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.     

Modes of modifier action in E. coli aspartate transcarbamylase

The observed patterns for inhibition by CTP and succinate of equilibrium exchange kinetics with native aspartate transcarbamylase (E. coli) are consistent with an ordered substrate-binding system in which aspartate binds after carbamyl phosphate, and phosphate is released after carbamyl aspartate. ATP selectively stimulates Asp carbamyl-Asp exchange, but not carbamyl phosphate P_i. Initial velocity studies at 5 °, 15 °, and 35 °C were carried out, using modifiers as perturbants of the system. Modifiers alter the Hill n and S_0.5 for aspartate, most markedly at 15 °C but less so at the other temperatures. ATP does increase V under saturating substrate conditions, and substrate inhibition is observed for aspartate. ATP does not make the Hill n = 1 at any temperature. It is proposed that CTP and ATP act by separate mechanisms, not by simply perturbing in opposite directions the equilibrium for aspartate binding. ATP appears to act to increase the rate of aspartate association and dissociation, whereas CTP induces an intramolecular competitive effect in the protein.     

Modelling allosteric processes in E coli aspartate transcarbamylase

The allosteric properties of aspartate transcarbamylase from E coli have been investigated by a combination of genetic, biochemical and structural studies. Based on the X-ray structures of the enzyme in T and R state established by Lipscomb et al, we have analyzed the interactions between the 12 polypeptide chains and have identified subunit interfaces that play a major part in the allosteric mechanism: the c1c4 interface between the 2 catalytic trimers, and one of 2 different interfaces between catalytic and regulatory chains, the c1r4 interface, which exists only in T state. We have modelled mutations affecting these interfaces: mutation pAR5 in the gene coding for r chains concerns the c1r4 interface, mutation Tyr----Phe 240 in the gene coding for c chains, the c1c4 interface. Both mutant proteins have reduced cooperativity and/or allosteric regulation by CTP and ATP. Molecular mechanic simulations lead to specific proposals for the structural origin of these effects, and some of the proposals can be checked by site-directed mutagenesis. Finally, we have modelled substrates bound at the active site of the T state, which binds aspartate less tightly than the R state and for which X-ray structures of bound substrate analogs were not available.     

Comparison of van 't Hoff and calorimetrically determined enthalpies of binding of N-phosphonacetyl-L-aspartate to E. coli aspartate transcarbamylase.

A comparison has been made of the values obtained by direct calorimetric measurements and van 't Hoff analysis, under similar conditions, for the enthalpy of binding of the bisubstrate analog N-phosphonacetyl-L-aspartate (PALA) to E. coli aspartate transcarbamylase and its catalytic subunit. In the case of the catalytic subunit, data were obtained at both saturating and non-saturating concentrations of L-Asp, and at two ionic strengths. Despite a 1000-fold difference in protein concentrations, and the obligatory omission of carbamyl phosphate in the calorimetric experiments, the values obtained by the two methods are shown to agree to within 15% when appropriate corrections are made. These results suggest that subunit dissociation is not a significant factor at the low protein concentrations used in the van 't Hoff analysis, and, conversely, that aggregation of the protein is negligible at the high protein concentrations used in the calorimetric experiments. They also imply that, at pH 8.3, the enthalpic difference between the two conformational states of the enzyme which exist in the presence and absence of substrates is less than 2.5 kcal/mol. In addition, the trends in the three sets of data for the catalytic subunit indicate that ionic bonds are involved in binding PALA to the active site, and that non-productive binding by L-Asp is negligible under these experimental conditions.     

Propagation of allosteric changes through the catalytic-regulatory interface of Escherichia coli aspartate transcarbamylase

Each of two previously isolated strains of Escherichia coli containing a single nonsense codon within the pyrB gene was suppressed with four different nonsense suppressors. The kinetic analysis using crude extracts of these nonsense-suppressed strains indicated that the mutant aspartate transcarbamylases had altered cooperativity and affinity for aspartate as judged by the substrate concentration at half of the maximal velocity. Both pyrB genes were cloned and then sequenced. In both cases, a single base change was identified which converted a glutamine GAC codon into a TAC nonsense codon. Both mutations occurred in the catalytic chain of aspartate transcarbamylase and were identified at positions 108 and 246. The glutamine at position 108 in the wild-type structure is located at the interface between the catalytic and regulatory chains and is involved in a number of interactions with backbone and side chains of the regulatory chain. The glutamine at position 246 in the wild-type structure is located in the 240s loop of the enzyme. Two additional mutant versions of aspartate transcarbamylase were created by site-directed mutagenesis to further investigate the 108-position in the structure, a glutamine to tyrosine substitution at position 108 of the catalytic chain, and an asparagine to glycine change at position 113 of the regulatory chain, a residue which interacts directly with glutamine-108 in the wild-type structure. Both mutant enzymes have reduced affinity for aspartate. However, the Tyr-108 mutant enzyme exhibits a reduced Hill coefficient while the Gly-113 enzyme exhibits an increased Hill coefficient. The response to the allosteric effectors ATP and CTP is also changed for both the mutant enzymes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ordered substrate binding and evidence for a thermally induced change in mechanism for E. coli aspartate transcarbamylase

