M. Chen[Author] - Search Results

Year	Number of Results
1962	1
1968	1
1969	5
1970	4
1971	3
1972	10
1974	10
1975	17
1976	6
1977	18
1978	9
1979	13
1980	14
1981	21
1982	21
1983	29
1984	36
1985	29
1986	38
1987	57
1988	60
1989	83
1990	91
1991	95
1992	149
1993	134
1994	185
1995	195
1996	208
1997	244
1998	245
1999	282
2000	319
2001	397
2002	408
2003	541
2004	580
2005	743
2006	899
2007	984
2008	1133
2009	1247
2010	1455
2011	1691
2012	1985
2013	2233
2014	2735
2015	3122
2016	3401
2017	3755
2018	4512
2019	5240
2020	6005
2021	7002
2022	8141
2023	7955
2024	2953

1

Epigenetic modification of m(6)A regulator proteins in cancer.

Wang Y, Wang Y, Patel H, Chen J, Wang J, Chen ZS, Wang H. Wang Y, et al. Among authors: chen j, chen zs. Mol Cancer. 2023 Jun 30;22(1):102. doi: 10.1186/s12943-023-01810-1. Mol Cancer. 2023. PMID: 37391814 Free PMC article. Review.

Divergent N(6)-methyladenosine (m(6)A) modifications are dynamic and reversible posttranscriptional RNA modifications that are mediated by m(6)A regulators or m(6)A RNA methylation regulators, i.e., methyltransferases ("writers"), demethylases ("erasers"), an …

Divergent N(6)-methyladenosine (m(6)A) modifications are dynamic and reversible posttranscriptional RNA modifications that are mediat …

2

Differential m(6)A, m(6)A(m), and m(1)A Demethylation Mediated by FTO in the Cell Nucleus and Cytoplasm.

Wei J, Liu F, Lu Z, Fei Q, Ai Y, He PC, Shi H, Cui X, Su R, Klungland A, Jia G, Chen J, He C. Wei J, et al. Among authors: chen j. Mol Cell. 2018 Sep 20;71(6):973-985.e5. doi: 10.1016/j.molcel.2018.08.011. Epub 2018 Sep 6. Mol Cell. 2018. PMID: 30197295 Free PMC article.

We find that FTO binds multiple RNA species, including mRNA, snRNA, and tRNA, and can demethylate internal m(6)A and cap m(6)A(m) in mRNA, internal m(6)A in U6 RNA, internal and cap m(6)A(m) in snRNAs, and N(1)-methyladenosine (m(1 …

We find that FTO binds multiple RNA species, including mRNA, snRNA, and tRNA, and can demethylate internal m(6)A and cap m(6)A …

3

m(6)A modification negatively regulates translation by switching mRNA from polysome to P-body via IGF2BP3.

Shan T, Liu F, Wen M, Chen Z, Li S, Wang Y, Cheng H, Zhou Y. Shan T, et al. Among authors: chen z. Mol Cell. 2023 Dec 21;83(24):4494-4508.e6. doi: 10.1016/j.molcel.2023.10.040. Epub 2023 Nov 27. Mol Cell. 2023. PMID: 38016476

By quantifying the m(6)A level of polysomal and cytoplasmic mRNAs with m(6)A-LAIC-seq and m(6)A-LC-MS/MS in HeLa cells, we observed that polysome-associated mRNAs are hypo-m(6)A-methylated, whereas those enriched in P-body are hyper-m(6)A-methyl …

By quantifying the m(6)A level of polysomal and cytoplasmic mRNAs with m(6)A-LAIC-seq and m(6)A-LC-MS/MS in HeLa cells, …

4

Reversible methylation of m(6)A(m) in the 5' cap controls mRNA stability.

Mauer J, Luo X, Blanjoie A, Jiao X, Grozhik AV, Patil DP, Linder B, Pickering BF, Vasseur JJ, Chen Q, Gross SS, Elemento O, Debart F, Kiledjian M, Jaffrey SR. Mauer J, et al. Among authors: chen q. Nature. 2017 Jan 19;541(7637):371-375. doi: 10.1038/nature21022. Epub 2016 Dec 21. Nature. 2017. PMID: 28002401 Free PMC article.

Using a transcriptome-wide map of m(6)A(m) we find that m(6)A(m)-initiated transcripts are markedly more stable than mRNAs that begin with other nucleotides. ...FTO preferentially demethylates m(6)A(m) rather than N(6)-methyladenosine ( …

Using a transcriptome-wide map of m(6)A(m) we find that m(6)A(m)-initiated transcripts are markedly more stable …

5

CAR-Macrophages and CAR-T Cells Synergistically Kill Tumor Cells In Vitro.

