Improvement of Selenomonas ruminantium ß-xylosidase thermal stability by replacing buried free cysteines via site directed mutagenesis.

ß-xylosidase is an essential enzyme for breakdown of xylan to d-xylose. It has a significant potential application value for medicine, food, paper and pulp, and biofuel industries. Due to the negative consequences caused by buried free cysteine residues, mutational substitution of such residues is often accompanied by a notable increase in thermal stability. To characterize the role of cysteine residues in the structure, function and stability of Selenomonas ruminantium ß-d-Xylosidase (SXA), we prepared and evaluated wild-type and four cysteines- deficient SXA proteins. Buried cysteine residues were replaced with. In comparison with the wild-type, the Km values of the mutants remained relatively constant while their kcat values decreased. The C101V and C286V displayed higher thermal stability than the wild-type at 55 and 60 °C. Conformational changes of the secondary and tertiary structure as derived from circular dichroism and fluorescence spectroscopy revealed that changing a buried cysteine to a hydrophobic residue could lead to an increase in thermal stability with minimal perturbation of the wild-type protein structure. In addition to experimental methods, the stability of WT SXA and C101V and C286V mutants at 333 K was also studied by MD simulation. Our theoretical data had a good agreement with the experimental results.

[High-level expression and characterization of Selenomonas ruminantium ß-xylosidase in Pichia pastoris].

ß-xylosidase (EC 3.2.1.37) is an important part of the xylanolytic enzymes system. In the present research, ß-xylosidase gene Sxa derived from Selenomonas ruminantium was expressed in Pichia pastoris GS115. According to the codon bias and rare codons of P. pastoris, mRNA secondary structure and GC content, Sxa gene was optimized. The optimized full-length gene mSxa was obtained by gene synthesis technique and the recombinant yeast expression vector pPIC9K-mSxa was constructed. After being digested by restriction enzyme BglⅡ, the mSxa gene was transformed into P. pastoris GS115. Then, phenotype and geneticin G418 resistance screening, and PCR were adopted to identify the positive transformants. Finally, the recombinant P. pastoris GS115-pPIC9K-mSxa was obtained. Based on enzymatic activity assay, a high-level expression clone was picked up and then the enzymatic characteristics of the recombinant ß-xylosidase were studied. The results showed that the molecular weight of the mSxa expressed in P. pastoris G115 was about 66 kDa. The maximum activity was achieved 287.61 IU/mL at fermenter level. Enzymatic characterization showed the ß-xylosidase was stable between 40 ℃ and 60 ℃, and pH between 5.0 and 7.0. The optimal reaction temperature and pH were 55 ℃ and 6.0, and preferentially degrading the ß-xylose glycosidic bond. The enzymatic activity was activated by Mn²âº and Ca²âº, and inhibited by Fe³âº, Cu²âº, Co²âº, Mg²âº, EDTA and SDS. The study indicates that the modified ß-xylosidase gene mSxa from Selenomonas ruminantium can express successfully with high activity in P. pastoris. The study lays a foundation for further industrial application of the ß-xylosidase.

Bacterial PhyA protein-tyrosine phosphatase-like myo-inositol phosphatases in complex with the Ins(1,3,4,5)P4 and Ins(1,4,5)P3 second messengers.

