Submitted Successfully!
Thank you for your contribution! You can also upload a video entry related to this topic through the link below:
https://encyclopedia.pub/user/video_add?id=744
Check Note
2000/2000
Ver. Summary Created by Modification Content Size Created at Operation
1 This Entry Collection focuses on current progress in understanding the role of chromatin structure, its modifications and remodeling in developmental and physiological processes. + 1746 word(s) 1746 2020-04-30 11:40:24 |
2 format correct -452 word(s) 1294 2020-05-12 09:48:46 | |
3 format correct -452 word(s) 1294 2020-05-12 10:05:41 | |
4 format correct Meta information modification 1294 2020-05-12 10:07:15 | |
5 format correct -9 word(s) 1285 2020-10-29 07:51:52 |
Chromatin, Epigenetics and Plant Physiology
Edit
Upload a video

This Entry Collection 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 understanding 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.

chromatin assembly and remodeling chromosome introgression centromere and kinetochore plant epigenetics histone variants histone posttranslational modifications regulatory RNAs redox signaling plant hormone signaling developmental gene regulation.
Information
Subjects: Others
Contributor :
View Times: 337
Revisions: 5 times (View History)
Update Time: 29 Oct 2020

1. Introduction

The ever-increasing interest in epigenetics comes from the fact that in the diverse life situations of organisms, e.g., in cell differentiation, developmental decisions, or responses to biotic and abiotic stresses, it is primarily the reprogramming of the regulation of the existing genetic information, rather than its direct change, that solves the problem. Epigenetic mechanisms allow the organism to channel the appropriate response through diverse particular molecular tools modifying distinct levels of the structure of chromatin. Chromatin is thus marked with certain signals, for example, DNA methylation, posttranslational modifications of histones, incorporation of specific histone variants, or chromatin remodeling. These signals, written by respective enzymes and complexes, termed as epigenetic writers (e.g., DNA methyltransferases, histone methyltransferases, and histone acetyltransferases) have to find their readers—biomolecules recognizing the specific mark, and erasers which are capable of resetting the program. Recent data suggest a deep interconnection of individual epigenetic players, which frequently act together as components of the same multi-subunit complexes. For example, methylcytosine binding protein MeCP2 (a reader) recruits histone deacetylase (an eraser) and H3K9 histone methyltransferase Suv39h1 (a writer), and in this way reinforces the repressive state of a chromatin region [1][2]. Recent research in plants brings many novel findings elucidating the interdependence of diverse epigenetic mechanisms and their crosstalk with various signaling pathways, including the action of phytohormones and reactive oxygen and nitrogen species. Using these molecular tools, chromatin structure decides which particular set of genes will be active in a particular physiological process.

2. History and Development

The special issue “Chromatin, Epigenetics and Plant Physiology” in the International Journal of Molecular Sciences comprises two review articles and eight original research papers (Table 1). All contributions deal with important aspects of epigenetic regulations of crucial cellular processes involved in plant growth and development.

Table 1. Contributors to the special issue “Chromatin, Epigenetics and Plant Physiology”.

Authors Title Type
Wang et al. [3] Roles of the INO80 and SWR1 Chromatin Remodeling Complexes in Plants Review
Guo et al. [4] Mutations in the Rice OsCHR4 Gene, Encoding a CHD3 Family Chromatin Remodeler, Induce Narrow and Rolled Leaves with Increased Cuticular Wax Original
Research
Zhao et al. [5] Identification and Characterization of Tomato SWI3-Like Proteins: Overexpression of SlSWIC Increases the Leaf Size in Transgenic Arabidopsis Original
Research
Gratkowska-Zmuda et al. [6] The SWI/SNF ATP-Dependent Chromatin Remodeling Complex in Arabidopsis Responds to Environmental Changes in Temperature-Dependent Manner Original
Research
Krispil et al. [7] The Position and Complex Genomic Architecture of Plant T-DNA Insertions Revealed by 4SEE Original
Research
Lochmanová
et al. [8]
Different Modes of Action of Genetic and Chemical Downregulation of Histone Deacetylases with Respect to Plant Development and Histone Modifications Original
Research
Koláčková et al. [9] Nuclear Disposition of Alien Chromosome Introgressions into Wheat and Rye Using 3D-FISH Original
Research
Zhang et al. [10] Identification and Characterization of circRNAs Responsive to Methyl Jasmonate in Arabidopsis thaliana Original
Research
Boudichevskaia et al. [11] Depletion of KNL2 Results in Altered Expression of Genes Involved in Regulation of the Cell Cycle, Transcription, and Development in Arabidopsis Original
Research
R.M.S. et al. [12] Redox Components: Key-Regulators of Epigenetic Modifications in Plants Review