Liu M, Liu J, Liang Z, Dai K, Gan J, Wang Q, Xu Y, Chen YH, Wan X. Liu M, et al. Among authors: chen yh. Cells. 2022 Nov 21;11(22):3692. doi: 10.3390/cells11223692. Cells. 2022. PMID: 36429120 Free PMC article.

We found that CAR-M(FcRgamma) exerted more potent phagocytic and tumor-killing capacity than CAR-M(Megf10) and CAR-M(PI3K). CAR-M and CAR-T demonstrated synergistic cytotoxicity against tumor cells in vitro. ...

We found that CAR-M(FcRgamma) exerted more potent phagocytic and tumor-killing capacity than CAR-M(Megf10) and CAR-M(PI …

6

TROP2 translation mediated by dual m(6)A/m(7)G RNA modifications promotes bladder cancer development.

Chen C, Chao Y, Zhang C, Hu W, Huang Y, Lv Y, Liu B, Ji D, Liu M, Yang B, Jiang L, Liang Y, Zhang H, Yuan G, Ying X, Ji W. Chen C, et al. Cancer Lett. 2023 Jul 10;566:216246. doi: 10.1016/j.canlet.2023.216246. Epub 2023 Jun 1. Cancer Lett. 2023. PMID: 37268280

RNA modifications, including adenine methylation (m(6)A) of mRNA and guanine methylation (m(7)G) of tRNA, are crucial for the biological function of RNA. ...We demonstrated that m(6)A methyltransferase METTL3-mediated programmable m(6)A modification of …

RNA modifications, including adenine methylation (m(6)A) of mRNA and guanine methylation (m(7)G) of tRNA, are crucial for the …

7

Detection, regulation, and functions of RNA N⁶-methyladenosine modification in plants.

Tang J, Chen S, Jia G. Tang J, et al. Among authors: chen s. Plant Commun. 2023 May 8;4(3):100546. doi: 10.1016/j.xplc.2023.100546. Epub 2023 Jan 10. Plant Commun. 2023. PMID: 36627844 Free PMC article. Review.

Recently, the breadth of research on m(6)A in plants has expanded, and the vital roles of m(6)A in plant development, biotic and abiotic stress responses, and crop trait improvement have been investigated. In this review, we discuss recent developments in research o …

Recently, the breadth of research on m(6)A in plants has expanded, and the vital roles of m(6)A in plant development, biotic a …

8

Emerging roles of biological m(6)A proteins in regulating virus infection: A review.

Chen Y, Wang W, Zhang W, He M, Li Y, Qu G, Tong J. Chen Y, et al. Int J Biol Macromol. 2023 Dec 31;253(Pt 3):126934. doi: 10.1016/j.ijbiomac.2023.126934. Epub 2023 Sep 16. Int J Biol Macromol. 2023. PMID: 37722640 Review.

As a dynamic process, three groups of biological proteins control the levels of m(6)A modification in eukaryocyte, designed as m(6)A writers, erasers, and readers. ...The known m(6)A readers include the YTH family and the hnRNP family. As m(6)A modific …

As a dynamic process, three groups of biological proteins control the levels of m(6)A modification in eukaryocyte, designed as m …

9

Immune Evasion of Mycoplasma bovis.

Askar H, Chen S, Hao H, Yan X, Ma L, Liu Y, Chu Y. Askar H, et al. Among authors: chen s. Pathogens. 2021 Mar 4;10(3):297. doi: 10.3390/pathogens10030297. Pathogens. 2021. PMID: 33806506 Free PMC article. Review.

This consists of an inflammatory response in the host that causes pathological immune damage, which is essential for the pathogenic mechanism of M. bovis. Additionally, M. bovis can escape host immune system elimination and, thus, cause chronic infection. ...This re …

This consists of an inflammatory response in the host that causes pathological immune damage, which is essential for the pathogenic mechanis …

10

Mapping single-nucleotide m(6)A by m(6)A-REF-seq.

Chen HX, Zhang Z, Ma DZ, Chen LQ, Luo GZ. Chen HX, et al. Among authors: chen lq. Methods. 2022 Jul;203:392-398. doi: 10.1016/j.ymeth.2021.06.013. Epub 2021 Jun 24. Methods. 2022. PMID: 34174388

However, limitations of the detection method impede functional studies of m(6)A. Here we introduce m(6)A-REF-seq, a powerful and straightforward method to identify m(6)A at single-nucleotide resolution. m(6)A-REF-seq relies on the recognition of RNA en …

However, limitations of the detection method impede functional studies of m(6)A. Here we introduce m(6)A-REF-seq, a powerful a …

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