Role of Glu318 at the putative distal site in the catalytic function of cytochrome P450d.

Most microsomal P450s have a conserved "threonine cluster" composed of three Thrs (Thr319, Thr321, Thr322 for P450d) at a putative distal site. An ionic amino acid at 318 is also well conserved as Glu or Asp for most P450s. To understand the role of these conserved polar amino acids at the putative distal site in the catalytic function of microsomal P450, we studied how mutations at this site of P450d influence the activation of molecular oxygen in the reconstituted system. Catalytic activity (0.02 min-1) toward 7-ethoxycoumarin of the Glu318Ala mutant of P450d was just 6% of that (0.33 min-1) of the wild type, while those of Glu318Asp, Thr319Ala, and Thr322Ala were comparable to or even higher than that of the wild type. Consumption rates of O2 and formation rates of H2O2 of those mutants varied in accord with the catalytic activities. Especially, the efficiency (0.5%) of incorporated oxygen atom to the substrate versus produced H2O2 for the Glu318Ala mutant was much lower than that (3.7%) of the wild type, while that (58.8%) for the mutant Glu318Asp was 16-fold higher than that of the wild type. In addition, the autoxidation [Fe(II)---- Fe(III)] rate (0.074 s-1) of the Glu318Ala mutant was much lower than those (0.374-0.803 s-1) of the wild type and other mutants. Thus, we strongly suggest that Glu318 plays an important role in the catalytic function toward 7-ethoxycoumarin of microsomal P450d.     

Functional investigation of conserved membrane-embedded glutamate residues in the proton-coupled peptide transporter YjdL

Proton-dependent oligopeptide transporters (POTs) are secondary active symporters that utilize the proton gradient to drive the inward translocation of di- and tripeptides. We have mutated two highly conserved membraneembedded glutamate residues (Glu20 and Glu388) in the E. coli POT YjdL to probe their possible functional roles, in particular if they were involved/implicated in recognition of the substrate N-terminus. The mutants (Glu20Asp, Glu20Gln, Glu388Asp, and Glu388Gln) were tested for substrate uptake, which indicated that both the negative charge and the side chain length were important for function. The IC50 values of dipeptides with lack of or varying N-terminus (Ac-Lys, Gly- Lys, β-Ala-Lys, and 4-GABA-Lys), showed that Gly-Lys and β-Ala-Lys ranged between ~0.1 to ~1.0 mM for wild type and Glu20 mutants. However, for Glu388Gln the IC50 increased to ~2.0 and > 10 mM for Gly-Lys and β-Ala-Lys, respectively, suggesting that Glu388, and not Glu20, is able to sense the position of the N-terminus and important for the interaction. Furthermore, uptake as a function of pH showed that the optimum at around pH 6.5 for wild type YjdL shifted to 7.0-7.5 for the Glu388Asp/Gln mutants while the Glu20Asp retained the wild type optimum. Uptake by the Glu20Gln on the other hand was completely unaffected by the bulk pH in the range tested, which indicated a possible role of Glu20 in proton translocation.     

Importance of van der Waals contact between Glu 35 and Trp 109 to the catalytic action of human lysozyme.

The importance of van der Waals contact between Glu 35 and Trp 109 to the active-site structure and the catalytic properties of human lysozyme (HL) has been investigated by site-directed mutagenesis. The X-ray analysis of mutant HLs revealed that both the replacement of Glu 35 by Asp or Ala, and the replacement of Trp 109 by Phe or Ala resulted in a significant but localized change in the active-site cleft geometry. A prominent movement of the backbone structure was detected in the region of residues 110 to 120 and in the region of residues 100 to 115 for the mutations concerning Glu 35 and Trp 109, respectively. Accompanied by the displacement of the main-chain atoms with a maximal deviation of C alpha atom position ranging from 0.7 A to 1.0 A, the mutant HLs showed a remarkable change in the catalytic properties against Micrococcus luteus cell substrate as compared with native HL. Although the replacement of Glu 35 by Ala completely abolished the lytic activity, HL-Asp 35 mutant retained a weak but a certain lytic activity, showing the possible involvement of the side-chain carboxylate group of Asp 35 in the catalytic action. The kinetic consequence derived from the replacement of Trp 109 by Phe or Ala together with the result of the structural change suggested that the structural detail of the cleft lobe composed of the residues 100 to 115 centered at Ala 108 was responsible for the turnover in the reaction of HL against the bacterial cell wall substrate. The results revealed that the van der Waals contact between Glu 35 and Trp 109 was an essential determinant in the catalytic action of HL.     

