Analysis of an Erwinia chrysanthemi gene cluster involved in pectin degradation

A group of four genes of Erwinia chrysanthemi involved in pectin degradation has been characterized. These four genes form independent transcription units and are regulated by the negative regulatory gene, kdgR. The functions of two of these genes are known: kduD codes for the 2-keto-3-deoxygluconate oxydoreductase and kdul for the 5-keto-4-deoxyuronate isomerase, two enzymes of the pectin degradation pathway. kdgC has 36% homology with pectate lyase genes of the periplasmic family but its product does not seem to have pectinolytic activity. The fourth gene, kdgF, could have a role in the pathogenicity of E. chrysanthemi. A comparison of the regulatory regions of all the genes controlled by kdgR allowed better definition of the KdgR-binding-site consensus.

Complementation of the inability of Lactobacillus strains to utilize D-xylose with D-xylose catabolism-encoding genes of Lactobacillus pentosus

The inability of two Lactobacillus strains to ferment D-xylose was complemented by the introduction of Lactobacillus pentosus genes encoding D-xylose isomerase, D-xylulose kinase, and a D-xylose catabolism regulatory protein. This result opens the possibility of using D-xylose fermentation as a food-grade selection marker for Lactobacillus spp.

Kinetic studies of Mg(2+)-, Co(2+)- and Mn(2+)-activated D-xylose isomerases

The kinetic parameters for the interconverting substrates D-xylose in equilibrium D-xylulose and D-glucose in equilibrium D-fructose were determined for several D-xylose isomerases, with Mg2+, Co2+ and Mn2+ as metal ion activators. The Km, kcat. and kcat./Km values are tabulated for the anomeric mixtures (observed parameters) as well as for the respective reactive species, i.e. the alpha-pyranose anomers of D-xylose and D-glucose and the alpha-furanose forms of D-xylulose and D-fructose (real parameters). The real Km values and catalytic efficiencies are more favourable for the ketose sugars (reverse reaction) than for the aldose sugars (forward reaction). Comparisons of the kinetic parameters further support the existence of two distinct groups of D-xylose isomerases. Inhibition constants for the cyclic substrate analogues 5-thio-alpha-D-xylopyranose and alpha-D-xylopyranosyl fluoride and for the acyclic substrate analogue xylitol and its dehydrated form 1,5-anhydroxylitol were determined and are discussed.

Enhancing the Thermostability of Glucose Isomerase by Protein Engineering

We have engineered recombinant glucose isomerase (GI) from Actinoplanes missouriensis by site-directed mutagenesis to enhance its thermal stability in both the soluble and immobilized forms. Substitution of arginine for lysine at position 253, which lies at the dimer/dimer interface of the GI tetramer, produced the largest stabilization under model industrial conditions. We discuss our results in terms of a model in which chemical glycation of lysines by sugars in the industrial corn syrup substrate represents a major pathway of destabilization.

L-lyxose metabolism employs the L-rhamnose pathway in mutant cells of Escherichia coli adapted to grow on L-lyxose

Escherichia coli cannot grow on L-lyxose, a pentose analog of the 6-deoxyhexose L-rhamnose, which supports the growth of this and other enteric bacteria. L-Rhamnose is metabolized in E. coli by a system that consists of a rhamnose permease, rhamnose isomerase, rhamnulose kinase, and rhamnulose-1-phosphate aldolase, which yields the degradation products dihydroxyacetone phosphate and L-lactaldehyde. This aldehyde is oxidized to L-lactate by lactaldehyde dehydrogenase. All enzymes of the rhamnose system were found to be inducible not only by L-rhamnose but also by L-lyxose. L-Lyxose competed with L-rhamnose for the rhamnose transport system, and purified rhamnose isomerase catalyzed the conversion of L-lyxose into L-xylulose. However, rhamnulose kinase did not phosphorylate L-xylulose sufficiently to support the growth of wild-type E. coli on L-lyxose. Mutants able to grow on L-lyxose were analyzed and found to have a mutated rhamnulose kinase which phosphorylated L-xylulose as efficiently as the wild-type enzyme phosphorylated L-rhamnulose. Thus, the mutated kinase, mapped in the rha locus, enabled the growth of the mutant cells on L-lyxose. The glycolaldehyde generated in the cleavage of L-xylulose 1-phosphate by the rhamnulose-1-phosphate aldolase was oxidized by lactaldehyde dehydrogenase to glycolate, a compound normally utilized by E. coli.

