Calcium oscillations in mammalian eggs triggered by a soluble sperm protein

At fertilization in mammals, the sperm induces a characteristic series of Ca2+ oscillations in the egg which serve as the essential trigger for egg activation and early development of the embryo. It is not known how the sperm initiates this fundamental process, however, nor has any pathway linking sperm-egg membrane-receptor binding with intracellular Ca2+ release been demonstrated. Microinjection of sperm extracts into mammalian eggs elicits Ca2+ oscillations identical to those occurring at fertilization, which suggests that sperm may introduce a Ca2+ oscillation-inducing factor into the egg on gamete membrane fusion. Here we identify a soluble sperm protein that exhibits Ca2+ oscillation-inducing ('oscillogen') activity in eggs. Sperm oscillogen exists as an oligomer with a subunit of M(r) 33K and a specific intracellular localization at the equatorial segment of the sperm head. Cloning of the 33K oscillogen complementary DNA indicates similarity with a hexose phosphate isomerase found in prokaryotes. This sperm-derived oscillogen, termed oscillin, may represent the physiological trigger for development in mammals.

Structure and catalytic mechanism of glucosamine 6-phosphate deaminase from Escherichia coli at 2.1 A resolution

BACKGROUND

Glucosamine 6-phosphate deaminase from Escherichia coli is an allosteric hexameric enzyme which catalyzes the reversible conversion of D-glucosamine 6-phosphate into D-fructose 6-phosphate and ammonium ion and is activated by N-acetyl-D-glucosamine 6-phosphate. Mechanistically, it belongs to the group of aldoseketose isomerases, but its reaction also accomplishes a simultaneous amination/deamination. The determination of the structure of this protein provides fundamental knowledge for understanding its mode of action and the nature of allosteric conformational changes that regulate its function.

RESULTS

The crystal structure of glucosamine 6-phosphate deaminase with bound phosphate ions is presented at 2.1 A resolution together with the refined structures of the enzyme in complexes with its allosteric activator and with a competitive inhibitor. The protein fold can be described as a modified NAD-binding domain.

CONCLUSIONS

From the similarities between the three presented structures, it is concluded that these represent the enzymatically active R state conformer. A mechanism for the deaminase reaction is proposed. It comprises steps to open the pyranose ring of the substrate and a sequence of general base-catalyzed reactions to bring about isomerization and deamination, with Asp72 playing a key role as a proton exchanger.

Epigenetic control of an endogenous gene family is revealed by a novel blue fluorescent mutant of Arabidopsis

The Wassilewskija strain of Arabidopsis has four genes encoding the tryptophan enzyme phosphoribosylanthranilate isomerase (PAI) located at three unlinked sites. These four PAI genes are methylated over their regions of DNA homology. When PAI copy number is reduced by deletion of two tandemly arrayed genes (MePAI1-PAI4), a mutant with fluorescent, tryptophan-deficient phenotypes results, because the two remaining methylated PAI genes (MePAI2 and MePAI3) supply insufficient PAI activity. These two methylated genes can be inherited through meiosis, even when they are segregated away from each other in crosses to a strain with unmethylated PAI genes. However, the mutant phenotypes conferred by the methylated PAI genes are unstable, and mutant plants yield occasional revertant somatic sectors and progeny. Revertant lines display coordinately reduced methylation of both PAI2 and PAI3, implying that this hypomethylation acts in a concerted manner across the genome rather than at individual sites.

Molecular evolution of the histidine biosynthetic pathway

The available sequences of genes encoding the enzymes associated with histidine biosynthesis suggest that this is an ancient metabolic pathway that was assembled prior to the diversification of the Bacteria, Archaea, and Eucarya. Paralogous duplications, gene elongation, and fusion events involving different his genes have played a major role in shaping this biosynthetic route. Evidence that the hisA and the hisF genes and their homologous are the result of two successive duplication events that apparently took place before the separation of the three cellular lineages is extended. These two successive gene duplication events as well as the homology between the hisH genes and the sequences encoding the TrpG-type amidotransferases support the idea that during the early stages of metabolic evolution at least parts of the histidine biosynthetic pathway were mediated by enzymes of broader substrate specificities. Maximum likelihood trees calculated for the available sequences of genes encoding these enzymes have been obtained. Their topologies support the possibility of an evolutionary proximity of archaebacteria with low GC Gram-positive bacteria. This observation is consistent with those detected by other workers using the sequences of heat-shock proteins (HSP70), glutamine synthetases, glutamate dehydrogenases, and carbamoylphosphate synthetases.