Four articles, one review, and three research papers deal with chromatin remodeling complexes. Wang et al. [3] provide a review on the role of Arabidopsis SWR1 and INO80 chromatin remodeling complexes involved in the regulation of the replacement of nucleosomal H2A/H2B dimers with H2A.Z/H2B. The authors describe the composition of the SWR1/INO80-c complex and discuss its diverse nuclear roles ranging from repair processes to regulation of gene expression. Guo et al. [4] report on the involvement of the chromatin remodeler encoded by the OsCHR4 gene in regulation of rice leaf morphology, via modulation of accumulation of cuticle wax on leaf surfaces and auxin biosynthesis. Expression profiles and subcellular localizations of tomato SWI3-like proteins were studied by Zhao et al. [5]. The authors further identify interactions of these subunits of the chromatin remodeling complex with proteins participating in the reproductive development. Their observations support the idea of evolutionary conservation of SWI3 physiological functions in different plant species. Similarly, the involvement of the SWI subunits of the chromatin remodeling complex in temperature-dependent regulation of plant growth and developmental responses in Arabidopsis is reported by Gratkowska-Zmuda et al. [6]. Altogether, these results demonstrate the importance of the proper chromatin remodeling in crucial cellular processes, including gene expression, cell cycle regulation, DNA replication and repair, and hormone signaling.

Results presented in two papers within the special issue “Chromatin, Epigenetics, and Plant Physiology” were obtained using specific advanced methodical approaches. Circular chromosome conformation capture (4C)-based method was utilized by Krispil et al. [7] for the detection of the entire scope of T-DNA insertions, by capturing the local enrichment of spatial chromosomal associations in their genomic proximity without prior knowledge of their genomic locations in Arabidopsis transgenic lines. This approach enables the identification of previously unmapped T-DNA insertions and related chromosomal rearrangements and is applicable to any plant with a sequenced genome. Lochmanová et al. [8] studied the acetylation of histone proteins by a mass spectrometry-based proteomic approach. They conclude that the effect of epigenetically active drugs on early plant development is complex and is not restricted to the ability of these compounds to modulate the levels of histone acetylation marks.

Koláčková et al. [9] solved an interesting problem of the spatial organization of parental genomes in the somatic nuclei of interspecific plant hybrids. They demonstrate that domains of introgressed chromosomes are highly stable among the tissue types and during the cell cycle phases. High-throughput sequencing of Arabidopsis seedlings exposed to methyl jasmonic acid was performed by Zhang et al. [10] to identify differentially expressed circular RNAs. Based on their data, differentially expressed circular RNAs are involved in metabolic and developmental processes and are supposed to play important roles in methyl jasmonic acid-mediated signaling. Boudichevskaia et al. [11] dealt with the characterization of the role of Arabidopsis KNL2 (kinetochore null 2), which is important for deposition of CENH3 at centromeric regions. Transcriptomic analysis of mutant plants reveals that the KNL2 gene loss of function affects processes of cell cycle regulation, transcription, development, and DNA repair. In the review article by R.M.S. et al. [12], the impact of redox components on activities of important epigenetic regulators was described. Authors provide an integrated view on the roles of oxidants (reactive oxygen species and nitric oxide) and antioxidants (pyridine nucleotides and glutathione) in the modulation of DNA methylation and histone modifications in plants.

Together, this collection offers diverse insights into the current plant epigenetics to allow readers to update their knowledge on the described phenomena and mechanisms in this highly complex and quickly evolving field.

