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Literature DB >> 27179969

N (6)-Methyladenosine (m(6)A) Methylation in mRNA with A Dynamic and Reversible Epigenetic Modification.

Ruifan Wu^1,2,3, Denghu Jiang^1,2,3, Yizhen Wang^1,2,3, Xinxia Wang^4,5,6.

Abstract

N (6)-methyladenosine (m(6)A) is the most abundant and reversible internal modification ubiquitously occurring in eukaryotic mRNA, albeit the significant biological roles of m(6)A methylation have remained largely unclear. The well-known DNA and histone methylations play crucial roles in epigenetic modification of biologic processes in eukaryotes. Analogously, the dynamic and reversible m(6)A RNA modification, which is installed by methyltransferase (METTL3, METTL14, and WTAP), reversed by demethylases (FTO, ALKBH5) and mediated by m(6)A-binding proteins (YTHDF1-3, YTHDC1), may also have a profound impact on gene expression regulation. Recent discoveries of the distributions, functions, and mechanisms of m(6)A modification suggest that this methylation functionally modulates the eukaryotic transcriptome to influence mRNA transcription, splicing, nuclear export, localization, translation, and stability. This reversible mRNA methylation shed light on a new dimension of post-transcriptional regulation of gene expression at the RNA level. m(6)A methylation also plays significant and broad roles in various physiological processes, such as development, fertility, carcinogenesis, stemness, early mortality, meiosis and circadian cycle, and links to obesity, cancer, and other human diseases. This review mainly describes the current knowledge of m(6)A and perspectives on future investigations.

Entities: Chemical Disease Gene Species

Keywords: FTO; N 6-Methyladenosine; Post-transcriptional regulation; mRNA methylation

Mesh：

Substances：

Year: 2016 PMID： 27179969 DOI： 10.1007/s12033-016-9947-9

Source DB: PubMed Journal: Mol Biotechnol ISSN： 1073-6085 Impact factor: 2.695

98 in total

1. Molecular biology. Methylation talk between histones and DNA.

Authors: A Bird
Journal: Science Date: 2001-12-07 Impact factor: 47.728

2. hnRNP C tetramer measures RNA length to classify RNA polymerase II transcripts for export.

Authors: Asako McCloskey; Ichiro Taniguchi; Kaori Shinmyozu; Mutsuhito Ohno
Journal: Science Date: 2012-03-30 Impact factor: 47.728

3. N(6)-methyladenosine Modulates Messenger RNA Translation Efficiency.

Authors: Xiao Wang; Boxuan Simen Zhao; Ian A Roundtree; Zhike Lu; Dali Han; Honghui Ma; Xiaocheng Weng; Kai Chen; Hailing Shi; Chuan He
Journal: Cell Date: 2015-06-04 Impact factor: 41.582

4. m(6)A RNA modification controls cell fate transition in mammalian embryonic stem cells.

Authors: Pedro J Batista; Benoit Molinie; Jinkai Wang; Kun Qu; Jiajing Zhang; Lingjie Li; Donna M Bouley; Ernesto Lujan; Bahareh Haddad; Kaveh Daneshvar; Ava C Carter; Ryan A Flynn; Chan Zhou; Kok-Seong Lim; Peter Dedon; Marius Wernig; Alan C Mullen; Yi Xing; Cosmas C Giallourakis; Howard Y Chang
Journal: Cell Stem Cell Date: 2014-10-16 Impact factor: 24.633

5. Wilms' tumor 1-associating protein regulates G2/M transition through stabilization of cyclin A2 mRNA.

Authors: Keiko Horiuchi; Michihisa Umetani; Takashi Minami; Hiroto Okayama; Shinji Takada; Masayuki Yamamoto; Hiroyuki Aburatani; Patrick C Reid; David E Housman; Takao Hamakubo; Tatsuhiko Kodama
Journal: Proc Natl Acad Sci U S A Date: 2006-11-06 Impact factor: 11.205

6. High-resolution N(6) -methyladenosine (m(6) A) map using photo-crosslinking-assisted m(6) A sequencing.

Authors: Kai Chen; Zhike Lu; Xiao Wang; Ye Fu; Guan-Zheng Luo; Nian Liu; Dali Han; Dan Dominissini; Qing Dai; Tao Pan; Chuan He
Journal: Angew Chem Int Ed Engl Date: 2014-12-09 Impact factor: 15.336

Review 7. Mapping and significance of the mRNA methylome.

Authors: Tennille Sibbritt; Hardip R Patel; Thomas Preiss
Journal: Wiley Interdiscip Rev RNA Date: 2013-05-16 Impact factor: 9.957

Review 8. The scanning mechanism of eukaryotic translation initiation.

Authors: Alan G Hinnebusch
Journal: Annu Rev Biochem Date: 2014-01-29 Impact factor: 23.643

9. FTO-dependent demethylation of N6-methyladenosine regulates mRNA splicing and is required for adipogenesis.

Authors: Xu Zhao; Ying Yang; Bao-Fa Sun; Yue Shi; Xin Yang; Wen Xiao; Ya-Juan Hao; Xiao-Li Ping; Yu-Sheng Chen; Wen-Jia Wang; Kang-Xuan Jin; Xing Wang; Chun-Min Huang; Yu Fu; Xiao-Meng Ge; Shu-Hui Song; Hyun Seok Jeong; Hiroyuki Yanagisawa; Yamei Niu; Gui-Fang Jia; Wei Wu; Wei-Min Tong; Akimitsu Okamoto; Chuan He; Jannie M Rendtlew Danielsen; Xiu-Jie Wang; Yun-Gui Yang
Journal: Cell Res Date: 2014-11-21 Impact factor: 25.617

10. Phylogenomic identification of five new human homologs of the DNA repair enzyme AlkB.

Authors: Michal A Kurowski; Ashok S Bhagwat; Grzegorz Papaj; Janusz M Bujnicki
Journal: BMC Genomics Date: 2003-12-10 Impact factor: 3.969

46 in total

Review 1. Understanding m⁶A Function Through Uncovering the Diversity Roles of YTH Domain-Containing Proteins.