The evolution of sugar isomerases

L-Arabinose isomerase (EC 5.3.1.4) catalyzes the isomerization of L-arabinose to L-ribulose. Here we report on the purification, kinetic mechanism and chemical mechanism of L-arabinose isomerase from Escherichia coli. The enzyme catalyzes the isomerization of L-arabinose to L-ribulose by a proton transfer mechanism, in contrast to xylose isomerase which uses a hydride transfer mechanism to perform a similar isomerization. Arabinose isomerase activity is metal dependent, although the enzyme can catalyze the exchange of the proton attached to carbon 2 of arabinose with the solvent in the absence of metal ion. Manganese(II) is the only metal ion which renders the enzyme active for the isomerization reaction. Arabinose isomerase has high substrate specificity for L-arabinose. The difference in chemical mechanism between xylose isomerase and arabinose isomerase suggests that these enzymes are not related by convergent evolution. This work also suggests that unless convergent evolution has been demonstrated, the mechanism of one enzyme may not give any insight into the mechanism of a second enzyme catalyzing the same reaction.

Cloning of the Candida glabrata TRP1 and HIS3 genes, and construction of their disruptant strains by sequential integrative transformation

The Candida glabrata (Cg) TRP1 and HIS3 genes have been isolated by complementation of the Saccharomyces cerevisiae (Sc) trp1 and his3 mutants, respectively. Cg TRP1 encodes a polypeptide of 217 amino acids (aa), whose aa sequence is 58% identical to that of Sc TRP1. Cg HIS3 encodes a polypeptide of 210 aa, whose aa sequence is 73% identical to that of the Sc HIS3. Both Cg TRP1 and HIS3 were disrupted by sequential integrative transformation where the Sc URA3 was used as a selection marker for transformation. The resulting auxotrophic strain of his3- and trp1- was used to examine the ability of the Sc genes to complement the Cg mutations; Sc HIS3 and TRP1 complemented the Cg his3- and trp1- mutations, respectively.

Nature of abortive transformation in Saccharomyces cerevisiae

Disruption mutagenesis by homologous recombination in Saccharomyces cerevisiae is carried out by transforming-DNA fragments containing the target gene disrupted by a selectable marker. A large number of transient (abortive) transformants are often formed that may hinder the isolation of integrants containing the gene disruption. We show that abortive transformants result from re-circularization of the linear transforming-DNA in vivo. Their number was greatly reduced when the cut DNA could not readily re-ligate, either by digestions that gave non-compatible or blunt ends, or by de-phosphorylation. In addition, true integrants could be readily distinguished from abortive transformants through replica plating onto selective media. Enhanced disruption-mutagenesis was also observed when non-compatible ends were generated in an ARS-containing insertion vector.

Glucosamine 6-phosphate deaminase in Plasmodium falciparum

The pathways of glucose utilization for energy production in the malaria parasite, Plasmodium falciparum, have been studied extensively. Little is known, however, about the reactions by which glucose is converted into complex carbohydrates in the parasite, and knowledge of the catabolism of these substances is likewise scanty. The present investigation was undertaken to determine whether the parasites possess a key enzyme of glucosamine catabolism, i.e. glucosamine 6-phosphate deaminase (EC 5.3.1.40), which catalyses the conversion of the sugar phosphate to fructose 6-phosphate and ammonia. Lysates of Plasmodium-infected erythrocytes had substantially higher deaminase activity than control samples from normal erythrocytes, and an even higher specific activity was observed in extracts of isolated parasites, amounting to 20-40 times that of uninfected cells. Anion exchange chromatography indicated that the parasite deaminase eluted in a retarded position when compared to the elution profile of the erythrocyte enzyme. The charge difference suggested by these findings was established more directly by chromatofocusing, which indicated pI values of 6.85 and 8.55 for the parasite and erythrocyte deaminases, respectively. Other differences were also observed, notably a greater thermolability on the part of the parasite enzyme. These results indicated that the parasites synthesize a specific deaminase that is distinct from the normal erythrocyte enzyme. Studies on synchronized parasite cultures further indicated that the parasite deaminase is developmentally regulated, because a dramatic increase in activity levels occurred during the later stages of parasite development.

