Improvement of the enzymatic activity of the hyperthermophilic cellulase from <Emphasis Type="Italic">Pyrococcus horikoshii</Emphasis>

A hyperthermophilic β-1,4 endoglucanase (EGPh) from the hyperthermophilic archaeon Pyrococcus horikoshii exhibits a strong hydrolyzing activity toward crystalline cellulose. The characteristic features of EGPh are: (1) it appears to have disulfide bonds, which is rare among anaerobic hyperthermophilic archaeon proteins, and (2) it lacks a carbohydrate-binding domain, which is necessary for effective hydrolysis of cellulose. We first examined the relationship between the disulfide bonds and the catalytic activity by analyzing various cysteine mutations. The activities of the mutated enzymes toward carboxy methyl cellulose (CMC) increased without any loss in thermostability. Second, we prepared a fusion enzyme so that the thermostable chitin-binding domain of chitinase from P. furiosus was joined to the C-terminus of EGPh and its variants. These fusion enzymes showed stronger activities than did the wild-type EGPh toward both CMC and crystalline cellulose (Avicel).     

Functional analysis of hyperthermophilic endocellulase from Pyrococcus horikoshii by crystallographic snapshots

A hyperthermophilic membrane-related β-1,4-endoglucanase (family 5, cellulase) of the archaeon Pyrococcus horikoshii was found to be capable of hydrolysing cellulose at high temperatures. The hyperthermophilic cellulase has promise for applications in biomass utilization. To clarify its detailed function, we determined the crystal structures of mutants of the enzyme in complex with either the substrate or product ligands. We were able to resolve different kinds of complex structures at 1.65-2.01?? (1??=0.1?nm). The structural analysis of various mutant enzymes yielded a sequence of crystallographic snapshots, which could be used to explain the catalytic process of the enzyme. The substrate position is fixed by the alignment of one cellobiose unit between the two aromatic amino acid residues at subsites +1 and +2. During the enzyme reaction, the glucose structure of cellulose substrates is distorted at subsite -1, and the β-1,4-glucoside bond between glucose moieties is twisted between subsites -1 and +1. Subsite -2 specifically recognizes the glucose residue, but recognition by subsites +1 and +2 is loose during the enzyme reaction. This type of recognition is important for creation of the distorted boat form of the substrate at subsite -1. A rare enzyme-substrate complex was observed within the low-activity mutant Y299F, which suggested the existence of a trapped ligand structure before the formation by covalent bonding of the proposed intermediate structure. Analysis of the enzyme-substrate structure suggested that an incoming water molecule, essential for hydrolysis during the retention process, might be introduced to the cleavage position after the cellobiose product at subsites +1 and +2 was released from the active site.     

Identification of the amino acid residues essential for proteolytic activity in an archaeal signal peptide peptidase

Signal peptide peptidases (SPPs) are enzymes involved in the initial degradation of signal peptides after they are released from the precursor proteins by signal peptidases. In contrast to the eukaryotic enzymes that are aspartate peptidases, the catalytic mechanisms of prokaryotic SPPs had not been known. In this study on the SPP from the hyperthermophilic archaeon Thermococcus kodakaraensis (SppA(Tk)), we have identified amino acid residues that are essential for the peptidase activity of the enzyme. DeltaN54SppA(Tk), a truncated protein without the N-terminal 54 residues and putative transmembrane domain, exhibits high peptidase activity, and was used as the wild-type protein. Sixteen residues, highly conserved among archaeal SPP homologue sequences, were selected and replaced by alanine residues. The mutations S162A and K214A were found to abolish peptidase activity of the protein, whereas all other mutant proteins displayed activity to various extents. The results indicated the function of Ser(162) as the nucleophilic serine and that of Lys(214) as the general base, comprising a Ser/Lys catalytic dyad in SppA(Tk). Kinetic analyses indicated that Ser(184), His(191) Lys(209), Asp(215), and Arg(221) supported peptidase activity. Intriguingly, a large number of mutations led to an increase in activity levels of the enzyme. In particular, mutations in Ser(128) and Tyr(165) not only increased activity levels but also broadened the substrate specificity of SppA(Tk), suggesting that these residues may be present to prevent the enzyme from cleaving unintended peptide/protein substrates in the cell. A detailed alignment of prokaryotic SPP sequences strongly suggested that the majority of archaeal enzymes, along with the bacterial enzyme from Bacillus subtilis, adopt the same catalytic mechanism for peptide hydrolysis.     

