Catalytic mechanism of S-adenosylhomocysteine hydrolase. Site-directed mutagenesis of Asp-130, Lys-185, Asp-189, and Asn-190

S-Adenosylhomocysteine hydrolase (AdoHcyase) catalyzes the hydrolysis of S-adenosylhomocysteine to form adenosine and homocysteine. On the bases of crystal structures of the wild type enzyme and the D244E mutated enzyme complexed with 3'-keto-adenosine (D244E.Ado*), we have identified the important amino acid residues, Asp-130, Lys-185, Asp-189, and Asn-190, for the catalytic reaction and have proposed a catalytic mechanism (Komoto, J., Huang, Y., Gomi, T., Ogawa, H., Takata, Y., Fujioka, M., and Takusagawa, F. (2000) J. Biol. Chem. 275, 32147-32156). To confirm the proposed catalytic mechanism, we have made the D130N, K185N, D189N, and N190S mutated enzymes and measured the catalytic activities. The catalytic rates (k(cat)) of D130N, K185N, D189N, and N190S mutated enzymes are reduced to 0.7%, 0.5%, 0.1%, and 0.5%, respectively, in comparison with the wild type enzyme, indicating that Asp-130, Lys-185, Asp-189, and Asn-190 are involved in the catalytic reaction. K(m) values of the mutated enzymes are increased significantly, except for the N190S mutation, suggesting that Asp-130, Lys-185, and Asp-189 participate in the substrate binding. To interpret the kinetic data, the oxidation states of the bound NAD molecules of the wild type and mutated enzymes were measured during the catalytic reaction by monitoring the absorbance at 340 nm. The crystal structures of the WT and D244E.Ado*, containing four subunits in the crystallographic asymmetric unit, were re-refined to have the same subunit structures. A detailed catalytic mechanism of AdoHcyase has been revealed based on the oxidation states of the bound NAD and the re-refined crystal structures of WT and D244E.Ado*. Lys-185 and Asp-130 abstract hydrogen atoms from 3'-OH and 4'-CH, respectively. Asp-189 removes a proton from Lys-185 and produces the neutral N zeta (-NH(2)), and Asn-190 facilitates formation of the neutral Lys-185. His-54 and His-300 hold and polarize a water molecule, which nucleophilically attacks the C5'- of 3'-keto-4',5'-dehydroadenosine to produce 3'-keto-Ado.     

Role of alpha-Asp181, beta-Asp192, and gamma-Asp190 in the distinctive subunits of human NAD-specific isocitrate dehydrogenase

Human NAD-dependent isocitrate dehydrogenase (IDH) is allosterically activated by ADP by lowering the Km for isocitrate. The enzyme has three subunit types with distinguishable sequences present in the approximate ratio 2alpha:1beta:1gamma and, per tetramer, binds 2 mol of each ligand. To evaluate whether the subunits also have distinct functions, we replaced equivalent aspartates, one subunit at a time, by asparagines; each expressed, purified enzyme was composed of one mutant and two wild-type subunits. The aspartates were chosen because beta-Asp192 and gamma-Asp190 had previously been affinity labeled by a reactive ADP analogue and alpha-Asp181 is equivalent based on sequence alignments. The alpha-D181N IDH mutant exhibits a 2000-fold decrease in Vmax, with increases of 15-fold in the Kms for Mn(II) and NAD and a much smaller change in the Km for isocitrate. In contrast, the Vmax values of the beta-D192N and gamma-D190N IDHs are only reduced 4-5-fold as compared to wild-type enzyme. The Km for NAD of the beta-D192N enzyme is 9 times that of the normal enzyme with little or no effect on the affinity for Mn(II) or isocitrate, while the Kms for coenzyme and for Mn(II) of the gamma-D190N enzyme are 19 and 72 times, respectively, that of the normal enzyme with a much smaller effect on the Km for isocitrate. Finally, all three mutant enzymes fail to respond to ADP by lowering the Km for isocitrate, although they do bind ADP. Thus, these aspartates are close to but not in the ADP site and are required for communication between the ADP and isocitrate sites. These results demonstrate that alpha-Asp181 is the only one of these aspartates essential for catalysis. Beta-Asp192 is a determinant of the enzyme's affinity for NAD, as is gamma-Asp190, while gamma-Asp190 also influences the enzyme's affinity for metal ion. We conclude that the NAD and ADP sites are shared between alpha- and beta- and alpha- and gamma-subunits, and the Mn(II) site is shared between alpha- and gamma-subunits, while the alpha-subunit is essential for catalysis. Although alpha-Asp181, beta-Asp192, and gamma-Asp190 may have derived from a common progenitor, these aspartates of the three subunits have evolved distinct functions.     