A review of protein engineering for the food industry

In this review I briefly describe the technique of protein engineering and indicate how the present state of knowledge allows proteins to be mutated to increase or decrease stability. I discuss experiments on both model proteins and those of relevance to the food industry and show how hydrophobic forces are a major driving force for folding as well as having a major role in thermostability. I also indicate the large contribution that hydrogen bonding, electrostatic interactions and, in a less well predicted way, disulfide bridges make to thermostability.

Cloning and overexpression of rhamnose isomerase and fucose isomerase

Rhamnose isomerase and fucose isomerase were overexpressed in E. coli, purified and characterized. The rhamnose isomerase gene was ligated to the restriction sites of PstI and Hind III of vector pTrcHis and the fucose isomerase gene was ligated to the EcoRI and PstI sites of vector pKK223-3 for overexpression of the enzymes in E. coli XL1-Blue MRF. Approximately 16,500 U of active fucose isomerase and 2400 of rhamnose isomerase can be obtained per liter of culture from these expression systems.

Probing the roles of active site residues in D-xylose isomerase

The roles of active site residues His54, Phe94, Lys183, and His220 in the Streptomyces rubiginosus D-xylose isomerase were probed by site-directed mutagenesis. The kinetic properties and crystal structures of the mutant enzymes were characterized. The pH dependence of diethylpyrocarbonate modification of His54 suggests that His54 does not catalyze ring-opening as a general acid. His54 appears to be involved in anomeric selection and stabilization of the acyclic transition state by hydrogen bonding. Phe94 stabilizes the acyclic-extended transition state directly by hydrophobic interactions and/or indirectly by interactions with Trp137 and Phe26. Lys183 and His220 mutants have little or no activity and the structures of these mutants with D-xylose reveal cyclic alpha-D-xylopyranose. Lys183 functions structurally by maintaining the position of Pro187 and Glu186 and catalytically by interacting with acyclic-extended sugars. His220 provides structure for the M2-metal binding site with properties which are necessary for extension and isomerization of the substrate. A second M2 metal binding site (M2') is observed at a relatively lower occupancy when substrate is added consistent with the hypothesis that the metal moves as the hydride is shifted on the extended substrate.

Chromatin structure snap-shots: rapid nuclease digestion of chromatin in yeast

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(Beta alpha)8-barrel proteins of tryptophan biosynthesis in the hyperthermophile Thermotoga maritima

To better understand the evolution of a key metabolic pathway, we have sequenced the trpCFBA gene cluster of the hyperthermophilic bacterium Thermotoga maritima. The genes were cloned by complementation in vivo of trp deletion strains of Escherichia coli. The new sequences, together with earlier findings, establish that the trp operon of T.maritima has the order trpE(G.D)CFBA, which might represent the ancestral organization of the tryptophan operon. Heterologous expression of the trp(G.D) and trpC genes in E.coli and N-terminal sequencing of their polypeptide products showed that their translation is initiated at the rate start codons TTG and ATC, respectively. Consequently, the N-terminus of the trp(G.D) fusion protein is 43 residues shorter than previously postulated. Amino acid composition and sequence analyses of the protein products of T.maritima trpC (indoleglycerol phosphate synthase), trpF (phosphoribosyl anthranilate isomerase) and trpA (alpha-subunit of tryptophan synthase) suggest that these thermostable (beta alpha)8-barrel proteins may be stabilized by additional salt bridges, compared with the mesostable forms. Another notable feature is the predicted lack of the N-terminal helix alpha 0 in the alpha-subunit of tryptophan synthase.

