质体转化表明，苔藓tRNA(精氨酸)-CCG对质体功能并非必不可少。

Plastid transformation reveals that moss tRNA(Arg)-CCG is not essential for plastid function.

作者信息

Sugiura Chika, Sugita Mamoru

机构信息

Center for Gene Research, Nagoya University, Chikusa, Nagoya 464-8602, Japan.

出版信息

Plant J. 2004 Oct;40(2):314-21. doi: 10.1111/j.1365-313X.2004.02202.x.

DOI:10.1111/j.1365-313X.2004.02202.x

PMID:15447656

Abstract

Three distinct arginine tRNA genes, trnR-CCG, trnR-ACG, and trnR-UCU, are present in the plastid genome of bryophytes, whereas only the latter two trnR genes are present in the major vascular plants, except for black pine. trnR-CCG is located between rbcL and accD in the moss Physcomitrella patens and it was previously believed to be functional in plastids. However, no trnR-CCG transcript has been detected by Northern hybridization, and the codon usage of CGG is quite low in plastid protein-coding sequences. This raises the possibility that trnR-CCG is non-functional. To investigate this possibility, we integrated a foreign gene into the trnR-CCG coding region via homologous recombination, and constructed stable plastid trnR-CCG knock-out moss transformants. The trnR-CCG knock-out transformants grew normally, indicating that the P. patenstrnR-CCG gene is not essential for plastid function.

摘要

苔藓植物的质体基因组中存在三个不同的精氨酸转运RNA基因，即trnR-CCG、trnR-ACG和trnR-UCU，而在主要的维管植物中，除了黑松外，仅存在后两个trnR基因。trnR-CCG位于小立碗藓的rbcL和accD之间，以前人们认为它在质体中具有功能。然而，通过Northern杂交未检测到trnR-CCG转录本，并且CGG在质体蛋白质编码序列中的密码子使用频率相当低。这增加了trnR-CCG无功能的可能性。为了研究这种可能性，我们通过同源重组将一个外源基因整合到trnR-CCG编码区，并构建了稳定的质体trnR-CCG敲除苔藓转化体。trnR-CCG敲除转化体生长正常，这表明小立碗藓的trnR-CCG基因对于质体功能并非必不可少。

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质体转化表明，苔藓tRNA(精氨酸)-CCG对质体功能并非必不可少。

Plastid transformation reveals that moss tRNA(Arg)-CCG is not essential for plastid function.

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