Transfer RNA:A dancer between charging and mis-charging for protein biosynthesis 被引量：5

Transfer RNA: A dancer between charging and mis-charging for protein biosynthesis

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摘要 Transfer RNA plays a fundamental role in the protein biosynthesis as an adaptor molecule by functioning as a biological link between the genetic nucleotide sequence in the mRNA and the amino acid sequence in the protein.To perform its role in protein biosynthesis,it has to be accurately recognized by aminoacyl-tRNA synthetases(aaRSs)to generate aminoacyl-tRNAs(aa-tRNAs).The correct pairing between an amino acid with its cognate tRNA is crucial for translational quality control.Production and utilization of mis-charged tRNAs are usually detrimental for all the species,resulting in cellular dysfunctions.Correct aa-tRNAs formation is collectively controlled by aaRSs with distinct mechanisms and/or other trans-factors.However,in very limited instances,mis-charged tRNAs are intermediate for specific pathways or essential components for the translational machinery.Here,from the point of accuracy in tRNA charging,we review our understanding about the mechanism ensuring correct aa-tRNA generation.In addition,some unique mis-charged tRNA species necessary for the organism are also briefly described. Transfer RNA plays a fundamental role in the protein biosynthesis as an adaptor molecule by functioning as a biological link between the genetic nucleotide sequence in the mRNA and the amino acid sequence in the protein. To perform its role in pro- tein biosynthesis, it has to be accurately recognized by aminoacyl-tRNA synthetases （aaRSs） to generate aminoacyl-tRNAs （aa-tRNAs）. The correct pairing between an amino acid with its cognate tRNA is crucial for translational quality control. Pro- duction and utilization of mis-charged tRNAs are usually detrimental for all the species, resulting in cellular dysfunctions. Correct aa-tRNAs formation is collectively controlled by aaRSs with distinct mechanisms and/or other trans-factors. However, in very limited instances, mis-charged tRNAs are intermediate for specific pathways or essential components for the transla- tional machinery. Here, from the point of accuracy in tRNA charging, we review our understanding about the mechanism en- suring correct aa-tRNA generation. In addition, some unique mis-charged tRNA species necessary for the organism are also briefly described.

作者 ZHOU XiaoLong WANG EnDuo

机构地区 Center for RNA Research

出处《Science China(Life Sciences)》 SCIE CAS 2013年第10期921-932,共12页 中国科学（生命科学英文版）

基金 supported by the National Natural Science Foundation of China(31270852,31000355) the National Key Basic Research Program of China(2012CB911000)

关键词 TRNA aminoacyl-tRNA synthetase AMINOACYLATION EDITING 蛋白质合成 mRNA 氨酰tRNA合成酶充电氨基酸序列 tRNA基因转运反式作用因子

分类号 Q522 [生物学—生物化学]

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二级参考文献133

1Wilcox M, Nirenberg M. Transfer RNA as a cofactor coupling amino acid synthesis with that of protein. Proc Natl Acad Sci USA 1968, 61: 229-236 被引量：1
2Curnow AW, Hong K, Yuan R, Kim S, Martins O, Winkler W, Henkin TM et al. GIu-tRNA^Gln amidotransferase: a novel heterotrimeric enzyme required for correct decoding of glutamine codons during translation. Proc Natl Acad Sci USA 1997, 94: 11819-11826 被引量：1
3Curnow AW, Tumbula DL, Pelaschier JT, Min B, Soll D. GlutamyltRNA^Gln amidotransferase in Deinococcus radiodurans may be confined to asparagine biosynthesis. Proc Natl Acad Sci USA 1998, 95:12838-12843 被引量：1
4Tumbula DL, Becker HD, Chang WZ, Soll D. Domain-specific recruitment of amide amino acids for protein synthesis. Nature 2000, 407:106-110 被引量：1
5Sauerwald A, Zhu W, Major TA, Roy H, Palioura S, Jahn D, Whitman WB et al. RNA-dependent cysteine biosynthesis in archaea. Science 2005, 307:1969-1972 被引量：1
6Yuan J, Palioura S, Salazar JC, Su D, O'Donoghue P, Hohn MJ, Cardoso AM et al. RNA-dependent conversion of phosphoserine forms selenocysteine in eukaryotes and archaea. Proc Natl Acad Sci USA 2006, 103:18923-18927 被引量：1
7Sheppard K, Akochy PM, Salazar JC, Soll D. The Helicobacter pylori amidotransferase GatCAB is equally efficient in glutamine- dependent transamidation of Asp-tRNA^Asn and Glu-tRNA^Gln. J Biol Chem 2007, 282:11866-11873 被引量：1
8Roy H, Becker HD, Reinbolt J, Kern D. When contemporary aminoacyl-tRNA synthetases invent their cognate amino acid metabolism. Proc Natl Acad Sci USA 2003, 100:9837-9842 被引量：1
9Bult CJ, White O, Olsen GJ, Zhou L, Fleischmann RD, Sutton GG, Blake JA et al. Complete genome sequence of the methanogenic archaeon, Methanococcus jannaschii. Science 1996, 273: 1058- 1073 被引量：1
10Smith DR, Doucette-Stamm LA, Deloughery C, Lee H, Dubois J, Aldredge T, Bashirzadeh R et al. Complete genome sequence of Methanobacterium thermoautotrophicum deltaH: functional analysis and comparative genomics. J Bacteriol 1997, 179: 7135-7155 被引量：1

