Lysine-60 in the regulatory chain of Escherichia coli aspartate transcarbamoylase is important for the discrimination between CTP and ATP

Metal ion involvement in the allosteric mechanism of Escherichia coli aspartate transcarbamoylase

Escherichia coli aspartate transcarbamoylase (ATCase) allosterically regulates pyrimidine nucleotide biosynthesis. The enzyme is inhibited by CTP and can be further inhibited by UTP, although UTP alone has little or no influence on activity; however, the mechanism for the synergistic inhibition is still unknown. To determine how UTP is able to synergistically inhibit ATCase in the presence of CTP, we determined a series of X-ray structures of ATCase·nucleotide complexes. Analysis of the X-ray structures revealed that (1) CTP and dCTP bind in a very similar fashion, (2) UTP, in the presence of dCTP or CTP, binds at a site that does not overlap the CTP/dCTP site, and (3) the triphosphates of the two nucleotides are parallel to each other with a metal ion, in this case Mg(2+), coordinated between the β- and γ-phosphates of the two nucleotides. Kinetic experiments showed that the presence of a metal ion such as Mg(2+) is required for synergistic inhibition. Together, these results explain how the binding of UTP can enhance the binding of CTP and why UTP binds more tightly in the presence of CTP. A mechanism for the synergistic inhibition of ATCase is proposed in which the presence of UTP stabilizes the T state even more than CTP alone. These results also call into question many of the past kinetic and binding experiments with ATCase with nucleotides as the presence of metal contamination was not considered important.

Asymmetric allosteric signaling in aspartate transcarbamoylase

Here we use the fluorescence from a genetically encoded unnatural amino acid, l-(7-hydroxycoumarin-4-yl)ethylglycine (HCE-Gly), replacing an amino acid in the regulatory site of Escherichia coli aspartate transcarbamoylase (ATCase) to decipher the molecular details of regulation of this allosteric enzyme. The fluorescence of HCE-Gly is exquisitely sensitive to the binding of all four nucleotide effectors. Although ATP and CTP are primarily responsible for influencing enzyme activity, the results of our fluorescent binding studies indicate that UTP and GTP bind with similar affinities, suggesting a dissociation between nucleotide binding and control of enzyme activity. Furthermore, while CTP is the strongest regulator of enzyme activity, it binds selectively to only a fraction of regulatory sites, allowing UTP to effectively fill the residual ones. Our results suggest that CTP and UTP are not competing for the same binding sites, but instead reveal an asymmetry between the two allosteric sites on the regulatory subunit of the enzyme. Correlation of binding and activity measurements explain how ATCase uses asymmetric allosteric sites to achieve regulatory sensitivity over a broad range of heterotropic effector concentrations.

Allosteric communication network in the tetrameric restriction endonuclease Bse634I

Restriction endonuclease Bse634I is a homotetramer arranged as a dimer of two primary dimers. Bse634I displays its maximum catalytic efficiency upon binding of two copies of cognate DNA, one per each primary dimer. The catalytic activity of Bse634I on a single DNA copy is down-regulated due to the cross-talking interactions between the primary dimers. The mechanism of signal propagation between the individual active sites of Bse634I remains unclear. To identify communication pathways involved in the catalytic activity regulation of Bse634I tetramer we mutated a selected set of amino acid residues at the dimer-dimer interface and analysed the oligomeric state and catalytic properties of the mutant proteins. We demonstrate that alanine replacement of N262 and V263 residues located in the loop at the tetramerisation interface did not inhibit tetramer assembly but dramatically altered the catalytic properties of Bse634I despite of the distal location from the active site. Kinetic analysis using cognate hairpin oligonucleotide and one and two-site plasmids as substrates allowed us to identify two types of communication signals propagated through the dimer-dimer interface in the Bse634I tetramer: the inhibitory, or "stopper" and the activating, or "sync" signal. We suggest that the interplay between the two signals determines the catalytic and regulatory properties of the Bse634I and mutant proteins.

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.

Characterization of the aspartate transcarbamoylase from Methanococcus jannaschii

The genes from the thermophilic archaeabacterium Methanococcus jannaschii that code for the putative catalytic and regulatory chains of aspartate transcarbamoylase were expressed at high levels in Escherichia coli. Only the M. jannaschii PyrB (Mj-PyrB) gene product exhibited catalytic activity. A purification protocol was devised for the Mj-PyrB and M. jannaschii PyrI (Mj-PyrI) gene products. Molecular weight measurements of the Mj-PyrB and Mj-PyrI gene products revealed that the Mj-PyrB gene product is a trimer and the Mj-PyrI gene product is a dimer. Preliminary characterization of the aspartate transcarbamoylase from M. jannaschii cell-free extract revealed that the enzyme has a similar molecular weight to that of the E. coli holoenzyme. Kinetic analysis of the M. jannaschii aspartate transcarbamoylase from the cell-free extract indicates that the enzyme exhibited limited homotropic cooperativity and little if any regulatory properties. The purified Mj-catalytic trimer exhibited hyperbolic kinetics, with an activation energy similar to that observed for the E. coli catalytic trimer. Homology models of the Mj-PyrB and Mj-PyrI gene products were constructed based on the three-dimensional structures of the homologous E. coli proteins. The residues known to be critical for catalysis, regulation, and formation of the quaternary structure from the well characterized E. coli aspartate transcarbamoylase were compared.

