Interactions of the acid and base catalysts on staphylococcal nuclease as studied in a double mutant.

The mechanism of the phosphodiesterase reaction catalyzed by staphylococcal nuclease is believed to involve concerted general acid-base catalysis by Arg-87 and Glu-43. The mutual interactions of Arg-87 and Glu-43 were investigated by comparing kinetic and thermodynamic properties of the single mutant enzymes E43S (Glu-43 to Ser) and R87G (Arg-87 to Gly) with those of the double mutant, E43S + R87G, in which both the basic and acidic functions have been inactivated. Denaturation studies with guanidinium chloride, CD, and 600-MHz 1D and 2D proton NMR spectra, indicate all enzyme forms to be predominantly folded in absence of the denaturant and reveal small antagonistic effects of the E43S and R87G mutations on the stability and structure of the wild-type enzyme. The free energies of binding of the divalent cation activator Ca2+, the inhibitor Mn2+, and the substrate analogue 3',5'-pdTp show simple additive effects of the two mutations in the double mutant, indicating that Arg-87 and Glu-43 act independently to facilitate the binding of divalent cations and of 3',5'-pdTP by the wild-type enzyme. The free energies of binding of the substrate, 5'-pdTdA, both in binary E-S and in active ternary E-Ca(2+)-S complexes, show synergistic effects of the two mutations, suggesting that Arg-87 and Glu-43 interact anticooperatively in binding the substrate, possibly straining the substrate by 1.6 kcal/mol in the wild-type enzyme. The large free energy barriers to Vmax introduced by the R87G mutation (delta G1 = 6.5 kcal/mol) and by the E43S mutation (delta G2 = 5.0 kcal/mol) are partially additive in the double mutant (delta G1+2 = 8.1 kcal/mol). These partially additive effects on Vmax are most simply explained by a cooperative component to transition state binding by Arg-87 and Glu-43 of -3.4 kcal/mol. The combination of anticooperative, cooperative, and noncooperative effects of Arg-87 and Glu-43 together lower the kinetic barrier to catalysis by 8.1 kcal/mol.     

Crystal structures of native and inactivated cis-3-chloroacrylic acid dehalogenase. Structural basis for substrate specificity and inactivation by (R)-oxirane-2-carboxylate

The bacterial degradation pathways for the nematocide 1,3-dichloropropene rely on hydrolytic dehalogenation reactions catalyzed by cis- and trans-3-chloroacrylic acid dehalogenases (cis-CaaD and CaaD, respectively). X-ray crystal structures of native cis-CaaD and cis-CaaD inactivated by (R)-oxirane-2-carboxylate were elucidated. They locate four known catalytic residues (Pro-1, Arg-70, Arg-73, and Glu-114) and two previously unknown, potential catalytic residues (His-28 and Tyr-103'). The Y103F and H28A mutants of these latter two residues displayed reductions in cis-CaaD activity confirming their importance in catalysis. The structure of the inactivated enzyme shows covalent modification of the Pro-1 nitrogen atom by (R)-2-hydroxypropanoate at the C3 position. The interactions in the complex implicate Arg-70 or a water molecule bound to Arg-70 as the proton donor for the epoxide ring-opening reaction and Arg-73 and His-28 as primary binding contacts for the carboxylate group. This proposed binding mode places the (R)-enantiomer, but not the (S)-enantiomer, in position to covalently modify Pro-1. The absence of His-28 (or an equivalent) in CaaD could account for the fact that CaaD is not inactivated by either enantiomer. The cis-CaaD structures support a mechanism in which Glu-114 and Tyr-103' activate a water molecule for addition to C3 of the substrate and His-28, Arg-70, and Arg-73 interact with the C1 carboxylate group to assist in substrate binding and polarization. Pro-1 provides a proton at C2. The involvement of His-28 and Tyr-103' distinguishes the cis-CaaD mechanism from the otherwise parallel CaaD mechanism. The two mechanisms probably evolved independently as the result of an early gene duplication of a common ancestor.     

A loop involving catalytic chain residues 230-245 is essential for the stabilization of both allosteric forms of Escherichia coli aspartate transcarbamylase

