Catalytic and allosteric mechanism of AMP nucleosidase from primary, beta-secondary, and multiple heavy atom kinetic isotope effects

Adenosine 5'-phosphate was synthesized with specific heavy atom substitutions to permit measurement of V/K kinetic isotope effects for the N-glycohydrolase activity of the allosteric AMP nucleosidase and the acid-catalyzed solvolysis of these compounds. The effects of allosteric activation on the kinetic isotope effects together with the kinetic mechanism of AMP nucleosidase [DeWolf, W. E., Jr., Emig, F. A., & Schramm, V. L. (1986) Biochemistry 25, 4132-4140] indicate that the kinetic isotope effects are fully expressed. Comparison of individual primary and secondary kinetic isotope effects with combined isotope effects and the isotope effect of the reverse reaction indicated that kinetic isotope effects in AMP nucleosidase arise from a single step in the reaction mechanism. Under these conditions, kinetic isotope effects can be used to interpret transition-state structure for AMP nucleosidase. Changes in kinetic isotope effects occurred as a function of allosteric activator, demonstrating that allosteric activation alters transition-state structure for AMP nucleosidase. Kinetic isotope effects, expressed as [V/K(normal isotope]/[V/K(heavy isotope)], were observed with [2'-2H]AMP (1.061 +/- 0.002), [9-15N]AMP (1.030 +/- 0.003), [1'-2H]AMP (1.045 +/- 0.002), and [1'-14C]AMP (1.035 +/- 0.002) when hydrolyzed by AMP nucleosidase in the absence of MgATP. Addition of MgATP altered the [2'-2H]AMP effect (1.043 +/- 0.002) and the [1'-2H]AMP effect (1.030 +/- 0.003) and caused a smaller decrease of the 14C and 15N effects. Multiple heavy atom substitutions into AMP caused an increase in observed isotope effects to 1.084 +/- 0.004 for [1'-2H,1'-14C]AMP and to 1.058 +/- 0.002 for [9-15N,1'-14C]AMP with the enzyme in the absence of ATP.(ABSTRACT TRUNCATED AT 250 WORDS)     

Transition state analysis of adenosine nucleosidase from yellow lupin (Lupinus luteus)

The transition state of adenosine nucleosidase (EC 3.2.2.7) isolated from yellow lupin (Lupinus luteus) was determined based upon a series of heavy atom kinetic isotope effects. Adenosine labeled with 13C, 2H, and 15N was analyzed by liquid chromatography/electrospray mass spectrometry to determine kinetic isotope effects. Values of 1.024+/-0.004, 1.121+/-0.005, 1.093+/-0.004, 0.993+/-0.006, and 1.028+/-0.005 were found for [1'-13C], [1'-2H], [2'-2H], [5'-2H], and [9-15N] adenosine, respectively. Using a bond order bond energy vibrational analysis, a transition state consisting of a significantly broken C-N bond, formation of an oxocarbenium ion in the ribose ring, a conformation of C3-exo for the ribose ring, and protonation of the heterocyclic base was proposed. This transition state was found to be very similar to the transition state for nucleoside hydrolase, another purine metabolizing enzyme, isolated from Crithidia fasciculata.     

Transition state analysis for human and Plasmodium falciparum purine nucleoside phosphorylases

