Towards the mechanism of trimeric purine nucleoside phosphorylases: stopped-flow studies of binding of multisubstrate analogue inhibitor - 2-amino-9-[2-(phosphonomethoxy)ethyl]-6-sulfanylpurine

The binding of multisubstrate analogue inhibitor - 2-amino-9-[2-(phosphonomethoxy)ethyl]-6-sulfanylpurine (PME-6-thio-Gua) to purine nucleoside phosphorylase from Cellulomonas sp. at 20 degrees C, in 20 mM Hepes buffer with ionic strength adjusted to 50 mM using KCl, at several pH values between 6.5 and 8.2, was investigated using a stopped-flow spectrofluorimeter. The kinetic transients registered after mixing a protein solution with ligand solutions of different concentrations were simultaneously fitted by several association reaction models using nonlinear least-squares procedure based on numerical integration of the chemical kinetic equations appropriate for given model. It is concluded that binding of a PME-6-thio-Gua molecule by each of the binding sites is sufficiently well described by one-step process, with a model assuming interacting binding sites being more probable than a model assuming independent sites. The association rate constants derived from experimental data, assuming one step binding and independent sites, are decreasing with an increase in pH, changing from 30 to 6 microM(-1)s(-1) per binding site. The dissociation rate constants are in the range of 1-3 s(-1), and they are rather insensitive of changes in pH. Interestingly, for each pH value, the one-step binding model with interacting sites results in the association rate constant per site 1.5-4 times smaller for the binding of the first ligand molecule than that for the binding of the second one. Decrease of association constants with pH indicate that the enzyme does not prefer binding of the naturally occurring anionic form of the 6-thioguanine ring (pK(a) 8.7) resulting from a dissociation of N(1)-H. This finding supports the mechanism in which hydrogen bond interaction of N(1)-H with Glu204 (Glu 201 in mammalian PNPs) is crucial in the catalytic process. Results obtained also indicate that, in contrast to transition-state analogues, for which binding is followed by a conformational change, binding of multisubstrate analogue inhibitors to trimeric PNPs is a one-step process.     

Stopped-flow studies of guanine binding by calf spleen purine nucleoside phosphorylase

The binding of guanine to calf spleen purine nucleoside phosphorylase at 20 degrees C, in 20 mM Hepes-NaOH buffer, pH 7.0, at several ionic strength between 5 and 150 mM was investigated using a stopped-flow spectrofluorimeter. The kinetic transients registered after mixing a protein solution with ligand solutions of different concentrations were simultaneously fitted by several association reaction models using nonlinear least-squares procedure based on numerical integration of the chemical kinetic equations appropriate for given model. It is concluded that binding of a guanine molecule by each of the binding sites is a two-step process and that symmetrical trimeric calf spleen purine nucleoside phosphorylase represents a system of (identical) interacting binding sites. The interaction is visible through relations between the rate constants and non-additivity of changes in "molar" fluorescence for different forms of PNP-guanine complexes. It is also probable that electrostatic effects in guanine binding are weak, which indicates that it is the neutral form of the ligand which is bound and dissociated by PNP molecule.     

Construction and evaluation of the kinetic scheme associated with dihydrofolate reductase from Escherichia coli

A kinetic scheme is presented for Escherichia coli dihydrofolate reductase that predicts steady-state kinetic parameters and full time course kinetics under a variety of substrate concentrations and pHs. This scheme was derived from measuring association and dissociation rate constants and pre-steady-state transients by using stopped-flow fluorescence and absorbance spectroscopy. The binding kinetics suggest that during steady-state turnover product dissociation follows a specific, preferred pathway in which tetrahydrofolate (H4F) dissociation occurs after NADPH replaces NADP+ in the ternary complex. This step, H4F dissociation from the E X NADPH X H4F ternary complex, is proposed to be the rate-limiting step for steady-state turnover at low pH because koff = VM. The rate constant for hydride transfer from NADPH to dihydrofolate (H2F), measured by pre-steady-state transients, has a deuterium isotope effect of 3 and is rapid, khyd = 950 s-1, essentially irreversible, Keq = 1700, and pH dependent, pKa = 6.5, reflecting ionization of a single group in the active site. This scheme accounts for the apparent pKa = 8.4 observed in the steady state as due to a change in the rate-determining step from product release at low pH to hydride transfer above pH 8.4. This kinetic scheme is a necessary background to analyze the effects of single amino acid substitutions on individual rate constants.     