Conserved residues in the putative catalytic triad of human bile acid Coenzyme A:amino acid N-acyltransferase

Human bile acid-CoA:amino acid N-acyltransferase (hBAT), an enzyme catalyzing the conjugation of bile acids with the amino acids glycine or taurine has significant sequence homology with dienelactone hydrolases and other alpha/beta hydrolases. These enzymes have a conserved catalytic triad that maps onto the mammalian BATs at residues Cys-235, Asp-328, and His-362 of the human sequence, albeit that the hydrolases contain a serine instead of a cysteine. In the present study, the function of the putative catalytic triad of hBAT was examined by chemical modification with the cysteine alkylating reagent N-ethylmaleimide (NEM) and by site-directed mutagenesis of the triad residues followed by enzymology studies of mutant and wild-type hBATs. Treatment with NEM caused inactivation of wild-type hBAT. However, preincubation of wild-type hBAT with the substrate cholyl-CoA before NEM treatment prevented loss of N-acyltransferase activity. Substitution of His-362 or Asp-328 with alanine results in inactivation of hBAT. Although substitution of Cys-235 with serine generated an hBAT mutant with lower N-acyltransferase activity, it substantially increased the bile acid-CoA thioesterase activity compared with wild type. In summary, data from this study support the existence of an essential catalytic triad within hBAT consisting of Cys-235, His-362, and Asp-328 with Cys-235 serving as the probable nucleophile and thus the site of covalent attachment of the bile acid molecule.     

Identification of essential amino acid residues for catalytic activity and thermostability of novel chitosanase by site-directed mutagenesis

The functional importance of a conserved region in a novel chitosanase from Bacillus sp. CK4 was investigated. Each of the three carboxylic amino acid residues (Glu-50, Glu-62, and Asp-66) was changed to Asp and Gln or Asn and Glu by site-directed mutagenesis, respectively. The Asp-66-->Asn and Asp-66-->Glu mutation remarkably decreased kinetic parameters such as Vmax and kcat to approximately 1/1,000 those of the wild-type enzyme, indicating that the Asp-66 residue was essential for catalysis. The thermostable chitosanase contains three Cys residues at positions 49, 72, and 211. The Cys-49-->Ser/Tyr and Cys-72-->Ser/Tyr mutant enzymes were as stable to thermal inactivation and denaturating agents as the wild-type enzyme. However, the half-life of the Cys-211-->Ser/Tyr mutant enzyme was less than 10 min at 80 degrees C, while that of the wild-type enzyme was about 90 min. Moreover, the residual activity of Cys-211-->Ser/Tyr enzyme was substantially decreased by 8 M urea; and it lost all catalytic activity in 40% ethanol. These results show that the substitution of Cys with any amino acid residues at position 211 seems to affect the conformational stability of the chitosanase.     

