MCM2-7 解旋酶通过与 Cdc45 和 GINS 蛋白的结合被激活。
Activation of the MCM2-7 helicase by association with Cdc45 and GINS proteins.
机构信息
Department of Molecular and Cell Biology, Division of Biochemistry and Molecular Biology, University of California, Berkeley, Berkeley, CA 94720, USA.
出版信息
Mol Cell. 2010 Jan 29;37(2):247-58. doi: 10.1016/j.molcel.2009.12.030.
Abstract
MCM2-7 proteins provide essential helicase functions in eukaryotes at chromosomal DNA replication forks. During the G1 phase of the cell cycle, they remain loaded on DNA but are inactive. We have used recombinant methods to show that the Drosophila MCM2-7 helicase is activated in complex with Cdc45 and the four GINS proteins (CMG complex). Biochemical activities of the MCM AAA+ motor are altered and enhanced through such associations: ATP hydrolysis rates are elevated by two orders of magnitude, helicase activity is robust on circular templates, and affinity for DNA substrates is improved. The GINS proteins contribute to DNA substrate affinity and bind specifically to the MCM4 subunit. All pairwise associations among GINS, MCMs, and Cdc45 were detected, but tight association takes place only in the CMG. The onset of DNA replication and unwinding may thus occur through allosteric changes in MCM2-7 affected by the association of these ancillary factors.
摘要
MCM2-7 蛋白在真核生物染色体 DNA 复制叉处提供必需的解旋酶功能。在细胞周期的 G1 期,它们仍结合在 DNA 上,但处于非活性状态。我们使用重组方法表明,果蝇 MCM2-7 解旋酶与 Cdc45 和四个 GINS 蛋白(CMG 复合物)复合后被激活。通过这种关联,MCM AAA+ 马达的生化活性发生改变并增强:ATP 水解速率提高了两个数量级,解旋酶活性在环形模板上稳健,对 DNA 底物的亲和力提高。GINS 蛋白有助于 DNA 底物的亲和力,并特异性结合到 MCM4 亚基上。检测到 GINS、MCM 和 Cdc45 之间的所有成对关联,但仅在 CMG 中发生紧密关联。因此,DNA 复制和解旋的开始可能通过这些辅助因子的关联影响 MCM2-7 的别构变化发生。
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