Aromatic interactions at the catalytic subsite of sucrose phosphorylase: their roles in enzymatic glucosyl transfer probed with Phe52→Ala and Phe52→Asn mutants

Mutants of Leuconostoc mesenteroides sucrose phosphorylase having active-site Phe(52) replaced by Ala (F52A) or Asn (F52N) were characterized by free energy profile analysis for catalytic glucosyl transfer from sucrose to phosphate. Despite large destabilization (≥3.5kcal/mol) of the transition states for enzyme glucosylation and deglucosylation in both mutants as compared to wild-type, the relative stability of the glucosyl enzyme intermediate was weakly affected by substitution of Phe(52). In reverse reaction where fructose becomes glucocylated, "error hydrolysis" was the preponderant path of breakdown of the covalent intermediate of F52A and F52N. It is proposed, therefore, that Phe(52) facilitates reaction of the phosphorylase through (1) positioning of the transferred glucosyl moiety at the catalytic subsite and (2) strong cation-π stabilization of the oxocarbenium ion-like transition states flanking the covalent enzyme intermediate.     

Interplay of catalytic subsite residues in the positioning of α-d-glucose 1-phosphate in sucrose phosphorylase

Kinetic and molecular docking studies were performed to characterize the binding of α-d-glucose 1-phosphate (αGlc 1-P) at the catalytic subsite of a family GH-13 sucrose phosphorylase (from L. mesenteroides) in wild-type and mutated form. The best-fit binding mode of αGlc 1-P dianion had the phosphate group placed anti relative to the glucosyl moiety (adopting a relaxed ⁴C₁ chair conformation) and was stabilized mainly by hydrogen bonds from residues of the enzyme?s catalytic triad (Asp¹⁹⁶, Glu²³⁷ and Asp²⁹⁵) and from Arg¹³⁷. Additional feature of the αGlc 1-P docking pose was an intramolecular hydrogen bond (2.7 Å) between the glucosyl C2-hydroxyl and the phosphate oxygen. An inactive phosphonate analog of αGlc 1-P did not show binding to sucrose phosphorylase in different experimental assays (saturation transfer difference NMR, steady-state reversible inhibition), consistent with evidence from molecular docking study that also suggested a completely different and strongly disfavored binding mode of the analog as compared to αGlc 1-P. Molecular docking results also support kinetic data in showing that mutation of Phe⁵², a key residue at the catalytic subsite involved in transition state stabilization, had little effect on the ground-state binding of αGlc 1-P by the phosphorylase. However, when combined with a second mutation involving one of the catalytic triad residues, the mutation of Phe⁵² by Ala caused complete (F52A_D196A; F52A_E237A) or very large (F52A_D295A) disruption of the proposed productive binding mode of αGlc 1-P with consequent effects on the enzyme activity. Effects of positioning of αGlc 1-P for efficient glucosyl transfer from phosphate to the catalytic nucleophile of the enzyme (Asp¹⁹⁶) are suggested. High similarity between the αGlc 1-P conformers bound to sucrose phosphorylase (modeled) and the structurally and mechanistically unrelated maltodextrin phosphorylase (experimental) is revealed.     

Mechanistic differences among retaining disaccharide phosphorylases: insights from kinetic analysis of active site mutants of sucrose phosphorylase and alpha,alpha-trehalose phosphorylase

