Reprint

Chromatin, Epigenetics and Plant Physiology

Edited by
August 2020
190 pages
  • ISBN978-3-03936-028-4 (Hardback)
  • ISBN978-3-03936-029-1 (PDF)

This is a Reprint of the Special Issue Chromatin, Epigenetics and Plant Physiology that was published in

Biology & Life Sciences
Chemistry & Materials Science
Medicine & Pharmacology
Summary
This eBook focuses on current progress in understanding the role of chromatin structure, its modifications and remodeling in developmental and physiological processes. Eukaryotic genomes are packed into the supramolecular nucleoprotein structure of chromatin. Therefore, our understanding of processes such as DNA replication and repair, transcription, and cell differentiation requires an understanding of the structure and function of chromatin. While the nucleotide sequence of the DNA component of chromatin constitutes the genetic material of the cell, the other chromatin components (and also modifications of bases in the DNA itself) participate in so-called epigenetic processes. These processes are essential, e.g., in ontogenesis or adaptation to environmental changes. Therefore, epigenetics is particularly important (and elaborated) in plants that show a high developmental plasticity and, as sessile organisms, display an enormous capacity to cope with environmental stress. In these processes, epigenetic mechanisms show a crosstalk with plant signaling pathways mediated by phytohormones and redox components. You are welcome to read examples of current research and review articles in this hot research topic.
Format
  • Hardback
License and Copyright
© 2020 by the authors; CC BY-NC-ND license
Keywords
auxin; chromatin remodeling factor; cuticular wax; drought tolerance; epigenetic regulation; leaf width; histone modification; narrow leaf; OsCHR4; rice; 3D-FISH; barley; chromatin; hybrid; introgression; nucleus; rye; wheat; chromatin remodeling; INO80/SWR1 complexes; NuA4 complex; histone variant H2A.Z; gene regulation; plant development; Arabidopsis thaliana; epigenetics; histone; mass spectrometry; post-translational modifications; sodium butyrate; trichostatin A; Swi3-like proteins; gene expression; protein interaction; leaf development; tomato; Arabidopsis; KNL2; kinetochores; RNA-seq; centromere; SWI3C; SWI/SNF; cold response; ATP-dependent chromatin remodeling; transcriptional control of gene expression; circRNAs; jasmonic acid; Arabidopsis thaliana; GO enrichment; miRNA decoys; epigenetic modifications; DNA methylation; histone modification; chromatin remodeling; redox regulation; reactive oxygen species; nitric oxide; antioxidants; circular chromosome conformation capture; genome architecture; T-DNA; transgenic; chromosomal rearrangements; synthetic biology; n/a

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