Effects of single mutations on the stability of horseradish peroxidase to hydrogen peroxide

Horseradish peroxidase (HRP) is a commonly used enzyme in many biotechnological fields. Improvement of HRP stability would further increase its potential application range. In the present study, 13 single- and three double-mutants of solvent exposed, proximal lysine and glutamic acid residues were analysed for enhanced H(2)O(2) stability. Additionally, five single- and one pentuple-consensus mutants were investigated. Most mutants displayed little or no alteration in H(2)O(2) stability; however, three (K232N, K241F and T110V) exhibited significantly increased H(2)O(2) tolerances of 25- (T110V), 18- (K232N), and 12-fold (K241F). This improved stability may be due to an altered enzyme-H(2)O(2) catalysis pathway or to removal of potentially oxidisable residues.     

Mutation of two intramembrane polar residues conserved within the hyaluronan synthase family alters hyaluronan product size

We identified two conserved polar amino acids within different membrane domains (MD) of Streptococcus equisimilis hyaluronan synthase (seHAS), Lys48 in MD2 and Glu327 in MD4. In eukaryotic HASs, the position of the Glu is very similar and the Lys is replaced by a conserved polar Gln. To assess whether Lys48 and Glu327 interact or influence seHAS activity, we investigated the effects of changing Lys48 to Arg or Glu and Glu327 to Lys, Asp, or Gln. Mutants, including a double switch variant with Lys48 and Glu327 exchanged, were expressed and assayed in Escherichia coli membranes. SeHASE327Q and seHASE327K were expressed at low levels, whereas seHASE327D and the Lys48 mutants were expressed well. The specific enzyme activities (relative to wild type) were 17 and 7% for the K48R and K48E mutants and 26 and 38% for the E327Q and E327D mutants, respectively. In contrast, seHAS(E327K) showed only 0.16% of wild-type activity but was rescued over 46-fold by changing Lys48 to Glu. Expression of the seHASE327K,K48E protein was also rescued to near wild-type levels. Based on size exclusion chromatography coupled to multiangle laser light scattering analysis, all the variants synthesized hyaluronan (HA) of smaller weight-average molar mass than wild-type enzyme (3.6 MDa); the smallest HA (approximately 0.6 MDa) was made by seHASE327K,K48E and seHASK48E. The results indicate that Glu327 within MD4 is a critical residue for the stability of seHAS, that it may interact with Lys48 within MD2, and that these residues are involved in the ability of HAS to synthesize very large HA.     

Luminol activity of horseradish peroxidase mutants mimicking a proposed binding site for luminol in Arthromyces ramosus peroxidase.

To enhance the oxidation activity for luminol in horseradish peroxidase (HRP), we have prepared three HRP mutants by mimicking a possible binding site for luminol in Arthromyces ramosus peroxidase (ARP) which shows 500-fold higher oxidation activity for luminol than native HRP. Spectroscopic studies by (1)H NMR revealed that the chemical shifts of 7-propionate and 8-methyl protons of the heme in cyanide-ligated ARP were deviated upon addition of luminol (4 mM), suggesting that the charged residues, Lys49 and Glu190, which are located near the 7-propionate and 8-methyl groups of the heme, are involved in the specific binding to luminol. The positively charged Lys and negatively charged Glu were introduced into the corresponding positions of Ser35 (S35K) and Gln176 (Q176E) in HRP, respectively, to build the putative binding site for luminol. A double mutant, S35K/Q176E, in which both Ser35 and Gln176 were replaced, was also prepared. Addition of luminol to the HRP mutants induced more pronounced effects on the resonances from the heme substituents and heme environmental residues in the (1)H NMR spectra than that to the wild-type enzyme, indicating that the mutations in this study induced interactions with luminol in the vicinity of the heme. The catalytic efficiencies (V(max)/K(m)) for luminol oxidation of the S35K and S35K/Q176E mutants were 1.5- and 2-fold improved, whereas that of the Q176E mutant was slightly depressed. The increase in luminol activity of the S35K and S35K/Q176E mutants was rather small but significant, suggesting that the electrostatic interactions between the positive charge of Lys35 and the negative charge of luminol can contribute to the effective binding for the luminol oxidation. On the other hand, the negatively charged residue would not be so crucial for the luminol oxidation. The absence of drastic improvement in the luminol activity suggests that introduction of the charged residues into the heme vicinity is not enough to enhance the oxidation activity for luminol as observed for ARP.     

