Site-specific mutagenesis of lysine-204, tyrosine-224, tyrosine-228, and histidine-307 of porcine kidney D-amino acid oxidase and the implications as to its catalytic function

In order to evaluate the possible contributions of Lys-204, Tyr-224, Tyr-228, and His-307 in porcine kidney D-amino acid oxidase [EC 1.4.3.3] (DAO) to its catalytic function, we constructed four point mutant cDNAs encoding enzymes possessing Glu-204, Phe-224, Phe-228, and Leu-307 by oligonucleotide-directed in vitro mutagenesis. The four mutant cDNAs and the wild type cDNA could be expressed in vitro with similar efficiencies and about 200 ng of each enzyme protein was produced from 5 micrograms of the respective capped RNA. The electrophoretic mobilities of the in vitro synthesized mutant enzymes on SDS-polyacrylamide gel were almost identical with that of the wild type DAO, and the molecular weight was calculated to be 38,000. The Glu-204 and Phe-224 mutant DAOs showed comparable enzyme activities to that of the wild type enzyme, and were inhibited strongly by sodium benzoate, a potent competitive inhibitor of DAO. The kinetic parameters of the two mutant DAOs were also comparable to those of the wild type DAO. On the other hand, the Phe-228 and Leu-307 mutant DAOs showed no detectable activity. The results indicate that Tyr-228 and His-307 play important roles as to the constitution of the active site or participate in the reaction directly, while Lys-204 and Tyr-224 are not essential in the enzyme reaction.     

Effect of mutations at Met-88 and Met-90 on the biotination of Lys-89 of the apo 1.3S subunit of transcarboxylase

The apo 1.3S subunit of transcarboxylase contains the sequence Ala-87-Met-88-Lys-89-Met-90, and it is Lys-89 that is biotinated. This sequence is highly conserved in all the biotin enzymes that have been sequenced (with the exception of acetyl-CoA carboxylase from chicken liver, which has Val in place of Ala). The role of Met-88 and Met-90 in specifying Lys-89 for biotination by synthetase was examined by site-directed mutagenesis. Genes of the 1.3S subunit coding for Thr-88, Leu-88, or Leu-90 were generated by oligonucleotide-directed in vitro mutagenesis and expressed in Escherichia coli. The mutated apo 1.3S subunits were isolated and the biotination by homogeneous synthetase from Propionibacterium shermanii was compared with that of the apo wild-type subunit. The Vmax for the apo mutants was the same as that for the apo wild type, but when Leu was substituted for Met-88 or Met-90, the Km for the mutant was lower than that of the wild-type or mutant Thr-88. The activity of the synthetase of E. coli was determined by an in vivo assay. During the early log phase of growth, a smaller portion of mutants Thr-88 and Leu-90 was biotinated than with the wild-type or mutant Leu-88. When the cultures progressed to stationary phase, mutants and the wild type were biotinated to the same extent. The overall results show that Met-88 and Met-90 are not required for biotination of the apo 1.3S subunit by the synthetases.     

Site-directed mutagenesis of tyrosine hydroxylase. Role of serine 40 in catalysis.

