Coupling of homotropic and heterotropic interactions in Escherichia coli aspartate transcarbamylase

Solution NMR Spectroscopy for the Study of Enzyme Allostery

Allostery is a ubiquitous biological regulatory process in which distant binding sites within a protein or enzyme are functionally and thermodynamically coupled. Allosteric interactions play essential roles in many enzymological mechanisms, often facilitating formation of enzyme-substrate complexes and/or product release. Thus, elucidating the forces that drive allostery is critical to understanding the complex transformations of biomolecules. Currently, a number of models exist to describe allosteric behavior, taking into account energetics as well as conformational rearrangements and fluctuations. In the following Review, we discuss the use of solution NMR techniques designed to probe allosteric mechanisms in enzymes. NMR spectroscopy is unequaled in its ability to detect structural and dynamical changes in biomolecules, and the case studies presented herein demonstrate the range of insights to be gained from this valuable method. We also provide a detailed technical discussion of several specialized NMR experiments that are ideally suited for the study of enzymatic allostery.

Methyl groups as probes of supra-molecular structure, dynamics and function

The development of new protein labeling strategies, along with optimized experiments that exploit the label, have significantly impacted on the types of biochemical problems that can now be addressed by solution NMR spectroscopy. Here we describe how methyl labeling of key residues in a highly deuterated protein background has facilitated studies of the structure, dynamics and interactions of supra-molecular particles. The methyl-labeling approach is briefly reviewed, followed by a summary of applications to three different molecular machines so as to illustrate the types of questions that can now be addressed. Areas where future innovations will lead to yet further improvements are highlighted as well.

Application of methyl-TROSY NMR to test allosteric models describing effects of nucleotide binding to aspartate transcarbamoylase

Aspartate transcarbamoylase has emerged as a textbook example of an allosteric enzyme whose binding of active-site substrates can be explained on the basis of the classical Monod-Wyman-Changeux (MWC) model of allostery. There is still debate, however, regarding the mode of action of ATP and cytidine triphosphate (CTP)--allosteric effectors that bind at regulatory sites 60 A away from the nearest active site. A large body of data for nucleotide binding is consistent with the MWC model, including a previous NMR study showing a shift in the allosteric equilibrium between R and T states that is predicted by this scheme. The possibility of binding-promoted changes to the structures of the active sites, while not within the framework of the MWC model, cannot be excluded, however. Here, the effects of binding of nucleotides are monitored in a series of (1)H-(13)C methyl transverse relaxation optimized spectroscopy spectra recorded on the 300-kDa aspartate transcarbamoylase holoenzyme in both the absence and the presence of saturating amounts of ATP or CTP. No changes in shifts of methyl probes of the catalytic chains (c-chains) that include the active sites are observed, consistent with a lack of structural changes. In addition, methyl (1)H-(13)C residual dipolar couplings are measured that are exquisitely sensitive to methyl axis orientations, and correlations between couplings measured on samples with and without nucleotide show no changes in structure of the c-chains. These results indicate that the mechanism of action of ATP and CTP can be explained fully by the MWC model and that any scheme invoking structural changes of the c-chains is not correct.

A solution NMR study showing that active site ligands and nucleotides directly perturb the allosteric equilibrium in aspartate transcarbamoylase

The 306-kDa aspartate transcarbamoylase is a well studied regulatory enzyme, and it has emerged as a paradigm for understanding allostery and cooperative binding processes. Although there is a consensus that the cooperative binding of active site ligands follows the Monod-Wyman-Changeux (MWC) model of allostery, there is some debate about the binding of effectors such as ATP and CTP and how they influence the allosteric equilibrium between R and T states of the enzyme. In this article, the binding of substrates, substrate analogues, and nucleotides is studied, along with their effect on the R-T equilibrium by using highly deuterated, (1)H,(13)C-methyl-labeled protein in concert with methyl-transverse relaxation optimized spectroscopy (TROSY) NMR. Although only the T state of the enzyme can be observed in spectra of wild-type unliganded aspartate transcarbamoylase, binding of active-site substrates shift the equilibrium so that correlations from the R state become visible, allowing the equilibrium constant (L') between ligand-saturated R and T forms of the enzyme to be measured quantitatively. The equilibrium constant between unliganded R and T forms (L) also is obtained, despite the fact that the R state is "invisible" in spectra, by means of an indirect process that makes use of relations that emerge from the fact that ligand binding and the R-T equilibrium are linked. Titrations with MgATP unequivocally establish that its binding directly perturbs the R-T equilibrium, consistent with the Monod-Wyman-Changeux model. This study emphasizes the utility of modern solution NMR spectroscopy in understanding protein function, even for systems with aggregate molecular masses in the hundreds of kilodaltons.

T-State Active Site of Aspartate Transcarbamylase: Crystal Structure of the Carbamyl Phosphate and l-Alanosine Ligated Enzyme,

An X-ray diffraction study to 2.0 A resolution shows that this enzyme, ATCase, is in the T-state (the c3 to c3 distance is 45.2 A) when ATCase is bound to carbamyl phosphate (CP) and to L-alanosine (an analogue of aspartate). This result strongly supports the kinetic results that alanosine did not inhibit the carbamylation of aspartate in the normal reaction of native ATCase plus CP and aspartate [Baillon, J., Tauc, P., and Hervé, G. (1985) Biochemistry 24, 7182-7187]. The structure further reveals that the phosphate of CP is 4 A away from its known position in the R-state and is in the T-state position of P(i) in a recent study of ATCase complexed with products, phosphate (P(i)) and N-carbamyl-L-aspartate [Huang, J., and Lipscomb, W. N. (2004) Biochemistry 43, 6422-6426]. Moreover, the alanosine position in this T-state is somewhat displaced from that expected for its analogue, aspartate, from the R-state position. The relations of these structural aspects to the kinetics are presented.