Analysis of the catalytic mechanism of pyruvate dehydrogenase kinase

It has been proposed that "Glu238" within the N-box of pyruvate dehydrogenase kinase (PDK) is a base catalyst. The pH dependence of k(cat) of Arabidopsis thaliana PDK indicates that ionizable groups with pK values of 6.2 and 8.4 are necessary for catalysis, and the temperature dependence of these values suggests that the acidic pK is due to a carboxyl- or imidazole-group. The E238 and K241 mutants had elevated K(m,ATP) values. The acidic pK value of the E238A mutant was shifted to 5.5. The H233A, L234H, and L234A mutants had the same pK values as wild-type AtPDK, contrary to the previous proposal of a "Glu-polarizing" His. Instead, we suggest that the conserved Glu, Lys, and Asn residues of the N-box contribute to coordinating Mg2+ in a position critical for formation of the PDK-MgATP-substrate ternary complex.     

Location of crosslinks in chemically stabilized horseradish peroxidase: implications for design of crosslinks.

The bifunctional compound, ethylene-glycol bis(N-hydroxysuccinimidylsuccinate) (EGNHS), stabilizes horseradish peroxidase C (HRP) by reaction with the enzyme's lysine residues. In this study we compare native and modified HRP by proteolytic fragmentation, peptide sequencing, and mass spectroscopy, and identify the sites of modification. Most significantly, EGNHS is shown to form a crosslink between Lys232 and Lys241 of HRP and modifies Lys174 without formation of a crosslink. These findings are in agreement with the lysine side-chain reactivities predicted from the surface accessibility of the amino groups, and the maximal span of 16 A of the EGNHS crosslinker.     

Structural stabilization and functional improvement of horseradish peroxidase upon modification of accessible lysines: experiments and simulation

Horseradish peroxidase (HRP) is an important heme enzyme with enormous medical diagnostic, biosensing, and biotechnological applications. Thus, any improvement in the applicability and stability of the enzyme is potentially interesting. We previously reported that covalent attachment of an electron relay (anthraquinone 2-carboxylic acid) to the surface-exposed Lys residues successfully improves electron transfer properties of HRP. Here we investigated structural and functional consequences of this modification, which alters three accessible charged lysines (Lys-174, Lys-232, and Lys-241) to the hydrophobic anthraquinolysine residues. Thermal denaturation and thermoinactivation studies demonstrated that this kind of modification enhances the conformational and operational stability of HRP. The melting temperature increased 3 degrees C and the catalytic efficiency enhanced by 80%. Fluorescence and circular dichroism investigations suggest that the modified HRP benefits from enhanced aromatic packing and more buried hydrophobic patches as compared to the native one. Molecular dynamics simulations showed that modification improves the accessibility of His-42 and the heme prosthetic group to the peroxide and aromatic substrates, respectively. Additionally, the hydrophobic patch, which functions as a binding site or trap for reducing aromatic substrates, is more extended in the modified enzyme. In summary, this modification produces a new derivative of HRP with enhanced electron transfer properties, catalytic efficiency, and stability for biotechnological applications.     

How Modification of Accessible Lysines to Phenylalanine Modulates the Structural and Functional Properties of Horseradish Peroxidase: A Simulation Study

