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一种新型的、意想不到的假尿苷合酶,在细菌、古细菌和真核生物中均有同源物。

A novel unanticipated type of pseudouridine synthase with homologs in bacteria, archaea, and eukarya.

作者信息

Kaya Yusuf, Ofengand James

机构信息

Department of Biochemistry and Molecular Biology, University of Miami School of Medicine, Miami, Florida 33101, USA.

出版信息

RNA. 2003 Jun;9(6):711-21. doi: 10.1261/rna.5230603.

DOI:10.1261/rna.5230603
PMID:12756329
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1370438/
Abstract

Putative pseudouridine synthase genes are members of a class consisting of four subgroups that possess characteristic amino acid sequence motifs. These genes have been found in all organisms sequenced to date. In Escherichia coli, 10 such genes have been identified, and the 10 synthase gene products have been shown to function in making all of the pseudouridines found in tRNA and ribosomal RNA except for tRNA(Glu) pseudouridine13. In this work, a protein able to make this pseudouridine was purified by standard biochemical procedures. Amino-terminal sequencing of the isolated protein identified the synthase as YgbO. Deletion of the ygbO gene caused the loss of tRNA(Glu) pseudouridine13 and plasmid-borne restoration of the structural gene restored pseudouridine13. Reaction of the overexpressed gene product, renamed TruD, with a tRNA(Glu) transcript made in vitro also yielded only pseudouridine13. A search of the database detected 58 homologs of TruD spanning all three phylogenetic domains, including ancient organisms. Thus, we have identified a new wide-spread class of pseudouridine synthase with no sequence homology to the previously known four subgroups. The only completely conserved sequence motif in all 59 organisms that contained aspartate was GXKD, in motif II. This aspartate was essential for in vitro activity.

摘要

推定的假尿苷合酶基因是一个由四个亚组组成的类别的成员,这些亚组具有特征性的氨基酸序列基序。这些基因在迄今测序的所有生物体中都已发现。在大肠杆菌中,已鉴定出10个这样的基因,并且已证明这10种合酶基因产物在生成tRNA和核糖体RNA中发现的除tRNA(Glu)假尿苷13之外的所有假尿苷中发挥作用。在这项工作中,通过标准生化程序纯化了一种能够生成这种假尿苷的蛋白质。对分离出的蛋白质进行氨基末端测序,确定该合酶为YgbO。删除ygbO基因导致tRNA(Glu)假尿苷13缺失,而结构基因的质粒介导恢复则恢复了假尿苷13。过量表达的基因产物(重新命名为TruD)与体外合成的tRNA(Glu)转录本反应也仅产生假尿苷13。对数据库的搜索检测到跨越所有三个系统发育域(包括古老生物体)的58个TruD同源物。因此,我们鉴定出了一类新的广泛存在的假尿苷合酶,其与先前已知的四个亚组没有序列同源性。在所有59个含有天冬氨酸的生物体中,唯一完全保守的序列基序是基序II中的GXKD。这个天冬氨酸对于体外活性至关重要。

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