that are essential to the catalytic activities of LF. The site-directed mutagenesis was employed to replace the 10 histidine residues in domains II, III, and IV of LF with alanine residues, respectively. The cytotoxicity of these mutants was tested, and the results revealed that the alanine substitution for His-669 completely abolished toxicity to the lethal toxin (LT)-sensitive RAW264.7 cells. The reason for the toxicity loss was further explored. The zinc content of this LF mutant was the same as that of the wild type. Also this LF mutant retained its protective antigan (PA)-binding activity. Finally, the catalytic cleavage activity of this mutant was demonstrated to be drastically reduced. Thus, we conclude that residue His-669 is crucial to the proteolytic activity of LF.Anthrax is a zoonotic disease caused by toxigenic strains of the Gram-positive bacterium Bacillus anthracis (24). Because infections are highly fatal, the organisms are easily produced, and the spores spread easily, B. anthracis has been used as a bioweapon in biological war and biological terrorism (38). If inhaled, the spores are phagocytosed by alveolar macrophages, where they germinate to produce vegetative bacteria (10, 24). The vegetative bacteria further release anthrax toxins, which inhibit the innate and adaptive immune responses of the hosts. This enables the capsulated bacteria to escape the lymph node defense barrier to reach the blood system, causing bacteremia and toxemia, which can rapidly kill the hosts (24, 26). The great threat posed by anthrax to the public is not only due to the highly lethal rate of inhaled anthrax, but also is due to the social panic caused by the lethality. Therefore, efficient ways to defend against anthrax infection and spreading are greatly needed. This mostly depends on a full understanding of the mechanisms of anthrax infection and toxicities.Anthrax toxins are the dominant virulence factors of Bacillus anthracis (6, 33, 37). They consist of three proteins: protective antigen (PA; 83 kDa), lethal factor (LF; 90 kDa), and edema factor (EF; 89 kDa). The 83-kDa PA (PA₈₃) directly binds to cellular membrane receptors and was cleaved to an active fragment of 63-kDa PA (PA₆₃) by cellular proteases of the furin family or by serum proteases. The receptor-bound portion of PA₆₃ self-assembles into either ring-shaped heptamers, which bind to three molecules of LF and/or EF, resulting in (PA₆₃)₇(LF/EF)₃ (21), or octamers which bind up to four molecules of these moieties, resulting in (PA₆₃)₈(LF/EF)₄ complexes (16, 17). The catalytic partners (EF and/or LF) are subsequently transported across the membrane to the cell cytosol (24, 27). EF is a Ca²⁺- and calmodulin-dependent adenylate cyclase that, together with PA, forms edema toxin. EF causes a rapid increase in intracellular cyclic AMP (cAMP) levels in host cells and alters the elaborate balance of intracellular signaling pathways (20, 23). LF is a Zn²⁺-dependent protease that, together with PA, forms lethal toxin (LT). It is a dominant virulence factor and the major cause of death for the B. anthracis-infected animals (1, 29, 30). LF specifically cleaves the N-terminal domain of mitogen-activated protein kinase kinases (MAPKKs) (11, 35). Because the N-terminal domain of MAPKKs is essential for the interaction between MAPKKs and MAPKs, the cleavage of this domain impairs the activation of MAPKs (8, 11, 15) and leads to the inhibition of three major cellular signaling pathways—the ERK (extracellular signal-regulated kinase), p38, and JNK (c-Jun N-terminal kinase) pathways (29, 31)—and thus induces the lysis of the host cells in an unknown mechanism.The crystal structure of LF with the N-terminal domain of MEK2 has been reported (28). LF has 776 amino acids and comprises four different domains. Domain I (residues 1 to 254) is a PA-binding domain which delivers the remaining domains of the LF to the cell cytoplasm (3). The interface among domains II, III, and IV creates long, deep, 40-Å-long catalytic grooves into which the N terminus of MEK fits and forms an active site complex (28). Domain IV is central to catalytic activities of LF, containing two zinc-binding motifs (residues 686 to 690 and residues E735 to E739) and bound to a single Zn ion (18). However, which residues of LF are critical for efficient catalytic activities and execute the substrate cleavage remains unclear.Histidine is the only naturally occurring amino acid to contain an imidazole residue as a side chain. The catalytic activity of histidine mostly depends on the special features of the imidazole residue. The logarithm of the proton dissociation constant of imidazolyl in the histidine residue is about 6.5; thus, under the physiological condition, it tends to form hydrogen bonds and shares donor and acceptor properties that can take part in either nucleophilic or base catalysis. The speed of the imidazole residue to give or accept protons is very fast, with a half-life of less than 10 s. So in the process of natural selection, histidine was chosen as the catalytic structure, indicating that it plays an important role in the catalysis process of enzymes (9, 12, 14). There are 21 histidines in LF, with 9 of them in LF domain I and 12 of them in domains II, III, and IV. The histidine residues important to LF activities in domain I have been identified (2, 22). The other 12 histidine residues in the remaining three domains include His-277, His-280, and His-424 in domain II; His-309 in domain III; and His-588, His-645, His-654, His-669, His-686, His-690, His-745, and His-749 in domain IV (28). His-686 and His-690 in domain IV were demonstrated to form a zinc binding site constituting a thermolysin-like zinc metalloprotease motif, HEXXH (18). The activities of the remaining 10 histidine residues in domains II, III, and IV have not been explored yet. In this study, we replaced these 10 histidine residues separately with alanine residues by site-directed mutagenesis. By the cytotoxicity assay of all these mutants, the H669A mutant was found to lose cell toxicity completely. Further assay revealed that residue His-669 was involved in neither zinc stabilization nor PA binding but participated in the substrate proteolytic activity of LF.     