Sucrose phosphorylase utilizes a glycoside hydrolase-like double displacement mechanism to convert its disaccharide substrate and phosphate into alpha-d-glucose 1-phosphate and fructose. Site-directed mutagenesis was employed to characterize the proposed roles of Asp(196) and Glu(237) as catalytic nucleophile and acid-base, respectively, in the reaction of sucrose phosphorylase from Leuconostoc mesenteroides. The side chain of Asp(295) is suggested to facilitate the catalytic steps of glucosylation and deglucosylation of Asp(196) through a strong hydrogen bond (23 kJ/mol) with the 2-hydroxyl of the glucosyl oxocarbenium ion-like species believed to be formed in the transition states flanking the beta-glucosyl enzyme intermediate. An assortment of biochemical techniques used to examine the mechanism of alpha-retaining glucosyl transfer by Schizophyllum commune alpha,alpha-trehalose phosphorylase failed to provide evidence in support of a similar two-step catalytic reaction via a covalent intermediate. Mutagenesis studies suggested a putative active-site structure for this trehalose phosphorylase that is typical of retaining glycosyltransferases of fold family GT-B and markedly different from that of sucrose phosphorylase. While ambiguity remains regarding the chemical mechanism by which the trehalose phosphorylase functions, the two disaccharide phosphorylases have evolved strikingly different reaction coordinates to achieve catalytic efficiency and stereochemical control in their highly analogous substrate transformations.     

Probing enzyme–substrate interactions at the catalytic subsite of Leuconostoc mesenteroides sucrose phosphorylase with site-directed mutagenesis: the roles of Asp49 and Arg395

Abstract

Sucrose phosphorylase is a bacterial α-transglucosidase that catalyses glucosyl transfer from sucrose to phosphate, releasing d-fructose and α-d-glucose 1-phosphate as the product of the first (enzyme glucosylation) and second (enzyme deglucosylation) step of the enzymatic reaction, respectively. The transferred glucosyl moiety of sucrose is accommodated at the catalytic subsite of the phosphorylase through a network of charged hydrogen bonds whereby a highly conserved residue pair of Asp and Arg points towards the equatorial hydroxyl at C₄. To examine the role of this ‘hyperpolar’ binding site for the substrate 4-OH, we have mutated Asp⁴⁹ and Arg³⁹⁵ of Leuconostoc mesenteroides sucrose phosphorylase individually to Ala (D49A) and Leu (R395L), respectively, and also prepared an ‘uncharged’ double mutant harbouring both site-directed substitutions. The efficiency for enzyme glucosylation from sucrose was massively decreased in purified preparations of D49A (10⁷-fold) and R395L (10⁵-fold) as compared to wild-type enzyme. The double mutant was not active above the detection limit. Enzyme deglucosylation to phosphate proceeded relatively efficient in D49A as well as R395L, about 500-fold less than in the wild-type phosphorylase. Substrate inhibition by phosphate and a loss in selectivity for reaction with phosphate as compared to water were new features in the two mutants. Asp⁴⁹ and Arg³⁹⁵ are both essential in the catalytic reaction of L. mesenteroides sucrose phosphorylase.     

Sucrose phosphorylase: a powerful transglucosylation catalyst for synthesis of α-D-glucosides as industrial fine chemicals

Abstract

Sucrose phosphorylase is a bacterial transglucosidase that catalyzes conversion of sucrose and phosphate into α-D-glucose-1-phosphate and D-fructose. The enzyme utilizes a glycoside hydrolase-like double displacement mechanism that involves a catalytically competent β-glucosyl enzyme intermediate. In addition to reaction with phosphate, glucosylated sucrose phosphorylase can undergo hydrolysis to yield α-D-glucose or it can decompose via glucosyl transfer to a hydroxy group in suitable acceptor molecules, giving new α-D-glucosidic products. The glucosyl acceptor specificity of sucrose phosphorylase is reviewed, focusing on applications of the enzyme in glucoside synthesis. Polyhydroxylated compounds such as sugars and sugar alcohols are often glucosylated efficiently. Aryl alcohols and different carboxylic acids also serve as acceptors for enzymatic transglucosylation. The natural osmolyte 2-O-(α-D-glucopyranosyl)-sn-glycerol (GG) was prepared by regioselective glucosylation of glycerol from sucrose using the phosphorylase from Leuconostoc mesenteroides. An industrial process for production of GG as active ingredient of cosmetic formulations has been recently developed. General advantages of sucrose phosphorylase as a transglucosylation catalyst lie in the use of sucrose as a high-energy glucosyl donor and the usually weak hydrolase activity of the enzyme towards substrate and product.     