Isotopic exchange kinetics at equilibrium for E. coli native aspartate transcarbamylase at pH 7.8, 30 °C, are consistent with an ordered BiBi substrate binding mechanism. Carbamyl phosphate binds before l-Asp, and carbamyl-aspartate is released before inorganic phosphate. The rate of [¹⁴C]Asp C-Asp exchange is much faster than [³²P]carbamyl phosphate P_i exchange. Phosphate, and perhaps carbamyl phosphate, appears to bind at a separate modifier site and prevent dissociation of active-site bound P_i or carbamyl phosphate. Initial velocity studies in the range of 0–40 °C reveal a biphasic Arrhenius plot for native enzyme: E_a (>15 °C) = 6.3 kcal/ mole and E_a (<15 °C) = 22.1 kcal/mole. Catalytic subunits show a monophasic plot with E_a ? 20.2 kcal/mole. This, with other data, suggests that with native enzyme a conformational change accompanying aspartate association contributes significantly to rate limitation at t > 15 °C, but that catalytic steps become definitively slower below 15 °C. Model kinetics are derived to show that this change in mechanism at low temperature can force an ordered substrate binding system to produce exchange-rate patterns consistent with a random binding system with all exchange rates equal. The nonlinear Arrhenius plot also has important consequences for current theories of catalytic and regulatory mechanisms for this enzyme.     

Electrostatic interactions in the assembly of Escherichia coli aspartate transcarbamylase

Although ionizable groups are known to play important roles in the assembly, catalytic, and regulatory mechanisms of Escherichia coli aspartate transcarbamylase, these groups have not been characterized in detail. We report the application of static accessibility modified Tanford-Kirkwood theory to model electrostatic effects associated with the assembly of pairs of chains, subunits, and the holoenzyme. All of the interchain interfaces except R1-R6 are stabilized by electrostatic interactions by -2 to -4 kcal-m-1 at pH 8. The pH dependence of the electrostatic component of the free energy of stabilization of intrasubunit contacts (C1-C2 and R1-R6) is qualitatively different from that of intersubunit contacts (C1-C4, C1-R1, and C1-R4). This difference may allow the transmission of information across subunit interfaces to be selectively regulated. Groups whose calculated pK or charge changes as a result of protein-protein interactions have been identified and the results correlated with available information about their function. Both the 240s loop of the c chain and the region near the Zn(II) ion of the r chain contain clusters of ionizable groups whose calculated pK values change by relatively large amounts upon assembly. These pK changes in turn extend to regions of the protein remote from the interface. The possibility that networks of ionizable groups are involved in transmitting information between binding sites is suggested.     

Coupling of homotropic and heterotropic interactions in Escherichia coli aspartate transcarbamylase

Several types of conditions allow the disconnection of homotropic and heterotropic interactions in Escherichia coli aspartate transcarbamylase. A model that includes a concerted gross conformational change corresponding to the homotropic cooperative interactions between the catalytic sites and local “site by site” effects promoted by the effectors accounts for this disconnection as well as for the other known properties of the enzyme. However, the substrate concentration influences the extent of stimulation and feedback inhibition of the catalytic activity by the effectors. This result is explained by assuming that these effectors promote a “primary effect”, which is exerted locally “site by site”, and a “secondary effect”, which is mediated by the substrate. As predicted by the model, relaxed (R) forms of the enzyme show only the primary effect. In addition 2-ThioU-aspartate transcarbamylase, a modified form of the enzyme in which the homotropic cooperative interactions between the catalytic sites are selectively abolished, shows the same heterogeneity in CTP binding sites as normal aspartate transcarbamylase.     

Kinetic mechanism of catalytic subunits (c3) of E. coli aspartate transcarbamylase at pH 7.0

In contrast to holo-enzyme (c6r6), catalytic subunits (c3) of Escherichia coli aspartate transcarbamylase (carbamoyl-phosphate:L-aspartate carbamoyltransferase, EC 2.1.3.2) do not exhibit allosteric interactions or inhibition effects that complicate kinetic investigations of substrate binding order. Equilibrium isotope-exchange kinetic probes of c3 at pH 7.0 and 30 degrees C produced kinetic saturation patterns consistent with a strongly preferred order random kinetic mechanism, in which carbamoyl phosphate binds prior to aspartate and carbamoyl aspartate is released before Pi. Weak substrate inhibition effects observed with c6r6 did not occur with c3, possibly due to decreased affinity for ligands at the dianion inhibition site.     