myo-Inositol phosphates (IPs) are important bioactive molecules that have multiple activities within eukaryotic cells, including well-known roles as second messengers and cofactors that help regulate diverse biochemical processes such as transcription and hormone receptor activity. Despite the typical absence of IPs in prokaryotes, many of these organisms express IPases (or phytases) that dephosphorylate IPs. Functionally, these enzymes participate in phosphate-scavenging pathways and in plant pathogenesis. Here, we determined the X-ray crystallographic structures of two catalytically inactive mutants of protein-tyrosine phosphatase-like myo-inositol phosphatases (PTPLPs) from the non-pathogenic bacteria Selenomonas ruminantium (PhyAsr) and Mitsuokella multacida (PhyAmm) in complex with the known eukaryotic second messengers Ins(1,3,4,5)P4 and Ins(1,4,5)P3 Both enzymes bound these less-phosphorylated IPs in a catalytically competent manner, suggesting that IP hydrolysis has a role in plant pathogenesis. The less-phosphorylated IP binding differed in both the myo-inositol ring position and orientation when compared with a previously determined complex structure in the presence of myo-inositol-1,2,3,4,5,6-hexakisphosphate (InsP6 or phytate). Further, we have demonstrated that PhyAsr and PhyAmm have different specificities for Ins(1,2,4,5,6)P5, have identified structural features that account for this difference, and have shown that the absence of these features results in a broad specificity toward Ins(1,2,4,5,6)P5 These features are main-chain conformational differences in loops adjacent to the active site that include the extended loop prior to the penultimate helix, the extended Ω-loop, and a ß-hairpin turn of the Phy-specific domain.

Lysine Decarboxylase with an Enhanced Affinity for Pyridoxal 5-Phosphate by Disulfide Bond-Mediated Spatial Reconstitution.

Lysine decarboxylase (LDC) catalyzes the decarboxylation of l-lysine to produce cadaverine, an important industrial platform chemical for bio-based polyamides. However, due to high flexibility at the pyridoxal 5-phosphate (PLP) binding site, use of the enzyme for cadaverine production requires continuous supplement of large amounts of PLP. In order to develop an LDC enzyme from Selenomonas ruminantium (SrLDC) with an enhanced affinity for PLP, we introduced an internal disulfide bond between Ala225 and Thr302 residues with a desire to retain the PLP binding site in a closed conformation. The SrLDCA225C/T302C mutant showed a yellow color and the characteristic UV/Vis absorption peaks for enzymes with bound PLP, and exhibited three-fold enhanced PLP affinity compared with the wild-type SrLDC. The mutant also exhibited a dramatically enhanced LDC activity and cadaverine conversion particularly under no or low PLP concentrations. Moreover, introduction of the disulfide bond rendered SrLDC more resistant to high pH and temperature. The formation of the introduced disulfide bond and the maintenance of the PLP binding site in the closed conformation were confirmed by determination of the crystal structure of the mutant. This study shows that disulfide bond-mediated spatial reconstitution can be a platform technology for development of enzymes with enhanced PLP affinity.

Engineering disulfide bonds in Selenomonas ruminantium ß-xylosidase by experimental and computational methods.

Homotetrameric ß-xylosidase from Selenomonas ruminantium (SXA) is one of the most efficient enzymes known for the hydrolysis of cell wall hemicellulose. SXA shows a rapid rate of activity loss at temperatures above 50°C. In this study, we have introduced two inter-subunit disulfide bridges with one point mutation. Lys237 was chosen to be replaced with cysteine since it interacts with the same residue in the opposite subunit. While pH optimum, temperature profile and catalytic efficiency of the mutated variant were similar to the native enzyme, the mutated enzyme showed about 40% increase in thermal stability at 55°C. Our results showed that introduction of a single residue mutation in structure of SXA results in appearance of two disulfide bonds at dimer-dimer interface of the enzyme. Coarse-grained molecular dynamics (CG-MD) simulations also proved lower amounts of root mean square fluctuation (RMSF) for position 237 and potential energy for mutated SXA. Based these results, we suggest that choosing a correct residue for mutation in multi subunit proteins results in multiple site conversions which equals to several simultaneous mutations. Furthermore, CG-MD simulation in agreement with experimental methods showed higher thermostability of mutated SXA which proved applicability of this simulation for thermostability analysis.

Crystal Structure and Pyridoxal 5-Phosphate Binding Property of Lysine Decarboxylase from Selenomonas ruminantium.

