哺乳动物发育过程中全基因组调控 DNA 复制时间。
Domain-wide regulation of DNA replication timing during mammalian development.
机构信息
Department of Biological Science, Florida State University, Tallahassee, FL, 32306, USA.
出版信息
Chromosome Res. 2010 Jan;18(1):127-36. doi: 10.1007/s10577-009-9100-8.
Abstract
Studies of replication timing provide a handle into previously impenetrable higher-order levels of chromosome organization and their plasticity during development. Although mechanisms regulating replication timing are not clear, novel genome-wide studies provide a thorough survey of the extent to which replication timing is regulated during most of the early cell fate transitions in mammals, revealing coordinated changes of a defined set of 400-800 kb chromosomal segments that involve at least half the genome. Furthermore, changes in replication time are linked to changes in sub-nuclear organization and domain-wide transcriptional potential, and tissue-specific replication timing profiles are conserved from mouse to human, suggesting that the program has developmental significance. Hence, these studies have provided a solid foundation for linking megabase level chromosome structure to function, and suggest a central role for replication in domain-level genome organization.
摘要
复制时间的研究为深入了解染色体组织的先前难以理解的更高阶层次及其在发育过程中的可塑性提供了一个切入点。虽然调节复制时间的机制尚不清楚,但新的全基因组研究全面调查了在哺乳动物的大多数早期细胞命运转变过程中复制时间受到多大程度的调节,揭示了至少一半基因组涉及的一组定义明确的 400-800 kb 染色体片段的协调变化。此外,复制时间的变化与核内组织和全域转录潜力的变化相关,并且从老鼠到人类,组织特异性的复制时间图谱保持保守,这表明该程序具有发育意义。因此,这些研究为将兆碱基水平的染色体结构与功能联系起来提供了坚实的基础,并表明复制在域级基因组组织中起核心作用。
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