Department of Molecular and Cellular Biology, Harvard University, Cambridge, MA 02138, USA.
Cell. 2013 May 9;153(4):882-95. doi: 10.1016/j.cell.2013.04.006. Epub 2013 Apr 25.
Visualization of living E. coli nucleoids, defined by HupA-mCherry, reveals a discrete, dynamic helical ellipsoid. Three basic features emerge. (1) Nucleoid density coalesces into longitudinal bundles, giving a stiff, low-DNA-density ellipsoid. (2) This ellipsoid is radially confined within the cell cylinder. Radial confinement gives helical shape and directs global nucleoid dynamics, including sister segregation. (3) Longitudinal density waves flux back and forth along the nucleoid, with 5%-10% of density shifting within 5 s, enhancing internal nucleoid mobility. Furthermore, sisters separate end-to-end in sequential discontinuous pulses, each elongating the nucleoid by 5%-15%. Pulses occur at 20 min intervals, at defined cell-cycle times. This progression includes sequential installation and release of programmed tethers, implying cyclic accumulation and relief of intranucleoid mechanical stress. These effects could comprise a chromosome-based cell-cycle engine. Overall, the presented results suggest a general conceptual framework for bacterial nucleoid morphogenesis and dynamics.
活大肠杆菌核体的可视化,由 HupA-mCherry 定义,显示出离散的、动态的螺旋椭球体。出现了三个基本特征。(1)核体密度凝聚成纵向束,形成刚性、低 DNA 密度的椭球体。(2)这个椭球体在细胞圆柱体内径向受限。径向限制赋予了螺旋形状,并指导全局核体动力学,包括姐妹分离。(3)纵向密度波在核体上前后通量,5%到 10%的密度在 5 秒内转移,增强了内部核体的流动性。此外,姐妹以连续的不连续脉冲末端到末端分离,每次使核体延长 5%到 15%。脉冲发生在 20 分钟的间隔,在特定的细胞周期时间。这一进展包括有计划的系链的顺序安装和释放,暗示着核体内机械应力的周期性积累和缓解。这些效应可能构成基于染色体的细胞周期引擎。总的来说,所呈现的结果提出了一个细菌核体形态发生和动力学的通用概念框架。