Diffusion-controlled association of a dye, 1-anilinonaphthalene-8-sulfonic acid, to a protein, bovine serum albumin, using a fast-flow microsecond mixer and stopped-flow

The kinetic constants of the two fastest reactions of 1-anilinonaphthalene-8-sulfonic acid binding to bovine serum albumin are derived from the results of experiments with a microsecond fast-flow mixing technique and a stopped-flow method. The experiments are interpreted in terms of rapid bimolecular diffusion-controlled associations to two independent regions on the protein surface; this reaction mechanism contrasts with previous kinetic studies of ligand binding to bovine serum albumin which have not demonstrated the fastest kinetic processes.     

Kinetic and thermodynamic analysis of 9-cis-retinoic acid binding to retinoid X receptor alpha.

The interaction of retinoid X receptor alpha with 9-cis-retinoic acid was studied using stopped-flow fluorescence spectroscopy. Transient kinetic analyses of this interaction suggest a two-step binding mechanism involving a rapid, enthalpically driven pre-equilibrium followed by a slower, entropically driven reaction that may arise from a conformational change within the ligand binding domain of the receptor. The assignment of this kinetic mechanism was supported by agreement between the overall equilibrium constant, Kov, derived from kinetic studies with that determined by equilibrium fluorescence titrations. Although these analyses do not preclude ligand-induced alteration in the oligomerization state of the receptor in solution, the simplest model that can be applied to these data involves the stoichiometric interaction of 9-cis-retinoic acid with retinoid X receptor alpha monomers.     

Stopped-Flow Kinetic Studies of the Interaction of Bovine Folate Binding Protein (FBP) and Folate

The kinetics of the interaction of bovine folate binding protein and folate at pH 7.4 and 5.0 were followed by measuring the changes of the intrinsic protein fluorescence intensity using the stopped-flow technique, which enables the study of reactions from the millisecond time-range. Our results immediately reject a simple one-step binding model, which requires a linear dependence of the observed rate constant on the concentration of the ligand. Thus, we are able to conclude that at pH 5.0 the interaction occurs in two steps and at pH 7.4 in three steps. Changes of fluorescence spectra at equilibrium were used to estimate the overall binding constants. Comparative studies on the binding of folate to human albumin are also reported.     

A procedure for analysis of stopped-flow transients for protein-ligand association

A method for extracting kinetic and optical parameters from progress curves for protein-ligand association, obtained by stopped-flow experiments, is described. The method is limited to one-step and two-step association kinetics, but it allows concentration of protein and offset of the signals to be adjustable parameters during an interactive non-linear least-squares fitting procedure. The method is tested on simulated pseudo-experimental data and applied to progress curves obtained in a stopped-flow spectrofluorimeter, for association of the translation initiation factor eIF4E with 7-methyl-GDP, an analog of 5'-end of mRNA.     

Enthalpic barriers to the hydrophobic binding of oligosaccharides to phage P22 tailspike protein

The structural thermodynamics of the recognition of complex carbohydrates by proteins are not well understood. The recognition of O-antigen polysaccharide by phage P22 tailspike protein is a highly suitable model for advancing knowledge in this field. The binding to octa- and dodecasaccharides derived from Salmonella enteritidis O-antigen was studied by isothermal titration calorimetry and stopped-flow spectrofluorimetry. At room temperature, the binding reaction is enthalpically driven with an unfavorable change in entropy. A large change of -1.8 +/- 0.2 kJ mol(-1) K(-1) in heat capacity suggests that the hydrophobic effect and water reorganization contribute substantially to complex formation. As expected from the large heat-capacity change, we found enthalpy-entropy compensation. The calorimetrically measured binding enthalpies were identical within error to van't Hoff enthalpies determined from fluorescence titrations. Binding kinetics were determined at temperatures ranging from 10 to 30 degrees C. The second-order association rate constant varied from 1 x 10(5) M(-1) s(-1) for dodecasaccharide at 10 degrees C to 7 x 10(5) M(-1) s(-1) for octasaccharide at 30 degrees C. The first-order dissociation rate constants ranged from 0.2 to 3.8 s(-1). The Arrhenius activation energies were close to 50 and 100 kJ mol(-1) for the association and dissociation reactions, respectively, indicating mainly enthalpic barriers. Despite the fact that this system is quite complex due to the flexibility of the saccharide, both the thermodynamic and kinetic data are compatible with a simple one-step binding model.     

