Multiple substrate binding states and chiral recognition in cofactor-independent glutamate racemase: a molecular dynamics study

Glutamate racemase (MurI) catalyzes the racemization of glutamate; two cysteine residues serve as catalytic acid and base. On the basis of the crystal structure of MurI from the hyperthermophilic bacterium Aquifex pyrophilus, we performed molecular dynamics (MD) simulations of six different systems to investigate stereochemistry, substrate ligation, and active site protonation state. The catalytic competence of individual systems was assessed by the abundance of reactive conformers. Only systems in which Cys70 is poised to deprotonate d-Glu were found to be catalytically competent (idem Cys178/l-Glu), in agreement with the experimentally observed stereochemistry of Lactobacillus fermentii MurI [Tanner, M. E. et al. (1993) Biochemistry 32, 3998-4006]. Only systems in which the alpha-amino group of l/d-Glu and the imidazole moiety of His are deprotonated are catalytically competent. The active site of MurI displays an unusual flexibility in substrate ligation, and several transitions between stable binding patterns were observed. In catalytically competent binding states, the conserved threonine residues 72, 114, and 117 ligate the alpha-carboxylate of Glu and the Asn71 amides ligate the alpha-amino group of Glu, whereas the delta-carboxylate of Glu is steered by electrostatic repulsion from the Asp7 and Glu147 side chain carboxylates. A network of hydrogen bonds controls the positioning of each thiol/thiolate. In what we term substrate flipping, Glu suddenly rotates into a binding pattern that resembles the post-racemization state of the other enantiomer, i.e., each enantiomer can be bound in two distinct states. Substrate flipping and unfavorable substrate binding successively trigger dissociation of the substrate, accompanied by an opening of the active site channel. We explain how the weak binding of Glu contributes to catalysis and suggest a mechanism by which binding mismatches are propagated into an opening of the active site.     

Role of Phe283 in enzymatic reaction of cyclodextrin glycosyltransferase from alkalophilic Bacillus sp.1011: Substrate binding and arrangement of the catalytic site

Cyclodextrin glycosyltransferase (CGTase) belonging to the alpha-amylase family mainly catalyzes transglycosylation and produces cyclodextrins from starch and related alpha-1,4-glucans. The catalytic site of CGTase specifically conserves four aromatic residues, Phe183, Tyr195, Phe259, and Phe283, which are not found in alpha-amylase. To elucidate the structural role of Phe283, we determined the crystal structures of native and acarbose-complexed mutant CGTases in which Phe283 was replaced with leucine (F283L) or tyrosine (F283Y). The temperature factors of the region 259-269 in native F283L increased >10 A(2) compared with the wild type. The complex formation with acarbose not only increased the temperature factors (>10 A(2)) but also changed the structure of the region 257-267. This region is stabilized by interactions of Phe283 with Phe259 and Leu260 and plays an important role in the cyclodextrin binding. The conformation of the side-chains of Glu257, Phe259, His327, and Asp328 in the catalytic site was altered by the mutation of Phe283 with leucine, and this indicates that Phe283 partly arranges the structure of the catalytic site through contacts with Glu257 and Phe259. The replacement of Phe283 with tyrosine decreased the enzymatic activity in the basic pH range. The hydroxyl group of Tyr283 forms hydrogen bonds with the carboxyl group of Glu257, and the pK(a) of Glu257 in F283Y may be lower than that in the wild type.     