Mutagenic and enzymological studies of the hydratase and isomerase activities of 2-enoyl-CoA hydratase-1

Structural and enzymological studies have shown the importance of Glu144 and Glu164 for the catalysis by 2-enoyl-CoA hydratase-1 (crotonase). Here we report about the enzymological properties of the Glu144Ala and Glu164Ala variants of rat mitochondrial 2-enoyl-CoA hydratase-1. Size-exclusion chromatography and CD spectroscopy showed that the wild-type protein and mutants have similar oligomerization states and folding. The kcat values of the active site mutants Glu144Ala and Glu164Ala were decreased about 2000-fold, but the Km values were unchanged. For study of the potential intrinsic Delta3-Delta2-enoyl-CoA isomerase activity of mECH-1, a new assay using 2-enoyl-CoA hydratase-2 and (R)-3-hydroxyacyl-CoA dehydrogenase as auxiliary enzymes was introduced. It was demonstrated that rat wild-type mECH-1 is also capable of catalyzing isomerization with the activity ratio (isomerization/hydration) of 1/5000. The kcat values of isomerization in Glu144Ala and Glu164Ala were decreased 10-fold and 1000-fold, respectively. The data are in line with the proposal that Glu164 acts as a protic amino acid residue for both the hydration and the isomerization reaction. The structural factors favoring the hydratase over the isomerase reaction have been addressed by investigating the enzymological properties of the Gln162Ala, Gln162Met, and Gln162Leu variants. The Gln162 side chain is hydrogen bonded to the Glu164 side chain; nevertheless, these mutants have enzymatic properties similar to that of the wild type, indicating that catalytic function of the Glu164 side chain in the hydratase and isomerase reaction does not depend on the interactions with the Gln162 side chain.     

Role of Glu318 and Thr319 in the catalytic function of cytochrome P450d (P4501A2): effects of mutations on the methanol hydroxylation.

Polar amino acids in the (putative) distal site are well conserved in P450s. For example, Glu318 for P450d is well conserved as either Glu or Asp for P450s, and Thr319 for P450d is also conserved for P450s. We have studied how mutations at Glu318 and Thr319 of P450d influence the catalytic activity toward methanol associated with the activation of O2. Catalytic activities of Glu318Asp, Glu318Ala, and Thr319Ala mutants toward methanol were 60, 25, and 38%, respectively, compared with that of the wild type. O2 consumption and NADPH oxidation rates of each mutants varied corresponding to the catalytic activities. However, surprisingly, efficiency (16-40%) of incorporated O to the substrate vs. consumed O2 for the Glu318Ala and Thr319Ala mutants were higher than that (9%) of the wild type. In addition, H2O2, which is produced from uncoupling for the wild-type P450d, was not observed for reaction of the Glu318Ala and Thr319Ala mutants. It seemed that consumed O2 was partially reduced to 2 mol of H2O by 4-electron transfer from NADPH for the wild-type and Thr319Ala mutant. However, for the two Glu318 mutants, it appeared that the consumed O2 was not reduced in the same way. It was thus suggested that the conserved Glu318 and Thr319 of P450d are not essential for the activation of O2 in the methanol oxidation. Role of the water molecule or the methanol molecule in the catalytic function was implied.     