Lysine decarboxylase (LDC) is a crucial enzyme for acid stress resistance and is also utilized for the biosynthesis of cadaverine, a promising building block for bio-based polyamides. We determined the crystal structure of LDC from Selenomonas ruminantium (SrLDC). SrLDC functions as a dimer and each monomer consists of two distinct domains; a PLP-binding barrel domain and a sheet domain. We also determined the structure of SrLDC in complex with PLP and cadaverine and elucidated the binding mode of cofactor and substrate. Interestingly, compared with the apo-form of SrLDC, the SrLDC in complex with PLP and cadaverine showed a remarkable structural change at the PLP binding site. The PLP binding site of SrLDC contains the highly flexible loops with high b-factors and showed an open-closed conformational change upon the binding of PLP. In fact, SrLDC showed no LDC activity without PLP supplement, and we suggest that highly flexible PLP binding site results in low PLP affinity of SrLDC. In addition, other structurally homologous enzymes also contain the flexible PLP binding site, which indicates that high flexibility at the PLP binding site and low PLP affinity seems to be a common feature of these enzyme family.

Cloning and high-level expression of ß-xylosidase from Selenomonas ruminantium in Pichia pastoris by optimizing of pH, methanol concentration and temperature conditions.

ß-xylosidase and several other glycoside hydrolase family members, including xylanase, cooperate together to degrade hemicelluloses, a commonly found xylan polymer of plant-cell wall. ß-d-xylosidase/α-l-arabinofuranosidase from the ruminal anaerobic bacterium Selenomonas ruminantium (SXA) has potential utility in industrial processes such as production of fuel ethanol and other bioproducts. The optimized synthetic SXA gene was overexpressed in methylotrophic Pichia pastoris under the control of alcohol oxidase I (AOX1) promoter and secreted into the medium. Recombinant protein showed an optimum pH 4.8 and optimum temperature 50 °C. Furthermore, optimization of growth and induction conditions in shake flask was carried out. Using the optimum expression condition (pH 6, temperature 20 °C and 1% methanol induction), protein production was increased by about three times in comparison to the control. The recombinant SXA we have expressed here showed higher turnover frequency using ρ-nitrophenyl ß-xylopyranoside (PNPX) substrate, in contrast to most xylosidase experiments reported previously. This is the first report on the cloning and expression of a ß-xylosidase gene from glycoside hydrolase (GH) family 43 in Pichia pastoris. Our results confirm that P. pastoris is an appropriate host for high level expression and production of SXA for industrial applications.

Effects of nitrate addition to a diet on fermentation and microbial populations in the rumen of goats, with special reference to Selenomonas ruminantium having the ability to reduce nitrate and nitrite.

This study investigated the effects of dietary nitrate addition on ruminal fermentation characteristics and microbial populations in goats. The involvement of Selenomonas ruminantium in nitrate and nitrite reduction in the rumen was also examined. As the result of nitrate feeding, the total concentration of ruminal volatile fatty acids decreased, whereas the acetate : propionate ratio and the concentrations of ammonia and lactate increased. Populations of methanogens, protozoa and fungi, as estimated by real-time PCR, were greatly decreased as a result of nitrate inclusion in the diet. There was modest or little impact of nitrate on the populations of prevailing species or genus of bacteria in the rumen, whereas Streptococcus bovis and S. ruminantium significantly increased. Both the activities of nitrate reductase (NaR) and nitrite reductase (NiR) per total mass of ruminal bacteria were increased by nitrate feeding. Quantification of the genes encoding NaR and NiR by real-time PCR with primers specific for S. ruminantium showed that these genes were increased by feeding nitrate, suggesting that the growth of nitrate- and nitrite-reducing S. ruminantium is stimulated by nitrate addition. Thus, S. ruminantium is likely to play a major role in nitrate and nitrite reduction in the rumen.

Efficient production of mutant phytase (phyA-7) derived from Selenomonas ruminantium using recombinant Escherichia coli in pilot scale.

