Function of serine-52 and serine-80 in the catalytic mechanism of Escherichia coli aspartate transcarbamoylase

Carbamoyl phosphate is held in the active site of Escherichia coli aspartate transcarbamoylase by a variety of interactions with specific side chains of the enzyme. In particular, oxygens of the phosphate of carbamoyl phosphate interact with Ser-52, Thr-53 (backbone), Arg-54, Thr-55, and Arg-105 from one catalytic chain, as well as Ser-80 and Lys-84 from an adjacent chain in the same catalytic subunit. In order to define the role of Ser-52 and Ser-80 in the catalytic mechanism, two mutant versions of the enzyme were created with Ser-52 or Ser-80 replaced by alanine. The Ser-52----Ala holoenzyme exhibits a 670-fold reduction in maximal observed specific activity, and a loss of both aspartate and carbamoyl phosphate cooperativity. This mutation also causes 23-fold and 5.6-fold increases in the carbamoyl phosphate and aspartate concentrations required for half the maximal observed specific activity, respectively. Circular dichroism spectroscopy indicates that saturating carbamoyl phosphate does not induce the same conformational change in the Ser-52----Ala holoenzyme as it does for the wild-type holoenzyme. The kinetic properties of the Ser-52----Ala catalytic subunit are altered to a lesser extent than the mutant holoenzyme. The maximal observed specific activity is reduced by 89-fold, and the carbamoyl phosphate concentration at half the maximal observed velocity increases by 53-fold while the aspartate concentration at half the maximal observed velocity increases 6-fold.(ABSTRACT TRUNCATED AT 250 WORDS)     

Importance of a conserved residue, aspartate-162, for the function of Escherichia coli aspartate transcarbamoylase.

Aspartate-162 in the catalytic chain of aspartate transcarbamoylase is conserved in all of the sequences determined to date. The X-ray structure of the Escherichia coli enzyme indicates that this residue is located in a loop region (160's loop) that is near the interface between two catalytic trimers and is also close to the active site. In order to test whether this conserved residue is important for support of the internal architecture of the enzyme and/or involved in transmitting homotropic and heterotropic effects, the function of this residue was studied using a mutant version of the enzyme with an alanine at this position (Asp-162----Ala) created by site-specific mutagenesis. The Asp-162----Ala enzyme exhibits a 400-fold reduction in the maximal observed specific activity, approximately 2-fold and 10-fold decreases in the aspartate and carbamoyl phosphate concentrations at half the maximal observed specific activity respectively, a loss of homotropic cooperativity, and loss of response to the regulatory nucleotides ATP and CTP. Furthermore, equilibrium binding studies indicate that the affinity of the mutant enzyme for CTP is reduced more than 10-fold. The isolated catalytic subunit exhibits a 660-fold reduction in maximal observed specific activity compared to the wild-type catalytic subunit. The Km values for aspartate and carbamoyl phosphate for the Asp-162----Ala catalytic subunit were within 2-fold of the values observed for the wild-type catalytic subunit. Computer simulations of the energy-minimized mutant enzyme indicate that the space once occupied by the side chain of Asp-162 may be filled by other side chains, suggesting that Asp-162 is important for stabilizing the internal architecture of the wild-type enzyme.     

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)     

Function of serine-171 in domain closure, cooperativity, and catalysis in Escherichia coli aspartate transcarbamoylase

Structural studies of Escherichia coli aspartate transcarbamoylase suggest that the R state of the enzyme is stabilized by an interaction between Ser-171 of the aspartate domain and both the backbone carbonyl of His-134 and the side chain of Gln-133 of the carbamoyl phosphate domain of a catalytic chain [Ke, H.-M., Lipscomb, W.N., Cho, Y., & Honzatko, R. B. (1988) J. Mol. Biol. 204, 725-747]. In the present study, site-specific mutagenesis is used to replace Ser-171 by alanine, thereby eliminating the interactions between Ser-171 and both Gln-133 and His-134. The Ser-171----Ala holoenzyme exhibits no cooperativity, more than a 140-fold loss of activity, little change in the carbamoyl phosphate concentration at half the maximal observed specific activity, and a 7-fold increase in the aspartate concentration at half the maximal observed specific activity. Although the Ser-171----Ala enzyme exhibits no homotropic cooperativity, it is still activated by N-(phosphonacetyl)-L-aspartate (PALA), but not by succinate, in the presence of saturating carbamoyl phosphate and subsaturating aspartate. At subsaturating concentrations of aspartate, the Ser-171----Ala enzyme is still activated by ATP but is inhibited less by CTP than is the wild-type enzyme. At saturating concentrations of aspartate, the Ser-171----Ala enzyme is activated by ATP and inhibited by CTP to an even greater extent than at subsaturating concentrations of aspartate. At saturating aspartate, the wild-type enzyme is neither activated by ATP nor inhibited by CTP.(ABSTRACT TRUNCATED AT 250 WORDS)     

