Boehlein S K, Richards N G, Schuster S M
Department of Biochemistry and Molecular Biology, College of Medicine, University of Florida, Gainesville 32610.
J Biol Chem. 1994 Mar 11;269(10):7450-7.
The mechanism of nitrogen transfer in glutamine-dependent amidotransferases remains to be unambiguously established. We now report the overexpression, purification, and kinetic characterization of both the glutamine- and ammonia-dependent activities of Escherichia coli asparagine synthetase B (AS-B) and a series of mutants. In common with other members of the purF family of amidotransferases, the recombinant enzyme possesses an NH2-terminal cysteine residue. Replacement of Cys-1 by either alanine or serine results in a loss of glutaminase and glutamine-dependent activity, without out any significant effect upon ammonia-dependent asparagine synthesis. As previously observed for human AS (Sheng, S., Moraga-Amador, D., Van Heeke, G., Allison, R. D., Richards, N. G. J., and Schuster, S. M. (1993) J. Biol. Chem. 268, 16771-16780), glutamine is an inhibitor of the ammonia-dependent reaction catalyzed by both the Cys-1-->Ala (C1A) and Cys-1-->Ser (C1S) mutants of AS-B. In the case of C1A, the inhibition pattern suggests that an abortive complex is formed. This is consistent with a recent proposal implicating the formation of an imide intermediate in the nitrogen transfer reaction (Richards, N. G. J., and Schuster, S. M. (1992) FEBS Lett. 313, 98-102). In contrast, glutamine appears to be only a competitive inhibitor of the ammonia-dependent activity of C1S. Cys-1 does not appear to be required for glutamine binding. Replacement of Asp-33 by either asparagine or glutamic acid has little effect on the kinetic properties of the mutant enzymes when compared to wild-type AS-B. Cys-1 and Asp-33 are cognate to residues Cys-1 and Asp-29 in glutamine phosphoribosylpyrophosphate amidotransferase which have been proposed to be members of a catalytic triad responsible for mediating nitrogen transfer in this enzyme (Mei, B., and Zalkin, H. (1989) J. Biol. Chem. 264, 16613-16619). In the case of AS-B, although Cys-1 is essential for glutamine-dependent activity, Asp-33 does not appear to participate in mediating nitrogen transfer. In an effort to locate other residues which might form part of a "catalytic triad" in the glutamine amidotransferase domain of AS-B, we have expressed and characterized mutant proteins in which His-29 and His-80, which are conserved within the glutamine amidotransferase domain of purF amidotransferases, are replaced by alanine (H29A and H80A).(ABSTRACT TRUNCATED AT 400 WORDS)
谷氨酰胺依赖性酰胺转移酶中氮转移的机制仍有待明确确立。我们现在报告了大肠杆菌天冬酰胺合成酶B(AS-B)及其一系列突变体的谷氨酰胺依赖性和氨依赖性活性的过表达、纯化及动力学特征。与酰胺转移酶purF家族的其他成员一样,重组酶具有一个NH2末端的半胱氨酸残基。用丙氨酸或丝氨酸取代Cys-1会导致谷氨酰胺酶活性和谷氨酰胺依赖性活性丧失,而对氨依赖性天冬酰胺合成没有任何显著影响。正如之前在人AS中观察到的那样(盛,S.,莫拉加-阿马多尔,D.,范·赫克,G.,艾利森,R.D.,理查兹,N.G.J.,和舒斯特,S.M.(1993)《生物化学杂志》268,16771 - 16780),谷氨酰胺是AS-B的Cys-1→Ala(C1A)和Cys-1→Ser(C1S)突变体催化的氨依赖性反应的抑制剂。就C1A而言,抑制模式表明形成了一种无效复合物。这与最近提出的在氮转移反应中涉及形成酰亚胺中间体的提议一致(理查兹,N.G.J.,和舒斯特,S.M.(1992)《欧洲生物化学学会联合会快报》313,98 - 102)。相比之下,谷氨酰胺似乎只是C1S氨依赖性活性的竞争性抑制剂。Cys-1对于谷氨酰胺结合似乎不是必需的。与野生型AS-B相比,用天冬酰胺或谷氨酸取代Asp-33对突变酶的动力学性质影响很小。Cys-1和Asp-33与谷氨酰胺磷酸核糖焦磷酸酰胺转移酶中的Cys-1和Asp-29残基同源,有人提出它们是负责介导该酶中氮转移的催化三联体的成员(梅,B.,和扎尔金,H.(1989)《生物化学杂志》264,16613 - 16619)。就AS-B而言,尽管Cys-1对于谷氨酰胺依赖性活性至关重要,但Asp-33似乎并未参与介导氮转移。为了找到可能构成AS-B谷氨酰胺酰胺转移酶结构域中“催化三联体”一部分的其他残基,我们表达并表征了其中purF酰胺转移酶谷氨酰胺酰胺转移酶结构域内保守的His-29和His-80被丙氨酸取代的突变蛋白(H29A和H80A)。(摘要截断于400字)