Identification of the principal catalytically important acidic residue of 3-hydroxy-3-methylglutaryl coenzyme A reductase

Kinetic analysis of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase has implicated a glutamate or aspartate residue in (i) formation of mevaldate thiohemiacetal by proton transfer to the carbonyl oxygen of mevaldate and (ii) enhanced ionization of CoASH by the resulting enzyme carboxylate anion, facilitating attack by CoAS- on the carbonyl carbon of mevaldate (Veloso, D., Cleland, W. W., and Porter, J. W. (1981) Biochemistry 81, 887-894). Although neither the identity of this acidic residue nor its location is known, the catalytic domains of 11 sequenced HMG-CoA reductases contain only 3 conserved acidic residues. For HMG-CoA reductase of Pseudomonas mevalonii, these residues are Glu52, Glu83, and Asp183. To identify the acidic residue that functions in catalysis, we generated mutants having alterations in these residues. The mutant proteins were expressed, purified, and characterized. Mutational alteration of residues Glu52 or Asp183 of P. mevalonii HMG-CoA reductase yielded enzymes with significant, but in some cases reduced, activity (Vmax = 100% Asp183----Ala, 65% Asp183----Asn, and 15% Glu52----Gln of wild-type activity, respectively). Although the activity of mutant enzymes Glu52----Gln and Asp183----Ala was undetectable under standard assay conditions, their Km values for substrates were 4-300-fold higher than those for wild-type enzyme. Km values for wild-type enzyme and for mutant enzymes Glu52----Gln and Asp183----Ala were, respectively: 0.41, 73, and 120 mM [R,S)-mevalonate); 0.080, 4.4, and 2.0 mM (coenzyme A); and 0.26, 4.4, and 1.0 mM (NAD+). By these criteria, neither Glu52 nor Asp183 is the acidic catalytic residue although each may function in substrate recognition. During chromatography on coenzyme A agarose or HMG-CoA agarose, mutant enzymes Asp183----Asn and Glu83----Gln behaved like wild-type enzyme. By contrast, and in support of a role for these residues in substrate recognition, mutant enzymes Glu52----Gln and Asp183----Ala exhibited impaired ability to bind to either support. Despite displaying Km values for substrates and chromatographic behavior on substrate affinity supports comparable to wild-type enzyme, only mutant enzyme Glu83----Gln was essentially inactive under all conditions studied (Vmax = 0.2% that of wild-type enzyme). Glutamate residue 83 of P. mevalonii HMG-CoA reductase, and consequently the glutamate of the consensus Pro-Met-Ala-Thr-Thr-Glu-Gly-Cys-Leu-Val-Ala motif of the catalytic domains of eukaryotic HMG-CoA reductases, is judged to be the acidic residue functional in catalysis.     

Crystal structures of amylosucrase from Neisseria polysaccharea in complex with D-glucose and the active site mutant Glu328Gln in complex with the natural substrate sucrose

The structure of amylosucrase from Neisseria polysaccharea in complex with beta-D-glucose has been determined by X-ray crystallography at a resolution of 1.66 A. Additionally, the structure of the inactive active site mutant Glu328Gln in complex with sucrose has been determined to a resolution of 2.0 A. The D-glucose complex shows two well-defined D-glucose molecules, one that binds very strongly in the bottom of a pocket that contains the proposed catalytic residues (at the subsite -1), in a nonstrained (4)C(1) conformation, and one that binds in the packing interface to a symmetry-related molecule. A third weaker D-glucose-binding site is located at the surface near the active site pocket entrance. The orientation of the D-glucose in the active site emphasizes the Glu328 role as the general acid/base. The binary sucrose complex shows one molecule bound in the active site, where the glucosyl moiety is located at the alpha-amylase -1 position and the fructosyl ring occupies subsite +1. Sucrose effectively blocks the only visible access channel to the active site. From analysis of the complex it appears that sucrose binding is primarily obtained through enzyme interactions with the glucosyl ring and that an important part of the enzyme function is a precise alignment of a lone pair of the linking O1 oxygen for hydrogen bond interaction with Glu328. The sucrose specificity appears to be determined primarily by residues Asp144, Asp394, Arg446, and Arg509. Both Asp394 and Arg446 are located in an insert connecting beta-strand 7 and alpha-helix 7 that is much longer in amylosucrase compared to other enzymes from the alpha-amylase family (family 13 of the glycoside hydrolases).     