D-Xylose (D-glucose) isomerase from Arthrobacter strain N.R.R.L. B3728. Gene cloning, sequence and expression

Arthrobacter strain N.R.R.L. B3728 superproduces a D-xylose isomerase that is also a useful industrial D-glucose isomerase. The gene (xylA) that encodes it has been cloned by complementing a xylA mutant of the ancestral strain, with the use of a shuttle vector. The 5' region shows strong sequence similarity to Escherichia coli consensus promoters and ribosome-binding sequences and allows high levels of expression in E. coli. The coding sequence shows similarity to those for other D-xylose isomerases and is followed by 22 nucleotide residues with stop codons in each reading frame, a good 'consensus' ribosome-binding site and an open reading frame showing similarity to those of known D-xylulokinases (xylB). Studies on the expression of the cloned gene in Arthrobacter and in E. coli suggest that the two genes are part of a xyl operon regulated by a repressor that is defective in strain B3728. Codon usage in these two genes, and in another open reading frame (nxi) that was adventitiously isolated during early cloning attempts, shows some characteristic omissions and a strong G + C preference in redundant positions.

Organization, promoter analysis and transcriptional regulation of the Staphylococcus xylosus xylose utilization operon

The Staphylococcus xylosus xyl genes were cloned in Staphylococcus carnosus by complementation to xylose utilization. Xylose isomerase assays under inducing (xylose present) and non-inducing (xylose absent) conditions indicated the presence of a regulated xylA gene on the recombinant plasmid. The nucleotide sequence (4520 bases) revealed three open reading frames with the same polarity. They were identified by sequence homologies as xylR, encoding the Xyl repressor, xylA, encoding xylose isomerase and xylB, encoding xylulokinase. Primer extension analyses indicated constitutive transcription of xylR and xylose-inducible transcription of xylA. Promoter consensus sequences were found upstream of both transcriptional start sites. A transcriptional terminator between xylR and xylA separates the different transcriptional units. Potential regulatory elements were identified by sequence analysis and suggest a repressor-operator mechanism for the regulation of xylAB expression.

D-Xylose (D-glucose) isomerase from Arthrobacter strain N.R.R.L. B3728. Purification and properties

D-Xylose (D-glucose) isomerase was purified to homogeneity in yields of approx. 1 g/kg of wet cells from a strain of Arthrobacter that produces it as about 10% of total soluble protein. It is a tetramer of identical 43,114 Da subunits containing a preponderance of acidic residues and no cysteine. Partial protein sequences were determined as a step to gene cloning. It requires Mg2+, Co2+ or Mn2+ for activity, Mg2+ being best; Ca2+ is an inhibitor, competitive with Mg2+. It is a good D-glucose isomerase with kcat. 1200 min-1 at pH 8 at 60 degrees C, which is higher than that of any other enzyme of this class. L-Arabinose, D-ribose and D-lyxose are poor substrates, with kcat. 78, 31 and 3.7 min-1 respectively at pH 8 at 30 degrees C, compared with 533 min-1 for D-xylose. Xylitol is a true competitive inhibitor for D-xylose (Ki 0.3 mM), but D-sorbitol shows mixed inhibition (Ki 6.5 mM). For D-fructose the pH optimum at 60 degrees C is 8, and at pH 7 the Arrhenius activation energy is 75 kJ/mol over the range 30-70 degrees C.

