Functional mapping of charged residues of the 82-116 sequence in factor Xa: evidence that lysine 96 is a factor Va independent recognition site for prothrombin in the prothrombinase complex

It has been hypothesized that two antiparallel structures comprised of residues 82-91 and 102-116 in factor Xa (fXa) may harbor a factor Va- (fVa-) dependent prothrombin recognition site in the prothrombinase complex. There are 11 charged residues in the 82-116 loop of human fXa (Glu-84, Glu-86, Lys-90, Arg-93, Lys-96, Glu-97, Asp-100, Asp-102, Arg-107, Lys-109, and Arg-115). With the exception of Glu-84, which did not express, and Asp-102, which is a catalytic residue, we expressed the Ala substitution mutants of all other residues and evaluated their proteolytic and amidolytic activities in both the absence and presence of fVa. K96A and K109A activated prothrombin with 5-10-fold impaired catalytic efficiency in the absence of fVa. All mutants, however, exhibited normal activity toward the substrate in the presence of fVa. K109A also exhibited impaired amidolytic activity and affinity for Na(+); however, both fVa and higher Na(+) restored the catalytic defect caused by the mutation. Analysis of the X-ray crystal structure of fXa indicated that Glu-84 may interact by a salt bridge with Lys-109, explaining the lack of expression of E84A and the lower activity of K109A in the absence of fVa. These results suggest that none of the residues under study is a fVa-dependent recognition site for prothrombin in the prothrombinase complex; however, Lys-96 is a recognition site for the substrate independent of the cofactor. Moreover, the 82-116 loop is energetically linked to fVa and Na(+) binding sites of the protease.     

Mutation of a unique aspartate residue abolishes the catalytic activity but not substrate binding of the mouse N-methylpurine-DNA glycosylase (MPG)

N-Methylpurine-DNA glycosylase (MPG) initiates base excision repair in DNA by removing a variety of alkylated purine adducts. Although Asp was identified as the active site residue in various DNA glycosylases based on the crystal structure, Glu-125 in human MPG (Glu-145 in mouse MPG) was recently proposed to be the catalytic residue. Mutational analysis for all Asp residues in a truncated, fully active MPG protein showed that only Asp-152 (Asp-132 in the human protein), which is located near the active site, is essential for catalytic activity. However, the substrate binding was not affected in the inactive Glu-152, Asn-152, and Ala-152 mutants. Furthermore, mutation of Asp-152 did not significantly affect the intrinsic tryptophan fluorescence of the enzyme and the far UV CD spectra, although a small change in the near UV CD spectra of the mutants suggests localized conformational change in the aromatic residues. We propose that in addition to Glu-145 in mouse MPG, which functions as the activator of a water molecule for nucleophilic attack, Asp-152 plays an essential role either by donating a proton to the substrate base and, thus, facilitating its release or by stabilizing the steric configuration of the active site pocket.     

Conjugation and modeled structure/function analysis of lysozyme on glycine esterified cotton cellulose-fibers

The antimicrobial activity of lysozyme covalently bound to glycine-derivatized cotton cellulose was assessed in a 96-well format. Lysozyme was immobilized on glycine-bound cotton through a carbodiimide reaction. The attachment to cotton fibers was made through both a single glycine and a glycine dipeptide esterified to cotton cellulose. Higher levels of lysozyme incorporation were evident in the diglycine-linked cotton cellulose samples. The antibacterial activity of the lysozyme-conjugated cotton cellulose against Bacillus subtilis was assessed as a suspension of pulverized cotton fibers in microtiter wells. Inhibition of B. subtilis growth was observed to be optimal within a range of 0.14-0.3 mM (equivalent to 4-20 mg of lysozyme-bound cotton/mL) of lysozyme. Enhancement of activity over soluble lysozyme may result from the solid-phase protection afforded by the cellulose linkage of the glycoprotein against proteolytic lysis. Computational models of lysozyme based on its crystal structure attached through aspartate, glutamate, and COOH-terminal residues to cellopentaose-(3) Gly-O-6-glycyl-glycine ester were constructed. The models demonstrate no steric constraints to the active-site cleft from the glycine-conjugated cellulose chain when lysozyme is bound at the carboxylates of Asp-87, Glu-7, Asp-119, Asp-18, and COOH-terminal Leu-129. The more robust antibacterial activity of the enzyme when bonded to cotton fibers suggests good potential for biologically active enzymes on cotton-based fabrics.     