The kinetic mechanism of wild-type and mutant mouse dihydrofolate reductases

A kinetic mechanism is presented for mouse dihydrofolate reductase that predicts all the steady-state parameters and full time-course kinetics. This mechanism was derived from association and dissociation rate constants and pre-steady-state transients by using stopped-flow fluorescence and absorbance measurements. The major features of this kinetic mechanism are as follows: (1) the two native enzyme conformers, E1 and E2, bind ligands with varying affinities although only one conformer, E1, can support catalysis in the forward direction, (2) tetrahydrofolate dissociation is the rate-limiting step under steady-state turnover at low pH, and (3) the pH-independent rate of hydride transfer from NADPH to dihydrofolate is fast (khyd = 9000 s-1) and favorable (Keq = 100). The overall mechanism is similar in form to the Escherichia coli kinetic scheme (Fierke et al., 1987), although several differences are observed: (1) substrates and products predominantly bind the same form of the E. coli enzyme, and (2) the hydride transfer rate from NADPH to either folate or dihydrofolate is considerably faster for the mouse enzyme. The role of Glu-30 (Asp-27 in E. coli) in mouse DHFR has also been examined by using site-directed mutagenesis as a potential source of these differences. While aspartic acid is strictly conserved in all bacterial DHFRs, glutamic acid is conserved in all known eucaryotes. The two major effects of substituting Asp for Glu-30 in the mouse enzyme are (1) a decreased rate of folate reduction and (2) an increased rate of hydride transfer from NADPH to dihydrofolate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Chain non-equivalence in nitric oxide binding to hemoglobin

The ratio of the apparent rates of ligand binding to the α and β subunits of human hemoglobin on mixing with non-saturating amounts of nitric oxide has been measured by two independent methods. Electron spin resonance measurements permit direct determination of the ratio of the amounts of the respective chains bound by NO. In stopped-flow kinetics measurements, use was made of the known difference in the kinetic constants of α and β chains in hemoglobin in the reaction with n-butyl isocyanide. Both methods concur in indicating that the apparent association rate constant of NO is greater for the α than for the β chain.     

Homeostasis in mRNA initiation: wheat germ poly(A)-binding protein lowers the activation energy barrier to initiation complex formation

Previous kinetic binding studies of wheat germ protein synthesis eukaryotic initiation factor iso4F (eIFiso4F) and its subunit, eIF4E, with m(7)GTP and mRNA analogues indicated that binding occurred by a two-step process with the first step being too fast to measure by stopped-flow techniques (). Further equilibrium studies showed that poly(A)-binding protein (PABP) enhanced the cap binding of eIFiso4F about 40-fold. The kinetic effects of PABP on cap binding and the temperature dependence of this reaction were measured and compared. Fluorescence stopped-flow studies of the PABP.eIFiso4F protein complex with cap show a concentration-independent conformational change. PABP did not significantly increase the rate of the conformational change, and because the initial second-order binding is essentially diffusion-controlled, the enhancement of cap affinity must reside in the dissociation rate. The dissociation rate was more than 5-fold slower in the presence of PABP. The temperature dependence of the cap binding reaction was markedly reduced in the presence of PABP. The reduced energy barrier for formation of a cap.eIFiso4F complex suggests a more stable platform for further initiation complex formation and a possible means of adapting to varying temperature conditions.     

Multiple transients in the pre-steady-state of nucleoside hydrolase reveal complex substrate binding, product base release, and two apparent rates of chemistry

We have investigated the transient kinetics of the nucleoside hydrolase from Trypanosoma vivax (TvNH) at low temperatures (5 degrees C). Three novel absorbance transients (termed tau1, tau3, and tau4) were detected during multiple-guanosine turnover stopped-flow absorbance spectroscopy, in addition to a transient (tau2) that had been observed previously at 35 degrees C. At 5 degrees C, TvNH displays full-sites activity and not half-of-the-sites activity as is apparent at 35 degrees C. Both tau1 and tau2 are assigned to chemistry based on rapid-quench results. For tau1, the rate of chemistry is ca. 3000-fold faster than kcat (1-2 orders of magnitude greater than previous estimates). The pH dependencies of the burst amplitudes for tau1 and tau2 indicate that these transients arise from the formation of two different dimeric TvNH.substrate complexes and not from TvNH that contains kinetically asymmetric monomers. The saturating burst rates for tau1 and tau2 are surprisingly pH-independent, given the prominent role of acid-base chemistry in the proposed mechanism for TvNH. tau3 and tau4 are assigned to the substrate binding and base release processes, respectively, and shown to be equivalent to two fluorescence transients (tau3 and tau4, respectively) observed previously by stopped-flow methods at 35 degrees C. The rate of base release is shown to be an apparent rate. Together with steady-state product inhibition results, the data indicate that TvNH follows an ordered uni-bi kinetic mechanism with a TvNH.base dead-end complex, and not the rapid equilibrium random uni-bi mechanism proposed for other NHs. Two applicable kinetic models are presented and their implications for future mechanistic studies discussed.     