Recent studies have shown that Plasmodium falciparum is sensitive to a purine salvage block at purine nucleoside phosphorylase (PNP) and that human PNP is a target for T-cell proliferative diseases. Specific tight-binding inhibitors might be designed on the basis of specific PNP transition state structures. Kinetic isotope effects (KIEs) were measured for arsenolysis of inosine catalyzed by P. falciparum and human purine nucleoside phosphorylases. Intrinsic KIEs from [1'-(3)H]-, [2'-(3)H]-, [1'-(14)C]-, [9-(15)N]-, and [5'-(3)H]inosines were 1.184 +/- 0.004, 1.031 +/- 0.004, 1.002 +/- 0.006, 1.029 +/- 0.006, and 1.062 +/- 0.002 for the human enzyme and 1.116 +/- 0.007, 1.036 +/- 0.003, 0.996 +/- 0.006, 1.019 +/- 0.005, and 1.064 +/- 0.003 for P. falciparum PNPs, respectively. Analysis of KIEs indicated a highly dissociative D(N)A(N) (S(N)1) stepwise mechanism with very little leaving group involvement. The near-unity 1'-(14)C KIEs for both human and P. falciparum PNP agree with the theoretical value for a 1'-(14)C equilibrium isotope effect for oxacarbenium ion formation when computed at the B1LYP/6-31G(d) level of theory. The 9-(15)N KIE for human PNP is also in agreement with theory for equilibrium formation of hypoxanthine and oxacarbenium ion at this level of theory. The 9-(15)N KIE for P. falciparum PNP shows a constrained vibrational environment around N9 at the transition state. A relatively small beta-secondary 2'-(3)H KIE for both enzymes indicates a 3'-endo conformation for ribose and relatively weak hyperconjugation at the transition state. The large 5'-(3)H KIE reveals substantial distortion at the 5'-hydroxymethyl group which causes loosening of the C5'-H5' bonds during the reaction coordinate.     

Transition state structure for ADP-ribosylation of eukaryotic elongation factor 2 catalyzed by diphtheria toxin

Bacterial protein toxins are the most powerful human poisons known, exhibiting an LD(50) of 0.1-1 ng kg(-)(1). A major subset of such toxins is the NAD(+)-dependent ADP-ribosylating exotoxins, which include pertussis, cholera, and diphtheria toxin. Diphtheria toxin catalyzes the ADP ribosylation of the diphthamide residue of eukaryotic elongation factor 2 (eEF-2). The transition state of ADP ribosylation catalyzed by diphtheria toxin has been characterized by measuring a family of kinetic isotope effects using (3)H-, (14)C-, and (15)N-labeled NAD(+) with purified yeast eEF-2. Isotope trapping experiments yield a commitment to catalysis of 0.24 at saturating eEF-2 concentrations, resulting in suppression of the intrinsic isotope effects. Following correction for the commitment factor, intrinsic primary kinetic isotope effects of 1.055 +/- 0.003 and 1.022 +/- 0.004 were observed for [1(N)'-(14)C]- and [1(N)-(15)N]NAD(+), respectively; the double primary isotope effect was 1.066 +/- 0.004 for [1(N)'-(14)C, 1(N)-(15)N]NAD(+). Secondary kinetic isotope effects of 1.194 +/- 0.002, 1.101 +/- 0.003, 1.013 +/- 0.005, and 0.988 +/- 0.002 were determined for [1(N)'-(3)H]-, [2(N)'-(3)H]-, [4(N)'-(3)H]-, and [5(N)'-(3)H]NAD(+), respectively. The transition state structure was modeled using density functional theory (B1LYP/6-31+G) as implemented in Gaussian 98, and theoretical kinetic isotope effects were subsequently calculated using Isoeff 98. Constraints were varied in a systematic manner until the calculated kinetic isotope effects matched the intrinsic isotope effects. The transition state model most consistent with the intrinsic isotope effects is characterized by the substantial loss in bond order of the nicotinamide leaving group (bond order = 0.18, 1.99 A) and weak participation of the attacking imidazole nucleophile (bond order = 0.03, 2.58 A). The transition state structure imparts strong oxacarbenium ion character to the ribose ring even though significant bond order remains to the nicotinamide leaving group. The transition state model presented here is asymmetric and consistent with a dissociative S(N)1 type mechanism in which attack of the diphthamide nucleophile lags behind departure of the nicotinamide.     

Kinetic isotope effects of nucleoside hydrolase from Escherichia coli

rihC is one of a group of three ribonucleoside hydrolases found in Escherichia coli (E. coli). The enzyme catalyzes the hydrolysis of selected nucleosides to ribose and the corresponding base. A family of Vmax/Km kinetic isotope effects using uridine labeled with stable isotopes, such as 2H, 13C, and 15N, were determined by liquid chromatography/mass spectrometry (LC/MS). The kinetic isotope effects were 1.012+/-0.006, 1.027+/-0.005, 1.134+/-0.007, 1.122+/-0.008, and 1.002+/-0.004 for [1'-13C], [1-15N], [1'-2H], [2'-2H], and [5'-2H2] uridine, respectively. A transition state based upon a bond-energy bond-order vibrational analysis (BEBOVIB) of the observed kinetic isotope effects is proposed. The main features of this transition state are activation of the heterocyclic base by protonation of/or hydrogen bonding to O2, an extensively broken C-N glycosidic bond, formation of an oxocarbenium ion in the ribose ring, C3'-exo ribose ring conformation, and almost no bond formation to the attacking nucleophile. The proposed transition state for the prokaryotic E. coli nucleoside hydrolase is compared to that of a similar enzyme isolated from Crithidia fasciculata (C. fasciculata).     