Molecular modelling of xylose isomerase catalysis: the role of electrostatics and charge transfer to metals

The two main steps of the mechanism of xylose-xylulose conversion catalysed by D-xylose isomerase, the ring opening of xylose and the isomerization of the opened product by hydride transfer, were investigated by molecular mechanical and molecular orbital techniques. The activation energies calculated for these reactions clearly showed that hydrogen transfer is the rate-determining step of the enzymatic isomerization and that Mg2+ ions activate whereas Zn2+ ions inhibit the reaction, in agreement with the experiments. The remarkable differences between the net charges of these ions found by molecular orbital calculations and the inspection of the protein electrostatic potential around the reaction intermediates indicate that the main role of bivalent metal ions should be the electrostatic stabilization of the substrate transition states. In order to propose a more detailed mechanism, an attempt was made to clarify the effects of nearby residues (e.g. His54, Asp57, Lys183, Asp257) in the reaction. Different isomerization mechanisms, such as through an enediol intermediate, were examined and could be excluded, in addition to the charge-relay mechanism during the ring opening.

Glucosamine 6-phosphate deaminase in normal human erythrocytes

In the course of an investigation of hexosamine catabolism in the human malaria parasite, Plasmodium falciparum, it became apparent that a basic understanding of the relevant enzymatic reactions in the host erythrocyte is lacking. To acquire the necessary basic knowledge, we have determined the activities of several enzymes involved in hexosamine metabolism in normal human red blood cells. In the present communication we report the results of studies of glucosamine 6-phosphate deaminase (GlcN6-P) using a newly developed sensitive radiometric assay. The mean specific activity in extracts of fresh erythrocytes assayed within 4h of collection was 14.7 nmol/h/mg protein, whereas preparations from older erythrocytes that had been stored at 4 degrees C for up to 4 weeks had a mean specific activity of 6.2 nmol/h/mg. Characterization of the deaminase by chromatofocusing gave a pI of 8.55. The enzyme was optimally active at pH 9.0 and had a Km of 41 microM. The metal chelators EDTA and EGTA were non-inhibitory; however, inhibition was observed in the presence of metal ions, especially Cu2+, Ni2+ and Zn2+. In addition, the deaminase was also inhibited by several sugar phosphates including the reaction product, fructose 6-phosphate.

Inverse protein folding by the residue pair preference profile method: estimating the correctness of alignments of structurally compatible sequences

The residue pair preference profile (R3P) method is an inverse folding method that combines environmental profiles and pair preference profiles. The method uses statistical preferences for residue pairs which score the likelihood of finding a profiled residue to be paired with a residue within its local environment. All pairs are characterized by their dihedral angles, secondary structure and number of neighboring residues as a function of residue type. Each residue pair preference is expressed for all 20 amino acids of the profiled residue and is weighted by the compatibility of the environment residue with its own local environment. The R3P method produces an initial profile-sequence alignment which is then refined by converting the initial profile into a profile of a target sequence threaded into the structure of the initial profile. We have tested this method by evaluating alignments of sequences with known 3-D structures using structural superposition alignments as reference. R3P-sequence alignments are > or = 50% correct on average for sequences whose 3-D structure pairs superimpose with an r.m.s. deviation of < or = 1.97 A. The average improvement in correctness during this iterative refinement is 14%. The R3P-sequence alignments are compared with sequence-sequence and 3-D profile-sequence alignments. When all three methods are combined, on average > or = 50% of the alignments are correct for pairs of 3-D structures that superimpose within 2.12 A. A 3-D model of HisA is predicted with the combined method.

