叶绿体多核糖体组装存在缺陷的玉米核突变体具有改变的叶绿体RNA代谢。
Nuclear Mutants of Maize with Defects in Chloroplast Polysome Assembly Have Altered Chloroplast RNA Metabolism.
作者信息
Barkan A.
机构信息
Institute of Molecular Biology, University of Oregon, Eugene, Oregon 97403-1229.
出版信息
Plant Cell. 1993 Apr;5(4):389-402. doi: 10.1105/tpc.5.4.389.
Abstract
The molecular basis for the photosynthetic defect in four nuclear mutants of maize was investigated. Mutants hcf7, cps1-1, cps1-2, and cps2 contained reduced levels of many chloroplast-encoded proteins without corresponding deficiencies in chloroplast mRNAs. Many chloroplast mRNAs were associated with abnormally few ribosomes, indicating that the protein deficiencies were due to global defects in chloroplast translation. These mutants were used to study the effects of reduced ribosome association on the metabolism of chloroplast RNAs. The level of the rbcL mRNA was reduced fourfold in each mutant, but was unaltered in other nonphotosynthetic mutants with normal chloroplast translation. These results suggest that the rbcL mRNA is destabilized as a consequence of its decreased association with ribosomes. The fact that many other chloroplast mRNAs accumulated to normal levels demonstrated that a decreased association with ribosomes does not significantly alter their stabilities or processing. hcf7 seedlings had a gross defect in the processing of the 16S rRNA: the primary lesion in this mutant may be a defect in 16S rRNA processing itself.
摘要
对玉米四个核突变体光合缺陷的分子基础进行了研究。突变体hcf7、cps1-1、cps1-2和cps2中许多叶绿体编码蛋白的水平降低,而叶绿体mRNA没有相应缺陷。许多叶绿体mRNA与异常少的核糖体相关联,这表明蛋白质缺陷是由于叶绿体翻译中的整体缺陷所致。这些突变体被用于研究核糖体结合减少对叶绿体RNA代谢的影响。每个突变体中rbcL mRNA的水平降低了四倍,但在叶绿体翻译正常的其他非光合突变体中未发生改变。这些结果表明,rbcL mRNA由于与核糖体的结合减少而变得不稳定。许多其他叶绿体mRNA积累到正常水平这一事实表明,与核糖体的结合减少不会显著改变它们的稳定性或加工过程。hcf7幼苗在16S rRNA加工方面存在严重缺陷:该突变体的主要损伤可能是16S rRNA加工本身的缺陷。
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