Molecular cloning, structure, promoters and regulatory elements for transcription of the Bacillus megaterium encoded regulon for xylose utilization

The xylA and xylB genes of Bacillus subtilis BR151 encoding xylose isomerase and xylulokinase, respectively, were disrupted by gene replacement rendering the constructed mutant strain unable to grow on xylose as the sole carbon source. The Bacillus megaterium encoded xyl genes were cloned by complementation of this strain to xylose utilization. The nucleotide sequence of about 4 kbp of the insertion indicates the presence of the xylA and xylB genes on the complementing plasmid. Furthermore, a regulatory gene, xylR, is located upstream of xylA and has opposite polarity to it. The intergenic region between the divergently oriented reading frames of xylR and xylA contains palindromic sequences of 24 bp spaced by five central bp and 29 bp spaced by 11 bp, respectively, and two promoters with opposite orientation as determined by primer extension analysis. They overlap with one nucleotide of their--35 consensus boxes. Transcriptional fusions of lacZ to xylA, xylB and xylR were constructed and revealed that xylA and xylB are repressed in the absence and can be 200-fold induced in the presence of xylose. The increased level of xylAB mRNA in induced and its absence in repressed cells confirms that this regulation occurs on the level of transcription. Deletion of the xylR gene encoding the Xyl repressor results in constitutive expression of xylAB. The transcription of xylR is autoregulated and can be induced 9-fold by xylose. The mechanism of this regulation is not clear. While the apparent xyl operator palindrome is upstream of the xylR promoter, the potential recognition of another palindrome downstream of this promoter by Xyl repressor is discussed.

Molecular cloning, structure, promoters and regulatory elements for transcription of the Bacillus licheniformis encoded regulon for xylose utilization

In this article we describe the cloning of the xyl regulon encoding xylose utilization from Bacillus licheniformis by complementation of a xyl mutant of B. subtilis. The xylose isomerase encoding gene, xylA, was sequenced and identified by its extensive homology to other xylose isomerases. The expression of xylA is regulated on the level of transcription by a repressor protein encoded by xylR. Its gene has the opposite orientation of xylA and the start codons are 181 bp apart. A deletion of xylR renders xylA expression constitutive. The xylR sequence was determined and is discussed with respect to its homology to other xylR structures. Primer extension analyses of the xylA and xylR transcripts under repressing and including conditions define their promoters and confirm the regulation of xylA transcription. Furthermore, some induction of the xylR transcript by xylose is also observed. The regulatory sequence of both genes consists of a bipolar promoter system and contains three palindromic sequence elements. Their potential functions with respect to xylA and xylR regulation are discussed. The primary structures of the genes, promoters and regulatory sequences are compared to the xyl regulons encoded by B. subtilis, B. megaterium, Staphylococcus xylosus and E. coli. Homology is greatest between the B. subtilis and B. megaterium encoded xyl genes while the B. licheniformis borne genes are clearly more distant. The next greater differences are found to the S. xylosus and the greatest to the E. coli encoded genes. These results are discussed with respect to the taxonomic relations of these bacteria.

Switching substrate preference of thermophilic xylose isomerase from D-xylose to D-glucose by redesigning the substrate binding pocket