Molecular cloning and characterization of the xylose isomerase gene from a thermophilic Bacillus species

The gene (xylA) encoding a thermostable xylose isomerase has been isolated and characterized from a thermophilic Bacillus species for the first time. The xylA open reading frame of 1323 bp encoded a protein containing 441 amino acids with a calculated molecular weight of 50,176. The amino acid sequence of this protein showed 76% homology to xylose isomerase isolated from Bacillus subtilis and contained all the important catalytic domains of the enzyme. The gene complemented the xyl-5 mutation and produced a functional enzyme constitutively in Escherichia coli. The crude cell-free extract of E. coli recombinants exhibited xylose isomerase activity over a wide range of temperatures from 60 to 100 degrees C with an optimal enzyme activity of 10.4 Units/mg protein at 85 degrees C. This optimal temperature was one of the highest reported so far for thermostable xylose isomerases. The recombinant enzyme was found to be a tetramer with each subunit having molecular weight of 50,000.

Asymmetric allosteric activation of Escherichia coli glucosamine-6-phosphate deaminase produced by replacements of Tyr 121

Tyrosine 121, a residue located in a alpha-helical polypeptide segment of glucosamine 6-phosphate deaminase from Escherichia coli, has recently been proposed to have a role in the binding of the allosteric activator N-acetyl-D-glucosamine 6-phosphate. Accordingly, the site-directed mutants Tyr 121-Thr and Tyr 121-Trp were constructed, to assess experimentally the role of Tyr 121 in the allosteric function of the enzyme. The kinetic study of both mutant forms revealed that the replacements caused striking changes in allosteric activator binding and allosteric properties, when compared to the wild-type enzyme. While the wild-type deaminase behaves as a classical allosteric K-system which can be described by the allosteric concerted model, both mutant forms present an asymmetric behavior toward the allosteric activator, which can be described as two distinct half-of-the-sites allosteric activation steps occurring with different affinities for the N-acetyl-D-glucosamine 6-phosphate. During the first (high affinity) activation phase, the mutant forms of deaminase behave as mixed K/V allosteric enzyme. The biphasic activation curve was also demonstrated by direct binding measurements of the 14C-labeled activator to Tyr 121-Trp and Tyr 121-Thr deaminases. The kinetic analysis of these mutant forms also showed that the threonine replacement produced an important distortion of the enzyme structure reflected in a considerable decrease of its catalytic efficiency.(ABSTRACT TRUNCATED AT 250 WORDS)

xylA cloning and sequencing and biochemical characterization of xylose isomerase from Thermotoga neapolitana

The xylA gene coding for xylose isomerase from the hyperthermophile Thermotoga neapolitana 5068 was cloned, sequenced, and expressed in Escherichia coli. The gene encoded a polypeptide of 444 residues with a calculated molecular weight of 50,892. The native enzyme was a homotetramer with a molecular weight of 200,000. This xylose isomerase was a member of the family II enzymes (these differ from family I isomerases by the presence of approximately 50 additional residues at the amino terminus). The enzyme was extremely thermostable, with optimal activity above 95 degrees C. The xylose isomerase showed maximum activity at pH 7.1, but it had high relative activity over a broad pH range. The catalytic efficiency (kcat/Km) of the enzyme was essentially constant between 60 and 90 degrees C, and the catalytic efficiency decreased between 90 and 98 degrees C primarily because of a large increase in Km. The T. neapolitana xylose isomerase had a higher turnover number and a lower Km for glucose than other family II xylose isomerases. Comparisons with other xylose isomerases showed that the catalytic and cation binding regions were well conserved. Comparison of different xylose isomerase sequences showed that numbers of asparagine and glutamine residues decreased with increasing enzyme thermostability, presumably as a thermophilic strategy for diminishing the potential for chemical denaturation through deamidation at elevated temperatures.

