Acad. Roumen Tsanev Institute of Molecular Biology, Bulgarian Academy of Sciences, Sofia, Bulgaria.
Oxid Med Cell Longev. 2013;2013:437146. doi: 10.1155/2013/437146. Epub 2013 Aug 19.
Intricate, dynamic, and absolutely unavoidable ageing affects cells and organisms through their entire lifetime. Driven by diverse mechanisms all leading to compromised cellular functions and finally to death, this process is a challenge for researchers. The molecular mechanisms, the general rules that it follows, and the complex interplay at a molecular and cellular level are yet little understood. Here, we present our results showing a connection between the linker histones, the higher-order chromatin structures, and the process of chronological lifespan of yeast cells. By deleting the gene for the linker histone in Saccharomyces cerevisiae we have created a model for studying the role of chromatin structures mainly at its most elusive and so far barely understood higher-order levels of compaction in the processes of yeast chronological lifespan. The mutant cells demonstrated controversial features showing slower growth than the wild type combined with better survival during the whole process. The analysis of the global chromatin organization during different time points demonstrated certain loss of the upper levels of chromatin compaction in the cells without linker histone. The results underlay the importance of this histone for the maintenance of the chromatin loop structures during ageing.
衰老过程复杂、动态且不可避免,会影响细胞和生物体的整个生命周期。受各种机制的驱动,这些机制都会导致细胞功能受损,最终导致死亡,这一过程给研究人员带来了挑战。分子机制、其遵循的一般规则以及分子和细胞水平上的复杂相互作用仍知之甚少。在这里,我们展示了我们的研究结果,表明连接组蛋白、高级染色质结构与酵母细胞的时序寿命之间存在联系。通过删除酿酒酵母中的连接组蛋白基因,我们创建了一个研究染色质结构作用的模型,主要研究其最难以捉摸的高级结构,以及目前几乎不了解的酵母时序寿命过程中压缩的高级结构。突变细胞表现出相互矛盾的特征,表现为生长速度比野生型慢,同时在整个过程中的存活率更高。在不同时间点对整个染色质组织的分析表明,没有连接组蛋白的细胞中,染色质的高级压缩水平会出现一定程度的丢失。这些结果强调了这种组蛋白在衰老过程中维持染色质环结构的重要性。