The substrate specificity of thermophilic xylose isomerase from Clostridium thermosulfurogenes was examined by using predictions from the known crystal structure of the Arthrobacter enzyme and site-directed mutagenesis of the thermophile xylA gene. The orientation of glucose as a substrate in the active site of the thermophilic enzyme was modeled to position the C-6 end of hexose toward His-101 in the substrate-binding pocket. The locations of Met-87, Thr-89, Val-134, and Glu-180, which contact the C-6-OH group of the substrate in the sorbitol-bound xylose isomerase from Arthrobacter [Collyer, C.A., Henrick, K. & Blow, D. M. (1990) J. Mol. Biol. 212, 211-235], are equivalent to those of Trp-139, Thr-141, Val-186, and Glu-232 in the thermophilic enzyme. Replacement of Trp-139 with Phe reduced the Km and enhanced the kcat of the mutant thermophilic enzyme toward glucose, whereas this substitution reversed the effect toward xylose. Replacement of Val-186 with Thr also enhanced the catalytic efficiency of the enzyme toward glucose. Double mutants with replacements Trp-139----Phe/Val-186----Thr and Trp-139----Phe/Val-186----Ser had a higher catalytic efficiency (kcat/Km) for glucose than the wild-type enzyme of 5- and 2-fold, respectively. They also exhibited 1.5- and 3-fold higher catalytic efficiency for D-glucose than for D-xylose, respectively. These results provide evidence that alteration in substrate specificity of factitious thermophilic xylose isomerases can be achieved by designing reduced steric constraints and enhanced hydrogen-bonding capacity for glucose in the substrate-binding pocket of the active site.

Xylose (glucose) isomerase gene from the thermophile Thermus thermophilus: cloning, sequencing, and comparison with other thermostable xylose isomerases

The xylose isomerase gene from the thermophile Thermus thermophilus was cloned by using a fragment of the Streptomyces griseofuscus gene as a probe. The complete nucleotide sequence of the gene was determined. T. thermophilus is the most thermophilic organism from which a xylose isomerase gene has been cloned and characterized. The gene codes for a polypeptide of 387 amino acids with a molecular weight of 44,000. The Thermus xylose isomerase is considerably more thermostable than other described xylose isomerases. Production of the enzyme in Escherichia coli, by using the tac promoter, increases the xylose isomerase yield 45-fold compared with production in T. thermophilus. Moreover, the enzyme from E. coli can be purified 20-fold by simply heating the cell extract at 85 degrees C for 10 min. The characteristics of the enzyme made in E. coli are the same as those of enzyme made in T. thermophilus. Comparison of the Thermus xylose isomerase amino acid sequence with xylose isomerase sequences from other organisms showed that amino acids involved in substrate binding and isomerization are well conserved. Analysis of amino acid substitutions that distinguish the Thermus xylose isomerase from other thermostable xylose isomerases suggests that the further increase in thermostability in T. thermophilus is due to substitution of amino acids which react during irreversible inactivation and results also from increased hydrophobicity.

Isolation and characterization of Escherichia coli mutants able to utilize the novel pentose L-ribose

Wild-type strains of Escherichia coli were unable to utilize L-ribose for growth. However, L-ribose-positive mutants could be isolated from strains of E. coli K-12 which contained a ribitol operon. L-ribose-positive strains of E. coli, isolated after 15 to 20 days, had a growth rate of 0.22 generation per h on L-ribose. Growth on L-ribose was found to induce the enzymes of the L-arabinose and ribitol pathways, but only ribitol-negative mutants derived from strains originally L-ribose positive lost the ability to grow on L-ribose, showing that a functional ribitol pathway was required. One of the mutations permitting growth on L-ribose enabled the mutants to produce constitutively an NADPH-linked reductase which converted L-ribose to ribitol. L-ribose is not metabolized by an isomerization to L-ribulose, as would be predicted on the basis of other pentose pathways in enteric bacteria. Instead, L-ribose was metabolized by the reduction of L-ribose to ribitol, followed by the conversion to D-ribulose by enzymes of the ribitol pathway.

Chloroplast phosphoribulokinase associates with yeast phosphoriboisomerase in the presence of substrate

Pea chloroplastic phosphoribulokinase and yeast phosphoriboisomerase partition independently of one another in a two-phase polyethyleneglycol, dextran system, but apparent interaction is seen when ribose-5-phosphate is added to the two-phase system. It appears that the pea leaf kinase recognizes yeast isomerase when it is carrying metabolite.