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1Dongyu Hu,Wei Lei,Hongsheng Yu,Weiwei Qi,Jian Jiang,Yali Miao,Shanai Song,Ruyong Yao.Mechanism of RNA interference targeting at survivin gene on apoptosis of hepatoma-cellular carcinoma cell line HepG2[J].The Chinese-German Journal of Clinical Oncology,2011,10(4):208-213.
2潘秀懿,苏征征,钟金晶,余婷,卫昱燕,许云屹,尹晓雪,郭小煜,张孟尼,聂玲,徐苗,龚静,陈铌,陈雪芹,周桥.肿瘤分子病理学中的调节性RNA[J].中国科学：生命科学,2022,52(11):1578-1602. 被引量：2

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1Lan-Tao Gou,Peng Dai,Jian-Hua Yang,Yuanchao Xue,Yun-Ping Hu,Yu Zhou,Jun-Yan Kang,Xin Wang,Hairi Li,Min-Min Hua,Shuang Zhao,Si-Da Hu,Li-Gang Wu,Hui-Juan Shi,Yong Li,Xiang-Dong Fu,Liang-Hu Qu,En-Duo Wang,Mo-Fang Liu.Pachytene piRNAs instruct massive mRNA elimination during late spermiogenesis[J].Cell Research,2014,24(6):680-700. 被引量：42
2Yang, Xin,Yang, Ying,Sun, Bao-Fa,Chen, Yu-Sheng,Xu, Jia-Wei,Lai, Wei-Yi,Li, Ang,Wang, Xing,Bhattarai, Devi Prasad,Xiao, Wen,Sun, Hui-Ying,Zhu, Qin,Ma, Hai-Li,Adhikari, Samir,Sun, Min,Hao, Ya-Juan,Zhang, Bing,Huang, Chun-Min,Huang, Niu,Jiang, Gui-Bin,Zhao, Yong-Liang,Wang, Hai-Lin,Sun, Ying-Pu,Yang, Yun-Gui.5-methylcytosine promotes mRNA export--NSUN2 as the methyltransferase and ALYREF as an m5C reader[J].Cell Research,2017,27(5):606-625. 被引量：78
3Yi Yang,Han Wu,Xiangjin Kang,Yanhui Liang,Ting Lan,Tianjie Li,Tao Tan,Jiangyun Peng,Quanjun Zhang,Geng An,Yali Liu,Qian Yu,Zhenglai Ma,Ying Lian,Boon Seng Soh,Qingfeng Chen,Ping Liu,Yaoyong Chen,Xiaofang Sun,Rong Li,Xiumei Zhen,Yang Yu,Xiaoping Li,Yong Fan.Fargeted elimination of mutant mitochondria DNA in MELAS-iPSCs by mitoTALENs[J].Protein & Cell,2018,9(3):283-297. 被引量：8
4Tao Pan.Modifications and functional genomics of human transfer RNA[J].Cell Research,2018,28(4):395-404. 被引量：12
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5姚诗莹,周小龙.tRNA代谢及其紊乱与疾病[J].生命的化学,2024,44(9):1542-1549.

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4庞可心,朱敏,汤健,丁乐.低髓鞘化脑白质营养不良的基因研究进展[J].中华实用儿科临床杂志,2024,39(1):69-73.

1古代动物园不是谁都能进[J].人生十六七,2016,0(7):46-47.
2Jianping Ding Institute of Biochemistry and Cell Biology, Shanghai Institutes for Biological Sciences, Chinese Academy of Sciences, 320 Yue-Yang Road, Shanghai 200031, China.Molecular basis of the high fidelity in protein synthesis[J].生物物理学报,2009,25(S1):81-81.
3脑力充电室[J].少年科普世界（快乐数学1-3年级版）,2009(8):21-21.
4SANG ICK PARK,JIN Mo PARK,HAROLD S. CHITTUM,EUN SUNG YANG,BRADLEY A. CARLSON,BYEONG JAE LEE AND DOLPH L. HATFIELD(Laboratory of Experimental Chrcinogenesis, National Cancer Insti tute, National Institutes of Health, Bethesda, MD 20892USA,Laboratory o.Selenocysteine tRNAs as Central Components of Selenoprotein Biosynthesis in Eukaryotes[J].Biomedical and Environmental Sciences,1997,10(2):116-124. 被引量：2
5QI GuoRong Institute of Biochemistry and Cell Biology,Shanghai Institute for Biological Sciences,Chinese Academy of Sciences,Shanghai 200031,China.The background of the total synthesis of yeast alanine transfer RNA[J].Science China(Life Sciences),2010,53(1):19-21. 被引量：6
6张萃.六方法为大脑“充电”[J].应用写作,2009(11):62-62.
7金迪.“纽崔莱之父”的浴火重生[J].新民周刊,2014,0(41):26-33.
8张萃.六方法为大脑“充电”[J].甘肃林业,2009(5):47-47.
9大脑充电“十味汤”[J].求学（文科版）,2009(5):39-39.
10累的时候，就用这个“充电宝”给大脑“充电”[J].科学大众（小诺贝尔）,2016,0(1):14-14.

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