Ofengand J, Bakin A
Department of Biochemistry and Molecular Biology, University of Miami School of Medicine, FL 33101, USA.
J Mol Biol. 1997 Feb 21;266(2):246-68. doi: 10.1006/jmbi.1996.0737.
The pseudouridine (psi) residues present in the high molecular mass RNA from the large ribosomal subunit (LSU) have been sequenced from representative species of the eukaryotes, prokaryotes and archaebacteria, and from mitochondrial and chloroplast organelles. Ribosomes from Bacillus subtilis, Halobacter halobium, Drosphilia melanogaster, Mus musculus, Homo sapiens, mitochondria of M. musculus, H. sapiens and Trypanosoma brucei, and Zea mays chloroplasts were examined, resulting in the exact localization of 190 psi residues. The number of psi residues per RNA varied from one in the mitochondrial RNAs to 57 in the cytoplasmic LSU RNA of D. melanogaster and M. musculus. Despite this, all of the psi residues were found in three domains, II, IV and V. All three are at or have been linked to the peptidyl transferase center according to the literature. Comparison of the sites for psi among the species examined revealed four conserved or semi-conserved segments. One is the region 1911 to 1917, which contains three psi or modified psi in almost all species examined. This site is also juxtaposed to the decoding site of the 30 S subunit in the 70 S ribosome and has been implicated in the fidelity of codon recognition. Three additional sites were at the peptidyl transferase center itself. The juxtaposition of the conserved sites for psi with the two important functions of the ribosome, codon recognition and peptide bond formation, implies an important role for psi in ribosome function. We report some new putative modified nucleosides in LSU RNAs as detected by reverse transcription, correct a segment of the sequence of Z. mays chloroplasts and D. melanogaster LSU RNA, correlate the secondary structural context for all known psi residues in ribosomal RNA, and compare the sites for psi with those known for methylated nucleosides in H. sapiens.
已对来自真核生物、原核生物和古细菌的代表性物种以及线粒体和叶绿体细胞器的大核糖体亚基(LSU)高分子量RNA中的假尿苷(ψ)残基进行了测序。研究了来自枯草芽孢杆菌、嗜盐盐杆菌、黑腹果蝇、小家鼠、智人、小家鼠线粒体、智人和布氏锥虫的核糖体,以及玉米叶绿体,确定了190个ψ残基的确切位置。每个RNA中ψ残基的数量从线粒体RNA中的1个到黑腹果蝇和小家鼠细胞质LSU RNA中的57个不等。尽管如此,所有的ψ残基都位于三个结构域,即结构域II、IV和V中。根据文献,这三个结构域都位于肽基转移酶中心或与之相连。在所研究的物种中,ψ位点的比较揭示了四个保守或半保守片段。其中一个是1911至1917区域,几乎在所研究的所有物种中都含有三个ψ或修饰的ψ。该位点也与70S核糖体中30S亚基的解码位点相邻,并且与密码子识别的保真度有关。另外三个位点位于肽基转移酶中心本身。ψ的保守位点与核糖体的两个重要功能,即密码子识别和肽键形成并列,这意味着ψ在核糖体功能中起重要作用。我们报告了通过逆转录检测到的LSU RNA中一些新的推定修饰核苷,校正了玉米叶绿体和黑腹果蝇LSU RNA的一段序列,关联了核糖体RNA中所有已知ψ残基的二级结构背景,并将ψ位点与智人中甲基化核苷的已知位点进行了比较。