A kinetic isotope effect study and transition state analysis of the S-adenosylmethionine synthetase reaction

The biosynthesis of S-adenosylmethionine occurs in a unique enzymatic reaction in which the synthesis of the sulfonium center results from displacement of the entire polyphosphate chain from MgATP. The mechanism of S-adenosylmethionine synthetase (ATP:L-methionine s-adenosyltransferase) from Escherichia coli has been characterized by kinetic isotope effect and substrate trapping measurements. Replacement of 12C by 14C at the 5' carbon of ATP yields a primary Vmax/Km isotope effect (12C/14C) of 1.128 +/- 0.003 in the absence of added monovalent cation activator (K+). At saturating K+ concentrations (10 mM) the primary isotope effect diminishes slightly to 1.108 +/- 0.003, indicating that the step in the mechanism involving bond breaking at the 5' carbon of MgATP has a small commitment to catalysis at conditions near Vmax. No alpha-secondary 3H isotope effect from [5'-3H]ATP was detected, (1H/3H) = 1.000 +/- 0.002, even in the absence of KCl. There was no significant primary sulfur isotope effect from [35S]methionine at KCl concentrations from 0 to 10 mM. Substitution of the methyl group of methionine with tritium yielded a beta-secondary isotope effect (CH3/C3H3) = 1.009 +/- 0.008 independent of KCl concentration. The reaction of selenomethionine and [5'-14C]ATP gave a primary isotope effect of 1.097 +/- 0.006, independent of KCl concentration. Substrate trapping experiments demonstrated that the step in the mechanism involving bond making to sulfur of methionine does not have a significant commitment to catalysis at 0.25 mM KCl, therefore intrinsic isotope effects were observed. Substrate trapping experiments indicated that the step involving bond breaking at carbon 5' of MgATP has a 10% commitment to catalysis at 0.25 mM KCl. The isotope effects are interpreted in terms of an Sn2-like transition state structure in which bonding of the C5' is symmetric with respect to the departing tripolyphosphate group and the incoming sulfur of methionine. With selenomethionine as substrate an earlier transition state is implicated.     

Biosynthesis of biopterin. Studies on the mechanism of 6-pyruvoyltetrahydropteridine synthase

[1'-3H]- and [2'-3H]dihydroneopterin triphosphate (NH2TP) were prepared enzymatically from [4-3H]- and [5-3H]glucose and converted to tetrahydrobiopterin (BH4) by an extract from bovine adrenal medulla. The formation of BH4 from both [1'-3H]- and [2'-3H]-NH2TP proceeds with virtually complete loss of the respective tritium label. The breaking of the CH-bond at C-1' is characterized by a kinetic isotope effect of 2.6 +/- 0.5. A smaller kinetic isotope effect of 1.5 +/- 0.2 was found for the breaking of the CH-bond at C-2'.     

Transition state structure of 5'-methylthioadenosine/S-adenosylhomocysteine nucleosidase from Escherichia coli and its similarity to transition state analogues

