拟南芥生物钟基因 PRR5 在调控避荫反应中的独特功能。

The unique function of the Arabidopsis circadian clock gene PRR5 in the regulation of shade avoidance response.

机构信息

Department of Biological Science; Graduate School of Science; The University of Tokyo; Tokyo, Japan.

出版信息

Plant Signal Behav. 2013 Apr;8(4):e23534. doi: 10.4161/psb.23534. Epub 2013 Jan 18.

DOI:10.4161/psb.23534

PMID:23333981

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7030191/

Abstract

Shade avoidance response (S.A.R) is regulated by light and circadian clock. Circadian clock controls S.A.R by the transcriptional regulation of positive regulators of S.A.R, PIF4 and PIF5, to prevent plants from responding to 'light' of dark period. Thus, in many cases, deficits in circadian clock appear in abnormalities of hypocotyl and/or petiole elongation. Previously, interesting phenomena were reported that the triple mutants of PSEUDO RESPONSE REGULATORS9, 7 and 5, which are clock components, show longer petioles and smaller leaves under light/dark cycle than those under continuous lighting. These S.A.R-like phenotypes cannot be explained by their hyposensitivity to red light. We demonstrated detailed analyses of this mutant to reveal the leaf-specific S.A.R regulated by circadian clock. Expression analyses of S.A.R-related genes suggested that PRR5 functions as a repressor of S.A.R. Morphological analyses of leaves under different light condition revealed that PRR5 is involved in the inhibition of leaf expansion in S.A.R.

摘要

避荫反应（SAR）受光和生物钟调节。生物钟通过 SAR 的正调控因子 PIF4 和 PIF5 的转录调控来控制 SAR，以防止植物对暗期“光”的反应。因此，在许多情况下，生物钟的缺陷似乎会导致下胚轴和/或叶柄伸长的异常。以前曾报道过有趣的现象，即拟南芥生物钟成分的 PSEUDO RESPONSE REGULATORS9、7 和 5 的三重突变体在光/暗循环下的叶柄比连续光照下的长，叶片比连续光照下的小。这些类似于 SAR 的表型不能用它们对红光的低敏感性来解释。我们对该突变体进行了详细的分析，以揭示受生物钟调节的叶片特异性 SAR。SAR 相关基因的表达分析表明，PRR5 作为 SAR 的阻遏物发挥作用。在不同光照条件下叶片的形态分析表明，PRR5 参与了 SAR 中叶片扩张的抑制。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/eb7e/7030191/86c17021364c/kpsb-08-04-10923534-g001.jpg

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拟南芥生物钟基因 PRR5 在调控避荫反应中的独特功能。

The unique function of the Arabidopsis circadian clock gene PRR5 in the regulation of shade avoidance response.

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