A loop involving catalytic chain residues 230-245 is essential for the stabilization of both allosteric forms of Escherichia coli aspartate transcarbamylase

The allosteric transition of Escherichia coli aspartate transcarbamylase involves significant alterations in structure at both the quaternary and tertiary levels. On the tertiary level, the 240s loop (residues 230-245 of the catalytic chain) repositions, influencing the conformation of Arg-229, a residue near the aspartate binding site. In the T state, Arg-229 is bent out of the active site and may be stabilized in this position by an interaction with Glu-272. In the R state, the conformation of Arg-229 changes, allowing it to interact with the beta-carboxylate of aspartate, and is stabilized in this position by a specific interaction with Glu-233. In order to ascertain the function of Arg-229, Glu-233, and Glu-272 in the catalytic and cooperative interactions of the enzyme, three mutant enzymes were created by site-specific mutagenesis. Arg-229 was replaced by Ala, while both Glu-233 and Glu-272 were replaced by Ser. The Arg-229----Ala and Glu-233----Ser enzymes exhibit 10,000-fold and 80-fold decreases in maximal activity, respectively, and they both exhibit a 2-fold increase in the aspartate concentration at half the maximal observed velocity, [S]0.5. The Arg-229----Ala enzyme still exhibits substantial homotropic cooperativity, but all cooperativity is lost in the Glu-233----Ser enzyme. The Glu-233----Ser enzyme also shows a 4-fold decrease in the carbamyl phosphate [S]0.5, while the Arg-229----Ala enzyme shows no change in the carbamyl phosphate [S]0.5 compared to the wild-type enzyme. The Glu-272 to Ser mutation results in a slight reduction in maximal activity, an increase in [S]0.5 for both aspartate and carbamyl phosphate, and reduced cooperativity. Analysis of the isolated catalytic subunits from these three mutant enzymes reveals that in each case the changes in the kinetic properties of the isolated catalytic subunit are similar to the changes caused by the mutation in the holoenzyme. PALA was able to activate the Glu-233----Ser enzyme, at low aspartate concentrations, even though the mutant holoenzyme did not exhibit any cooperativity, indicating that cooperative interactions still exist between the active sites in this enzyme. It is proposed that Glu-233 of the 240s loop helps create the high-activity-high-affinity R state by positioning the side chain of Arg-229 for aspartate binding while Glu-272 helps stabilize the low-activity-low-affinity T state by positioning the side chain of Arg-229 so that it cannot interact with aspartate.(ABSTRACT TRUNCATED AT 400 WORDS)     

Function of arginine-234 and aspartic acid-271 in domain closure, cooperativity, and catalysis in Escherichia coli aspartate transcarbamylase

Two mutant versions of Escherichia coli aspartate transcarbamylase were created by site-specific mutagenesis. Arg-234 of the 240s loop was replaced by serine in order to help deduce the function of the interactions that normally occur between Arg-234 and both Glu-50 and Gln-231 in the R state of the enzyme. The other mutation involved the replacement of Asp-271 by asparagine to further test the functional importance of the Tyr-240-Asp-271 link that has previously been proposed to stabilize the T state of the enzyme [Middleton, S. A., & Kantrowitz, E. R. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 5866-5870]. The Arg-234----Ser holoenzyme exhibits no cooperativity, a 24-fold reduction in maximal velocity, normal affinity for carbamyl phosphate, and substantially reduced affinity for aspartate and N-(phosphonoacetyl)-L-aspartate (PALA). Unlike the wild-type enzyme, the heterotropic effectors ATP and CTP are able to influence the activity of the Arg-234----Ser enzyme at saturating aspartate concentrations. The Arg-234----Ser catalytic subunit exhibits a 33-fold reduction in maximal activity, an aspartate Km of 261 mM, compared to 5.7 mM for the wild-type catalytic subunit, and only a small alteration in the Km for carbamyl phosphate. Together these results provide additional evidence that the interdomain bridging interactions between Glu-50 of the carbamyl phosphate domain and both Arg-167 and Arg-234 of the aspartate domain are necessary for the stabilization of the high-activity-high-affinity configuration of the active site of the enzyme. Furthermore, without the interdomain bridging interactions, the holoenzyme no longer exhibits homotropic cooperativity.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

