Grzesiak Adam L, Matzger Adam J
Department of Chemistry and the Macromolecular Science and Engineering Program, The University of Michigan, Ann Arbor, Michigan 48109-1055.
Cryst Growth Des. 2008;8(1):347-350. doi: 10.1021/cg0703745.
Crystallization of biological macromolecules as high quality single crystals is critical for determining their structure and facilitates the rational design of drugs. Because macromolecules often crystallize in multiple phases that have unique diffraction properties, the selective production of phases is desirable. Furthermore, determining multiple structures allows for a greater understanding of the relationship between crystal packing and conformation. With the aim of exploiting the polymer-induced heteronucleation approach to selectively nucleate multiple macromolecule crystal forms, hen egg white lysozyme (HEWL) was chosen as a model. Selective phase production was achieved under conditions that, in the absence of added heteronuclei, result in crystallization of a single crystal form. Moreover, nucleation rate, which in turn affects the size and quality of HEWL crystals, was controlled by various polymer surfaces. Thus, the polymer-induced heteronucleation approach provides an additional diversity element which can be easily implemented to complement standard crystal growth techniques for the selective production of high quality protein crystals.
生物大分子结晶形成高质量单晶对于确定其结构至关重要,并有助于药物的合理设计。由于大分子通常会在具有独特衍射特性的多个相中结晶,因此选择性地产生这些相是很有必要的。此外,确定多个结构有助于更深入地理解晶体堆积与构象之间的关系。为了利用聚合物诱导的异质成核方法来选择性地使多种大分子晶体形式成核,选择了鸡蛋清溶菌酶(HEWL)作为模型。在没有添加异质核时会导致单一晶体形式结晶的条件下,实现了选择性相的产生。此外,成核速率反过来会影响HEWL晶体的大小和质量,它受到各种聚合物表面的控制。因此,聚合物诱导的异质成核方法提供了一个额外的多样性元素,可以很容易地实施,以补充标准晶体生长技术,用于选择性地生产高质量蛋白质晶体。