Mitochondrial Carbamoyl Phosphate Synthetase Activity in the Absence of N‐Acetyl‐l‐glutamate

Abstract

Rat liver carbamoyl-phosphate synthetase I is shown to have synthetase and ATPase activity in the absence of acetylglutamate. K_m values for ATP, Mg²⁺ and K⁺ are greatly increased, the K_m for HCO⁻₃ is not changed much, and the K_m for NH⁺₄ is markedly reduced. V_max for the synthetase reaction is < 20% of that of the acetylglutamate-activated enzyme whereas V_max for the ATPase activity is > 40% of that with acetylglutamate. Pulse-chase experiments with H¹⁴CO⁻₃ show formation of less “active CO₂” (the central intermediate) than with acetylglutamate; ATPase activity is reduced in proportion, but the synthetase activity is much smaller. Binding of one ATP molecule with high affinity (K_d=20–30μM) is shown in the absence of acetylglutamate. This appears to be the molecule of ATP_B (ATP_B provides the phosphoryl group of carbamoyl phosphate). In contrast, the affinity for ATP_A (ATP_A yields P_i) is much reduced. Initial velocity measurements without acetylglutamate show a time lag before reaching a constant velocity. At 50 μM acetylglutamate the lag is much longer, but at 10 μM acetylglutamate it is shorter. Activation by acetylglutamate requires ATP at concentrations sufficient to occupy the ATP_A and the ATP_B binding sites. Preincubation with 10 mM acetylglutamate alone shortens the activation time. From these findings we propose an allosteric model for activation of carbamoyl-phosphate synthetase in which there are two active states, R and R · AcGlu. Binding of ATP_A is associated with the conversion of T to R. R · AcGlu differs from R in that transfer to carbamate of the γ-phosphoryl group of ATP_B appears to be facilitated.