Horseradish Peroxidase (HRP) is one of the most studied peroxidases and a great number of chemical modifications and genetic manipulations have been carried out on its surface accessible residues to improve its stability and catalytic efficiency necessary for biotechnological applications. Most of the stabilized derivatives of HRP reported to date have involved chemical or genetic modifications of three surface-exposed lysines (K174, K232 and K241). In this computational study, we altered these lysines to phenylalanine residues to model those chemical modifications or genetic manipulations in which these positively charged lysines are converted to aromatic hydrophobic residues. Simulation results implied that upon these substitutions, the protein structure becomes less flexible. Stability gains are likely to be achieved due to the increased number of stable hydrogen bonds, improved heme-protein interactions and more integrated proximal Ca²⁺ binding pocket. We also found a new persistent hydrogen bond between the protein moiety (F174) and the heme prosthetic group as well as two stitching hydrogen bonds between the connecting loops GH and F′F″ in mutated HRP. However, detailed analysis of functionally related structural properties and dynamical features suggests reduced reactivity of the enzyme toward its substrates. Molecular dynamics simulations showed that substitutions narrow the bottle neck entry of peroxide substrate access channel and reduce the surface accessibility of the distal histidine (H42) and heme prosthetic group to the peroxide and aromatic substrates, respectively. Results also demonstrated that the area and volume of the aromatic-substrate binding pocket are significantly decreased upon modifications. Moreover, the hydrophobic patch functioning as a binding site or trap for reducing aromatic substrates is shrunk in mutated enzyme. Together, the results of this simulation study could provide possible structural clues to explain those experimental observations in which the protein stability achieved concurrent with a decrease in enzyme activity, upon manipulation of charge/hydrophobicity balance at the protein surface.     

Species-specific inhibition of inosine 5'-monophosphate dehydrogenase by mycophenolic acid

IMPDH catalyzes the oxidation of IMP to XMP with the concomitant reduction of NAD(+) to NADH. This reaction is the rate-limiting step in de novo guanine nucleotide biosynthesis. Mycophenolic acid (MPA) is a potent inhibitor of mammalian IMPDHs but a poor inhibitor of microbial IMPDHs. MPA inhibits IMPDH by binding in the nicotinamide half of the dinucleotide site and trapping the covalent intermediate E-XMP. The MPA binding site of resistant IMPDH from the parasite Tritrichomonas foetuscontains two residues that differ from human IMPDH. Lys310 and Glu431 of T. foetus IMPDH are replaced by Arg and Gln, respectively, in the human type 2 enzyme. We characterized three mutants of T. foetusIMPDH: Lys310Arg, Glu431Gln, and Lys310Arg/Glu431Gln in order to determine if these substitutions account for the species selectivity of MPA. The mutation of Lys310Arg causes a 10-fold decrease in the K(i) for MPA inhibition and a 8-13-fold increase in the K(m) values for IMP and NAD(+). The mutation of Glu431Gln causes a 6-fold decrease in the K(i) for MPA. The double mutant displays a 20-fold increase in sensitivity to MPA. Pre-steady-state kinetics were performed to obtain rates of hydride transfer, NADH release, and hydrolysis of E-XMP for the mutant IMPDHs. The Lys310Arg mutation results in a 3-fold increase in the accumulation level of E-XMP, while the Glu431Gln mutation has only a minimal effect on the kinetic mechanism. These experiments show that 20 of the 450-fold difference in sensitivity between the T. foetus and human IMPDHs derive from the residues in the MPA binding site. Of this, 3-fold can be attributed to a change in kinetic mechanism. In addition, we measured MPA binding to enzyme adducts with 6-Cl-IMP and EICARMP. Neither of these adducts proved to be a good model for E-XMP.     

The region from phenylalanine-17 to phenylalanine-28 of a yeast mitochondrial ATPase inhibitor is essential for its ATPase inhibitory activity.

Mitochondrial ATP synthase (F(1)F(o)-ATPase) is regulated by an intrinsic ATPase inhibitor protein. In the present study, we investigated the structure-function relationship of the yeast ATPase inhibitor by amino acid replacement. A total of 22 mutants were isolated and characterized. Five mutants (F17S, R20G, R22G, E25A, and F28S) were entirely inactive, indicating that the residues, Phe17, Arg20, Arg22, Glu25, and Phe28, are essential for the ATPase inhibitory activity of the protein. The activity of 7 mutants (A23G, R30G, R32G, Q36G, L37G, L40S, and L44G) decreased, indicating that the residues, Ala23, Arg30, Arg32, Gln36, Leu37, Leu40, and Leu44, are also involved in the activity. Three mutants, V29G, K34Q, and K41Q, retained normal activity at pH 6.5, but were less active at pH 7.2, indicating that the residues, Val29, Lys34, and Lys41, are required for the protein's action at higher pH. The effects of 6 mutants (D26A, E35V, H39N, H39R, K46Q, and K49Q) were slight or undetectable, and the residues Asp26, Glu35, His39, Lys46, and Lys49 thus appear to be dispensable. The mutant E21A retained normal ATPase inhibitory activity but lacked pH-sensitivity. Competition experiments suggested that the 5 inactivated mutants (F17S, R20G, R22G, E25A, and F28S) could still bind to the inhibitory site on F(1)F(o)-ATPase. These results show that the region from the position 17 to 28 of the yeast inhibitor is the most important for its activity and is required for the inhibition of F(1), rather than binding to the enzyme.     