Influence of nucleotide effectors on the kinetics of the quaternary structure transition of allosteric aspartate transcarbamylase

We report the effects of allosteric effectors, ATP, CTP and UTP on the kinetics of the quaternary structure change of Escherichia coli ATCase during the enzyme reaction with physiological substrates. Time-resolved, small-angle, X-ray scattering of solutions allows direct observation of structural transitions over the entire time-course of the enzyme reaction initiated by fast mixing of the enzyme and substrates. In the absence of effectors, all scattering patterns recorded during the reaction are consistent with a two-state, concerted transition model, involving no detectable intermediate conformation that differs from the less active, unliganded T-state and the more active, substrate-bound R-state. The latter predominates during the steady-state phase of enzyme catalysis, while the initial T-state is recovered after substrate consumption. The concerted character of the structural transition is preserved in the presence of all effectors. CTP slightly shifts the dynamical equilibrium during a shortened steady state toward T while the additional presence of UTP makes the steady state vanishingly short. The return transition to the T conformation is slowed significantly in the presence of inhibitors, the effect being most severe in the presence of UTP. While ATP increases the apparent T to R rate, it also increases the duration of the steady-state phase, an apparently paradoxical observation. This observation can be accounted for by the greater increase in the association rate constant of aspartate, promoted by ATP, while the nucleotide produces a lesser degree of increase in the dissociation rate constant. Under our experimental conditions, using high concentrations of both enzyme and substrate, it appears that this very mechanism of activation turns the activator into an efficient inhibitor. The scattering patterns recorded in the presence of ATP support the view that ATP alters the quaternary structure of the substrate-bound enzyme, an effect reminiscent of the reported modification of PALA-bound R-state by Mg-ATP.

240s Loop Interactions Stabilize the T State of Escherichia coli Aspartate Transcarbamoylase

Here the functional and structural importance of interactions involving the 240s loop of the catalytic chain for the stabilization of the T state of aspartate transcarbamoylase were tested by replacement of Lys-244 with Asn and Ala. For the K244A and K244N mutant enzymes, the aspartate concentration required to achieve half-maximal specific activity was reduced to 8.4 and 4.0 mm, respectively, as compared with 12.4 mM for the wild-type enzyme. Both mutant enzymes exhibited dramatic reductions in homotropic cooperativity and the ability of the heterotropic effectors to modulate activity. Small angle x-ray scattering studies showed that the unligated structure of the mutant enzymes, and the structure of the mutant enzymes ligated with N-phosphonacetyl-L-aspartate, were similar to that observed for the unligated and N-phosphonacetyl-L-aspartateligated wild-type enzyme. A saturating concentration of carbamoyl phosphate alone has little influence on the small angle x-ray scattering of the wild-type enzyme. However, carbamoyl phosphate was able to shift the structure of the two mutant enzymes dramatically toward R, establishing that the mutations had destabilized the T state of the enzyme. The x-ray crystal structure of K244N enzyme showed that numerous local T state stabilizing interactions involving 240s loop residues were lost. Furthermore, the structure established that the mutation induced additional alterations at the subunit interfaces, the active site, the relative position of the domains of the catalytic chains, and the allosteric domain of the regulatory chains. Most of these changes reflect motions toward the R state structure. However, the K244N mutation alone only changes local conformations of the enzyme to an R-like structure, without triggering the quaternary structural transition. These results suggest that loss of cooperativity and reduction in heterotropic effects is due to the dramatic destabilization of the T state of the enzyme by this mutation in the 240s loop of the catalytic chain.

A fluorescent probe-labeled Escherichia coli aspartate transcarbamoylase that monitors the allosteric conformational state

A new system has been developed capable of monitoring conformational changes of the 240s loop of aspartate transcarbamoylase, which are tightly correlated with the quaternary structural transition, with high sensitivity in solution. Pyrene, a fluorescent probe, was conjugated to residue 241 in the 240s loop of aspartate transcarbamoylase to monitor changes in conformation by fluorescence spectroscopy. Pyrene maleimide was conjugated to a cysteine residue on the 240s loop of a previously constructed double catalytic chain mutant version of the enzyme, C47A/A241C. The pyrene-labeled enzyme undergoes the normal T to R structural transition, as demonstrated by small-angle x-ray scattering. Like the wild-type enzyme, the pyrene-labeled enzyme exhibits cooperativity toward aspartate, and is activated by ATP and inhibited by CTP at subsaturating concentrations of aspartate. The binding of the bisubstrate analogue N-(phosphonoacetyl)-l-aspartate (PALA), or the aspartate analogue succinate, in the presence of saturating carbamoyl phosphate, to the pyrenelabeled enzyme caused a sigmoidal change in the fluorescence emission. Saturation with ATP and CTP (in the presence of either subsaturating amounts of PALA or succinate and carbamoyl phosphate) caused a hyperbolic increase and decrease, respectively, in the fluorescence emission. The half-saturation values from the fluorescence saturation curves and kinetic saturation curves were, within error, identical. Fluorescence and small-angle x-ray scattering stopped-flow experiments, using aspartate and carbamoyl phosphate, confirm that the change in excimer fluorescence and the quaternary structure change correlate. These results in conjunction with previous studies suggest that the allosteric transition involves both global and local conformational changes and that the heterotropic effect of the nucleotides may be exerted through local conformational changes in the active site by directly influencing the conformation of the 240s loop.

The role of intersubunit interactions for the stabilization of the T state of Escherichia coli aspartate transcarbamoylase

Homotropic cooperativity in Escherichia coli aspartate transcarbamoylase results from the substrate-induced transition from the T to the R state. These two alternate states are stabilized by a series of interdomain and intersubunit interactions. The salt link between Lys-143 of the regulatory chain and Asp-236 of the catalytic chain is only observed in the T state. When Asp-236 is replaced by alanine the resulting enzyme exhibits full activity, enhanced affinity for aspartate, no cooperativity, and no heterotropic interactions. These characteristics are consistent with an enzyme locked in the functional R state. Using small angle x-ray scattering, the structural consequences of the D236A mutant were characterized. The unliganded D236A holoenzyme appears to be in a new structural state that is neither T, R, nor a mixture of T and R states. The structure of the native D236A holoenzyme is similar to that previously reported for another mutant holoenzyme (E239Q) that also lacks intersubunit interactions. A hybrid version of aspartate transcarbamoylase in which one catalytic subunit was wild-type and the other had the D236A mutation was also investigated. The hybrid holoenzyme, with three of the six possible interactions involving Asp-236, exhibited homotropic cooperativity, and heterotropic interactions consistent with an enzyme with both T and R functional states. Small angle x-ray scattering analysis of the unligated hybrid indicated that the enzyme was in a new structural state more similar to the T than to the R state of the wild-type enzyme. These data suggest that three of the six intersubunit interactions involving D236A are sufficient to stabilize a T-like state of the enzyme and allow for an allosteric transition.