Y265H mutator mutant of DNA polymerase beta. Proper teometric alignment is critical for fidelity

DNA polymerases have the unique ability to select a specific deoxynucleoside triphosphate from a pool of similarly structured substrates. One of these enzymes, DNA polymerase beta, offers a simple system to relate polymerase structure to the fidelity of DNA synthesis. In this study, a mutator DNA polymerase beta, Y265H, was identified using an in vivo genetic screen. Purified Y265H produced errors at a 40-fold higher frequency than the wild-type protein in a forward mutation assay. At 37 degrees C, transient kinetic analysis demonstrated that the alteration caused a 111-fold decrease in the maximum rate of polymerization and a 117-fold loss in fidelity for G misincorporation opposite template A. Our data suggest that the maximum rate of polymerization was reduced, because Y265H was dramatically impaired in its ability to perform nucleotidyl transfer in the presence of the correct nucleotide substrate. In contrast, at 20 degrees C, the mutant protein had a fidelity similar to wild-type enzyme. Both proteins at 20 degrees C demonstrate a rapid change in protein conformation, followed by a slow chemical step. These data suggest that proper geometric alignment of template, 3'-OH of the primer, magnesium ions, dNTP substrates, and the active site residues of DNA polymerase beta are important factors in polymerase fidelity and provide the first evidence that Tyr-265 is important for this alignment to occur properly in DNA polymerase beta.     

Structural and functional integrity of specificity and catalytic sites of trypsin

The aspartic acid residue at the bottom of the substrate-binding pocket of trypsin was replaced by glutamic acid through site-directed mutagenesis. The wild-type (Asp-189) and mutant (Glu-189) trypsinogens were expressed in E. coli, purified to homogeneity, activated by enterokinase, and tested on a series of fluorogenic tetrapeptide substrates. The substrates were of the general formula succinyl-Ala-Ala-Pro-X-AMC, where AMC is 7-amino-4-methylcoumarin and X is Lys, Arg, or Orn (ornithine). As compared to Asp-189 trypsin, the activity of Glu-189 trypsin on lysyl and arginyl substrates decreased by 3-4 orders of magnitude while its Km values did not significantly change. Lengthening the side-chain of Asp-189 by one methylene group could not be compensated for by shortening the side-chain of the substrate, since Glu-189 trypsin had no measurable activity on the ornithyl substrate. The replacement of Asp-189 with glutamic acid at the base of the substrate-binding pocket of trypsin appears to distort the structure of the critical transition-state complex. This could happen by disrupting interactions normally associated with Asp-189, and by altering the relative position of the scissile peptide bond in the active site of the enzyme.     

Identification of the catalytic residues of bifunctional glycogen debranching enzyme

Eukaryotic glycogen debranching enzyme (GDE) possesses two different catalytic activities (oligo-1,4-->1,4-glucantransferase/amylo-1,6-glucosidase) on a single polypeptide chain. To elucidate the structure-function relationship of GDE, the catalytic residues of yeast GDE were determined by site-directed mutagenesis. Asp-535, Glu-564, and Asp-670 on the N-terminal half and Asp-1086 and Asp-1147 on the C-terminal half were chosen by the multiple sequence alignment or the comparison of hydrophobic cluster architectures among related enzymes. The five mutant enzymes, D535N, E564Q, D670N, D1086N, and D1147N were constructed. The mutant enzymes showed the same purification profiles as that of wild-type enzyme on beta-CD-Sepharose-6B affinity chromatography. All the mutant enzymes possessed either transferase activity or glucosidase activity. Three mutants, D535N, E564Q, and D670N, lost transferase activity but retained glucosidase activity. In contrast, D1086N and D1147N lost glucosidase activity but retained transferase activity. Furthermore, the kinetic parameters of each mutant enzyme exhibiting either the glucosidase activity or transferase activity did not vary markedly from the activities exhibited by the wild-type enzyme. These results strongly indicate that the two activities of GDE, transferase and glucosidase, are independent and located at different sites on the polypeptide chain.     