We have investigated the role of serine 40 (Ser-40) in tyrosine hydroxylase (TH) catalysis of basal and activated enzymes by protein kinase A (PKA)-mediated phosphorylation. Wild type and mutant TH were transiently and stably expressed in AtT-20 cells, and the enzymatic activities of the recombinant enzymes were analyzed. The specific enzymatic activity of transiently expressed TH mutants Ser-40-->leucine or-->tyrosine (Leu-40m or Tyr-40m) was higher than that of the wild type enzyme or of other mutants in which Ser-8, -19, and -31 were replaced by leucine. The kinetic studies carried out with the stably expressed TH show that the Km for the cofactor 6-methyltetrahydropterine is lower and the Ki for dopamine is higher when the enzymatic hydroxylation is catalyzed by the Leu-40m or Tyr-40m than by the wild type enzyme. The kinetic parameters and the pH profile of the enzymatic hydroxylation catalyzed by the Leu-40m or Tyr-40m are similar to the enzyme activated by PKA-mediated phosphorylation. We suggest that Ser-40 in TH exerts an inhibitory influence on the enzymatic activity, and its replacement with another amino acid by site-directed mutagenesis or its modification by phosphorylation leads to a change in conformation with an increased enzymatic activity. The importance of Ser-40 in the activation of TH by PKA-mediated phosphorylation was investigated by comparing the activation of the wild type enzyme with that of Leu-40m or Tyr-40m. The findings that the enzymatic activity is increased by PKA-mediated phosphorylation of the wild type enzyme, but not of the Leu-40m or Tyr-40m, demonstrate that phosphorylation at Ser-40 is essential for activation of TH by PKA. The findings that addition of ATP plus cAMP to homogenates from transfected AtT-20 cells stimulates the recombinant wild type TH activity indicate that these cells contain endogenous cAMP-dependent protein kinase.     

Effects of Amino Acid Substitutions at the Active Site in Escherichia Coli β-Galactosidase

Forty-nine amino acid substitutions were made at four positions in the Escherichia coli enzyme β-galactosidase; three of the four targeted amino acids are thought to be part of the active site. Many of the substitutions were made by converting the appropriate codon in lacZ to an amber codon, and using one of 12 suppressor strains to introduce the replacement amino acid. Glu-461 and Tyr-503 were replaced, independently, with 13 amino acids. All 26 of the strains containing mutant enzymes are Lac(-). Enzyme activity is reduced to less than 10% of wild type by substitutions at Glu-461 and to less than 1% of wild type by substitutions at Tyr-503. Many of the mutant enzymes have less than 0.1% wild-type activity. His-464 and Met-3 were replaced with 11 and 12 amino acids, respectively. Strains containing any one of these mutant proteins are Lac(+). The results support previous evidence that Glu-461 and Tyr-503 are essential for catalysis, and suggest that His-464 is not part of the active site. Site-directed mutagenesis was facilitated by construction of an f1 bacteriophage containing the complete lacZ gene on a single EcoRI fragment.     

Isolation of four novel tachykinins from frog (Rana catesbeiana) brain and intestine

In a survey for unknown bioactive peptides in frog (Rana catesbeiana) brain and intestine, we isolated four novel peptides that exhibit potent stimulant effects on smooth muscle preparation of guinea pig ileum. By microsequencing and synthesis, these peptides were identified as Lys- Pro- Ser- Pro- Asp- Arg- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin A), Tyr- Lys- Ser- Asp- Ser- Phe- Tyr- Gly- Leu- Met- NH2 (ranatachykinin B), His- Asn- Pro- Ala- Ser- Phe- Ile- Gly- Leu- Met- NH2 (ranatachykinin C) and Lys- Pro- Ans- Pro- Glu- Arg- Phe- Tyr- Ala- Pro- Met- NH2 (ranatachykinin D). Ranatachykinin (RTK) A, B and C conserve the C- terminal sequence, Phe- X- Gly- Leu- Met- NH2, which is common to known members of the tachykinin family. On the other hand, RTK-D has a striking feature in its C-terminal sequence, Phe- Tyr- Ala- Pro- Met- NH2, which has never been found in other known tachykinins, and may constitute a new subclass in the tachykinin family.     

Tyrosine residues near the FAD binding site are critical for FAD binding and for the maintenance of the stable and active conformation of rat monoamine oxidase A.

