ATP诱导的大肠杆菌MukB蛋白及MukBEF复合物与DNA的收缩作用
ATP-induced shrinkage of DNA with MukB protein and the MukBEF complex of Escherichia coli.
作者信息
Chen Ning, Zinchenko Anatoly A, Yoshikawa Yuko, Araki Sumiko, Adachi Shun, Yamazoe Mitsuyoshi, Hiraga Sota, Yoshikawa Kenichi
机构信息
Department of Physics, Graduate School of Science, Kyoto University, Kyoto 606-8502, Japan.
出版信息
J Bacteriol. 2008 May;190(10):3731-7. doi: 10.1128/JB.01863-07. Epub 2008 Mar 7.
Abstract
Fluorescence microscopic observation of individual T4 DNA molecules revealed that the MukBEF complex (bacterial condensin) and its subunit, the MukB (a member of the SMC [structural maintenance of chromosomes] superfamily) homodimer, of Escherichia coli markedly shrunk large DNA molecules in the presence of hydrolyzable ATP. In contrast, in the presence of ADP or ATP-gammaS, the conformation of DNA was almost not changed. This suggests that the ATPase activity of subunit MukB is essential for shrinking large DNA molecules. Stretching experiments on the shrunken DNA molecules in the presence of ATP and MukBEF indicated a cross-bridging interaction between DNA molecules.
摘要
对单个T4 DNA分子进行荧光显微镜观察发现,大肠杆菌的MukBEF复合物(细菌凝聚素)及其亚基MukB(染色体结构维持[SMC]超家族成员)同型二聚体,在存在可水解ATP的情况下能显著收缩大型DNA分子。相比之下,在存在ADP或ATP-γS的情况下,DNA的构象几乎没有变化。这表明亚基MukB的ATP酶活性对于收缩大型DNA分子至关重要。在ATP和MukBEF存在的情况下对收缩后的DNA分子进行拉伸实验,结果表明DNA分子之间存在交联相互作用。
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