Intermediate trapping on a mutant retaining alpha-galactosyltransferase identifies an unexpected aspartate residue

Lipopolysaccharyl-alpha-1,4-galactosyltransferase C (LgtC), a glycosyltransferase family 8 alpha-1,4-galactosyltransferase from Neisseria meningitidis, catalyzes the transfer of galactose from UDP galactose to terminal lactose-containing acceptor sugars with net retention of anomeric configuration. To investigate the potential role of discrete nucleophilic catalysis suggested by the double displacement mechanism generally proposed for retaining glycosyltransferases, the side chain amide of Gln-189, which is suitably positioned to act as the catalytic nucleophile of LgtC, was substituted with the more nucleophilic carboxylate-containing side chain of glutamate in the hope of accumulating a glycosyl-enzyme intermediate. The resulting mutant was subjected to kinetic, mass spectrometric, and x-ray crystallographic analysis. Although the K(m) for UDP-galactose is not significantly altered, the k(cat) was reduced to 3% that of the wild type enzyme. Electrospray mass spectrometric analysis revealed that a steady state population of the Q189E variant contains a covalently bound galactosyl moiety. Liquid chromatographic/mass spectrometric analysis of fragmented proteolytic digests identified the site of labeling not as Glu-189 but, surprisingly, as the sequentially adjacent Asp-190. However, the side chain carboxylate of Asp-190 is located 8.9 A away from the donor substrate in the available crystal structure. Kinetic analysis of a D190N mutant at this position revealed a k(cat) value 3000-fold lower than that of the wild type enzyme. A 2.6-A crystal structure of the Q189E mutant with bound uridine 5'-diphospho-2-deoxy-2-fluoro-alpha-d-galactopyranose revealed no significant perturbation of the mode of donor sugar binding nor of active site configuration. This is the first trapping of an intermediate in the active site of a retaining glycosyltransferase and, although not conclusive, implicates Asp-190 as an alternative candidate catalytic nucleophile, thereby rekindling a longstanding mechanistic debate.     

The I260Q variant of DNA polymerase beta extends mispaired primer termini due to its increased affinity for deoxynucleotide triphosphate substrates

DNA polymerase beta plays a key role in base excision repair. We have previously shown that the hydrophobic hinge region of polymerase beta, which is distant from its active site, plays a critical role in the fidelity of DNA synthesis by this enzyme. The I260Q hinge variant of polymerase beta misincorporates nucleotides with a significantly higher catalytic efficiency than the wild-type enzyme. In the study described here, we show that I260Q extends mispaired primer termini. The kinetic basis for extension of mispairs is defective discrimination by I260Q at the level of ground-state binding of the dNTP substrate. Our results suggest that the hydrophobic hinge region influences the geometry of the dNTP binding pocket exclusively. Because the DNA forms part of the binding pocket, our data are also consistent with the interpretation that the mispaired primer terminus affects the geometry of the dNTP binding pocket such that the I260Q variant has a higher affinity for the incoming dNTP than wild-type polymerase beta.     

The active site of the Escherichia coli MutY DNA adenine glycosylase.

Escherichia coli MutY is an adenine DNA glycosylase active on DNA substrates containing A/G, A/C, or A/8-oxoG mismatches. Although MutY can form a covalent intermediate with its DNA substrates, its possession of 3' apurinic lyase activity is controversial. To study the reaction mechanism of MutY, the conserved Asp-138 was mutated to Asn and the reactivity of this mutant MutY protein determined. The glycosylase activity was completely abolished in the D138N MutY mutant. The D138N mutant and wild-type MutY protein also possessed different DNA binding activities with various mismatches. Several lysine residues were identified in the proximity of the active site by analyzing the imino-covalent MutY-DNA intermediate. Mutation of Lys-157 and Lys-158 both individually and combined, had no effect on MutY activities but the K142A mutant protein was unable to form Schiff base intermediates with DNA substrates. However, the MutY K142A mutant could still bind DNA substrates and had adenine glycosylase activity. Surprisingly, the K142A mutant MutY, but not the wild-type enzyme, could promote a beta/delta-elimination on apurinic DNA. Our results suggest that Asp-138 acts as a general base to deprotonate either the epsilon-amine group of Lys-142 or to activate a water molecule and the resulting apurinic DNA then reacts with Lys-142 to form the Schiff base intermediate with DNA. With the K142A mutant, Asp-138 activates a water molecule to attack the C1' of the adenosine; the resulting apurinic DNA is cleaved through beta/delta-elimination without Schiff base formation.     

