Kriauciunas A, Frolik C A, Hassell T C, Skatrud P L, Johnson M G, Holbrook N L, Chen V J
Department of Biochemistry, Lilly Research Laboratories, Indianapolis, Indiana 46285.
J Biol Chem. 1991 Jun 25;266(18):11779-88.
Isopenicillin N synthase (IPNS) from Cephalosporium acremonium contains 2 cysteine residues in positions 106 and 255 which are invariant in all IPNS sequences reported to date (Miller, J.R., and Ingolia, T.D. (1989) Mol. Microbiol. 3, 689-695). Although these residues have been postulated to play a role in catalysis (Samson, S.M., Chapman, J.L., Belagaje, R., Queener, S., and Ingolia, T.D. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 5705-5709) as well as enzyme inactivation (Perry, D., Abraham, E.P., and Baldwin, J.E. (1988) Biochem. J. 255, 345-351) little information exists regarding their oxidation state and reactivity. In this paper, the functions of these cysteines have been addressed by chemical modification techniques in combination with site-directed mutagenesis. In the intact wild type protein, both cysteines are inert toward 5,5'-dithiobis-(2-nitrobenzoic acid) and iodoacetic acid. However, Cys-106, but not Cys-255, can be slowly modified by N-ethylmaleimide, and its modification is partially blocked by the presence of a substrate analog inhibitor. Complete modification of both cysteines by sulfhydryl reagents requires unfolding of the protein but not the presence of a disulfide reducing agent. The thiol content of IPNS is shown to be the same before and after exposing the enzyme to substrate even though during catalysis the enzyme is rapidly inactivated. The impact on catalysis due to alteration of the cysteines has been assessed using three site-specific mutants: Cys-106----Ser, Cys-255----Ser, and Cys-106,255----Ser. These mutant proteins have been purified as apoenzymes with the nature of the mutation verified by peptide mapping. The stoichiometry of metal required for activity remains as one equivalent of Fe2+/mol of enzyme in the mutants as in wild type IPNS. Compared with wild type, Cys-255----Ser shows a reduction in Vmax by 33%, and an increase in Km by 1.4-fold, while Cys-106----Ser and Cys-106,255----Ser, which have identical kinetic properties, exhibit a decrease in Vmax by 63% but an elevation of Km by 14-fold. The data presented demonstrate that 1) both cysteines are free thiols; 2) Cys-106 is more exposed than Cys-255; 3) substrate-induced inactivation is not caused by cysteine modification; 4) neither cysteine is absolutely essential for bond making or breaking events during catalysis.(ABSTRACT TRUNCATED AT 400 WORDS)
顶头孢霉的异青霉素N合酶(IPNS)在106位和255位含有2个半胱氨酸残基,在迄今报道的所有IPNS序列中这两个位置是不变的(米勒,J.R.,和因戈利亚,T.D.(1989年)《分子微生物学》3,689 - 695)。尽管推测这些残基在催化作用(萨姆森,S.M.,查普曼,J.L.,贝拉加耶,R.,奎纳,S.,和因戈利亚,T.D.(1987年)《美国国家科学院院刊》84,5705 - 5709)以及酶失活过程中起作用(佩里,D.,亚伯拉罕,E.P.,和鲍德温,J.E.(1988年)《生物化学杂志》255,345 - 351),但关于它们的氧化态和反应性的信息却很少。在本文中,通过化学修饰技术结合定点诱变研究了这些半胱氨酸的功能。在完整的野生型蛋白中,两个半胱氨酸对5,5'-二硫代双(2 - 硝基苯甲酸)和碘乙酸都呈惰性。然而,Cys - 106能被N - 乙基马来酰亚胺缓慢修饰,而Cys - 255则不能,并且其修饰被底物类似物抑制剂部分阻断。用巯基试剂完全修饰这两个半胱氨酸需要使蛋白展开,但不需要二硫键还原剂的存在。即使在催化过程中酶迅速失活,IPNS在暴露于底物前后的巯基含量显示是相同的。利用三个位点特异性突变体:Cys - 106→Ser、Cys - 255→Ser和Cys - 106,255→Ser评估了半胱氨酸改变对催化作用的影响。这些突变蛋白已作为脱辅基酶进行了纯化,通过肽图谱验证了突变的性质。突变体中酶活性所需金属的化学计量与野生型IPNS一样,仍然是每摩尔酶1当量的Fe²⁺。与野生型相比,Cys - 255→Ser的Vmax降低了33%,Km增加了1.4倍,而具有相同动力学性质的Cys - 106→Ser和Cys - 106,255→Ser的Vmax降低了63%,但Km升高了14倍。所呈现的数据表明:1)两个半胱氨酸都是游离巯基;2)Cys - 106比Cys - 255更易暴露;3)底物诱导的失活不是由半胱氨酸修饰引起的;4)在催化过程中,两个半胱氨酸对于键的形成或断裂事件都不是绝对必需的。(摘要截短至400字)