Stabilization of the R allosteric structure of Escherichia coli aspartate transcarbamoylase by disulfide bond formation

Here we report the first use of disulfide bond formation to stabilize the R allosteric structure of Escherichia coli aspartate transcarbamoylase. In the R allosteric state, residues in the 240s loop from two catalytic chains of different subunits are close together, whereas in the T allosteric state they are far apart. By substitution of Ala-241 in the 240s loop of the catalytic chain with cysteine, a disulfide bond was formed between two catalytic chains of different subunits. The cross-linked enzyme did not exhibit cooperativity for aspartate. The maximal velocity was increased, and the concentration of aspartate required to obtain one-half the maximal velocity, [Asp](0.5), was reduced substantially. Furthermore, the allosteric effectors ATP and CTP did not alter the activity of the cross-linked enzyme. When the disulfide bonds were reduced by the addition of 1,4-dithio-dl-threitol the resulting enzyme had kinetic parameters very similar to those observed for the wild-type enzyme and regained the ability to be activated by ATP and inhibited by CTP. Small-angle x-ray scattering was used to verify that the cross-linked enzyme was structurally locked in the R state and that this enzyme after reduction with 1,4-dithio-dl-threitol could undergo an allosteric transition similar to that of the wild-type enzyme. The complete abolition of homotropic and heterotropic regulation from stabilizing the 240s loop in its closed position in the R state, which forms the catalytically competent active site, demonstrates the significance that the quaternary structural change and closure of the 240s loop has in the functional mechanism of aspartate transcarbamoylase.

Importance of domain closure for the catalysis and regulation of Escherichia coli aspartate transcarbamoylase

Two hybrid versions of Escherichia coli aspartate transcarbamoylase were studied to determine the influence of domain closure on the homotropic and heterotropic properties of the enzyme. Each hybrid holoenzyme had one wild-type and one inactive catalytic subunit. In the first case the inactive catalytic subunit had Arg-54 replaced by alanine. The holoenzyme with this mutation in all six catalytic chains exhibits a 17,000-fold reduction in activity, no loss in substrate affinity, and an R state structurally identical to that of the wild-type enzyme. In the second case, the inactive catalytic subunit had Arg-105 replaced by alanine. The holoenzyme with this mutation in all six catalytic chains exhibits a 1,100-fold reduction in activity, substantial loss in substrate affinity, and loss of the ability to be converted to the R state. Thus, the R54A substitution results in a holoenzyme that can undergo closure of the catalytic chain domains to form the high activity, high affinity active site and to undergo the allosteric transition, whereas the R105A substitution results in a holoenzyme that can neither undergo domain closure nor the allosteric transition. The hybrid holoenzyme with one wild-type and one R54A catalytic subunit exhibited the same maximal velocity per active site as the wild-type holoenzyme, reduced cooperativity, and normal heterotropic interactions. The hybrid with one wild-type and one R105A catalytic subunit exhibited significantly reduced maximal velocity per active site as compared with the wild-type holoenzyme, reduced cooperativity, and substantially reduced heterotropic interactions. Small angle x-ray scattered was used to verify that the R105A-containing hybrid could attain an R state structure. These results indicate the global nature of the conformational changes associated with the allosteric transition in the enzyme. If one catalytic subunit cannot undergo domain closure to create the active sites, then the entire molecule cannot attain the high activity, high activity R state.

Allosteric regulation of catalytic activity: Escherichia coli aspartate transcarbamoylase versus yeast chorismate mutase

Allosteric regulation of key metabolic enzymes is a fascinating field to study the structure-function relationship of induced conformational changes of proteins. In this review we compare the principles of allosteric transitions of the complex classical model aspartate transcarbamoylase (ATCase) from Escherichia coli, consisting of 12 polypeptides, and the less complicated chorismate mutase derived from baker's yeast, which functions as a homodimer. Chorismate mutase presumably represents the minimal oligomerization state of a cooperative enzyme which still can be either activated or inhibited by different heterotropic effectors. Detailed knowledge of the number of possible quaternary states and a description of molecular triggers for conformational changes of model enzymes such as ATCase and chorismate mutase shed more and more light on allostery as an important regulatory mechanism of any living cell. The comparison of wild-type and engineered mutant enzymes reveals that current textbook models for regulation do not cover the entire picture needed to describe the function of these enzymes in detail.

Tryptophan residues at subunit interfaces used as fluorescence probes to investigate homotropic and heterotropic regulation of aspartate transcarbamylase

The homotropic and heterotropic interactions in Escherichia coli aspartate transcarbamylase (EC 2.1.3.2) are accompanied by various structure modifications. The large quaternary structure change associated with the T to R transition, promoted by substrate binding, is accompanied by different local conformational changes. These tertiary structure modifications can be monitored by fluorescence spectroscopy, after introduction of a tryptophan fluorescence probe at the site of investigation. To relate unambiguously the fluorescence signals to structure changes in a particular region, both naturally occurring Trp residues in positions 209c and 284c of the catalytic chains were previously substituted with Phe residues. The regions of interest were the so-called 240's loop at position Tyr240c, which undergoes a large conformational change upon substrate binding, and the interface between the catalytic and regulatory chains in positions Asn153r and Phe145r supposed to play a role in the different regulatory processes. Each of these tryptophan residues presents a complex fluorescence decay with three to four independent lifetimes, suggesting that the holoenzyme exists in slightly different conformational states. The bisubstrate analogue N-phosphonacetyl-L-aspartate affects mostly the environment of tryptophans at position 240c and 145r, and the fluorescence signals were related to ligand binding and the quaternary structure transition, respectively. The binding of the nucleotide activator ATP slightly affects the distribution of the conformational substates as probed by tryptophan residues at position 240c and 145r, whereas the inhibitor CTP modifies the position of the C-terminal residues as reflected by the fluorescence properties of Trp153r. These results are discussed in correlation with earlier mutagenesis studies and mechanisms of the enzyme allosteric regulation.