Negative complementation in aspartate transcarbamylase. Analysis of hybrid enzyme molecules containing different arrangements of polypeptide chains from wild-type and inactive mutant catalytic subunits.

A comprehensive set of hybrid molecules of aspartate transcarbamylase (ATCase) from Escherichia coli has been constructed of wild-type and mutationally altered catalytic chains. The mutant enzymes that were virtually devoid of activity contained a replacement of Gly-128 in the catalytic polypeptide chains by either Asp or Arg. The kinetic properties of these hybrid enzyme-like molecules were analyzed to evaluate the basis for the unusual quaternary constraint demonstrated by an intersubunit hybrid containing one wild-type catalytic subunit, one inactive mutant subunit (containing the Gly to Asp replacement), and three wild-type regulatory subunits. A similar intersubunit hybrid was constructed from the wild-type catalytic subunit and the mutant in which Gly-128 was replaced by Arg, and it too demonstrated a pronounced decrease in activity relative to that expected for a hybrid containing three active sites. Moreover, neither of these hybrid holoenzymes exhibited the cooperativity with respect to aspartate that is characteristic of wild-type ATCase. In contrast, hybrid holoenzymes containing at least one wild-type chain in each catalytic subunit showed cooperativity. Also, hybrid enzymes containing different arrangements of five, four, three, or two wild-type catalytic chains with an appropriate complement of mutant chains had specific activities proportional to the number of wild-type chains in the holoenzymes. Exceptions were observed only in hybrids in which one of the two subunits in the holoenzyme was composed completely of mutant catalytic chains. For these hybrids the negative complementation was manifested as a much lower enzyme activity than expected from the number of wild-type chains in the enzyme and the loss of cooperativity. Thus, the activity and allosteric properties of these hybrids is dependent on the arrangement of catalytic chains in the holoenzyme, in contrast to results obtained for hybrids containing native and chemically modified catalytic chains. Intrasubunit hybrid catalytic trimers containing one or two wild-type chains exhibited one-third and two-thirds the activity of the intact wild-type catalytic subunit, respectively, indicating the dominant negative effect that was seen in intersubunit hybrid holoenzymes is absent within trimers.     

The allosteric activator ATP induces a substrate-dependent alteration of the quaternary structure of a mutant aspartate transcarbamoylase impaired in active site closure.