A mutant gene of rumen phytase (phyA-7) was cloned into pET23b(+) vector and expressed in the Escherichia coli BL21 under the control of the T7 promoter. The study of fermentation conditions includes the temperature impacts of mutant phytase expression, the effect of carbon supplements over induction stage, the inferences of acetic acid accumulation upon enzyme expression and the comparison of one-stage and two-stage operations in batch mode. The maximum value of phytase activity was reached 107.0 U mL(-1) at induction temperature of 30°C. Yeast extract supplement demonstrated a significant increase on both protein concentration and phytase activity. The acetic acid (2 g L(-1)) presented in the modified synthetic medium demonstrated a significant decrease on expressed phytase activity. A two-stage batch operation enhanced the level of phytase activity from 306 to 1204 U mL(-1) in the 20 L of fermentation scale. An overall 3.7-fold improvement in phytase yield (35,375.72-1,31,617.50 U g(-1) DCW) was achieved in the two-stage operation.

Substrate binding in protein-tyrosine phosphatase-like inositol polyphosphatases.

Protein-tyrosine phosphatase-like inositol polyphosphatases are microbial enzymes that catalyze the stepwise removal of one or more phosphates from highly phosphorylated myo-inositols via a relatively ordered pathway. To understand the substrate specificity and kinetic mechanism of these enzymes we have determined high resolution, single crystal, x-ray crystallographic structures of inactive Selenomonas ruminantium PhyA in complex with myo-inositol hexa- and pentakisphosphate. These structures provide the first glimpse of a myo-inositol polyphosphatase-ligand complex consistent with its known specificity and reveal novel features of the kinetic mechanism. To complement the structural studies, fluorescent binding assays have been developed and demonstrate that the K(d) for this enzyme is several orders of magnitude lower than the K(m). Together with rapid kinetics data, these results suggest that the protein tyrosine phosphatase-like inositol polyphosphatases have a two-step, substrate-binding mechanism that facilitates catalysis.

Opposing influences by subsite -1 and subsite +1 residues on relative xylopyranosidase/arabinofuranosidase activities of bifunctional ß-D-xylosidase/α-L-arabinofuranosidase.

Conformational inversion occurs 7-8kcal/mol more readily in furanoses than pyranoses. This difference is exploited here to probe for active-site residues involved in distorting pyranosyl substrate toward reactivity. Spontaneous glycoside hydrolysis rates are ordered 4-nitrophenyl-α-l-arabinofuranoside (4NPA)>4-nitrophenyl-ß-d-xylopyranoside (4NPX)>xylobiose (X2). The bifunctional ß-d-xylosidase/α-l-arabinofuranosidase exhibits the opposite order of reactivity, illustrating that the enzyme is well equipped in using pyranosyl groups of natural substrate X2 in facilitating glycoside hydrolysis. Probing the roles of all 17 active-site residues by single-site mutation to alanine and by changing both moieties of substrate demonstrates that the mutations of subsite -1 residues decrease the ratio k(cat)(4NPX/4NPA), suggesting that the native residues support pyranosyl substrate distortion, whereas the mutations of subsite +1 and the subsite -1/+1 interface residues increase the ratio k(cat)(4NPX/4NPA), suggesting that the native residues support other factors, such as C1 migration and protonation of the leaving group. Alanine mutations of subsite -1 residues raise k(cat)(X2/4NPX) and alanine mutations of subsite +1 and interface residues lower k(cat)(X2/4NPX). We propose that pyranosyl substrate distortion is supported entirely by native residues of subsite -1. Other factors leading to the transition state are supported entirely by native residues of subsite +1 and interface residues.

Engineering lower inhibitor affinities in ß-D-xylosidase of Selenomonas ruminantium by site-directed mutagenesis of Trp145.

