Control of plant cell differentiation by histone modification and DNA methylation

Control of plant cell differentiation by histone modification and DNA methylation

•Epigenetic modifications in DNA and histones play pivotal roles in cell differentiation.•Transcription factors recruit epigenetic modifiers to regulate specific target loci.•Stem cell regulators recruit histone deacetylases to prevent precocious cellular differentiation.•Polycomb group proteins sup...

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Bibliographic Details
Published in:Current opinion in plant biology Vol. 28; pp. 60 - 67
Main Authors: Ikeuchi, Momoko, Iwase, Akira, Sugimoto, Keiko
Format: Journal Article
Language:English
Published: England Elsevier Ltd 01-12-2015
Subjects:
Cell Differentiation
DNA Methylation
Histone Code
Plant Cells - physiology
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Summary:•Epigenetic modifications in DNA and histones play pivotal roles in cell differentiation.•Transcription factors recruit epigenetic modifiers to regulate specific target loci.•Stem cell regulators recruit histone deacetylases to prevent precocious cellular differentiation.•Polycomb group proteins suppress stem cell regulators and reprogramming regulators to maintain cellular differentiation status. How cells differentiate and acquire diverse arrays of determined states in multicellular organisms is a fundamental and yet unanswered question in biology. Molecular genetic studies over the last few decades have identified many transcriptional regulators that activate or repress gene expression to promote cell differentiation in plant development. What has recently emerged as an additional important regulatory layer is the control at the epigenetic level by which locus-specific DNA methylation and histone modification alter the chromatin state and limit the expression of key developmental regulators to specific windows of time and space. Accumulating evidence suggests that histone acetylation is commonly linked with active transcription and this mechanism is adopted to control sequential progression of cell differentiation. Histone H3 trimethylation at lysine 27 and DNA methylation are both associated with gene repression, and these mechanisms are often utilised to promote and/or maintain the differentiated status of plant cells.
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ISSN:1369-5266
1879-0356
DOI:10.1016/j.pbi.2015.09.004