Identification of catalytic and substrate-binding site residues in Bacillus cereus ATCC7064 oligo-1,6-glucosidase.

Three active site residues (Asp199, Glu255, Asp329) and two substrate-binding site residues (His103, His328) of oligo-1,6-glucosidase (EC 3.2.1.10) from Bacillus cereus ATCC7064 were identified by site-directed mutagenesis. These residues were deduced from the X-ray crystallographic analysis and the comparison of the primary structure of the oligo-1,6-glucosidase with those of Saccharomyces carlsbergensis alpha-glucosidase, Aspergillus oryzae alpha-amylase and pig pancreatic alpha-amylase which act on alpha-1,4-glucosidic linkages. The distances between these putative residues of B. cereus oligo-1,6-glucosidase calculated from the X-ray analysis data closely resemble those of A. oryzae alpha-amylase and pig pancreatic alpha-amylase. A single mutation of Asp199-->Asn, Glu255-->Gln, or Asp329-->Asn resulted in drastic reduction in activity, confirming that three residues are crucial for the reaction process of alpha-1,6-glucosidic bond cleavage. Thus, it is identified that the basic mechanism of oligo-1,6-glucosidase for the hydrolysis of alpha-1,6-glucosidic linkage is essentially the same as those of other amylolytic enzymes belonging to Family 13 (alpha-amylase family). On the other hand, mutations of histidine residues His103 and His328 resulted in pronounced dissimilarity in catalytic function. The mutation His328-->Asn caused the essential loss in activity, while the mutation His103-->Asn yielded a mutant enzyme that retained 59% of the k0/Km of that for the wild-type enzyme. Since mutants of other alpha-amylases acting on alpha-1,4-glucosidic bond linkage lost most of their activity by the site-directed mutagenesis at their equivalent residues to His103 and His328, the retaining of activity by His103-->Asn mutation in B. cereus oligo-1,6-glucosidase revealed the distinguished role of His103 for the hydrolysis of alpha-1,6-glucosidic bond linkage.     

Perturbing the polar environment of Asp102 in trypsin: consequences of replacing conserved Ser214.

Much of the catalytic power of trypsin is derived from the unusual buried, charged side chain of Asp102. A polar cave provides the stabilization for maintaining the buried charge, and it features the conserved amino acid Ser214 adjacent to Asp102. Ser214 has been replaced with Ala, Glu, and Lys in rat anionic trypsin, and the consequences of these changes have been determined. Three-dimensional structures of the Glu and Lys variant trypsins reveal that the new 214 side chains are buried. The 2.2-A crystal structure (R = 0.150) of trypsin S214K shows that Lys214 occupies the position held by Ser214 and a buried water molecule in the buried polar cave. Lys214-N zeta is solvent inaccessible and is less than 5 A from the catalytic Asp102. The side chain of Glu214 (2.8 A, R = 0.168) in trypsin S214E shows two conformations. In the major one, the Glu carboxylate in S214E forms a hydrogen bond with Asp102. Analytical isoelectrofocusing results show that trypsin S214K has a significantly different isoelectric point than trypsin, corresponding to an additional positive charge. The kinetic parameter kcat demonstrates that, compared to trypsin, S214K has 1% of the catalytic activity on a tripeptide amide substrate and S214E is 44% as active. Electrostatic potential calculations provide corroboration of the charge on Lys214 and are consistent with the kinetic results, suggesting that the presence of Lys214 has disturbed the electrostatic potential of Asp102.     

