Project description:In mammalian cells, DNA methylation on the 5th position of cytosine (5mC) plays an important role as an epigenetic mark. However, DNA methylation was considered to be absent in C. elegans because of the lack of detectable 5mC as well as homologs of the cytosine DNA methyltransferases. Here, using multiple approaches, we demonstrate the presence of adenine N6-methylation (6mA) in C. elegans DNA. We further demonstrate that this modification increases trans-generationally in a paradigm of epigenetic inheritance. Importantly, we identify a DNA demethylase, NMAD-1, and a potential DNA methyltransferase, DAMT-1, which regulate 6mA levels and crosstalk between methylation of histone H3K4me2 and 6mA, and control the epigenetic inheritance of phenotypes associated with the loss of the H3K4me2 demethylase spr-5. Together, these data identify a novel DNA modification in C. elegans and raise the exciting possibility that 6mA may be a carrier of heritable epigenetic information in eukaryotes. SMRT-sequencing for a mixed cell population of wildtype worms 6mA ChIP-Seq for a mixed cell population of wildtype worms

Project description:In mammalian cells, DNA methylation on the 5th position of cytosine (5mC) plays an important role as an epigenetic mark. However, DNA methylation was considered to be absent in C. elegans because of the lack of detectable 5mC as well as homologs of the cytosine DNA methyltransferases. Here, using multiple approaches, we demonstrate the presence of adenine N6-methylation (6mA) in C. elegans DNA. We further demonstrate that this modification increases trans-generationally in a paradigm of epigenetic inheritance. Importantly, we identify a DNA demethylase, NMAD-1, and a potential DNA methyltransferase, DAMT-1, which regulate 6mA levels and crosstalk between methylation of histone H3K4me2 and 6mA, and control the epigenetic inheritance of phenotypes associated with the loss of the H3K4me2 demethylase spr-5. Together, these data identify a novel DNA modification in C. elegans and raise the exciting possibility that 6mA may be a carrier of heritable epigenetic information in eukaryotes.

Project description:Methylation of cytosines at the 5th carbon position of the aromatic ring has long been regarded as the predominant type of DNA base modification in eukaryotes. Often called “the fifth base”, C5-methylcytosine (5mC) plays an important role in genome defense against mobile genetic elements, and is mostly associated with transcriptional silencing, establishment of the closed chromatin configuration, and repressive histone modifications. Recently, another type of DNA modification, N6-methyladenine (6mA), has been added to the repertoire of modified bases in eukaryotic DNA, and was mostly linked to elevated transcription levels. In prokaryotes, 5mC and 6mA typically constitute components of restriction-modification (R-M) systems, along with N4-methylcytosine (4mC), which so far has been confined to bacteria. Here we report the first case of 4mC occurrence in eukaryotic DNA. We find that bdelloid rotifers, small freshwater invertebrates known for their ability to reproduce clonally and to acquire genes from non-metazoan sources, lack the canonical eukaryotic C5-methyltransferases but instead encode an amino-methyltransferase of bacterial origin, N4CMT, which is present in all bdelloid families separated by tens of millions of years of evolution. The recombinant N4CMT introduces 4mC into genomic DNA in vivo and in vitro. Using SMRT-seq (PRJNA558051), MeDIP-seq, ChIP-seq, and RNA-seq, we examined genome-wide distribution of non-canonical base modifications over annotated genomic features and observed an excess of 4mC in silenced transposable elements and certain tandem repeats, while 6mA tends to associate with transcribed genes and active chromatin. The presence of the chromodomain in N4CMT explains its affinity for repressive histone marks, H3K9me3 and especially H3K27me3. Our results expand the known repertoire of eukaryotic base modifications, shed light on the process of recruitment of methyl groups as epigenetic marks in DNA, and highlight the role of horizontal gene transfer as an important driver of evolutionary innovation in eukaryotes.

