{"title":"Histone proteomics implicates H3K36me2 and its regulators in mouse embryonic stem cell pluripotency exit and lineage choice","authors":"Dersu Sezginmert, Nihal Terzİ ÇİzmecİoĞlu","doi":"10.1515/tjb-2023-0030","DOIUrl":null,"url":null,"abstract":"Abstract Objectives Gene expression changes during embryonic stem cell (ESC) differentiation is regulated by epigenetic mechanisms. Understanding these can help uncover how cell fate decisions are made during early embryonic development. Comparison of chromatin of ESCs with lineage-committed cells can implicate chromatin factors functional in exit from pluripotency and the choice of proper lineages. Therefore, we quantitatively analyzed histone modifications in mouse ESC differentiation towards neuroectoderm and endoderm. Methods We cultured mouse ESCs (mESCs) and differentiated them towards neuroectoderm or endoderm lineages and performed mass spectrometry on total histones. Subsequent Western blots verified significantly altered H3K36me2. RT-qPCR analyses showed changes in H3K36-specific methyltransferases, demethylases and readers at mESC stage or during neuroectoderm/endoderm commitment. Results We presented quantitative histone modification levels in mESCs and lineage-committed cells. H3K36me2 increased specifically in neuroectoderm compared to mESCs or endoderm-committed cells. Regulation of H3K36 methylation might have a role in pluripotency exit and/or differentiation. Nsd2, Dnmt3b and Zmynd11 increased during differentiation regardless of lineage. Conversely, mESCs had higher Kdm4c and Msh6 expression than differentiated cells. Comparing neuroectoderm and endoderm-committed cells, we revealed Nsd1, Setd5 and Dnmt3a had lineage specific expression pattern. Conclusions Our results show quantitative changes in histone modifications during mESC lineage commitment and implicate H3K36me2 regulation for not only pluripotency exit but also lineage choice. Its regulatory proteins show stage (mESC vs. committed) or lineage (neuroectoderm vs. endoderm) dependent expression changes. Further work will be needed to discover their possible involvement in cell fate decisions and target genes.","PeriodicalId":23344,"journal":{"name":"Turkish Journal of Biochemistry","volume":"37 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2023-07-19","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Turkish Journal of Biochemistry","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1515/tjb-2023-0030","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 0
Abstract
Abstract Objectives Gene expression changes during embryonic stem cell (ESC) differentiation is regulated by epigenetic mechanisms. Understanding these can help uncover how cell fate decisions are made during early embryonic development. Comparison of chromatin of ESCs with lineage-committed cells can implicate chromatin factors functional in exit from pluripotency and the choice of proper lineages. Therefore, we quantitatively analyzed histone modifications in mouse ESC differentiation towards neuroectoderm and endoderm. Methods We cultured mouse ESCs (mESCs) and differentiated them towards neuroectoderm or endoderm lineages and performed mass spectrometry on total histones. Subsequent Western blots verified significantly altered H3K36me2. RT-qPCR analyses showed changes in H3K36-specific methyltransferases, demethylases and readers at mESC stage or during neuroectoderm/endoderm commitment. Results We presented quantitative histone modification levels in mESCs and lineage-committed cells. H3K36me2 increased specifically in neuroectoderm compared to mESCs or endoderm-committed cells. Regulation of H3K36 methylation might have a role in pluripotency exit and/or differentiation. Nsd2, Dnmt3b and Zmynd11 increased during differentiation regardless of lineage. Conversely, mESCs had higher Kdm4c and Msh6 expression than differentiated cells. Comparing neuroectoderm and endoderm-committed cells, we revealed Nsd1, Setd5 and Dnmt3a had lineage specific expression pattern. Conclusions Our results show quantitative changes in histone modifications during mESC lineage commitment and implicate H3K36me2 regulation for not only pluripotency exit but also lineage choice. Its regulatory proteins show stage (mESC vs. committed) or lineage (neuroectoderm vs. endoderm) dependent expression changes. Further work will be needed to discover their possible involvement in cell fate decisions and target genes.
【摘要】目的胚胎干细胞(ESC)分化过程中基因表达变化受表观遗传机制调控。了解这些可以帮助揭示细胞命运是如何在早期胚胎发育过程中决定的。比较ESCs与谱系承诺细胞的染色质可以暗示染色质因子在多能性退出和适当谱系选择中的功能。因此,我们定量分析了小鼠ESC向神经外胚层和内胚层分化过程中的组蛋白修饰。方法培养小鼠ESCs,将其分化为神经外胚层和内胚层谱系,并对总组蛋白进行质谱分析。随后的Western blots证实H3K36me2显著改变。RT-qPCR分析显示,在mESC阶段或神经外胚层/内胚层发育期间,h3k36特异性甲基转移酶、去甲基化酶和读取器发生了变化。结果我们在mESCs和谱系承诺细胞中获得了定量的组蛋白修饰水平。与mESCs或内胚层细胞相比,H3K36me2在神经外胚层中特异性增加。H3K36甲基化的调控可能在多能性退出和/或分化中起作用。无论谱系如何,Nsd2、Dnmt3b和Zmynd11在分化过程中均有所增加。相反,mESCs的Kdm4c和Msh6表达高于分化后的细胞。比较神经外胚层细胞和内胚层细胞,我们发现Nsd1、Setd5和Dnmt3a具有谱系特异性表达模式。我们的研究结果表明,组蛋白修饰在mESC谱系承诺过程中发生了定量变化,并暗示H3K36me2调控不仅影响多能性退出,还影响谱系选择。其调节蛋白表现出阶段(mESC vs. committed)或谱系(神经外胚层vs.内胚层)依赖性表达变化。需要进一步的工作来发现它们可能参与细胞命运决定和靶基因。