Authors: Y L Zhao; Y H Liu; R F Wu; Z Bi; Y X Yao; Q Liu; Y Z Wang; X X Wang
Journal: Mol Biotechnol Date: 2019-05 Impact factor: 2.695

2. m⁶A mRNA methylation controls autophagy and adipogenesis by targeting Atg5 and Atg7.

Authors: Xinxia Wang; Ruifan Wu; Youhua Liu; Yuanling Zhao; Zhen Bi; Yongxi Yao; Qing Liu; Hailing Shi; Fengqin Wang; Yizhen Wang
Journal: Autophagy Date: 2019-08-26 Impact factor: 16.016

3. Maternal heat stress regulates the early fat deposition partly through modification of m⁶A RNA methylation in neonatal piglets.

Authors: Jinghui Heng; Min Tian; Wenfei Zhang; Fang Chen; Wutai Guan; Shihai Zhang
Journal: Cell Stress Chaperones Date: 2019-05-08 Impact factor: 3.667

4. Silencing METTL3 Stabilizes Atherosclerotic Plaques by Regulating the Phenotypic Transformation of Vascular Smooth Muscle Cells via the miR-375-3p/PDK1 Axis.

Authors: Jingquan Chen; Kun Lai; Xi Yong; Hongshun Yin; Zhilong Chen; Haifei Wang; Kai Chen; Jianghua Zheng
Journal: Cardiovasc Drugs Ther Date: 2022-06-15 Impact factor: 3.727

Review 5. N6-methyladenosine and Neurological Diseases.

Authors: Nan Zhang; Chunhong Ding; Yuxin Zuo; Yu Peng; Lielian Zuo
Journal: Mol Neurobiol Date: 2022-01-15 Impact factor: 5.590

6. Up-to-date on the evidence linking miRNA-related epitranscriptomic modifications and disease settings. Can these modifications affect cross-kingdom regulation?

Authors: João Tomé-Carneiro; María-Carmen López de Las Hazas; Hatim Boughanem; Yvonne Böttcher; Akin Cayir; Manuel Macias González; Alberto Dávalos
Journal: RNA Biol Date: 2021-11-29 Impact factor: 4.652

N (6)-Methyladenosine (m(6)A) Methylation in mRNA with A Dynamic and Reversible Epigenetic Modification.

1. Molecular biology. Methylation talk between histones and DNA.

2. hnRNP C tetramer measures RNA length to classify RNA polymerase II transcripts for export.

3. N(6)-methyladenosine Modulates Messenger RNA Translation Efficiency.

4. m(6)A RNA modification controls cell fate transition in mammalian embryonic stem cells.

5. Wilms' tumor 1-associating protein regulates G2/M transition through stabilization of cyclin A2 mRNA.

6. High-resolution N(6) -methyladenosine (m(6) A) map using photo-crosslinking-assisted m(6) A sequencing.

Review 7. Mapping and significance of the mRNA methylome.

Review 8. The scanning mechanism of eukaryotic translation initiation.

9. FTO-dependent demethylation of N6-methyladenosine regulates mRNA splicing and is required for adipogenesis.

10. Phylogenomic identification of five new human homologs of the DNA repair enzyme AlkB.

Review 1. Understanding m⁶A Function Through Uncovering the Diversity Roles of YTH Domain-Containing Proteins.

2. m⁶A mRNA methylation controls autophagy and adipogenesis by targeting Atg5 and Atg7.

3. Maternal heat stress regulates the early fat deposition partly through modification of m⁶A RNA methylation in neonatal piglets.

4. Silencing METTL3 Stabilizes Atherosclerotic Plaques by Regulating the Phenotypic Transformation of Vascular Smooth Muscle Cells via the miR-375-3p/PDK1 Axis.

Review 5. N6-methyladenosine and Neurological Diseases.

6. Up-to-date on the evidence linking miRNA-related epitranscriptomic modifications and disease settings. Can these modifications affect cross-kingdom regulation?

7. Active Site Breathing of Human Alkbh5 Revealed by Solution NMR and Accelerated Molecular Dynamics.

8. Cap-independent translation: A shared mechanism for lifespan extension by rapamycin, acarbose, and 17α-estradiol.

9. METTL3 mediates bone marrow mesenchymal stem cell adipogenesis to promote chemoresistance in acute myeloid leukaemia.

Review 10. Regulatory Role of N6-methyladenosine (m⁶A) Modification in Osteosarcoma.

Review 7. Mapping and significance of the mRNA methylome.

Review 8. The scanning mechanism of eukaryotic translation initiation.

Review 1. Understanding m6A Function Through Uncovering the Diversity Roles of YTH Domain-Containing Proteins.

Review 5. N6-methyladenosine and Neurological Diseases.

Review 10. Regulatory Role of N6-methyladenosine (m6A) Modification in Osteosarcoma.

Review 1. Understanding m⁶A Function Through Uncovering the Diversity Roles of YTH Domain-Containing Proteins.

Review 10. Regulatory Role of N6-methyladenosine (m⁶A) Modification in Osteosarcoma.