Blaber M, Zhang X J, Lindstrom J D, Pepiot S D, Baase W A, Matthews B W
Institute of Molecular Biology, Howard Hughes Medical Institute, Eugene, OR.
J Mol Biol. 1994 Jan 14;235(2):600-24. doi: 10.1006/jmbi.1994.1016.
To determine the effects of different amino acids on the structure and stability of an alpha-helix in the context of a globular protein, all 19 naturally-occurring amino acids were substituted for Ser44 in phage T4 lysozyme. A more restricted set of nine replacements was also made for Val131. Ser44 and Val131 are two of a very limited number of possible sites in T4 lysozyme that are well within alpha-helices, are solvent-exposed and relatively free of interactions with neighboring residues, and are not involved in crystal contacts. High resolution structures for the majority of the mutants, some of which crystallized non-isomorphously with wild-type, were determined. With the exception of proline, the amino acid substitutions caused little if any perturbation of the alpha-helix backbone. Also the beta-branched residues Thr, Val and Ile show no indication of either side-chain or backbone distortion. Therefore, other than proline, there is no evidence that differences in helix propensities are associated with different amounts of strain introduced into the helix. For reference, and also to allow estimates of side-chain entropy, a survey was made of side-chain conformations in 100 well-refined protein structures. As noted previously all side-chains within alpha-helices strongly avoid the g- conformation (chi 1 approximately 60 degrees). This restricts the beta-branched residues Thr, Val and Ile to a single conformer (g+, chi 1 approximately -60 degrees). Asp, Asn, Met and Ser within helices also overwhelmingly prefer the g+ conformation. For Arg, Cys, Gln, Glu, Leu and Lys the t (chi 1 approximately 180 degrees) and g+ conformers are populated roughly equally. Only the aromatic residues, His, Tyr, Trp and Phe prefer the t conformation. These preferences are the same whether the side-chain is buried or solvent-exposed. In general, the side-chain conformations adopted by the residues substituted at positions 44 and 131 correspond to the most commonly observed conformation for the same amino acid in helices in known protein structures. The changes in protein stability for the replacements at site 131 in general agree well with those at site 44 (correlation r = 0.97), suggesting that these may be representative of substitutions at fully solvent-exposed sites in the middle of alpha-helices. The free energy values also agree quite well with those observed for equivalent replacements in a number of soluble alpha-helical model peptides and with data from "host-guest" studies and statistical surveys (r = 0.69 to 0.93).(ABSTRACT TRUNCATED AT 400 WORDS)
为了在球状蛋白的背景下确定不同氨基酸对α-螺旋结构和稳定性的影响,在噬菌体T4溶菌酶中,将所有19种天然存在的氨基酸替换Ser44。还对Val131进行了一组更受限的9种替换。Ser44和Val131是T4溶菌酶中极少数可能位点中的两个,它们完全位于α-螺旋内,暴露于溶剂中且与相邻残基的相互作用相对较少,并且不参与晶体接触。测定了大多数突变体的高分辨率结构,其中一些与野生型非同晶型结晶。除脯氨酸外,氨基酸替换对α-螺旋主链几乎没有扰动。此外,β-分支残基苏氨酸、缬氨酸和异亮氨酸没有显示出侧链或主链扭曲的迹象。因此,除脯氨酸外,没有证据表明螺旋倾向的差异与引入螺旋的不同应变程度相关。作为参考,并且为了估计侧链熵,对100个精修良好的蛋白质结构中的侧链构象进行了调查。如前所述,α-螺旋内的所有侧链都强烈避免g-构象(χ1约为60度)。这将β-分支残基苏氨酸、缬氨酸和异亮氨酸限制在单一构象(g+,χ1约为-60度)。螺旋内的天冬氨酸、天冬酰胺、甲硫氨酸和丝氨酸也绝大多数更喜欢g+构象。对于精氨酸、半胱氨酸、谷氨酰胺、谷氨酸、亮氨酸和赖氨酸,t(χ1约为180度)和g+构象的占据大致相等。只有芳香族残基组氨酸、酪氨酸、色氨酸和苯丙氨酸更喜欢t构象。无论侧链是埋藏的还是暴露于溶剂中的,这些偏好都是相同的。一般来说,在44位和131位取代的残基所采用的侧链构象与已知蛋白质结构中螺旋中相同氨基酸最常观察到的构象相对应。131位取代的蛋白质稳定性变化总体上与44位的变化非常吻合(相关性r = 0.97),这表明这些可能代表α-螺旋中间完全暴露于溶剂的位点的取代。自由能值也与许多可溶性α-螺旋模型肽中等效取代所观察到的值以及“主客体”研究和统计调查的数据非常吻合(r = 0.69至0.93)。(摘要截断于400字)