Monoamine oxidase is a flavin-containing enzyme located at the mitochondrial outer membrane that catalyzes the oxidative deamination of amines. To investigate the role of tyrosine residues near the FAD-binding site, Cys-406, of monoamine oxidase A, the tyrosine residues at posiyions 402, 407, and 410 were indurdually replaced with alanine or phenylalanine and the effects of the mutations on catalytic activity, FAD binding, and enzyme structure were examined. Half or fewer of the mutant proteins incorporated FAD. The mutation of Tyr-407 to alanine led to an almost completely loss of catalytic activity for serotonin, PEA, tyramine, and tryptamine. A substantial decrease in the catalytic activity was also observed with the enzymes mutated at Tyr-402 and Tyr-410 to alanine, although the effect of the latter mutation was much less. All these mutants were sensitive to trypsin treatment of the purified enzyme, while the wild type enzyme was resistant to treatment. On the other hand, substitution of Tyr-402 or Tyr-407 with phenylalanine had little effect on these properties. Taken together, we conclude that tyrosine residues near Cys-406 may be form a pocket to facilitates FAD incorporation, the catalytic center, and a stable conformation, probably through interactions among the aromatic rings of the tyrosine residues and FAD.     

The contribution of key hydrophobic residues in ecotin to enzyme-inhibitor complex stability

The Escherichia coli protease inhibitor ecotin is believed to be implicated in the evasion of host defenses during infection. The protein has also attracted attention as a scaffold for the design of novel, specific protease inhibitors. Ecotin interacts with its targets through two sites. Key hydrophobic residues in both sites (Leu-64, Trp-67, Tyr-69, Met-84, and Met-85) were mutated to alanine and the effects on the inhibition of trypsin, chymotrypsin, and elastase were assessed. Each of these mutant ecotin proteins tested in kinetic assays with these enzymes exerted less inhibitory potency compared to wild-type ecotin. However, these effects were relatively small and not additive.     

Replacement of putative axial ligands of heme iron in yeast cytochrome c1 by site-directed mutagenesis

The His-44 and Met-164 residues of yeast cytochrome c1 are evolutionally conserved and regarded as heme axial ligands bonding to the fifth and sixth coordination sites of the heme iron, which is directly involved in the electron transfer mechanism. Oligonucleotide-directed mutagenesis was used to generate mutant forms of cytochrome c1 of yeast having amino acid replacements of the putative axial ligands of the heme iron. When a cytochrome c1-deficiency yeast strain was transformed with a gene encoding the Phe-44, Tyr-44, Leu-164, or Lys-164 protein, none of these transformants could grow on the non-fermentable carbon source. These results suggest that the His-44 and Met-164 residues have a critical role in the function of cytochrome c1 in vivo, most probably as axial ligands of the heme iron. Further analysis revealed that the mutant yeast cells with the Phe-44, Tyr-44, or Leu-164 protein lacked the characteristic difference spectroscopic signal of cytochrome c1. However, in the Lys-164 mutant cells, partial recovery of the cytochrome c1 signal was observed. Moreover, the Lys-164 protein retained a low but significant level of succinate-cytochrome c reductase activity in vitro. The possibility that the nitrogen of Lys-164 served as the sixth heme ligand is discussed in comparison with cytochrome f of a photosynthetic electron-transfer complex, in which lysine has been proposed to be the sixth ligand.     

Structural insights into activation of phosphatidylinositol 4-kinase (Pik1) by yeast frequenin (Frq1)

