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"DNA methylation"

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"DNA methylation"

Research Article

Regulation of Abiotic Stress Response Through NtROS2a-mediated Demethylation in Tobacco
In Hye Lee, Jang Sun Choi, Marjohn Nino, Yong-Gu Cho, Kwon Kyoo Kang, Yu Jin Jung
Plant Breed. Biotech. 2015;3(2):108-118.   Published online June 30, 2015
DOI: https://doi.org/10.9787/PBB.2015.3.2.108

DNA methylation is a common and rapid evolving epigeneticmechanism among higher eukaryotic organisms including cytosine residues in CG and CNG sequences. NtROS2a gene isolated from tobacco plants (Nicotiana tabacum cv Xanthi nc) contains DNA glycosylase domain with significant similarities to Arabidopsis ROS1 and DME at the C-terminus. Purified NtROS2a protein gene is 5879 bp long and is designated as Nicotiana tabacum Repressor Of Silencing (NtROS: accession numbers; AB281588). RT-PCR analysis initially revealed the adaptive response of the lines overexpressing the gene in tobacco to various abiotic stresses. This was validated when phenotypic evaluation to cold, salt, simulated drought and osmotic stress tolerance was performed. Reduction in leaf wilting rate against high salinity treatment is remarkable in transgenic plants which showed at least 50% less wilting than the WT. Moreover, about 70% wilt rate difference was noted between the transgenic and WT in H2O2 treatment. This study showed that NtROS2a gene encoding DNA glycosylase which caused demethylation could regulate adaptive response of tobacco to various abiotic stress conditions.

Citations

Citations to this article as recorded by  
  • How Selenium Alleviates Salt Stress in Tobacco Seedlings: Regulation of Osmotic Adjustment Substances, Antioxidation and Gene Expression
    Shiqi Cao, Yanqiu Wei, Xiuhua Li, Huifang Shao, Wei Jia, Zicheng Xu, Wuxing Huang, Dan Han
    Agronomy.2026; 16(12): 1184.     CrossRef
  • Functional identification of DNA demethylase gene CaROS1 in pepper (Capsicum annuum L.) involved in salt stress
    Xuelian Ou, Qingzhu Hua, Jichi Dong, Kexian Guo, Minghua Wu, Yinjun Deng, Zhiming Wu
    Frontiers in Plant Science.2024;[Epub]     CrossRef
  • Drought induces DNA methylation balance‐related genes in a stage-dependent manner during tomato fruit ripening
    Paulo H. G. A. de Oliveira, Ana C. O. Barbosa, Nathiele S. Araújo, Marcio G. C. Costa
    Theoretical and Experimental Plant Physiology.2024; 36(4): 717.     CrossRef
  • The pattern of DNA methylation alteration, and its association with the expression changes of non-coding RNAs and mRNAs in Moso bamboo under abiotic stress
    Yiqian Ding, Long-Hai Zou, Jiajun Wu, Muthusamy Ramakrishnan, Yubang Gao, Liangzhen Zhao, Mingbing Zhou
    Plant Science.2022; 325: 111451.     CrossRef
  • Genome-Wide Characterization of DNA Demethylase Genes and Their Association with Salt Response in Pyrus
    Chunxiao Liu, Hui Li, Jing Lin, Ying Wang, Xiaoyang Xu, Zong-Ming (Max) Cheng, Yonghong Chang
    Genes.2018; 9(8): 398.     CrossRef
  • Current status and prospects of epigenetic information in sexual reproductive processes of plants
    Yu Jin Jung, Yong-Gu Cho, Kwon Kyoo Kang
    Journal of Plant Biotechnology.2017; 44(1): 19.     CrossRef
  • Overexpression ofNtROS2agene encoding cytosine DNA demethylation enhances drought tolerance in transgenic rice
    Jang Sun Choi, In Hye Lee, Yong-Gu Cho, Yu Jin Jung, Kwon Kyoo Kang
    Journal of Plant Biotechnology.2016; 43(3): 376.     CrossRef
  • DNA microarray analysis of RNAi plant regulated expression ofNtROS2agene encoding cytosine DNA demethylation
    Jang Sun Choi, In Hye Lee, Yu Jin Jung, Kwon Kyoo Kang
    Journal of Plant Biotechnology.2016; 43(2): 231.     CrossRef
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Review Article
Heritable Epigenetic Variation and its Potential Applications for Crop Improvement
Changqing Zhang, Tzung-Fu Hsieh
Plant Breed. Biotech. 2013;1(4):307-319.   Published online December 31, 2013
DOI: https://doi.org/10.9787/PBB.2013.1.4.307