Mutagenesis of human acetylcholinesterase. Identification of residues involved in catalytic activity and in polypeptide folding.

Evidence for the involvement of Ser-203, His-447, and Glu-334 in the catalytic triad of human acetylcholinesterase was provided by substitution of these amino acids by alanine residues. Of 20 amino acid positions mutated so far in human acetylcholinesterase (AChE), these three were unique in abolishing detectable enzymatic activity (less than 0.0003 of wild type), yet allowing proper production, folding, and secretion. This is the first biochemical evidence for the involvement of a glutamate in a hydrolase triad (Schrag, J.D., Li, Y., Wu, M., and Cygler, M. (1991) Nature 351, 761-764), supporting the x-ray crystal structure data of the Torpedo californica acetylcholinesterase (Sussman, J.L., Harel, M., Frolow, F., Oefner, C., Goldman, A., Toker, L. and Silman, I. (1991) Science 253, 872-879). Attempts to convert the AChE triad into a Cys-His-Glu or Ser-His-Asp configuration by site-directed mutagenesis did not yield effective AChE activity. Another type of substitution, that of Asp-74 by Gly or Asn, generated an active enzyme with increased resistance to succinylcholine and dibucaine; thus mimicking in an AChE molecule the phenotype of the atypical butyrylcholinesterase natural variant (D70G mutation). Mutations of other carboxylic residues Glu-84, Asp-95, Asp-333, and Asp-349, all conserved among cholinesterases, did not result in detectable alteration in the recombinant AChE, although polypeptide productivity of the D95N mutant was considerably lower. In contrast, complete absence of secreted human AChE polypeptide was observed when Asp-175 or Asp-404 were substituted by Asn. These two aspartates are conserved in the entire cholinesterase/thyroglobulin family and appear to play a role in generating and/or maintaining the folded state of the polypeptide. The x-ray structure of the Torpedo acetylcholinesterase supports this assumption by revealing the participation of these residues in salt bridges between neighboring secondary structure elements.     

Glutamate 83 is important for stabilization of domain-domain conformation of Thermus aquaticus glycerol kinase

The gene glpK, encoding glycerol kinase (GlpK) of Thermus aquaticus, has recently been identified. The protein encoded by glpK was found to have an unusually high identity of 81% with the sequence of GlpK from Bacillus subtilis. Three residues (Arg-82, Glu-83, and Asp-244) of T. aquaticus GlpK are conserved in all the known GlpK sequences, including those from various bacteria, yeast and human. The roles that these three residues play in the catalytic mechanism were investigated by using site-directed mutagenesis to produce three mutants: Arg-82-Ala, Glu-83-Ala, and Asp-244-Ala. Replacement of Asp-244 by Ala resulted in a complete loss of activity, thus suggesting that Asp-244 is important for catalysis. Taking k(cat)/K(m) as a simple measure of catalytic efficiency, the mutants Arg-82-Ala and Glu-83-Ala were judged to cause 190- and 37,000-fold decrease, respectively, when compared to the wild-type GlpK. Thus, these three residues play a critical role in the catalytic mechanism. However, only mutant Glu-83-Ala was cleaved by alpha-chymotrypsin, and proteolysis studies showed that the mutant Glu-83-Ala involves a change in the exposure of Tyr-331 at the alpha-chymotrypsin site. This indicates a large domain conformational change, since the residues corresponding to Glu-83 and Tyr-331 in the Escherichia coli GlpK sequence are located in domain IB and domain IIB, respectively. The apparent conformational change caused by replacement of Glu-83 leads us to propose that Glu-83 is an important residue for stabilization of domain conformation.     