Yeast frequenin (Frq1), a small N-myristoylated EF-hand protein, activates phosphatidylinositol 4-kinase Pik1. The NMR structure of Ca2+-bound Frq1 complexed to an N-terminal Pik1 fragment (residues 121-174) was determined. The Frq1 main chain is similar to that in free Frq1 and related proteins in the same branch of the calmodulin superfamily. The myristoyl group and first eight residues of Frq1 are solvent-exposed, and Ca2+ binds the second, third, and fourth EF-hands, which associate to create a groove with two pockets. The Pik1 peptide forms two helices (125-135 and 156-169) connected by a 20-residue loop. Side chains in the Pik1 N-terminal helix (Val-127, Ala-128, Val-131, Leu-132, and Leu-135) interact with solvent-exposed residues in the Frq1 C-terminal pocket (Leu-101, Trp-103, Val-125, Leu-138, Ile-152, and Leu-155); side chains in the Pik1 C-terminal helix (Ala-157, Ala-159, Leu-160, Val-161, Met-165, and Met-167) contact solvent-exposed residues in the Frq1 N-terminal pocket (Trp-30, Phe-34, Phe-48, Ile-51, Tyr-52, Phe-55, Phe-85, and Leu-89). This defined complex confirms that residues in Pik1 pinpointed as necessary for Frq1 binding by site-directed mutagenesis are indeed sufficient for binding. Removal of the Pik1 N-terminal region (residues 8-760) from its catalytic domain (residues 792-1066) abolishes lipid kinase activity, inconsistent with Frq1 binding simply relieving an autoinhibitory constraint. Deletion of the lipid kinase unique motif (residues 35-110) also eliminates Pik1 activity. In the complex, binding of Ca2+-bound Frq1 forces the Pik1 chain into a U-turn. Frq1 may activate Pik1 by facilitating membrane targeting via the exposed N-myristoyl group and by imposing a structural transition that promotes association of the lipid kinase unique motif with the kinase domain.     

Site-directed mutagenesis of human aldolase isozymes: the role of Cys-72 and Cys-338 residues of aldolase A and of the carboxy-terminal Tyr residues of aldolases A and B

In order to elucidate the role of particular amino acid residues in the catalytic activity and conformational stability of human aldolases A and B [EC 4.1.2.13], the cDNAs encoding these isoenzyme were modified using oligonucleotide-directed, site-specific mutagenesis. The Cys-72 and/or Cys-338 of aldolase A were replaced by Ala and the COOH-terminal Tyr of aldolases A and B was replaced by Ser. The three mutant aldolases A thus prepared, A-C72A, A-C338A, and A-C72,338A, were indistinguishable from the wild-type enzyme with respect to general catalytic properties, while the replacement of Tyr-363 by Ser in aldolase A (A-Y363S) resulted in decreases of the Vmax of the fructose-1, 6-bisphosphate (FDP) cleavage reaction, activity ratio of FDP/fructose-1-phosphate (F1P), and the Km values for FDP and F1P. The wild-type and all the mutant aldolase A proteins exhibited similar thermal stabilities. In contrast, the mutant aldolase A proteins were more stable than the wild-type enzyme against tryptic and alpha-chymotryptic digestions. Based upon these results it is concluded that the strictly conserved Tyr-363 of human aldolase A is required for the catalytic function with FDP as the substrate, while neither Cys-72 nor Cys-338 directly takes part in the catalytic function although the two Cys residues may be involved in maintaining the correct spatial conformation of aldolase A. Replacement of Tyr-363 by Ser in human aldolase B lowered the Km value for FDP appreciably and also diminished the stability against elevated temperatures and tryptic digestion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural and functional effects of mutations altering the subunit interface of mitochondrial malate dehydrogenase

Among highly conserved residues in eucaryotic mitochondrial malate dehydrogenases are those with roles in maintaining the interactions between identical monomeric subunits that form the dimeric enzymes. The contributions of two of these residues, Asp-43 and His-46, to structural stability and catalytic function were investigated by construction of mutant enzymes containing Asn-43 and Leu-46 substitutions using in vitro mutagenesis of the Saccharomyces cerevisiae gene (MDH1) encoding mitochondrial malate dehydrogenase. The mutant enzymes were expressed in and purified from a yeast strain containing a disruption of the chromosomal MDH1 locus. The enzyme containing the H46L substitution, as compared to the wild type enzyme, exhibits a dramatic shift in the pH profile for catalysis toward an optimum at low pH values. This shift corresponds with an increased stability of the dimeric form of the mutant enzyme, suggesting that His-46 may be the residue responsible for the previously described pH-dependent dissociation of mitochondrial malate dehydrogenase. The D43N substitution results in a mutant enzyme that is essentially inactive in in vitro assays and that tends to aggregate at pH 7.5, the optimal pH for catalysis for the dimeric wild type enzyme.     