Methylthioadenosine/S-adenosylhomocysteine nucleosidase (MTAN) catalyzes reactions linked to polyamine metabolism, quorum sensing pathways, methylation reactions, and adenine salvage. It is a candidate target for antimicrobial drug design. Kinetic isotope effects (KIEs) were measured on the MTAN-catalyzed hydrolysis of 5'-methylthioadenosine (MTA) to determine the transition state structure. KIEs measured at pH 7.5 were near unity due to the large forward commitment to catalysis. Intrinsic KIEs were expressed by increasing the pH to 8.5. Intrinsic KIEs from MTAs labeled at 1'-(3)H, 1'-(14)C, 2'-(3)H, 4'-(3)H, 5'-(3)H, 9-(15)N, and Me-(3)H(3) were 1.160 +/- 0.004, 1.004 +/- 0.003, 1.044 +/- 0.004, 1.015 +/- 0.002, 1.010 +/- 0.002, 1.018 +/- 0.006, and 1.051 +/- 0.002, respectively. The large 1'-(3)H and small 1'-(14)C KIEs indicate that the Escherichia coli MTAN reaction undergoes a dissociative (D(N)A(N)) (S(N)1) mechanism with little involvement of the leaving group or participation of the attacking nucleophile at the transition state, causing the transition state to have significant ribooxacarbenium ion character. A transition state constrained to match the intrinsic KIEs was located with density functional theory [B3LYP/6-31G(d,p)]. The leaving group (N9) is predicted to be 3.0 A from the anomeric carbon. The small beta-secondary 2'-(3)H KIE of 1.044 corresponds to a modest 3'-endo conformation for ribose and a H1'-C1'-C2'-H2' dihedral angle of 53 degrees at the transition state. Natural bond orbital analysis of the substrate and the transition state suggests that the 4'-(3)H KIE is due to hyperconjugation between the lone pair (n(p)) of O3' and the antibonding (sigma) orbital of the C4'-H4' group, and the methyl-(3)H(3) KIE is due to hyperconjugation between the n(p) of sulfur and the sigma of methyl C-H bonds. Transition state analogues that resemble this transition state structure are powerful inhibitors, and their molecular electrostatic potential maps closely resemble that of the transition state.     

Transition-state structures for N-glycoside hydrolysis of AMP by acid and by AMP nucleosidase in the presence and absence of allosteric activator

The mechanism of acid and enzymatic hydrolysis of the N-glycosidic bond of AMP has been investigated by fitting experimentally observed kinetic isotope effects [Parkin, D. W., & Schramm, V. L. (1987) Biochemistry (preceding paper in this issue)] to calculated kinetic isotope effects for proposed transition-state structures. The sensitivity of the transition-state calculations was tested by "arying the transition-state structure and comparing changes in the calculated kinetic isotope effects with the experimental values of the isotope effect measurements. The kinetic isotope effects for the acid-catalyzed hydrolysis of AMP are best explained by a transition state with considerable oxycarbonium character in the ribose ring, significant bonding remaining to the departing adenine ring, participation of a water nucleophile, and protonation of the adenine ring. A transition-state structure without preassociation of the water nucleophile cannot be eliminated by the data. Enzymatic hydrolysis of the N-glycosidic bond of AMP by AMP nucleosidase from Azotobacter vinelandii was analyzed in the absence and presence of MgATP, the allosteric activator that increases Vmax approximately 200-fold. The transition states for enzyme-catalyzed hydrolysis that best explain the kinetic isotope effects involve early SN1 transition states with significant bond order in the glycosidic bond and protonation of the adenine base. The enzyme enforces participation of an enzyme-bound water molecule, which has weak bonding to C1' in the transition state. Activation of AMP nucleosidase by MgATP causes the bond order of the glycosidic bond in the transition state to increase significantly. Hyperconjugation in the ribosyl group is altered by enzymatic stabilization of the oxycarbonium ion. This change is consistent with the interaction of an amino acid on the enzyme. Together, these changes stabilize a carboxonium-like transition-state complex that occurs earlier in the reaction pathway than in the absence of allosteric activator. In addition to the allosteric changes that alter transition-state structure, the presence of other inductive effects that are unobserved by kinetic isotope measurements is also likely to increase the catalytic rate.     

Mechanism and activation for allosteric adenosine 5'-monophosphate nucleosidase. Kinetic alpha-deuterium isotope effects for the enzyme-catalyzed hydrolysis of adenosine 5'-monophosphate and nicotinamide mononucleotide

