Department of Fundamental Microbiology, University of Lausanne, 1015 Lausanne, Switzerland.
Curr Biol. 2013 Feb 4;23(3):255-9. doi: 10.1016/j.cub.2012.12.025. Epub 2013 Jan 17.
Lateral gene transfer (LGT) is one of the most important processes leading to prokaryotic genome innovation. LGT is typically associated with conjugative plasmids and bacteriophages, but recently, a new class of mobile DNA known as integrating and conjugative elements (ICE) was discovered, which is abundant and widespread among bacterial genomes. By studying at the single-cell level the behavior of a prevalent ICE type in the genus Pseudomonas, we uncover the remarkable way in which the ICE orchestrates host cell differentiation to ensure horizontal transmission. We find that the ICE induces a state of transfer competence (tc) in 3%-5% of cells in a population under nongrowing conditions. ICE factors control the development of tc cells into specific assemblies that we name "mating bodies." Interestingly, cells in mating bodies undergo fewer and slower division than non-tc cells and eventually lyse. Mutations in ICE genes disrupting mating-body formation lead to 5-fold decreased ICE transfer rates. Hence, by confining the tc state to a small proportion of the population, ICE horizontal transmission is achieved with little cost in terms of vertical transmission. Given the low transfer frequencies of most ICE, we anticipate regulation by subpopulation differentiation to be widespread.
横向基因转移(LGT)是导致原核生物基因组创新的最重要过程之一。LGT 通常与可移动的质粒和噬菌体有关,但最近,一种称为整合和共轭元件(ICE)的新型可移动 DNA 被发现,它在细菌基因组中丰富且广泛存在。通过在单细胞水平上研究假单胞菌属中一种普遍存在的 ICE 类型的行为,我们揭示了 ICE 协调宿主细胞分化以确保水平传播的惊人方式。我们发现,ICE 在非生长条件下将种群中 3%-5%的细胞诱导到转移能力(tc)状态。ICE 因子控制 tc 细胞发育成我们称之为“交配体”的特定组合。有趣的是,与非 tc 细胞相比,交配体中的细胞分裂次数更少、速度更慢,最终裂解。破坏交配体形成的 ICE 基因的突变导致 ICE 转移率降低 5 倍。因此,通过将 tc 状态限制在种群的一小部分,ICE 水平传播以最小的垂直传播代价实现。鉴于大多数 ICE 的转移频率较低,我们预计亚群分化的调节将广泛存在。
