合成电路识别具有 DNA 损伤持续记忆的亚群。
Synthetic circuit identifies subpopulations with sustained memory of DNA damage.
机构信息
Department of Systems Biology, Harvard Medical School, Boston, Massachusetts 02115, USA.
出版信息
Genes Dev. 2011 Mar 1;25(5):434-9. doi: 10.1101/gad.1994911.
Abstract
Differential responses to stimuli can affect how cells succumb to disease. In yeast, DNA damage can create heterogeneous responses. To delineate how a response contributes to a cell's future behavior, we constructed a transcription-based memory circuit that detects DNA repair to isolate subpopulations with heritable damage responses. Strongly responsive cells show multigenerational effects, including growth defects and iron-associated gene expression. Less-responsive cells exhibit increased mutation frequencies but resume wild-type behavior. These two subpopulations remain distinct for multiple generations, indicating a transmissible memory of damage. Collectively, this work demonstrates the efficacy of using synthetic biology to define how environmental exposure contributes to distinct cell fates.
摘要
对刺激的不同反应会影响细胞对疾病的易感性。在酵母中,DNA 损伤会产生异质的反应。为了描绘出这种反应如何影响细胞的未来行为,我们构建了一个基于转录的记忆电路,用于检测 DNA 修复,以分离具有可遗传损伤反应的亚群。反应强烈的细胞表现出多代效应,包括生长缺陷和与铁相关的基因表达。反应较弱的细胞表现出更高的突变频率,但恢复野生型行为。这两个亚群在多代中仍然保持明显的区别,表明损伤具有可传递的记忆。总的来说,这项工作证明了使用合成生物学来定义环境暴露如何导致不同的细胞命运的有效性。
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