The role of Asp-295 in the catalytic mechanism of Leuconostoc mesenteroides sucrose phosphorylase probed with site-directed mutagenesis

Replacements of Asp-295 by Asn (D295N) and Glu (D295E) decreased the catalytic center activity of Leuconostoc mesenteroides sucrose phosphorylase to about 0.01% of the wild-type level (k(cat)=200s(-1)). Glucosylation and deglucosylation steps of D295N were affected uniformly, approximately 10(4.3)-fold, and independently of leaving group ability and nucleophilic reactivity of the substrate, respectively. pH dependences of the catalytic steps were similar for D295N and wild-type. The 10(5)-fold preference of the wild-type for glucosyl transfer compared with mannosyl transfer from phosphate to fructose was lost in D295N and D295E. Selective disruption of catalysis to glucosyl but not mannosyl transfer in the two mutants suggests that the side chain of Asp-295, through a strong hydrogen bond with the equatorial sugar 2-hydroxyl, stabilizes the transition states flanking the beta-glucosyl enzyme intermediate by > or = 23kJ/mol.     

Asp-196-->Ala mutant of Leuconostoc mesenteroides sucrose phosphorylase exhibits altered stereochemical course and kinetic mechanism of glucosyl transfer to and from phosphate

Mutagenesis of Asp-196 into Ala yielded an inactive variant of Leuconostoc mesenteroides sucrose phosphorylase (D196A). External azide partly complemented the catalytic defect in D196A with a second-order rate constant of 0.031 M-1 s-1 (pH 5, 30 degrees C) while formate, acetate and halides could not restore activity. The mutant utilized azide to convert alpha-D-glucose 1-phosphate into beta-D-glucose 1-azide, reflecting a change in stereochemical course of glucosyl transfer from alpha-retaining in wild-type to inverting in D196A. Phosphorolysis of beta-D-glucose 1-azide by D196A occurred through a ternary complex kinetic mechanism, in marked contrast to the wild-type whose reactions feature a common glucosyl enzyme intermediate and Ping-Pong kinetics. Therefore, Asp-196 is identified unambiguously as the catalytic nucleophile of sucrose phosphorylase, and its substitution by Ala forces the reaction to proceed via single nucleophilic displacement. D196A is not detectably active as alpha-glucosynthase.     

Selective labelling of the beta-subunit of L-phenylalanyl-tRNA synthetase from E. coli with N-bromoacetyl-L-phenylalanyl-tRNA Phe

L-Phenylalanyl-tRNA synthetase has been reacted with N-bromoacetyl-[¹⁴C]Phe-tRNA^Phe to yield covalently linked enzyme-N-acetyl-[¹⁴C]Phe-tRNA^Phe. The labelled enzyme was dissociated in the presence of 4M guanidinium chloride and the subunits subsequently separated by gel chromatography. The elution pattern is indicative of covalent binding of the tRNA to the β-subunit of the enzyme.     

The effect of substitution of Phe181 and Phe182 with Ala on activity,substrate specificity and stabilization of substrate at the active site of Bacillus thermocatenulatus lipase

Steric hindrance leads to limitation in the access of substrate into the enzyme active site. In order to decrease steric hindrance, two conserved residues, Phe¹⁸¹ and Phe¹⁸², in the lid domain of Bacillus thermocatenulatus lipase were substituted with alanine by using site-directed mutagenesis. As a result, three mutant lipases were produced. Circular dichroism (CD) spectroscopy showed that the secondary structure of all lipases is similar to one another. F181A mutation increased the distance between phe¹⁸¹ and catalytic ser¹¹⁴, which is buried in the active site by 3.24 Å. It can be suggested that such an increase in distance may lead to a decrease in steric hindrance. F181A mutation increased overall lipase activity by up to 2.6-fold (4670 U mg⁻¹) toward C8 substrate. It also resulted in optimal lipase activity at 65 °C rather than 55 °C. F182A mutation increased the distance between phe¹⁸² and catalytic ser¹¹⁴ by 1.54 Å but failed to induce any significant effect on lipase activity. However, F181A–F182A mutation significantly decreased the activity due to decreased van der Waals interactions between the phenyl group of phenylalanines and the acyl chain of triacylglycerol. These results indicate that presence of one of the two residues, Phe¹⁸¹ or Phe¹⁸², is important for stabilizing triacylglycerols in active site.     