Conformational rearrangement of beta-lactoglobulin upon interaction with an anionic membrane

The recent availability of the SHV-1 beta-lactamase crystal structure provides a framework for the understanding of the functional role of amino acid residues in this enzyme. To that end, we have constructed by site-directed mutagenesis 18 variants of the SHV beta-lactamase: an extended spectrum group: Gly238Ser, Gly238Ser-Glu240Lys, Asp104Lys-Gly238Ser, Asp104Lys-Thr235Ser-Gly238Ser, Asp179Asn, Arg164His, and Arg164Ser; an inhibitor resistant group: Arg244Ser, Met69Ile, Met69Leu, and Ser130Gly; mutants that are synergistic with those that confer resistance to oxyimino-cephalosporins: Asp104Glu, Asp104Lys, Glu240Lys, and Glu240Gln; and structurally conserved mutants: Thr235Ser, Thr235Ala and Glu166Ala. Among the extended spectrum group the combination of high-level ampicillin and cephalosporin resistance was demonstrated in the Escherichia coli DH10B strains possessing the Gly238Ser mutation: Gly238Ser, Gly238Ser-Glu240Lys, Asp104Lys-Gly238Ser, and Asp104Lys-Thr235Ser-Gly238Ser. Of the inhibitor resistant group, the Ser130Gly mutant was the most resistant to ampicillin/clavulanate. Using a polyclonal anti-SHV antibody, we assayed steady state protein expression levels of the SHV beta-lactamase variants. Mutants with the Gly238Ser substitution were among the most highly expressed. The Gly238Ser substitution resulted in an improved relative k(cat)/K(m) value for cephaloridine and oxyimino-cephalosporins compared to SHV-1 and Met69Ile. In our comparative survey, the Gly238Ser and extended spectrum beta-lactamase variants containing this substitution exhibited the greatest substrate versatility against penicillins and cephalosporins and greatest protein expression. This defines a unique role of Gly238Ser in broad-spectrum beta-lactam resistance in this family of class A beta-lactamases.     

Identification of active site residues in E. coli ketopantoate reductase by mutagenesis and chemical rescue

Ketopantoate reductase (EC 1.1.1.169) catalyzes the NADPH-dependent reduction of alpha-ketopantoate to D-(-)-pantoate in the biosynthesis of pantothenate. The pH dependence of V and V/K for the E. coli enzyme suggests the involvement of a general acid/base in the catalytic mechanism. To identify residues involved in catalysis and substrate binding, we mutated the following six strictly conserved residues to Ala: Lys72, Lys176, Glu210, Glu240, Asp248, and Glu256. Of these, the K176A and E256A mutant enzymes showed 233- and 42-fold decreases in V(max), and 336- and 63-fold increases in the K(m) value of ketopantoate, respectively, while the other mutants exhibited WT kinetic properties. The V(max) for the K176A and E256A mutant enzymes was markedly increased, up to 25% and 75% of the wild-type level, by exogenously added primary amines and formate, respectively. The rescue efficiencies for the K176A and E256A mutant enzymes were dependent on the molecular volume of rescue agents, as anticipated for a finite active site volume. The protonated form of the amine is responsible for recovery of activity, suggesting that Lys176 functions as a general acid in catalysis of ketopantoate reduction. The rescue efficiencies for the K176A mutant by primary amines were independent of the pK(a) value of the rescue agents (Bronsted coefficient, alpha = -0.004 +/-0.008). Insensitivity to acid strength suggests that the chemical reaction is not rate-limiting, consistent with (a) the catalytic efficiency of the wild-type enzyme (k(cat)/K(m) = 2x10(6) M(-1) s(-1) and (b) the small primary deuterium kinetic isotope effects, (D)V = 1.3 and (D)V/K = 1.5, observed for the wild-type enzyme. Larger primary deuterium isotope effects on V and V/K were observed for the K176A mutant ((D)V = 3.0, (D)V/K = 3.7) but decreased nearly to WT values as the concentration of ethylamine was increased. The nearly WT activity of the E256A mutant in the presence of formate argues for an important role for this residue in substrate binding. The double mutant (K176A/E256A) has no detectable ketopantoate reductase activity. These results indicate that Lys176 and Glu256 of the E. coli ketopantoate reductase are active site residues, and we propose specific roles for each in binding ketopantoate and catalysis.     