The structural basis for catalysis and specificity of the Pseudomonas cellulosa alpha-glucuronidase, GlcA67A

Alpha-glucuronidases, components of an ensemble of enzymes central to the recycling of photosynthetic biomass, remove the alpha-1,2 linked 4-O-methyl glucuronic acid from xylans. The structure of the alpha-glucuronidase, GlcA67A, from Pseudomonas cellulosa reveals three domains, the central of which is a (beta/alpha)(8) barrel housing the catalytic apparatus. Complexes of the enzyme with the individual reaction products, either xylobiose or glucuronic acid, and the ternary complex of both glucuronic acid and xylotriose reveal a "blind" pocket which selects for short decorated xylooligosaccharides substituted with the uronic acid at their nonreducing end, consistent with kinetic data. The catalytic center reveals a constellation of carboxylates; Glu292 is poised to provide protonic assistance to leaving group departure with Glu393 and Asp365 both appropriately positioned to provide base-catalyzed assistance for inverting nucleophilic attack by water.     

Substrate recognition mechanism of a glycosyltrehalose trehalohydrolase from Sulfolobus solfataricus KM1

Glycosyltrehalose trehalohydrolase (GTHase) is an α-amylase that cleaves the α-1,4 bond adjacent to the α-1,1 bond of maltooligosyltrehalose to release trehalose. To investigate the catalytic and substrate recognition mechanisms of GTHase, two residues, Asp252 (nucleophile) and Glu283 (general acid/base), located at the catalytic site of GTHase were mutated (Asp252→Ser (D252S), Glu (D252E) and Glu283→Gln (E283Q)), and the activity and structure of the enzyme were investigated. The E283Q, D252E, and D252S mutants showed only 0.04, 0.03, and 0.6% of enzymatic activity against the wild-type, respectively. The crystal structure of the E283Q mutant GTHase in complex with the substrate, maltotriosyltrehalose (G3-Tre), was determined to 2.6-Å resolution. The structure with G3-Tre indicated that GTHase has at least five substrate binding subsites and that Glu283 is the catalytic acid, and Asp252 is the nucleophile that attacks the C1 carbon in the glycosidic linkage of G3-Tre. The complex structure also revealed a scheme for substrate recognition by GTHase. Substrate recognition involves two unique interactions: stacking of Tyr325 with the terminal glucose ring of the trehalose moiety and perpendicularly placement of Trp215 to the pyranose rings at the subsites −1 and +1 glucose.     

Differential labeling of the catalytic subunit of cAMP-dependent protein kinase with a water-soluble carbodiimide: identification of carboxyl groups protected by MgATP and inhibitor peptides

The catalytic subunit of cAMP-dependent protein kinase typically phosphorylates protein substrates containing basic amino acids preceding the phosphorylation site. To identify amino acids in the catalytic subunit that might interact with these basic residues in the protein substrate, the enzyme was treated with a water-soluble carbodiimide, 1-ethyl-3-[3-(dimethylamino)propyl]carbodiimide (EDC), in the presence of [14C]glycine ethyl ester. Modification of the catalytic subunit in the absence of substrates led to the irreversible, first-order inhibition of activity. Neither MgATP nor a 6-residue inhibitor peptide alone was sufficient to protect the catalytic subunit against inactivation by the carbodiimide. However, the inhibitor peptide and MgATP together completely blocked the inhibitory effects of EDC. Several carboxyl groups in the free catalytic subunit were radiolabeled after the catalytic subunit was modified with EDC and [14C]glycine ethyl ester. After purification and sequencing, these carboxyl groups were identified as Glu 107, Glu 170, Asp 241, Asp 328, Asp 329, Glu 331, Glu 332, and Glu 333. Three of these amino acids, Glu 331, Glu 107, and Asp 241, were labeled regardless of the presence of substrates, while Glu 333 and Asp 329 were modified to a slight extent only in the free catalytic subunit. Glu 170, Asp 328, and Glu 332 were all very reactive in the apoenzyme but fully protected from modification by EDC in the presence of MgATP and an inhibitor peptide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of Catalytic and Substrate-binding Site Residues in Bacillus cereus ATCC7064 Oligo-1,6-glucosidase