Minor groove interactions at the DNA polymerase beta active site modulate single-base deletion error rates

The structures of open and closed conformations of DNA polymerase beta (pol beta) suggests that the rate of single-nucleotide deletions during synthesis may be modulated by interactions in the DNA minor groove that align the templating base with the incoming dNTP. To test this hypothesis, we measured the single-base deletion error rates of wild-type pol beta and lysine and alanine mutants of Arg(283), whose side chain interacts with the minor groove edge of the templating nucleotide at the active site. The error rates of both mutant enzymes are increased >100-fold relative to wild-type pol beta. Template engineering experiments performed to distinguish among three possible models for deletion formation suggest that most deletions in repetitive sequences by pol beta initiate by strand slippage. However, pol beta also generates deletions by a different mechanism that is strongly enhanced by the substitutions at Arg(283). Analysis of error specificity suggests that this mechanism involves nucleotide misinsertion followed by primer relocation, creating a misaligned intermediate. The structure of pol beta bound to non-gapped DNA also indicates that the templating nucleotide and its downstream neighbor are out of register in the open conformation and this could facilitate misalignment (dNTP or primer terminus) with the next template base.     

Phage phi29 terminal protein residues Asn80 and Tyr82 are recognition elements of the replication origins.

Initiation of phage phi29 DNA replication starts with the recognition of the origin of replication, located at both ends of the linear DNA, by a heterodimer formed by the phi29 terminal protein (TP) and the phi29 DNA polymerase. The parental TP, covalently linked to the DNA ends, is one of the main components of the replication origin. Here we provide evidence that recognition of the origin is mediated through interactions between the TP of the TP/DNA polymerase heterodimer, called primer TP, and the parental TP. Based on amino acid sequence comparisons, various phi29 TP mutants were generated at conserved amino acid residues from positions 61 to 87. In vitro phi29 DNA amplification analysis revealed that residues Asn80 and Tyr82 are essential for functional interaction between primer and parental TP required for recognition of the origin of replication. Although these mutant TPs can form functional heterodimers with phi29 DNA polymerase that are able to recognize the origin of replication, these heterodimers are not able to recognize an origin containing a mutant TP.     

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.     

A mutation in human topoisomerase II alpha whose expression is lethal in DNA repair-deficient yeast cells

Type II DNA topoisomerases are ATP-dependent enzymes that catalyze alterations in DNA topology. These enzymes are important targets of a variety of anti-bacterial and anti-cancer agents. We identified a mutation in human topoisomerase II alpha, changing aspartic acid 48 to asparagine, that has the unique property of failing to transform yeast cells deficient in recombinational repair. In repair-proficient yeast strains, the Asp-48 --> Asn mutant can be expressed and complements a temperature-sensitive top2 mutation. Purified Asp-48 --> Asn Top2alpha has relaxation and decatenation activity similar to the wild type enzyme, but the purified protein exhibits several biochemical alterations compared with the wild type enzyme. The mutant enzyme binds both covalently closed and linear DNA with greater avidity than the wild type enzyme. hTop2alpha(Asp-48 --> Asn) also exhibited elevated levels of drug-independent cleavage compared with the wild type enzyme. The enzyme did not show altered sensitivity to bisdioxopiperazines nor did it form stable closed clamps in the absence of ATP, although the enzyme did form elevated levels of closed clamps in the presence of a non-hydrolyzable ATP analog compared with the wild type enzyme. We suggest that the lethality exhibited by the mutant is likely because of its enhanced drug-independent cleavage, and we propose that alterations in the ATP binding domain of the enzyme are capable of altering the interactions of the enzyme with DNA. This mutant enzyme also serves as a new model for understanding the action of drugs targeting topoisomerase II.     