The kinetic alpha-deuterium isotope effect on Vmax/Km for hydrolysis of NMN catalyzed by AMP nucleosidase at saturating concentrations of the allosteric activator MgATP2- is kH/kD = 1.155 +/- 0.012. This value is close to that reported previously for the nonenzymatic hydrolysis of nucleosides of related structure, suggesting that the full intrinsic isotope effect for enzymatic NMN hydrolysis is expressed under these conditions; that is, bond-changing reactions are largely or completely rate-determining and the transition state has marked oxocarbonium ion character. The kinetic alpha-deuterium isotope effect for this reaction is unchanged when deuterium oxide replaces water as solvent, corroborating this conclusion. Furthermore, this isotope effect is independent of pH over the range 6.95-9.25, for which values of Vmax/Km change by a factor of 90, suggesting that the isotope-sensitive and pH-sensitive steps for AMP-nucleosidase-catalyzed NMN hydrolysis are the same. Values of kH/kD for AMP nucleosidase-catalyzed hydrolysis of NMN decrease with decreasing saturation of enzyme with MgATP2- and reach unity when the enzyme is less than half-saturated with this activator. This requires that the rate-determining step changes from cleavage of the covalent C-N bond to one which is isotope-independent. In contrast to the case for NMN hydrolysis, AMP nucleosidase-catalyzed hydrolysis of AMP at saturating concentrations of MgATP2- shows a kinetic alpha-deuterium isotope effect of unity. Thus, covalent bond-changing reactions are largely or completely rate-determining for hydrolysis of a poor substrate, NMN, but make little or no contribution to rate-determining step for hydrolysis of a good substrate, AMP, by maximally activated enzyme. This behavior has several precedents.     

Second-sphere amino acids contribute to transition-state structure in bovine purine nucleoside phosphorylase

Transition-state structures of human and bovine of purine nucleoside phosphorylases differ, despite 87% homologous amino acid sequences. Human PNP (HsPNP) has a fully dissociated transition state, while that for bovine PNP (BtPNP) has early SN1 character. Crystal structures and sequence alignment indicate that the active sites of these enzymes are the same within crystallographic analysis, but residues in the second-sphere from the active sites differ significantly. Residues in BtPNP have been mutated toward HsPNP, resulting in double (Asn123Lys; Arg210Gln) and triple mutant PNPs (Val39Thr; Asn123Lys; Arg210Gln). Steady-state kinetic studies indicated unchanged catalytic activity, while pre-steady-state studies indicate that the chemical step is slower in the triple mutant. The mutant enzymes have higher affinity for inhibitors that are mimics of a late dissociative transition state. Kinetic isotope effects (KIEs) and computational chemistry were used to identify the transition-state structure of the triple mutant. Intrinsic KIEs from [1'-3H], [1'-14C], [2'-3H], [5'-3H], and [9-15N] inosines were 1.221, 1.035, 1.073, 1.062 and 1.025, respectively. The primary intrinsic [1'-14C] and [9-15N] KIEs indicate a highly dissociative SN1 transition state with low bond order to the leaving group, a transition state different from the native enzyme. The [1'-14C] KIE suggests significant nucleophilic participation at the transition state. The transition-state structure of triple mutant PNP is altered as a consequence of the amino acids in the second sphere from the catalytic site. These residues are implicated in linking the dynamic motion of the protein to formation of the transition state.     

Remote mutations alter transition-state structure of human purine nucleoside phosphorylase

Purine nucleoside phosphorylase (PNP) catalyzes the reversible phosphorolysis of purine (2'-deoxy)ribonucleosides to give the corresponding purine base and (2'-deoxy)ribose 1-phosphate as products. Human and bovine PNPs (HsPNP and BtPNP) form distinct transition states despite 87% identity in amino acid sequence. A PNP hybrid was produced by replacing K22 and H104 in HsPNP with the corresponding Glu and Arg residues found in BtPNP. We solved the transition-state structure of E:R-HsPNP (K22E:H104R mutant of HsPNP) using competitive kinetic isotope effects (KIE) and global density functional calculations. An array of PNP transition states was generated from optimized structure candidates with varied C1'-N9, C1'-Ophosphate distances, ribosyl pucker configurations and N7-protonation states. Isotopically labeled [1'-3H], [2'-3H], [1'-14C], [9-15N], [1'-14C, 9-15N] and [5'-3H2]inosines gave intrinsic KIE values of 1.210, 1.075, 1.035, 1.024, 1.065, 1.063 with E:R-HsPNP, respectively. The suite of E:R-HsPNP KIEs match a single structure from the array of PNP transition-state candidates. The transition state of E:R-HsPNP is fully dissociative, N7-protonated hypoxanthine (C1'-N9 distance >or= 3.0 A) with partial participation of phosphate (C1'-Ophosphate distance = 2.26 A), 2'-C-exo-ribosyl ring pucker and the O5'-C5'-C4'-O4' dihedral angle near 60 degrees . The transition state of E:R-HsPNP is altered from the fully dissociative DN*AN character for HsPNP to a late phosphate-associative character. E:R-HsPNP differs from native HsPNP by only two residues over 25 A away from the active site. New interactions caused by the mutations increase the catalytic efficiency of the enzyme for formation of a late transition state with increased participation of the phosphate nucleophile. Dynamic coupling motions from the remote mutations to the catalytic sites are proposed.     