Structural rearrangements of sucrose phosphorylase from Bifidobacterium adolescentis during sucrose conversion

The reaction mechanism of sucrose phosphorylase from Bifidobacterium adolescentis (BiSP) was studied by site-directed mutagenesis and x-ray crystallography. An inactive mutant of BiSP (E232Q) was co-crystallized with sucrose. The structure revealed a substrate-binding mode comparable with that seen in other related sucrose-acting enzymes. Wild-type BiSP was also crystallized in the presence of sucrose. In the dimeric structure, a covalent glucosyl intermediate was formed in one molecule of the BiSP dimer, and after hydrolysis of the glucosyl intermediate, a beta-D-glucose product complex was formed in the other molecule. Although the overall structure of the BiSP-glucosyl intermediate complex is similar to that of the BiSP(E232Q)-sucrose complex, the glucose complex discloses major differences in loop conformations. Two loops (residues 336-344 and 132-137) in the proximity of the active site move up to 16 and 4 A, respectively. On the basis of these findings, we have suggested a reaction cycle that takes into account the large movements in the active-site entrance loops.     

Acid-base catalysis in Leuconostoc mesenteroides sucrose phosphorylase probed by site-directed mutagenesis and detailed kinetic comparison of wild-type and Glu237-->Gln mutant enzymes

The role of acid-base catalysis in the two-step enzymatic mechanism of alpha-retaining glucosyl transfer by Leuconostoc mesenteroides sucrose phosphorylase has been examined through site-directed replacement of the putative catalytic Glu237 and detailed comparison of purified wild-type and Glu237-->Gln mutant enzymes using steady-state kinetics. Reactions with substrates requiring Br?nsted catalytic assistance for glucosylation or deglucosylation were selectively slowed at the respective step, about 10(5)-fold, in E237Q. Azide, acetate and formate but not halides restored catalytic activity up to 300-fold in E237Q under conditions in which the deglucosylation step was rate-determining, and promoted production of the corresponding alpha-glucosides. In situ proton NMR studies of the chemical rescue of E237Q by acetate and formate revealed that enzymatically formed alpha-glucose 1-esters decomposed spontaneously via acyl group migration and hydrolysis. Using pH profiles of kcat/K(m), the pH dependences of kinetically isolated glucosylation and deglucosylation steps were analysed for wild-type and E237Q. Glucosylation of the wild-type proceeded optimally above and below apparent pK(a) values of about 5.6 and 7.2 respectively whereas deglucosylation was dependent on the apparent single ionization of a group of pK(a) approximately 5.8 that must be deprotonated for reaction. Glucosylation of E237Q was slowed below apparent pK(a) approximately 6.0 but had lost the high pH dependence of the wild-type. Deglucosylation of E237Q was pH-independent. The results allow unequivocal assignment of Glu237 as the catalytic acid-base of sucrose phosphorylase. They support a mechanism in which the pK(a) of Glu237 cycles between approximately 7.2 in free enzyme and approximately 5.8 in glucosyl enzyme intermediate, ensuring optimal participation of the glutamate residue side chain at each step in catalysis. Enzyme deglucosylation to an anionic nucleophile took place with Glu237 protonated or unprotonated. The results delineate how conserved active-site groups of retaining glycoside hydrolases can accommodate enzymatic function of a phosphorylase.     