ß-D-Xylosidase/α-L-arabinofuranosidase from Selenomonas ruminantium is the most active enzyme reported for catalyzing hydrolysis of 1,4-ß-D-xylooligosaccharides to D-xylose. One property that could use improvement is its relatively high affinities for D-glucose and D-xylose (K (i) ~ 10 mM), which would impede its performance as a catalyst in the saccharification of lignocellulosic biomass for the production of biofuels and other value-added products. Previously, we discovered that the W145G variant expresses K(i)(D-glucose) and K(i)(D-xylose) twofold and threefold those of the wild-type enzyme. However, in comparison to the wild type, the variant expresses 11% lower k(cat)(D-xylobiose) and much lower stabilities to temperature and pH. Here, we performed saturation mutagenesis of W145 and discovered that the variants express K (i) values that are 1.5-2.7-fold (D-glucose) and 1.9-4.6-fold (D-xylose) those of wild-type enzyme. W145F, W145L, and W145Y express good stability and, respectively, 11, 6, and 1% higher k(cat)(D-xylobiose) than that of the wild type. At 0.1 M D-xylobiose and 0.1 M D-xylose, kinetic parameters indicate that W145F, W145L, and W145Y catalytic activities are respectively 46, 71, and 48% greater than that of the wild-type enzyme.

Lactate dehydrogenase gene variability among predominant lactate utilizing ruminal bacteria.

The inter- and intraspecies variability of lactate dehydrogenase (ldh) gene was determined among the predominant ruminal lactate utilizing bacteria. Nearly complete nucleotide sequences of ldh gene, encoding NAD-dependent lactate dehydrogenase of three Megasphaera elsdenii and six Selenomonas ruminantium strains, were obtained and compared. Phylogenetic analyses revealed a limited variability between the ldh sequences studied. The majority of differences observed were silent mutations at the 3rd position of codons. Surprisingly, the intraspecies diversity of the ldh gene among S. ruminantium isolates was higher than the interspecies level between S. ruminantium and M. elsdenii, which strongly suggests the possibility of acquisition of this gene by horizontal gene transfer.

Properties and applications of microbial beta-D-xylosidases featuring the catalytically efficient enzyme from Selenomonas ruminantium.

Xylan 1,4-beta-D-xylosidase catalyzes hydrolysis of non-reducing end xylose residues from xylooligosaccharides. The enzyme is currently used in combination with beta-xylanases in several large-scale processes for improving baking properties of bread dough, improving digestibility of animal feed, production of D-xylose for xylitol manufacture, and deinking of recycled paper. On a grander scale, the enzyme could find employment alongside cellulases and other hemicellulases in hydrolyzing lignocellulosic biomass so that reaction product monosaccharides can be fermented to biofuels such as ethanol and butanol. Catalytically efficient enzyme, performing under saccharification reactor conditions, is critical to the feasibility of enzymatic saccharification processes. This is particularly important for beta-xylosidase which would catalyze breakage of more glycosidic bonds of hemicellulose than any other hemicellulase. In this paper, we review applications and properties of the enzyme with emphasis on the catalytically efficient beta-D-xylosidase from Selenomonas ruminantium and its potential use in saccharification of lignocellulosic biomass for producing biofuels.

beta-D-Xylosidase from Selenomonas ruminantium: role of glutamate 186 in catalysis revealed by site-directed mutagenesis, alternate substrates, and active-site inhibitor.

beta-D-Xylosidase/alpha-L-arabinofuranosidase from Selenomonas ruminantium is the most active enzyme known for catalyzing hydrolysis of 1,4-beta-D-xylooligosaccharides to D-xylose. Catalysis and inhibitor binding by the GH43 beta-xylosidase are governed by the protonation states of catalytic base (D14, pKa 5.0) and catalytic acid (E186, pKa 7.2). Biphasic inhibition by triethanolamine of E186A preparations reveals minor contamination by wild-type-like enzyme, the contaminant likely originating from translational misreading. Titration of E186A preparations with triethanolamine allows resolution of binding and kinetic parameters of the E186A mutant from those of the contaminant. The E186A mutation abolishes the pKa assigned to E186; mutant enzyme binds only the neutral aminoalcohol pH-independent K(triethanolamine)(i)=19 mM), whereas wild-type enzyme binds only the cationic aminoalcohol pH-independent K(triethanolamine)(i)=0.065 mM. At pH 7.0 and 25 degrees C, relative kinetic parameter, k(4NPX)(cat)=k(4NPA)(cat), for substrates 4-nitrophenyl-beta-D-xylopyranoside (4NPX) and 4-nitrophenyl-alpha-L-arabinofuranoside (4NPA) of E186A is 100-fold that of wild-type enzyme, consistent with the view that, on the enzyme, protonation is of greater importance to the transition state of 4NPA whereas ring deformation dominates the transition state of 4NPX.

