Nautiyal S, Alber T
Department of Molecular and Cell Biology, University of California, Berkeley 94720-3206, USA.
Protein Sci. 1999 Jan;8(1):84-90. doi: 10.1110/ps.8.1.84.
Electrostatic interactions are often critical for determining the specificity of protein-protein complexes. To study the role of electrostatic interactions for assembly of helical bundles, we previously designed a thermostable, heterotrimeric coiled coil, ABC, in which charged residues were employed to drive preferential association of three distinct, 34-residue helices. To investigate the basis for heterotrimer specificity, we have used multiwavelength anomalous diffraction (MAD) analysis to determine the 1.8 A resolution crystal structure of ABC. The structure shows that ABC forms a heterotrimeric coiled coil with the intended arrangement of parallel chains. Over half of the ion pairs engineered to restrict helix associations were apparent in the experimental electron density map. As seen in other trimeric coiled coils, ABC displays acute knobs-into-holes packing and a buried anion coordinated by core polar amino acids. These interactions validate the design strategy and illustrate how packing and polar contacts determine structural uniqueness.
静电相互作用对于确定蛋白质-蛋白质复合物的特异性通常至关重要。为了研究静电相互作用在螺旋束组装中的作用,我们之前设计了一种热稳定的异源三聚体卷曲螺旋ABC,其中利用带电残基驱动三个不同的34个残基螺旋的优先缔合。为了研究异源三聚体特异性的基础,我们使用多波长反常衍射(MAD)分析来确定ABC的1.8埃分辨率晶体结构。该结构表明,ABC形成了具有预期平行链排列的异源三聚体卷曲螺旋。在实验电子密度图中,超过一半用于限制螺旋缔合的离子对清晰可见。正如在其他三聚体卷曲螺旋中所见,ABC显示出尖锐的旋钮-入-孔堆积以及由核心极性氨基酸配位的埋藏阴离子。这些相互作用验证了设计策略,并说明了堆积和极性接触如何决定结构独特性。