Function of Y in codon-anticodon interaction of tRNA Phe

Molar association constants of binding oligonucleotides to the anticodon loops of (yeast) tRNA^Phe, (yeast) tRNA_HCl^Phe and (E. coli) tRNA_F^Met have been determined by equilibrium dialysis. From the temperature dependence of the molar association constants, ΔF, ΔH and ΔS of oligomer-anticodon loop interaction have been determined. The data indicate that the free energy change of codon-anticodon interaction is highly influenced by the presence of a modified purine (tRNA^Phe), of an unmodified purine (tRNA_F^Met) or its absence (tRNA_HCl^Phe). Excision of the modified purine Y in the anticodon loop of tRNA^Phe results in a conformational change of the anticodon loop, which is discussed on the basis of the corresponding changes in ΔF, ΔH and ΔS.     

The crystal structure of rice (Oryza sativa L.) Os4BGlu12, an oligosaccharide and tuberonic acid glucoside-hydrolyzing β-glucosidase with significant thioglucohydrolase activity

Rice Os4BGlu12, a glycoside hydrolase family 1 (GH1) β-glucosidase, hydrolyzes β-(1,4)-linked oligosaccharides of 3–6 glucosyl residues and the β-(1,3)-linked disaccharide laminaribiose, as well as certain glycosides. The crystal structures of apo Os4BGlu12, and its complexes with 2,4-dinitrophenyl-2-deoxyl-2-fluoroglucoside (DNP2FG) and 2-deoxy-2-fluoroglucose (G2F) were solved at 2.50, 2.45 and 2.40 Å resolution, respectively. The overall structure of rice Os4BGlu12 is typical of GH1 enzymes, but it contains an extra disulfide bridge in the loop B region. The glucose ring of the G2F in the covalent intermediate was found in a ⁴C₁ chair conformation, while that of the noncovalently bound DNP2FG had a ¹S₃ skew boat, consistent with hydrolysis via a ⁴H₃ half-chair transition state. The position of the catalytic nucleophile (Glu393) in the G2F structure was more similar to that of the Sinapsis alba myrosinase G2F complex than to that in covalent intermediates of other O-glucosidases, such as rice Os3BGlu6 and Os3BGlu7 β-glucosidases. This correlated with a significant thioglucosidase activity for Os4BGlu12, although with 200- to 1200-fold lower k_cat/K_m values for S-glucosides than the comparable O-glucosides, while hydrolysis of S-glucosides was undetectable for Os3BGlu6 and Os3BGlu7.     

Triple mutated antibody scFv2F3 with high GPx activity: insights from MD, docking, MDFE, and MM-PBSA simulation

By combining computational design and site-directed mutagenesis, we have engineered a new catalytic ability into the antibody scFv2F3 by installing a catalytic triad (Trp²⁹–Sec⁵²–Gln⁷²). The resulting abzyme, Se-scFv2F3, exhibits a high glutathione peroxidase (GPx) activity, approaching the native enzyme activity. Activity assays and a systematic computational study were performed to investigate the effect of successive replacement of residues at positions 29, 52, and 72. The results revealed that an active site Ser⁵²/Sec substitution is critical for the GPx activity of Se-scFv2F3. In addition, Phe²⁹/Trp–Val⁷²/Gln mutations enhance the reaction rate via functional cooperation with Sec⁵². Molecular dynamics simulations showed that the designed catalytic triad is very stable and the conformational flexibility caused by Tyr¹⁰¹ occurs mainly in the loop of complementarity determining region 3. The docking studies illustrated the importance of this loop that favors the conformational shift of Tyr⁵⁴, Asn⁵⁵, and Gly⁵⁶ to stabilize substrate binding. Molecular dynamics free energy and molecular mechanics-Poisson Boltzmann surface area calculations estimated the pK _a shifts of the catalytic residue and the binding free energies of docked complexes, suggesting that dipole–dipole interactions among Trp²⁹–Sec⁵²–Gln⁷² lead to the change of free energy that promotes the residual catalytic activity and the substrate-binding capacity. The calculated results agree well with the experimental data, which should help to clarify why Se-scFv2F3 exhibits high catalytic efficiency.     

