Spolaore B, Bermejo R, Zambonin M, Fontana A
CRIBI Biotechnology Centre, University of Padua, Italy.
Biochemistry. 2001 Aug 14;40(32):9460-8. doi: 10.1021/bi010582c.
Proteolysis experiments have been used to monitor the conformational transitions from an unfolded to a folded state occurring when the apo form of horse cytochrome c (cyt c) binds the heme moiety or when two fragments of cyt c form a native-like 1:1 complex. Proteinase K was used as a proteolytic probe, in view of the fact that the broad substrate specificity of this protease allows digestion at many sites along a polypeptide chain. The rather unfolded apo form of cyt c binds heme with a concomitant conformational transition to a folded species characterized by an enhanced content of helical secondary structure. While the holoprotein is fully resistant to proteolytic digestion and the apoprotein is digested to small peptides, the noncovalent complex of the apoprotein and heme exhibits an intermediate resistance to proteolysis, in agreement with the fact that the more folded structure of the complex makes the protein substrate more resistant to proteolysis. The noncovalent native-like complex of the two fragments 1-56 and 57-104 of cyt c, covering the entire polypeptide chain of 104 residues of the protein, is rather resistant to proteolysis, while the individual fragments are easily digested. Fragment 57-104 is fast degraded to several peptides, while fragment 1-56 is slowly degraded stepwise from its C-terminal end, leading initially mostly to fragments 1-48 and 1-40 and, at later stages of proteolysis, fragments 1-38, 1-35, 1-33, and 1-31. Thus, proteolysis data indicate that the heme containing fragment 1-56 has a rather compact core and a C-terminal flexible tail. Upon prolonged incubation of the complex of fragments 1-56 and 57-104 (nicked cyt c) with proteinase K, a chain segment is removed from the nicked protein, leading to a gapped protein complex of fragments of 1-48 and 57-104 and, on further digestion, fragments 1-40 and 57-104. Of interest, the chain segment being removed by proteolysis of the complex matches the omega-loop which is evolutionarily removed in cyt c of microbial origin. Overall, rates and/or resistance to proteolysis correlates well with the extent of folding of the protein substrates, as deduced from circular dichroism measurements. Thus, our results underscore the utility of proteolytic probes for analyzing conformational and dynamic features of proteins. Finally, a specific interest of the cyt c fragment system herewith investigated resides in the fact that the fragments are exactly the exon products of the cyt c gene.
蛋白水解实验已被用于监测马细胞色素c(cyt c)的脱辅基形式结合血红素部分时或cyt c的两个片段形成类似天然的1:1复合物时发生的从未折叠状态到折叠状态的构象转变。鉴于这种蛋白酶广泛的底物特异性允许在多肽链上的许多位点进行消化,因此使用蛋白酶K作为蛋白水解探针。cyt c相当未折叠的脱辅基形式与血红素结合,同时发生构象转变,形成以螺旋二级结构含量增加为特征的折叠物种。虽然全蛋白对蛋白水解消化完全有抗性,脱辅基蛋白被消化成小肽,但脱辅基蛋白和血红素的非共价复合物对蛋白水解表现出中等抗性,这与复合物更折叠的结构使蛋白质底物对蛋白水解更具抗性这一事实相符。cyt c的两个片段1-56和57-104的非共价类似天然的复合物覆盖了该蛋白质104个残基的整个多肽链,对蛋白水解相当有抗性,而单个片段很容易被消化。片段57-104迅速降解为几种肽,而片段1-56从其C末端逐步缓慢降解,最初主要产生片段1-48和1-40,在蛋白水解的后期阶段产生片段1-38、1-35、1-33和1-31。因此,蛋白水解数据表明含血红素的片段1-56有一个相当紧密的核心和一个C末端柔性尾巴。将片段1-56和57-104的复合物(带切口的cyt c)与蛋白酶K长时间孵育后,一个链段从带切口的蛋白质中被去除,导致形成片段1-48和57-104的有缺口的蛋白质复合物,进一步消化后形成片段1-40和5-104。有趣的是,通过复合物的蛋白水解去除的链段与微生物来源的cyt c中进化上被去除的ω环相匹配。总体而言,蛋白水解的速率和/或抗性与蛋白质底物的折叠程度密切相关,这是通过圆二色性测量推断出来的。因此,我们的结果强调了蛋白水解探针在分析蛋白质的构象和动态特征方面的实用性。最后,此处研究的cyt c片段系统的一个特别有趣之处在于这些片段恰好是cyt c基因的外显子产物。