Engineering lower inhibitor affinities in beta-D-xylosidase.

Beta-D-Xylosidase catalyzes hydrolysis of xylooligosaccharides to D-xylose residues. The enzyme, SXA from Selenomonas ruminantium, is the most active catalyst known for the reaction; however, its activity is inhibited by D-xylose and D-glucose (K (i) values of approximately 10(-2) M). Higher K (i)'s could enhance enzyme performance in lignocellulose saccharification processes for bioethanol production. We report here the development of a two-tier high-throughput screen where the 1 degrees screen selects for activity (active/inactive screen) and the 2 degrees screen selects for a higher K (i(D-xylose)) and its subsequent use in screening approximately 5,900 members of an SXA enzyme library prepared using error-prone PCR. In one variant, termed SXA-C3, K (i(D-xylose)) is threefold and K (i(D-glucose)) is twofold that of wild-type SXA. C3 contains four amino acid mutations, and one of these, W145G, is responsible for most of the lost affinity for the monosaccharides. Experiments that probe the active site with ligands that bind only to subsite -1 or subsite +1 indicate that the changed affinity stems from changed affinity for D-xylose in subsite +1 and not in subsite -1 of the two-subsite active site. Trp145 is 6 A from the active site, and its side chain contacts three active-site residues, two in subsite +1 and one in subsite -1.

Dilution rates influence ammonia-assimilating enzyme activities and cell parameters of Selenomonas ruminantium strain D in continuous (glucose-limited) culture.

AIMS: The objective of this study was to examine the effect of dilution rates (Ds, varying from 0.05 to 0.42 h(-1)) in glucose-limited continuous culture on cell yield, cell composition, fermentation pattern and ammonia assimilation enzymes of Selenomonas ruminantium strain D. METHODS AND RESULTS: All glucose-limited continuous culture experiments were conducted under anaerobic conditions. Except for protein, all cell constituents including carbohydrates, RNA and DNA yielded significant cubic responses to Ds with the highest values at Ds of either 0.10 or 0.20 h(-1). At Ds higher than 0.2 h(-1), fermentation acid pattern shifted primarily from propionate and acetate to lactate production. Succinate also accumulated at the higher Ds (0.30 and 0.42 h(-1)). Glucose was most efficiently utilized by S. ruminantium D at 0.20 h(-1) after which decreases in glucose and ATP yields were observed. Under energy limiting conditions, glutamine synthetase (GS) and glutamate dehydrogenase (GDH) appeared to be the major enzymes involved in nitrogen assimilation suggesting that other potential ammonia incorporating enzymes were of little importance in ammonia assimilation in S. ruminantium D. GS exhibited lower activities than GDH at all Ds, which indicates that the bacterial growth rate is not a primary regulator of their activities. CONCLUSIONS: Studied dilution rates influenced cell composition, fermentation pattern and nitrogen assimilation of S. ruminantium strain D grown in glucose-limited continuous culture. SIGNIFICANCE AND IMPACT OF THE STUDY: Selenomonas ruminantium D is an ecologically and evolutionary important bacterium in ruminants and is present under most rumen dietary conditions. Characterizing the growth physiology and ammonia assimilation enzymes of S. ruminantium D during glucose limitation at Ds, which simulate the liquid turnover rates in rumen, will provide a better understanding of how this micro-organism responds to differing growth conditions.

Aminoalcohols as probes of the two-subsite active site of beta-D-xylosidase from Selenomonas ruminantium.