Domain bridging interactions. A necessary contribution to the function and structure of Escherichia coli aspartate transcarbamoylase

Aspartate transcarbamoylase undergoes a domain closure in the catalytic chains upon binding of the substrates that initiates the allosteric transition. Interdomain bridging interactions between Glu(50) and both Arg(167) and Arg(234) have been shown to be critical for stabilization of the R state. A hybrid version of the enzyme has been generated in vitro containing one wild-type catalytic subunit, one catalytic subunit in which Glu(50) in each catalytic chain has been replaced by Ala (E50A), and wild-type regulatory subunits. Thus, the hybrid enzyme has one catalytic subunit capable of domain closure and one catalytic subunit incapable of domain closure. The hybrid does not behave as a simple mixture of the constituent subunits; it exhibits lower catalytic activity and higher aspartate affinity than would be expected. As opposed to the wild-type enzyme, the hybrid is inhibited allosterically by CTP at saturating substrate concentrations. As opposed to the E50A holoenzyme, the hybrid is not allosterically activated by ATP at saturating substrate concentrations. Small angle x-ray scattering showed that three of the six interdomain bridging interactions in the hybrid is sufficient to cause the global structural change to the R state, establishing the critical nature of these interactions for the allosteric transition of aspartate transcarbamoylase.

The allosteric activator Mg-ATP modifies the quaternary structure of the R-state of Escherichia coli aspartate transcarbamylase without altering the T<-->R equilibrium

The allosteric enzyme aspartate transcarbamylase from Escherichia coli (ATCase) displays regulatory properties that involve various conformational changes, including a large quaternary structure rearrangement. This entails a major change in its solution X-ray scattering curve upon binding substrate analogues. We show here that, in the presence of the nucleotide effector ATP, known to stimulate the enzyme activity, the scattering profiles show a marked dependence on the metal bound to ATP. Whereas ATP has no major effect on the scattering pattern of ATCase, a saturating concentration of Mg-ATP notably modifies the scattering profile of the enzyme, either in the absence or in the presence of the bisubstrate analogue N-(phosphonacetyl)-l-aspartate (PALA). The transition with PALA in the presence of this metal-nucleotide complex remains concerted. Furthermore, Mg-ATP, as already observed with ATP, has no detectable direct effect on the T to R transition. The experimental scattering curves in the presence of Mg-ATP were fitted by a modeling approach using rigid body movements of the regulatory subunits and the catalytic trimers in the crystal structures. While the differences observed in the T-state in the presence of Mg-ATP are essentially attributed to the binding per se of the nucleotide, the solution structure of the R-state complexed to Mg-ATP is even more extended along the 3-fold axis than the previously described R solution structure, which is already more stretched out along the same axis than the crystal R structure. Based on the crystal structure of the enzyme in the R-state complexed with free ATP, a proposal is made to account for the effect of magnesium.

The contribution of individual interchain interactions to the stabilization of the T and R states of Escherichia coli aspartate transcarbamoylase

Stabilization of the T and R allosteric states of Escherichia coli aspartate transcarbamoylase is governed by specific intra- and interchain interactions. The six interchain interactions between Glu-239 in one catalytic chain of one catalytic trimer with both Lys-164 and Tyr-165 of a different catalytic chain in the other catalytic trimer have been shown to be involved in the stabilization of the T state. In this study a series of hybrid versions of aspartate transcarbamoylase was studied to determine the minimum number of these Glu-239 interactions necessary to maintain homotropic cooperativity and the T allosteric state. Hybrids with zero, one, and two Glu-239 stabilizing interactions do not exhibit cooperativity, whereas the hybrids with three or more Glu-239 stabilizing interactions exhibit cooperativity. The hybrid enzymes with one or more of the Glu-239 stabilizing interactions also exhibit heterotropic interactions. Two hybrids with three Glu-239 stabilizing interactions, in different geometric relationships, had identical properties. From this and previous studies, it is concluded that the 239 stabilizing interactions play a critical role in the manifestation of homotropic cooperativity in aspartate transcarbamoylase by the stabilization of the T state of the enzyme. As substrate binding energy is utilized, more and more of the T state stabilizing interactions are relaxed, and finally the enzyme shifts to the R state. In the case of the Glu-239 stabilizing interactions more than three of the interactions must be broken before the enzyme shifts to the R state. The interactions between the catalytic and regulatory chains and between the two catalytic trimers of aspartate transcarbamoylase provide a global set of interlocking interactions that stabilize the T and R states of the enzyme. The substrate-induced local conformational changes observed in the structure of the isolated catalytic subunit drive the quaternary T to R transition of aspartate transcarbamoylase and functionally induced homotropic cooperativity.

Allosteric signal transmission involves synergy between discrete structural units of the regulatory subunit of aspartate transcarbamoylase

Previous studies have shown that the S5' beta-strand (r93-r97) of the regulatory polypeptides of the aspartate transcarbamoylases (ATCases) from Serratia marcescens and Escherichia coli are responsible for their diverged allosteric regulatory patterns, including conversion of CTP from an inhibitor in E. coli to an activator in S. marcescens. Similarly, mutation of residues located in the interface between the allosteric and the zinc domains resulted in conversion of the ATP responses of the E. coli enzyme from activation to inhibition, suggesting that this interface not only mediates but also discriminates the allosteric responses of ATP and CTP. To further decipher the roles and the interrelationships of these regions in allosteric communication, allosteric-zinc interface mutations (Y77F and V106A) have been introduced into both the native and the S5' beta-strand chimeric backgrounds. While the significance of this interface in the allosteric regulation has been confirmed, there is no direct evidence supporting the presence of distinct pathways for the ATP and CTP signals through this interface. The analysis of the mutational effects reported here suggested that the S5' beta-strand transmits the allosteric signal by modulating the hydrophobic allosteric-zinc interface rather than disturbing the allosteric ligand binding. Intragenic suppression by substitutions in the hydrophobic interface between the allosteric and the zinc domains of the regulatory chains resulted in the partial recovery of allosteric responses in the EC:rS5'sm chimera and reduced the activation by ATP in the Sm:rS5'ec chimera. Thus, it seems that there is a synergy between these two structural units.