Structural and functional analysis of critical amino acids in TMVI of the NHE1 isoform of the Na+/H+ exchanger

The mammalian Na(+)/H(+) exchanger isoform 1 (NHE1) resides on the plasma membrane and exchanges one intracellular H(+) for one extracellular Na(+). It maintains intracellular pH and regulates cell volume, and cell functions including growth and cell differentiation. Previous structural and functional studies on TMVI revealed several amino acids that are potentially pore lining. We examined these and other critical residues by site-directed mutagenesis substituting Asn227→Ala, Asp, Arg; Ile233→Ala; Leu243→Ala; Glu247→Asp, Gln; Glu248→Asp, Gln. Mutant NHE1 proteins were characterized in AP-1 cells, which do not express endogenous NHE1. All the TMVI critical amino acids were highly sensitive to substitution and changes often lead to a dysfunctional protein. Mutations of Asn227→Ala, Asp, Arg; Ile233→Ala; Leu243→Ala; Glu247→Asp; Glu248→Gln yielded significant reduction in NHE1 activity. Mutants of Asn227 demonstrated defects in protein expression, targeting and activity. Substituting Asn227→Arg and Ile233→Ala decreased the surface localization and expression of NHE1 respectively. The pore lining amino acids Ile233 and Leu243 were both essential for activity. Glu247 was not essential, but the size of the residue at this location was important while the charge on residue Glu248 was more critical to NHE1 function. Limited trypsin digestion on Leu243→Ala and Glu248→Gln revealed that they had increased susceptibility to proteolytic attack, indicating an alteration in protein conformation. Modeling of TMVI with TMXI suggests that these TM segments form part of the critical fold of NHE1 with Ile233 and Leu465 of TMXI forming a critical part of the extracellular facing ion conductance pathway.     

Amino acid substitution at the substrate-binding subsite alters the specificity of the Phanerochaete chrysosporium cellobiose dehydrogenase

The active site of cellobiose dehydrogenase from Phanerochaete chrysosporium is composed of two subsites, a catalytic C subsite and a substrate-binding B subsite. Based on the crystal structure of the enzyme with a cellobiose analogue, residue Glu279 was selected for site-directed mutagenesis studies. Substitution of Glu279 to Ala, Asn, and Asp had no effect on the expression of the protein in Pichia pastoris but completely abolished its enzymatic activity. Substitution of Glu279 to Gln drastically altered the enzyme’s substrate specificity. While the wild-type cellobiose dehydrogenase efficiently oxidizes cellobiose and lactose, the Glu279Gln mutant retained most of its activity with cellobiose but was completely inactive with lactose. We generated structural models of the active site interacting with cellobiose and lactose to provide an interpretation of these results.     

Importance of stalk segment S5 for intramolecular communication in the sarcoplasmic reticulum Ca2+-ATPase

Sixteen residues in stalk segment S5 of the Ca(2+)-ATPase of sarcoplasmic reticulum were studied by site-directed mutagenesis. The rate of the Ca(2+) binding transition, determined at 0 degrees C, was enhanced relative to wild type in mutants Ile(743) --> Ala, Val(747) --> Ala, Glu(748) --> Ala, Glu(749) --> Ala, Met(757) --> Gly, and Gln(759) --> Ala and reduced in mutants Asp(737) --> Ala, Asp(738) --> Ala, Ala(752) --> Leu, and Tyr(754) --> Ala. In mutant Arg(762) --> Ile, the rate of the Ca(2+) binding transition was wild type like at 0 degrees C, whereas it was 3.5-fold reduced relative to wild type at 25 degrees C. The rate of dephosphorylation of the ADP-insensitive phosphoenzyme was increased conspicuously in mutants Ile(743) --> Ala and Tyr(754) --> Ala (close to 20-fold in the absence of K(+)) and increased to a lesser extent in Asn(739) --> Ala, Glu(749) --> Ala, Gly(750) --> Ala, Ala(752) --> Gly, Met(757) --> Gly, and Arg(762) --> Ile, whereas it was reduced in mutants Asp(737) --> Ala, Val(744) --> Gly, Val(744) --> Ala, Val(747) --> Ala, and Ala(752) --> Leu. In mutants Ile(743) --> Ala, Tyr(754) --> Ala, and Arg(762) --> Ile, the apparent affinities for vanadate were enhanced 23-, 30-, and 18-fold, respectively, relative to wild type. The rate of Ca(2+) dissociation was 11-fold increased in Gly(750) --> Ala and 2-fold reduced in Val(747) --> Ala. Mutants with alterations to Arg(751) either were not expressed at a significant level or were completely nonfunctional. The findings show that S5 plays a crucial role in mediating communication between the Ca(2+) binding pocket and the catalytic domain and that Arg(751) is important for both structural and functional integrity of the enzyme.     