Mechanistic characterization of N-formimino-L-glutamate iminohydrolase from Pseudomonas aeruginosa

N-Formimino-l-glutamate iminohydrolase (HutF) from Pseudomonas aeruginosa catalyzes the deimination of N-formimino-l-glutamate in the histidine degradation pathway. An amino acid sequence alignment between HutF and members of the amidohydrolase superfamily containing mononuclear metal centers indicated that residues Glu-235, His-269, and Asp-320 are involved in substrate binding and activation of the nucleophilic water molecule. The purified enzyme contained up to one equivalent of zinc. The metal was removed by dialysis against the metal chelator dipicolinate with the complete loss of catalytic activity. Enzymatic activity was restored by incubation of the apoprotein with Zn2+, Cd2+, Ni2+, or Cu2+. The mutation of Glu-235, His-269, or Asp-320 resulted in the diminution of catalytic activity by two to six orders of magnitude. Bell-shaped profiles were observed for kcat and kcat/Km as a function of pH. The pKa of the group that must be unprotonated for catalytic activity was consistent with the ionization of His-269. This residue is proposed to function as a general base in the abstraction of a proton from the metal-bound water molecule. In the proposed catalytic mechanism, the reaction is initiated by the abstraction of a proton from the metal-bound water molecule by the side chain imidazole of His-269 to generate a tetrahedral intermediate of the substrate. The collapse of the tetrahedral intermediate commences with the abstraction of a second proton via the side chain carboxylate of Asp-320. The C-N bond of the substrate is subsequently cleaved with proton transfer from His-269 to form ammonia and the N-formyl product. The postulated role of the invariant Glu-235 is to ion pair with the positively charged formimino group of the substrate.     

A fungal cellulase shows sequence homology with the active site of hen egg-white lysozyme

The N-terminal amino acid sequence of an endo-β-1,4-glucanase from the cellulase complex of the white-rot fungus Schizophyllum commune has been determined. The sequence from Glu-33 to Tyr-51 was homologous with the active site sequences of various hen egg-white type lysozymes, including lysozyme catalytic residues (Glu-35, Asp-52) and substrate binding residue Asn-44. The homology offers evidence for a lysozyme-type mechanism in enzymic hydrolysis of cellulose.     

Weakening of the interface between adjacent catalytic chains promotes domain closure in Escherichia coli aspartate transcarbamoylase.

Aspartate transcarbamoylase from Escherichia coli is a dodecameric enzyme consisting of two trimeric catalytic subunits and three dimeric regulatory subunits. Asp-100, from one catalytic chain, is involved in stabilizing the C1-C2 interface by means of its interaction with Arg-65 from an adjacent catalytic chain. Replacement of Asp-100 by Ala has been shown previously to result in increases in the maximal specific activity, homotropic cooperativity, and the affinity for aspartate (Baker DP, Kantrowitz ER, 1993, Biochemistry 32:10150-10158). In order to determine whether these properties were due to promotion of domain closure induced by the weakening of the C1-C2 interface, we constructed a double mutant version of aspartate transcarbamoylase in which the Asp-100-->Ala mutation was introduced into the Glu-50-->Ala holoenzyme, a mutant in which domain closure is impaired. The Glu-50/Asp-100-->Ala enzyme is fourfold more active than the Glu-50-->Ala enzyme, and exhibits significant restoration of homotropic cooperativity with respect to aspartate. In addition, the Asp-100-->Ala mutation restores the ability of the Glu-50-->Ala enzyme to be activated by succinate and increases the affinity of the enzyme for the bisubstrate analogue N-(phosphonacetyl)-L-aspartate (PALA). At subsaturating concentrations of aspartate, the Glu-50/Asp-100-->Ala enzyme is activated more by ATP than the Glu-50-->Ala enzyme and is also inhibited more by CTP than either the wild-type or the Glu-50-->Ala enzyme. As opposed to the wild-type enzyme, the Glu-50/Asp-100-->Ala enzyme is activated by ATP and inhibited by CTP at saturating concentrations of aspartate. Structural analysis of the Glu-50/Asp-100-->Ala enzyme by solution X-ray scattering indicates that the double mutant exists in the same T quaternary structure as the wild-type enzyme in the absence of ligands and in the same R quaternary structure in the presence of saturating PALA. However, saturating concentrations of carbamoyl phosphate and succinate only convert a fraction of the Glu-50/Asp-100-->Ala enzyme population to the R quaternary structure, a behavior intermediate between that observed for the Glu-50-->Ala and wild-type enzymes. Solution X-ray scattering was also used to investigate the structural consequences of nucleotide binding to the Glu-50/Asp-100-->Ala enzyme.     