Project description:Methylation of cytosines at the 5th carbon position of the aromatic ring has long been regarded as the predominant type of DNA base modification in eukaryotes. Often called “the fifth base”, C5-methylcytosine (5mC) plays an important role in genome defense against mobile genetic elements, and is mostly associated with transcriptional silencing, establishment of the closed chromatin configuration, and repressive histone modifications. Recently, another type of DNA modification, N6-methyladenine (6mA), has been added to the repertoire of modified bases in eukaryotic DNA, and was mostly linked to elevated transcription levels. In prokaryotes, 5mC and 6mA typically constitute components of restriction-modification (R-M) systems, along with N4-methylcytosine (4mC), which so far has been confined to bacteria. Here we report the first case of 4mC occurrence in eukaryotic DNA. We find that bdelloid rotifers, small freshwater invertebrates known for their ability to reproduce clonally and to acquire genes from non-metazoan sources, lack the canonical eukaryotic C5-methyltransferases but instead encode an amino-methyltransferase of bacterial origin, N4CMT, which is present in all bdelloid families separated by tens of millions of years of evolution. The recombinant N4CMT introduces 4mC into genomic DNA in vivo and in vitro. Using SMRT-seq (PRJNA558051), MeDIP-seq, ChIP-seq, and RNA-seq, we examined genome-wide distribution of non-canonical base modifications over annotated genomic features and observed an excess of 4mC in silenced transposable elements and certain tandem repeats, while 6mA tends to associate with transcribed genes and active chromatin. The presence of the chromodomain in N4CMT explains its affinity for repressive histone marks, H3K9me3 and especially H3K27me3. Our results expand the known repertoire of eukaryotic base modifications, shed light on the process of recruitment of methyl groups as epigenetic marks in DNA, and highlight the role of horizontal gene transfer as an important driver of evolutionary innovation in eukaryotes.

Project description:Methylation of cytosines at the 5th carbon position of the aromatic ring has long been regarded as the predominant type of DNA base modification in eukaryotes. Often called “the fifth base”, C5-methylcytosine (5mC) plays an important role in genome defense against mobile genetic elements, and is mostly associated with transcriptional silencing, establishment of the closed chromatin configuration, and repressive histone modifications. Recently, another type of DNA modification, N6-methyladenine (6mA), has been added to the repertoire of modified bases in eukaryotic DNA, and was mostly linked to elevated transcription levels. In prokaryotes, 5mC and 6mA typically constitute components of restriction-modification (R-M) systems, along with N4-methylcytosine (4mC), which so far has been confined to bacteria. Here we report the first case of 4mC occurrence in eukaryotic DNA. We find that bdelloid rotifers, small freshwater invertebrates known for their ability to reproduce clonally and to acquire genes from non-metazoan sources, lack the canonical eukaryotic C5-methyltransferases but instead encode an amino-methyltransferase of bacterial origin, N4CMT, which is present in all bdelloid families separated by tens of millions of years of evolution. The recombinant N4CMT introduces 4mC into genomic DNA in vivo and in vitro. Using SMRT-seq (PRJNA558051), MeDIP-seq, ChIP-seq, and RNA-seq, we examined genome-wide distribution of non-canonical base modifications over annotated genomic features and observed an excess of 4mC in silenced transposable elements and certain tandem repeats, while 6mA tends to associate with transcribed genes and active chromatin. The presence of the chromodomain in N4CMT explains its affinity for repressive histone marks, H3K9me3 and especially H3K27me3. Our results expand the known repertoire of eukaryotic base modifications, shed light on the process of recruitment of methyl groups as epigenetic marks in DNA, and highlight the role of horizontal gene transfer as an important driver of evolutionary innovation in eukaryotes.

Project description:To interrogate single-base resolution 6mA sites in the genome-wide, we develop DA-6mA-seq (DpnI-Assisted N6-methylAdenine sequencing), an optimized sequencing method taking advantage of restriction enzyme DpnI, which exclusively cleaves methylated adenine sites. We find DpnI also recognizes other sequence motifs besides the canonical GATC restriction sites, largely expanding the application range of this method. DA-6mA-seq requires less starting material and lower sequencing depth than previous methods, but achieves higher sensitivity, providing a good strategy to identify 6mA in large genome with a low abundance of 6mA. We rebuild the 6mA maps of Chlamydomonas by DA-6mA-seq and then apply this method to another two eukaryotic organisms, Plasmodium and Penicillium. Further analysis reveals most 6mA sites are symmetric at various sequence contexts, suggesting 6mA may function as a new heritable epigenetic mark in eukaryotes. A new sequencing method is developed to detect 6mA in eukaryotes