Importance of a conserved residue, aspartate-162, for the function of Escherichia coli aspartate transcarbamoylase.

Aspartate-162 in the catalytic chain of aspartate transcarbamoylase is conserved in all of the sequences determined to date. The X-ray structure of the Escherichia coli enzyme indicates that this residue is located in a loop region (160's loop) that is near the interface between two catalytic trimers and is also close to the active site. In order to test whether this conserved residue is important for support of the internal architecture of the enzyme and/or involved in transmitting homotropic and heterotropic effects, the function of this residue was studied using a mutant version of the enzyme with an alanine at this position (Asp-162----Ala) created by site-specific mutagenesis. The Asp-162----Ala enzyme exhibits a 400-fold reduction in the maximal observed specific activity, approximately 2-fold and 10-fold decreases in the aspartate and carbamoyl phosphate concentrations at half the maximal observed specific activity respectively, a loss of homotropic cooperativity, and loss of response to the regulatory nucleotides ATP and CTP. Furthermore, equilibrium binding studies indicate that the affinity of the mutant enzyme for CTP is reduced more than 10-fold. The isolated catalytic subunit exhibits a 660-fold reduction in maximal observed specific activity compared to the wild-type catalytic subunit. The Km values for aspartate and carbamoyl phosphate for the Asp-162----Ala catalytic subunit were within 2-fold of the values observed for the wild-type catalytic subunit. Computer simulations of the energy-minimized mutant enzyme indicate that the space once occupied by the side chain of Asp-162 may be filled by other side chains, suggesting that Asp-162 is important for stabilizing the internal architecture of the wild-type enzyme.     

Kinetic studies of Thermobifida fusca Cel9A active site mutant enzymes

Thermobifida fusca Cel9A-90, an unusual family 9 enzyme, is a processive endoglucanase containing a catalytic domain closely linked to a family 3c cellulose binding domain (Cel9A-68) followed by a fibronectin III-like domain and a family 2 cellulose binding domain. To study its catalytic mechanism, 12 mutant genes with changes in five conserved residues of Cel9A-68 were constructed, cloned, and expressed in Escherichia coli. The purified mutant enzymes were assayed for their activities on (carboxymethyl)cellulose, phosphoric acid-swollen cellulose, bacterial microcrystalline cellulose, and 2,4-dinitrophenyl beta-D-cellobioside. They were also tested for ligand binding, enzyme processivity, and thermostability. The results clearly show that E424 functions as the catalytic acid, D55 and D58 are both required for catalytic base activity, and Y206 plays an important role in binding, catalysis, and processivity, while Y318 plays an important role in binding of crystalline cellulose substrates and is required for processivity. Several amino acids located in a loop at the end of the catalytic cleft (T245-L251) were deleted from Cel9A-68, and this enzyme showed slightly improved filter paper activity and binding to BMCC but otherwise behaved like the wild-type enzyme. The FnIII-like domain was deleted from Cel9A-90, reducing BMCC activity to 43% of the wild type.     

Exchange of active site residues alters substrate specificity in extremely thermostable β-glycosidase from Thermococcus kodakarensis KOD1

β-Glycosidase from Thermococcus kodakarensis KOD1 is a hyperthermophilic enzyme with β-glucosidase, β-mannosidase, β-fucosidase and β-galactosidase activities. Sequence alignment with other β-glycosidases from hyperthermophilic archaea showed two unique active site residues, Gln77 and Asp206. These residues were represented by Arg and Asp in all other hyperthermophilic β-glycosidases. The two active site residues were mutated to Q77R, D206N and D206Q, to study the role of these unique active site residues in catalytic activity and to alter the substrate specificity to enhance its β-glucosidase activity. The secondary structure analysis of all the mutants showed no change in their structure and exhibited in similar conformation like wild-type as they all existed in dimer form in an SDS-PAGE under non-reducing conditions. Q77R and D206Q affected the catalytic activity of the enzyme whereas the D206N altered the catalytic turn-over rate for glucosidase and mannosidase activities with fucosidase activity remain unchanged. Gln77 is reported to interact with catalytic nucleophile and Asp206 with axial C2-hydroxyl group of substrates. Q77R might have made some changes in three dimensional structure due to its electrostatic effect and lost its catalytic activity. The extended side chains of D206Q is predicted to affect the substrate binding during catalysis. The high-catalytic turn-over rate by D206N for β-glucosidase activity makes it a useful enzyme in cellulose degradation at high temperatures.     