Rapid determination of parvalbumin amino acid sequence from Rana catesbeiana (pI 4.78) by combination of ESI mass spectrometry, protein sequencing, and amino acid analysis

The complete amino acid sequence of beta-type parvalbumin (PA) from bullfrog Rana catesbeiana (pI 4.78) was determined by tandem mass spectrometry in combination with amino acid analysis and peptide sequencing following Arg-C and V(8) protease digestion. The primary structure of the protein was compared with that of beta-type PA from R. esculenta (pI 4.50), with which it is highly homologous. Compared with R. esculenta beta-type PA4.50, R. catesbeiana beta-type parvalbumin (PA 4.78) differed in 15 out of 108 amino acid residues (14% displacement), PA4.78 had Cys at residue 64 and was acetylated at the amino terminus, but 25 residues of the carboxyl terminus were completely conserved. Several amino acid displacements were found between residues 51 and 80 (30% displacement), although the functionally important sequence of PA was completely conserved. The amino acids residues of putative calcium-binding sites were Asp-51, Asp-53, Ser-55, Phe-57, Glu-59, Glu-62, Asp-90, Asp-92, Asp-94, Lys-96, and Glu-101, which were conserved in all a and b-types of R. catesbeiana as well as other parvalbumins. In addition, Arg-75 and Glu-81, which are thought to form a salt bridge located in the interior of the molecule [Coffee, C.J. et al. (1976) Biochim. Biophys. Acta 453, 67-80], were also conserved in PA4.78.     

Crystal Structures of the Catalytic Domain of a Novel Glycohydrolase Family 23 Chitinase from Ralstonia sp. A-471 Reveals a Unique Arrangement of the Catalytic Residues for Inverting Chitin Hydrolysis

Chitinase C from Ralstonia sp. A-471 (Ra-ChiC) has a catalytic domain sequence similar to goose-type (G-type) lysozymes and, unlike other chitinases, belongs to glycohydrolase (GH) family 23. Using NMR spectroscopy, however, Ra-ChiC was found to interact only with the chitin dimer but not with the peptidoglycan fragment. Here we report the crystal structures of wild-type, E141Q, and E162Q of the catalytic domain of Ra-ChiC with or without chitin oligosaccharides. Ra-ChiC has a substrate-binding site including a tunnel-shaped cavity, which determines the substrate specificity. Mutation analyses based on this structural information indicated that a highly conserved Glu-141 acts as a catalytic acid, and that Asp-226 located at the roof of the tunnel activates a water molecule as a catalytic base. The unique arrangement of the catalytic residues makes a clear contrast to the other GH23 members and also to inverting GH19 chitinases.     

The effect of various acylating agents on the catalytic properties and structure of aspartate aminotransferase]