Structure-based design of beta 1,4-galactosyltransferase I (beta 4Gal-T1) with equally efficient N-acetylgalactosaminyltransferase activity: point mutation broadens beta 4Gal-T1 donor specificity

beta1,4-Galactosyltransferase I (Gal-T1) normally transfers Gal from UDP-Gal to GlcNAc in the presence of Mn(2+) ion. In the presence of alpha-lactalbumin (LA), the Gal acceptor specificity is altered from GlcNAc to Glc. Gal-T1 also transfers GalNAc from UDP-GalNAc to GlcNAc, but with only approximately 0.1% of Gal-T activity. To understand this low GalNAc-transferase activity, we have carried out the crystal structure analysis of the Gal-T1.LA complex with UDP-GalNAc at 2.1-A resolution. The crystal structure reveals that the UDP-GalNAc binding to Gal-T1 is similar to the binding of UDP-Gal to Gal-T1, except for an additional hydrogen bond formed between the N-acetyl group of GalNAc moiety with the Tyr-289 side chain hydroxyl group. Elimination of this additional hydrogen bond by mutating Tyr-289 residue to Leu, Ile, or Asn enhances the GalNAc-transferase activity. Although all three mutants exhibit enhanced GalNAc-transferase activity, the mutant Y289L exhibits GalNAc-transferase activity that is nearly 100% of its Gal-T activity, even while completely retaining its Gal-T activity. The steady state kinetic analyses on the Leu-289 mutant indicate that the K(m) for GlcNAc has increased compared to the wild type. On the other hand, the catalytic constant (k(cat)) in the Gal-T reaction is comparable with the wild type, whereas it is 3-5-fold higher in the GalNAc-T reaction. Interestingly, in the presence of LA, these mutants also transfer GalNAc to Glc instead of to GlcNAc. The present study demonstrates that, in the Gal-T family, the Tyr-289/Phe-289 residue largely determines the sugar donor specificity.     

Lipase from Pseudomonas stutzeri: Purification,homology modelling and rational explanation of the substrate binding mode

After purification from the crude commercial preparation, the 3D structure of the synthetically valuable lipase from Pseudomonas stutzeri (LipC) is described through homology modelling, leading to a rational explanation of its catalytic behaviour. This elucidates that the enzyme has an active site defined by residues Ser-109, His-277 and Asp-255, and an oxyanion hole formed by peptidic NH groups from Met-43 and His-110. Interestingly, the active site is covered by two lids, one of them (Lid1, residues 145–181) being larger than the other (Lid2, residues 233–253). The opening and closing of these lids have been simulated by molecular modelling assuming both water and pure THF as solvents. Accordingly, THF clearly helps the exposure of the catalytic serine to the reaction medium which explains its excellent reported performance in this organic solvent. On the other hand, the stereospecificity of this enzyme is explained considering a small hydrophobic cavity formed by Gly-45, Phe-46, Tyr-54, Trp-55, Leu-278, Val-281 and Phe-284; particularly, Tyr-54 plays an important role in substrate recognition. In fact, in benzoin acylation, this residue forces the benzoyl group of the substrate to go into that cavity via H bonding with the carbonyl O atom of benzoin, thereby explaining the observed S-preference in benzoin acylation, which apparently contradicts the canonical Kazlauskas’ rule. For other alcohols non possessing the α-hydroxycarbonyl core, Tyr-54 is allowing the entrance into the above-mentioned hydrophobic cavity only to those substrates with no steric hindrance in the vicinity of the hydroxymethane moiety.     

