(Received for publication, February 11, 1997, and in revised form, May 22, 1997)
From the Department of Biochemistry and Molecular Biology, Wayne State University School of Medicine, Detroit, Michigan 48201
Escherichia coli carbamyl-phosphate synthetase consists of two subunits that act in concert to synthesize carbamyl phosphate. The 40-kDa subunit is an amidotransferase (GLN subunit) that hydrolyzes glutamine and transfers ammonia to the 120-kDa synthetase subunit (CPS subunit). The enzyme can also catalyze ammonia-dependent carbamyl phosphate synthesis if provided with exogenous ammonia. In mammalian cells, homologous amidotransferase and synthetase domains are carried on a single polypeptide chain called CAD. Deletion of the 29-residue linker that bridges the GLN and CPS domains of CAD stimulates glutamine-dependent carbamyl phosphate synthesis and abolishes the ammonia-dependent reaction (Guy, H. I., and Evans, D. R. (1997) J. Biol. Chem. 272, 19906-19912), suggesting that the deletion mutant is trapped in a closed high activity conformation. Since the catalytic mechanisms of the mammalian and bacterial proteins are the same, we anticipated that similar changes in the function of the E. coli protein could be produced by direct fusion of the GLN and CPS subunits. A construct was made in which the intergenic region between the contiguous carA and carB genes was deleted and the sequences encoding the carbamyl-phosphate synthetase subunits were fused in frame. The resulting fusion protein was activated 10-fold relative to the native protein, was unresponsive to the allosteric activator ornithine, and could no longer use ammonia as a nitrogen donor. Moreover, the functional linkage that coordinates the rate of glutamine hydrolysis with the activation of bicarbonate was abolished, suggesting that the protein was locked in an activated conformation similar to that induced by the simultaneous binding of all substrates.
Escherichia coli carbamyl-phosphate synthetase (CPSase1; EC 6.3.5.5) initiates both de novo pyrimidine and arginine biosynthesis (1) and is regulated by metabolites from both pathways. The enzyme consists of a small 40-kDa subunit (GLN subunit), encoded by carA, that hydrolyzes glutamine and transfers ammonia to the large 120-kDa subunit (CPS subunit) (2, 3). The carB gene encodes the large synthetase subunit (CPS subunit), which catalyzes the synthesis of carbamyl phosphate from ammonia, 2 ATP molecules, and bicarbonate (1, 4, 5). Ammonia, not ammonium ion, is the substrate (1), and thus, ammonia generated in situ must therefore be sequestered within the complex to escape protonation in the aqueous phase. Ammonium chloride can also serve as a nitrogen donor for carbamyl phosphate synthesis by the intact enzyme or the isolated synthetase subunit, but only if high enough concentrations are used so that, at neutral pH, there is sufficient ammonia to sustain catalysis at a significant rate.
Mammalian carbamyl phosphate synthesis is catalyzed by CAD (6-8), a multifunctional protein that also has aspartate transcarbamylase and dihydroorotase activities. All of the CAD functions are associated with specific domains and subdomains (9-14) of a 254-kDa polypeptide. Carbamyl phosphate is synthesized by the concerted action of the contiguous GLN and CPS domains (15, 16), which are connected by a 29-residue chain segment, the GC linker. The amino acid sequences of the mammalian domains and the subunits of bacterial CPSase are clearly homologous, suggesting a common tertiary structure (15-25). Moreover, the mechanism of carbamyl phosphate synthesis (1) by both proteins is thought to be identical.
In the accompanying report (26), we showed that deletion of the linker to produce a protein in which the GLN and CPS domains are fused in frame alters the catalytic and regulatory properties of mammalian CPSase. The kcat for glutamine-dependent carbamyl phosphate synthesis is increased 10-fold, whereas the ammonia-dependent reaction is abolished. These observations suggested a model in which the enzyme cycles between two conformations, an open inactive conformation that can bind exogenous ammonia and a catalytically active conformation in which access to the ammonia site on the synthetase subunit is restricted. These conformations are likely to involve changes in the juxtaposition of the GLN and CPS domains made possible by the linker that serves as a spacer, allowing the covalently linked domains to move relative to one another. Deletion of the GC linker was postulated to trap the enzyme in the catalytic conformation. Since the GLN and CPS domains are separate subunits in the E. coli enzyme (2), there are no constraints on the relative position of the domains. To test the idea that the mammalian multifunctional protein arose during the course of evolution by gene fusion, Kern et al. (27) linked the E. coli CPSase subunits together via the mammalian GC linker. The resulting protein was found to be fully functional. Thus, the GC linker is long enough and flexible enough to accommodate any changes in the juxtaposition of the domains that may occur in both mammalian and bacterial proteins.
