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心脏慢性缺氧的综合转录组反应:翻译调控因子与细胞存活中的应激反应

Integrated transcriptomic response to cardiac chronic hypoxia: translation regulators and response to stress in cell survival.

作者信息

Iacobas Dumitru A, Fan Chenhao, Iacobas Sanda, Haddad Gabriel G

机构信息

DP Purpura Department of Neuroscience, Kennedy Center, Albert Einstein College of Medicine, Bronx, NY 10461, USA.

出版信息

Funct Integr Genomics. 2008 Aug;8(3):265-75. doi: 10.1007/s10142-008-0082-y. Epub 2008 May 1.

DOI:10.1007/s10142-008-0082-y
PMID:18446526
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2856931/
Abstract

Complementary deoxyribonucleic acid microarray data from 36 mice subjected for 1, 2, or 4 weeks of their early life to normal atmospheric conditions (normoxia) or chronic intermittent (CIH) or constant (CCH) hypoxia were analyzed to extract organizational principles of the developing heart transcriptome and determine the integrated response to oxygen deprivation. Although both CCH and CIH regulated numerous genes involved in a wide diversity of processes, the changes in maturational profile, expression stability, and coordination were vastly different between the two treatments, indicating the activation of distinct regulatory mechanisms of gene transcription. The analysis focused on the main regulators of translation and response to stress because of their role in the cardiac hypertrophy and cell survival in hypoxia. On average, the expression of each heart gene was tied to the expression of about 20% of other genes in normoxia but to only 8% in CCH and 9% in CIH, indicating a strong decoupling effect of hypoxia. In contrast to the general tendency, the interlinkages among components of the translational machinery and response to stress increased significantly in CIH and much more in CCH, suggesting a coordinated response to the hypoxic stress. Moreover, the transcriptomic networks were profoundly and differently remodeled by CCH and CIH.

摘要

分析了36只小鼠的互补脱氧核糖核酸微阵列数据,这些小鼠在生命早期分别经历了1周、2周或4周的正常大气条件(常氧)、慢性间歇性(CIH)或持续性(CCH)缺氧,以提取发育中心脏转录组的组织原则,并确定对缺氧的综合反应。尽管CCH和CIH都调节了许多参与广泛过程的基因,但两种处理之间在成熟特征、表达稳定性和协调性方面的变化却大不相同,这表明基因转录的不同调节机制被激活。由于翻译的主要调节因子和对应激的反应在心肌肥大和缺氧时的细胞存活中起作用,因此分析集中于此。平均而言,在常氧条件下,每个心脏基因的表达与约20%的其他基因的表达相关,但在CCH中仅与8%相关,在CIH中与9%相关,这表明缺氧具有很强的解耦效应。与一般趋势相反,翻译机制的组成部分与对应激的反应之间的相互联系在CIH中显著增加,在CCH中增加得更多,这表明对缺氧应激有协调反应。此外,CCH和CIH对转录组网络进行了深刻且不同的重塑。

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