Preparation of a glycosynthase from the β-glycosidase of the Archaeon Pyrococcus horikoshii

The β-glycosidase from the hyperthermophilic Archaeon Pyrococcus horikoshii (Phoβ-gly) is a monomeric enzyme with wide substrate specificity belonging to family 1 of glycoside hydrolases classification. Inspection of the three-dimensional structure of the enzyme, recently resolved, showed that Phoβ-gly is membrane bound and that the residues putatively involved in the catalytic activity are Glu155 and Glu324 working as the general acid/base and the nucleophile of the reaction, respectively. We show here that mutation of the latter completely eliminated the activity of the enzyme and that it could be reactivated in the presence of sodium formate. Analysis of the products obtained in the presence of sodium formate buffer pH 4.0 at 75°C showed that the Glu324Gly mutant acts as a hyperthermophilic glycosynthase.     

Production and characterization of a thermostable L-threonine dehydrogenase from the hyperthermophilic archaeon Pyrococcus furiosus

The gene encoding a threonine dehydrogenase (TDH) has been identified in the hyperthermophilic archaeon Pyrococcus furiosus. The Pf-TDH protein has been functionally produced in Escherichia coli and purified to homogeneity. The enzyme has a tetrameric conformation with a molecular mass of approximately 155 kDa. The catalytic activity of the enzyme increases up to 100 degrees C, and a half-life of 11 min at this temperature indicates its thermostability. The enzyme is specific for NAD(H), and maximal specific activities were detected with L-threonine (10.3 U x mg(-1)) and acetoin (3.9 U x mg(-1)) in the oxidative and reductive reactions, respectively. Pf-TDH also utilizes L-serine and D-threonine as substrate, but could not oxidize other L-amino acids. The enzyme requires bivalent cations such as Zn2+ and Co2+ for activity and contains at least one zinc atom per subunit. Km values for L-threonine and NAD+ at 70 degrees C were 1.5 mm and 0.055 mm, respectively.     

Molecular and Biochemical Analyses of CbCel9A/Cel48A,a Highly Secreted Multi-Modular Cellulase by Caldicellulosiruptor bescii during Growth on Crystalline Cellulose

During growth on crystalline cellulose, the thermophilic bacterium Caldicellulosiruptor bescii secretes several cellulose-degrading enzymes. Among these enzymes is CelA (CbCel9A/Cel48A), which is reported as the most highly secreted cellulolytic enzyme in this bacterium. CbCel9A/Cel48A is a large multi-modular polypeptide, composed of an N-terminal catalytic glycoside hydrolase family 9 (GH9) module and a C-terminal GH48 catalytic module that are separated by a family 3c carbohydrate-binding module (CBM3c) and two identical CBM3bs. The wild-type CbCel9A/Cel48A and its truncational mutants were expressed in Bacillus megaterium and Escherichia coli, respectively. The wild-type polypeptide released twice the amount of glucose equivalents from Avicel than its truncational mutant that lacks the GH48 catalytic module. The truncational mutant harboring the GH9 module and the CBM3c was more thermostable than the wild-type protein, likely due to its compact structure. The main hydrolytic activity was present in the GH9 catalytic module, while the truncational mutant containing the GH48 module and the three CBMs was ineffective in degradation of either crystalline or amorphous cellulose. Interestingly, the GH9 and/or GH48 catalytic modules containing the CBM3bs form low-density particles during hydrolysis of crystalline cellulose. Moreover, TM3 (GH9/CBM3c) and TM2 (GH48 with three CBM3 modules) synergistically hydrolyze crystalline cellulose. Deletion of the CBM3bs or mutations that compromised their binding activity suggested that these CBMs are important during hydrolysis of crystalline cellulose. In agreement with this observation, seven of nine genes in a C. bescii gene cluster predicted to encode cellulose-degrading enzymes harbor CBM3bs. Based on our results, we hypothesize that C. bescii uses the GH48 module and the CBM3bs in CbCel9A/Cel48A to destabilize certain regions of crystalline cellulose for attack by the highly active GH9 module and other endoglucanases produced by this hyperthermophilic bacterium.     