Aspartate transcarbamoylase from Escherichia coli shows homotropic cooperativity for aspartate as well as heterotropic regulation by nucleotides. Structurally, it consists of two trimeric catalytic subunits and three dimeric regulatory subunits, each chain being comprised of two domains. Glu-50 and Ser-171 are involved in stabilizing the closed conformation of the catalytic chain. Replacement of Glu-50 or Ser-171 by Ala in the holoenzyme has been shown previously to result in marked decreases in the maximal observed specific activity, homotropic cooperativity, and affinity for aspartate (Dembowski NJ, Newton CJ, Kantrowitz ER, 1990, Biochemistry 29:3716-3723; Newton CJ, Kantrowitz ER, 1990, Biochemistry 29:1444-1451). We have constructed a double mutant enzyme combining both mutations. The resulting Glu-50/ser-171-->Ala enzyme is 9-fold less active than the Ser-171-->Ala enzyme, 69-fold less active than the Glu-50-->Ala enzyme, and shows 1.3-fold and 1.6-fold increases in the [S]0.5Asp as compared to the Ser-171-->Ala and Glu-50-->Ala enzymes, respectively. However, the double mutant enzyme exhibits some enhancement of homotropic cooperativity with respect to aspartate, relative to the single mutant enzymes. At subsaturating concentrations of aspartate, the Glu-50/Ser-171 -->Ala enzyme is activated less by ATP than either the Glu-50-->Ala or Ser-171-->Ala enzyme, whereas CTP inhibition is intermediate between that of the two single mutants. As opposed to the wild-type enzyme, the Glu-50/Ser-171 -->Ala enzyme is activated by ATP and inhibited by CTP at saturating concentrations of aspartate. Structural analysis of the Ser-171-->Ala and Glu-50/Ser-171-->Ala enzymes by solution X-ray scattering indicates that both mutants exist in the same T quaternary structure as the wild-type enzyme in the absence of ligands, and in the same R quaternary structure in the presence of saturating N-(phosphonoacetyl)-L-aspartate. However, saturating concentrations of carbamoyl phosphate and succinate are unable to convert a significant fraction of either mutant enzyme population to the R quaternary structure, as has been observed previously for the Glu-50-->Ala enzyme. The curves for both the Ser-171-->Ala and Glu-50/Ser-171-->Ala enzymes obtained in the presence of substoichiometric amounts of PALA are linear combinations of the two extreme T and R states. The structural consequences of nucleotide binding to these two enzymes were also investigated. Most surprisingly, the direction and amplitude of the effect of ATP upon the double mutant enzyme were shown to vary depending upon the substrate analogue used.     

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.     

Site-specific mutagenesis of aspartate transcarbamoylase. Replacement of tyrosine 165 in the catalytic chain by serine reduces enzymatic activity

Site-specific mutagenesis was used to modify an amino acid residue of the catalytic trimer of aspartate transcarbamoylase thought to be at the active site. Tyrosine 165 of the catalytic chain was replaced by a serine residue. This mutation substantially reduces but does not entirely abolish the catalytic activity of the holoenzyme and the isolated catalytic trimer. Km for aspartate for the mutant catalytic trimer is 12-fold higher than for the wild type. Vmax is reduced by a factor of 4 and Kd for carbamoylphosphate is increased 3-fold in the mutant. Although these results suggest that tyrosine 165 is at the active site, they demonstrate that the residue is not essential for catalysis.     

Weakening of the interface between adjacent catalytic chains promotes domain closure in Escherichia coli aspartate transcarbamoylase.

Aspartate transcarbamoylase from Escherichia coli is a dodecameric enzyme consisting of two trimeric catalytic subunits and three dimeric regulatory subunits. Asp-100, from one catalytic chain, is involved in stabilizing the C1-C2 interface by means of its interaction with Arg-65 from an adjacent catalytic chain. Replacement of Asp-100 by Ala has been shown previously to result in increases in the maximal specific activity, homotropic cooperativity, and the affinity for aspartate (Baker DP, Kantrowitz ER, 1993, Biochemistry 32:10150-10158). In order to determine whether these properties were due to promotion of domain closure induced by the weakening of the C1-C2 interface, we constructed a double mutant version of aspartate transcarbamoylase in which the Asp-100-->Ala mutation was introduced into the Glu-50-->Ala holoenzyme, a mutant in which domain closure is impaired. The Glu-50/Asp-100-->Ala enzyme is fourfold more active than the Glu-50-->Ala enzyme, and exhibits significant restoration of homotropic cooperativity with respect to aspartate. In addition, the Asp-100-->Ala mutation restores the ability of the Glu-50-->Ala enzyme to be activated by succinate and increases the affinity of the enzyme for the bisubstrate analogue N-(phosphonacetyl)-L-aspartate (PALA). At subsaturating concentrations of aspartate, the Glu-50/Asp-100-->Ala enzyme is activated more by ATP than the Glu-50-->Ala enzyme and is also inhibited more by CTP than either the wild-type or the Glu-50-->Ala enzyme. As opposed to the wild-type enzyme, the Glu-50/Asp-100-->Ala enzyme is activated by ATP and inhibited by CTP at saturating concentrations of aspartate. Structural analysis of the Glu-50/Asp-100-->Ala enzyme by solution X-ray scattering indicates that the double mutant exists in the same T quaternary structure as the wild-type enzyme in the absence of ligands and in the same R quaternary structure in the presence of saturating PALA. However, saturating concentrations of carbamoyl phosphate and succinate only convert a fraction of the Glu-50/Asp-100-->Ala enzyme population to the R quaternary structure, a behavior intermediate between that observed for the Glu-50-->Ala and wild-type enzymes. Solution X-ray scattering was also used to investigate the structural consequences of nucleotide binding to the Glu-50/Asp-100-->Ala enzyme.     

