Orville A M, Chen V J, Kriauciunas A, Harpel M R, Fox B G, Münck E, Lipscomb J D
Department of Biochemistry, Medical School, University of Minnesota, Minneapolis 55455.
Biochemistry. 1992 May 19;31(19):4602-12. doi: 10.1021/bi00134a010.
Isopenicillin N synthase (IPNS) catalyzes double ring closure of the tripeptide (L-alpha-amino-delta-adipoyl)-L-cysteinyl-D-valine (ACV) to form the beta-lactam and thiazolidine rings of penicillin-type antibiotics. Our previous spectroscopic study using IPNS from Cephalosporium acremonium expressed in Escherichia coli [Chen, V. J., Orville, A. M., Harpel, M. R., Frolik, C. A., Surerus, K. K., Münck, E., & Lipscomb, J. D. (1989) J. Biol. Chem. 264, 21677-21681] indicated that a thiolate enters the coordination of the essential active site Fe2+ when ACV binds to IPNS. The presence of an Fe-S bond in the IPNS.ACV complex is confirmed by EXAFS data presented in the preceding paper [Scott, R. A., Wang, S., Eidsness, M. K., Kriauciunas, A., Frolik, C. A. & Chen, V. J. (1992) Biochemistry (preceding paper in this issue)]. However, these studies leave unclear whether the coordinating thiolate derives from ACV or an endogenous cysteine. Here, we examine the spectroscopic properties of three genetically engineered variants of IPNS in which the only two endogenous cysteines are individually and collectively replaced by serine. The EPR, Mössbauer, and optical spectra of the mutant enzymes and their complexes with ACV, NO, or both ACV and NO are found to be essentially the same as those of wild-type IPNS, showing that the endogenous cysteines are not Fe2+ ligands in any of these complexes. Spectral quantitations show that the double Cys----Ser mutation decreases the affinity of the enzyme for ACV by about 6-fold, suggesting that the endogenous cysteines influence the structure of the substrate binding pocket remote from the iron. Thiolate complexation of the Fe2+ is also examined using ACV analogues. All ACV analogues examined in which the cysteinyl thiol moiety is unaltered are found to bind to the IPNS.NO complex to give optical and EPR spectra very similar to those of the ACV complex. In contrast, analogues in which the cysteinyl moiety of ACV is replaced with serine or cysteic acid fail to elicit the characteristic EPR and optical features despite the fact that they are bound with reasonable affinity to the enzyme. These results demonstrate that the thiolate of ACV coordinates the Fe2+. The EPR spectra of both the IPNS.NO and IPNS.ACV.NO complexes are broadened for samples prepared in 17O-enriched water, showing that water (or hydroxide) is also an iron ligand in each case. Thus, the Fe2+ coordination of the IPNS.ACV.NO complex accommodates at least three exogenous ligands.(ABSTRACT TRUNCATED AT 400 WORDS)
异青霉素N合酶(IPNS)催化三肽(L-α-氨基-δ-己二酰基)-L-半胱氨酰-D-缬氨酸(ACV)的双环闭合,形成青霉素类抗生素的β-内酰胺环和噻唑烷环。我们之前使用在大肠杆菌中表达的顶头孢霉IPNS进行的光谱研究[Chen, V. J., Orville, A. M., Harpel, M. R., Frolik, C. A., Surerus, K. K., Münck, E., & Lipscomb, J. D. (1989) J. Biol. Chem. 264, 21677 - 21681]表明,当ACV与IPNS结合时,一个硫醇盐进入必需活性位点Fe2+的配位。前文[Scott, R. A., Wang, S., Eidsness, M. K., Kriauciunas, A., Frolik, C. A. & Chen, V. J. (1992) Biochemistry(本期前文)]给出的扩展X射线吸收精细结构(EXAFS)数据证实了IPNS.ACV复合物中存在Fe-S键。然而,这些研究尚不清楚配位硫醇盐是来自ACV还是内源性半胱氨酸。在此,我们研究了IPNS的三种基因工程变体的光谱性质,其中仅有的两个内源性半胱氨酸分别或同时被丝氨酸取代。发现突变酶及其与ACV、NO或ACV和NO两者形成的复合物的电子顺磁共振(EPR)、穆斯堡尔和光谱与野生型IPNS的基本相同,表明在这些复合物中内源性半胱氨酸都不是Fe2+配体。光谱定量显示,双半胱氨酸突变为丝氨酸使酶对ACV的亲和力降低约6倍,表明内源性半胱氨酸影响远离铁的底物结合口袋的结构。还使用ACV类似物研究了Fe2+的硫醇盐络合。发现所研究的所有半胱氨酰硫醇部分未改变的ACV类似物都与IPNS.NO复合物结合,产生与ACV复合物非常相似的光学和EPR光谱。相反,ACV的半胱氨酰部分被丝氨酸或半胱氨酸酸取代的类似物,尽管它们以合理的亲和力与酶结合,但未能引发特征性的EPR和光学特征。这些结果表明ACV的硫醇盐与Fe2+配位。在富含17O的水中制备的样品中,IPNS.NO和IPNS.ACV.NO复合物的EPR光谱都变宽,表明在每种情况下水(或氢氧化物)也是铁配体。因此,IPNS.ACV.NO复合物的Fe2+配位容纳至少三个外源性配体。(摘要截短于400字)