Three active site residues (Asp199, Glu255, Asp329) and two substrate-binding site residues (His103, His328) of oligo-1,6-glucosidase (EC 3.2.1.10) from Bacillus cereus ATCC7064 were identified by site-directed mutagenesis. These residues were deduced from the X-ray crystallographic analysis and the comparison of the primary structure of the oligo-1,6-glucosidase with those of Saccharomyces carlsbergensis α-glucosidase, Aspergillus oryzae α-amylase and pig pancreatic α-amylase which act on α-1,4-glucosidic linkages. The distances between these putative residues of B. cereus oligo-1,6-glucosidase calculated from the X-ray analysis data closely resemble those of A. oryzae α-amylase and pig pancreatic α-amylase. A single mutation of Asp199→Asn, Glu255→Gln, or Asp329→Asn resulted in drastic reduction in activity, confirming that three residues are crucial for the reaction process of α-1,6-glucosidic bond cleavage. Thus, it is identified that the basic mechanism of oligo-1,6-glucosidase for the hydrolysis of α-1,6-glucosidic linkage is essentially the same as those of other amylolytic enzymes belonging to Family 13 (α-amylase family). On the other hand, mutations of histidine residues His103 and His328 resulted in pronounced dissimilarity in catalytic function. The mutation His328→Asn caused the essential loss in activity, while the mutation His103→Asn yielded a mutant enzyme that retained 59% of the κ₀/K_m of that for the wild-type enzyme. Since mutants of other α-amylases acting on α-1,4-glucosidic bond linkage lost most of their activity by the site-directed mutagenesis at their equivalent residues to His103 and His328, the retaining of activity by Hisl03→Asn mutation in B. cereus oligo-1,6-glucosidase revealed the distinguished role of His103 for the hydrolysis of α-1,6-glucosidic bond linkage.     

Crystal structure of maltose phosphorylase from Lactobacillus brevis: unexpected evolutionary relationship with glucoamylases

BACKGROUND: Maltose phosphorylase (MP) is a dimeric enzyme that catalyzes the conversion of maltose and inorganic phosphate into beta-D-glucose-1-phosphate and glucose without requiring any cofactors, such as pyridoxal phosphate. The enzyme is part of operons that are involved in maltose/malto-oligosaccharide metabolism. Maltose phosphorylases have been classified in family 65 of the glycoside hydrolases. No structure is available for any member of this family. RESULTS: We report here the 2.15 A resolution crystal structure of the MP from Lactobacillus brevis in complex with the cosubstrate phosphate. This represents the first structure of a disaccharide phosphorylase. The structure consists of an N-terminal complex beta sandwich domain, a helical linker, an (alpha/alpha)6 barrel catalytic domain, and a C-terminal beta sheet domain. The (alpha/alpha)6 barrel has an unexpected strong structural and functional analogy with the catalytic domain of glucoamylase from Aspergillus awamori. The only conserved glutamate of MP (Glu487) superposes onto the catalytic residue Glu179 of glucoamylase and likely represents the general acid catalyst. The phosphate ion is bound in a pocket facing the carboxylate of Glu487 and is ideally positioned for nucleophilic attack of the anomeric carbon atom. This site is occupied by the catalytic base carboxylate in glucoamylase. CONCLUSIONS: These observations strongly suggest that maltose phosphorylase has evolved from glucoamylase. MP has probably conserved one carboxylate group for acid catalysis and has exchanged the catalytic base for a phosphate binding pocket. The relative positions of the acid catalytic group and the bound phosphate are compatible with a direct-attack mechanism of a glycosidic bond by phosphate, in accordance with inversion of configuration at the anomeric carbon as observed for this enzyme.     