Visible, EPR and electron nuclear double-resonance spectroscopic studies on the two metal-binding sites of oxovanadium (IV)-substituted D-xylose isomerase

The two metal-binding sites of the D-xylose isomerase from Streptomyces rubiginosus were studied using VO2+ as a sensor for the ligand environment. Titration of the tetrameric enzyme with VO2+, followed by EPR spectroscopy and inhibition studies, show that the first four VO2+ equivalents occupy, in analogy to Co2+, Cd2+ and Pb2+, the binding site B. The visible absorption data and the EPR parameters indicate that a nitrogen ligand is involved in the ligand sphere of the high-affinity B site. The low-affinity A site could be studied selectively by blocking the B site with visible and EPR-silent Cd2+. The visible data and EPR parameters for this site are consistent with a ligand environment composed of oxygen donors without nitrogen ligation. The nitrogen coordination in the high-affinity site could be demonstrated by electron nuclear double-resonance (ENDOR) studies of the 4VO2+ enzyme, and was assigned to a histidine ligand. The 14N resonances are interpreted in terms of a quartet with a coupling value of 13.2 MHz. 1H-ENDOR coupling of 1.7 MHz, exchangeable in D2O, has been assigned to the N-H proton of the histidine. Additional proton ENDOR couplings, which are not exchangeable, are due to protons bound to the carbon atoms of the histidine. For the low-affinity binding site, a nitrogen coordination could be definitely excluded by the ENDOR measurements. Exchangeable 1H-ENDOR couplings observed in this sample were assigned to H2O ligands in the vicinity of VO2+. The results closely relate to what is known from X-ray structure. However, the relative affinities for the two binding sites seem not to be the same for different bivalent cations. In mixed metal samples with four VO2+ and four Co2+ equivalents, the VO2+ is distributed between both binding sites. Small changes in the complex geometry of the A site, indicated by different EPR features, seem to occur if the B site is occupied by Co2+ or by Cd2+.

Ethanolic fermentation of pentoses in lignocellulose hydrolysates

In the fermentation of lignocellulose hydrolysates to ethanol, two major problems are encountered: the fermentation of the pentose sugar xylose, and the presence of microbial inhibitors. Xylose can be directly fermented with yeasts, such as Pachysolen tannophilus, Candida shehatae, and Pichia stipis, or by isomerization of xylose to xylulose with the enzyme glucose (xylose) isomerase (XI; EC 5.3.1.5), and subsequent fermentation with bakers' yeast, Saccharomyces cerevisiae. The direct fermentation requires low, carefully controlled oxygenation, as well as the removal of inhibitors. Also, the xylose-fermenting yeasts have a limited ethanol tolerance. The combined isomerization and fermentation with XI and S. cerevisiae gives yields and productivities comparable to those obtained in hexose fermentations without oxygenation and removal of inhibitors. However, the enzyme is not very stable in a lignocellulose hydrolysate, and S. cerevisiae has a poorly developed pentose phosphate shunt. Different strategies involving strain adaptation, and protein and genetic engineering adopted to overcome these different obstacles, are discussed.

A metal-mediated hydride shift mechanism for xylose isomerase based on the 1.6 A Streptomyces rubiginosus structures with xylitol and D-xylose