The allosteric transition of Escherichia coli aspartate transcarbamylase involves significant alterations in structure at both the quaternary and tertiary levels. On the tertiary level, the 240s loop (residues 230-245 of the catalytic chain) repositions, influencing the conformation of Arg-229, a residue near the aspartate binding site. In the T state, Arg-229 is bent out of the active site and may be stabilized in this position by an interaction with Glu-272. In the R state, the conformation of Arg-229 changes, allowing it to interact with the beta-carboxylate of aspartate, and is stabilized in this position by a specific interaction with Glu-233. In order to ascertain the function of Arg-229, Glu-233, and Glu-272 in the catalytic and cooperative interactions of the enzyme, three mutant enzymes were created by site-specific mutagenesis. Arg-229 was replaced by Ala, while both Glu-233 and Glu-272 were replaced by Ser. The Arg-229----Ala and Glu-233----Ser enzymes exhibit 10,000-fold and 80-fold decreases in maximal activity, respectively, and they both exhibit a 2-fold increase in the aspartate concentration at half the maximal observed velocity, [S]0.5. The Arg-229----Ala enzyme still exhibits substantial homotropic cooperativity, but all cooperativity is lost in the Glu-233----Ser enzyme. The Glu-233----Ser enzyme also shows a 4-fold decrease in the carbamyl phosphate [S]0.5, while the Arg-229----Ala enzyme shows no change in the carbamyl phosphate [S]0.5 compared to the wild-type enzyme. The Glu-272 to Ser mutation results in a slight reduction in maximal activity, an increase in [S]0.5 for both aspartate and carbamyl phosphate, and reduced cooperativity. Analysis of the isolated catalytic subunits from these three mutant enzymes reveals that in each case the changes in the kinetic properties of the isolated catalytic subunit are similar to the changes caused by the mutation in the holoenzyme. PALA was able to activate the Glu-233----Ser enzyme, at low aspartate concentrations, even though the mutant holoenzyme did not exhibit any cooperativity, indicating that cooperative interactions still exist between the active sites in this enzyme. It is proposed that Glu-233 of the 240s loop helps create the high-activity-high-affinity R state by positioning the side chain of Arg-229 for aspartate binding while Glu-272 helps stabilize the low-activity-low-affinity T state by positioning the side chain of Arg-229 so that it cannot interact with aspartate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Human immunodeficiency virus-1 protease. 2. Use of pH rate studies and solvent kinetic isotope effects to elucidate details of chemical mechanism

The pH dependence of the peptidolytic reaction of recombinant human immunodeficiency virus type 1 protease has been examined over a pH range of 3-7 for four oligopeptide substrates and two competitive inhibitors. The pK values obtained from the pKis vs pH profiles for the unprotonated and protonated active-site aspartyl groups, Asp-25 and Asp-25', in the monoprotonated enzyme form were 3.1 and 5.2, respectively. Profiles of log V/K vs pH for all four substrates were "bell-shaped" in which the pK values for the unprotonated and protonated aspartyl residues were 3.4-3.7 and 5.5-6.5, respectively. Profiles of log V vs pH for these substrates were "wave-shaped" in which V was shifted to a constant lower value upon protonation of a residue of pK = 4.2-5.2. These results indicate that substrates bind only to a form of HIV-1 protease in which one of the two catalytic aspartyl residues is protonated. Solvent kinetic isotope effects were measured over a pH (D) range of 3-7 for two oligopeptide substrates, Ac-Arg-Ala-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2 and Ac-Ser-Gln-Asn-Tyr-Pro-Val-Val-NH2. The pH-independent value for DV/K was 1.0 for both substrates, and DV = 1.5-1.7 and 2.2-3.2 at low and high pH (D), respectively. The attentuation of both V and DV at low pH (D) is consistent with a change in rate-limiting step from a chemical one at high pH (D) to one in which a product release step or an enzyme isomerization step becomes partly rate-limiting at low pH (D). Proton inventory data is in accord with the concerted transfer of two protons in the transition state of a rate-limiting chemical step in which the enzyme-bound amide hydrate adduct collapses to form the carboxylic acid and amine products.     

Mutational,kinetic, and NMR studies of the mechanism of E. coli GDP-mannose mannosyl hydrolase,an unusual Nudix enzyme