Characterization of Candida albicans RNA triphosphatase and mutational analysis of its active site

The RNA triphosphatase component (CaCet1p) of the mRNA capping apparatus of the pathogenic fungus Candida albicans differs mechanistically and structurally from the RNA triphosphatase of mammals. Hence, CaCet1p is an attractive antifungal target. Here we identify a C-terminal catalytic domain of CaCet1p from residue 257 to 520 and characterize a manganese-dependent and cobalt-dependent NTPase activity intrinsic to CaCet1p. The NTPase can be exploited to screen in vitro for inhibitors. The amino acids that comprise the active site of CaCet1p were identified by alanine-scanning mutagenesis, which was guided by the crystal structure of the homologous RNA triphosphatase from Saccharomyces cerevisiae (Cet1p). Thirteen residues required for the phosphohydrolase activity of CaCet1p (Glu287, Glu289, Asp363, Arg379, Lys396, Glu420, Arg441, Lys443, Arg445, Asp458, Glu472, Glu474 and Glu476) are located within the hydrophilic interior of an eight-strand β barrel of Cet1p. Each of the eight strands contributes at least one essential amino acid. The essential CaCet1p residues include all of the side chains that coordinate manganese and sulfate (i.e., γ phosphate) in the Cet1p product complex. These results suggest that the active site structure and catalytic mechanism are conserved among fungal RNA triphosphatases.     

Molecular structure and function of bacterial nitric oxide reductase

The crystal structure of the membrane-integrated nitric oxide reductase cNOR from Pseudomonas aeruginosa was determined. The smaller NorC subunit of cNOR is comprised of 1 trans-membrane helix and a hydrophilic domain, where the heme c is located, while the larger NorB subunit consists of 12 trans-membrane helices, which contain heme b and the catalytically active binuclear center (heme b(3) and non-heme Fe(B)). The roles of the 5 well-conserved glutamates in NOR are discussed, based on the recently solved structure. Glu211 and Glu280 appear to play an important role in the catalytic reduction of NO at the binuclear center by functioning as a terminal proton donor, while Glu215 probably contributes to the electro-negative environment of the catalytic center. Glu135, a ligand for Ca(2+) sandwiched between two heme propionates from heme b and b(3), and the nearby Glu138 appears to function as a structural factor in maintaining a protein conformation that is suitable for electron-coupled proton transfer from the periplasmic region to the active site. On the basis of these observations, the possible molecular mechanism for the reduction of NO by cNOR is discussed. This article is part of a Special Issue entitled: Respiratory Oxidases.     

Crystal structure of mammalian cysteine dioxygenase. A novel mononuclear iron center for cysteine thiol oxidation

Cysteine dioxygenase is a mononuclear iron-dependent enzyme responsible for the oxidation of cysteine with molecular oxygen to form cysteine sulfinate. This reaction commits cysteine to either catabolism to sulfate and pyruvate or the taurine biosynthetic pathway. Cysteine dioxygenase is a member of the cupin superfamily of proteins. The crystal structure of recombinant rat cysteine dioxygenase has been determined to 1.5-A resolution, and these results confirm the canonical cupin beta-sandwich fold and the rare cysteinyltyrosine intramolecular cross-link (between Cys(93) and Tyr(157)) seen in the recently reported murine cysteine dioxygenase structure. In contrast to the catalytically inactive mononuclear Ni(II) metallocenter present in the murine structure, crystallization of a catalytically competent preparation of rat cysteine dioxygenase revealed a novel tetrahedrally coordinated mononuclear iron center involving three histidines (His(86), His(88), and His(140)) and a water molecule. Attempts to acquire a structure with bound ligand using either cocrystallization or soaking crystals with cysteine revealed the formation of a mixed disulfide involving Cys(164) near the active site, which may explain previously observed substrate inhibition. This work provides a framework for understanding the molecular mechanisms involved in thiol dioxygenation and sets the stage for exploration of the chemistry of both the novel mononuclear iron center and the catalytic role of the cysteinyl-tyrosine linkage.     