Structure determinants and substrate recognition of serine carboxypeptidase-like acyltransferases from plant secondary metabolism

Structures of the serine carboxypeptidase-like enzymes 1-O-sinapoyl-beta-glucose:L-malate sinapoyltransferase (SMT) and 1-O-sinapoyl-beta-glucose:choline sinapoyltransferase (SCT) were modeled to gain insight into determinants of specificity and substrate recognition. The structures reveal the alpha/beta-hydrolase fold as scaffold for the catalytic triad Ser-His-Asp. The recombinant mutants of SMT Ser173Ala and His411Ala were inactive, whereas Asp358Ala displayed residual activity of 20%. 1-O-sinapoyl-beta-glucose recognition is mediated by a network of hydrogen bonds. The glucose moiety is recognized by a hydrogen bond network including Trp71, Asn73, Glu87 and Asp172. The conserved Asp172 at the sequence position preceding the catalytic serine meets sterical requirements for the glucose moiety. The mutant Asn73Ala with a residual activity of 13% underscores the importance of the intact hydrogen bond network. Arg322 is of key importance by hydrogen bonding of 1-O-sinapoyl-beta-glucose and L-malate. By conformational change, Arg322 transfers L-malate to a position favoring its activation by His411. Accordingly, the mutant Arg322Glu showed 1% residual activity. Glu215 and Arg219 establish hydrogen bonds with the sinapoyl moiety. The backbone amide hydrogens of Gly75 and Tyr174 were shown to form the oxyanion hole, stabilizing the transition state. SCT reveals also the catalytic triad and a hydrogen bond network for 1-O-sinapoyl-beta-glucose recognition, but Glu274, Glu447, Thr445 and Cys281 are crucial for positioning of choline.     

The active site base controls cofactor reactivity in Escherichia coli amine oxidase: x-ray crystallographic studies with mutational variants.

Amine oxidases utilize a proton abstraction mechanism following binding of the amine substrate to the C5 position of the cofactor, the quinone form of trihydroxyphenylalanine (TPQ). Previous work [Wilmot, C. M., et al. (1997) Biochemistry 36, 1608-1620] has shown that Asp383 in Escherichia coliamine oxidase (ECAO) is the catalytic base which performs the key step of proton abstraction. This paper explores in more depth this and other roles of Asp383. The crystal structures of three mutational variants are presented together with their catalytic properties, visible spectra, and binding properties for a substrate-like inhibitor, 2-hydrazinopyridine (2-HP), in comparison to those of the wild type enzyme. In wild type ECAO, the TPQ is located in a wedge-shaped pocket which allows more freedom of movement at the substrate binding position (C5) than for TPQ ring carbons C1-C4. A role of Asp383, whose carboxylate is located close to O5, is to stabilize the TPQ in its major conformation in the pocket. Replacement of Asp383 with the isostructural, but chemically distinct, Asn383 does not affect the location or dynamics of the TPQ cofactor significantly, but eliminates catalytic activity and drastically reduces the affinity for 2-HP. Removal of the side chain carboxyl moiety, as in Ala383, additionally allows the TPQ the greater conformational flexibility to coordinate to the copper, which demonstrates that Asp383 helps maintain the active site structure by preventing TPQ from migrating to the copper. Glu383 has a greatly decreased catalytic activity, as well as a decreased affinity for 2-HP relative to that of wild type ECAO. The electron density reveals that the longer side chain of Glu prevents the pivotal motion of the TPQ by hindering its movement within the wedge-shaped active site pocket. The results show that Asp383 performs multiple roles in the catalytic mechanism of ECAO, not only in acting as the active site base at different stages of the catalytic cycle but also in regulating the mobility of the TPQ that is essential to catalysis.     