Cryo-EM Structure of the Yeast ATP Synthase

We have used electron cryomicroscopy of single particles to determine the structure of the ATP synthase from Saccharomyces cerevisiae. The resulting map at 24 Å resolution can accommodate atomic models of the F₁-c₁₀ subcomplex, the peripheral stalk subcomplex, and the N-terminal domain of the oligomycin sensitivity conferral protein. The map is similar to an earlier electron cryomicroscopy structure of bovine mitochondrial ATP synthase but with important differences. It resolves the internal structure of the membrane region of the complex, especially the membrane embedded subunits b, c, and a. Comparison of the yeast ATP synthase map, which lacks density from the dimer-specific subunits e and g, with a map of the bovine enzyme that included e and g indicates where these subunits are located in the intact complex. This new map has allowed construction of a model of subunit arrangement in the F_O motor of ATP synthase that dictates how dimerization of the complex via subunits e and g might occur.     

Converting the Yeast Arginine Can1 Permease to a Lysine Permease

Amino acid uptake in yeast cells is mediated by about 16 plasma membrane permeases, most of which belong to the amino acid-polyamine-organocation (APC) transporter family. These proteins display various substrate specificity ranges. For instance, the general amino acid permease Gap1 transports all amino acids, whereas Can1 and Lyp1 catalyze specific uptake of arginine and lysine, respectively. Although Can1 and Lyp1 have different narrow substrate specificities, they are close homologs. Here we investigated the molecular rules determining the substrate specificity of the H⁺-driven arginine-specific permease Can1. Using a Can1-Lyp1 sequence alignment as a guideline and a three-dimensional Can1 structural model based on the crystal structure of the bacterial APC family arginine/agmatine antiporter, we introduced amino acid substitutions liable to alter Can1 substrate specificity. We show that the single substitution T456S results in a Can1 variant transporting lysine in addition to arginine and that the combined substitutions T456S and S176N convert Can1 to a Lyp1-like permease. Replacement of a highly conserved glutamate in the Can1 binding site leads to variants (E184Q and E184A) incapable of any amino acid transport, pointing to a potential role for this glutamate in H⁺ coupling. Measurements of the kinetic parameters of arginine and lysine uptake by the wild-type and mutant Can1 permeases, together with docking calculations for each amino acid in their binding site, suggest a model in which residues at positions 176 and 456 confer substrate selectivity at the ligand-binding stage and/or in the course of conformational changes required for transport.     

Control of Lysine Biosynthesis in Yeast by a Feedback Mechanism

Homocitric acid (β-hydroxy-β-carboxyadipic acid; HC) is accumulated by a lysine-requiring yeast mutant when grown in a chemically defined medium, supplemented with limited amounts of lysine. A study of the formation of HC in relation to the depletion of lysine from the growth medium indicates that HC accumulated only when the concentration of lysine was low. The enzymatic formation of HC from α-ketoglutarate plus acetyl-coenzyme A in cell-free extracts of the same organism was also inhibited by lysine. The inhibitory effect of lysine on the formation of HC in both whole cells and cell-free extracts is indicative of the functional existence of a feedback control mechanism in the pathway for lysine biosynthesis in yeast.     

Characterization of Sucrolysis via the Uridine Diphosphate and Pyrophosphate-Dependent Sucrose Synthase Pathway

The breakdown of sucrose to feed both hexoses into glycolytic carbon flow can occur by the sucrose synthase pathway. This uridine diphosphate (UDP) and pyrophosphate (PPi)-dependent pathway was biochemically characterized using soluble extracts from several plants. The sucrolysis process required the simultaneous presence of sucrose, UDP, and PPi with their respective K_m values being about 40 millimolar, 23 micromolar, and 29 micromolar. UDP was the only active nucleotide diphosphate. Slightly alkaline pH optima were observed for sucrose breakdown either to glucose 1-phosphate or to triose phosphate. Sucrolysis incrased with increasing temperature to near 50°C and then a sharp drop occurred between 55 and 60°C. The breakdown of sucrose to triose-P was activated by fructose 2,6-P₂ which had a K_m value near 0.2 micromolar. The cytoplasmic phosphofructokinase and fructokinase in plants were fairly nonselective for nucleotide triphosphates (NTP) but glucokinase definitely favored ATP. A predicted stoichiometric relationship of unity for UDP and PPi was measured when one also measured competing UDPase and pyrophosphatase activity. The cycling of uridylates, UDP to UTP to UDP, was demonstrated both with phosphofructokinase and with fructokinase. Enzyme activity measurements indicated that the sucrose synthase pathway has a major role in plant sucrose sink tissues. In the cytoplasmic sucrose synthase breakdown pathway, a role for the PPi-phosphofructokinase was to produce PPi while a role for the NTP-phosphofructokinase and for the fructokinase was to produce UDP.     

Expression Pattern of the Coparyl Diphosphate Synthase Gene in Developing Rice Anthers

Rice anthers contain high concentrations of gibberellins A₄ and A₇. To understand their physiological roles, we examined the site of their biosynthesis by analyzing the expression pattern of a gene (OsCPS) encoding coparyl diphosphate synthase in developing rice flowers. Expression was apparent in the anthers 1–2 days before flowering, and CPS mRNA accumulated in the maturing pollen.