GDP-mannose mannosyl hydrolase (GDPMH) is an unusual Nudix family member, which catalyzes the hydrolysis of GDP-alpha-D-mannose to GDP and the beta-sugar by nucleophilic substitution at carbon rather than at phosphorus (Legler, P. M., Massiah, M. A., Bessman, M. J., and Mildvan, A. S. (2000) Biochemistry 39, 8603-8608). Using the structure and mechanism of MutT, the prototypical Nudix enzyme as a guide, we detected six catalytic residues of GDPMH, three of which were unique to GDPMH, by the kinetic and structural effects of site-specific mutations. Glu-70 (corresponding to Glu-57 in MutT) provides a ligand to the essential divalent cation on the basis of the effects of the E70Q mutation which decreased kcat 10(2.2)-fold, increased the dissociation constant of Mn2+ from the ternary E-Mn2+-GDP complex 3-fold, increased the K(m)Mg2+ 20-fold, and decreased the paramagnetic effect of Mn2+ on 1/T1 of water protons, indicating a change in the coordination sphere of Mn2+. In the E70Q mutant, Gln-70 was shown to be very near the active site metal ion by large paramagnetic effects of Mn2+ on its side chain -NH2 group. With wild-type GDPMH, the effect of pH on log(kcat/K(m)GDPmann) at 37 degrees C showed an ascending limb of unit slope, followed by a plateau yielding a pK(a) of 6.4, which increased to 6.7 +/- 0.1 in the pH dependence of log(kcat). The general base catalyst was identified as a neutral His residue by the DeltaH(ionization) = 7.0 +/- 0.7 kcal/mol, by the increase in pK(a) with ionic strength, and by mutation of each of the four histidine residues of GDPMH to Gln. Only the H124Q mutant showed the loss of the ascending limb in the pH versus log(kcat) rate profile, which was replaced by a weak dependence of rate on hydroxide concentration, as well as an overall 10(3.4)-fold decrease in kcat, indicating His-124 to be the general base, unlike MutT, which uses Glu-53 in this role. The H88Q mutant showed a 10(2.3)-fold decrease in kcat, a 4.4-fold increase in K(m)GDPmann, and no change in the pH versus log(kcat) rate profile, indicating an important but unidentified role of His-88 in catalysis. One and two-dimensional NMR studies permitted the sequence specific assignments of the imidazole HdeltaC, H(epsilon)C, N(delta), and N(epsilon) resonances of the four histidines and defined their protonation states. The pK(a) of His-124 (6.94 +/- 0.04) in the presence of saturating Mg2+ was comparable to the kinetically determined pK(a) at the same temperature (6.40 +/- 0.20). The other three histidines were neutral N(epsilon)H tautomers with pK(a) values below 5.5. Arg-52 and Arg-65 were identified as catalytic residues which interact electrostatically with the GDP leaving group by mutating these residues to Gln and Lys. The R52Q mutant decreased kcat 309-fold and increased K(m)GDPmann 40.6-fold, while the R52K mutant decreased kcat by only 12-fold and increased K(m)GDPmann 81-fold. The partial rescue of kcat, but not of K(m)GDPmann in the R52K mutant, suggests that Arg-52 is a bifunctional hydrogen bond donor to the GDP leaving group in the ground state and a monofunctional hydrogen bond donor in the transition state. Opposite behavior was found with the Arg-65 mutants, suggesting this residue to be a monofunctional hydrogen bond donor to the GDP leaving group in the ground state and a bifunctional hydrogen bond donor in the transition state. From these observations, a mechanism for GDPMH is proposed involving general base catalysis and electrostatic stabilization of the leaving group.     

The catalytic mechanism of a pyrimidine dimer-specific glycosylase (pdg)/abasic lyase, Chlorella virus-pdg

The repair of UV light-induced cyclobutane pyrimidine dimers can proceed via the base excision repair pathway, in which the initial step is catalyzed by DNA glycosylase/abasic (AP) lyases. The prototypical enzyme studied for this pathway is endonuclease V from the bacteriophage T4 (T4 bacteriophage pyrimidine dimer glycosylase (T4-pdg)). The first homologue for T4-pdg has been found in a strain of Chlorella virus (strain Paramecium bursaria Chlorella virus-1), which contains a gene that predicts an amino acid sequence homology of 41% with T4-pdg. Because both the structure and critical catalytic residues are known for T4-pdg, homology modeling of the Chlorella virus pyrimidine dimer glycosylase (cv-pdg) predicted that a conserved glutamic acid residue (Glu-23) would be important for catalysis at pyrimidine dimers and abasic sites. Site-directed mutations were constructed at Glu-23 to assess the necessity of a negatively charged residue at that position (Gln-23) and the importance of the length of the negatively charged side chain (Asp-23). E23Q lost glycosylase activity completely but retained low levels of AP lyase activity. In contrast, E23D retained near wild type glycosylase and AP lyase activities on cis-syn dimers but completely lost its activity on the trans-syn II dimer, which is very efficiently cleaved by the wild type cv-pdg. As has been shown for other glyscosylases, the wild type cv-pdg catalyzes the cleavage at dimers or AP sites via formation of an imino intermediate, as evidenced by the ability of the enzyme to be covalently trapped on substrate DNA when the reactions are carried out in the presence of a strong reducing agent; in contrast, E23D was very poorly trapped on cis-syn dimers but was readily trapped on DNA containing AP sites. It is proposed that Glu-23 protonates the sugar ring, so that the imino intermediate can be formed.     

Exchange mechanisms for hydrogen bonding protons of cytidylic and guanylic acids.

The pH dependence of buffer catalysis of exchange of the C-4 amino protons of cyclic cytosine 2',3'-monophosphate (cCMP) and the N-1 proton of cyclic guanosine 2',3'-monophosphate (cGMP) conforms to an exchange mechanism, in which protonation of the nucleobases at C(N-3) AND G(N-7) establishes the important intermediates at neutral to acidic pH. Rate constants for transfer of the G(N-1) proton to H2O, OH-, phosphate, acetate, chloracetate, lactate, and cytosine (N-3) were obtained from 1H nuclear magnetic resonance line width measurements at 360 MHz and were used to estimate the pK or acidity of the exchange site in both the protonated and unprotonated nucleobase. These estimates reveal an increase in acidity of the G(N-1) site corresponding to 2 to 3 pK units as the G(N-7) site is protonated: At neutral pH the G(N-1) site of the protonated purine would be ionized (pK = 6.3). Determinations of phosphate, imidazole, and methylimidazole rate constants for transfer of the amino protons of cCMP provide a more approximate estimate of pK = 7 to 9 for the amino of the protonated pyrimidine. A comparison of the intrinsic amino acidity in the neutral and protonated cytosine is vitiated by the observation that OH- catalyzed exchange in the neutral base is not diffusion limited. This leads to the conclusion that protonation of the nucleobase effects a qualitative increase in the ability of the amino protons to form hydrogen bonds: from very poor in the neutral base to "normal" in the conjugate acid.     