Amino acid replacements in yeast iso-1-cytochrome c. Comparison with the phylogenetic series and the tertiary structure of related cytochromes c

The structural and folding requirements of eukaryotic cytochromes c have been investigated by determining the appropriate DNA sequences of a collection of 46 independent cyc 1 missense mutations obtained in the yeast Saccharomyces cerevisiae and by deducing the corresponding amino acid replacements that abolish function of iso-1-cytochrome c. A total of 33 different replacements at 19 amino acid positions were uncovered in this and previous studies. Because all of these nonfunctional iso-1-cytochromes c are produced at far below the normal level and because a representative number are labile in vitro, most of the replacements appear to be affecting stability of the protein or heme attachment. By considering the tertiary structure of related cytochromes c, the loss of function of most of the mutant iso-1-cytochromes c could be attributed to either replacements of critical residues that directly interact with the heme group or to replacements that disrupt the proper folding of the protein. The replacements of residues interacting with the heme group include those required for covalent attachment (Cys-19 and Cys-22), ligand formation (His-23 and Met-85), and formation of the immediate heme environment (Leu-37, Tyr-53, Trp-64, and Leu-73). Proper folding of the protein is prevented by replacements of glycine residues at sites that cannot accommodate side chains (Gly-11 and Gly-34); by replacements of residues with proline, which limit the torsion angle (Leu-14 and His-38); and by replacements apparently unable to direct the local folding of the backbone into the proper conformation (Pro-35, Tyr-72, Asn-75, Pro-76, Lys-84, Leu-99, and Leu-103). Even though most of the missense mutations occurred at sites corresponding to evolutionarily invariant or conserved residues, a consideration of the replacements in functional revertants indicates that the requirement for residues evolutionarily preserved is less stringent than commonly assumed.     

Site-directed mutagenesis of the T4 endonuclease V gene: mutations which enhance enzyme specific activity at low salt concentrations

Previous structure/function analyses of the DNA repair enzyme, T4 endonuclease V, have suggested that the extreme carboxyl portion of the enzyme is associated with pyrimidine dimer-specific binding (Recinos and Lloyd, and Stump and Lloyd, Biochemistry 27:1832-1838 and 1839-1843, 1988, respectively). Within the final 11 amino acids there are 5 aromatic, 2 basic, and no acidic residues and it has been proposed that these residues stack with and electrostatically interact with the kinked DNA at the site of a pyrimidine dimer. The role of the tyrosine residue at position 129 has been investigated by oligonucleotide site-directed mutagenesis in which the codon for Tyr-129 has been altered to reflect conservative changes of Trp and Phe and more dramatic changes of Ser, a stop codon, deletion of the codon or introduction of a frameshift. Both changes to the aromatic amino acids resulted in proteins which accumulated well in E. coli and not only significantly enhanced the UV survival of repair-deficient cells but also complemented a defective denV gene within UV-irradiated T4 phage. Partially purified preparations of the Tyr-129----Trp and Tyr-129----Phe mutants were assayed for their ability to processively incise UV-irradiated plasmid DNA (a nicking reaction carried out at low 25 mM salt concentrations). The mutant enzymes Tyr-129----Phe and Tyr-129----Trp displayed a 1000% and 500% enhanced specific nicking activity, respectively. These reactions were also shown to be completely processive. Assays performed at higher (100 mM) salt concentrations reduced the specific activities of the mutant enzymes approximately to that of wild type for the Tyr-129----Phe mutant and to 20% that of wild type for the Tyr-129----Trp mutant.     

Crystal structure of the Y52F/Y73F double mutant of phospholipase A2: increased hydrophobic interactions of the phenyl groups compensate for the disrupted hydrogen bonds of the tyrosines.