A primer independent activity of rabbit muscle phosphorylaseb

Summary Rabbit muscle phosphorylaseb was found to be capable of forming protein bound±-1,4 glucosyl chains upon incubation of the enzyme with appropriate concentrations of glucose-1-phosphate with no primer addition (unprimed synthesis). This activity would only be present in a small fraction of the total muscle phosphorylaseb activity, as judged from the high concentrations of enzyme which are required to demonstrate the occurrence of unprimed synthesis. Polyacrylamide gel electrophoresis shows the presence of a phosphorylase isoenzyme capable of accepting glucosyl moieties, giving rise to a glucosylated protein enzymatically active in the chain lengthening of its own glucan.Dedicated to ProfessorLuis F. Leloir on the occasion of his 70^th birthday.     

On the donor substrate dependence of group-transfer reactions by hydrolytic enzymes: Insight from kinetic analysis of sucrose phosphorylase-catalyzed transglycosylation

Chemical group-transfer reactions by hydrolytic enzymes have considerable importance in biocatalytic synthesis and are exploited broadly in commercial-scale chemical production. Mechanistically, these reactions have in common the involvement of a covalent enzyme intermediate which is formed upon enzyme reaction with the donor substrate and is subsequently intercepted by a suitable acceptor. Here, we studied the glycosylation of glycerol from sucrose by sucrose phosphorylase (SucP) to clarify a peculiar, yet generally important characteristic of this reaction: partitioning between glycosylation of glycerol and hydrolysis depends on the type and the concentration of the donor substrate used (here: sucrose, α-d -glucose 1-phosphate (G1P)). We develop a kinetic framework to analyze the effect and provide evidence that, when G1P is used as donor substrate, hydrolysis occurs not only from the β-glucosyl-enzyme intermediate (E-Glc), but additionally from a noncovalent complex of E-Glc and substrate which unlike E-Glc is unreactive to glycerol. Depending on the relative rates of hydrolysis of free and substrate-bound E-Glc, inhibition (Leuconostoc mesenteroides SucP) or apparent activation (Bifidobacterium adolescentis SucP) is observed at high donor substrate concentration. At a G1P concentration that excludes the substrate-bound E-Glc, the transfer/hydrolysis ratio changes to a value consistent with reaction exclusively through E-Glc, independent of the donor substrate used. Collectively, these results give explanation for a kinetic behavior of SucP not previously accounted for, provide essential basis for design and optimization of the synthetic reaction, and establish a theoretical framework for the analysis of kinetically analogous group-transfer reactions by hydrolytic enzymes.     

The bacterial ribonuclease P holoenzyme requires specific, conserved residues for efficient catalysis and substrate positioning

RNase P is an RNA-based enzyme primarily responsible for 5′-end pre-tRNA processing. A structure of the bacterial RNase P holoenzyme in complex with tRNA^Phe revealed the structural basis for substrate recognition, identified the active site location, and showed how the protein component increases functionality. The active site includes at least two metal ions, a universal uridine (U52), and P RNA backbone moieties, but it is unclear whether an adjacent, bacterially conserved protein loop (residues 52–57) participates in catalysis. Here, mutagenesis combined with single-turnover reaction kinetics demonstrate that point mutations in this loop have either no or modest effects on catalytic efficiency. Similarly, amino acid changes in the ‘RNR’ region, which represent the most conserved region of bacterial RNase P proteins, exhibit negligible changes in catalytic efficiency. However, U52 and two bacterially conserved protein residues (F17 and R89) are essential for efficient Thermotoga maritima RNase P activity. The U52 nucleotide binds a metal ion at the active site, whereas F17 and R89 are positioned >20 Å from the cleavage site, probably making contacts with N₋₄ and N₋₅ nucleotides of the pre-tRNA 5′-leader. This suggests a synergistic coupling between transition state formation and substrate positioning via interactions with the leader.     