Uridine phosphorylase from Trypanosoma cruzi: kinetic and chemical mechanisms

The reversible phosphorolysis of uridine to generate uracil and ribose 1-phosphate is catalyzed by uridine phosphorylase and is involved in the pyrimidine salvage pathway. We define the reaction mechanism of uridine phosphorylase from Trypanosoma cruzi by steady-state and pre-steady-state kinetics, pH-rate profiles, kinetic isotope effects from uridine, and solvent deuterium isotope effects. Initial rate and product inhibition patterns suggest a steady-state random kinetic mechanism. Pre-steady-state kinetics indicated no rate-limiting step after formation of the enzyme-products ternary complex, as no burst in product formation is observed. The limiting single-turnover rate constant equals the steady-state turnover number; thus, chemistry is partially or fully rate limiting. Kinetic isotope effects with [1'-(3)H]-, [1'-(14)C]-, and [5'-(14)C,1,3-(15)N(2)]uridine gave experimental values of (α-T)(V/K)(uridine) = 1.063, (14)(V/K)(uridine) = 1.069, and (15,β-15)(V/K)(uridine) = 1.018, in agreement with an A(N)D(N) (S(N)2) mechanism where chemistry contributes significantly to the overall rate-limiting step of the reaction. Density functional theory modeling of the reaction in gas phase supports an A(N)D(N) mechanism. Solvent deuterium kinetic isotope effects were unity, indicating that no kinetically significant proton transfer step is involved at the transition state. In this N-ribosyl transferase, proton transfer to neutralize the leaving group is not part of transition state formation, consistent with an enzyme-stabilized anionic uracil as the leaving group. Kinetic analysis as a function of pH indicates one protonated group essential for catalysis and for substrate binding.     

31P NMR studies of the arginine kinase reaction. Equilibrium constants and exchange rates at stoichiometric enzyme concentration.

The arginine kinase reaction, the reversible transfer of the terminal phosphoryl group of ATP to L-arginine, has been investigated by the technique of 31P NMR at catalytic and stoichiometric concentrations of the enzyme. Three of the four substrates, ATP, ADP, and P-arginine produce easily distinguishable resonances in the 31P NMR spectrum, thus permitting a determination of equilibrium constants from the integrated areas of the resonances. From the linewidths, the exchange rates between reactants and products may be evaluated. At pH 7.25 and a temperature of 12 degrees, the equilibrium constant at catalytic enzyme concentration: Keq = [MgADP] [P-arginine]/[MgATP] [L-arginine], is found to be 0.10 +/- 0.02 and that at stoichiometric enzyme concentration: K'eq = [E-MgADP] [E-P-arginine]/[E-MgATP] [E-arginine] to be 1.56 +/- 0.5. Thus, as the enzyme concentration increased, the production of P-arginine is increasingly favored. From the NMR line shapes in the presence of excess enzyme, the rate of the single step, the transfer of the phosphoryl group on the surface of the enzyme is found to be 192 +/- 15 s-1 in the forward direction, i.e. from E-MgATP, and 154 +/- 15 s-1 in the reverse direction from E-P-argine. At 12 degrees and pH 7.25, the rate of the overall reaction in the forward direction was determined from kinetic measurements to be 19 s-1, an order of magnitude slower than the rate measured by NMR. It can, therefore, be concluded that the interconversion of substrates on the surface of the enzyme is not the rate-determining step in the overal reaction. From the equilibrium constants and other known data the dissociation constant of P-arginine from its enzyme complex can be determined and is found to be 100 muM.     