Enhanced activity of <Emphasis Type="Italic">Withania somnifera</Emphasis> family-1 glycosyltransferase (UGT73A16) via mutagenesis

This work used an approach of enzyme engineering towards the improved production of baicalin as well as alteration of acceptor and donor substrate preferences in UGT73A16. The 3D model of Withania somnifera family-1 glycosyltransferase (UGT73A16) was constructed based on the known crystal structures of plant UGTs. Structural and functional properties of UGT73A16 were investigated using docking and mutagenesis. The docking studies were performed to understand the key residues involved in substrate recognition. In the molecular model of UGT73A16, substrates binding pockets are located between N- and C-terminal domains. Modeled UGT73A16 was docked with UDP-glucose, UDP-glucuronic acid (UDPGA), kaempferol, isorhamnetin, 3-hydroxy flavones, naringenin, genistein and baicalein. The protein–ligand interactions showed that His 16, Asp 246, Lys 255, Ala 337, Gln 339, Val 340, Asn 358 and Glu 362 amino acid residues may be important for catalytic activity. The kinetic parameters indicated that mutants A337C and Q339A exhibited 2–3 fold and 6–7 fold more catalytic efficiency, respectively than wild type, and shifted the sugar donor specificity from UDP-glucose to UDPGA. The mutant Q379H displayed large loss of activity with UDP-glucose and UDPGA strongly suggested that last amino acid residue of PSPG box is important for glucuronosylation and glucosylation and highly specific to sugar binding sites. The information obtained from docking and mutational studies could be beneficial in future to engineer this biocatalyst for development of better ones.     

Engineering PQQ glucose dehydrogenase with improved substrate specificity. Site-directed mutagenesis studies on the active center of PQQ glucose dehydrogenase

Site-directed mutagenesis was carried out on the active site of water-soluble PQQ glucose dehydrogenase (PQQGDH-B) to improve its substrate specificity. Amino acid substitution of His168 resulted in a drastic decrease in the enzyme's catalytic activity, consistent with its putative catalytic role. Substitutions were also carried out in neighboring residues, Lys166, Asp167, and Gln169, in an attempt to alter the enzyme's substrate binding site. Lys166 and Gln169 mutants showed only minor changes in substrate specificity profiles. In sharp contrast, mutants of Asp167 showed considerably altered specificity profiles. Of the numerous Asp167 mutants characterized, Asp167Glu showed the best substrate specificity profile, while retaining most of its catalytic activity for glucose and stability. We also investigated the cumulative effect of combining the Asp167Glu substitution with the previously reported Asn452Thr mutation. Interpretation of the effect of the replacement of Asp167 to Glu on the alteration of substrate specificity in relation with the predicted 3D model of PQQGDH-B is also discussed.     