Changes of quaternary structure and conformation of molecule concomitant with inactivation were observed in the course of aspartate transaminase acylation by maleic, citraconic, dimethylmaleic and succinic anhydrides. It was established that acylation of 10-12 xi-amino groups of lysine did not induce the dissociation of transaminase into subunits. Further acylation of amino groups (2 groups if dimethylmaleic anhydrade was used as acylating agent) induced dissociation of transaminase dimer into subunits. These data were obtained by sedimentation analysis. The dissociation was accompanied with a sharp decrease of correlation time (from 18 nsec to 9 nsec) of the paramagnetic label covalently bound to the protein. The obtained results allow us to distinguish three types of xi-aminogroups of aspartate transaminase: exposed (about 12 residues), "contact" (2 residues) located in the vicinity to complementary surfaces of subunits and buried (about 6 residues). The stepwise inactivation occurred during the acylation as a result of conformational changes or appearance of sterical hindrances in the cataytic site of the enzyme. The thiol groups were not modified in transaminase molecule under experimental conditions used. Aspartate transaminase treated with citraconic or dimethylmaleic anhydride may be deacylated under mild conditions. After reacylation the quaternary structure was reconstituted and catalytic activity was almost fully restored.     

Site-directed mutagenesis of active-site-related residues in Torpedo acetylcholinesterase. Presence of a glutamic acid in the catalytic triad.

Site-directed mutagenesis was used to investigate the role of acidic amino acid residues close to the active site of Torpedo acetylcholinesterase. The recently determined atomic structure of this enzyme shows the conserved Glu-327, together with His-440 and Ser-200 as forming a catalytic triad, while the adjacent conserved Asp-326 points away from the active site. Transfection of appropriately mutated DNA into COS cells showed that the mutation of Asp-326----Asn had little effect on catalytic activity or the molecular forms expressed, suggesting no crucial structural or functional role for this residue. Mutation of Glu-327 to Gln or to Asp led to an inactive product. These results support the conclusions of the structural analysis for the two acidic residues.     

Identification of critical residues of choline kinase A2 from Caenorhabditis elegans

Choline kinase catalyzes the phosphorylation of choline by ATP, the first committed step in the CDP-choline pathway for phosphatidylcholine biosynthesis. To begin to elucidate the mechanism of catalysis by this enzyme, choline kinase A-2 from Caenorhabditis elegans was analyzed by systematic mutagenesis of highly conserved residues followed by analysis of kinetic and structural parameters. Specifically, mutants were analyzed with respect to K(m) and k(cat) values for each substrate and Mg(2+), inhibitory constants for Mg(2+) and Ca(2+), secondary structure as monitored by circular dichroism, and sensitivity to unfolding in guanidinium hydrochloride. The most severe impairment of catalysis occurred with the modification of Asp-255 and Asn-260, which are located in the conserved Brenner's phosphotransferase motif, and Asp-301 and Glu-303, in the signature choline kinase motif. For example, mutation of Asp-255 or Asp-301 to Ala eliminated detectable catalytic activity, and mutation of Asn-260 and Glu-303 to Ala decreased k(cat) by 300- and 10-fold, respectively. Additionally, the K(m) for Mg(2+) for mutants N260A and E303A was approximately 30-fold higher than that of wild type. Several other residues (Ser-86, Arg-111, Glu-125, and Trp-387) were identified as being important: Catalytic efficiencies (k(cat)/K(m)) for the enzymes in which these residues were mutated to Ala were reduced to 2-25% of wild type. The high degree of structural similarity among choline kinase A-2, aminoglycoside phosphotransferases, and protein kinases, together with the results from this mutational analysis, indicates it is likely that these conserved residues are located at the catalytic core of choline kinase.     

Staphylococcus aureus aminopeptidase S is a founding member of a new peptidase clan

Staphylococcus aureus aminopeptidase S (AmpS) has been named for its predicted, but experimentally untested, aminopeptidase activity. The enzyme is homologous to biochemically characterized aminopeptidases that contain two cobalt or zinc ions in their active centers, but it is unrelated to all structurally characterized metallopeptidases. Here, we demonstrate AmpS aminopeptidase activity experimentally, and we present the 1.8-A crystal structure of the enzyme. Two metal ions with full occupancy and a third metal ion with low occupancy are present in the active site. A water molecule and Glu-319 serve as bridging ligands to the two metals with full occupancy. One of these metal ions is additionally coordinated by Glu-253 and His-348 and the other by His-381 and Asp-383. In addition, the metals are involved in weak metal-donor interactions to a water molecule and to Tyr-355. In the crystal, AmpS forms a dimer with a large internal cavity. The active sites are located at opposite ends of this internal cavity and are essentially inaccessible from the outside, suggesting that an inactive conformation was crystallized. Because gel filtration and analytical ultracentrifugation data also suggest dimer formation, the problem of substrate access to the active site cavity remains unresolved.     