A single amino acid substitution in the active site of Escherichia coli aspartate transcarbamoylase prevents the allosteric transition

Modeling of the tetrahedral intermediate within the active site of Escherichia coli aspartate transcarbamoylase revealed a specific interaction with the side-chain of Gln137, an interaction not previously observed in the structure of the X-ray enzyme in the presence of N-phosphonacetyl-L-aspartate (PALA). Previous site-specific mutagenesis experiments showed that when Gln137 was replaced by alanine, the resulting mutant enzyme (Q137A) exhibited approximately 50-fold less activity than the wild-type enzyme, exhibited no homotropic cooperativity, and the binding of both carbamoyl phosphate and aspartate were extremely compromised. To elucidate the structural alterations in the mutant enzyme that might lead to such pronounced changes in kinetic and binding properties, the Q137A enzyme was studied by time-resolved, small-angle X-ray scattering and its structure was determined in the presence of PALA to 2.7 angstroms resolution. Time-resolved, small-angle X-ray scattering established that the natural substrates, carbamoyl phosphate and L-aspartate, do not induce in the Q137A enzyme the same conformational changes as observed for the wild-type enzyme, although the scattering pattern of the Q137A and wild-type enzymes in the presence of PALA were identical. The overall structure of the Q137A enzyme is similar to that of the R-state structure of wild-type enzyme with PALA bound. However, there are differences in the manner by which the Q137A enzyme coordinates PALA, especially in the side-chain positions of Arg105 and His134. The replacement of Gln137 by Ala also has a dramatic effect on the electrostatics of the active site. These data taken together suggest that the side-chain of Gln137 in the wild-type enzyme is required for the binding of carbamoyl phosphate in the proper orientation so as to induce conformational changes required for the creation of the high-affinity aspartate-binding site. The inability of carbamoyl phosphate to create the high-affinity binding site in the Q137A enzyme results in an enzyme locked in the low-activity low-affinity T state. These results emphasize the absolute requirement of the binding of carbamoyl phosphate for the creation of the high-affinity aspartate-binding site and for inducing the homotropic cooperativity in aspartate transcarbamoylase.     

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.     

Three residues involved in binding and catalysis in the carbamyl phosphate binding site of Escherichia coli aspartate transcarbamylase

Site-directed mutagenesis was used to create four mutant versions of Escherichia coli aspartate transcarbamylase at three positions in the catalytic chain of the enzyme. The location of all the amino acid substitutions was near the carbamyl phosphate binding site as previously determined by X-ray crystallography. Arg-54, which interacts with both the anhydride oxygen and a phosphate oxygen of carbamyl phosphate, was replaced by alanine. This mutant enzyme was approximately 17,000-fold less active than the wild type, although the binding of substrates and substrate analogues was not altered substantially. Arg-105, which interacts with both the carbonyl oxygen and a phosphate oxygen of carbamyl phosphate, was replaced by alanine. This mutant enzyme exhibited an approximate 1000-fold loss of activity, while the activity of catalytic subunit isolated from this mutant enzyme was reduced by 170-fold compared to the wild-type catalytic subunit. The KD of carbamyl phosphate and the inhibition constants for acetyl phosphate and N-(phosphono-acetyl)-L-aspartate (PALA) were increased substantially by this amino acid substitution. Furthermore, this loss in substrate and substrate analogue binding can be correlated with the large increases in the aspartate and carbamyl phosphate concentrations at half of the maximum observed specific activity, [S]0.5. Gln-137, which interacts with the amino group of carbamyl phosphate, was replaced by both asparagine and alanine. The asparagine mutant exhibited only a small reduction in activity while the alanine mutant was approximately 50-fold less active than the wild type. The catalytic subunits of both these mutant enzymes were substantially more active than the corresponding holoenzymes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Site-specific substitutions of the Tyr-165 residue in the catalytic chain of aspartate transcarbamoylase promotes a T-state preference in the holoenzyme