The crystal structure of recombinant Streptomyces rubiginosus D-xylose isomerase (D-xylose keto-isomerase, EC 5.3.1.5) solved by the multiple isomorphous replacement technique has been refined to R = 0.16 at 1.64 A resolution. As observed in an earlier study at 4.0 A (Carrell et al., J. Biol. Chem. 259: 3230-3236, 1984), xylose isomerase is a tetramer composed of four identical subunits. The monomer consists of an eight-stranded parallel beta-barrel surrounded by eight helices with an extended C-terminal tail that provides extensive contacts with a neighboring monomer. The active site pocket is defined by an opening in the barrel whose entrance is lined with hydrophobic residues while the bottom of the pocket consists mainly of glutamate, aspartate, and histidine residues coordinated to two manganese ions. The structures of the enzyme in the presence of MnCl2, the inhibitor xylitol, and the substrate D-xylose in the presence and absence of MnCl2 have also been refined to R = 0.14 at 1.60 A, R = 0.15 at 1.71 A, R = 0.15 at 1.60 A, and R = 0.14 at 1.60 A, respectively. Both the ring oxygen of the cyclic alpha-D-xylose and its C1 hydroxyl are within hydrogen bonding distance of NE2 of His-54 in the structure crystallized in the presence of D-xylose. Both the inhibitor, xylitol, and the extended form of the substrate, D-xylose, bind such that the C2 and C4 OH groups interact with one of the two divalent cations found in the active site and the C1 OH with the other cation. The remainder of the OH groups hydrogen bond with neighboring amino acid side chains. A detailed mechanism for D-xylose isomerase is proposed. Upon binding of cyclic alpha-D-xylose to xylose isomerase, His-54 acts as the catalytic base in a ring opening reaction. The ring opening step is followed by binding of D-xylose, involving two divalent cations, in an extended conformation. The isomerization of D-xylose to D-xylulose involves a metal-mediated 1,2-hydride shift. The final step in the mechanism is a ring closure to produce alpha-D-xylulose. The ring closing is the reverse of the ring opening step. This mechanism accounts for the majority of xylose isomerase's biochemical properties, including (1) the lack of solvent exchange between the 2-position of D-xylose and the 1-pro-R position of D-xylulose, (2) the chemical modification of histidine and lysine, (3) the pH vs. activity profile, and (4) the requirement for two divalent cations in the mechanism.

Transcriptional activation by upstream activator sequences requires distinct interactions with downstream elements in the yeast TRP1 promoter

The interactions between different upstream activator sequences (UAS) and the downstream transcriptional elements of the TRP1 promoter were studied. We have inserted the UAS from the PGK gene into a series of TRP1 promoter deletions such that the PGK UAS is positioned at various distances upstream from or replaces the TRP1 UAS (UAST1). We show that activation of the TRP1 transcription unit I by the PGK UAS shows a marked position dependence, which is solely a function of the position of the PGKUAS relative to sequences involved in the determination of the RNA initiation sites in the TRP1 promoter. No cooperative activation is seen when both UASs are present in the promoter; the PGK UAS is dominant and is not repressed by the TRP1 negative element. In addition, we show that the PGK and TRP1 UASs interact differently with TATA sequence at the TRP1 RNA initiation site. Our results suggest that these UASs are functionally distinct because they use different mechanisms for activating heterologous promoters.

Xylose (glucose) isomerase gene from the thermophile Clostridium thermohydrosulfuricum; cloning, sequencing, and expression in Escherichia coli

The xylose isomerase gene from the thermophile Clostridium thermohydrosulfuricum has been cloned, using a fragment of the Bacillus subtilis gene as a probe. The complete nucleotide sequence of the gene was analyzed. C. thermohydrosulfuricum is the most thermophilic organism from which a xylose isomerase gene has been cloned and characterized. Comparison with amino acid sequences from other xylose isomerases showed that amino acids involved in substrate binding and isomerization are well conserved. Purification of the enzyme produced in E. coli was done by heating a cell-free extract at 85 degrees C for 10 min, giving a 20-fold purified enzyme. The native enzyme is a homomeric tetramer with a molecular weight of 200,000.

Direct evidence of the Entner-Doudoroff pathway operating in the metabolism of D-glucosamine in bacteria