Secondary 15N isotope effects on the reactions catalyzed by alcohol and formate dehydrogenases

Secondary 15N isotope effects at the N-1 position of 3-acetylpyridine adenine dinucleotide have been determined, by using the internal competition technique, for horse liver alcohol dehydrogenase (LADH) with cyclohexanol as a substrate and yeast formate dehydrogenase (FDH) with formate as a substrate. On the basis of less precise previous measurements of these 15N isotope effects, the nicotinamide ring of NAD has been suggested to adopt a boat conformation with carbonium ion character at C-4 during hydride transfer [Cook, P. F., Oppenheimer, N. J. & Cleland, W. W. (1981) Biochemistry 20, 1817]. If this mechanism were valid, as N-1 becomes pyramidal an 15N isotope effect of up to 2-3% would be observed. In the present study the equilibrium 15N isotope effect for the reaction catalyzed by LADH was measured as 1.0042 +/- 0.0007. The kinetic 15N isotope effect for LADH catalysis was 0.9989 +/- 0.0006 for cyclohexanol oxidation and 0.997 +/- 0.002 for cyclohexanone reduction. The kinetic 15N isotope effect for FDH catalysis was 1.004 +/- 0.001. These values suggest that a significant 15N kinetic isotope effect is not associated with hydride transfer for LADH and FDH. Thus, in contrast with the deformation mechanism previously postulated, the pyridine ring of the nucleotide apparently remains planar during these dehydrogenase reactions.     

Kinetic studies on the two common inherited forms of human erythrocyte adenylate kinase

1. The kinetic properties of two genetic variants of human erythrocyte adenylate kinase were studied at limiting concentrations of both ADP and MgADP(-) in the forward direction and at limiting concentrations of both AMP and MgATP(2-) in the reverse direction. 2. Primary reciprocal plots rule out the possibility of a Ping Pong mechanism for both forms of the enzyme. 3. Analysis of the kinetic data by an appropriate computer program gave the following K(m) values for the type 1 enzyme: AMP, 0.33mm+/-0.1; MgATP(2-), 0.95mm+/-0.13; ADP, 0.12mm+/-0.03; MgADP(-), 0.22mm+/-0.04. Values for the type 2 enzyme were: AMP, 0.27mm+/-0.03; MgATP(2-), 0.40mm+/-0.05; ADP, 0.08mm+/-0.07; MgADP(-), 0.20mm+/-0.04. 4. Product inhibition studies were done by studying the reverse reaction. With ADP as product inhibitor competitive inhibition patterns were obtained with AMP and/or MgATP(2-) as variable substrate. Similar results were obtained for product inhibition by MgADP(-) with AMP as variable substrate. The results are consistent with a Rapid Equilibrium Random mechanism. 5. Secondary plots of slope versus product concentration were linear. The data were fitted to the appropriate equation and analysed by computer to give values for the product inhibition constants. 6. Differences between the values of certain kinetic constants for the two forms of the enzyme were observed.     

Kinetic isotope effects on the oxidation of reduced nicotinamide adenine dinucleotide phosphate by the flavoprotein methylenetetrahydrofolate reductase

Previous work from this laboratory has established that the NADPH-menadione oxidoreductase reaction catalyzed by methylenetetrahydrofolate reductase from pig liver proceeds by Ping Pong Bi Bi kinetics and that the reductive half-reaction is rate limiting in steady-state turnover. We have now shown that methylenetetrahydrofolate reductase stereo-specifically removes the pro-S hydrogen from the 4-position of NADPH. During the oxidation of [4(S)-3H]NADPH, we observed a kinetic isotope on V/KNADPH of 10.8 +/- 0.4. When comparing the rates of oxidation of [4(S)-2H]NADPH and [4(S)-1H]NADPH, we measure kinetic isotope effects on V of 4.78 +/- 0.15 and on V/KNADPH of 4.54 +/- 0.59. When oxidation of [4(R)-2H]NADPH and [4(R)-1H]NADPH is compared, the secondary kinetic isotope effect on V is 1.04 +/- 0.01. When the NADPH-menadione oxidoreductase reaction is catalyzed in tritiated water, no incorporation of solvent tritium into residual NADPH is observed. We conclude from these observations that the oxidation of NADPH is largely or entirely rate limiting in the reductive half-reaction and, hence, in NADPH-menadione oxidoreductase turnover at saturating menadione concentration. In the presence of saturating NADPH, the flavin reduction proceeds with a rate constant of 160 S-1, which is at least 29-fold slower than estimates of the lower limit for the diffusion-limited rate constant characterizing NADPH binding to the enzyme under physiological conditions. Albery & Knowles have defined criteria for perfection in enzyme catalysis [Albery, W. J., & Knowles, J.R. (1976) Biochemistry 15, 5631-5640].(ABSTRACT TRUNCATED AT 250 WORDS)     