Three of the six possible intersubunit stabilizing interactions involving Glu-239 are sufficient for restoration of the homotropic and heterotropic properties of Escherichia coli aspartate transcarbamoylase

A hybrid version of Escherichia coli aspartate transcarbamoylase was investigated in which one catalytic subunit has the wild-type sequence, and the other catalytic subunit has Glu-239 replaced by Gln. Since Glu-239 is involved in intersubunit interactions, this hybrid could be used to evaluate the extent to which T state stabilization is required for homotropic cooperativity and for heterotropic effects. Reconstitution of the hybrid holoenzyme (two different catalytic subunits with three wild-type regulatory subunits) was followed by separation of the mixture by anion-exchange chromatography. To make possible the resolution of the three holoenzyme species formed by the reconstitution, the charge of one of the catalytic subunits was altered by the addition of six aspartic acid residues to the C terminus of each of the catalytic chains (AT-C catalytic subunit). Control experiments indicated that the AT-C catalytic subunit as well as the holoenzyme formed with AT-C and wild-type regulatory subunits had essentially the same homotropic and heterotropic properties as the native catalytic subunit and holoenzyme, indicating that the addition of the aspartate tail did not influence the function of either enzyme. The control reconstituted holoenzyme, in which both catalytic subunits have Glu-239 replaced by Gln, exhibited no cooperativity, an enhanced affinity for aspartate, and essentially no heterotropic response identical to the enzyme isolated without reconstitution. The hybrid containing one normal and one mutant catalytic subunit exhibited homotropic cooperativity with a Hill coefficient of 1.4 and responded to the nucleotide effectors at about 50% of the level of the wild-type enzyme. Small angle x-ray scattering experiments with the hybrid enzyme indicated that in the absence of ligands it was structurally similar, but not identical, to the T state of the wild-type enzyme. In contrast to the wild-type enzyme, addition of carbamoyl phosphate induced a significant alteration in the scattering pattern, whereas the bisubstrate analog N-phosphonoacetyl-L-aspartate induced a significant change in the scattering pattern indicating the transition to the R-structural state. These data indicate that in the hybrid enzyme only three of the usual six interchain interactions involving Glu-239 are sufficient to stabilize the enzyme in a low affinity, low activity state and allow an allosteric transition to occur.

Threonine 82 in the regulatory chain is important for nucleotide affinity and for the allosteric stabilization of Escherichia coli aspartate transcarbamoylase

The three-dimensional structure of Escherichia coli aspartate transcarbamoylase complexed with the allosteric effector CTP, shows an interaction between the hydroxyl of Thr-82 in the regulatory chain (Thr-82r) with the gamma-phosphate of CTP (R.P. Kosman, J.E. Gouaux, W.N. Lipscomb, Crystal structure of CTP-ligated T state aspartate transcarbamoylase at 2.5 A resolution: implications for aspartate transcarbamoylase mutants and the mechanism of negative cooperativity, Proteins Struct. Funct. Genet. 15 (1993) 147-176). In order to determine whether the Thr-82r interaction with the gamma-phosphate of CTP is important for either binding of the nucleotide effectors or their function, site-specific mutagenesis was employed. The mutant enzyme in which Thr-82r was replaced by Ala had almost the identical maximal observed specific activity as the wild-type enzyme; however, the mutant enzyme had a significantly increased [Asp]0.5, the aspartate concentration at one-half the maximal observed specific activity, as well as slightly increased homotropic cooperativity. The mutant enzyme was also activated more by ATP and inhibited less by CTP as compared to the wild-type enzyme. In addition, the nucleotide concentration required for one-half maximal effect was increased approx. 3-fold as compared to the corresponding values for the wild-type enzyme. The maximal inhibition of the mutant enzyme, in the presence of UTP and CTP was similar to that observed for the wild-type enzyme; however, higher concentrations of the nucleotides were required to achieve this level of inhibition. The reduced affinity of CTP, UTP and ATP induced by the mutation indicates that the hydrogen bonding interaction between the gamma-phosphate of the nucleotide effector and the side-chain hydroxyl of Thr-82r is important for the binding of the nucleotide effectors to the allosteric site. Furthermore, this interaction is important for the discrimination between CTP and CDP. Finally, the greater homotropic cooperativity, greater [Asp]0.5, diminished CTP inhibition and greater ATP activation of the mutant enzyme correlates with the X-ray structure of the mutant enzyme which shows that the unligated enzyme is in an 'extreme' T-state. These findings add support to the theory that the global stabilization of the enzyme is critical for both the homotropic and heterotropic properties of aspartate transcarbamoylase.

L-aspartate association contributes to rate limitation and induction of the T-->R transition in Escherichia coli aspartate transcarbamoylase. Equilibrium exchanges and kinetic isotope effects with a Vmax-enhanced mutant, Asp-236-->Ala

Equilibrium isotope exchange kinetics (EIEK) and kinetic isotope effects have been used to determine the mechanistic basis for the altered kinetic characteristics of a mutant version of Escherichia coli aspartate transcarbamylase in which Asp-236 of the catalytic chain is replaced by alanine (Asp-236-->Ala). The [14C]Asp<--> N-carbamyl-L-aspartate (CAsp) and [14C]CP<-->CAsp exchange rates, observed as a function of various reactant-product pairs, exhibited dramatic increases in maximal rates, along with decreases in substrate half-saturation values and cooperativity. The carbon kinetic isotope effect, 13C versus 12C at the carbonyl group of carbamoyl phosphate, for the Asp-236-->Ala enzyme decreased toward unity as [Asp] increased, as observed for the wild-type enzyme. Both the kinetic isotope effects and EIEK results indicate that the Asp-236-->Ala enzyme operates by the same ordered kinetic mechanism as the wild-type enzyme. Although activation effects by ATP and N-phosphonacetyl-L-aspartate are lost, inhibition by CTP was apparent in equilibrium exchanges. Simulation of the EIEK data indicated that the best fit to the observed changes in saturation curves was obtained by preferentially increasing the rate of the T-->R transition, kappa T-->R, thereby destabilizing the T-state and increasing the equilbrium constant for the T<-->R transition. A multistep model for Asp bindng to aspartate transcarbamoylase is proposed, in which Asp induces the initial conformational changes that in turn trigger the T-->R transition, followed by stepwise filling of the remaining active sites.