Effects of mutations of the active site arginine residues in 4-oxalocrotonate tautomerase on the pKa values of active site residues and on the pH dependence of catalysis.

The unusually low pK(a) value of the general base catalyst Pro-1 (pK(a) = 6.4) in 4-oxalocrotonate tautomerase (4-OT) has been ascribed to both a low dielectric constant at the active site and the proximity of the cationic residues Arg-11 and Arg-39 [Stivers, J. T., Abeygunawardana, C., Mildvan, A. S., Hajipour, G., and Whitman, C. P. (1996) Biochemistry 35, 814-823]. In addition, the pH-rate profiles in that study showed an unidentified protonated group essential for catalysis with a pK(a) of 9.0. To address these issues, the pK(a) values of the active site Pro-1 and lower limit pK(a) values of arginine residues were determined by direct (15)N NMR pH titrations. The pK(a) values of Pro-1 and of the essential acid group were determined independently from pH-rate profiles of the kinetic parameters of 4-OT in arginine mutants of 4-OT and compared with those of wild type. The chemical shifts of all of the Arg Nepsilon resonances in wild-type 4-OT and in the R11A and R39Q mutants were found to be independent of pH over the range 4.9-9.7, indicating that no arginine is responsible for the kinetically determined pK(a) of 9.0 for an acidic group in free 4-OT. With the R11A mutant, where k(cat)/K(m) was reduced by a factor of 10(2.9), the pK(a) of Pro-1 was not significantly altered from that of the wild-type enzyme (pK(a) = 6.4 +/- 0.2) as revealed by both direct (15)N NMR titration (pK(a) = 6.3 +/- 0.1) and the pH dependence of k(cat)/K(m) (pK(a) = 6.4 +/- 0.2). The pH-rate profiles of both k(cat)/K(m) and k(cat) for the reaction of the R11A mutant with the dicarboxylate substrate, 2-hydroxymuconate, showed humps, i.e., sharply defined maxima followed by nonzero plateaus. The humps disappeared in the reaction with the monocarboxylate substrate, 2-hydroxy-2,4-pentadienoate, indicating that, unlike the wild-type enzyme which reacts only with the dianionic form of the dicarboxylic substrate, the R11A mutant reacts with both the 6-COOH and 6-COO(-) forms, with the 6-COOH form being 12-fold more active. This reversal in the preferred ionization state of the 6-carboxyl group of the substrate that occurs upon mutation of Arg-11 to Ala provides strong evidence that Arg-11 interacts with the 6-carboxylate of the substrate. In the R39Q mutant, where k(cat)/K(m) was reduced by a factor of 10(3), the kinetically determined pK(a) value for Pro-1 was 4.6 +/- 0.2, while the ionization of Pro-1 showed negative cooperativity with an apparent pK(a) of 7.1 +/- 0.1 determined by 1D (15)N NMR. From the Hill coefficient of 0.54, it can be shown that the apparent pK(a) value of 7.1 could result most simply from the averaging of two limiting pK(a) values of 4.6 and 8.2. Mutation of Arg-39, by altering the structure of the beta-hairpin which covers the active site, could result in an increase in the solvent exposure of Pro-1, raising its upper limit pK(a) value to 8.2. In the R39A mutant, the kinetically determined pK(a) of Pro-1 was also low, 5.0 +/- 0.2, indicating that in both the R39Q and R39A mutants, only the sites with low pK(a) values were kinetically operative. With the fully active R61A mutant, the kinetically determined pK(a) of Pro-1 (pK(a) = 6.5 +/- 0.2) agreed with that of wild-type 4-OT. It is concluded that the unusually low pK(a) of Pro-1 shows little contribution from electrostatic effects of the nearby cationic Arg-11, Arg-39, and Arg-61 residues but results primarily from a site of low local dielectric constant.     

Purification and characterization of 5-hydroxymethyluracil-DNA glycosylase from calf thymus. Its possible role in the maintenance of methylated cytosine residues

5-Hydroxymethyluracil (HmUra) residues formed by the oxidation of thymine are removed from DNA through the action of a DNA glycosylase activity. This activity was purified over 1870-fold from calf thymus and found to be distinct from uracil (Ura)-DNA glycosylase. The HmUra-DNA glycosylase has a molecular weight of 38,000, a pH optimum of 6.7-6.8 and an apparent Km of 0.73 +/- 0.04 microM. These values are similar to those reported for other mammalian DNA glycosylases. The enzyme removed HmUra residues from single- and double-stranded DNA with almost equal efficiency. HmUra-DNA glycosylase activity was not product inhibited by free HmUra. The DNA glycosylase activity was inhibited by Mg2+, but the purest enzyme fractions contained a Mg2+-dependent apurinic/apyrimidinic endonuclease activity. HmUra-DNA glycosylase and the recently described 5-hydroxymethylcytosine (HmCyt)-DNA glycosylase (Cannon, S. V., Cummings, A. C., and Teebor, G. W. (1988) Biochem. Biophys. Res. Commun. 151, 1173-1179) are unique among known DNA glycosylases in being present in mammalian cells and absent from bacteria. These DNA glycosylase activities were shown here to reside on different proteins. We suggest that the major function of HmUra-DNA glycosylase, together with HmCyt-DNA glycosylase, is the maintenance of methylated cytosine residues in the DNA of higher organisms.     