Remote nitrogen-15 isotope effects on addition of cyanide to NAD

The reversible reaction NAD + CN(-)----NAD-CN was examined for remote secondary 15N isotope effects caused by isotopic substitution at the ring nitrogen of the nicotinamide group. These were compared with analogous effects for dehydrogenase-catalyzed reactions, since both cyanide and the hydride ion add at the N-4 position of the nicotinamide ring. The 15N effects on the rate constants for the forward and reverse processes were examined directly by conducting both the normal and isotopic reactions simultaneously under carefully controlled conditions in the sample and reference cells of a dual-beam spectrophotometer. In both cases, the 15N kinetic isotope effect differed from 1.00 by considerably less than 0.01. The 15N equilibrium isotope effect, 15K, was obtained as the ratio of equilibrium constants measured separately with natural-abundance and labeled NAD by using a concentration jump procedure [1.004 +/- 0.002 (cyanide addition)]. A similar value for 15K of 1.010 +/- 0.008 was obtained in an analogous manner for the reaction catalyzed by lactate dehydrogenase: NAD + lactate----pyruvate + NADH + H+. The latter value is significantly smaller than a previously reported value obtained from kinetic studies [1.044 +/- 0.012; Cook, P. F., Oppenheimer, N. J., & Cleland, W. W. (1981) Biochemistry 20, 1817]. The present value also is smaller than might be expected for a change in bond order from 4 to 3 [Cleland, W. W. (1980) Methods Enzymol. 64, 104-125] on the basis of the canonical resonance structures for NAD and NADH.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of MgATP and MgADP on the cross-bridge kinetics of rabbit soleus slow-twitch muscle fibers.

The elementary steps surrounding the nucleotide binding step in the cross-bridge cycle were investigated with sinusoidal analysis in rabbit soleus slow-twitch muscle fibers. The single-fiber preparations were activated at pCa 4.40, ionic strength 180 mM, 20 degrees C, and the effects of MgATP (S) and MgADP (D) concentrations on three exponential processes B, C, and D were studied. Our results demonstrate that all apparent (measured) rate constants increased and saturated hyperbolically as the MgATP concentration was increased. These results are consistent with the following cross-bridge scheme: [cross-bridge scheme: see text] where A = actin, M = myosin, S = MgATP, and D = MgADP. AM+S is a collision complex, and AM*S is its isomerized form. From our studies, we obtained K0 = 18 +/- 4 mM-1 (MgADP association constant, N = 7, average +/- sem), K1a = 1.2 +/- 0.3 mM-1 (MgATP association constant, N = 8 hereafter), k1b = 90 +/- 20 s-1 (rate constant of ATP isomerization), k-1b = 100 +/- 9 s-1 (rate constant of reverse isomerization), K1b = 1.0 +/- 0.2 (equilibrium constant of isomerization), k2 = 21 +/- 3 s-1 (rate constant of cross-bridge detachment), k-2 = 14.1 +/- 1.0 s-1 (rate constant of reversal of detachment), and K2 = 1.6 +/- 0.3 (equilibrium constant of detachment). K0 is 8 times and K1a is 2.2 times those in rabbit psoas, indicating that nucleotides bind to cross-bridges more tightly in soleus slow-twitch muscle fibers than in psoas fast-twitch muscle fibers. These results indicate that cross-bridges of slow-twitch fibers are more resistant to ATP depletion than those of fast-twitch fibers. The rate constants of ATP isomerization and cross-bridge detachment steps are, in general, one-tenth to one-thirtieth of those in psoas.