The establishment and maintenance of DNA methylation are relatively well understood whereas little is known about their dynamics and biological relevance in innate immunity. In plants, modulation of DNA methylation might be an effective mechanism to regulate gene expression in response to abiotic and biotic stresses. Recent evidence through large-scale epigenomic approaches indicate that dynamic DNA methylation changes are not limited to gene imprinting but can regulate the plant's immune system in response to pathogens. In plants, virus infections trigger expression and regulation of non-coding smallRNAs, and genomic regions are epigenetically modified through the action of the same molecules; however, the involvement of DNA methylation in regulation of plant immune system in response to virus infection was not investigated before. We have examined for the first time the impact of virus infections on genomic DNA methylation and the correlation with smallRNA regulation and gene expression by integrating together analysis of multiple "omics" datasets based on next-generation sequencing platforms. To investigate the possibility that DNA methylation dynamically responds to virus infection, we performed whole-genome bisulfite sequencing on Arabidopsis leaves systemically infected with either the DNA genome virus Cauliflower mosaic virus (CaMV-Arabidopsis) or the RNA virus Cucumber mosaic virus (CMV-Arabidopsis). Single-base resolution methylome analysis revealed more than 3.7million methyl-cytosines (mCs) for the control plant. Interestingly in CMV-Arabidopsis we found 300.000 more mCs (hypermethylated) and in CaMV-Arabidopsis 700.000 mCs less (hypomethylated). Focusing on differentially methylated regions (DMR, 250nt in length) we observed a balanced distribution of hyper- and hypomethylation in CG and CHH context in CMV-Arabidopsis (total DMRs 2700) but in CaMV-Arabidopsis we have predominantly hypomethylated DMRs in CHH context (total DMRs 5600). Gene features including coding, non-coding and promoter sequences were assigned to unique gene identifiers according to the TAIR nomenclature. Among differentially methylated gene features, promoter regions were the vast majority, accounting, in specific mCs contexts, for up to 80% of the total. The whole gene ID dataset was subjected to gene functional enrichment analysis by using the DAVID package tool. Interestingly, definite functional categories such as "plant defense" and "auxin signalling pathway" resulted significantly enriched. The correlation between the DNA methylation status and the transcriptional modulation of those genes is under investigation. A comparison between methylation profiles induced by either CaMV or CMV infections revealed conspicuous qualitative and quantitative differences. Taken together our results indicate that RNA- and DNA-genome virus infection induce different regulation of DNA methylation and, at least in part, different immune response in Arabidopsis.
Plant responses to two diverse viruses involve different DNA methylation profiles
Cillo F;Tulipano A;Carluccio AV;D'elia D;Stavolone L;Gisel A
2015
Abstract
The establishment and maintenance of DNA methylation are relatively well understood whereas little is known about their dynamics and biological relevance in innate immunity. In plants, modulation of DNA methylation might be an effective mechanism to regulate gene expression in response to abiotic and biotic stresses. Recent evidence through large-scale epigenomic approaches indicate that dynamic DNA methylation changes are not limited to gene imprinting but can regulate the plant's immune system in response to pathogens. In plants, virus infections trigger expression and regulation of non-coding smallRNAs, and genomic regions are epigenetically modified through the action of the same molecules; however, the involvement of DNA methylation in regulation of plant immune system in response to virus infection was not investigated before. We have examined for the first time the impact of virus infections on genomic DNA methylation and the correlation with smallRNA regulation and gene expression by integrating together analysis of multiple "omics" datasets based on next-generation sequencing platforms. To investigate the possibility that DNA methylation dynamically responds to virus infection, we performed whole-genome bisulfite sequencing on Arabidopsis leaves systemically infected with either the DNA genome virus Cauliflower mosaic virus (CaMV-Arabidopsis) or the RNA virus Cucumber mosaic virus (CMV-Arabidopsis). Single-base resolution methylome analysis revealed more than 3.7million methyl-cytosines (mCs) for the control plant. Interestingly in CMV-Arabidopsis we found 300.000 more mCs (hypermethylated) and in CaMV-Arabidopsis 700.000 mCs less (hypomethylated). Focusing on differentially methylated regions (DMR, 250nt in length) we observed a balanced distribution of hyper- and hypomethylation in CG and CHH context in CMV-Arabidopsis (total DMRs 2700) but in CaMV-Arabidopsis we have predominantly hypomethylated DMRs in CHH context (total DMRs 5600). Gene features including coding, non-coding and promoter sequences were assigned to unique gene identifiers according to the TAIR nomenclature. Among differentially methylated gene features, promoter regions were the vast majority, accounting, in specific mCs contexts, for up to 80% of the total. The whole gene ID dataset was subjected to gene functional enrichment analysis by using the DAVID package tool. Interestingly, definite functional categories such as "plant defense" and "auxin signalling pathway" resulted significantly enriched. The correlation between the DNA methylation status and the transcriptional modulation of those genes is under investigation. A comparison between methylation profiles induced by either CaMV or CMV infections revealed conspicuous qualitative and quantitative differences. Taken together our results indicate that RNA- and DNA-genome virus infection induce different regulation of DNA methylation and, at least in part, different immune response in Arabidopsis.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.