Project description:Arbuscular mycorrhizal (AM) fungi form mutualistic relationships with most land plant species. AM fungi have long been considered as ancient asexuals. Long-term clonal evolution would be remarkable for a eukaryotic lineage and suggests the importance of alternative mechanisms to promote genetic variability facilitating adaptation. Here, we assessed the potential of transposable elements (TEs) for generating genomic diversity. The dynamic expression of TEs during Rhizophagus irregularis spore development suggests ongoing TE activity. We find Mutator-like elements located near genes belonging to highly expanded gene families. Characterising the epigenomic status of R. irregularis provides evidence of DNA methylation and small RNA production occurring at TE loci. Our results support a potential role for TEs in shaping the genome, and roles for DNA methylation and small RNA-mediated silencing in regulating TEs. A well-controlled balance between TE activity and repression may therefore contribute to genome evolution in AM fungi.

Project description:DNA methylation is an epigenetic modification that specifies the basic state of pluripotent stem cells and regulates the developmental transition from stem cells to various cell types. In flowering plants, the shoot apical meristem (SAM) contains a pluripotent stem cell population which generates the aerial part of plants including the germ cells. Under appropriate conditions, the SAM undergoes a developmental transition from a leaf-forming vegetative SAM to an inflorescence- and flower-forming reproductive SAM. While SAM characteristics are largely altered in this transition, the complete picture of DNA methylation remains elusive. Here, by analyzing whole-genome DNA methylation of isolated rice SAMs in the vegetative and reproductive stages, we found that methylation at CHH sites is kept high, particularly at transposable elements (TEs), in the vegetative SAM relative to the differentiated leaf, and increases in the reproductive SAM via the RNA-dependent DNA methylation pathway. We also found that half of the TEs that were highly methylated in gametes had already undergone CHH hypermethylation in the SAM. Our results indicate that changes in DNA methylation begin in the SAM long before germ cell differentiation to protect the genome from harmful TEs.

Project description:DNA methylation is an important epigenetic modification involved in many biological processes and diseases. Many studies have mapped DNA methylation changes associated with embryogenesis, cell differentiation and cancer at a genome-wide scale. Our understanding of genome-wide DNA methylation changes in a developmental or disease-related context has been steadily growing. However, the investigation of which CpGs are variably methylated in different normal cell or tissue types is still limited. Here we present an in-depth analysis of 54 single-CpG-resolution DNA methylomes of normal human cell types by integrating high-throughput sequencing-based methylation data. We find that the percentage of unmethylated CpGs is relatively fixed regardless of cell type. However, which CpGs are unmethylated is cell-type specific. We categorize the 26 million human autosomal CpGs based on their methylation levels across multiple cell types to identify variably methylated CpGs. Among all the autosomal CpGs, 22.6% exhibit variable DNA methylation across cell types included in our study. These variably methylated CpGs form 66 thousand variably methylated regions (VMRs), encompassing 11% of the genome. By integrating a multitude of genomic data, we found that VMRs enrich for histone modifications indicative of enhancers, suggesting their role as regulatory elements marking cell type specificity. VMRs enrich for transcription factor binding sites in a tissue-dependent manner. Importantly, they enrich for GWAS variants, suggesting VMRs could potentially be implicated in disease and complex traits. Taken together, our results highlight the link among CpG methylation variation, genetic variation and disease risk in a tissue-specific manner for many human cell types. Processed data includes new Samples and 75 Samples from GSE16368 and 2 Samples from GSE51565.

Project description:DNA methylation is an important epigenetic modification involved in many biological processes and diseases. Many studies have mapped DNA methylation changes associated with embryogenesis, cell differentiation and cancer at a genome-wide scale. Our understanding of genome-wide DNA methylation changes in a developmental or disease-related context has been steadily growing. However, the investigation of which CpGs are variably methylated in different normal cell or tissue types is still limited. Here we present an in-depth analysis of 54 single-CpG-resolution DNA methylomes of normal human cell types by integrating high-throughput sequencing-based methylation data. We find that the percentage of unmethylated CpGs is relatively fixed regardless of cell type. However, which CpGs are unmethylated is cell-type specific. We categorize the 26 million human autosomal CpGs based on their methylation levels across multiple cell types to identify variably methylated CpGs. Among all the autosomal CpGs, 22.6% exhibit variable DNA methylation across cell types included in our study. These variably methylated CpGs form 66 thousand variably methylated regions (VMRs), encompassing 11% of the genome. By integrating a multitude of genomic data, we found that VMRs enrich for histone modifications indicative of enhancers, suggesting their role as regulatory elements marking cell type specificity. VMRs enrich for transcription factor binding sites in a tissue-dependent manner. Importantly, they enrich for GWAS variants, suggesting VMRs could potentially be implicated in disease and complex traits. Taken together, our results highlight the link among CpG methylation variation, genetic variation and disease risk in a tissue-specific manner for many human cell types.