Apparent cooperativity for carbamoylphosphate in Escherichia coli aspartate transcarbamoylase only reflects cooperativity for aspartate

The reaction catalyzed by Escherichia coli aspartate transcarbamoylase (ATCase) proceeds through an ordered mechanism, in which carbamoylphosphate binds first, followed by aspartate; upon binding of this second substrate, the enzyme undergoes a concerted transition from a low-affinity T state to a high-affinity R state. In various studies, conflicting results were obtained concerning the existence of positive cooperativity for the first substrate, carbamoylphosphate. It is shown here that cooperativity for this substrate is only apparent. Indeed, saturation curves for carbamoylphosphate display sigmoidicity only if the aspartate concentration used is high enough to shift ATCase into the R state. Furthermore, it is shown that succinate, an unreactive aspartate analogue which is able to promote the T-->R conformational transition, also induces the appearance of cooperativity for carbamoylphosphate. Similar results were obtained in the course of continuous-flow-dialysis experiments, which show that the binding of carbamoylphosphate is apparently cooperative only in the presence of a concentration of succinate high enough to shift the enzyme into the R state. Taken together, these data show that the apparent cooperativity for carbamoylphosphate is not an intrinsic property of ATCase, as it only reflects the cooperativity for the second substrate, aspartate, as a consequence of the process of ordered substrate binding.

A molecular mechanism for pyrimidine and purine nucleotide control of aspartate transcarbamoylase

CTP (ATP) binding to the T or R state causes reorientation of several key residues and results in a decrease (increase) in the size of the nucleotide binding site and a related decrease (increase) in the extension of the outer parts of the dimer of the regulatory chains, R1 and R6. As a result, CTP pinches the regulatory dimers together by 0.3 A in the R state; ATP pushes the regulatory dimers apart by 0.3 A in the T state. These changes influence key residues in the R1-C1 interface of the R state and the R1-C1 and R1-C4 interfaces of the T state, such that the separation of catalytic trimers (c3 ... c3) is decreased by 0.5 A by CTP in the R state and increased by 0.4 A by ATP in the T state. (Smaller effects on c3 ... c3 are observed when CTP binds to the sterically crowded T state or when ATP binds to the elongated R state). These changes reorient key residues in the active site (e.g., catalytic chain residue Arg-229, a residue involved in aspartate binding). This pattern for action of CTP and ATP in perturbing the regulatory dimer, and consequently both the structure and flexibility in critical parts of the T state or R state, is called the nucleotide perturbation mechanism.

Heterotropic interactions in aspartate transcarbamoylase: turning allosteric ATP activation into inhibition as a consequence of a single tyrosine to phenylalanine mutation

Aspartate transcarbamoylase (EC 2.1.3.2) is extensively studied as a model for cooperativity and allostery. This enzyme shows cooperativity between the catalytic sites, and its activity is feedback inhibited by CTP and activated by ATP. These regulatory processes involve several interfaces between catalytic and regulatory chains as well as between domains within these two types of chains. As far as the regulatory chain is concerned, its two domains are in contact through a hydrophobic interface, in which a tyrosine residue is inserted in a pocket involving two leucine residues of the allosteric domain and a valine and a leucine residue of the zinc domain. To probe the possible implication of this hydrophobic core in the CTP and ATP regulatory effect, the tyrosine was replaced by a phenylalanine through oligonucleotide-directed mutagenesis. Interestingly, the resulting mutant shows a complete inversion of the ATP effect; it is now inhibited by ATP instead of being activated by this nucleotide triphosphate. This mutant remains normally sensitive to the feedback inhibitor CTP. This result shows that the hydrophobic interface between the two domains of the regulatory chain plays an important role in the discrimination between the regulatory signals promoted by the two allosteric effectors.

Heterotropic interactions in Escherichia coli aspartate transcarbamylase. Subunit interfaces involved in CTP inhibition and ATP activation

In Escherichia coli aspartate transcarbamylase, each regulatory chain is involved in two kinds of interfaces with the catalytic chains, one with the neighbour catalytic chain which belongs to the same half of the molecule (R1-C1 type of interaction), the other one with a catalytic chain belonging to the other half of the molecule (R1-C4 type of interaction). In the present work, site-directed mutagenesis was used to investigate the involvement of the C-terminal region of the regulatory chain in the process of feed-back inhibition by CTP. Removal of the two last C-terminal residues of the regulatory chains is sufficient to abolish entirely the sensitivity of the enzyme to CTP. Thus, it appears that the contact between this region and the 240s loop of the catalytic chain (R1-C4 type of interaction) is essential for the transmission of the regulatory signal which results from CTP binding to the regulatory site. None of the modifications made in the R1-C4 interface altered the sensitivity of the enzyme to the activator ATP, suggesting that the effect of this nucleotide rather involves the R1-C1 type of interface. These results are in agreement with the previously proposed interpretation that CTP and ATP do not simply act in inverse ways on the same equilibrium.

Allosteric control of quaternary states in E. coli aspartate transcarbamylase

Changes in the molecular dimensions of ATCase in the unligated T-state are an increase of 0.4 A in the separation of catalytic trimers when ATP binds. When the R-state is produced by binding of phosphonoacetamide and malonate, addition of CTP or CTP + UTP decreases the separation of catalytic trimers by 0.5 A. In the unliganded Glu239----Gln mutant, in which the T-state is destabilized so that the enzyme exists in an intermediate quaternary state, ligation of ATP transforms the mutant enzyme to the R-state, whereas CTP converts this enzyme to the T-state. Thus, this mutant is much more sensitive to heterotropic allosteric control than is the native enzyme. In this communication we propose a preliminary model based on new crystallographic results that heterotropic regulation occurs partly through control of the quaternary structure by these effectors, thus regulating catalysis.