Identification by mutational analysis of amino acid residues essential in the chaperone function of calreticulin

Calreticulin is a Ca2+ -binding chaperone that resides in the lumen of the endoplasmic reticulum and is involved in the regulation of intracellular Ca2+ homeostasis and in the folding of newly synthesized glycoproteins. In this study, we have used site-specific mutagenesis to map amino acid residues that are critical in calreticulin function. We have focused on two cysteine residues (Cys(88) and Cys(120)), which form a disulfide bridge in the N-terminal domain of calreticulin, on a tryptophan residue located in the carbohydrate binding site (Trp(302)), and on certain residues located at the tip of the "hairpin-like" P-domain of the protein (Glu(238), Glu(239), Asp(241), Glu(243), and Trp(244)). Calreticulin mutants were expressed in crt(-/-) fibroblasts, and bradykinin-dependent Ca2+ release was measured as a marker of calreticulin function. Bradykinin-dependent Ca2+ release from the endoplasmic reticulum was rescued by wild-type calreticulin and by the Glu(238), Glu(239), Asp(241), and Glu(243) mutants. The Cys(88) and Cys(120) mutants rescued the calreticulin-deficient phenotype only partially ( approximately 40%), and the Trp(244) and Trp(302) mutants did not rescue it at all. We identified four amino acid residues (Glu(239), Asp(241), Glu(243), and Trp(244)) at the hairpin tip of the P-domain that are critical in the formation of a complex between ERp57 and calreticulin. Although the Glu(239), Asp(241), and Glu(243) mutants did not bind ERp57 efficiently, they fully restored bradykinin-dependent Ca2+ release in crt(-/-) cells. This indicates that binding of ERp57 to calreticulin may not be critical for the chaperone function of calreticulin with respect to the bradykinin receptor.     

Critical role of Lys212 and Tyr140 in porcine NADP-dependent isocitrate dehydrogenase

Lys212 and Tyr140 are close to the enzyme-bound isocitrate in the recently determined crystal structure of porcine NADP-specific isocitrate dehydrogenase (Ceccarelli, C., Grodsky, N. B., Ariyaratne, N., Colman, R. F., and Bahnson, B. J. (2002) J. Biol. Chem. 277, 43454-43462). We have constructed mutant enzymes in which Lys212 is replaced by Gln, Tyr, and Arg, and Tyr140 is replaced by Phe, Thr, Glu, and Lys. Wild type and mutant enzymes were each expressed in Escherichia coli and purified to homogeneity. At pH 7.4, the specific activity is decreased in K212Q, K212Y, and K212R, respectively, to 0.01-9% of wild type. The most striking change is in the pH-V(max) curves. Wild type depends on the deprotonated form of a group of pKaes 5.7, whereas this pKaes is increased to 7.4 in neutral K212Q and to 8.3 in K212Y. In contrast, the positive K212R has a pKaes of 5.9. These results indicate that (by electrostatic repulsion) a positively charged residue at position 212 lowers the pK of the nearby ionizable group in the enzyme-substrate complex. Lys212 may also stabilize the carbanion formed initially on substrate decarboxylation. The Tyr140 mutants have specific activities at pH 7.4 that are reduced to 0.2-0.5% of those of wild type, whereas their Km values for isocitrate and NADP are not increased. Most notable are the altered pH-V(max) profiles. V(max) is constant from pH 5.3 to 8 for Y140F and Y140T and increases as pH is decreased for Y140E and Y140K. These results suggest that in wild type enzyme, Tyr140 is the general acid that protonates the substrate after decarboxylation and that the carboxyl and ammonium forms of Y140E and Y140K provide partial substitutes. Relative to wild type, the Y140T enzyme is specifically activated 106-fold by exogenous addition of acetic acid and 88-fold by added phenol; and the K212Q enzyme is activated 4-fold by added ethylamine. These chemical rescue experiments support the conclusion that Tyr140 and Lys212 are required for the catalytic activity of porcine NADP-dependent isocitrate dehydrogenase.     