The enzyme phospholipase A2 (PLA2) catalyzes the hydrolysis of the sn-2 ester bond of membrane phospholipids. The highly conserved Tyr residues 52 and 73 in the enzyme form hydrogen bonds to the carboxylate group of the catalytic Asp-99. These hydrogen bonds were initially regarded as essential for the interfacial recognition and the stability of the overall catalytic network. The elimination of the hydrogen bonds involving the phenolic hydroxyl groups of the Tyr-52 and -73 by changing them to Phe lowered the stability but did not significantly affect the catalytic activity of the enzyme. The X-ray crystal structure of the double mutant Y52F/Y73F has been determined at 1.93 A resolution to study the effect of the mutation on the structure. The crystals are trigonal, space group P3(1)21, with cell parameters a = b = 46.3 A and c = 102.95 A. Intensity data were collected on a Siemens area detector, 8,024 reflections were unique with an R(sym) of 4.5% out of a total of 27,203. The structure was refined using all the unique reflections by XPLOR to a final R-factor of 18.6% for 955 protein atoms, 91 water molecules, and 1 calcium ion. The root mean square deviation for the alpha-carbon atoms between the double mutant and wild type was 0.56 A. The crystal structure revealed that four hydrogen bonds were lost in the catalytic network; three involving the tyrosines and one involving Pro-68. However, the hydrogen bonds of the catalytic triad, His-48, Asp-99, and the catalytic water, are retained. There is no additional solvent molecule at the active site to replace the missing hydroxyl groups; instead, the replacement of the phenolic OH groups by H atoms draws the Phe residues closer to the neighboring residues compared to wild type; Phe-52 moves toward His-48 and Asp-99 of the catalytic diad, and Phe-73 moves toward Met-8, both by about 0.5 A. The closing of the voids left by the OH groups increases the hydrophobic interactions compensating for the lost hydrogen bonds. The conservation of the triad hydrogen bonds and the stabilization of the active site by the increased hydrophobic interactions could explain why the double mutant has activity similar to wild type. The results indicate that the aspartyl carboxylate group of the catalytic triad can function alone without additional support from the hydrogen bonds of the two Tyr residues.     

Molecular insights into DNA polymerase deterrents for ribonucleotide insertion

DNA polymerases can misinsert ribonucleotides that lead to genomic instability. DNA polymerase β discourages ribonucleotide insertion with the backbone carbonyl of Tyr-271; alanine substitution of Tyr-271, but not Phe-272, resulted in a >10-fold loss in discrimination. The Y271A mutant also inserted ribonucleotides more efficiently than wild type on a variety of ribonucleoside (rNMP)-containing DNA substrates. Substituting Mn²⁺ for Mg²⁺ decreased sugar discrimination for both wild-type and mutant enzymes primarily by increasing the affinity for rCTP. This facilitated crystallization of ternary substrate complexes of both the wild-type and Y271A mutant enzymes. Crystallographic structures of Y271A- and wild type-substrate complexes indicated that rCTP is well accommodated in the active site but that O2′ of rCTP and the carbonyl oxygen of Tyr-271 or Ala-271 are unusually close (∼2.5 and 2.6 Å, respectively). Structure-based modeling indicates that the local energetic cost of positioning these closely spaced oxygens is ∼2.2 kcal/mol for the wild-type enzyme. Because the side chain of Tyr-271 also hydrogen bonds with the primer terminus, loss of this interaction affects its catalytic positioning. Our results support a model where DNA polymerase β utilizes two strategies, steric and geometric, with a single protein residue to deter ribonucleotide insertion.     

F0F1-ATPase gamma subunit mutations perturb the coupling between catalysis and transport.