Structural consequences of effector binding to the T state of aspartate carbamoyltransferase: crystal structures of the unligated and ATP- and CTP-complexed enzymes at 2.6-A resolution

The crystal structure of Escherichia coli aspartate carbamoyltransferase complexed with adenosine 5'-triphosphate (ATP) has been solved by molecular replacement and has been refined to a crystallographic residual of 0.17 at 2.6-A resolution by using the computer program X-PLOR. The unit cell dimensions of this crystal form are a = b = 122.2 A and c = 143.3 A and the space group is P321. Although the c-axis unit cell dimension is approximately 1 A longer than the corresponding dimension of the CTP-ligated P321 crystal form (c = 142.2 A), the ATP-ligated enzyme adopts a T-like quaternary structure. The base moiety of ATP interacts with residues Glu10, Ile12, and Lys60 while the ribose is near Asp19 and Lys60; the triphosphate entity is bound to Lys94, although His20 and Arg96 are nearby. We observe a higher occupancy for ATP in the allosteric site of the R1 regulatory chain in comparison to the occupancy of the R6 allosteric site. These crystallographically independent sites are related by a molecular 2-fold axis. There are other violations of the noncrystallographic symmetry that are similar to those observed in the refined CTP-ligated aspartate carbamoyltransferase structure. These infringements on the molecular symmetry might be the result of intermolecular interactions in the crystal. To ensure the most meaningful comparison with the ATP-ligated structure, we refined the previously reported CTP-bound and unligated structures to crystallographic residuals between 0.17 and 0.18 using X-PLOR. These X-PLOR refined structures are not significantly different from the initial structures that had been crystallographically refined by a restrained least-squares method. After making all possible comparisons between the CTP- and ATP-ligated and the unligated T-state structures, we find that the most significant differences are located at the allosteric sites and in small changes in the quaternary structures. At the allosteric site, the binding of CTP and ATP successively enlarges the nucleotide binding cavity, particularly in the vicinity of the base. The changes in the quaternary structure can be characterized by an increase in the separation of the catalytic trimers by approximately 0.5 A as ATP binds to the unligated T structure. On the basis of these structural studies, we discuss the relationships between the conformational differences in the allosteric site and the small changes in the quaternary structure within the T form to the possible mechanisms for CTP inhibition and ATP activation.

Engineering aspartate transcarbamylase

Aspartate transcarbamylase from Escherichia coli is one of the most extensively studied regulatory enzymes as a model of cooperativity and allostery. Numerous methods are used to engineer variants of this molecule: random and site-directed mutagenesis, dissociation and reassociation of the catalytic and regulatory subunits and chains, construction of hybrids made from normal and modified subunits or chains, interspecific hybrids and construction of chimeric enzymes. These methods provide detailed information on the regions, domains, interfaces and aminoacid residues which are involved in the mechanism of co-operativity between the catalytic sites, and of regulation by the antagonistic effectors CTP and ATP. These effectors induce the transmission of intramolecular signals whose pathways begin to be delineated.

Carbamoyl phosphate biosynthesis and partition in pyrimidine and arginine pathways of Escherichia coli. In situ properties of carbamoyl-phosphate synthase, ornithine transcarbamylase and aspartate transcarbamylase in permeabilized cells

A procedure for the permeabilization of Escherichia coli cells was adapted to the in situ determination of the catalytic and regulatory properties of the enzymes responsible for the biosynthesis of carbamoyl phosphate and its utilization in the pyrimidine and arginine pathways. Differences in enzyme sensitivity to effectors and changes in pH dependence were observed. Partition of carbamoyl phosphate in the two metabolic pathways could be measured under conditions of substrate saturation. The results obtained will allow to test experimentally the theoretical predictions made by A. Goldbeter (1973) PhD thesis, Université Libre de Bruxelles, on the distribution of carbamoyl phosphate and the oscillation of its intracellular concentration.

In the presence of CTP, UTP becomes an allosteric inhibitor of aspartate transcarbamoylase

The allosteric control of aspartate transcarbamoylase (ATCase, EC 2.1.3.2) of Escherichia coli involves feedback inhibition by both CTP and UTP rather than just CTP alone. It has been known that CTP functions as a heterotropic inhibitor of catalysis; however, the inhibition by CTP alone is incomplete (50-70% at various aspartate concentrations) and there is only a partial occupancy of the allosteric binding sites by CTP at saturating concentrations. The logic of these allosteric characteristics can now be understood in that UTP is a synergistic inhibitor of ATCase in the presence of CTP even though UTP has no independent effect at pH 7.0. When saturating concentrations of CTP are present, the concentration of substrate required for half-maximal activity (S0.5) of the native holoenzyme for aspartate increases from 5 to 11 mM. When CTP and UTP are both present, the aspartate requirement increases further (S0.5 = 17 mM). At aspartate concentrations less than 5 mM, the heterotropic inhibition of ATCase is 90-95% in the presence of both pyrimidine nucleotides. UTP does enhance the binding of CTP to the holoenzyme but the number of tight binding sites does not change (n = 3). The binding of UTP is stabilized in the presence of CTP although its binding characteristics are not as strong as those of CTP. The recent crystallographic studies of Kim et al. [Kim, H.K., Pan, Z., Honzatko, R.B., Ke, H.M. & Lipscomb, W.N. (1987) J. Mol. Biol. 196, 853-875] have described a structural asymmetry across the molecular two-fold axis that is consistent with these CTP/UTP interactions. The synergistic inhibition of ATCase by both CTP and UTP provides a satisfying logic for ensuring a balance of endogenous pyrimidine nucleotide pools.

