Kinetics of the interaction of N-(phosphonacetyl)-L-aspartate with the catalytic subunit of aspartate transcarbamoylase. A slow conformational change subsequent to binding

The binding of the bisubstrate ligand N-(phosphonacetyl)-L-aspartate (PALA) to the active sites of both the free catalytic subunit of aspartate transcarbamoylase and the intact holoenzyme causes conformational changes which have been studied extensively. However, no kinetic information has been available about the sequence of events occurring during the formation or dissociation of the complexes. Stopped flow kinetics, 31P saturation transfer NMR spectroscopy, and presteady-state kinetics were used to monitor the interaction of PALA with the catalytic subunit (or a derivative containing nitrotyrosyl chromophores which served as spectral probes). The various experimental approaches lead to a mechanism that includes a rapid binding of PALA with an "on" rate of about 10(8)M-1s-1 and an "off" rate of 28 s-1, followed by a much slower isomerization of the complex with a forward rate constant of 0.18 s-1. Analysis of the presteady-state bursts of enzyme activity when the protein is added to a mixture of substrates and PALA and of the lag in activity when the PALA complex with catalytic subunit is added to substrates yielded a rate constant for the reverse isomerization of 0.018s-1. Thus, the conformational change subsequent to PALA binding leads to a 10-fold increase in the equilibrium constant for complex formation. Stopped flow kinetic measurements of the spectral change resulting from mixing the complex of PALA and nitrated protein with native enzyme showed a slow process with a t1/2 of about 11 s, whereas 31P saturation transfer NMR experiments yielded at t1/2 of about 260 ms for the dissociation of PALA from the complex. This apparent disparity is understood in terms of the two-step binding scheme where rapid dissociation of the initial ligand X enzyme complex is measured by the NMR technique and the slow isomerization of the complex is responsible for the bulk of the stopped flow signal.     

Effects of replacement of active site residue glutamine 231 on activity and allosteric properties of aspartate transcarbamoylase.

Since crystallographic studies on Escherichia coli aspartate transcarbamoylase (ATCase) indicate that Gln 231 is in the active site of the enzyme and participates in the binding of the substrate, aspartate, it seemed of interest to examine mutant enzymes in which Gln 231 was replaced by Asn or Ile. The two mutant forms containing amino acid substitutions were characterized by a combination of steady-state kinetics, hydrodynamic measurements, and equilibrium ligand binding techniques. Both mutant forms exhibited a dramatic reduction in the affinity of the protein for substrates and substrate analogues as well as a very large decrease in catalytic activity. Moreover, the amino acid substitutions introduced within the active site of the enzyme led to unusual allosteric properties in the mutant enzymes. Although the bisubstrate analogue N-(phosphonoacetyl)-L-aspartate promotes the characteristic global conformational change in the mutant forms that is observed with the wild-type enzyme, the combination of substrate and substrate analogue does not. Cooperativity with respect to substrate binding is largely reduced compared to wild-type ATCase. Also, the effector molecules ATP and CTP which bind to the regulatory chains have dramatic effects on the activity of the mutant enzymes containing replacements for Gln 231 in the catalytic chains. In stark contrast to the wild-type enzyme, in which effects of nucleotides are manifested primarily by changes in the K0.5 of the enzyme, ATP and CTP have large effects on the Vmax of the mutant enzymes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ionization of amino acid residues involved in the catalytic mechanism of aspartate transcarbamoylase.

The chemical and kinetic mechanisms of the reaction catalyzed by the catalytic trimer of aspartate transcarbamoylase have been examined. The variation of the kinetic parameters with pH indicated that at least four ionizing amino acid residues are involved in substrate binding and catalysis. The pH dependence of K(ia) for carbamoyl phosphate and the K(i) for N-(phosphonoacetyl)-L- aspartate revealed that a protonated residue with a pK value of 9.0 is required for the binding of carbamoyl phosphate. However, the variation with pH of K(i) for succinate, a competitive inhibitor of aspartate, and for cysteine sulfinate, a slow substrate, showed that a single residue with a pK value of 7.3 must be protonated for binding these analogues and, by inference, aspartate. The profile of log V against pH displayed a decrease in reaction rate at low and high pH, suggesting that two groups associated with the Michaelis complex, a deprotonated residue with a pK value of 7.2 and a protonated group with a pK value of 9.5, are involved in catalysis. By contrast, the catalytically productive form of the enzyme-carbamoyl phosphate complex, as illustrated in the bell-shaped pH dependence of log (V/K)(asp), is one in which a residue with a pK value of 7.0 must be protonated while a group with a pK value of 9.1 is deprotonated. This interpretation is supported by the results from the temperature dependence of the V and V/K profiles and from the pH dependence of pK(i) for the aspartate analogues.(ABSTRACT TRUNCATED AT 250 WORDS)     

13C isotope effects as a probe of the kinetic mechanism and allosteric properties of Escherichia coli aspartate transcarbamylase.