Role of the streptokinase alpha-domain in the interactions of streptokinase with plasminogen and plasmin

The role of the streptokinase (SK) alpha-domain in plasminogen (Pg) and plasmin (Pm) interactions was investigated in quantitative binding studies employing active site fluorescein-labeled [Glu]Pg, [Lys]Pg, and [Lys]Pm, and the SK truncation mutants, SK-(55-414), SK-(70-414), and SK-(152-414). Lysine binding site (LBS)-dependent and -independent binding were resolved from the effects of the lysine analog, 6-aminohexanoic acid. The mutants bound indistinguishably, consistent with unfolding of the alpha-domain on deletion of SK-(1-54). The affinity of SK for [Glu]Pg was LBS-independent, and although [Lys]Pg affinity was enhanced 13-fold by LBS interactions, the LBS-independent free energy contributions were indistinguishable. alpha-Domain truncation reduced the affinity of SK for [Glu]Pg 2-7-fold and [Lys]Pg 相似文献   

Identification of the catalytic residues involved in the carboxyl transfer of pyruvate carboxylase

To clarify the mechanism of carboxyl transfer from carboxylbiotin to pyruvate, the following conserved amino acid residues present in the carboxyl transferase domain of Bacillus thermodenitrificans pyruvate carboxylase were converted to homologous amino acids: Asp543, Glu576, Glu592, Asp649, Lys712, Asp713, and Asp762. The carboxylase activity of the resulting mutants, D543E, E576D, E576Q, E592Q, D649N, K712R, K712Q, D713E, D713N, D762E, and D762N, was generally less than that of the wild type from mutation, but it decreased the most to 5% or even less than that of the wild type with D543E, D576Q, D649N, K712R, and K712Q. The decrease in activity observed for Asp543, Asp649, and Lys712 mutants was not for structural reasons because their structures seemed to remain intact as assessed by gel filtration and circular dichroism. On the basis of these data, a mechanism is proposed where Lys712 and Asp543 serve as the key acid and base catalyst, respectively.     

Different sensitivities of mutants and chimeric forms of human muscle and liver fructose-1,6-bisphosphatases towards AMP

AMP is an allosteric inhibitor of human muscle and liver fructose-1,6-bisphosphatase (FBPase). Despite strong similarity of the nucleotide binding domains, the muscle enzyme is inhibited by AMP approximately 35 times stronger than liver FBPase: I0.5 for muscle and for liver FBPase are 0.14 microM and 4.8 microM, respectively. Chimeric human muscle (L50M288) and chimeric human liver enzymes (M50L288), in which the N-terminal residues (1-50) were derived from the human liver and human muscle FBPases, respectively, were inhibited by AMP 2-3 times stronger than the wild-type liver enzyme. An amino acid exchange within the N-terminal region of the muscle enzyme towards liver FBPase (Lys20-->Glu) resulted in 13-fold increased I0.5 values compared to the wild-type muscle enzyme. However, the opposite exchanges in the liver enzyme (Glu20-->Lys and double mutation Glu19-->Asp/Glu20-->Lys) did not change the sensitivity for AMP inhibition of the liver mutant (I0.5 value of 4.9 microM). The decrease of sensitivity for AMP of the muscle mutant Lys20-->Glu, as well as the lack of changes in the inhibition by AMP of liver mutants Glu20-->Lys and Glu19-->Asp/Glu20-->Lys, suggest a different mechanism of AMP binding to the muscle and liver enzyme.     

