Laboratoire Charles Coulomb (L2C), Univ. Montpellier, CNRS, Montpellier, France.
CNRS, Univ. Grenoble Alpes, TIMC, Grenoble, France.
PLoS Comput Biol. 2021 Apr 16;17(4):e1008869. doi: 10.1371/journal.pcbi.1008869. eCollection 2021 Apr.
ParABS, the most widespread bacterial DNA segregation system, is composed of a centromeric sequence, parS, and two proteins, the ParA ATPase and the ParB DNA binding proteins. Hundreds of ParB proteins assemble dynamically to form nucleoprotein parS-anchored complexes that serve as substrates for ParA molecules to catalyze positioning and segregation events. The exact nature of this ParBS complex has remained elusive, what we address here by revisiting the Stochastic Binding model (SBM) introduced to explain the non-specific binding profile of ParB in the vicinity of parS. In the SBM, DNA loops stochastically bring loci inside a sharp cluster of ParB. However, previous SBM versions did not include the negative supercoiling of bacterial DNA, leading to use unphysically small DNA persistences to explain the ParB binding profiles. In addition, recent super-resolution microscopy experiments have revealed a ParB cluster that is significantly smaller than previous estimations and suggest that it results from a liquid-liquid like phase separation. Here, by simulating the folding of long (≥ 30 kb) supercoiled DNA molecules calibrated with realistic DNA parameters and by considering different possibilities for the physics of the ParB cluster assembly, we show that the SBM can quantitatively explain the ChIP-seq ParB binding profiles without any fitting parameter, aside from the supercoiling density of DNA, which, remarkably, is in accord with independent measurements. We also predict that ParB assembly results from a non-equilibrium, stationary balance between an influx of produced proteins and an outflux of excess proteins, i.e., ParB clusters behave like liquid-like protein condensates with unconventional "leaky" boundaries.
ParABS 是最广泛的细菌 DNA 分离系统,由一个着丝粒序列 parS 和两个蛋白质,ParA ATPase 和 ParB DNA 结合蛋白组成。数百个 ParB 蛋白动态组装形成核蛋白 parS 锚定复合物,作为 ParA 分子催化定位和分离事件的底物。这种 ParBS 复合物的确切性质一直难以捉摸,我们在这里通过重新审视引入的 Stochastic Binding model(SBM)来解决这个问题,该模型用于解释 ParB 在 parS 附近的非特异性结合谱。在 SBM 中,DNA 环随机将基因座带入 ParB 的一个尖锐簇内。然而,以前的 SBM 版本不包括细菌 DNA 的负超螺旋,导致使用不物理上的小 DNA 持久性来解释 ParB 结合谱。此外,最近的超分辨率显微镜实验揭示了 ParB 簇明显小于以前的估计值,并表明它是由液-液相分离产生的。在这里,通过模拟长(≥30kb)超螺旋 DNA 分子的折叠,这些分子经过真实 DNA 参数的校准,并考虑 ParB 簇组装的不同物理可能性,我们表明 SBM 可以定量解释 ChIP-seq ParB 结合谱,而无需任何拟合参数,除了 DNA 的超螺旋密度,这与独立测量结果非常一致。我们还预测 ParB 组装是由产生的蛋白质流入和过量蛋白质流出之间的非平衡、稳定平衡产生的,即 ParB 簇表现为具有非常规“渗漏”边界的类液体蛋白凝聚物。