Tertiary structure and carbohydrate recognition by the chitin-binding domain of a hyperthermophilic chitinase from Pyrococcus furiosus

A chitinase is a hyperthermophilic glycosidase that effectively hydrolyzes both α and β crystalline chitins; that studied here was engineered from the genes PF1233 and PF1234 of Pyrococcus furiosus. This chitinase has unique structural features and contains two catalytic domains (AD1 and AD2) and two chitin-binding domains (ChBDs; ChBD1 and ChBD2). A partial enzyme carrying AD2 and ChBD2 also effectively hydrolyzes crystalline chitin. We determined the NMR and crystal structures of ChBD2, which significantly enhances the activity of the catalytic domain. There was no significant difference between the NMR and crystal structures. The overall structure of ChBD2, which consists of two four-stranded β-sheets, was composed of a typical β-sandwich architecture and was similar to that of other carbohydrate-binding module 2 family proteins, despite low sequence similarity. The chitin-binding surface identified by NMR was flat and contained a strip of three solvent-exposed Trp residues (Trp274, Trp308 and Trp326) flanked by acidic residues (Glu279 and Asp281). These acidic residues form a negatively charged patch and are a characteristic feature of ChBD2. Mutagenesis analysis indicated that hydrophobic interaction was dominant for the recognition of crystalline chitin and that the acidic residues were responsible for a higher substrate specificity of ChBD2 for chitin compared with that of cellulose. These results provide the first structure of a hyperthermostable ChBD and yield new insight into the mechanism of protein-carbohydrate recognition. This is important in the development of technology for the exploitation of biomass.     

Structure,Dynamics, and Specificity of Endoglucanase D from Clostridium cellulovorans

The enzymatic degradation of cellulose is a critical step in the biological conversion of plant biomass into an abundant renewable energy source. An understanding of the structural and dynamic features that cellulases utilize to bind a single strand of crystalline cellulose and hydrolyze the β-1,4-glycosidic bonds of cellulose to produce fermentable sugars would greatly facilitate the engineering of improved cellulases for the large-scale conversion of plant biomass. Endoglucanase D (EngD) from Clostridium cellulovorans is a modular enzyme comprising an N-terminal catalytic domain and a C-terminal carbohydrate-binding module, which is attached via a flexible linker. Here, we present the 2.1-Å-resolution crystal structures of full-length EngD with and without cellotriose bound, solution small-angle X-ray scattering (SAXS) studies of the full-length enzyme, the characterization of the active cleft glucose binding subsites, and substrate specificity of EngD on soluble and insoluble polymeric carbohydrates. SAXS data support a model in which the linker is flexible, allowing EngD to adopt an extended conformation in solution. The cellotriose-bound EngD structure revealed an extended active-site cleft that contains seven glucose-binding subsites, but unlike the majority of structurally determined endocellulases, the active-site cleft of EngD is partially enclosed by Trp162 and Tyr232. EngD variants, which lack Trp162, showed a significant reduction in activity and an alteration in the distribution of cellohexaose degradation products, suggesting that Trp162 plays a direct role in substrate binding.     