Indoleglycerol phosphate synthase-phosphoribosyl anthranilate isomerase: comparison of the bifunctional enzyme from Escherichia coli with engineered monofunctional domains

Putative domain--domain interactions of the monomeric bifunctional enzyme indoleglycerol phosphate synthase:phosphoribosyl anthranilate isomerase from Escherichia coli were probed by separating the domains on the gene level and expressing them as monofunctional proteins. The engineered monofunctional enzymes were found to be stable, monomeric proteins with virtually full catalytic activity. In addition, binding of indolyglycerol phosphate to the active site of indoleglycerol phosphate synthase and binding of reduced 1-[(2-carboxyphenyl)amino]-1-deoxyribulose 5-phosphate, a competitive inhibitor of both indoleglycerol phosphate synthase and phosphoribosyl anthranilate isomerase, were almost identical in both the mono- and bifunctional enzymes. Furthermore, no association between the monofunctional enzymes was found, neither in vitro, by sedimentation and gel filtration experiments, nor in vivo, by coexpression of the domains in the same cell. Thus, no selective advantages of the bifunctional enzyme from Escherichia coli over the respective monofunctional enzymes were found on a functional level. However, the phosphoribosyl anthranilate isomerase domain appears to stabilize the indoleglycerol phosphate synthase domain of the bifunctional enzyme from Escherichia coli by interactions that seem to subtly influence the kinetics of ligand binding.

Phosphoribosyl anthranilate isomerase catalyzes a reversible amadori reaction

Data from steady state and transient kinetics show that the functional phosphoribosyl anthranilate isomerase domain of the naturally bifunctional enzyme from Escherichia coli has properties similar to those of its artificially excised domain. The naturally monofunctional enzyme from Saccharomyces cerevisiae has significantly higher values of both kcat and kcat/KMPRA. The primary product of a single turnover of phosphoribosylanthranilate is fluorescent, but it slowly isomerizes to the nonfluorescent stable product. The latter is the competent substrate of indoleglycerol phosphate synthase, which catalyzes the subsequent step of tryptophan biosynthesis. The isomerization is characterized by a monoexponential decay independent of phosphoribosyl anthranilate isomerase. Due to a tentative assignment of the fluorescent, primary product and the nonfluorescent, stable product to an enol and a keto compound, respectively, tryptophan biosynthesis appears to be rate-limited by an uncatalyzed enol/keto tautomerization. A formal kinetic mechanism of the reaction catalyzed by phosphoribosyl anthranilate isomerase is proposed that is consistent with the combined enzymic and ligand binding properties of the three variants of phosphoribosyl anthranilate isomerase.

The ribose 5-phosphate isomerase-encoding gene is located immediately downstream from that encoding murine immunoglobulin kappa

The immunoglobulin kappa locus (Ig kappa) is active only in the B-lymphocyte cell lineage. By exon-trapping we found a gene situated downstream from the murine Ig kappa locus. This gene encodes a protein with 53% sequence identity to the ribose 5-phosphate isomerase A (RPI-A) of Escherichia coli and is therefore likely to be the murine homologue (mRPI) of this enzyme. We confirmed this assumption by showing that a glutathione S-transferase (GST)::mRPI fusion protein has enzymatic activity and that an anti-mRPI antibody detects a protein of the predicted mass of RPI (33 kDa). Cloning and sequencing of the human counterpart show that the RPI gene is evolutionarily conserved. The expression of mRPI is not influenced by the rearrangement status of the Ig kappa locus in B cells and mRPI is expressed in all tissues. We thus show that two genes with very different expression patterns, a housekeeping gene and a gene expressed in a tissue-specific manner, can be located on a chromosome in close proximity to each other.

Arabidopsis phosphoribosylanthranilate isomerase: molecular genetic analysis of triplicate tryptophan pathway genes