SRC tail phosphorylation is limited by structural changes in the regulatory tyrosine kinase Csk

Src family tyrosine kinases are down-regulated through phosphorylation of a single C-terminal tyrosine by the nonreceptor tyrosine kinase Csk. Despite the fundamental role of Csk in controlling cell growth and differentiation, it is unclear what limits this key signaling reaction and controls the production of catalytically repressed Src. To investigate this issue, stopped-flow fluorescence experiments were performed to determine which steps modulate catalysis. Both Src binding and phosphorylation can be monitored by changes in intrinsic tryptophan fluorescence. Association kinetics are biphasic with the initial phase corresponding to the bimolecular interaction of both proteins and the second phase representing a slow conformational change that coincides with the rate of maximum turnover. The kinetic transients for the phosphorylation reaction are also biphasic with the initial phase corresponding to the rapid phosphorylation and the release of phospho-Src. These data, along with equilibrium sedimentation and product inhibition experiments, suggest that steps involving Src association, phosphorylation, and product release are fast and that a structural change in Csk participates in limiting the catalytic cycle.     

The mechanism of binding of dihydropyridine calcium channel blockers to rat brain membranes

Detailed kinetic and equilibrium studies of the binding of two radiolabeled 1,4-dihydropyridine calcium antagonists to putative calcium channels in rat brain membranes were performed. (+/-)-[3H]Nitrendipine, a racemic ligand, and (+)-[3H]isopropyl 4-(2,1,3-benzoxadiazol-4-yl)-1, 4-dihydro-2,6-dimethyl-5-methoxycarbonylpyridine-3-carboxylate (PN200-110), a pure isomer, were used and their binding properties were quantitated and compared. Analysis of equilibrium binding revealed a single high affinity component for each radioligand with the same density of binding sites for both ligands. Association rates were determined over a 60-fold range of concentration of each radioligand. For both radioligands, the pseudo-first order association time courses were biphasic with the rate of the faster component dependent on radioligand concentration and the rate of the slower component independent of both the structure of the radioligand and the concentration of the radioligand. Dissociation rates were determined after various times of association. The dissociation of the optically pure radioligand, (+)-[3H]PN200-110, was monophasic at all association times, consistent with a single bound species being present throughout association. However, (+/-)-[3H]nitrendipine dissociation was biphasic after short association times (1-10 min). The biphasic dissociation observed with (+/-)-[3H]nitrendipine is consistent with the two optical isomers binding with approximately the same association rate but having different dissociation rates. These results appear to reflect the existence of two interconvertible binding states of the putative calcium channel in the membrane, one which binds the radioligands with high affinity in a simple bimolecular reaction and one which has no detectable affinity for the ligands. This mechanism of isomerization before ligand binding has been modeled by numerical solution of the differential equations of the scheme providing estimates of the rate constants for each reaction in the scheme.     

Activation of Escherichia coli pyruvate oxidase enhances the oxidation of hydroxyethylthiamin pyrophosphate