AdoMet-dependent methyl-transfer: Glu119 is essential for DNA C5-cytosine methyltransferase M.HhaI

The role of Glu119 in S-adenosyl-L-methionine-dependent DNA methyltransferase M.HhaI-catalyzed DNA methylation was studied. Glu119 belongs to the highly conserved Glu/Asn/Val motif found in all DNA C5-cytosine methyltransferases, and its importance for M.HhaI function remains untested. We show that formation of the covalent intermediate between Cys81 and the target cytosine requires Glu119, since conversion to Ala, Asp or Gln lowers the rate of methyl transfer 10(2)-10(6) fold. Further, unlike the wild-type M.HhaI, these mutants are not trapped by the substrate in which the target cytosine is replaced with the mechanism-based inhibitor 5-fluorocytosine. The DNA binding affinity for the Glu119Asp mutant is decreased 10(3)-fold. Thus, the ability of the enzyme to stabilize the extrahelical cytosine is coupled directly to tight DNA binding. The structures of the ternary protein/DNA/AdoHcy complexes for both the Glu119Ala and Glu119Gln mutants (2.70 A and 2.75 A, respectively) show that the flipped base is positioned nearly identically with that observed in the wild-type M.HhaI complex. A single water molecule in the Glu119Ala structure between Ala119 and the extrahelical cytosine N3 is lacking in the Glu119Gln and wild-type M.HhaI structures, and most likely accounts for this mutant's partial activity. Glu119 has essential roles in activating the target cytosine for nucleophilic attack and contributes to tight DNA binding.     

The crystal structure of a lysozyme c from housefly Musca domestica, the first structure of a digestive lysozyme

Lysozymes from family 22 of glycoside hydrolases are usually part of the defense system against bacteria. However in ruminant artiodactyls and saprophagous insects, lysozymes are involved in the digestion of bacteria. Here, we report the first crystallographic structure of a digestive lysozyme in its native and complexed forms, the structure of lysozyme 1 from Musca domestica larvae midgut (MdL1). Structural and biochemical data presented for MdL1 are analyzed in light of digestive lysozymes' traits. The structural core is similar, but a careful analysis of a structural alignment generated with other lysozymes c reveals that significant differences occur in coil regions. The loop from MdL1 defined by residues 98-100 has one deletion previous to residue Gln100, which leads to a less exposed conformation and might justify the resistance to proteolysis observed for MdL1. In addition, Gln100 is directly involved in a few hydrogen bonds to the ligand in a yet unobserved substrate binding mode. The pK(a)s of the MdL1 catalytic residues (Glu32 and Asp50) are lower (6.40 and 3.09, respectively) than those from Gallus gallus egg lysozyme (GgL, hen egg white lysozyme-HEWL) (6.61 and 3.85, respectively). A unique feature of MdL1 is a hydrogen bond between Thr107 Ogamma and Glu32 carboxylate group, which combined with the presence of Ser106 contributes to decrease the pK(a) of Glu32. Furthermore, in MdL1 the presence of Asn46 preventing the occurrence of an electrostatic repulsion with Asp50 and the increment in the solvent exposition of Asp50 due to Pro42 insertion contribute to reduce the pK(a) of Asp50. These structural elements affecting the pK(a)s of the catalytic residues should contribute to the acidic pH optimum presented by MdL1.     

Anaerobiospirillum succiniciproducens phosphoenolpyruvate carboxykinase: mutagenesis at metal site 2

Phosphoenolpyruvate (PEP) carboxykinases harbor two divalent metal-binding sites. One cation interacts with the enzyme (metal binding site 1) to elicit activation, while a second cation (metal binding site 2) interacts with the nucleotide to serve as the metal nucleotide substrate. Mutants of Anaerobiospirillum succiniciproducens PEP carboxykinase have been constructed where Thr249 and Asp262, two residues of metal binding site 2 of the enzyme, were altered. Binding of the 3'(2')-O-(N-methylantraniloyl) derivative of ADP provides a test of the structural integrity of these mutants. The conservative mutation (Asp262Glu) retains a significant proportion of the wild type enzymatic activity. Meanwhile, removal of the OH group of Thr249 in the Thr249Ala mutant causes a decrease in V(max) by a factor of 1.1 x 10(4). Molecular modeling of wild type and mutant enzymes suggests that the lower catalytic efficiency of the Thr249Ala enzyme could be explained by a movement of the lateral chain of Lys248, a critical catalytic residue, away from the reaction center.     