Phosphoribosylanthranilate isomerase (PAI) catalyzes the third step of the tryptophan biosynthetic pathway. Arabidopsis PAI cDNAs were cloned from a cDNA expression library by complementation of an Escherichia coli trpC- PAI deficiency mutation. Genomic DNA blot hybridization analysis detected three nonallelic genes encoding PAI in the Arabidopsis genome. DNA sequence analysis of cDNA and genomic clones indicated that the PAI1 and PAI2. All three PAI polypeptides possess an N-terminal putative plastid target sequence, suggesting that these enzymes all function in plastids. The PAI1 gene is flanked by nearly identical direct repeats of approximately 350 nucleotides. Our results indicate that, in contrast to most microorganisms, the Arabidopsis PAI protein is not fused with indole-3-glycerolphosphate synthase, which catalyzes the next step in the pathway. Yeast artificial chromosome hybridization studies indicated that the PAI2 gene is tightly linked to the anthranilate synthase alpha subunit 1 (ASA1) gene on chromosome 5. PAI1 was mapped to the top of chromosome 1 using recombinant inbred lines, and PAI3 is loosely linked to PAI1. cDNA restriction mapping and sequencing and RNA gel blot hybridization analysis indicated that all three genes are transcribed in wild-type plants. The expression of antisense PAI1 RNA significantly reduced the immunologically observable PAI protein and enzyme activity in transgenic plants. The plants expressing antisense RNA also showed two phenotypes consistent with a block early in the pathway: blue fluorescence under UV light and resistance to the anthranilate analog 6-methylanthranilate. The extreme nucleotide conservation between the unlinked PAI1 and PAI2 loci suggests that this gene family is actively evolving.

Wild-type and mutant D-xylose isomerase from Actinoplanes missouriensis: metal-ion dissociation constants, kinetic parameters of deuterated and non-deuterated substrates and solvent-isotope effects

The metal-ion dissociation constants (Mg2+, Mn2+) of wild-type and mutant D-xylose isomerases from Actinoplanes missouriensis have been determined by titrating the metal-ion-free enzymes with Mg2+ and Mn2+ respectively. Substitution of amino acids co-ordinated to metal-ion 1 (E181D, D245N) dramatically affects the dissociation constants, pH-activity profiles and apparent substrate binding. Mutagenesis of groups ligated to metal-ion 2 is less drastic except for that of Asp-255: a decrease in metal-ion affinity, a change in metal-ion preference and an improved apparent substrate binding (at pH values above the optimum), especially in the presence of Mn2+, are observed for the D255N enzyme. Similar effects, except for a slightly increased metal-ion affinity, are obtained by mutagenesis of the adjacent Glu-186 to Gln and the unconserved Ala-25 to Lys. Moreover, the striking acidic-pH shifts observed for the D255N and E186Q enzymes support the crucial role of the water molecule, Wa-690, Asp-255 and the adjacent Glu-186 in proton transfer from 2-OH to O-1 of the open and extended aldose substrate. Mutations of other important groups scarcely affect the metal-ion dissociation constants and pH-activity profiles, although pronounced effects on the kinetic parameters may be observed.

Design, synthesis, and characterization of a potent xylose isomerase inhibitor, D-threonohydroxamic acid, and high-resolution X-ray crystallographic structure of the enzyme-inhibitor complex

The binding of a potent inhibitor to the enzyme D-xylose isomerase from Streptomyces olivochromogenes was examined by kinetics and X-ray crystallography. The inhibitor D-threonohydroxamic acid (THA) was designed to mimic the putative transition state of the isomerization step catalyzed by the enzyme on the substrate xylose. THA was synthesized and found to be a slow-binding competitive inhibitor with the substrate glucose. The Ki < or = 100 nM was at least one million-fold less than the KM for glucose. The X-ray crystallographic structure of xylose isomerase with THA soaked into the crystals (concentration = 1000Ki) was obtained to 1.6-A resolution and refined to an R factor of 21.6%. The free enzyme and the enzyme in the xylose isomerase-THA complex show no significant structural differences. THA binds in an analogous fashion to glucose, in a linear conformation, forming ligands with Mg-1 and Mg-2 and hydrogen bonds with His53 and Lys182. On the basis of these similarities to glucose binding and its potent inhibition, we propose that THA resembles the transition state for the enzyme-catalyzed hydride transfer reaction. The THA C2 hydroxyl forms a bridging ligand between Mg-1 and Mg-2; it must be deprotonated to do so. By analogy, we propose that, during the catalytic reaction, C2 of the substrate glucose is deprotonated, and that this proton can be moved to the C1 hydroxyl concomitant with hydride transfer. We find evidence for metal movement during catalysis upon deprotonation of the C2 hydroxyl, to allow formation of a bridging ligand.(ABSTRACT TRUNCATED AT 250 WORDS)