Liwo A, Gibson K D, Scheraga H A, Brandt-Rauf P W, Monaco R, Pincus M R
Department of Pathology, State University of New York, Health Science Center, Syracuse 13210.
J Protein Chem. 1994 Feb;13(2):237-51. doi: 10.1007/BF01891982.
Oncogenic p21 protein, encoded by the ras-oncogene, that causes malignant transformation of normal cells and many human tumors, is almost identical in sequence to its normal protooncogene-encoded counterpart protein, except for the substitution of arbitrary amino acids for the normally occurring amino acids at critical positions such as Gly 12 and Gln 61. Since p21 is normally activated by the binding of GTP in place of GDP, it has been postulated that oncogenic forms must retain bound GTP for prolonged time periods. However, two multiply substituted p21 proteins have been cloned, neither of which binds GDP or GTP. One of these mutant proteins with Val for Gly 10, Arg for Gly 12, and Thr for Ala 59 causes cell transformation, while the other, similar protein with Gly 10, Arg 12, Val for Gly 13 and Thr 59 does not transform cells. To define the critical conformational changes that occur in the p21 protein that cause it to become oncogenic, we have calculated the low energy conformations of the two multiply substituted mutant p21 proteins using a new adaptation of the electrostatically driven Monte Carlo (EDMC) technique, based on the program ECEPP. We have used this method to explore the conformational space available to both proteins and to compute the average structures for both using statistical mechanical averaging. Comparison of the average structures allows us to detect the major differences in conformation between the two proteins. Starting structures for each protein were calculated using the recently deposited x-ray crystal coordinates for the p21 protein, that was energy-refined using ECEPP, and then perturbed using the EDMC method to compute its average structure. The specific amino acid substitutions for both proteins were then generated into the lowest energy structure generated by this procedure, subjected to energy minimization and then to full EDMC perturbations. We find that both mutant proteins exhibit major differences in conformation in specific regions, viz., residues 35-47, 55-78, 81-93, 96-110, 115-126, and 123-134, compared with the EDMC-refined x-ray structure of the wild-type protein. These regions have been found to be the most flexible in the p21 protein bound to GDP from prior molecular dynamics calculations (Dykes et al., 1993). Comparison of the EDMC-average structure of the transforming mutant with that of the nontransforming mutant reveals major structural differences at residues 10-16, 32-40, and 60-68. These structural differences appear to be the ones that are critical in activation of the p21 protein.(ABSTRACT TRUNCATED AT 400 WORDS)
由ras癌基因编码的致癌性p21蛋白可导致正常细胞发生恶性转化并引发多种人类肿瘤,其序列与其正常原癌基因编码的对应蛋白几乎完全相同,只是在关键位置(如甘氨酸12和谷氨酰胺61)上,任意氨基酸取代了正常存在的氨基酸。由于p21通常通过结合GTP而非GDP被激活,因此推测致癌形式的p21必须长时间保持与GTP的结合。然而,已克隆出两种多重取代的p21蛋白,它们都不结合GDP或GTP。其中一种突变蛋白在第10位由缬氨酸取代甘氨酸、第12位由精氨酸取代甘氨酸、第59位由苏氨酸取代丙氨酸,可导致细胞转化,而另一种类似的蛋白在第10位为甘氨酸、第12位为精氨酸、第13位由缬氨酸取代甘氨酸、第59位为苏氨酸,则不能使细胞转化。为了确定p21蛋白中发生的导致其致癌的关键构象变化,我们基于ECEPP程序,对静电驱动蒙特卡罗(EDMC)技术进行了新的改进,计算了这两种多重取代突变p21蛋白的低能构象。我们使用该方法探索了两种蛋白可利用的构象空间,并通过统计力学平均计算了它们的平均结构。平均结构的比较使我们能够检测出两种蛋白在构象上的主要差异。每种蛋白的起始结构是利用最近公布的p21蛋白的x射线晶体坐标计算得出的,该坐标使用ECEPP进行了能量优化,并随后使用EDMC方法进行微扰以计算其平均结构。然后,将两种蛋白的特定氨基酸取代引入此过程生成的最低能量结构中,进行能量最小化,然后进行完全的EDMC微扰。我们发现,与野生型蛋白经EDMC优化的x射线结构相比,两种突变蛋白在特定区域(即残基35 - 47、55 - 78、81 - 93、96 - 110、115 - 126和123 - 134)的构象存在重大差异。根据先前的分子动力学计算(戴克斯等人,1993年),这些区域在与GDP结合的p21蛋白中是最灵活的。将转化型突变体的EDMC平均结构与非转化型突变体的结构进行比较,发现在残基10 - 16、32 - 40和60 - 68处存在重大结构差异。这些结构差异似乎是p21蛋白激活过程中的关键因素。(摘要截选至400字)