Purification, characterization, and nucleotide sequence of the thermolabile alpha-amylase from the antarctic psychrotroph Alteromonas haloplanctis A23.

The alpha-amylase excreted by the antarctic bacterium Alteromonas haloplanctis was purified and the corresponding amy gene was cloned and sequenced. N- and C-terminal amino acid sequencing were used to establish the primary structure of the mature A. haloplanctis alpha-amylase which is composed of 453 amino acids with a predicted Mr of 49,340 and a pI of 5.5. Three Ca2+ ions are bound per molecule and its activity is modulated by chloride ions. Within the four consensus sequences, Asp-174, Glu-200, and Asp-264 are the proposed catalytic residues. The psychrotrophic A. haloplanctis alpha-amylase is characterized by a high amylolytic activity at low temperatures, a reduced apparent optimal temperature, and typical thermodynamic activation parameters A. haloplanctis alpha-amylase has also a low thermal stability as demonstrated by the temperature effect on both activity and secondary structure. It is suggested that structure flexibility and lower sensitivity of secondary structure to temperature variations in the low temperature range are the main structural adaptations of the psychrotrophic enzyme. The unusual stacking of small amino acids around the catalytic residues is proposed as a factor inducing active site flexibility and concomitant high activity of the enzyme at low temperatures.     

Molecular mechanism of the Thermus thermophilus ADP-ribose pyrophosphatase from mutational and kinetic studies

ADP-ribose pyrophosphatase (ADPRase), a member of the nudix protein family, catalyzes the hydrolysis of ADP-ribose to AMP and ribose 5'-phosphate. We have determined the crystal structure of ADPRase from Thermus thermophilus HB8 (TtADPRase). We performed kinetic analysis of mutants of TtADPRase to elucidate the substrate recognition and the catalytic mechanism. Our results suggest that interactions responsible for the substrate recognition are located at the terminal moieties of the substrate. The adenine moiety is recognized by Ile-19 and the main chain carbonyl group of Glu-29 and/or Gly-104. The terminal ribose moiety is recognized by the sum of some weak interactions with multiple residues that are close in space. Glu-82 and Glu-86, conserved in the nudix motif, were previously shown to be essential for catalysis. Mutation of these residues shows that the dependence of kcat on pH is almost the same as that of the wild-type enzyme. Results suggest that Glu-82 and Glu-86 are essential for catalysis but unlikely to act as a catalytic base. In the crystal structure, each acidic residue coordinates with a metal ion. Furthermore, a water molecule coordinates between these two metals. Our results suggest a two-metal ion mechanism for the catalysis of ADPRase in which a water molecule is activated to act as a nucleophile by the cations coordinated by Glu-82 and Glu-86. Arg-54, Glu-70, Arg-81, and Glu-85 are predicted to support this nucleophilic attack on the alpha-phosphate of the substrate. Interestingly, ADPRase displays differences in the substrate recognition and the catalytic mechanism from the models proposed for other nudix proteins. Our results highlight the diversity within the nudix protein family in terms of substrate recognition and catalysis.     

Analysis of the active center of branching enzyme II from maize endosperm

Analysis of the primary structure of mBEII, with those of other branching and amylolytic enzymes as reference, identifies four highly conserved regions which may be involved in substrate binding and in catalysis. When one of the amino acid residues corresponding to the putative catalytic sites of mBEII, i.e., Asp-386, Glu-441, and Asp-509, was replaced, activity disappeared. These putative catalytic residues are located in three different regions (regions 2–4) of the four highly conserved regions (regions 1–4) which exist in the primary structure of most starch hydrolases and related enzymes, including branching enzymes. Region 3, which contains Glu-441 as one of the putative catalytic residues, was located downstream of the carboxyl-terminal position previously reported. The importance of the carboxyl amino acid residues was also demonstrated by chemical modification of the branching enzyme protein using 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide.     