The use of nucleotide analogs to evaluate the mechanism of the heterotropic response of Escherichia coli aspartate transcarbamoylase

As an alternative method to study the heterotropic mechanism of Escherichia coli aspartate transcarbamoylase, a series of nucleotide analogs were used. These nucleotide analogs have the advantage over site-specific mutagenesis experiments in that interactions between the backbone of the protein and the nucleotide could be evaluated in terms of their importance for function. The ATP analogs purine 5'-triphosphate (PTP), 6-chloropurine 5'-triphosphate (Cl-PTP), 6-mercaptopurine 5'-triphosphate (SH-PTP), 6-methylpurine 5'-triphosphate (Me-PTP), and 1-methyladenosine 5'-triphosphate (Me-ATP) were partially synthesized from their corresponding nucleosides. Kinetic analysis was performed on the wild-type enzyme in the presence of these ATP analogs along with GTP, ITP, and XTP. PTP, Cl-PTP, and SH-PTP each activate the enzyme at subsaturating concentrations of L-aspartate and saturating concentrations of carbamoyl phosphate, but not to the same extent as does ATP. These experiments suggest that the interaction between N6-amino group of ATP and the backbone of the regulatory chain is important for orienting the nucleotide and inducing the displacements of the regulatory chain backbone necessary for initiation of the regulatory response. Me-PTP and Me-ATP also activate the enzyme, but in a more complex fashion, which suggests differential binding at the two sites within each regulatory dimer. The purine nucleotides GTP, ITP, and XTP each inhibit the enzyme but to a lesser extent than CTP. The influence of deoxy and dideoxynucleotides on the activity of the enzyme was also investigated. These experiments suggest that the 2' and 3' ribose hydroxyl groups are not of significant importance for binding and orientation of the nucleotide in the regulatory binding site. 2'-dCTP inhibits the enzyme to the same extent as CTP, indicating that the interactions of the enzyme to the O2-carbonyl of CTP are critical for CTP binding, inhibition, and the ability of the enzyme to discriminate between ATP and CTP. Examination of the electrostatic surface potential of the nucleotides and the regulatory chain suggest that the complimentary electrostatic interactions between the nucleotides and the regulatory chain are important for binding and orientation of the nucleotide necessary to induce the local conformational changes that propagate the heterotropic effect.

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.

Crystal structure of CTP-ligated T state aspartate transcarbamoylase at 2.5 A resolution: implications for ATCase mutants and the mechanism of negative cooperativity

The X-ray crystal structure of CTP-ligated T state aspartate transcarbamoylase has been refined to an R factor of 0.182 at 2.5 A resolution using the computer program X-PLOR. The structure contains 81 sites for solvent and has rms deviations from ideality in bond lengths and bond angles of 0.018 A and 3.722 degrees, respectively. The cytosine base of CTP interacts with the main chain carbonyl oxygens of rTyr-89 and rIle-12, the main chain NH of rIle-12, and the amino group of rLys-60. The ribose hydroxyls form polar contacts with the amino group of rLys-60, a carboxylate oxygen of rAsp-19, and the main chain carbonyl oxygen of rVal-9. The phosphate oxygens of CTP interact with the amino group of rLys-94, the hydroxyl of rThr-82, and an imidazole nitrogen of rHis-20. Recent mutagenesis experiments evaluated in parallel with the structure reported here indicate that alterations in the hydrogen bonding environment of the side chain of rAsn-111 may be responsible for the homotropic behavior of the pAR5 mutant of ATCase. The location of the first seven residues of the regulatory chain has been identified for the first time in a refined ATCase crystal structure, and the proximity of this portion of the regulatory chain to the allosteric site suggests a potential role for these residues in nucleotide binding to the enzyme. Finally, a series of amino acid side chain rearrangements leading from the R1 CTP allosteric to the R6 CTP allosteric site has been identified which may constitute the molecular mechanism of distinct CTP binding sites on ATCase.

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.

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.

Crystal structures of aspartate carbamoyltransferase ligated with phosphonoacetamide, malonate, and CTP or ATP at 2.8-A resolution and neutral pH

The R-state structures of the ATP and CTP complexes of aspartate carbamoyltransferase ligated with phosphonoacetamide and malonate have been determined at 2.8-A resolution and neutral pH. These structures were solved by the method of molecular replacement and were refined to crystallographic residuals between 0.167 and 0.182. The triphosphate, the ribose, and the purine and pyrimidine moieties of ATP and CTP interact with similar regions of the allosteric domain of the regulatory dimer. ATP and CTP relatively increase and decrease the size of the allosteric site in the vicinity of the base, respectively. For both CTP and ATP at pH 7, the gamma-phosphates are bound to His20 and are also near Lys94, while the alpha-phosphates interact exclusively with Lys94. The 2'-hydroxyls of both CTP and ATP are near the amino group of Lys60. The pyrimidine ring of CTP makes specific hydrogen bonds at the allosteric site: the NH2 group donates hydrogen bonds to the main-chain carbonyls of Ile12 and Tyr89 and the pyrimidine ring carbonyl oxygen accepts a hydrogen bond from the amino group of Lys60; the nitrogen at position 3 in the pyrimidine ring is hydrogen bonded to a main-chain NH group of Ile12. The purine ring of ATP also makes numerous interactions with residues at the allosteric site: the purine NH2 (analogous to the amino group of CTP) donates a hydrogen bond to the main-chain carbonyl oxygen of Ile12, the N3 nitrogen interacts with the amino group of Lys60, and the N1 nitrogen hydrogen bonds to the NH group of Ile12. The binding of CTP and ATP to the allosteric site in the presence of phosphonoacetamide and malonate does not dramatically alter the structure of the allosteric binding site or of the allosteric domain. Nonetheless, in the CTP-ligated structure, the average separation between the catalytic trimers decreases by approximately 0.5 A, indicating a small shift of the quaternary structure toward the T state. In the CTP- and ATP-ligated R-state structures, the binding and occupancy of phosphonoacetamide and malonate are similar and the structures of the active sites are similar at the current resolution of 2.8 A.

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.