Functional importance of calcium binding sites in outer membrane phospholipase A

Outer membrane phospholipase A (OMPLA) is an integral membrane enzyme that hydrolyses phospholipids requiring Ca(2+) as cofactor. In vitro studies have shown that OMPLA is only active as a dimer. The structures of monomeric and dimeric OMPLA provided possible clues to the activation process. In the inhibited dimeric species calcium ions are located at the dimer interface ideally suited to stabilise the oxyanion intermediates formed during catalysis. The side chain hydroxyl function of Ser152 is one of the ligands of this interfacial calcium. In the crystal structure of monomeric OMPLA the interfacial calcium site is lacking, but calcium was found to bind at a site involving the carboxylates of Asp149 and Asp184. In the current study the relevance of the identified calcium sites has been studied by site-directed mutagenesis. The Ser152Asn variant confirmed the importance of the interfacial calcium site for catalysis, and also demonstrated that this site is essentially involved in the dimerisation process. Replacements of the ligands in monomeric OMPLA, i.e. Asp149Asn, Asp149Ala and Asp184Asn, only showed minor effects on catalytic activity and dimerisation. A stronger effect observed for the variant Asp184Ala was explained by the proximity of Asp184 to the catalytically important Ser152 residue. We propose that Asp149 and Asp184 provide an electronegative funnel that may facilitate Ca(2+) transfer to the interfacial calcium site.     

Mutational and computational analysis of the role of conserved residues in the active site of a family 18 chitinase.

Glycoside hydrolysis by retaining family 18 chitinases involves a catalytic acid (Glu) which is part of a conserved DXDXE sequence motif that spans strand four of a (betaalpha)8 barrel (TIM barrel) structure. These glycoside hydrolases are unusual in that the positive charge emerging on the anomeric carbon after departure of the leaving group is stabilized by the substrate itself (the N-acetyl group of the distorted -1 sugar), rather than by a carboxylate group on the enzyme. We have studied seven conserved residues in the catalytic center of chitinase B from Serratia marcescens. Putative roles for these residues are proposed on the basis of the observed mutational effects, the pH-dependency of these effects, pKa calculations and available structural information. The results indicate that the pKa of the catalytic acid (Glu144) is 'cycled' during catalysis as a consequence of substrate-binding and release and, possibly, by a back and forth movement of Asp142 between Asp140 and Glu144. Rotation of Asp142 towards Glu144 also contributes to an essential distortion of the N-acetyl group of the -1 sugar. Two other conserved residues (Tyr10 and Ser93) are important because they stabilize the charge on Asp140 while Asp142 points towards Glu144. Asp215, lying opposite Glu144 on the other side of the scissile glycosidic bond, contributes to catalysis by promoting distortion of the -1 sugar and by increasing the pKa of the catalytic acid. The hydroxyl group of Tyr214 makes a major contribution to the positioning of the N-acetyl group of the -1 sugar. Taken together, the results show that catalysis in family 18 chitinases depends on a relatively large number of (partly mobile) residues that interact with each other and the substrate.     

Identification of a catalytic residue of Clostridium paraputrificum N-acetyl-beta-D-glucosaminidase Nag3A by site-directed mutagenesis

Clostridium paraputrificum M-21 beta-N-acetylglucosaminidase 3A (Nag3A) is an enzyme classified in family 3 of the glycoside hydrolases. To identify catalytic residues of this enzyme, mutations were introduced into highly conserved Glu and Asp residues. Replacement of Asp175 with Ala abolished the catalytic activity without change in the circular dichroism spectrum, strongly suggesting that this residue is a catalytic residue, a nucleophile/base or a proton donor. Since the K(m) values of mutant enzymes D119N, D229N, D229A and D274N increased 17 to 41 times as compared with that of wild-type enzyme, Asp119, Asp229, and Asp274 appear to be involved in substrate recognition and binding. Taking previous studies into consideration, we presume that Asp303 is the catalytic nucleophile and Asp175 is the proton donor of C. paraputrificum Nag3A.     