Catalysis and inhibitor binding by the GH43 beta-xylosidase are governed by the protonation states of catalytic base (D14, pK(a) 5.0) and catalytic acid (E186, pK(a) 7.2) which reside in subsite -1 of the two-subsite active site. Cationic aminoalcohols are shown to bind exclusively to subsite -1 of the catalytically-inactive, dianionic enzyme (D14(-)E186(-)). Enzyme (E) and aminoalcohols (A) form E-A with the affinity progression: triethanolamine>diethanolamine>ethanolamine. E186A mutation raises the K(i)(triethanolamine) 1000-fold. By occupying subsite -1 with aminoalcohols, affinity of monosaccharide inhibitors (I) for subsite +1 is demonstrated. The single access route for ligands into the active site dictates ordered formation of E-A followed by E-A-I. E-A-I forms with the affinity progression: ethanolamine>diethanolamine>triethanolamine. The latter affinity progression is seen in formation of E-A-substrate complexes with substrate 4-nitrophenyl-beta-d-xylopyranoside (4NPX). Inhibition patterns of aminoalcohols versus 4NPX appear competitive, noncompetitive, and uncompetitive depending on the strength of E-A-4NPX. E-A-substrate complexes form weakly with substrate 4-nitrophenyl-alpha-l-arabinofuranoside (4NPA), and inhibition patterns appear competitive. Biphasic inhibition by triethanolamine reveals minor (<0.03%) contamination of E186A preparations (including a His-Tagged form) by wild-type-like enzyme, likely originating from translational misreading. Aminoalcohols are useful in probing glycoside hydrolases; they cause artifacts when used unwarily as buffer components.

Beta-D-xylosidase from Selenomonas ruminantium: thermodynamics of enzyme-catalyzed and noncatalyzed reactions.

Beta-D-Xylosidase/alpha-L-arabinofuranosidase from Selenomonas ruminantium is the most active enzyme known for catalyzing hydrolysis of 1,4-beta-D: -xylooligosaccharides to D-xylose. Temperature dependence for hydrolysis of 4-nitrophenyl-beta-D-xylopyranoside (4NPX), 4-nitrophenyl-alpha-L-arabinofuranoside (4NPA), and 1,4-beta-D-xylobiose (X2) was determined on and off (k (non)) the enzyme at pH 5.3, which lies in the pH-independent region for k (cat) and k (non). Rate enhancements (k (cat)/k (non)) for 4NPX, 4NPA, and X2 are 4.3 x 10(11), 2.4 x 10(9), and 3.7 x 10(12), respectively, at 25 degrees C and increase with decreasing temperature. Relative parameters k (cat) (4NPX)/k (cat) (4NPA), k (cat) (4NPX)/k (cat) (X2), and (k (cat)/K (m))(4NPX)/(k (cat)/K (m))(X2) increase and (k (cat)/K (m))(4NPX)/(k (cat)/K (m))(4NPA), (1/K (m))(4NPX)/(1/K (m))(4NPA), and (1/K (m))(4NPX)/(1/K (m))(X2) decrease with increasing temperature.

Kinetics, substrate specificity, and stereospecificity of two new protein tyrosine phosphatase-like inositol polyphosphatases from Selenomonas lacticifex.

Inositol polyphosphatases (IPPases) play an important role in the metabolism of inositol polyphosphates, a class of molecules involved in signal transduction. Here we characterize 2 new protein tyrosine phosphatase-like IPPases (PhyAsl and PhyBsl) cloned from Selenomonas lacticifex that can hydrolyze myo-inositol hexakisphosphate (InsP6) in vitro. To determine their preferred substrates and stereospecificity of InsP6 dephosphorylation, a combination of kinetic and high-performance ion pair chromatography studies were conducted. Despite only 33% amino acid sequence identity between them, both enzymes display strict specificity for IPP substrates and cleave InsP6 primarily at the D-3-phosphate position (>90%). Furthermore, both enzymes predominantly degrade InsP6 to Ins(2)P via identical and very specific routes of dephosphorylation (3,4,5,6,1). Despite these similarities, PhylAsl is shown to have a slight kinetic preference for the major inositol pentakisphosphate intermediate in its InsP6 hydrolysis pathway, whereas PhyBsl displays a unique and substantial preference for an inositol tetrakisphosphate intermediate.