BLM, one of the human RecQ helicases, plays a fundamental role in homologous recombination-based error-free DNA repair pathways, which require its translocation and DNA unwinding activities. Although translocation is essential in vivo during DNA repair processes and it provides a framework for more complex activities of helicases, including strand separation and nucleoprotein displacement, its mechanism has not been resolved for any human DNA helicase. Here, we present a quantitative model for the translocation of a monomeric form of BLM along ssDNA. We show that BLM performs translocation at a low adenosine triphosphate (ATP) coupling ratio (1 ATP consumed/1 nucleotide traveled) and moderate processivity (with a mean number of 50 nucleotides traveled in a single run). We also show that the rate-limiting step of the translocation cycle is a transition between two ADP-bound enzyme states. Via opening of the helicase core, this structural change may drive the stepping of BLM along the DNA track by a directed inchworm mechanism. The data also support the conclusion that BLM performs double-stranded DNA unwinding by fully active duplex destabilization.
展开▼
机译:BLM是人类RecQ解旋酶之一,在基于同源重组的无错DNA修复途径中起着基本作用,这需要其易位和DNA解链活性。尽管易位在DNA修复过程中是体内必不可少的,并且它为解旋酶的更复杂的活动(包括链分离和核蛋白置换)提供了框架,但其机制对于任何人类DNA解旋酶都尚未解决。在这里,我们提出了沿ssDNA的单体形式的BLM易位的定量模型。我们显示,BLM在低三磷酸腺苷(ATP)耦合比(消耗1 ATP / 1个核苷酸)和中等生产力(一次运行中平均有50个核苷酸)下进行易位。我们还表明,易位循环的限速步骤是两个ADP结合酶状态之间的过渡。通过解旋酶核心的开放,这种结构变化可以通过定向的蠕虫机制驱动BLM沿着DNA轨道步进。数据还支持BLM通过完全活性的双链去稳定作用进行双链DNA解链的结论。
展开▼