The amino acid residue Tyr-165C of aspartate transcarbamoylase (EC 2.1.3.2) of Escherichia coli has been proposed to be involved in the transition from the T-state to the R-state upon binding of the bisubstrate analogue N-(phosphonacetyl)-L-aspartate. Site-specific mutagenesis has been used to substitute phenylalanine for tyrosine, thus maintaining the aromatic R-group but removing the charged hydroxyl moiety. This mutation dramatically altered the aspartate requirements for the holoenzyme but did not substantially affect the homotropic or heterotropic characteristics of the oligomer. The aspartate requirements for half-maximal saturation increased from 5.5 mM at pH 7.0 for the native holoenzyme to approximately 90 mM in the mutant enzyme. Nonetheless, estimates of the kinetic cooperativity index remained similar (Hill coefficients: Tyr-165C, n = 2.1; Phe-165C, n = 2.5). CTP inhibited both enzymes approximately 70% and ATP activated approximately 40% at the aspartate concentrations required for half-maximal saturation (5 and 90 mM, respectively). The maximal velocity of the mutant holoenzyme is almost identical to that of the wild-type enzyme. The phenylalanine substitution does not affect the stability of the holoenzyme to heat or mercurials, and the Vmax of the catalytic trimer was 444% greater than that of the holoenzyme. Upon dissociation of the wild-type native enzyme into catalytic trimers, the Vmax increased 450%. The Km for aspartate in the separated catalytic trimer is approximately 2-fold higher than for the native catalytic trimer (16.5 versus 8 mM at pH 7.0). It is clear from the data that although Tyr-165C is not directly involved in the active site of the enzyme, it does play a pivotal role in catalytic transitions of the holoenzyme. In addition, the homotropic and heterotropic characteristics of the enzyme do not seem to be altered by the substitution of phenylalanine for Tyr-165C in the E. coli aspartate transcarbamoylase, although other substitutions have been reported (Robey, E. H., and Schachman, H. K. (1984) J. Biol. Chem. 259, 11180-11183) which show more complex effects.     

Lysine 274 is essential for fructose 2,6-bisphosphate inhibition of fructose-1,6-bisphosphatase.

Lysine 274 is conserved in all known fructose-1,6-bisphosphatase sequences. It has been implicated in substrate binding and/or catalysis on the basis of reactivity with pyridoxal phosphate as well as by x-ray crystallographic analysis. Lys274 of rat liver fructose-1,6-bisphosphatase was mutated to alanine by the polymerase chain reaction, and the T7-RNA polymerase-transcribed construct containing the mutant sequence was expressed in Escherichia coli. The mutant and wild-type forms of the enzyme were purified to homogeneity, and their specific activity, substrate dependence, and inhibition by fructose 2,6-bisphosphate and AMP were compared. While the mutant exhibited no change in maximal velocity, its Km for fructose 1,6-bisphosphate was 20-fold higher than that of the wild-type, and its Ki for fructose 2,6-bisphosphate was increased 1000-fold. Consistent with the unaltered maximal velocity, there were no apparent difference between the secondary structure of the wild-type and mutant enzyme forms, as measured by circular dichroism and ultraviolet difference spectroscopy. The Ki for the allosteric inhibitor AMP was only slightly increased, indicating that Lys274 is not directly involved in AMP inhibition. Fructose 2,6-bisphosphate potentiated AMP inhibition of both forms, but 500-fold higher concentrations of fructose 2,6-bisphosphate were needed to reduce the Ki for AMP for the mutant compared to the wild-type. However, potentiation of AMP inhibition of the Lys274----Ala mutant was evident at fructose 2,6-bisphosphate concentrations (approximately 100 microM) well below those that inhibited the enzyme, which suggests that fructose 2,6-bisphosphate interacts either with the AMP site directly or with other residues involved in the active site-AMP synergy. The results also demonstrate that although Lys274 is an important binding site determinant for sugar bisphosphates, it plays a more significant role in binding fructose 2,6-bisphosphate than fructose 1,6-bisphosphate, probably because it binds the 2-phospho group of the former while other residues bind the 1-phospho group of the substrate. It is concluded that the enzyme utilizes Lys274 to discriminate between its substrate and fructose 2,6-bisphosphate.     