Stability-increasing mutants of glucose dehydrogenase from Bacillus megaterium IWG3

A glucose dehydrogenase gene was isolated from Bacillus megaterium IWG3, and its nucleotide sequence was identified. The amino acid sequence of the enzyme deduced from the nucleotide sequence is very similar to the protein sequence of the enzyme from B. megaterium M1286 reported by Jany et al. (Jany, K.-D., Ulmer, W., Froschle, M., and Pfleiderer, G. (1984) FEBS Lett. 165, 6-10). The isolated gene was mutagenized with hydrazine, formic acid, or sodium nitrite, and 12 clones (H35, H39, F18, F20, F191, F192, N1, N13, N14, N28, N71, and N72) containing mutant genes for thermostable glucose dehydrogenase were obtained. The nucleotide sequences of the 12 genes show that they include 8 kinds of mutants having the following amino acid substitutions: H35 and H39, Glu-96 to Gly; F18 and F191, Glu-96 to Ala; F20, Gln-252 to Leu; F192, Gln-252 to Leu and Ala-258 to Gly; N1, Glu-96 to Lys and Val-183 to Ile; N13 and N14, Glu-96 to Lys, Val-112 to Ala, Glu-133 to Lys, and Tyr-217 to His; N28, Glu-96 to Lys, Asp-108 to Asn, Pro-194 to Gln, and Glu-210 to Lys; and N71 and N72, Tyr-253 to Cys. These mutant enzymes have higher stability at 60 degrees C than the wild-type enzyme. The results of this study indicate that the tetrameric structure of glucose dehydrogenase is stabilized by several kinds of mutation, and at least one of the following amino acid substitutions stabilizes the enzyme: Glu-96 to Gly, Glu-96 to Ala, Gln-252 to Leu, and Tyr-253 to Cys.     

Glutamic acid in the inhibitory site of mitochondrial ATPase inhibitor, IF(1), participates in pH sensing in both mammals and yeast

The mitochondrial ATPase inhibitor, IF(1), regulates the activity of F(1)F(o)-ATPase. The inhibitory activity of IF(1) is highly pH-dependent. The effective inhibition by IF(1) requires a low pH. Under basic conditions, its activity markedly declines. The importance of His49 in the pH dependence of bovine IF(1) is well-known. However, the residue is not conserved in yeast IF(1). We previously showed that Glu21 is required for the pH dependence of yeast IF(1), but the function of homologous Glu in mammalian IF(1) is not clear. In this study, we examined the requirement for Glu26 of bovine IF(1) (corresponding to Glu21 of yeast IF(1)) regarding its pH dependence by amino acid replacement. Three mutant proteins, E26A, H49K and the double mutant E26A/H49K, were overexpressed and purified. All mutants retained their inhibitory activity well at pH 8.2, although wild-type IF(1) was approximately 10-fold less active at pH 8.2 than at 6.5. A covalent cross-linking study revealed that both wild-type IF(1) and the E26A mutant formed a tetramer at pH 8.2, although H49K and E26A/H49K mutants did not. These results indicate that, in addition to His49, Glu26 participates in pH sensing in bovine IF(1), and the mechanism of pH sensing mediated by Glu26 is different from the dimer-tetramer model proposed previously.     

Lys691 and Asp714 of the Na+/K+-ATPase alpha subunit are essential for phosphorylation, dephosphorylation, and enzyme turnover