A low pKa cysteine at the active site of mouse methionine sulfoxide reductase A

Methionine sulfoxide reductase A is an essential enzyme in the antioxidant system which scavenges reactive oxygen species through cyclic oxidation and reduction of methionine and methionine sulfoxide. Recently it has also been shown to catalyze the reverse reaction, oxidizing methionine residues to methionine sulfoxide. A cysteine at the active site of the enzyme is essential for both reductase and oxidase activities. This cysteine has been reported to have a pK(a) of 9.5 in the absence of substrate, decreasing to 5.7 upon binding of substrate. Using three independent methods, we show that the pK(a) of the active site cysteine of mouse methionine sulfoxide reductase is 7.2 even in the absence of substrate. The primary mechanism by which the pK(a) is lowered is hydrogen bonding of the active site Cys-72 to protonated Glu-115. The low pK(a) renders the active site cysteine susceptible to oxidation to sulfenic acid by micromolar concentrations of hydrogen peroxide. This characteristic supports a role for methionine sulfoxide reductase in redox signaling.     

The pH dependent configurations of the C.A mispair in DNA.

The structure of the cytosine-adenine mispair in a 7 base pair duplex has been investigated by proton NMR spectroscopy. At low pH, the predominant structure is protonated on the A residue and assumes a wobble conformation consistent with previous findings. The C residue of the mispair is found in a C2'-C3' endo equilibrium. This is confirmed by molecular dynamics calculations which suggest that the conformation of the protonated wobble is flexible and not as rigid as a normal base pair. As the solution pH is raised, a structural transition is observed with an apparent pK of 7.54 at 23 degrees C. At higher pH the predominant structure is one in which both the C and A residues are intrahelical. Evidence is presented that this structure corresponds to a reverse wobble in which the two bases are held together by one hydrogen bond. This structure is much less stable than the protonated form and even at low temperature single strands are observed in slow exchange with the neutral duplex form.     

The ionization state and the conformation of Glu-71 in the KcsA K(+) channel.

The side chain of Glu-71 of the KcsA K(+) channel, an important residue in the vicinity of the selectivity filter, was not resolved in the crystallographic structure of Doyle et al. (Doyle, D. A., J. M. Cabral, R. A. Pfuetzner, A. Kuo, J. M. Gulbis, S. L. Cohen, B. T. Chait, and R. MacKinnon. 1998. Science. 280:69-77). Its atomic coordinates are undetermined and its ionization state is unknown. For meaningful theoretical and computational studies of the KcsA K(+) channel, it is essential to address questions about the conformation and the ionization state of this residue in detail. In previous MD simulations in which the side chain of Glu-71 is protonated and forming a strong hydrogen bond with Asp-80 it was observed that the channel did not deviate significantly from the crystallographic structure (Bernèche, S., and B. Roux. 2000. Biophys. J. 78:2900-2917). In contrast, we show here that the structure of the selectivity filter of the KcsA channel is significantly disrupted when these side chains are fully ionized on each of the four monomers. To further resolve questions about the ionization state of Glu-71 we calculated the pK(a) value of this residue using molecular dynamics free energy simulations (MD/FES) with a fully flexible system including explicit solvent and membrane and finite-difference Poisson-Boltzmann (PB) continuum electrostatics. It is found that the pK(a) of Glu-71 is shifted by approximately +10 pK(a) units. These results strongly suggest that Glu-71 is protonated under normal conditions.     

Role of glutamate-268 in the catalytic mechanism of nonphosphorylating glyceraldehyde-3-phosphate dehydrogenase from Streptococcus mutans