References

  1. François Fuks; Paul Hurd; Daniel Wolf; Xinsheng Nan; Adrian Bird; Tony Kouzarides; The Methyl-CpG-binding Protein MeCP2 Links DNA Methylation to Histone Methylation. Journal of Biological Chemistry 2002, 278, 4035-4040, 10.1074/jbc.m210256200.
  2. Peter L. Jones; Gert Jan C. Veenstra; Paul A. Wade; Danielle Vermaak; Stefan U. Kass; Nicoletta Landsberger; John Strouboulis; Alan P. Wolffe; Methylated DNA and MeCP2 recruit histone deacetylase to repress transcription. Nature Genetics 1998, 19, 187-191, 10.1038/561.
  3. Jianhao Wang; Sujuan Gao; Xiuling Peng; Keqiang Wu; Yangsongguang Yang; Roles of the INO80 and SWR1 Chromatin Remodeling Complexes in Plants.. International Journal of Molecular Sciences 2019, 20, 4591, 10.3390/ijms20184591.
  4. Tingting Guo; Daofeng Wang; Jingjing Fang; Jinfeng Zhao; Shoujiang Yuan; Langtao Xiao; Xueyong Li; Mutations in the Rice OsCHR4 Gene, Encoding a CHD3 Family Chromatin Remodeler, Induce Narrow and Rolled Leaves with Increased Cuticular Wax. International Journal of Molecular Sciences 2019, 20, 2567, 10.3390/ijms20102567.
  5. Zhongyi Zhao; Tao Li; Xiuling Peng; Keqiang Wu; Yangsongguang Yang; Identification and Characterization of Tomato SWI3-Like Proteins: Overexpression of SlSWIC Increases the Leaf Size in Transgenic Arabidopsis.. International Journal of Molecular Sciences 2019, 20, 5121, 10.3390/ijms20205121.
  6. Dominika M. Gratkowska-Zmuda; Szymon Kubala; Elzbieta Sarnowska; Pawel Cwiek; Paulina Oksinska; Jaroslaw Steciuk; Anna T. Rolicka; Magdalena Zaborowska; Ernest Bucior; Anna Maassen; et al. The SWI/SNF ATP-Dependent Chromatin Remodeling Complex in Arabidopsis Responds to Environmental Changes in Temperature-Dependent Manner. International Journal of Molecular Sciences 2020, 21, 762, 10.3390/ijms21030762.
  7. Ronen Krispil; Miriam Tannenbaum; Avital Sarusi-Portuguez; Olga Loza; Olga Raskina; Ofir Hakim; The Position and Complex Genomic Architecture of Plant T-DNA Insertions Revealed by 4SEE. International Journal of Molecular Sciences 2020, 21, 2373, 10.3390/ijms21072373.
  8. Gabriela Lochmanová; Ivana Ihnatová; Hana Kuchaříková; Sylva Brabencová; Dagmar Zachová; Jiří Fajkus; Zbyněk Zdráhal; Miloslava Fojtová; Different Modes of Action of Genetic and Chemical Downregulation of Histone Deacetylases with Respect to Plant Development and Histone Modifications.. International Journal of Molecular Sciences 2019, 20, 5093, 10.3390/ijms20205093.
  9. Veronika Kolackova; Kateřina Perničková; Jan Vrána; Martin Duchoslav; Glyn Jenkins; Dylan W. Phillips; Edina Turkosi; Olga Samajova; Michaela Sedlarova; Jozef Šamaj; et al. Nuclear Disposition of Alien Chromosome Introgressions into Wheat and Rye Using 3D-FISH.. International Journal of Molecular Sciences 2019, 20, 4143, 10.3390/ijms20174143.
  10. Jingjing Zhang; Ruiqi Liu; Yanfeng Zhu; Jiaxin Gong; Shuwei Yin; Peisen Sun; Hao Feng; Qi Wang; Shuaijing Zhao; Zhongyuan Wang; et al. Identification and Characterization of circRNAs Responsive to Methyl Jasmonate in Arabidopsis thaliana. International Journal of Molecular Sciences 2020, 21, 792, 10.3390/ijms21030792.
  11. Anastassia Boudichevskaia; Andreas Houben; Anne Fiebig; Klara Prochazkova; Ales Pecinka; Inna Lermontova; Depletion of KNL2 Results in Altered Expression of Genes Involved in Regulation of the Cell Cycle, Transcription, and Development in Arabidopsis. International Journal of Molecular Sciences 2019, 20, 5726, 10.3390/ijms20225726.
  12. Saravana Kumar R M; Yibin Wang; Xiaopan Zhang; Hui Cheng; Li Rong Sun; Shibin He; Fu Shun Hao; Redox Components: Key Regulators of Epigenetic Modifications in Plants. International Journal of Molecular Sciences 2020, 21, 1419, 10.3390/ijms21041419.
More
Information
Subjects: Others
Contributor MDPI registered users' name will be linked to their SciProfiles pages. To register with us, please refer to https://encyclopedia.pub/register :
View Times: 337
Revisions: 5 times (View History)
Update Time: 29 Oct 2020
Table of Contents
    1000/1000

    Confirm

    Are you sure to Delete?

    Video Upload Options

    Do you have a full video?
    Cite
    If you have any further questions, please contact Encyclopedia Editorial Office.
    Fajkus, J. Chromatin, Epigenetics and Plant Physiology. Encyclopedia. Available online: https://encyclopedia.pub/entry/744 (accessed on 02 October 2022).
    Fajkus J. Chromatin, Epigenetics and Plant Physiology. Encyclopedia. Available at: https://encyclopedia.pub/entry/744. Accessed October 02, 2022.
    Fajkus, Jiří. "Chromatin, Epigenetics and Plant Physiology," Encyclopedia, https://encyclopedia.pub/entry/744 (accessed October 02, 2022).
    Fajkus, J. (2020, May 06). Chromatin, Epigenetics and Plant Physiology. In Encyclopedia. https://encyclopedia.pub/entry/744
    Fajkus, Jiří. ''Chromatin, Epigenetics and Plant Physiology.'' Encyclopedia. Web. 06 May, 2020.
    Top
    Feedback