Effect on catalysis by replacement of catalytic residue from hen egg white lysozyme to Venerupis philippinarum lysozyme*

Asn46Asp/Asp52Ser or Asn46Glu/Asp52Ser hen egg white lysozyme (HEL) mutant was designed by introducing the substituted catalytic residue Asp46 or Glu46, respectively, based on Venerupis philippinarum (Vp) lysozyme structure as a representative of invertebrate‐type (i‐type) lyzozyme. These mutations restored the bell‐shaped pH‐dependency of the enzyme activity from the sigmoidal pH‐dependency observed for the Asp52Ser mutant. Furthermore both lysozyme mutants possessed retaining mechanisms like Vp lysozyme and HEL. The Asn46Glu/Asp52Ser mutant, which has a shorter distance between two catalytic residues, formed a glycosyl adduct in the reaction with the N‐acetylglucosamine oligomer. Furthermore, we found the accelerated turnover through its glycosyl adduct formation and decomposition. The turnover rate estimated from the glycosyl formation and decomposition rates was only 20% of the observed hydrolysis rate of the substrate. Based on these results, we discussed the catalytic mechanism of lysozymes.     

Histidine-40 of ribonuclease T1 acts as base catalyst when the true catalytic base, glutamic acid-58, is replaced by alanine

Mechanisms for the ribonuclease T1 (RNase T1; EC 3.1.27.3) catalyzed transesterification reaction generally include the proposal that Glu58 and His92 provide general base and general acid assistance, respectively [Heinemann, U., & Saenger, W. (1982) Nature (London) 299, 27-31]. This view was recently challenged by the observation that mutants substituted at position 58 retain high residual activity; a revised mechanism was proposed in which His40, and not Glu58, is engaged in catalysis as general base [Nishikawa, S., Morioka, H., Kim, H., Fuchimura, K., Tanaka, T., Uesugi, S., Hakoshima, T., Tomita, K., Ohtsuka, E., & Ikehara, M. (1987) Biochemistry 26, 8620-8624]. To clarify the functional roles of His40, Glu58, and His92, we analyzed the consequences of several amino acid substitutions (His40Ala, His40Lys, His40Asp, Glu58Ala, Glu58Gln, and His92Gln) on the kinetics of GpC transesterification. The dominant effect of all mutations is on Kcat, implicating His40, Glu58, and His92 in catalysis rather than in substrate binding. Plots of log (Kcat/Km) vs pH for wild-type, His40Lys, and Glu58Ala RNase T1, together with the NMR-determined pKa values of the histidines of these enzymes, strongly support the view that Glu58-His92 acts as the base-acid couple. The curves also show that His40 is required in its protonated form for optimal activity of wild-type enzyme. We propose that the charged His40 participates in electrostatic stabilization of the transition state; the magnitude of the catalytic defect (a factor of 2000) from the His40 to Ala replacement suggests that electrostatic catalysis contributes considerably to the overall rate acceleration. For Glu58Ala RNase T1, the pH dependence of the catalytic parameters suggests an altered mechanism in which His40 and His92 act as base and acid catalyst, respectively. The ability of His40 to adopt the function of general base must account for the significant activity remaining in Glu58-mutated enzymes.     