Nonphosphorylating nicotinamide adenine dinucleotide (phosphate)- [NAD(P)-] dependent aldehyde dehydrogenases share a number of conserved amino acid residues, several of which are directly implicated in catalysis. In the present study, the role of Glu-268 from nonphosphorylating glyceraldehyde-3-phosphate dehydrogenase (GAPN) from Streptococcus mutans was investigated. Its substitution by Ala resulted in a k(cat) decrease by 3 orders of magnitude. Pre-steady-state analysis showed that, for both the wild-type and E268A GAPNs, the rate-limiting step of the reaction is associated with deacylation. The pH dependence of the rate of acylation of wild-type GAPN is characterized by the contributions of distinct enzyme protonic species with two pK(a)s of 6.2 and 7.5. Substitution of Glu-268 by Ala resulted in a monosigmoidal pH dependence of the rate constant of acylation with a pK(a) of 6.2, which suggested the assignment of pK(a) 7.5 to Glu-268. Moreover, the E268A substitution did not significantly affect the efficiency of acylation of GAPN, showing that Glu-268 is not critically involved in the acylation, which includes Cys-302 nucleophilic activation and hydride transfer. On the contrary, the drastic decrease of the steady-state rate constant for the E268A GAPN demonstrated the essential role of Glu-268 in the deacylation. At basic pH, the solvent isotope effect of 2.3, characterized by a unique pK(a) of 7.7, and the linearity of the proton inventory showed that the rate-limiting process for deacylation is associated with the hydrolysis step and suggested that the glutamate form of Glu-268 acts as a base catalyst in this process. Surprisingly, the double-sigmoidal form of the pH-steady-state rate constant profile, characterized by pK(a) values of 6.1 and 7.4, revealed the high efficiency of the deacylation even at pH lower than 7.4. Therefore, we propose that the major role of Glu-268 is to promote deacylation through activation and orientation of the attacking water molecule, and in addition to act as a base catalyst at basic pH. From these results in relation to those recently described [Marchal, S., and Branlant, G. (1999) Biochemistry 38, 12950-12958], a scenario for the chemical catalysis of GAPN is proposed.     

A conserved seven amino acid stretch important for murine mitochondrial glycerol-3-phosphate acyltransferase activity. Significance of arginine 318 in catalysis

Glycerol-3-phosphate acyltransferase (GPAT) catalyzes the initial and committed step in glycerolipid biosynthesis. We previously cloned the cDNA sequence to murine mitochondrial GPAT (Yet, S-F., Lee, S., Hahm, Y. T., and Sul, H.S. (1993) Biochemistry 32, 9486-9491). We expressed the protein in insect cells which was targeted to mitochondria, purified, and reconstituted mitochondrial GPAT activity using phospholipids (Yet, S.-F., Moon, Y., and Sul, H. S. (1995) Biochemistry 34, 7303-7310). Deletion of the seven amino acids from mitochondrial GPAT, (312)IFLEGTR(318), which is highly conserved among acyltransferases in glycerolipid biosynthesis, drastically reduced mitochondrial GPAT activity. Treatment of mitochondrial GPAT with arginine-modifying agents, phenylglyoxal and cyclohexanedione, inactivated the enzyme. Two highly conserved arginine residues, Arg-318, in the seven amino stretch, and Arg-278, were identified. Substitution of Arg-318 with either alanine, histidine, or lysine reduced the mitochondrial GPAT activity by over 90%. On the other hand, although substitution of Arg-278 with alanine and histidine decreased mitochondrial GPAT activity by 90%, replacement with lysine reduced activity by only 25%. A substitution of the nonconserved Arg-279 with either alanine, histidine, or lysine did not alter mitochondrial GPAT activity. Moreover, R278K mitochondrial GPAT still showed sensitivity to arginine-modifying agents, as in the case of wild-type mitochondrial GPAT. These results suggest that Arg-318 may be critical for mitochondrial GPAT activity, whereas Arg-278 can be replaced by a basic amino acid. Examination of the other conserved residues in the seven amino acid stretch revealed that Phe-313 and Glu-315 are also important, but conservative substitutions can partially maintain activity; substitution with alanine reduced activity by 83 and 72%, respectively, whereas substituting Phe-313 with tyrosine and Glu-315 with glutamine had even lesser effect. In addition, there was no change in fatty acyl-CoA selectivity. Kinetic analysis of the R318K and R318A mitochondrial GPAT showed an 89 and 95%, respectively, decrease in catalytic efficiency but no major change in substrate binding as indicated by the K(m) values for palmitoyl-CoA and glycerol 3-phosphate. These studies indicate importance of the conserved seven amino acid stretch for mitochondrial GPAT activity and the significance of Arg-318 for catalysis.     

Mutational analyses of yeast RNA triphosphatases highlight a common mechanism of metal-dependent NTP hydrolysis and a means of targeting enzymes to pre-mRNAs in vivo by fusion to the guanylyltransferase component of the capping apparatus.