Pseudomonas fluorescens (Migula) (IFO 14808) has both a membrane-bound PQQ-dependent D-glucose (D-Glc) dehydrogenase [EC 1.1.99.17] [which also acts on D-glucosamine (D-GlcN)] and a PLP-dependent D-glucosaminate (D-GlcNA) dehydratase [EC 4.2.1.26]. Further, these two enzymes were induced when D-GlcN was added to the culture medium. However, D-glucosamine-6-phosphate (D-GlcN-6-P) isomerase [EC 5.3.1.10], another enzyme involved in the metabolism of D-GlcN, was only present at a low level in this bacterium. The bacterium was able to grow in a minimal medium containing D-GlcN or D-GlcNA as the sole source of carbon and nitrogen. Intact cells of P. fluorescens (Migula) converted D-GlcN to D-GlcNA and then to 2-keto-3-deoxy-D-gluconate (KDGA). These results demonstrate that D-GlcN is metabolized via D-GlcNA to KDGA in P. fluorescens (Migula) (Entner-Doudoroff pathway). In contrast, Enterobacter cloacae(IFO 13535) and Agrobacterium radiobacter (IAM 1526) have significant amounts of D-GlcN-6-P isomerase with low levels of the D-Glc dehydrogenase and D-GlcNA dehydratase. Further, only the isomerase activity was induced on the addition of D-GlcN to the culture medium. These results demonstrate that there is a new route (Entner-Doudoroff pathway), i.e., in addition to the known one (Embden-Meyerhof pathway), for the metabolism of D-GlcN in bacteria and one of the two routes is predominant in the each of bacteria examined.

Refinement of glucose isomerase from Streptomyces albus at 1.65 A with data from an imaging plate

The structure of 'metal-free' glucose isomerase of Streptomyces albus strain number YT ATCC 21132 has been analysed and refined at 1.65 A. The space group is I222, with cell dimensions a = 93.9 (1), b = 99.7 (1) and c = 102.9 (1) A, and there is one monomer of the tetrameric molecule per asymmetric unit. The data were recorded from two crystals of the protein using synchrotron radiation from the EMBL beamline X11 at DESY, Hamburg. Data were recorded with an imaging plate scanner designed and built in the EMBL Hamburg outstation. The total data-collection time was less than 12 h and the processing of all data took less than 2 days. The coordinates of the Arthrobacter glucose isomerase refined at a resolution of 2.5 A were used as a starting model. The structure of the protein and of 445 associated water molecules in the asymmetric unit were refined by restrained least-squares minimization using all data between 8 and 1.65 A to a final R factor of 14.1%.

Spectroscopic studies on the metal-ion-binding sites of Co2(+)-substituted D-xylose isomerase from Streptomyces rubiginosus

The coordination sphere of the two metal-binding sites/subunit of the homotetrameric D-xylose isomerase from Streptomyces rubiginosus has been probed by the investigation of the Co2(+)-substituted enzyme using electronic absorption, CD and magnetic circular dichroic spectroscopies in the visible region. The spectrum of the high-affinity site (B site) has an absorption coefficient, epsilon 545, of 18 M-1 cm-1, indicating a distorted octahedral complex geometry. The spectrum of the low-affinity site (A site) shows two absorption maxima at 505 nm and 586 nm with epsilon values of 170 M-1 cm-1 and 240 M-1 cm-1, respectively, which indicates a distorted tetrahedral or pentacoordinated complex structure as also observed for the enzyme from Streptomyces violaceoruber [Callens et al. (1988) Biochem. J. 250, 285-290] having the same feature but lower epsilon values. The first 4 mol Co2+ added/mol apoenzyme occupy both sites nearly equally. Subsequently the Co2+ located in the A site slowly moves into the B site. After equilibrium is reached, the next 4 mol Co2+/mol again occupy the A site with its typical spectrum, restoring full activity. Addition of 4 mol Cd2+ or Pb2+/mol Co4-loaded derivative displaces the Co2+ from the B site to form the Pb4/Co4 derivative containing Co2+ in the A site, reducing activity fourfold while the Pb4/Pb4 species is completely inactive. In contrast, Eu3+ displaces Co2+ preferentially from the A site. Thus, the high- and low-affinity sites may be different for different cations. After addition of the substrates D-xylose, D-glucose and D-fructose and the inhibitor xylitol the intense Co2+ A-site spectrum of both the active Co4/Co4 derivative and the less active Pb4/PCo4 derivative decreases, indicating that these compounds are bound to the A site, changing the distorted tetrahedral or pentacoordinated symmetry there to a distorted octahedral complex geometry.

