Genes responsive to rapamycin and serum deprivation are clustered on chromosomes and undergo re-organization within local chromatin environments.

Z. Belak, Joshua A Pickering, Z. Gillespie, G. Audette, M. Eramian, Jennifer A. Mitchell, J. Bridger, A. Kusalik, C. Eskiw
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引用次数: 5

Abstract

We previously demonstrated that genome reorganization, through chromosome territory repositioning, occurred concurrently with significant changes in gene expression in normal primary human fibroblasts treated with the drug rapamycin, or stimulated into quiescence. Although these events occurred concomitantly, it is unclear how specific changes in gene expression relate to reorganization of the genome at higher resolution. Using computational analyses, genome organization assays and microscopy, the relationship between chromosome territory positioning and gene expression was investigated. We determined that despite relocation of chromosome territories, there was no substantial bias in the proportion of genes changing expression on any one chromosome, including chromosomes 10 and 18. Computational analyses identified that clusters of serum deprivation and rapamycin-responsive genes along the linear extent of chromosomes. Chromosome conformation capture (3C) analysis demonstrated the strengthening or loss of specific long-range chromatin interactions in response to rapamycin and quiescence induction, including a cluster of genes containing Interleukin-8 and several chemokine genes on chromosome 4. We further observed that the LIF gene, which is highly induced upon rapamycin treatment, strengthened interactions with up- and down-stream intergenic regions. Our findings indicate that the re-positioning of chromosome territories in response to cell stimuli, this does not reflect gene expression changes occurring within physically clustered groups of genes.
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响应雷帕霉素和血清剥夺的基因聚集在染色体上,并在局部染色质环境中进行重组。
我们之前已经证明,在接受雷帕霉素治疗或刺激进入静止状态的正常原代人成纤维细胞中,基因组重组(通过染色体区域重新定位)与基因表达的显著变化同时发生。尽管这些事件是同时发生的,但目前尚不清楚基因表达的特定变化如何与更高分辨率的基因组重组相关。通过计算分析、基因组组织分析和显微镜观察,研究了染色体区域定位与基因表达之间的关系。我们确定,尽管染色体区域发生了重新定位,但在任何一条染色体上,包括染色体10和18上,基因表达改变的比例都没有实质性的偏差。计算分析发现,血清剥夺和雷帕霉素反应基因的集群沿着染色体的线性范围。染色体构象捕获(3C)分析表明,在雷帕霉素和静止诱导下,特定的远程染色质相互作用增强或丧失,包括4号染色体上含有白细胞介素-8和几个趋化因子基因的基因簇。我们进一步观察到,受雷帕霉素高度诱导的LIF基因加强了与上游和下游基因间区域的相互作用。我们的研究结果表明,染色体区域的重新定位是对细胞刺激的反应,这并不能反映基因表达在物理上聚集的基因群中发生的变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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