Salt stress alters DNA methylation levels in alfalfa (Medicago spp)

Al-Bahry, Saif N.; Victor, Reginald; Al-Lawati, A.; Yaish, Mahmoud W.

doi:10.4238/gmr.15018299

Cited by 52 publications

(29 citation statements)

References 39 publications

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“…This is interesting that desiccation stress response in Nagina 22 is mediated via hypomethylation in CHH context and salinity stress response in Pokkali is mediated via hypermethylation in CHH context. Previous studies have also demonstrated that hypomethylation associated with higher gene expression under drought/salinity stress response and hypermethylation associated with higher gene expression under salinity stress response (Boyko et al ., 2010; Wang et al ., 2014; Al-Lawati et al ., 2016). These results suggest that abiotic stress response(s) is dependent on cultivar specific manner.…”

Section: Resultsmentioning

confidence: 99%

“…However, methylation differences between drought-tolerant and susceptible cultivars under control conditions were mostly found in CG context in rice (Garg et al ., 2015). Likewise, methylation dynamics under salinity stress have also been investigated in susceptible and tolerant cultivars in different plants using various approaches, and methylation changes under the stress conditions were found to be genotype-specific (Wang et al ., 2014; Al-Lawati et al ., 2016; Lu et al ., 2017). Interestingly, methylation changes induced in response to abiotic stress condition(s) reversed to its original methylation status after stress recovery (Wang et al ., 2011).…”

Section: Introductionmentioning

confidence: 99%

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Role of DNA methylation dynamics in desiccation and salinity stress responses in rice cultivars

Rajkumar

Shankar

Garg

et al. 2019

Preprint

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Word count: 5338 25 26Highlight: Bisulphite sequencing revealed single base resolution DNA methylation, and 27 cultivar-specific differential methylation patterns and correlation with gene expression that 28 control desiccation and salinity stress response in the rice cultivars. 29 30 2 Abstract 31 DNA methylation is an epigenetic mark that controls gene expression in response to internal and 32 environmental cues. In this study, we sought to understand the role of DNA methylation in 33 response to desiccation and salinity stresses in three rice cultivars (IR64, stress-sensitive; 34Nagina 22, drought-tolerant and Pokkali, salinity-tolerant) via bisulphite sequencing. We 35 identified DNA methylation patterns in different genomic/genic regions and analysed their 36 correlation with gene expression. Methylation in CG context within gene body and methylation 37 in CHH context in distal promoter regions were positively correlated with gene expression. 38However, methylation in other sequence contexts and genic regions was negatively correlated 39 with gene expression. DNA methylation was found to be most dynamic in CHH context under 40 stress condition(s) in the rice cultivars. The expression profiles of genes involved in de-novo 41 methylation were correlated with methylation dynamics. Hypomethylation in Nagina 22 and 42 hypermethylation in Pokkali in response to desiccation and salinity stress, respectively, were 43 correlated with higher expression of abiotic stress response related genes. Our results suggest an 44 important role of DNA methylation in abiotic stress responses in rice in cultivar-specific 45 manner. This study provides useful resource of DNA methylomes that can be integrated with 46 other data to understand abiotic stress response in rice. 47 48 49

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Role of DNA methylation dynamics in desiccation and salinity stress responses in rice cultivars

Rajkumar

Shankar

Garg

et al. 2019

Preprint

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“…This method is based primarily on Amplified Fragments Length Polymorphism (AFLP) analysis. 49 It uses two different reactions with MspI/EcoRI, and HpaII/EcoRI. The isoschizomeres recognize the same DNA site 5 0 -CCGG-3 0 with different sensitivity to methylation.…”

Section: Msap Epigenotypingmentioning

confidence: 99%

Genome-wide analysis of cytosine DNA methylation revealed salicylic acid promotes defense pathways over seedling development in pearl millet

Ngom¹,

Sarr

Kimatu

et al. 2017

Plant Signaling & Behavior

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Cytosine DNA methylation is an epigenetic regulatory system used by plants to control gene expression. Methylation pattern always changes after abiotic stresses, pathogens and pest infections or after a treatment with salicylic acid (SA). The latter is a key player in plant development and defense against insect herbivores, pathogens, and abiotic stresses. The roles of SA on the methylation patterns and the plant development were performed in 4 pearl millet (Pennisetum glaucum) varieties. Seedlings of 4 early-flowering photosensitive genotypes (PMS3, PMI8, PMG, and PMT2) were grown on MS medium supplemented with null or different doses of SA. Root growth was used as a parameter to evaluate the effects of SA at early stage development. DNA from these seedlings was extracted and Methylation-Sensitive Amplified Polymorphism (MSAP) was measured to assess the effects of SA on methylome. The methylation analysis revealed that SA treatment decreased the methylation, while inhibiting the root growth for all varieties tested, except in PMG at 0.5 mM, indicating a dose and a genotype response-dependence. The methylation level was positively correlated with the root growth. This suggests that SA influences both the methylome by demethylation activities and the root growth by interfering with the root development-responsive genes. The demethylation process, induced by the REPRESSOR OF SILCENCING 1 (ROS1) may activate R genes, or GH3.5 and downregulate the hormonal pathway under root development. These findings showed the pearl millet metabolism prioritized and promoted the defense pathways over vegetative development during stress.

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“…Overall, the emergence for the appreciation of the role of epigenetics in an ecological context has developed in both aquatic and terrestrial systems (Bonduriansky et al, 2012). Studies on plants have dominated the literature on ecological epigenetics (Schrey et al, 2013;Baulcombe and Dean, 2014;Verhoeven et al, 2016), especially in response to stress (Wang et al, 2011;Grativol et al, 2012;Al-Lawati et al, 2016). On the marine side, epigenetic and epigenomic approaches are being used to explore areas such as (1) sources of phenotypic plasticity, as created by differential gene expression (Dixon et al, 2014;Dimond and Roberts, 2016;Marsh et al, 2016), (2) mechanisms involved in development (Riviere et al, 2013), and (3) a possible rapid response to anthropogenic environmental change (Putnam et al, 2016).…”

Section: Epigenetics-a Brief Overviewmentioning

confidence: 99%

Ecological Epigenetics in Marine Metazoans

Hofmann

2017

Front. Mar. Sci.

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In this horizon scan article, I review the emerging area of ecological epigenetics in marine animals with studies of DNA methylation as the primary focus. Epigenetic mechanisms such as DNA methylation have the capacity to create rapid changes in phenotypic plasticity. Epigenetic modifications of DNA are mechanisms that modify gene expression, and may do so in marine animals in an environmentally-induced manner. Thus, changes in the transcriptome that are driven by DNA methylation in response to environmental change may be one process by which marine animals can respond to anthropogenic, environmental change. From a technical standpoint, assays to quantify levels of DNA methylation, and next-generation sequencing approaches are opening up new avenues of exploration, such as simultaneously profiling the transcriptome and the methylome. A horizon scan for this topic suggests that the use of epigenomics and other methods to quantify DNA methylation will likely reveal important mechanisms of response to rapid environmental change in marine metazoans.

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Salt stress alters DNA methylation levels in alfalfa (Medicago spp)

Cited by 52 publications

References 39 publications

Role of DNA methylation dynamics in desiccation and salinity stress responses in rice cultivars

Role of DNA methylation dynamics in desiccation and salinity stress responses in rice cultivars

Genome-wide analysis of cytosine DNA methylation revealed salicylic acid promotes defense pathways over seedling development in pearl millet

Ecological Epigenetics in Marine Metazoans

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