Based on the similarities of the structure and catalytic mechanism, we anticipated that functional changes analogous to those observed in the mammalian CPSase deletion mutant would be observed if the E. coli CPSase subunits were directly fused to one another. This expectation was confirmed by constructing a recombinant plasmid in which the carA and carB genes were fused in frame and by characterizing the protein expressed in E. coli. This result suggested that the changes in juxtaposition of the GLN and CPS domains, with concomitant changes in catalytic activity and accessibility to exogenous ammonia, are a common feature of this family of enzymes.
pLLK12, a plasmid encoding the small and large subunits of E. coli CPSase, was kindly provided by Dr. Carol Lusty (The Public Health Research Institute of the City of New York, New York), as were E. coli strains RC50 and L673 (28), which are defective in the carA and carB genes encoding the E. coli CPSase subunits. Strain L673 also lacks the lon protease. The recombinant proteins, which are expressed constitutively under the control of the carAB promoter, were isolated from cells grown to stationary phase (28).
Construction of the Recombinant PlasmidsOverlap extension
by polymerase chain reaction (29) was used to delete residues
1620-1675 of the carAB sequence. This region encoded the
carA gene stop codon and the first 12 residues (see Fig. 1
legend) of the carB gene. The loss of an NlaIII
site (residue 1642) in the polymerase chain reaction product confirmed
the deletion. The polymerase chain reaction product included the
BclI and ApaI restriction sites at the 5- and
3
-ends, respectively, which allowed the fragment to be directly
inserted (see Fig. 2) into the corresponding sites located at residues
1390 and 1688 in pLLK12. Standard protocols were followed for all
recombinant DNA methods (30). When pAR14 was transformed (31) into
strain L673, it complemented the defect in the host strain more
effectively than did pLLK12.
Protein Methods and Enzyme Assays
Wild-type E. coli CPSase was isolated from pLLK12 transformants as described previously (28). Protein concentrations were determined by the Bradford method (32). SDS-gel electrophoresis was carried out on 10% polyacrylamide gels (33). The E. coli fusion protein was expressed at high levels and was purified by gel filtration chromatography on a Sephacryl S-300 column followed by DEAE-Sephacryl chromatography using the procedures described for the isolation of the large subunit of E. coli CPSase (37). The CPSase activity was assayed at 37 °C using a radiometric procedure (12, 34) with a buffer consisting of 0.05 M Tris-HCl, pH 7.4, 1 mM dithiothreitol, 5% glycerol, and 25 mM MgCl2. Substrate saturation curves were obtained by assaying 6.8 µg of protein with the concentrations of sodium bicarbonate, glutamine, and ATP, when fixed, held at 5, 3.5, and 10 mM, respectively. A spectrophotometric coupled enzyme assay (35) was used to assay the glutaminase activity.
Gel Filtration ChromatographyThe molecular masses of the recombinant proteins were determined by gel filtration (36) on a 1.9 × 42-cm Sephacryl S-300 column equilibrated in 0.05 M Tris-HCl, pH 7.4, 1 mM dithiothreitol, and 5% glycerol and calibrated with 1 mg of standard proteins (Sigma), carbonic anhydrase (29 kDa), bovine serum albumin (66 kDa), and alcohol dehydrogenase (150 kDa). The void volume was determined with blue dextran. The column was eluted with the equilibration buffer following application of 0.5 ml (14-120 µg) of the test proteins. The elution volume was determined by measuring the CPSase activity, by SDS-gel electrophoresis, or by determining the absorbance at 280 nm.
The carA
and carB genes encoding the subunits of the E. coli CPSase GLN and CPS domains (Fig. 1) were fused
in frame (see "Experimental Procedures" and Fig. 2)
at residues that were exactly homologous to those used in the
construction of the mammalian deletion mutant lacking the GC linker
(26). The resulting construct, pAR14, encodes a fusion protein in which
the carboxyl-terminal end of the GLN subunit is directly linked to the
amino-terminal end of the CPS subunit. When the recombinant plasmid was
transformed into E. coli strain L673, the fusion protein was
expressed (Fig. 3) at a level comparable to that of the
wild-type E. coli protein (~20% of the total cellular
protein) and could be readily purified (see "Experimental
Procedures").
Molecular Mass of the Fusion Protein
The molecular mass of the fused protein was determined by SDS-polyacrylamide gel electrophoresis to be 160 kDa, close to the value calculated from the amino acid sequence. The protein eluted on a calibrated Sephacryl S-300 column as a single species with a calculated molecular mass of 648 kDa, indicating that it is a tetramer.
