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粗糙脉孢菌生物钟基因频率的光和生物钟表达由白领2蛋白差异驱动,但依赖于它。

Light and clock expression of the Neurospora clock gene frequency is differentially driven by but dependent on WHITE COLLAR-2.

作者信息

Collett Michael A, Garceau Norm, Dunlap Jay C, Loros Jennifer J

机构信息

Department of Biochemistry, Dartmouth Medical School, Hanover, New Hampshire 03755, USA.

出版信息

Genetics. 2002 Jan;160(1):149-58. doi: 10.1093/genetics/160.1.149.

DOI:10.1093/genetics/160.1.149
PMID:11805052
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1461937/
Abstract

Visible light is thought to reset the Neurospora circadian clock by acting through heterodimers of the WHITE COLLAR-1 and WHITE COLLAR-2 proteins to induce transcription of the frequency gene. To characterize this photic entrainment we examined frq expression in constant light, under which condition the mRNA and protein of this clock gene were strongly induced. In continuous illumination FRQ accumulated in a highly phosphorylated state similar to that seen at subjective dusk, the time at which a step from constant light to darkness sets the clock. Examination of frq expression in several wc-2 mutant alleles surprisingly revealed differential regulation when frq expression was compared between constant light, following a light pulse, and darkness (clock-driven expression). Construction of a wc-2 null strain then demonstrated that WC-2 is absolutely required for both light and clock-driven frq expression, in contrast to previous expectations based on presumptive nulls containing altered Zn-finger function. Additionally, we found that frq light signal transduction differs from that of other light-regulated genes. Thus clock and light-driven frq expression is differentially regulated by, but dependent on, WC-2.

摘要

可见光被认为是通过白领-1(WHITE COLLAR-1)和白领-2(WHITE COLLAR-2)蛋白的异二聚体发挥作用,诱导频率基因(frequency gene)转录,从而重置粗糙脉孢菌(Neurospora)的生物钟。为了表征这种光诱导同步,我们检测了在持续光照条件下频率基因(frq)的表达,在这种条件下,该生物钟基因的mRNA和蛋白质被强烈诱导。在持续光照下,FRQ以高度磷酸化的状态积累,类似于在主观黄昏时观察到的状态,即从持续光照到黑暗的转变设定生物钟的时间。对几个wc-2突变等位基因中frq表达的检测令人惊讶地发现,当比较持续光照、光脉冲后以及黑暗(生物钟驱动的表达)条件下的frq表达时,存在差异调节。构建一个wc-2缺失菌株,结果表明WC-2对于光和生物钟驱动的frq表达都是绝对必需的,这与基于推测含有改变的锌指功能的无效突变体的先前预期相反。此外,我们发现frq光信号转导与其他光调节基因的不同。因此,生物钟和光驱动的frq表达受到WC-2的差异调节,但依赖于WC-2。

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