The catalytic efficiency (kcat/Km) of Escherichia coli flavin pyruvate oxidase can be stimulated 450-fold either by the addition of lipid activators or by limited proteolytic hydrolysis. Previous studies have shown that a functional lipid binding site is a mandatory prerequisite for the in vivo functioning of this enzyme (Grabau, C., and Cronan, J. E., Jr. (1986) Biochemistry 25, 3748-3751). The effect of activation on the transient state kinetics of partial reactions in the overall oxidative conversion of pyruvate to acetate and CO2 has now been examined. The rate of decarboxylation of pyruvate to form CO2 and hydroxyethylthiamin pyrophosphate for both activated and unactivated forms of the enzyme is identical within experimental error. The decarboxylation step was measured using substrate concentrations of the enzyme in the absence of an electron acceptor. The pseudo-first order rate constant for the decarboxylation step is 60-80 s-1. The rate of oxidation of hydroxyethylthiamin pyrophosphate and concomitant enzyme-bound flavin reduction was analyzed by stopped-flow methods utilizing synthetic hydroxyethylthiamin pyrophosphate. The pseudo-first order rate for this step with unactivated enzyme was 2.85 s-1 and increased 145-fold for lipid-activated enzyme to 413 s-1 and 61-fold for the proteolytically activated enzyme to 173 s-1. The analysis of a third reaction step, the reoxidation of enzyme-bound FADH, was also investigated by stopped-flow techniques utilizing ferricyanide as the electron acceptor. The rate of oxidation of enzyme.FADH is very fast for both unactivated (1041 s-1) and activated enzyme (645 s-1). The data indicate that the FAD reduction step is the rate-limiting step in the overall reaction for unactivated enzyme. Alternatively, the rate-limiting step in the overall reaction with the activated enzyme shifts to one of the partial steps in the decarboxylation reaction.     

Kinetics of binding of multisubstrate analogue inhibitor (2-amino-9-[2-(phosphonomethoxy)ethyl]-6-sulfanylpurine) with trimeric purine nucleoside phosphorylase

Complex formation of multisubstrate analogue inhibitor--2-amino-9-[2-(phosphonomethoxy)ethyl]-6-sulfanylpurine (PME-6-thio-Gua) with trimeric purine nucleoside phosphorylase from Cellulomonas sp. was investigated using a stopped-flow spectrofluorimetric approach. Results obtained indicate that, in contrast to binding of guanine, i.e., the transition-state conformation trapping ligand, for which binding at each active site is followed by the enzyme conformational change, association of the ground-state analogue PME-6-thio-Gua is a one-step process.     

Stopped-flow fluorescence studies on saccharide binding to lysozyme.

The binding of the beta-1-4-linked trimer of N-acetyl-D-glucosamine to hen egg-white lysozyme was studied by rapid-reaction-kinetic methods with tryptophyl fluorescence observation of the transients. It was found that discrete segments of the fluorescence-difference spectrum from this reaction were perturbed at different time-points during the binding process. The results were interpretated as the formation of the initial complex, the fast phase of the reaction, perturbing the environment of tryptophan-62 and a subsequent and slower rearrangement of the initial complex perturbing the environment of tryptophan-108. At pH 4.4, the release of protons from aspartate-101 occurred during the rearrangement step of the binding reaction. A model for the reaction is presented (E, enzyme; L, ligand): (see article) The association of this ligand with lysozyme may be visualized in three-dimensional terms as initial complex-formation across the top of the active-site cleft followed by a diving motion of the ligand into the cleft.     

Kinetic model of protein-mediated ligand transport: influence of soluble binding proteins on the intermembrane diffusion of a fluorescent fatty acid

The mechanism (or mechanisms) whereby fatty acids and other amphipathic compounds are transported from the plasma membrane to intracellular sites of biotransformation remains poorly defined. In an attempt to better characterize the role of cytosolic binding proteins in this process, a kinetic model of intermembrane ligand transport was developed in which diffusional transfer of ligand between membrane and protein is assumed. The model was tested by utilizing stopped-flow techniques to monitor the transfer of the fluorescent fatty acid analogue, 12-anthroyloxy stearate (12-AS), between model membrane vesicles. Studies were conducted in the presence or absence of bovine serum albumin (BSA), liver fatty acid-binding protein (L-FABP), and intestinal fatty acid-binding protein (I-FABP) in order to determine the effect of soluble proteins on the rate of intermembrane ligand transfer. As predicted by the model, the initial velocity of 12-AS arrival at the acceptor membrane increases in an asymptotic manner with the acceptor concentration. Furthermore, probe transfer velocity was found to decline asymptotically with increasing concentrations of BSA or L-FABP, proteins that exhibit diffusional transfer kinetics. This observation was found to hold true independent of whether donor or acceptor vesicles were preequilibrated with the protein. In contrast, 12-AS transfer velocity exhibited a linear correlation with the concentration of I-FABP, a protein that is thought to transport fatty acids, at least in part, via a collisional mechanism. Taken together, these findings validate the derived kinetic model of protein-mediated ligand transport and further suggest that the mechanism of ligand-protein interaction is a key determinant of the effect of cytosolic proteins on intracellular ligand diffusion.