S-adenosylhomocysteine hydrolase from the archaeon Pyrococcus furiosus: biochemical characterization and analysis of protein structure by comparative molecular modeling

S-adenosylhomocysteine hydrolase (AdoHcyHD) is an ubiquitous enzyme that catalyzes the breakdown of S-adenosylhomocysteine, a powerful inhibitor of most transmethylation reactions, to adenosine and L-homocysteine. AdoHcyHD from the hyperthermophilic archaeon Pyrococcus furiosus (PfAdoHcyHD) was cloned, expressed in Escherichia coli, and purified. The enzyme is thermoactive with an optimum temperature of 95 degrees C, and thermostable retaining 100% residual activity after 1 h at 90 degrees C and showing an apparent melting temperature of 98 degrees C. The enzyme is a homotetramer of 190 kDa and contains four cysteine residues per subunit. Thiol groups are not involved in the catalytic process whereas disulfide bond(s) could be present since incubation with 0.8 M dithiothreitol reduces enzyme activity. Multiple sequence alignment of hyperthermophilic AdoHcyHD reveals the presence of two cysteine residues in the N-terminus of the enzyme conserved only in members of Pyrococcus species, and shows that hyperthermophilic AdoHcyHD lack eight C-terminal residues, thought to be important for structural and functional properties of the eukaryotic enzyme. The homology-modeled structure of PfAdoHcyHD shows that Trp220, Tyr181, Tyr184, and Leu185 of each subunit and Ile244 from a different subunit form a network of hydrophobic and aromatic interactions in the central channel formed at the subunits interface. These contacts partially replace the interactions of the C-terminal tail of the eukaryotic enzyme required for tetramer stability. Moreover, Cys221 and Lys245 substitute for Thr430 and Lys426, respectively, of the human enzyme in NAD-binding. Interestingly, all these residues are fairly well conserved in hyperthermophilic AdoHcyHDs but not in mesophilic ones, thus suggesting a common adaptation mechanism at high temperatures.     

Processivity, substrate binding, and mechanism of cellulose hydrolysis by Thermobifida fusca Cel9A

Thermobifida fusca Cel9A-90 is a processive endoglucanase consisting of a family 9 catalytic domain (CD), a family 3c cellulose binding module (CBM3c), a fibronectin III-like domain, and a family 2 CBM. This enzyme has the highest activity of any individual T. fusca enzyme on crystalline substrates, particularly bacterial cellulose (BC). Mutations were introduced into the CD or the CBM3c of Cel9A-68 using site-directed mutagenesis. The mutant enzymes were expressed in Escherichia coli; purified; and tested for activity on four substrates, ligand binding, and processivity. The results show that H125 and Y206 play an important role in activity by forming a hydrogen bonding network with the catalytic base, D58; another important supporting residue, D55; and Glc(-1) O1. R378, a residue interacting with Glc(+1), plays an important role in processivity. Several enzymes with mutations in the subsites Glc(-2) to Glc(-4) had less than 15% activity on BC and markedly reduced processivity. Mutant enzymes with severalfold-higher activity on carboxymethyl cellulose (CMC) were found in the subsites from Glc(-2) to Glc(-4). The CBM3c mutant enzymes, Y520A, R557A/E559A, and R563A, had decreased activity on BC but had wild-type or improved processivity. Mutation of D513, a conserved residue at the end of the CBM, increased activity on crystalline cellulose. Previous work showed that deletion of the CBM3c abolished crystalline activity and processivity. This study shows that it is residues in the catalytic cleft that control processivity while the CBM3c is important for loose binding of the enzyme to the crystalline cellulose substrate.     

Discrimination of esterase and peptidase activities of acylaminoacyl peptidase from hyperthermophilic Aeropyrum pernix K1 by a single mutation

It has been shown that highly conserved residues that form crucial structural elements of the catalytic apparatus may be used to account for the evolutionary history of enzymes. Using saturation mutagenesis, we investigated the role of a conserved residue (Arg(526)) at the active site of acylaminoacyl peptidase from hyperthermophilic Aeropyrum pernix K1 in substrate discrimination and catalytic mechanism. This enzyme has both peptidase and esterase activities. The esterase activity of the wild-type enzyme with p-nitrophenyl caprylate as substrate is approximately 7 times higher than the peptidase activity with Ac-Leu-p-nitroanilide as substrate. However, with the same substrates, this difference was increased to approximately 150-fold for mutant R526V. A more dramatic effect occurred with mutant R526E, which essentially completely abolished the peptidase activity but decreased the esterase activity only by a factor of 2, leading to a 785-fold difference in the enzyme activities. These results provide rare examples that illustrate how enzymes can be evolved to discriminate their substrates by a single mutation. The possible structural and energetic effects of the mutations on k(cat) and K(m) of the enzyme were discussed based on molecular dynamics simulation studies.     