We introduced mutations to test the function of the conserved amino-terminal region of the gamma subunit from the Escherichia coli ATP synthase (F0F1-ATPase). Plasmid-borne mutant genes were expressed in an uncG strain which is deficient for the gamma subunit (gamma Gln-14-->end). Most of the changes, which were between gamma Ile-19 and gamma Lys-33, gamma Asp-83 and gamma Cys-87, or at gamma Asp-165, had little effect on growth by oxidative phosphorylation, membrane ATPase activity, or H+ pumping. Notable exceptions were gamma Met-23-->Arg or Lys mutations. Strains carrying these mutations grew only very slowly by oxidative phosphorylation. Membranes prepared from the strains had substantial levels of ATPase activity, 100% compared with wild type for gamma Arg-23 and 65% for gamma Lys-23, but formed only 32 and 17%, respectively, of the electrochemical gradient of protons. In contrast, other mutant enzymes with similar ATPase activities (including gamma Met-23-->Asp or Glu) formed H+ gradients like the wild type. Membranes from the gamma Arg-23 and gamma Lys-23 mutants were not passively leaky to protons and had functional F0 sectors. These results suggested that substitution by positively charged side chains at position 23 perturbed the energy coupling. The catalytic sites of the mutant enzymes were still regulated by the electrochemical H+ gradient but were inefficiently coupled to H+ translocation in both ATP-dependent H+ pumping and delta mu H+ driven ATP synthesis.     

Catalytic activity of the D38A mutant of 3-oxo-Delta 5-steroid isomerase: recruitment of aspartate-99 as the base

3-oxo-Delta(5)-steroid isomerase (KSI) from Comamonas (Pseudomonas) testosteroni catalyzes the isomerization of beta,gamma-unsaturated 3-oxosteroids to their conjugated isomers through an intermediate dienolate. Residue Asp-38 (pK(a) 4.57) acts as a base to abstract a proton from C-4 of the substrate to form an intermediate dienolate, which is then reprotonated on C-6. Both Tyr-14 (pK(a) 11.6) and Asp-99 (pK(a) >/= 9.5) function as hydrogen-bond donors to O-3 of the steroid, helping to stabilize the transition states. Mutation of the active-site base Asp-38 to the weakly basic Asn (D38N) has previously been shown to result in a >10(8)-fold decrease of catalytic activity. In this work, we describe the preparation and kinetic analysis of the Ala-38 (D38A) mutant. Unexpectedly, D38A has a catalytic turnover number (k(cat)) that is ca. 10(6)-fold greater than the value for D38N and only about 140-fold less than that for wild type. Kinetic studies as a function of pH show that D38A-catalyzed isomerization involves two groups, with pK(a) values of 4.2 and 10.4, respectively, in the free enzyme, which are assigned to Asp-99 and either Tyr-14 or Tyr-55. A mechanism for D38A is proposed in which Asp-99 is recruited as the catalytic base, with stabilization of the intermediate dienolate ion and the flanking transition states provided by hydrogen bonding from both Tyr-14 and Tyr-55. This mechanism is supported by the lack of detectable activity of the D38A/D99N, D38A/Y14F, and D38A/Y55F double mutants.     

A beta-tubulin leucine cluster involved in microtubule assembly and paclitaxel resistance.

Analysis of beta-tubulin alleles from nine paclitaxel-resistant Chinese hamster ovary cell lines revealed an unexpected cluster of mutations affecting Leu-215, Leu-217, and Leu-228. Six of the mutant alleles encode a His, Arg, or Phe substitution at Leu-215; another mutant allele has an Arg substitution at Leu-217; and the final two mutant alleles have substitutions of His or Phe at Leu-228. Using plasmids that allow tetracycline regulated expression, the L215H, L217R, and L228F mutations were introduced into a hemagglutinin antigen-tagged beta-tubulin cDNA and transfected into wild-type Chinese hamster ovary cells. In all three cases, low to moderate expression of the transfected mutant gene conferred paclitaxel resistance. Higher levels of expression caused disruption of microtubule assembly, cell cycle arrest at mitosis, and failure to proliferate. Consistent with reduced microtubule stability, cells expressing mutant hemagglutinin beta-tubulin had fewer acetylated microtubules than nonexpressing cells in the same population. These data, together with previous studies showing that the paclitaxel-resistant mutant cell lines have less stable microtubules, indicate that the leucine cluster represents an important structural motif for microtubule assembly.