Function of the Fusion ProteinWhereas the Km of the fusion protein obtained from the ATP saturation curve of the glutamine-dependent CPSase activity was comparable to that of the wild-type protein (Table I), the Vmax was 10-fold higher. Similar results were obtained for the bicarbonate and glutamine saturation curves. Thus, direct fusion of the GLN and CPS domains results in activation of both bacterial and mammalian proteins. In contrast to the mammalian deletion mutant, the E. coli protein could still catalyze the ammonia-dependent reaction. However, the ammonia-dependent activity was so low (0.1% (Table I) to 2% in various preparations) that it was not possible to obtain a reproducible saturation curve.
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ATP saturation curves conducted in the presence of the
CPSase allosteric effectors, the inhibitor UMP and the activator
ornithine (Fig. 4), showed that the regulatory
properties of the fusion protein were also altered. UMP clearly
inhibits the protein, but the major effect is on the
Vmax, not the Km, as observed with the native protein. The Vmax was reduced by
40% in the presence of UMP. The kinetic parameters obtained for the
fusion protein in the presence of ornithine were virtually identical to
the control values, indicating that it could no longer be
allosterically activated.
Coupling of the Glutaminase and Synthetase Activities
The glutaminase activity of the fusion protein was 10-fold higher than the corresponding activity of the wild-type protein when all of the substrates needed for carbamyl phosphate synthesis were present (Table II). The rate of glutamine hydrolysis by native E. coli CPSase is normally suppressed in the absence of the other substrates needed for carbamyl phosphate synthesis (38), but is appreciably activated by ATP and bicarbonate (Table II). Under conditions of saturating bicarbonate and glutamine, the glutaminase activity of the native enzyme increased with increasing ATP concentrations (Fig. 5) to a maximum extrapolated value of 1204 ± 0.131%. The concentration of ATP that produces half-maximal activation is 5.6 ± 1.2 mM. This coupling mechanism is thought to spare glutamine hydrolysis when the concentration of ATP is limiting. However, in the case of the fusion protein (Fig. 5 and Table II), the glutaminase activity is high whether or not ATP and bicarbonate are present, and the addition of these substrates had little further stimulatory effect on the glutaminase activity.
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Elastase Digestion of the Fusion Protein
The low residual
ammonia-dependent activity of the fusion protein could be
explained by limited proteolytic cleavage into separate GLN and CPS
subunits. The trace amounts of a 40-kDa and a 120-kDa species observed
in various preparations are consistent with this explanation. To test
this idea, the purified fusion protein was subjected to limited
elastase digestion (Fig. 6). As expected, the protein
initially exhibited high glutamine-dependent activity and
barely detectable ammonia-dependent activity. As digestion
proceeded, the protein was progressively cleaved into 40- and 120-kDa
fragments, suggesting that cleavage occurred at the fusion junction of
the GLN and CPS subunits. Proteolysis was correlated with a decrease in
the glutamine-dependent activity and a parallel increase in
the ammonia-dependent CPSase activity. On complete
cleavage, the rates of the glutamine- and ammonia-dependent reactions were comparable to those observed for the wild-type protein.
The GLN and CPS domains of CAD are separated by a 29-residue chain segment that is believed to function as a spacer that allows the domains to move relative to one another (26). Deletion of this bridging segment produced profound changes in the catalytic and regulatory properties. In contrast, the domains of E. coli CPSase are separate subunits (2), and there are therefore no covalent constraints on quaternary structural changes. When the carboxyl-terminal end of the GLN subunit was fused to the amino-terminal end of the CPS subunit in a manner exactly analogous to the mammalian deletion mutant, similar functional changes were observed. Whereas the Km values for ATP, bicarbonate, and glutamine were unchanged, the glutamine-dependent CPSase activity increased 10-fold as a result of a corresponding increase in kcat. At the same time, ammonia could no longer serve as the nitrogen-donating substrate. In some preparations, the ammonia-dependent activity was unmeasurable, whereas in others, a small but significant activity could be detected. We attribute this residual ammonia-dependent activity to the presence of trace amounts of the unlinked subunits produced by endogenous proteases. Controlled elastase digestion showed that the artificial junction between the domains was the most susceptible region of the fusion protein to proteolysis. Upon cleavage into individual subunits, the hyperactivity was diminished, and the ammonia-dependent activity was restored. The catalytic properties of the cleaved fusion protein were indistinguishable from those of the native enzyme. This experiment clearly showed that the fusion of the two subunits per se produced the observed functional changes.