Cold-active citrate synthase: mutagenesis of active-site residues.

A comparison of the crystal structure of the dimeric enzyme citrate synthase from the psychrophilic Arthrobacter strain DS2-3R with that of the structurally homologous enzyme from the hyperthermophilic Pyrococcus furiosus reveals a significant difference in the accessibility of their active sites to substrates. In this work, we investigated the possible role in cold activity of the greater accessibility of the Arthrobacter citrate synthase. By site-directed mutagenesis, we replaced two alanine residues at the entrance to the active site with an arginine and glutamate residue, respectively, as found in the equivalent positions of the Pyrococcus enzyme Also, we introduced a loop into the active site of the psychrophilic citrate synthase, again mimicking the situation in the hyperthermophilic enzyme. Analysis of the thermoactivity and thermostability of the mutant enzymes reveals that cold activity is not significantly compromised by the mutations, but rather the affinity for one of the substrates, acetyl-CoA, is dramatically increased. Moreover, one mutant (Loop insertion/K313L/A361R) has an increased thermostability but a reduced temperature optimum for catalytic activity. This unexpected relationship between stability and activity is discussed with respect to the nature of the dependence of catalytic activity on temperature.     

Characterization of the 2-[(R)-2-hydroxypropylthio]ethanesulfonate dehydrogenase from Xanthobacter strain Py2: product inhibition, pH dependence of kinetic parameters, site-directed mutagenesis, rapid equilibrium inhibition, and chemical modification

Although the short-chain dehydrogenase/reductase (SDR) superfamily contains a very large number of members defined in annotated databases and by biochemical and structural studies, very few SDR enzymes have been identified that have a homologous partner catalyzing the same reaction but with an opposite stereospecificity. In the present study we have cloned and expressed one of these enzymes, the 2-[(R)-2-hydroxypropylthio]ethanesulfonate (R-HPC) dehydrogenase, that is part of the coenzyme M-dependent pathway of alkene and epoxide metabolism in Xanthobacter strain Py2. Investigation of the kinetic mechanism using product inhibition suggested that a compulsory-ordered ternary complex mechanism was followed. The pH dependence of k(cat)/K(m) indicated the presence of a single ionizable residue of catalytic importance (pK(a) = 6.9) that was proposed to be Y155 of the catalytic triad. Amino acid substitutions of the putative catalytic triad residues produced inactive enzymes (S142C, Y155F, Y155E, and K159A) or enzyme with a greatly decreased activity (S142A). Inhibitors were investigated as probes of the molecular features of R-HPC that contribute to substrate binding. 2-[(S)-2-Hydroxypropylthio]ethanesulfonate (S-HPC) and 2-(2-methyl-2-hydroxypropylthio)ethanesulfonate were found to be competitive inhibitors of R-HPC with K(ic) values close to the K(m) for R-HPC. The arginine-specific modifiers 2,3-butanedione and phenylglyoxal were found to be inactivators, and inactivation could be protected against by the addition of R-HPC. 2,3-Butanedione was found to reduce enzyme activity with R-HPC as a substrate much more dramatically than with substrates that lacked a sulfonate moiety [e.g., 2-propanol, (R)-2-pentanol, and (R)-2-heptanol]. Amino acid analyses of enzyme modified by 2,3-butanedione in the presence and absence of S-HPC suggested protection of a single arginine residue. On the basis of these results, we propose that one or more active site arginines play a key role in substrate binding via an ionic interaction with the sulfonate moiety of R-HPC.     

