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叶片发育过程中叶绿体mRNA稳定性的变化

Changes in Chloroplast mRNA Stability during Leaf Development.

作者信息

Klaff P., Gruissem W.

机构信息

Department of Plant Biology, University of California, Berkeley, California 94720.

出版信息

Plant Cell. 1991 May;3(5):517-529. doi: 10.1105/tpc.3.5.517.

DOI:10.1105/tpc.3.5.517

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC160019/

Abstract

During spinach leaf development, chloroplast-encoded mRNAs accumulate to different steady-state levels. Their relative transcription rates alone, however, cannot account for the changes in mRNA amount. In this study, we examined the importance of mRNA stability for the regulation of plastid mRNA accumulation using an in vivo system to measure mRNA decay in intact leaves by inhibiting transcription with actinomycin D. Decay of psbA and rbcL mRNAs was assayed in young and mature leaves. The psbA mRNA half-life was increased more than twofold in mature leaves compared with young leaves, whereas rbcL mRNA decayed with a similar relative half-life at both leaf developmental stages. The direct in vivo measurements demonstrated that differential mRNA stability in higher plant plastids can account for differences in mRNA accumulation during leaf development. The role of polysome association in mRNA decay was also investigated. Using organelle-specific translation inhibitors that force mRNAs into a polysome-bound state or deplete mRNAs of ribosomes, we measured mRNA decay in vivo in either state. The results showed that rbcL and psbA mRNAs are less stable when bound to polysomes relative to the polysome-depleted mRNAs and that their stabilities are differentially affected by binding to polysomes. The results suggested that ribosome binding and/or translation of the psbA and rbcL mRNAs may function to modulate the rate of their decay in chloroplasts.

摘要

在菠菜叶片发育过程中，叶绿体编码的mRNA积累到不同的稳态水平。然而，仅其相对转录速率无法解释mRNA量的变化。在本研究中，我们通过使用体内系统，用放线菌素D抑制转录来测量完整叶片中的mRNA衰变，从而研究了mRNA稳定性对质体mRNA积累调控的重要性。在幼叶和成熟叶中检测了psbA和rbcL mRNA的衰变。与幼叶相比，成熟叶中psbA mRNA的半衰期增加了两倍多，而在两个叶片发育阶段，rbcL mRNA以相似的相对半衰期衰变。直接的体内测量表明，高等植物质体中mRNA稳定性的差异可以解释叶片发育过程中mRNA积累的差异。还研究了多核糖体结合在mRNA衰变中的作用。使用细胞器特异性翻译抑制剂使mRNA进入多核糖体结合状态或使mRNA耗尽核糖体，我们在体内测量了两种状态下的mRNA衰变。结果表明，相对于多核糖体耗尽的mRNA，rbcL和psbA mRNA与多核糖体结合时稳定性较低，并且它们的稳定性受到与多核糖体结合的不同影响。结果表明，psbA和rbcL mRNA的核糖体结合和/或翻译可能起到调节其在叶绿体中衰变速率的作用。