The structural analysis and the role of calcium binding site for thermal stability in mannanase

Mannanase is an important enzyme involved in the degradation of mannan, production of bioactive oligosaccharides, and biobleaching of kraft pulp. Mannanase must be thermostable for use in industrial applications. In a previous study, we found that the thermal stability of mannanase from Streptomyces thermolilacinus (StMan) and Thermobifida fusca (TfMan) is enhanced by calcium. Here, we investigated the relationship between the three-dimensional structure and primary sequence to identify the putative calcium-binding site. The results of site-directed mutagenesis experiments indicated that Asp-285, Glu-286, and Asp-287 of StMan (StDEDAAAdC) and Asp-264, Glu-265, and Asp-266 of TfMan (TfDEDAAAdC) were the key residues for calcium binding affinity. Isothermal titration calorimetry revealed that the catalytic domain of StMan and TfMan (StMandC and TfMandC, respectively) bound calcium with a K_a of 3.02 × 10⁴ M⁻¹ and 1.52 × 10⁴ M⁻¹, respectively, both with stoichiometry consistent with one calcium-binding site per molecule of enzyme. Non-calcium-binding mutants (StDEDAAAdC and TfDEDAAAdC) did not show any calorimetric change. From the primary structure alignment of several mannanases, the calcium-binding site was found to be highly conserved in GH5 bacterial mannanases. This is the first study indicating enhanced thermal stability of GH5 bacterial mannanases by calcium binding.     

Modulation of Streptomyces leucine aminopeptidase by calcium: identification and functional analysis of key residues in activation and stabilization by calcium

Streptomyces griseus leucine aminopeptidase (SGAP), which has two zinc atoms in its active site, is clinically important as a model for understanding the structure and mechanism of action of other metallopeptidases. SGAP is a calcium-activated and calcium-stabilized enzyme, and its activation by calcium correlates with substrate specificity. In our previous study, we found a non-calcium-modulated leucine aminopeptidase secreted by Streptomyces septatus, the primary structure of which showed 71% identity with SGAP. In this study, we constructed chimeras of SGAP and S. septatus aminopeptidase by using an in vivo DNA shuffling system and several mutant enzymes by site-directed mutagenesis to identify the key residues in this modulation by calcium. We identified the key residues Asp-173 and Asp-174 of SGAP associated with both SGAP activation and stabilization by calcium. We also showed that the known calcium-binding site, which is composed of Asp-3, Ile-4, Asp-262, and Asp-266 of SGAP, only contributes to SGAP stabilization by calcium. Furthermore, we identified an important residue, Glu-196, that functions in cooperation with Asp-173, Asp-174, and calcium to increase the catalytic activity of SGAP.     

Crystal structure of the aspartic acid-199----asparagine mutant of chloramphenicol acetyltransferase to 2.35-A resolution: structural consequences of disruption of a buried salt bridge

The crystal structure of the Asp-199----Asn mutant of chloramphenicol acetyltransferase (CAT) has been determined to 2.35-A resolution. In wild-type CAT Asp-199 is involved in a fully buried intrasubunit salt bridge with Arg-18, an interaction that is adjacent to the active site. Replacement of aspartate with asparagine by site-directed mutagenesis disrupts this salt bridge and causes extensive conformational changes within the active site. The imidazole group of the catalytically essential His-195 is reoriented, with the loss of interactions thought to stabilize the preferred tautomer of this residue. Arg-18 and Asn-199 form three new intersubunit interactions as a result of large side-chain torsion angle changes which cause the movement of two polypeptide loops, some residues of which are up to 20 A away from the site of the mutation. The new interactions of Arg-18 and Asn-199 compensate for the loss of the buried salt bridge and afford near-wild-type thermostability to Asn-199 CAT, albeit with a greatly reduced activity.