P-type ATPases such as the sodium pump appear to be members of a superfamily of hydrolases structurally typified by the L-2-haloacid dehalogenases. In the dehalogenase L-DEX-ps, Lys151 serves to stabilize the excess negative charge in the substrate/reaction intermediates and Asp180 coordinates a water molecule that is directly involved in ester intermediate hydrolysis. To investigate the importance of the corresponding Lys691 and Asp714 of the sodium pump alpha subunit, sodium pump mutants were expressed in yeast and analyzed for their properties. Lys691Ala, Lys691Asp, Asp714Ala, and Asp714Arg mutants were inactive, not only with respect to ATPase activity but also to interaction with the highly sodium pump-specific inhibitors ouabain or palytoxin (PTX). In contrast, conservative mutants Lys691Arg and Asp714Glu retained some of the partial activities of the wild-type enzyme, although they completely failed to display any ATPase activity. Yeast cells expressing Lys691Arg and Asp714Glu mutants are sensitive to the sodium pump-specific inhibitor PTX and lose intracellular K+. Their sensitivity to PTX, with EC50 values of 118 +/- 24 and 76.5 +/- 3.6 nM, respectively, was clearly reduced by almost 7- or 4-fold below that of the native sodium pump (17.8 +/- 2.7 nM). Ouabain was recognized under these conditions with low affinity by the mutants and inhibited the PTX-induced K+ efflux from the yeast cells. The EC50 for the ouabain effect was 183 +/- 20 microM for Lys691Arg and 2.3 +/- 0.08 mM for the Asp714Glu mutant. The corresponding value obtained with cells expressing the native sodium pump was 69 +/- 18 microM. In the presence of Pi and Mg2+, none of the mutant sodium pumps were able to bind ouabain. When Mg2+ was omitted, however, both Lys691Asp and Asp714Glu mutants displayed ouabain binding that was reduced by Mg2+ with an EC50 of 0.76 +/- 0.11 and 2.3 +/- 0.2 mM, respectively. In the absence of Mg2+, ouabain binding was also reduced by K+. The EC50 values were 1.33 +/- 0.23 mM for the wild-type enzyme, 0.93 +/- 0.2 mM for the Lys691Arg mutant, and 1.02 +/- 0.24 mM for the Asp714Glu enzyme. None of the neutral or nonconservative mutants displayed any ouabain-sensitive ATPase activity. Ouabain-sensitive phosphatase activity, however, was present in membranes containing either the wild-type (1105 +/- 100 micromol of p-nitrophenol phosphate hydrolyzed min(-1) mg of protein(-1)) or the Asp714Glu mutant (575 +/- 75 micromol min(-1) mg(-1)) sodium pump. Some phosphatase activity was also associated with the Lys691Arg mutant (195 +/- 63 micromol min(-1) mg(-1)). The results are consistent with Lys691 and Asp714 being essential for the phosphorylation/dephosphorylation process that allows the sodium pump to accomplish the catalytic cycle.     

DNA polymerase beta: contributions of template-positioning and dNTP triphosphate-binding residues to catalysis and fidelity

The specific catalytic roles of two groups of DNA polymerase beta active site residues identified from crystal structures were investigated: residues possibly involved in DNA template positioning (Lys280, Asn294, and Glu295) and residues possibly involved in binding the triphosphate moiety of the incoming dNTP (Arg149, Ser180, Arg183, and Ser188). Eight site-specific mutants were constructed: K280A, N294A, N294Q, E295A, R149A, S180A, R183A, and S188A. Two-dimensional NMR analysis was employed to show that the global conformation of the mutants has not been perturbed significantly. Pre-steady-state kinetic analyses with single-nucleotide gapped DNA substrates were then performed to obtain the rate of catalysis at saturating dNTP (k(pol)), the apparent dissociation constant for dNTP (K(d)), catalytic efficiency k(pol)/K(d), and fidelity. Of the three template-positioning residues, Asn294 and Glu295 (but not Lys280) contribute significantly to k(pol). Taken together with other data, the results suggest that these two residues help to stabilize the transition state during catalysis even though they interact with the DNA template backbone rather than directly with the incoming dNTP or the opposite base on the template. Furthermore, the fidelity increases by up to 19-fold for N294Q due to differential k(pol) effects between correct and incorrect nucleotides. Of the four potential triphosphate-binding residues, Ser180 and Arg183 contribute significantly to k(pol) while the effects of R149A are relatively small and are primarily on K(d), and Ser188 appears to play a minimal role in the catalysis by Pol beta. These results identify several residues important for catalysis and quantitate the contributions of each of those residues. The functional data are discussed in relation to the prediction on the basis of available crystal structures.