Project description:N6-methyldeoxyadenosine (6mA or m6A) is a DNA modification preserved in prokaryotes to eukaryotes. It is widespread in bacteria, and functions in DNA mismatch repair, chromosome segregation, and virulence regulation. In contrast, the distribution and function of 6mA in eukaryotes have been unclear. Here we present a comprehensive analysis of the 6mA landscape in the genome of Chlamydomonas using new sequencing approaches. We identified the 6mA modification in 84% of genes in Chlamydomonas. We found that 6mA mainly locates at ApT dinucleotides around transcription start sites (TSS) with a bimodal distribution, and appears to mark active genes. A periodic pattern of 6mA deposition was also observed at base resolution, which is associated with nucleosome distribution near the TSS, suggesting a possible role in nucleosome positioning. The new genome-wide mapping of 6mA and its unique distribution in the Chlamydomonas genome suggest potential regulatory roles of 6mA in gene expression in eukaryotic organisms. Multiple sequencing methods are developed to profile the distribution of 6mA in Chlamydomonas including MeDIP-Seq, enzyme-treated DNA-Seq, MNase-Seq and RNA-Seq.

Project description:We report the application of 6mA IP-sequencing technology for high-throughput profiling in rice tissues of 12 days' leaf. By obtaining over 20 million high quality clean mapping sequenced reads from immunoprecipitated DNA, we generate genome-wide 6mA maps of rice 12 days' leaf. Using mass spectrometry and immunoprecipitation and validation with analysis of single-molecule real-time sequencing, we observed that about 0.2% of all adenines are 6mA-methylated in the rice genome. 6mA occurs most frequently at GAGG motifs and is mapped to about 20% of genes and 14% of transposable elements (TEs). In promoters, 6mA marks silent genes, but in bodies correlates with gene activity. 6mA overlaps with 5-methylated cytosine (5mC) at CG sites in gene bodies and is complementary to 5mC at CHH sites in TEs. We show that OsALKBH1 may be potentially involved in 6mA demethylation in rice. The results suggest that 6mA is complementary to 5mC as an epigenomic mark in rice and reinforces a distinct role for 6mA as a gene-expression associated epigenomic mark in eukaryotes.

Project description:N 4-methylcytosine (4mC) is a natural DNA modification occurring in thermophiles and plays important roles in restriction-modification (R-M) systems in bacterial genomes. However, the precise location and sequence context of 4mC in the whole genome are limited. In this study, we developed an APOBEC3A-mediated deamination sequencing (4mC-AMD-seq) method for genome-wide mapping of 4mC at single-base resolution. In the 4mC-AMD-seq method, cytosine and 5-methylcytosine (5mC) are deaminated by APOBEC3A (A3A) protein to generate uracil and thymine, both of which are read as thymine in sequencing, while 4mC is resistant to deamination and therefore read as cytosine. Thus, the readouts of cytosines from sequencing could manifest the original 4mC sites in genomes. With the 4mC-AMD-seq method, we achieved the genome-wide mapping of 4mC in Deinococcus radiodurans (D. radiodurans). In addition, we confirmed that 4mC, but not 5mC, was the major modification in the D. radiodurans genome. We identified 1586 4mC sites in the genome of D. radiodurans, among which 564 sites were located in the CCGCGG motif. The average methylation levels in the CCGCGG motif and non-CCGCGG sequence were 70.0% and 22.8%, respectively. We envision that the 4mC-AMD-seq method will facilitate the investigation of 4mC functions, including the 4mC-involved R-M systems, in uncharacterized but potentially useful strains.

Project description:DNA methylation on N6-adenine (6mA) has recently been found as a potentially new epigenetic mark in several unicellular and multicellular eukaryotes. However, its distribution patterns and potential functions in land plants, which are primary producers for most ecosystems, remain completely unknown. Here we report global profiling of 6mA sites at single-nucleotide resolution in the genome of Arabidopsis thaliana using single-molecule real-time sequencing. 6mA sites are widely distributed across the Arabidopsis genome and enriched over the pericentromeric heterochromatin regions. Nearly 30% of 6mA sites are present in gene bodies. Further analysis of 6mA methylome and RNA-sequencing data demonstrates that 6mA frequency positively correlates with the gene expression level in Arabidopsis. Consistently, histone variants associated with actively expressed genes interact with 6mA DNA. Our results uncover 6mA as a DNA mark associated with actively expressed genes in Arabidopsis, suggesting that 6mA serves as a novel epigenetic mark in land plants.