The conserved N-terminal helix of acylpeptide hydrolase from archaeon Aeropyrum pernix K1 is important for its hyperthermophilic activity

The acylpeptide hydrolases from hyperthermophilic archaeon Aeropyrum pernix K1 has a short conserved N-terminal helix in its family. The role of this N-terminal helix in the function of the hyperthermophilic enzyme, however, is unknown. Here, we investigated this question by protein engineering and biophysical methods. We found that a mutant (DeltaN21) with the N-terminal helix deleted is no longer functional at the optimum temperature for WT enzyme (95 degrees C), required for the survival of Aeropyrum pernix K1. Instead, DeltaN21 has the optimum activity at approximately 77 degrees C, with higher activities than the WT enzyme below this temperature. DeltaN21 is less stable than the WT enzyme and started unfolding at approximately 77 degrees C, indicating that the loss of the enzymatic activity of DeltaN21 at higher temperature is due to its low thermodynamic stability. In addition, we found that the salt bridges formed between the N-terminal helix and the catalytic domain of the enzyme play only a minor role in stabilizing the enzyme, suggesting that hydrophobic interactions mainly contribute to the stabilization. Since the N-terminal helix is conserved in this family of enzymes, our results suggest that the N-terminal helix is likely to play an important role for stabilizing all other enzymes in this family.     

Linkage between dynamics and catalysis in a thermophilic-mesophilic enzyme pair

A fundamental question is how enzymes can accelerate chemical reactions. Catalysis is not only defined by actual chemical steps, but also by enzyme structure and dynamics. To investigate the role of protein dynamics in enzymatic turnover, we measured residue-specific protein dynamics in hyperthermophilic and mesophilic homologs of adenylate kinase during catalysis. A dynamic process, the opening of the nucleotide-binding lids, was found to be rate-limiting for both enzymes as measured by NMR relaxation. Moreover, we found that the reduced catalytic activity of the hyperthermophilic enzyme at ambient temperatures is caused solely by a slower lid-opening rate. This comparative and quantitative study of activity, structure and dynamics revealed a close link between protein dynamics and catalytic turnover.     

Chlorophyllase as a serine hydrolase: identification of a putative catalytic triad

Chlorophyllases (Chlases), cloned so far, contain a lipase motif with the active serine residue of the catalytic triad of triglyceride lipases. Inhibitors specific for the catalytic serine residue in serine hydrolases, which include lipases effectively inhibited the activity of the recombinant Chenopodium album Chlase (CaCLH). From this evidence we assumed that the catalytic mechanism of hydrolysis by Chlase might be similar to those of serine hydrolases that have a catalytic triad composed of serine, histidine and aspartic acid in their active site. Thus, we introduced mutations into the putative catalytic residue (Ser162) and conserved amino acid residues (histidine, aspartic acid and cysteine) to generate recombinant CaCLH mutants. The three amino acid residues (Ser162, Asp191 and His262) essential for Chlase activity were identified. These results indicate that Chlase is a serine hydrolase and, by analogy with a plausible catalytic mechanism of serine hydrolases, we proposed a mechanism for hydrolysis catalyzed by Chlase.     

Analysis of the function of a hyperthermophilic endoglucanase from Pyrococcus horikoshii that hydrolyzes crystalline cellulose

A hyperthermophilic -1,4 endoglucanase was identified in Pyrococcus horikoshii, a hyperthermophilic archaeon. In order to clarify the function of the protein in detail, structural and catalytic site studies were performed using protein engineering. By removing some of the C-terminal sequence of the ORF of the endoglucanase (PH1171), two types of recombinant proteins were expressed from one ORF, using Escherichia coli. One exhibited endoglucanase activity, and the other did not. An SD-like sequence was identified in the ORF of the endoglucanase. By removing the SD-like sequence without changing the amino acid sequence of the endoglucanase, one recombinant endoglucanase was prepared effectively from E. coli. From the analysis of the N- and C-terminal regions of the ORF, this endoglucanase appears to be a secreted and membrane-binding enzyme of P. horikoshii. A mutation analysis of the endoglucanase, using the synthetic substrate, indicated that Glu342 is a candidate for the active center and plays a critical role in the activity of the enzyme. Additional catalytic amino acid residues were not found. These results indicate that the catalytic residue of the enzyme is different from that of typical family 5 endoglucanase, even though it has a high homology to the endoglucanase from Acidothermus celluloliticus. The activity of the enzyme, using carboxy methylcellulose and crystalline cellulose as the substrates, was increased, but not for a synthetic low-molecular substrate when a carbohydrate-binding module of chitinase from P. furiosus was added to the C-terminal region.