Effects of the T→R transition on the electrostatic properties of E. coli aspartate transcarbamylase

Aspartate transcarbamylase is a large (310 kD), multisubunit protein that binds substrates cooperatively and undergoes a large change in quaternary structure when substrates bind. The forces that drive this transition are poorly understood. We evaluated the electrostatic component of these forces by using finite difference and multigrid methods to solve the nonlinear Poisson-Boltzmann equation for complexes of the enzyme with several substrates and substrate analogs. The results have been compared with calculations for the unliganded protein. While pK_½ values of most ionizable residues fall within 3 pH units of values for model compounds, 31 have pK_½ values that fall outside the range 0–17. Many of these residues are at the active site, where they interact with the highly charged substrate, in the 80s loop or 240s loop or interact with these loops. The pK_½ values of eight ionizable residues related by the twofold molecular axes differ by more than 3 pH units, providing additional evidence for asymmetry within the crystal. As in the unliganded structure, a set of residues forms a network in which ionizable groups with W_ij values greater than 2 kcal-m^-1 are separated by distances greater than 5 Å. Some residues participate in this network in both the unliganded and N-phosphonacetyl-L-aspartate (PALA)-liganded structure, while others are found in only one structure. The network is more extensive in the PALA-liganded structure than in the unliganded structure, but consists of two separate networks in the two halves of the molecule. Proteins 32:200–210, 1998. © 1998 Wiley-Liss, Inc.     

Importance of domain closure for homotropic cooperativity in Escherichia coli aspartate transcarbamylase

The importance of the interdomain bridging interactions observed only in the R-state structure of Escherichia coli aspartate transcarbamylase between Glu-50 of the carbamoyl phosphate domain with both Arg-167 and Arg-234 of the aspartate domain has been investigated by using site-specific mutagenesis. Two mutant versions of aspartate transcarbamylase were constructed, one with alanine at position 50 (Glu-50----Ala) and the other with aspartic acid at position 50 (Glu-50----Asp). The alanine substitution totally prevents the interdomain bridging interactions, while the aspartic acid substitution was expected to weaken these interactions. The Glu-50----Ala holoenzyme exhibits a 15-fold loss of activity, no substrate cooperativity, and a more than 6-fold increase in the aspartate concentration at half the maximal observed specific activity. The Glu-50----Asp holoenzyme exhibits a less than 3-fold loss of activity, reduced cooperativity for substrates, and a 2-fold increase in the aspartate concentration at half the maximal observed specific activity. Although the Glu-50----Ala enzyme exhibits no homotropic cooperativity, it is activated by N-(phosphonoacetyl)-L-aspartate (PALA). As opposed to the wild-type enzyme, the Glu-50----Ala enzyme is activated by PALA at saturating concentrations of aspartate. At subsaturating concentrations of aspartate, both mutant enzymes are activated by ATP, but are inhibited less by CTP than is the wild-type enzyme. At saturating concentrations of aspartate, the Glu-50----Ala enzyme is activated by ATP and inhibited by CTP to an even greater extent than at subsaturating concentrations of aspartate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Use of L-asparagine and N-phosphonacetyl-L-asparagine to investigate the linkage of catalysis and homotropic cooperativity in E. coli aspartate transcarbomoylase

The mechanism of domain closure and the allosteric transition of Escherichia coli aspartate transcarbamoylase (ATCase) are investigated using L-Asn, in the presence of carbamoyl phosphate (CP), and N-phosphonacetyl-L-asparagine (PASN). ATCase was found to catalyze the carbamoylation of L-Asn with a K(m) of 122 mM and a maximal velocity 10-fold lower than observed with the natural substrate, L-Asp. As opposed to L-Asp, no cooperativity was observed with respect to L-Asn. Time-resolved small-angle X-ray scattering (SAXS) and fluorescence experiments revealed that the combination of CP and L-Asn did not convert the enzyme from the T to the R state. PASN was found to be a potent inhibitor of ATCase exhibiting a K(D) of 8.8 microM. SAXS experiments showed that PASN was able to convert the entire population of molecules to the R state. Analysis of the crystal structure of the enzyme in the presence of PASN revealed that the binding of PASN was similar to that of the R-state complex of ATCase with N-phosphonaceyl-L-aspartate, another potent inhibitor of the enzyme. The linking of CP and L-Asn into one molecule, PASN, correctly orients the asparagine moiety in the active site to induce domain closure and the allosteric transition. This entropic effect allows for the high affinity binding of PASN. However, the binding of L-Asn, in the presence of a saturating concentration of CP, does not induce the closure of the two domains of the catalytic chain, nor does the enzyme undergo the transition to the high-activity high- affinity R structure. These results imply that Arg229, which interacts with the beta-carboxylate of L-Asp, plays a critical role in the orientation of L-Asp in the active site and demonstrates the requirement of the beta-carboxylate of L-Asp in the mechanism of domain closure and the allosteric transition in E. coli ATCase.