Catalytic domains of carbamyl phosphate synthetase. Glutamine-hydrolyzing site of Escherichia coli carbamyl phosphate synthetase

We present evidence that cysteine 269 of the small subunit of Escherichia coli carbamyl phosphate synthetase is essential for the hydrolysis of glutamine. When cysteine 269 is replaced with glycine or with serine by site-directed mutagenesis of the carA gene, the resulting enzymes are unable to catalyze carbamyl phosphate synthesis with glutamine as nitrogen donor. Even though the glycine 269, and particularly the serine 269 enzyme bind significant amounts of glutamine, neither glycine 269 nor serine 269 can hydrolyze glutamine. The mutations at cysteine 269 do not affect carbamyl phosphate synthesis with NH3 as substrate. The NH3-dependent activity of the mutant enzymes was equal to that of wild-type. Measurements of Km indicate that the enzyme uses unionized NH3 rather than ammonium ion as substrate. The apparent Km for NH3 of the wild-type enzyme is calculated to be about 5 mM, independent of pH. The substitution of cysteine 269 with glycine or with serine results in a decrease of the apparent Km value for NH3 from 5 mM with the wild-type to 3.9 mM with the glycine, and 2.9 mM with the serine enzyme. Neither the glycine nor the serine mutation at position 269 affects the ability of the enzyme to catalyze ATP synthesis from ADP and carbamyl phosphate. Allosteric properties of the large subunit are also unaffected. However, substitution of cysteine 269 with glycine or with serine causes an 8- and 18-fold stimulation of HCO-3 -dependent ATPase activity, respectively. The increase in ATPase activity and the decrease in apparent Km for NH3 provide additional evidence for an interaction of the glutamine binding domain of the small subunit with one of the two known ATP sites of the large subunit.     

In vivo synthesis of carbamyl phosphate from NH3 by the large subunit of Escherichia coli carbamyl phosphate synthetase

The cloned carAB operon of Escherichia coli coding for the small and large subunits of carbamyl phosphate synthetase has been used to construct a recombinant plasmid with a 4.16 kilobase ClaI fragment of the car operon that lacks the major promoters, P1 and P2. The plasmid, pHN12, carries a functional carB gene. A mutant E. coli strain lacking both subunits of carbamyl phosphate synthetase when transformed with pHN12 overproduces the large subunit by 200-fold (8-10% of the cellular protein). The elevated levels of the large subunit enable the transformed cells to utilize NH3 but not glutamine as nitrogen donor for carbamyl phosphate synthesis. The large subunit has been purified from the overexpressing strain. The purified native large subunit is capable of synthesizing carbamyl phosphate from ammonia, HCO-3, and ATP. The kinetic properties of the large subunit compared with the holoenzyme indicate that the Michaelis constants of the large subunit for HCO-3 and ATP are modulated by its association with the small glutamine binding subunit.     

Estimation of micro amounts of carbamyl phosphate

A simple, fast and sensitive colorimetric method for the assay of carbamyl phosphate is described.     

Nonenzymatic phosphorylation of acetate by carbamyl phosphate

It is found that carbamyl phosphate is an efficient condensing agent for acetate and hydroxylamine in the presence of Be²⁺ and Al³⁺. The reaction has an optimum at pH 4 and is completed within 30 min. The yield of hydroxamate formation reaches 30% (based on initial carbamyl phosphate). Acetylphosphate as the intermediary product of this reaction was identified by P-NMR spectroscopy.     

Pyrimidine-specific carbamyl phosphate synthetase in Neurospora crassa

Two carbamyl phosphate synthetases, the first an arginine-synthetic enzyme (CPS(arg)) and the second a pyrimidine-synthetic enzyme (CPS(pyr)), are shown to be present in Neurospora. The two enzymes can be separated on the basis of size and are distinguished by several different properties. Both CPS(pyr) and CPS(arg) have substrate requirements of adenosine triphosphate, HCO(3) (-), and l-glutamine, although NH(4) (+) in high concentration will partially replace glutamine. CPS(pyr) activity can be completely inhibited by 5 x 10(-4) to 10 x 10(-4)m uridine triphosphate (UTP). CPS(pyr) is cold-labile and can be protected against cold inactivation by UTP. The synthesis of CPS(pyr) and aspartate transcarbamylase (ATC), the initial enzymatic steps of the pyrimidine pathway, are co-derepressed by pyrimidine starvation. Mutations affecting CPS(pyr) and ATC all map at the same locus, pyr-3. Three classes of mutants with respect to the two activities were found: CPS(+)ATC(-), CPS(-)ATC(+), and CPS(-)ATC(-). The distribution of these mutants on the genetic map, together with other data, indicate that the two activities are carried by a bifunctional protein.     

Aspartate transcarbamylase of Escherichia coli. Heterogeneity of binding sites for carbamyl phosphate and fluorinated analogs of carbamyl phosphate.

Some preparations of both native aspartate transcarbamylase from Escherichia coli and catalytic subunit have fewer tight binding sites per oligomer for carbamyl-P than the number of catalytic peptide chains. In contrast, the number of sites for the tight-binding inhibitor N-(phosphonacetyl)-L-aspartate does equal the number of catalytic chains in each case. Binding of the labile carbamyl-P was determined using rapid gel filtration, with conversion to stable carbamyl-L-aspartate during collection. Native enzyme (six catalytic chains) obtained from cells grown under the conditions of J.C. Gerhart and H. Holoubek (J. Biol. Chem. (1967) 242, 2886-2892) has 5.4 tight sites for carbamyl-P at pH 8.0 (KD = 9.9 muM), whereas native enzyme from cells grown with higher concentrations of glucose, uracil, and histidine (to yield more enzyme per unit volume of culture) has only 1.9 tight sites at pH 8.0 (KD = 4.6 muM) and only 2.3 tight sites at pH 7.0 (KD = 2.6 muM). At pH 8.0, catalytic subunit (three catalytic chains) obtained from the former native enzyme has 2.2 tight sites for carbamyl-P (KD = 2.4 muM) and the number of sites is 2.3 in the presence of 35 mM succinate, whereas catalytic subunit obtained from the latter native enzyme has 1.8 tight sites (KD = 3.6 muM) in the absence of succinate and 2.3 tight sites in its presence. The number of tight binding sites is also less than the number of subunit peptide chains in 19F nuclear magnetic resonance experiments performed with catalytic subunit and two fluorinated analogs of carbamyl-P at comparable concentrations of analogs and active sites. A model is proposed in which incomplete removal of formylmethionine from the NH2 termini of the enzyme under conditions of extreme depression affects affinity for ligands.     

Effect of carbamyl phosphate on the regulation of nitrogenase in Clostridium pasteurianum

One mM carbamyl phosphate inhibited the $\text{in}$$\text{vitro}$ acetylene reduction activity of nitrogenase 30% whereas at high concentrations a maximum inhibition of 50% was observed. When 1 mM carbamyl phosphate was added to a culture growing of N₂ 1) nitrogenase synthesis was completely repressed and 2) after a period of 2.5 hrs in the absence of growth, the specific activity decreased to less than 50% of its activity just before the addition of the inhibitor.