Contribution of active site residues to the activity and thermal stability of ribonuclease Sa

We have used site-specific mutagenesis to study the contribution of Glu 74 and the active site residues Gln 38, Glu 41, Glu 54, Arg 65, and His 85 to the catalytic activity and thermal stability of ribonuclease Sa. The activity of Gln38Ala is lowered by one order of magnitude, which confirms the involvement of this residue in substrate binding. In contrast, Glu41Lys had no effect on the ribonuclease Sa activity. This is surprising, because the hydrogen bond between the guanosine N1 atom and the side chain of Glu 41 is thought to be important for the guanine specificity in related ribonucleases. The activities of Glu54Gln and Arg65Ala are both lowered about 1000-fold, and His85Gln is totally inactive, confirming the importance of these residues to the catalytic function of ribonuclease Sa. In Glu74Lys, k(cat) is reduced sixfold despite the fact that Glu 74 is over 15 A from the active site. The pH dependence of k(cat)/K(M) is very similar for Glu74Lys and wild-type RNase Sa, suggesting that this is not due to a change in the pK values of the groups involved in catalysis. Compared to wild-type RNase Sa, the stabilities of Gln38Ala and Glu74Lys are increased, the stabilities of Glu41Lys, Glu54Gln, and Arg65Ala are decreased and the stability of His85Gln is unchanged. Thus, the active site residues in the ribonuclease Sa make different contributions to the stability.     

Role of two active site Glu residues in the molecular action of botulinum neurotoxin endopeptidase

Botulinum neurotoxin type A (BoNT/A) light chain (LC) is a zinc endopeptidase that causes neuroparalysis by blocking neurotransmitter release at the neuromuscular junctions. The X-ray crystal structure of the toxin reveals that His223 and His227 of the Zn(2+) binding motif HEXXH directly coordinate the active site zinc. Two Glu residues (Glu224 and Glu262) are also part of the active site, with Glu224 coordinating the zinc via a water molecule whereas Glu262 coordinates the zinc directly as the fourth ligand. In the past we have investigated the topographical role of Glu224 by replacing it with Asp thus reducing the side chain length by 1.4 A that reduced the endopeptidase activity dramatically [L. Li, T. Binz, H. Niemann, and B.R. Singh, Probing the role of glutamate residue in the zinc-binding motif of type A botulinum neurotoxin light chain, Biochemistry 39 (2000) 2399-2405]. In this study we have moved the Glu 224 laterally by a residue (HXEXH) to assess its positional influence on the endopeptidase activity, which was completely lost. The functional implication of Glu262 was investigated by replacing this residue with aspartate and glutamine using site-directed mutagenesis. Substitution of Glu262 with Asp resulted in a 3-fold decrease in catalytic efficiency. This mutation did not induce any significant structural alterations in the active site and did not interfere with substrate binding. Substitution of Glu262 with Gln however, dramatically impaired the enzymatic activity and this is accompanied by global alterations in the active site conformation in terms of topography of aromatic amino acid residues, zinc binding, and substrate binding, resulting from the weakened interaction between the active site zinc and Gln. These results suggest a pivotal role of the negatively charged carboxyl group of Glu262 which may play a critical role in enhancing the stability of the active site with strong interaction with zinc. The zinc may thus play structural role in addition to its catalytic role.     

Role of Asp187 and Gln190 in the Na+/proline symporter (PutP) of Escherichia coli

Asp187 and Gln190 were predicted as conserved and closely located at the Na(+) binding site in a topology and homology model structure of Na(+)/proline symporter (PutP) of Escherichia coli. The replacement of Asp187 with Ala or Leu did not affect proline transport activity; whereas, change to Gln abolished the active transport. The binding affinity for Na(+) or proline of these mutants was similar to that of wild-type (WT) PutP. This result indicates Asp187 to be responsible for active transport of proline without affecting the binding. Replacement of Gln190 with Ala, Asn, Asp, Leu and Glu had no effect on transport or binding, suggesting that it may not have a role in the transport. However, in the negative D187Q mutant, a second mutation, of Gln190 to Glu or Leu, restored 46 or 7% of the transport activity of WT, respectively, while mutation to Ala, Asn or Asp had no effect. Thus, side chain at position 190 has a crucial role in suppressing the functional defect of the D187Q mutant. We conclude that Asp187 is responsible for transport activity instead of coupling-ion binding by constituting the translocation pathway of the ion and Gln190 provides a suppressing mutation site to regain PutP functional activity.