Project description:Purpose: ME/CFS is a debilitating and complex disease. The majority of patients exist in a chronic state of health where they are affected by relapse events. Precision medicine following patients can capture changes in the DNA methylation indicative of biological dysfunction Methods: DNA was extracted from the PBMCs of 2 ME/CFS patients and a age/gender matched control at five different time points. After performing RRBS the sequence was aligned to hg19 genome using Bismark. The data was analyzed using a Chi squared test through DMAP in order to determine variation between the patient and control groups across 40-220bp fragments of the genome. Results: A total of 17 and 14 statistically significant variably methylated fragements were indentified in each patient that strongly associated with a relapse event. These fragements were found on regions of regulatory importance of the genome that associated with immune (primarily inflammatory) and metabolic function. Conclusions: Our study represents the first investigation of ME/CFS patients using reduced representation bisulfite sequencing along a longitudinal timeframe. We captured a number of major variably methylated fragments in each patient that associated with their relapse events. Our results identified a number of differentially methylated regulatory elements and gene bodies that highlight the disturbed pathophysiology in ME/CFS. DNA methylation that differentiates disease variability in ongoing ME/CFS may have practical applications for strategies to deacrease the frequency and severity of relapse events.

Project description:DNA methylation is important for silencing transposable elements (TEs) in diverse eukaryotes including plants. In plant genomes, TEs are heavily methylated at cytosines of both CG and non-CG (or CH, where H can be A, T, or C) contexts. The role of RNA interference (RNAi) in establishing TE-specific DNA methylation has been extensively studied, although the significance of RNAi-independent pathways in DNA-methylation reprograming remains unexplored. Here, we directly investigated transgenerational de novo DNA methylation of TEs after the loss of DNA methylation. Our analyses identified very potent and precise RNAi-independent pathways for recovering CH methylation in most TE genes, or coding regions within TEs. Characterization of a small subset of TE genes that did not show CH methylation recovery revealed the impacts of H3K9 demethylation and replacement of histone H2A variants. These chromatin components are conserved between plants and animals and may contribute to chromatin reprograming in a conserved manner.

Project description:Imprinted gene expression occurs during seed development in plants and is associated with differential DNA methylation of parental alleles, particularly at proximal transposable elements (TEs). Imprinting variability could contribute to observed parent-of-origin effects on seed development. We investigated intraspecific variation in imprinting, coupled with analysis of DNA methylation and small RNAs, among three Arabidopsis strains with diverse seed phenotypes. The majority of imprinted genes were parentally biased in the same manner among all strains. However, we identified several examples of allele-specific imprinting correlated with intraspecific epigenetic variation at a TE. We successfully predicted imprinting in additional strains based on methylation variability. We conclude that there is standing variation in imprinting even in recently diverged genotypes due to intraspecific epiallelic variation. These data demonstrate that epiallelic variation and genomic imprinting intersect to produce novel gene expression patterns in seeds. Whole genome bisulfite sequencing of embryo and endosperm (14 samples).

Project description:DNA methylation is an important epigenetic modification that is thought to contribute to the maintenance of genomic integrity in somatic cells, in part through the silencing of transposable elements (TEs). In this study we used CRISPR/Cas9 mediated gene editing to disrupt DNMT1, the key maintenance methyltransferase in somatic human cells. Surprisingly, and in contrast to findings in mouse, inactivation of DNMT1 in human neural progenitor cells (hNPCs) resulted in viable proliferating cells that maintained the expression of appropriate marker genes. Removal of DNA methylation in hNPCs resulted in a specific activation of hominid-specific LINE-1 elements (L1s), while other classes of TEs remained silent. We also found that the transcriptionally activated L1s acted as alternative promoters for many protein-coding genes involved in neuronal functions, uncovering an L1-based transcriptional network influencing neuronal protein-coding genes. Our results prove novel mechanistic insight into the role of DNA methylation in somatic human cells.

Project description:The PIWI protein MIWI2 and its associated PIWI-interacting RNAs (piRNAs) instruct DNA methylation of young active transposable elements (TEs) in the male germline. Here we show that MIWI2 associates with TEX15 in foetal gonocytes. TEX15 is predominantly a nuclear protein that is not required for piRNA biogenesis but is essential for piRNA-directed TE de novo methylation and silencing. In summary, TEX15 is an essential executor of mammalian piRNA-directed DNA methylation.

Project description:Imprinted gene expression occurs during seed development in plants and is associated with differential DNA methylation of parental alleles, particularly at proximal transposable elements (TEs). Imprinting variability could contribute to observed parent-of-origin effects on seed development. We investigated intraspecific variation in imprinting, coupled with analysis of DNA methylation and small RNAs, among three Arabidopsis strains with diverse seed phenotypes. The majority of imprinted genes were parentally biased in the same manner among all strains. However, we identified several examples of allele-specific imprinting correlated with intraspecific epigenetic variation at a TE. We successfully predicted imprinting in additional strains based on methylation variability. We conclude that there is standing variation in imprinting even in recently diverged genotypes due to intraspecific epiallelic variation. These data demonstrate that epiallelic variation and genomic imprinting intersect to produce novel gene expression patterns in seeds. Sequencing of 12 small RNA samples from whole seeds 6 days after pollination.