Saccharomyces cerevisiae Cet1p is the prototype of a family of metal-dependent RNA 5'-triphosphatases/NTPases encoded by fungi and DNA viruses; the family is defined by conserved sequence motifs A, B, and C. We tested the effects of 12 alanine substitutions and 16 conservative modifications at 18 positions of the motifs. Eight residues were identified as important for triphosphatase activity. These were Glu-305, Glu-307, and Phe-310 in motif A (IELEMKF); Arg-454 and Lys-456 in motif B (RTK); Glu-492, Glu-494, and Glu-496 in motif C (EVELE). Four acidic residues, Glu-305, Glu-307, Glu-494, and Glu-496, may comprise the metal-binding site(s), insofar as their replacement by glutamine inactivated Cet1p. E492Q retained triphosphatase activity. Basic residues Arg-454 and Lys-456 in motif B are implicated in binding to the 5'-triphosphate. Changing Arg-454 to alanine or glutamine resulted in a 30-fold increase in the K(m) for ATP, whereas substitution with lysine increased K(m) 6-fold. Changing Lys-456 to alanine or glutamine increased K(m) an order of magnitude; ATP binding was restored when arginine was introduced. Alanine in lieu of Phe-310 inactivated Cet1p, whereas Tyr or Leu restored function. Alanine mutations at aliphatic residues Leu-306, Val-493, and Leu-495 resulted in thermal instability in vivo and in vitro. A second S. cerevisiae RNA triphosphatase/NTPase (named Cth1p) containing motifs A, B, and C was identified and characterized. Cth1p activity was abolished by E87A and E89A mutations in motif A. Cth1p is nonessential for yeast growth and, by itself, cannot fulfill the essential role played by Cet1p in vivo. Yet, fusion of Cth1p in cis to the guanylyltransferase domain of mammalian capping enzyme allowed Cth1p to complement growth of cet1Delta yeast cells. This finding illustrates that mammalian guanylyltransferase can be used as a vehicle to deliver enzymes to nascent pre-mRNAs in vivo, most likely through its binding to the phosphorylated CTD of RNA polymerase II.     

Quaternary structure of the severe acute respiratory syndrome (SARS) coronavirus main protease

SARS (severe acute respiratory syndrome) has been one of the most severe viral infectious diseases last year and still remains as a highly risky public health problem around the world. Exploring the types of interactions responsible for structural stabilities of its component protein molecules constitutes one of the approaches to find a destabilization method for the virion particle. In this study, we performed a series of experiments to characterize the quaternary structure of the dimeric coronavirus main protease (M(pro), 3CL(pro)). By using the analytical ultracentrifuge, we demonstrated that the dimeric SARS coronavirus main protease exists as the major form in solution at protein concentration as low as 0.10 mg/mL at neutral pH. The enzyme started to dissociate at acidic and alkali pH values. Ionic strength has profound effect on the dimer stability indicating that the major force involved in the subunit association is ionic interactions. The effect of ionic strength on the protease molecule was reflected by the drastic change of electrostatic potential contour of the enzyme in the presence of NaCl. Analysis of the crystal structures indicated that the interfacial ionic interaction was attributed to the Arg-4...Glu-290 ion pair between the subunits. Detailed examination of the dimer-monomer equilibrium at different pH values reveals apparent pK(a) values of 8.0 +/- 0.2 and 5.0 +/- 0.1 for the Arg-4 and Glu-290, respectively. Mutation at these two positions reduces the association affinity between subunits, and the Glu-290 mutants had diminished enzyme activity. This information is useful in searching for substances that can intervene in the subunit association, which is attractive as a target to neutralize the virulence of SARS coronavirus.     

NMR docking of a substrate into the X-ray structure of staphylococcal nuclease.

The conformation of the staphylococcal nuclease-bound metal-dTdA complex, previously determined by NMR methods [Weber, D.J., Mullen, G.P., Mildvan, A.S. (1991) Biochemistry 30:7425-7437] was docked into the X-ray structure of the enzyme-Ca(2+)-3',5'-pdTp complex [Loll, P.J., Lattman, E.E. (1989) Proteins: Struct., Funct., Genet. 5:183-201] by superimposing the metal ions, taking into account intermolecular nuclear Overhauser effects from assigned aromatic proton resonances of Tyr-85, Tyr-113, and Tyr-115 to proton resonances of the leaving dA moiety of dTdA, and energy minimization to relieve small overlaps. The proton resonances of the Phe, Tyr, and Trp residues of the enzyme in the ternary enzyme-La(3+)-dTdA complex were sequence specifically assigned by 2D phase-sensitive NOESY, with and without deuteration of the aromatic protons of the Tyr residues, and by 2D heteronuclear multiple quantum correlation (HMQC) spectroscopy and 3D NOESY-HMQC spectroscopy with 15N labeling. While resonances of most Phe, Tyr and Trp residues were unshifted by the substrate dTdA from those found in the enzyme-La(3+)-3',5'-pdTp complex and the enzyme-Ca(2+)-3',5'-pdTp complex, proton resonances of Tyr-85, Tyr-113, Tyr-115, and Phe-34 were shifted by 0.08 to 0.33 ppm and the 15N resonance of Tyr-113 was shifted by 2.1 ppm by the presence of substrate. The optimized position of enzyme-bound dTdA shows the 5'-dA leaving group to partially overlap the inhibitor, 3',5'-pdTp (in the X-ray structure). The 3'-TMP moiety of dTdA points toward the solvent in a channel defined by Ile-18, Asp-19, Thr-22, Lys-45, and His-46. The phosphate of dTdA is coordinated by the metal, and an adjacent inner sphere water ligand is positioned to donate a hydrogen bond to the general base Glu-43 and to attack the phosphorus with inversion. Arg-35 and Arg-87 donate monodentate hydrogen bonds to different phosphate oxygens of dTdA, with Arg-87 positioned to protonate the leaving 5'-oxygen of dA, thus clarifying the mechanism of hydrolysis. Model building of an additional 5'-dGMP onto the 3'-oxygen of dA placed this third nucleotide onto a surface cleft near residues Glu-80, Asp-83, Lys-84, and Tyr-115 with its 3'-OH group accessible to the solvent, thus defining the size of the substrate binding site as accommodating a trinucleotide.     