13C kinetic isotope effects have been measured in carbamyl phosphate for the reaction catalyzed by aspartate transcarbamylase. For the holoenzyme, the value was 1.0217 at zero aspartate, but unity at infinite aspartate, with 4.8 mM aspartate eliminating half of the isotope effect. This pattern proves an ordered kinetic mechanism, with carbamyl phosphate adding before aspartate. The same parameters were observed in the presence of ATP or CTP, showing that there is only one form of active enzyme present, regardless of the presence or absence of allosteric modifiers. These data support the Monod model of allosteric behavior in which the equilibrium between fully active and inactive enzyme is perturbed by selective binding interactions of substrates and modifiers, and there are no enzyme forms having partial activity. Isolated catalytic subunits of the enzyme showed similar 13C isotope effects (1.0240 at zero aspartate, 1.0039 at infinite aspartate, 3.8 mM aspartate causing half of the change from one value to the other), but the finite isotope effect at infinite aspartate shows that the kinetic mechanism is now partly random. With the very slow and poorly bound aspartate analog cysteine sulfinate, the 13C isotope effects were 1.039 for both holoenzyme and catalytic subunits and were not decreased significantly by high levels of cysteine sulfinate. The value of 1.039 is probably close to the intrinsic isotope effect on the chemical reaction, while the kinetic mechanism with this substrate is now fully random because the chemistry is so much slower than release of either reactant from the enzyme.     

The contribution of threonine 55 to catalysis in aspartate transcarbamoylase.

Heavy-atom isotope effects and steady-state kinetic parameters were measured for the catalytic trimer of an active site mutant of aspartate transcarbamoylase, T55A, to assess the role of Thr 55 in catalysis. The binding of carbamoyl phosphate to the T55A mutant was decreased by 2 orders of magnitude relative to the wild-type enzyme whereas the affinities for aspartate and succinate were not markedly altered. This indicates that Thr 55 plays a significant role in the binding of CbmP. If, as had been suggested previously, Thr 55 assists in the polarization of the carbonyl group of CbmP, the carbon isotope effect for the T55A mutant should increase relative to that observed for the wild-type enzyme. However, the opposite is seen, indicating that Thr 55 is not involved in stabilizing the oxyanion in the transition state. Quantitative analysis of a series of 13C and 15N isotope effects suggested that the rate-determining step in the reaction catalyzed by T55A trimer may be a conformational change in the protein subsequent to formation of the Michaelis complex. Thus, Thr 55 may facilitate a conformational change in the enzyme that is a prerequisite for catalysis. An altered active site environment in the binary and Michaelis complexes with T55A trimer is reflected in the pH profiles for log V, log (V/K)asp, and pK(i) succinate, show a displacement in the pK values of ionizing residues involved in aspartate binding and catalysis relative to the wild-type enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

A 70-amino acid zinc-binding polypeptide fragment from the regulatory chain of aspartate transcarbamoylase causes marked changes in the kinetic mechanism of the catalytic trimer.

Interaction between a 70-amino acid and zinc-binding polypeptide from the regulatory chain and the catalytic (C) trimer of aspartate transcarbamoylase (ATCase) leads to dramatic changes in enzyme activity and affinity for active site ligands. The hypothesis that the complex between a C trimer and 3 polypeptide fragments (zinc domain) is an analog of R state ATCase has been examined by steady-state kinetics, heavy-atom isotope effects, and isotope trapping experiments. Inhibition by the bisubstrate ligand, N-(phosphonacetyl)-L-aspartate (PALA), or the substrate analog, succinate, at varying concentrations of substrates, aspartate, or carbamoyl phosphate indicated a compulsory ordered kinetic mechanism with carbamoyl phosphate binding prior to aspartate. In contrast, inhibition studies on C trimer were consistent with a preferred order mechanism. Similarly, 13C kinetic isotope effects in carbamoyl phosphate at infinite aspartate indicated a partially random kinetic mechanism for C trimer, whereas results for the complex of C trimer and zinc domain were consistent with a compulsory ordered mechanism of substrate binding. The dependence of isotope effect on aspartate concentration observed for the Zn domain-C trimer complex was similar to that obtained earlier for intact ATCase. Isotope trapping experiments showed that the compulsory ordered mechanism for the complex was attributable to increased "stickiness" of carbamoyl phosphate to the Zn domain-C trimer complex as compared to C trimer alone. The rate of dissociation of carbamoyl phosphate from the Zn domain-C trimer complex was about 10(-2) that from C trimer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Association of the catalytic subunit of aspartate transcarbamoylase with a zinc-containing polypeptide fragment of the regulatory chain leads to increases in thermal stability.