By Interacting with the C-terminal Phe of Apelin,Phe255 and Trp259 in Helix VI of the Apelin Receptor Are Critical for Internalization

Apelin is the endogenous ligand of the orphan seven-transmembrane domain (TM) G protein-coupled receptor APJ. Apelin is involved in the regulation of body fluid homeostasis and cardiovascular functions. We previously showed the importance of the C-terminal Phe of apelin 17 (K17F) in the hypotensive activity of this peptide. Here, we show either by deleting the Phe residue (K16P) or by substituting it by an Ala (K17A), that it plays a crucial role in apelin receptor internalization but not in apelin binding or in Gα_i-protein coupling. Then we built a homology three-dimensional model of the human apelin receptor using the cholecystokinin receptor-1 model as a template, and we subsequently docked K17F into the binding site. We visualized a hydrophobic cavity at the bottom of the binding pocket in which the C-terminal Phe of K17F was embedded by Trp¹⁵² in TMIV and Trp²⁵⁹ and Phe²⁵⁵ in TMVI. Using molecular modeling and site-directed mutagenesis studies, we further showed that Phe²⁵⁵ and Trp²⁵⁹ are key residues in triggering receptor internalization without playing a role in apelin binding or in Gα_i-protein coupling. These findings bring new insights into apelin receptor activation and show that Phe²⁵⁵ and Trp²⁵⁹, by interacting with the C-terminal Phe of the pyroglutamyl form of apelin 13 (pE13F) or K17F, are crucial for apelin receptor internalization.     

Computational analyses of the conformational itinerary along the reaction pathway of GH94 cellobiose phosphorylase

GH94 cellobiose phosphorylase (CBP) catalyzes the phosphorolysis of cellobiose into α-d-glucose 1-phosphate (G1P) and d-glucose with inversion of anomeric configuration. The complex crystal structure of CBP from Cellvibrio gilvus had previously been determined; glycerol, glucose, and phosphate are bound to subsites −1, +1, and the anion binding site, respectively. We performed computational analyses to elucidate the conformational itinerary along the reaction pathway of this enzyme. autodock was used to dock cellobiose with its glycon glucosyl residue in various conformations and with its aglycon glucosyl residue in the low-energy ⁴C₁ conformer. An oxocarbenium ion-like glucose molecule mimicking the transition state was also docked. Based on the clustering analysis, docked energies, and comparison with the crystallographic ligands, we conclude that the reaction proceeds from ¹S₃ as the pre-transition state conformer (Michaelis complex) via E₃ as the transition state candidate to ⁴C₁ as the G1P product conformer. The predicted reaction pathway of the inverting phosphorylase is similar to that proposed for the first-half glycosylation reaction of retaining cellulases, but is different from those for inverting cellulases. NAMD was used to simulate molecular dynamics of the enzyme. The ¹S₃ pre-transition state conformer is highly stable compared with other conformers, and a conformational change from ⁴C₁ to ^1,4B was observed.     

Phosphorolytic cleavage of sucrose by sucrose-grown ruminal bacterium <Emphasis Type="Italic">Pseudobutyrivibrio ruminis</Emphasis> strain k3

Rumen bacterium Pseudobutyrivibrio ruminis strain k3 utilized over 90 % sucrose added to the growth medium as a sole carbon source. Zymographic studies of the bacterial cell extract revealed the presence of a single enzyme involved in sucrose digestion. Thin layer chromatography showed fructose and glucose-1-phosphate (Glc1P) as end products of the digestion of sucrose by identified enzyme. The activity of the enzyme depended on the presence of inorganic phosphate and was the highest at the concentration of phosphate 56 mmol/L. The enzyme was identified as the sucrose phosphorylase (EC 2.4.1.7) of molar mass ≈54 kDa and maximum activity at pH 6.0 and 45 °C. The calculated Michaelis constant (K _m) for Glc1P formation and release of fructose by partially purified enzyme were 4.4 and 8.56 mmol/L while the maximum velocities of the reaction (v _lim) were 1.19 and 0.64 μmol/L per mg protein per min, respectively.