Bancroft S, Rhee S G, Neumann C, Kustu S
J Bacteriol. 1978 Jun;134(3):1046-55. doi: 10.1128/jb.134.3.1046-1055.1978.
glnD and glnE mutant strains of Salmonella typhimurium lack three of the four activities required for reversible covalent modification of glutamine synthetase (GS; EC 6.3.1.2). The glnD strains, which are unable to deadenylylate GS and therefore accumulate the adenylylated or less active form of the enzyme, were isolated as glutamine bradytrophs. They lack the activity of PIIA uridylyl-transferase, one of the proteins required for deadenylylation of GS; in addition, they lack PIID uridylyl-removing activity. Mutations in glnD are suppressed by second-site mutations in glnE that eliminate the activity of GS adenylyltransferase (EC 2.7.7.42) and thus prevent adenylylation of GS. The glnD and glnE strains have one-third to one-half as much total GS as the wild-type strain when they are grown in a medium containing a high concentration of NH4+. The wild-type strain derepresses synthesis of GS fourfold in response to nitrogen limitation; glnD and glnE strains derepress synthesis of the enzyme fourfold and sevenfold, respectively. Thus, mutations that alter covalent modification of GS in Salmonella do not significantly affect derepression of its synthesis. The glnD gene lies at 7 min on the Salmonella chromosome and is 50% linked to pyrH by P22-mediated transduction.
鼠伤寒沙门氏菌的glnD和glnE突变株缺乏谷氨酰胺合成酶(GS;EC 6.3.1.2)可逆共价修饰所需的四种活性中的三种。glnD菌株无法使GS去腺苷酸化,因此积累了腺苷酸化形式或活性较低的酶形式,这些菌株是作为谷氨酰胺生长缓慢型菌株分离出来的。它们缺乏GS去腺苷酸化所需的蛋白质之一PIIA尿苷酰转移酶的活性;此外,它们还缺乏PIID尿苷酰去除活性。glnD中的突变可被glnE中的第二位点突变抑制,该突变消除了GS腺苷酰转移酶(EC 2.7.7.42)的活性,从而防止了GS的腺苷酸化。当glnD和glnE菌株在含有高浓度NH4+的培养基中生长时,它们的总GS含量只有野生型菌株的三分之一到二分之一。野生型菌株在氮限制条件下会使GS的合成去阻遏四倍;glnD和glnE菌株分别使该酶的合成去阻遏四倍和七倍。因此,改变沙门氏菌中GS共价修饰的突变不会显著影响其合成的去阻遏。glnD基因位于沙门氏菌染色体的7分钟处,通过P22介导的转导与pyrH有50%的连锁。