The E249K mutator mutant of DNA polymerase beta extends mispaired termini

The DNA polymerase beta mutant enzyme, which is altered from glutamic acid to lysine at position 249, exhibits a mutator phenotype in primer extension assays and in the herpes simplex virus-thymidine kinase (HSV-tk) forward mutation assay. The basis for this loss of accuracy was investigated by measurement of misincorporation fidelity in single turnover conditions. For the four misincorporation reactions investigated, the fidelity of the E249K mutant was not significantly different from wild type, implying that the mutator phenotype was not caused by a general inability to distinguish between correct and incorrect bases during the incorporation reaction. However, the discrimination between correct and incorrect substrates by the E249K enzyme occurred less during the conformational change and chemical steps and more during the initial binding step, compared with pol beta wild type. This implies that the E249K mutation alters the kinetic mechanism of nucleotide discrimination without reducing misincorporation fidelity. In a missing base primer extension assay, we observed that the mutant enzyme produced mispairs and extended them. This indicates that the altered fidelity of E249K could be due to loss of discrimination against mispaired primer termini. This was supported by the finding that the E249K enzyme extended a G:A mispair 8-fold more efficiently than wild type and a C:T mispair 4-fold more efficiently. These results demonstrate that an enhanced ability to extend mispairs can produce a mutator phenotype and that the Glu-249 side chain of DNA polymerase beta is critical for mispair extension fidelity.     

Unique requirements for template primers of DNA polymerase beta from rat ascites hepatoma AH130 cells.

The optimal condition for the rat DNA polymerase beta activity with (rA)n . (dT)12-18 as a template-primer was determined. The activity was remarkably affected by the concentration of the primer, (dT)12-18' and the mixing ratio of (dT)12-18 to (rA)n. DNA polymerase beta requires higher primer concentration (Km = 11.1 microM with respect to 3'-OH of the primer) than DNA polymerase gamma (Km = 0.04 microM) or oncornaviral DNA polymerase (Km = 0.08 microM) and the enzyme represented the maximum activity in the base ratio of 2:1 with (dT)12-18 and (rA)n suggesting the difference in reaction mechanisms of these enzymes. Under the optimized conditions, the specific activity of the near homogeneous preparation of DNA polymerase beta was 1,000,000 units per mg protein.     

Identification of the enzymatic active site of tobacco caffeoyl-coenzyme A O-methyltransferase by site-directed mutagenesis.

Animal catechol O-methyltransferases and plant caffeoyl-coenzyme A O-methyltransferases share about 20% sequence identity and display common structural features. The crystallographic structure of rat liver catechol O-methyltransferase was used as a template to construct a homology model for tobacco caffeoyl-coenzyme A O-methyltransferase. Integrating substrate specificity data, the three-dimensional model identified several amino acid residues putatively involved in substrate binding. These residues were mutated by a polymerase chain reaction method and wild-type and mutant enzymes were each expressed in Escherichia coli and purified. Substitution of Arg-220 with Thr resulted in the total loss of enzyme activity, thus indicating that Arg-220 is involved in the electrostatic interaction with the coenzyme A moiety of the substrate. Changes of Asp-58 to Ala and Gln-61 to Ser were shown to increase K(m) values for caffeoyl coenzyme A and to decrease catalytic activity. Deletions of two amino acid sequences specific for plant enzymes abolished activity. The secondary structures of the mutants, as measured by circular dichroism, were essentially unperturbed as compared with the wild type. Similar changes in circular dichroism spectra were observed after addition of caffeoyl coenzyme A to the wild-type enzyme and the substitution mutants but not in the case of deletion mutants, thus revealing the importance of these sequences in substrate-enzyme interactions.