Molecular cloning and functional analysis of a Schizosaccharomyces pombe homologue of Escherichia coli endonuclease III.

The Escherichia coli endonuclease III (Nth-Eco) protein is involved in the removal of damaged pyrimidine residues from DNA by base excision repair. It is an iron-sulphur enzyme possessing both DNA glycosylase and apurinic/apyrimidinic lyase activities. A database homology search identified an open reading frame in genomic sequences of Schizosaccharomyces pombe which encodes a protein highly similar to Nth-Eco. The gene has been subcloned in an expression vector and the protein purified to apparent homogeneity. The S.pombe Nth homologue (Nth-Spo) is a 40.2 kDa protein of 355 amino acids. Nth-Spo possesses glycosylase activity on different types of DNA substrates with pyrimidine damage, being able to release both urea and thymine glycol from double-stranded polymers. The eukaryotic protein removes urea more efficiently than the prokaryotic enzyme, whereas its efficiency in excising thymine glycol is lower. A nicking assay was used to show that the enzyme also exhibits an AP lyase activity on UV- and gamma-irradiated DNA substrates. These findings show that Nth protein is structurally and functionally conserved from bacteria to fission yeast.     

Mechanism of the reaction catalyzed by dihydrofolate reductase from Escherichia coli: pH and deuterium isotope effects with NADPH as the variable substrate

The variations with pH of the kinetic parameters and primary deuterium isotope effects for the reaction of NADPH with dihydrofolate reductase from Escherichia coli have been determined. The aims of the investigations were to elucidate the chemical mechanism of the reaction and to obtain information about the location of the rate-limiting steps. The V and V/KNADPH profiles indicate that a single ionizing group at the active center of the enzyme must be protonated for catalysis, whereas the Ki profiles show that the binding of NADPH to the free enzyme and of ATP-ribose to the enzyme-dihydrofolate complex is pH independent. From the results of deuterium isotope effects on V/KNADPH, it is concluded that NADPH behaves as a sticky substrate. It is this stickiness that raises artificially the intrinsic pK value of 6.4 for the Asp-27 residue of the enzyme-dihydrofolate complex [Howell, E. E., Villafranca, J. E., Warren, M. S., Oatley, S. J., & Kraut, J. (1986) Science (Washington, D.C.) 231, 1123] to an observed value of 8.9. Thus, the binary enzyme complex is largely protonated at neutral pH. The elevation of the intrinsic pK value of 6.4 for the ternary enzyme-NADPH-dihydrofolate complex to 8.5 is not due to the kinetic effects of substrates. Rather, it is the consequence of the lower, pH-independent rate of product release and the faster pH-dependent catalytic step. At neutral pH, the proportion of enzyme present as a protonated ternary enzyme-substrate complex is sufficient to keep catalysis faster than product release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Substrate discrimination by formamidopyrimidine-DNA glycosylase: a mutational analysis

Formamidopyrimidine-DNA glycosylase (Fpg) is a primary participant in the repair of 8-oxoguanine, an abundant oxidative DNA lesion. Although the structure of Fpg has been established, amino acid residues that define damage recognition have not been identified. We have combined molecular dynamics and bioinformatics approaches to address this issue. Site-specific mutagenesis coupled with enzyme kinetics was used to test our predictions. On the basis of molecular dynamics simulations, Lys-217 was predicted to interact with the O8 of extrahelical 8-oxoguanine accommodated in the binding pocket. Consistent with our computational studies, mutation of Lys-217 selectively reduced the ability of Fpg to excise 8-oxoguanine from DNA. Dihydrouracil, also a substrate for Fpg, served as a nonspecific control. Other residues involved in damage recognition (His-89, Arg-108, and Arg-109) were identified by combined conservation/structure analysis. Arg-108, which forms two hydrogen bonds with cytosine in Fpg-DNA, is a major determinant of opposite-base specificity. Mutation of this residue reduced excision of 8-oxoguanine from thermally unstable mispairs with guanine or thymine, while excision from the stable cytosine and adenine base pairs was less affected. Mutation of His-89 selectively diminished the rate of excision of 8-oxoguanine, whereas mutation of Arg-109 nearly abolished binding of Fpg to damaged DNA. Taken together, these results suggest that His-89 and Arg-109 form part of a reading head, a structural feature used by the enzyme to scan DNA for damage. His-89 and Lys-217 help determine the specificity of Fpg in recognizing the oxidatively damaged base, while Arg-108 provides specificity for bases positioned opposite the lesion.