Functional consequences of mutations of conserved amino acids in the beta-strand domain of the Ca2(+)-ATPase of sarcoplasmic reticulum

The sequences Thr-Gly-Glu-Ser184 and Asp-Gln-Ser178 and individual residues Asp149, Asp157, and Asp162 in the sarcoplasmic reticulum Ca2(+)-ATPase are highly conserved throughout the family of cation-transporting ATPases. Mutant Thr181----Ala, Gly182----Ala, Glu183----Ala, and Glu183----Gln, created by in vitro mutagenesis, were devoid of Ca2+ transport activity. None of these mutations, however, affected phosphorylation of the enzyme by ATP in the presence of Ca2+ or by inorganic phosphate in the absence of Ca2+, indicating that the high affinity Ca2(+)-binding sites and the nucleotide-binding sites were intact. In each of these mutants, the ADP-sensitive phosphoenzyme intermediate (E1P) decayed to the ADP-insensitive form (E2P) very slowly relative to the wild-type enzyme, whereas E2P decayed at a rate similar to that of the wild-type enzyme. Thus, the inability of the mutants to transport Ca2+ was accounted for by an apparent block of the transport reaction at the E1P to E2P conformational transition. These results suggest that Thr181, Gly182, and Glu183 play essential roles in the conformational change between E1P and E2P. Mutation of Ser184, Asp157, or Ser178 had little or no effect on either Ca2+ transport activity or expression. Mutations of Asp149, Asp162, and Gln177, however, were poorly expressed. Where expression could be measured, in mutations to Asp162 and Gln177, Ca2+ transport activity was essentially equivalent to that of the wild-type enzyme.     

Hydrogen bonding and catalysis: a novel explanation for how a single amino acid substitution can change the pH optimum of a glycosidase

The pH optima of family 11 xylanases are well correlated with the nature of the residue adjacent to the acid/base catalyst. In xylanases that function optimally under acidic conditions, this residue is aspartic acid, whereas it is asparagine in those that function under more alkaline conditions. Previous studies of wild-type (WT) Bacillus circulans xylanase (BCX), with an asparagine residue at position 35, demonstrated that its pH-dependent activity follows the ionization states of the nucleophile Glu78 (pKa 4.6) and the acid/base catalyst Glu172 (pKa 6.7). As predicted from sequence comparisons, substitution of this asparagine residue with an aspartic acid residue (N35D BCX) shifts its pH optimum from 5.7 to 4.6, with an approximately 20% increase in activity. The bell-shaped pH-activity profile of this mutant enzyme follows apparent pKa values of 3.5 and 5.8. Based on 13C-NMR titrations, the predominant pKa values of its active-site carboxyl groups are 3.7 (Asp35), 5.7 (Glu78) and 8.4 (Glu172). Thus, in contrast to the WT enzyme, the pH-activity profile of N35D BCX appears to be set by Asp35 and Glu78. Mutational, kinetic, and structural studies of N35D BCX, both in its native and covalently modified 2-fluoro-xylobiosyl glycosyl-enzyme intermediate states, reveal that the xylanase still follows a double-displacement mechanism with Glu78 serving as the nucleophile. We therefore propose that Asp35 and Glu172 function together as the general acid/base catalyst, and that N35D BCX exhibits a "reverse protonation" mechanism in which it is catalytically active when Asp35, with the lower pKa, is protonated, while Glu78, with the higher pKa, is deprotonated. This implies that the mutant enzyme must have an inherent catalytic efficiency at least 100-fold higher than that of the parental WT, because only approximately 1% of its population is in the correct ionization state for catalysis at its pH optimum. The increased efficiency of N35D BCX, and by inference all "acidic" family 11 xylanases, is attributed to the formation of a short (2.7 A) hydrogen bond between Asp35 and Glu172, observed in the crystal structure of the glycosyl-enzyme intermediate of this enzyme, that will substantially stabilize the transition state for glycosyl transfer. Such a mechanism may be much more commonly employed than is generally realized, necessitating careful analysis of the pH-dependence of enzymatic catalysis.