The 80s loop of the catalytic chain of Escherichia coli aspartate transcarbamoylase is critical for catalysis and homotropic cooperativity.

The X-ray structure of the Escherichia coli aspartate transcarbamoylase with the bisubstrate analog phosphonacetyl-L-aspartate (PALA) bound shows that PALA interacts with Lys84 from an adjacent catalytic chain. To probe the function of Lys84, site-specific mutagenesis was used to convert Lys84 to alanine, threonine, and asparagine. The K84N and K84T enzymes exhibited 0.08 and 0.29% of the activity of the wild-type enzyme, respectively. However, the K84A enzyme retained 12% of the activity of the wild-type enzyme. For each of these enzymes, the affinity for aspartate was reduced 5- to 10-fold, and the affinity for carbamoyl phosphate was reduced 10- to 30-fold. The enzymes K84N and K84T exhibited no appreciable cooperativity, whereas the K84A enzyme exhibited a Hill coefficient of 1.8. The residual cooperativity and enhanced activity of the K84A enzyme suggest that in this enzyme another mechanism functions to restore catalytic activity. Modeling studies as well as molecular dynamics simulations suggest that in the case of only the K84A enzyme, the lysine residue at position 83 can reorient into the active site and complement for the loss of Lys84. This hypothesis was tested by the creation and analysis of the K83A enzyme and a double mutant enzyme (DM) that has both Lys83 and Lys84 replaced by alanine. The DM enzyme has no cooperativity and exhibited 0.18% of wild-type activity, while the K83A enzyme exhibited 61% of wild-type activity. These data suggest that Lys84 is not only catalytically important, but is also essential for binding both substrates and creation of the high-activity, high-affinity active site. Since low-angle X-ray scattering demonstrated that the mutant enzymes can be converted to the R-structural state, the loss of cooperativity must be related to the inability of these mutant enzymes to form the high-activity, high-affinity active site characteristic of the R-functional state of the enzyme.     

Site-directed mutagenesis in rat liver 6-phosphofructo-2-kinase. Mutation at the fructose 6-phosphate binding site affects phosphate activation.

To identify those residues involved in fructose 6-phosphate binding to the kinase domain of rat liver 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase site-directed mutations were engineered at Lys194, Arg195, Arg230, and Arg238. The mutant enzymes were purified to homogeneity by anion exchange and Blue-Sepharose chromatography and/or substrate elution from phosphocellulose columns. Circular dichroism experiments demonstrated that all of the single amino acid mutations had no effect on the secondary structure of the protein. In addition, when fructose-2,6-bisphosphatase activity was measured, all mutants had Km values for fructose 2,6-bisphosphate, Ki values for fructose 6-phosphate, and maximal velocities similar to that of the wild-type enzyme. Mutation of Arg195----Ala, or His, had little or no effect on the maximal velocity of the kinase but increased the Km for fructose 6-phosphate greater than 3,000-fold. Furthermore, the Ka for phosphate for Arg195Ala was increased 100-fold compared with the wild-type enzyme. Mutation of Lys194----Ala had no effect on maximal velocity or the Km for fructose 6-phosphate. Mutation of either Arg230 or Arg238----Ala increased the maximal velocity and the Km for fructose-6 phosphate of the kinase by 2-3-fold but had no effect on fructose-2,6-bisphosphatase. However, the Km values for ATP of the Arg230Ala and Arg238Ala mutants were 30-40-fold higher than that for the wild-type enzyme. Mutation of Gly48----Ala resulted in a form with no kinase activity, but fructose-2,6-bisphosphatase activity was identical to that of the wild-type enzyme. The results indicate that: 1) Arg195 is a critical residue for the binding of fructose 6-phosphate to the 6-phospho-fructo-2-kinase domain, and that interaction of the sugar phosphate with Arg195 is highly specific since mutation of the adjacent Lys194----Ala had no effect on fructose 6-phosphate binding; 2) Arg195 also play an important role in the binding of inorganic phosphate; and 3) Gly48 is an important residue in the nucleotide binding fold of 6-phosphofructo-2-kinase and that both Arg230 and Arg238 are also involved in ATP binding; and 4) the bifunctional enzyme has two separate and independent fructose 6-phosphate binding sites.