The regulatory enzyme aspartate transcarbamoylase (ATCase), comprising 2 catalytic (C) trimers and 3 regulatory (R) dimers, owes its stability to the manifold interchain interactions among the 12 polypeptide chains. With the availability of a recombinant 70-amino acid zinc-containing polypeptide fragment of the regulatory chain of ATCase, it has become possible to analyze directly the interaction between catalytic and regulatory chains in a complex of simpler structure independent of other interactions such as those between the 2 C trimers, which also contribute to the stability of the holoenzyme. Also, the effect of the interaction between the polypeptide, termed the zinc domain, and the C trimer on the thermal stability and other properties can be measured directly. Differential scanning microcalorimetry experiments demonstrated that the binding of the zinc domain to the C trimer leads to a complex of markedly increased thermal stability. This was shown with a series of mutant forms of the C trimer, which themselves varied greatly in their temperature of denaturation due to single amino acid replacements. With some C trimers, for which tm varied over a range of 30 degrees C due to diverse amino acid substitutions, the elevation of tm resulting from the interaction with the zinc domain was as large as 18 degrees C. The values of tm for a variety of complexes of mutant C trimers and the wild-type zinc domain were similar to those observed when the holoenzymes containing the mutant C trimers were subjected to heat denaturation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Peptide-protein interaction markedly alters the functional properties of the catalytic subunit of aspartate transcarbamoylase.

Interaction of a 70-amino acid zinc-binding polypeptide from the regulatory chain of aspartate transcarbamoylase (ATCase) with the catalytic (C) subunit leads to dramatic changes in enzyme activity and affinity for ligand binding at the active sites. The complex between the polypeptide (zinc domain) and wild-type C trimer exhibits hyperbolic kinetics in contrast to the sigmoidal kinetics observed with the intact holoenzyme. Moreover, the Scatchard plot for binding N-(phosphonacetyl)-L-aspartate (PALA) to the complex is linear with a Kd corresponding to that evaluated for the holoenzyme converted to the relaxed (R) state. Additional evidence that the binding of the zinc domain to the C trimer converts it to the R state was attained with a mutant form of ATCase in which Lys 164 in the catalytic chain is replaced by Glu. As shown previously (Newell, J.O. & Schachman, H.K., 1990, Biophys. Chem. 37, 183-196), this mutant holoenzyme, which exists in the R conformation even in the absence of active site ligands, has a 50-fold greater affinity for PALA than the free C subunit. Adding the zinc domain to the C trimer containing the Lys 164-->Glu substitution leads to a 50-fold enhancement in the affinity for the bisubstrate analog yielding a value of Kd equal to that for the holoenzyme. A different mutant ATCase containing the Gln 231 to Ile replacement was shown (Peterson, C.B., Burman, D.L., & Schachman, H.K., 1992, Biochemistry 31, 8508-8515) to be much less active as a holoenzyme than as the free C trimer. For this mutant holoenzyme, the addition of substrates does not cause its conversion to the R state. However, the addition of the zinc domain to the Gln 231-->Ile C trimer leads to a marked increase in enzyme activity, and PALA binding data indicate that the complex resembles the R state of the holoenzyme. This interaction leading to a more active conformation serves as a model of intergenic complementation in which peptide binding to a protein causes a conformational correction at a site remote from the interacting surfaces resulting in activation of the protein. This linkage was also demonstrated by difference spectroscopy using a chromophore covalently bound at the active site, which served as a spectral probe for a local conformational change. The binding of ligands at the active sites was shown also to lead to a strengthening of the interaction between the zinc domain and the C trimer.     

Differential scanning calorimetry of asparate transcarbamoylase and its isolate subunits.

The thermal denaturation of aspartate transcarbamoylas of Escherichia coli was investigated by differential scanning calorimetry. Isolated regulatory and catalytic subunits were heat denatured at 55 and 80 degrees C, respectively. In contrast, the intact enzyme was denatured in two steps. A small endotherm near 73 degrees C was assoicated with denaturation of the regulatory subunits and the major endotherm at 82 degrees C with denaturation of the catalytic subunits. Thus regulatory subunits are stabilized against heat denaturation by more than 17 degrees C when incorporated in the enzyme. Similar conclusions were obtained from measurements of the enthalpy of heat denaturation. Regulatory subunits yielded a much lower value of the enthalpy of denaturation, 1.91 cal/g, than that found for the catalytic subunit, 3.94 cal/g, or typical globular proteins (4 to 6 cal/g). When the regulatory subunits were incorporated into aspartate transcarbamoylase their enthalpy of denaturation was increased 125% (to 4.3 cal/g). The enthalpy of the catalytic subunits in the intact enzyme was increased 38% (enthalpy of denaturation of 5.43 cal/g). Stabilization of the isolated catalytic subunit as well as the intact enzyme was achieved by the addition of the bisubstrate analog N-(phosphonacetyl)-L-aspartate. Similarly the allosteric effectors, CTP and ATP, stabilized the isolated regulatory subunits or those subunits within the intact enzyme. However, the addition of the bisubstrate analog caused a decrease in the enthalpy of denaturation of the regulatory subunits within the enzyme. These results are consistent with other studies of the ligand-promoted conformational changes in the native enzyme.