These results suggest that E. coli CPSase, like its
mammalian counterpart, can exist in an open inactive conformation in
which the ammonia-binding site on the CPS subunit is accessible and a
closed catalytic conformation that cannot bind ammonia, but in which
the active-site residues are optimally positioned. The question then
becomes, what is the functional advantage of the inactive conformation?
The catalytically active conformation can still bind ATP, bicarbonate,
and glutamine, and the intermediates (ammonia and carboxy phosphate)
are effectively sequestered within the complex (Fig. 7).
While exogenous ammonia cannot serve as a substrate in the
catalytically active conformation, this limitation is not likely to be
physiologically significant since the intracellular concentration of
ammonia in E. coli is normally insufficient to sustain
carbamyl phosphate synthesis. It could be argued that allosteric
activation requires that the enzyme be constrained in a low activity
conformation. The constraints are then released when the activator
binds, allowing the transition to the high activity form of the enzyme.
The observation that allosteric activation is abolished in both the
E. coli fusion protein and the mammalian deletion mutant
would seem to support this interpretation. However, in the wild-type
bacterial and mammalian proteins (6, 39), the allosteric activators
modify the Km, but not the Vmax, whereas converse changes in the kinetic
parameters are produced by direct fusion of the GLN and CPS domains. We
would argue instead that the open inactive conformation is an essential
component of the functional linkage (40-45) between the GLN and CPS
domains. Glutamine hydrolysis proceeds through a thiol ester
intermediate formed by the reaction of glutamine with an essential
cysteine at the active site of the GLN domain. In the absence of ATP
and bicarbonate, the glutaminase activity is very low, but it is
activated when these substrates bind to the synthetase domain. In the
mammalian enzyme, the presence of ATP and bicarbonate does not alter
the Km for glutamine, but increases the
kcat 14-fold (42). Similar observations were
made for the E. coli enzyme (43, 44). This linkage is
thought to be a mechanism for the coordination of glutamine hydrolysis
and the activation of bicarbonate, reactions that occur simultaneously
when all of the substrates are bound. Through the operation of this
coupling mechanism, the rate of glutamine hydrolysis is controlled so
that it matches the rate of carboxy phosphate formation and thus avoids
the wasteful hydrolysis of glutamine or ATP. In native E. coli CPSase, saturating concentrations of ATP and bicarbonate
(Fig. 5 and Table II) increase the glutaminase activity 12-fold
compared with the activity in the presence of bicarbonate alone. By
contrast, in the E. coli CPSase fusion protein, the rate of
hydrolysis of glutamine is independent of the availability of the other
substrates and proceeds apace even in the absence of ATP and
bicarbonate. The high activity conformation assumed by the fusion
protein and the high activity conformation induced by the binding of
ATP and bicarbonate to the synthetase domain are characterized by a
comparable increase in kcat with no appreciable change in the Km for glutamine, suggesting that
these two conformational states are similar.
These studies also suggest a possible role for the nonfunctional GLN domain of mitochondrial CPSase I. This enzyme has a functional CPS domain fused to an inactive GLN domain via a 26-residue connecting chain segment (20, 46). Whereas the GLN domain is clearly homologous to the active amidotransferases, it lacks the active-site cysteine (20, 42) and probably has other, as yet unidentified, mutations (23) that render it inactive. Thus, ammonia is the only nitrogen-donating substrate. Long considered a vestige of the evolutionary history of this family of proteins, there may well have been selective pressures responsible for its retention. However, assuming that an analogous series of conformational changes occur in this enzyme, an open low activity conformation produced by changes in the juxtaposition of the GLN and CPS domains would be necessary for ammonia binding. Once all of the substrates are bound, the enzyme assumes the closed high activity conformation, which promotes catalysis and sequesters the intermediates. In this scheme, the GLN domain, despite its lack of catalytic activity, is an essential component involved in mediating conformational changes that occur during the catalytic cycle.
In summary, the direct fusion of the GLN and CPS domains traps the enzyme in a closed high activity conformation thought to be similar to that induced by the binding of ATP and bicarbonate. The conformational changes, revealed by studies of these constructs, may thus be an important element of the interdomain signaling that coordinates parallel reactions occurring at different sites of the molecule. The observation that similar changes in catalytic and regulatory properties occur in the mammalian deletion mutant and the E. coli fusion protein suggests that a common mechanism may be operative throughout this family of proteins.
We thank Dr. Carol Lusty for the generous gift of plasmids and strains.