Phenotypic variation within organisms is driven primarily by genetic diversity. However, there is a growing appreciation that epigenetic variation, resulting from a multitude of diverse chemical modifications to the DNA and chromatin, can have profound effects on phenotype. Heritable epigenetic marks persist through meiosis and can be stably transmitted to the next generation, resulting in transgenerational epigenetic inheritance. Importantly, when epigenetic changes occur near coding genes, affecting their transcriptional state, heritable epigenetic variation can result in heritable phenotypic variation. Large-scale interrogation of epigenome inheritance in Arabidopsis has revealed that spontaneous variation in DNA methylation occurs at a rate that is orders of magnitude greater than genetic mutation, indicating the key importance of epigenetic variation during evolution. Thus, there is a potential for epigenetics to play a role in crop improvement, including regulation of transgene expression and creation of novel epialleles. Here, we review cases of naturally occurring and genetically induced epialleles, and discuss how the studies from two epigenetic populations are rapidly increasing our understanding of epigenetic diversity.

Citations

Citations to this article as recorded by  
  • Epigenetic mechanisms regulating plant responses to abiotic stress and their role in developing climate resilient crops
    J. Bevin Nishanth, Baburao Gaddala, S. Suji, P. Rifa Fathima, A. Premkumar, Balasankar Karavadi, R S A Sorna Kumar, J Iyyappan, Yuvaraj Dinakarkumar
    Discover Plants.2025;[Epub]     CrossRef
  • Characterizing sorghum genotypes for forage yield, hydrocyanic acid and sugar contents under arid climate conditions
    Ahmad Sher, Sami Ul-Allah, Abdul Sattar, Lorenzo Barbanti, Muhammad Ijaz
    Plant Genetic Resources: Characterization and Utilization.2023; 21(4): 377.     CrossRef
  • Regulation of plant epigenetic memory in response to cold and heat stress: towards climate resilient agriculture
    Shamsur Rehman, Zishan Ahmad, Muthusamy Ramakrishnan, Ruslan Kalendar, Qiang Zhuge
    Functional & Integrative Genomics.2023;[Epub]     CrossRef
  • Advances in DNA methylation and demethylation in medicinal plants: a review
    Yimei Zang, Lei Xie, Jiaxian Su, Zuliang Luo, Xunli Jia, Xiaojun Ma
    Molecular Biology Reports.2023; 50(9): 7783.     CrossRef
  • Morphological and molecular divergence in ornamental variants of cactus which may be useful to generate new variants
    Andréa Florindo das Neves, Claudete Aparecida Mangolin, Vanessa Neves de Azevedo Fernandes, Eliane Rodrigues Monteiro, Maria de Fátima P. S. Machado
    Plant Genetic Resources: Characterization and Utilization.2022; 20(4): 290.     CrossRef
  • Molecular and genetic bases of heat stress responses in crop plants and breeding for increased resilience and productivity
    Michela Janni, Mariolina Gullì, Elena Maestri, Marta Marmiroli, Babu Valliyodan, Henry T Nguyen, Nelson Marmiroli, Christine Foyer
    Journal of Experimental Botany.2020; 71(13): 3780.     CrossRef
  • Towards Exploitation of Adaptive Traits for Climate-Resilient Smart Pulses
    Jitendra Kumar, Arbind K. Choudhary, Debjyoti Sen Gupta, Shiv Kumar
    International Journal of Molecular Sciences.2019; 20(12): 2971.     CrossRef