Catalytic mechanism of xylose (glucose) isomerase from Clostridium thermosulfurogenes. Characterization of the structural gene and function of active site histidine

The gene coding for thermophilic xylose (glucose) isomerase of Clostridium thermosulfurogenes was isolated and its complete nucleotide sequence was determined. The structural gene (xylA) for xylose isomerase encodes a polypeptide of 439 amino acids with an estimated molecular weight of 50,474. The deduced amino acid sequence of thermophilic C. thermosulfurogenes xylose isomerase displayed higher homology with those of thermolabile xylose isomerases from Bacillus subtilis (70%) and Escherichia coli (50%) than with those of thermostable xylose isomerases from Ampullariella (22%), Arthrobacter (23%), and Streptomyces violaceoniger (24%). Several discrete regions were highly conserved throughout the amino acid sequences of all these enzymes. To identify the histidine residue of the active site and to elucidate its function during enzymatic xylose or glucose isomerization, histidine residues at four different positions in the C. thermosulfurogenes enzyme were individually modified by site-directed mutagenesis. Substitution of His101 by phenylalanine completely abolished enzyme activity whereas substitution of other histidine residues by phenylalanine had no effect on enzyme activity. When His101 was changed to glutamine, glutamic acid, asparagine, or aspartic acid, approximately 10-16% of wild-type enzyme activity was retained by the mutant enzymes. The Gln101 mutant enzyme was resistant to diethylpyrocarbonate inhibition which completely inactivated the wild-type enzyme, indicating that His101 is the only essential histidine residue involved directly in enzyme catalysis. The constant Vmax values of the Gln101, Glu101, Asn101, and Asp101 mutant enzymes over the pH range of 5.0-8.5 indicate that protonation of His101 is responsible for the reduced Vmax values of the wild-type enzyme at pH below 6.5. Deuterium isotope effects by D-[2-2H]glucose on the rate of glucose isomerization indicated that hydrogen transfer and not substrate ring opening is the rate-determining step for both the wild-type and Gln101 mutant enzymes. These results suggest that the enzymatic sugar isomerization does not involve a histidine-catalyzed proton transfer mechanism. Rather, essential histidine functions to stabilize the transition state by hydrogen bonding to the C5 hydroxyl group of the substrate and this enables a metal-catalyzed hydride shift from C2 to C1.

Molecular cloning, nucleotide sequence, and promoter structure of the Acinetobacter calcoaceticus trpFB operon

The trpFB operon from Acinetobacter calcoaceticus encoding the phosphoribosyl anthranilate isomerase and the beta-subunit of tryptophan synthase has been cloned by complementation of a trpB mutation in A. calcoaceticus, identified by deletion analysis, and sequenced. It encodes potential polypeptides of 214 amino acids with a calculated molecular weight of 23,008 (TrpF) and 403 amino acids with a molecular weight of 44,296 (TrpB). The encoded TrpB sequence shows striking homologies to those from other bacteria, ranging from 47% amino acids identity with the Brevibacterium lactofermentum protein and 64% identity with the Caulobacter crescentus protein. The encoded TrpF sequence, on the other hand, is much less homologous to the ones from other species, ranging between 27% identity with the Bacillus subtilis enzyme and 36% identity with the C. crescentus enzyme. The homologies of both polypeptides are evenly distributed over the entire sequences. The codon usage shows the strong preference for A and T in the third positions typical for A. calcoaceticus genes. The trpFB operon appears to be unlinked to trpA. The trpFB promoter has been determined by primer extension analysis of RNA synthesized from the chromosomally and plasmid-encoded trpFB operons. The starting nucleotides are identical in both cases and define the first promoter from A. calcoaceticus. Potential regulatory features are implied by a palindromic element overlapping the -35 consensus box of the promoter.