Structure-function relationship in allosteric aspartate carbamoyltransferase from Escherichia coli. I. Primary structure of a pyrI gene encoding a modified regulatory subunit

In a previous article, we have identified a lambda bacteriophage directing the synthesis of a modified aspartate carbamoyltransferase lacking substrate-co-operative interactions and insensitive to the feedback inhibitor CTP. These abnormal properties were ascribed to a mutation in the gene pyrI encoding the regulatory polypeptide chain of the enzyme. We now report the sequence of the mutated pyrI and show that, during the generation of this pyrBI-bearing phage, six codons from lambda DNA have been substituted for the eight terminal codons of the wild-type gene. A model is presented for the formation of this modified pyrI gene during the integrative recombination of the parental lambda phage with the Escherichia coli chromosome. An accompanying paper emphasizes the importance of the carboxy-terminal end of the regulatory chain for the homotropic and heterotropic interactions of aspartate carbamoyltransferase.

Structure-function relationship in allosteric aspartate carbamoyltransferase from Escherichia coli. II. Involvement of the C-terminal region of the regulatory chain in homotropic and heterotropic interactions

The modified aspartate transcarbamylase (ATCase) encoded by the transducing phage described by Cunin et al. has been purified to homogeneity. In this altered form of enzyme (pAR5-ATCase) the last eight amino acids of the C-terminal end of the regulatory chains are replaced by a sequence of six amino acids coded for by the lambda DNA. This modification has very informative consequences on the allosteric properties of ATCase. pAR5-ATCase lacks the homotropic co-operative interactions between the catalytic sites for aspartate binding and is "frozen" in the R state. In addition, this altered form of enzyme is insensitive to the physiological feedback inhibitor CTP, in spite of the fact that this nucleotide binds normally to the regulatory sites. Conversely, pAR5-ATCase is fully sensitive to the activator ATP. However, this activation is limited to the extent of the previously described "primary effect" as expected from an ATCase form "frozen" in the R state. These results emphasize the importance of the three-dimensional structure of the C-terminal region of the regulatory chains for both homotropic and heterotropic interactions. In addition, they indicate that the primary effects of CTP and ATP involve different features of the regulatory chain-catalytic chain interaction area.

Quaternary structure changes in aspartate transcarbamylase studied by X-ray solution scattering. Signal transmission following effector binding

The result of binding the effectors ATP and CTP to aspartate transcarbamylase was studied by X-ray solution scattering. Binding of substrate analogues produces a substantial change in the solution scattering curve, allowing us to monitor the proportion of the different quaternary structure states present in solution. In the initial solution this ratio was made roughly unity by adding either carbamyl phosphate and succinate, or N-(phosphonacetyl)-L-aspartate (PALA). ATP or CTP were then added, and their effect on the proportion of the different quaternary structure states was followed. When using carbamyl phosphate and succinate (weakly bound), ATP or CTP had a clear effect, as observed previously by monitoring the sedimentation rate (Changeux et al., 1968). However, when PALA (strongly bound) was used, the effect of CTP was very much smaller, and that of ATP was undetectable. This result supports the explanation by Tauc et al. (1982), that nucleotides act mostly through changing the affinity of the active sites for substrate, and only to a small extent by directly modifying the quaternary structure equilibrium in the case of CTP.

Solvent effects on allosteric equilibria: stabilization of T and R conformations of Escherichia coli aspartate transcarbamylase by organic solvents

The activity of Escherichia coli aspartate transcarbamylase (ATCase) is markedly influenced by the addition of organic solvents to the assay medium. The cosolvents tested, which include simple aliphatic alcohols, amides, and ureas, as well as acetone and dioxane, fall into two different classes: the most polar ones (formamide, acetamide, N-methylformamide, and urea) stimulate the enzyme activity for all concentrations tested. In contrast, solvents that are less polar than water inhibit the enzyme at low concentrations but stimulate it at higher concentrations. No comparable effects are observed in the case of the isolated catalytic subunits, a non-regulated form of ATCase. Extensive kinetic studies on ATCase and on two of its Michaelian derivatives, 2-thioU-ATCase and carbamylated ATCase, indicate that solvents modulate the same allosteric transition that is responsible for homotropic interactions between the catalytic sites. The stabilization of the R state of ATCase by comparatively high concentrations of cosolvents is reminiscent of similar findings made on hemoglobin and glycogen phosphorylase, suggesting a common underlying mechanism. Addition of organic cosolvents to water is known to reduce hydrophobic interactions, and we suggest that this effect may preferentially stabilize the more "relaxed" conformations of allosteric proteins, because they have a larger surface exposed to solvent [Chothia, C. (1974) Nature (London) 248, 338-339]. On the other hand, we suggest that the stabilization of the T state by low concentrations of all but the most polar cosolvents simply reflects stronger electrostatic interactions in this conformation.

In situ behavior of the pyrimidine pathway enzymes in Saccharomyces cerevisiae. I. Catalytic and regulatory properties of aspartate transcarbamylase

A permeabilization procedure was adapted to allow the in situ determination of aspartate transcarbamylase activity in Saccharomyces cerevisiae. Permeabilization is obtained by treating cell suspensions with small amounts of 10% toluene in absolute ethanol. After washing, the cells can be used directly in the enzyme assays. Kinetic studies of aspartate transcarbamylase (EC 2.1.3.2) in such permeabilized cells showed that apparent Km for substrates and Ki for the feedback inhibitor UTP were only slightly different from those reported using partially purified enzyme. The aspartate saturation curve is hyperbolic both in the presence and absence of UTP. The inhibition by this nucleotide is noncompetitive with respect to aspartate, decreasing both the affinity for this substrate and the maximal velocity of the reaction. The saturation curves for both substrates give parallel double reciprocal plots. The inhibition by the products is linear noncompetitive. Succinate, an aspartate analog, provokes competitive and uncompetitive inhibitions toward aspartate and carbamyl phosphate, respectively. The inhibition by phosphonacetate, a carbamyl phosphate analog, is uncompetitive and noncompetitive toward carbamyl phosphate and aspartate, respectively, but pyrophosphate inhibition is competitive toward carbamyl phosphate and noncompetitive toward aspartate. These results, as well as the effect of the transition state analog N-phosphonacetyl-L-aspartate, all exclude a random mechanism for aspartate transcarbamylase. Most of the data suggest an ordered mechanism except the substrates saturation curves, which are indicative of a ping-pong mechanism. Such a discrepancy might be related to some channeling of carbamyl phosphate between carbamyl phosphate synthetase and aspartate transcarbamylase catalytic sites.