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昼夜阴阳调节及其对基因表达进行全局重编程的调控

Circadian yin-yang regulation and its manipulation to globally reprogram gene expression.

作者信息

Xu Yao, Weyman Philip D, Umetani Miki, Xiong Jing, Qin Ximing, Xu Qing, Iwasaki Hideo, Johnson Carl Hirschie

机构信息

Department of Biological Sciences, Vanderbilt University, Nashville, TN 37235, USA.

出版信息

Curr Biol. 2013 Dec 2;23(23):2365-74. doi: 10.1016/j.cub.2013.10.011. Epub 2013 Nov 7.

DOI:10.1016/j.cub.2013.10.011

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3889637/

Abstract

BACKGROUND

The cyanobacterial circadian program exerts genome-wide control of gene expression. KaiC undergoes rhythms of phosphorylation that are regulated by interactions with KaiA and KaiB. The phosphorylation status of KaiC is thought to mediate global transcription via output factors SasA, CikA, LabA, RpaA, and RpaB. Overexpression of kaiC has been reported to globally repress gene expression.

RESULTS

Here, we show that the positive circadian component KaiA upregulates "subjective dusk" genes and that its overexpression deactivates rhythmic gene expression without significantly affecting growth rates in constant light. We analyze the global patterns of expression that are regulated by KaiA versus KaiC and find in contrast to the previous report of KaiC repression that there is a "yin-yang" regulation of gene expression whereby kaiA overexpression activates "dusk genes" and represses "dawn genes," whereas kaiC overexpression complementarily activates dawn genes and represses dusk genes. Moreover, continuous induction of kaiA latched KaiABC-regulated gene expression to provide constitutively increased transcript levels of diverse endogenous and heterologous genes that are expressed in the predominant subjective dusk phase. In addition to analyzing KaiA regulation of endogenous gene expression, we apply these insights to the expression of heterologous proteins whose products are of potential value, namely human proinsulin, foreign luciferase, and exogenous hydrogenase.

CONCLUSIONS

Both KaiC and KaiA complementarily contribute to the regulation of circadian gene expression via yin-yang switching. Circadian patterns can be reprogrammed by overexpression of kaiA or kaiC to constitutively enhance gene expression, and this reprogramming can improve 24/7 production of heterologous proteins that are useful as pharmaceuticals or biofuels.

摘要

背景

蓝藻生物钟程序对基因表达进行全基因组控制。KaiC经历磷酸化节律，该节律受与KaiA和KaiB相互作用的调节。KaiC的磷酸化状态被认为通过输出因子SasA、CikA、LabA、RpaA和RpaB介导全局转录。据报道，kaiC的过表达会全局抑制基因表达。

结果

在此，我们表明生物钟正向组分KaiA上调“主观黄昏”基因，其过表达会使节律性基因表达失活，而在持续光照下对生长速率无显著影响。我们分析了由KaiA与KaiC调节的全局表达模式，发现与之前关于KaiC抑制的报道相反，存在基因表达的“阴阳”调节，即kaiA过表达激活“黄昏基因”并抑制“黎明基因”，而kaiC过表达则互补性地激活黎明基因并抑制黄昏基因。此外，持续诱导kaiA可锁定KaiABC调节的基因表达，以持续提高在主要主观黄昏阶段表达的多种内源和异源基因的转录水平。除了分析KaiA对内源基因表达的调节外，我们还将这些见解应用于具有潜在价值的异源蛋白的表达，即人胰岛素原、外源荧光素酶和外源氢化酶。

结论

KaiC和KaiA都通过阴阳转换互补地参与生物钟基因表达的调节。通过过表达kaiA或kaiC可重新编程生物钟模式，以组成性增强基因表达，这种重新编程可改善作为药物或生物燃料的异源蛋白的全天候生产。