  • Abnormalities in somatic embryogenesis caused by 2,4-D: an overview
    Claudia Garcia, Alex-Alan Furtado de Almeida, Marcio Costa, Dahyana Britto, Raúl Valle, Stefan Royaert, Jean-Philippe Marelli
    Plant Cell, Tissue and Organ Culture (PCTOC).2019; 137(2): 193.     CrossRef
  • Transgenerational Perpetuation of CHS Gene Expression and DNA Methylation Status Induced by Short Oligodeoxynucleotides in Flax (Linum usitatissimum)
    Magdalena Dzialo, Jan Szopa, Agata Hnitecka, Magdalena Zuk
    International Journal of Molecular Sciences.2019; 20(16): 3983.     CrossRef
  • Small RNA-based prediction of hybrid performance in maize
    Felix Seifert, Alexander Thiemann, Tobias A. Schrag, Dominika Rybka, Albrecht E. Melchinger, Matthias Frisch, Stefan Scholten
    BMC Genomics.2018;[Epub]     CrossRef
  • Evaluation of Factors Indicating Epigenetic Polymorphism through Population of Maize Seedlings
    A. P. Kravets, D. A. Sokolova
    Cytology and Genetics.2018; 52(3): 174.     CrossRef
  • Epigenetics for Plant Improvement: Current Knowledge and Modeling Avenues
    Philippe Gallusci, Zhanwu Dai, Michel Génard, Arnaud Gauffretau, Nathalie Leblanc-Fournier, Céline Richard-Molard, Denis Vile, Sophie Brunel-Muguet
    Trends in Plant Science.2017; 22(7): 610.     CrossRef
  • Fifteen years of quantitative trait loci studies in fish: challenges and future directions
    David T. Ashton, Peter A. Ritchie, Maren Wellenreuther
    Molecular Ecology.2017; 26(6): 1465.     CrossRef
  • Plant Stress Responses and Phenotypic Plasticity in the Epigenomics Era: Perspectives on the Grapevine Scenario, a Model for Perennial Crop Plants
    Ana M. Fortes, Philippe Gallusci
    Frontiers in Plant Science.2017;[Epub]     CrossRef
  • New insights into plant somatic embryogenesis: an epigenetic view
    Vijay Kumar, Johannes Van Staden
    Acta Physiologiae Plantarum.2017;[Epub]     CrossRef
  • Epigenetic mechanisms regulating seed germination rate
    O. P. Kravets, D. O. Sokolova
    Cytology and Genetics.2017; 51(5): 346.     CrossRef
  • Genetic and Epigenetic Approaches for the Possible Detection of Adulteration and Auto-Adulteration in Saffron (Crocus sativus L.) Spice
    Giovanna Soffritti, Matteo Busconi, Rosa Sánchez, Jean-Marie Thiercelin, Moschos Polissiou, Marta Roldán, José Fernández
    Molecules.2016; 21(3): 343.     CrossRef
  • Nongenetic Inheritance of Induced Resistance in a Wild Annual Plant
    Åsa Lankinen, Kibrom B. Abreha, Erik Alexandersson, Stefan Andersson, Erik Andreasson
    Phytopathology®.2016; 106(8): 877.     CrossRef
  • Epigenome Editing of Potato by Grafting Using Transgenic Tobacco as siRNA Donor
    Atsushi Kasai, Songling Bai, Hatsune Hojo, Takeo Harada, Sriharsa Pradhan
    PLOS ONE.2016; 11(8): e0161729.     CrossRef
  • AFLP and MS-AFLP Analysis of the Variation within Saffron Crocus (Crocus sativus L.) Germplasm
    Matteo Busconi, Licia Colli, Rosa Ana Sánchez, Marcela Santaella, Marcelino De-Los-Mozos Pascual, Omar Santana, Marta Roldán, José-Antonio Fernández, Mark Gijzen
    PLOS ONE.2015; 10(4): e0123434.     CrossRef
  • Correlating aluminium toxicity, heterosis and epigenetic mechanisms in maize yield improvement in acid soils
    Josphert
    Biotechnology and Molecular Biology Reviews.2015; 10(2): 12.     CrossRef
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  • 21 Crossref