Project description:Transposable elements are entangled in a constant evolutionary arms race with their host genomes, constantly evolving ways to evade host silencing mechanisms. One silencing mechanism used by many distantly related eukaryotes is dependent on cytosine methylation, an epigenetic mark deposited by C5 cytosine methyltransferases (CMTs). Therefore, it is expected transposable elements would acquire mechanisms to escape from being targeted by cytosine methylation. Here we report how two distantly related eukaryotic lineages have incorporated CMTs into the coding regions of distinct retrotransposon classes. Three of these events have occurred in the dinoflagellates of the genus Symbiodinium, where these CMT-encoding retrotransposons show hundreds of insertions. In a case of convergent evolution, the charophyte Klebsormidium nitens shows an independent expansion of CMT encoding retrotransposons. Concomitantly, we find that Symbiodinium genomes show cytosine methylation patterns unlike any other eukaryote with most of the genome hypermethylated in CpGs, while targeted CH methylation accumulates on transposable elements. Similarly, K. nitens shows CHH and CHG targeted methylation on repressed transposable elements, while CpG methylation is concentrated in gene bodies and transposable elements. Furthermore, we demonstrate the ability of retrotransposon CMTs to de novo methylate CpGs, indicating a putative role in mimicking retrotranscribed DNA as host active genomic DNA. Our results show an unprecedented example of how retrotransposons incorporate host-derived genes involved in DNA methylation as a source of adaptation to their host epigenomic environments.

Project description:Cytosine methylation of DNA is a widespread modification of DNA that plays numerous critical roles, yet has been lost many times in diverse eukaryotic lineages. In the yeast Cryptococcus neoformans, CG methylation occurs in transposon-rich repeats and requires the DNA methyltransferase, Dnmt5. We show that Dnmt5 displays exquisite maintenance-type specificity in vitro and in vivo and utilizes similar in vivo cofactors as the metazoan maintenance methylase Dnmt1. Remarkably, phylogenetic and functional analysis revealed that the ancestral species lost the gene for a de novo methylase, DnmtX, between 50-150 MYA. We examined how methylation has persisted since the ancient loss of DnmtX. Experimental and comparative studies reveal efficient replication of methylation patterns in C. neoformans, rare stochastic methylation loss and gain events, and the action of natural selection. We propose that an epigenome has been propagated for >50 MY through a process analogous to Darwinian evolution of the genome.

Project description:The non-methylable cytosine analogs, 5-azacytidine and zebularine, are widely used to disrupt DNA methyltransferase activity and reduce genomic DNA methylation. In this study, whole-genome bisulfite sequencing is used to construct maps of DNA methylation with single base pair resolution in Arabidopsis thaliana seedlings treated with each demethylating agent. We find that 5-azacytidine and zebularine-treated seedlings have nearly indistinguishable patterns of DNA methylation genome-wide and that 5-azacytidine, despite being more unstable in aqueous solution, has a slightly greater demethylating effect at higher concentrations across the genome. Transcriptome analyses revealed a substantial number of up-regulated genes and transposable element genes, particularly CACTA-like elements, demonstrating that chemical demethylating agents have a disproportionately large effect on loci that are silenced by DNA methylation. Bisulfite-Seq and RNA-Seq

Project description:Sugarcane is an important crop worldwide for sugar production and increasingly, as a renewable energy source. Modern cultivars have polyploid, large complex genomes, with highly unequal contributions from ancestral genomes. Long Terminal Repeat retrotransposons (LTR-RTs) are the single largest components of most plant genomes and can substantially impact the genome in many ways. It is therefore crucial to understand their contribution to the genome and transcriptome, however a detailed study of LTR-RTs in sugarcane has not been previously carried out. Sixty complete LTR-RT elements were classified into 35 families within four Copia and three Gypsy lineages. Structurally, within lineages elements were similar, between lineages there were large size differences. Four distinct patterns were observed in sRNA mapping, the most unusual of which was that of Ale1, with very large numbers of 24nt sRNAs in the coding region. The results presented support the conclusion that distinct small RNA-regulated pathways in sugarcane target the lineages of LTR-RT elements. Individual LTR-RT sugarcane families have distinct structures, and transcriptional and regulatory signatures. Our results indicate that in sugarcane individual LTR-RT families have distinct behaviors and can potentially impact the genome in diverse ways. For instance, these transposable elements may affect nearby genes by generating a diverse set of small RNA's that trigger gene silencing mechanisms. There is also some evidence that ancestral genomes contribute significantly different element numbers from particular LTR-RT lineages to the modern sugarcane cultivar genome. Examination of small RNA populations in the sugarcane leaves that show matches against sugarcane LTR-RTs.

Project description:Eukaryotic cytosine methylation represses transposable elements, but also occurs in bodies of active genes. The extent to which these processes are conserved is unclear, and little is known about methylation outside of mammals, Arabidopsis thaliana, and Neurospora crassa. Utilizing deep bisulfite sequencing, we have quantified DNA methylation in five plant, seven animal, and five fungal genomes. We find that gene body methylation is conserved between plants and animals, whereas selective methylation of transposons has evolved independently in the vertebrate lineage. We show that methylation of plant transposons in the CHG context extends to green algae, and present evidence for RNA-directed DNA methylation of fungal genes. We also show that antagonism between DNA methylation and histone H2A.Z is conserved between plants and animals. Our data demonstrate that extant DNA methylation systems are mosaics of conserved and derived features, and indicate that gene body methylation is an ancient property of eukaryotic genomes. Keywords: Epigenetics Examination of DNA methylation and transcription in plant, animal, and fungal genomes, and examination of how H2A.Z deposition relates to both methylation and transcription in puffer fish. Descriptions of the Samples' raw and processed data (provided as supplementary files) can be found in GSE19824_README.txt at the foot of this record.

Project description:Eukaryotic cytosine methylation represses transposable elements, but also occurs in bodies of active genes. The extent to which these processes are conserved is unclear, and little is known about methylation outside of mammals, Arabidopsis thaliana, and Neurospora crassa. Utilizing deep bisulfite sequencing, we have quantified DNA methylation in five plant, seven animal, and five fungal genomes. We find that gene body methylation is conserved between plants and animals, whereas selective methylation of transposons has evolved independently in the vertebrate lineage. We show that methylation of plant transposons in the CHG context extends to green algae, and present evidence for RNA-directed DNA methylation of fungal genes. We also show that antagonism between DNA methylation and histone H2A.Z is conserved between plants and animals. Our data demonstrate that extant DNA methylation systems are mosaics of conserved and derived features, and indicate that gene body methylation is an ancient property of eukaryotic genomes. Keywords: Epigenetics

Project description:Cytosine DNA methylation regulates the expression of eukaryotic genes and transposable elements. Methylation is copied by DNA methyltransferases after DNA replication, which results in faithful transmission of methylation patterns during cell division and, at least in flowering plants, across generations. Trans-generational inheritance is mediated by a small group of cells that includes gametes and their progenitors. However, methylation is usually analyzed in somatic tissues that do not contribute to the next generation, and the mechanisms of trans-generational inheritance are inferred from such studies. To gain a better understanding of how DNA methylation is inherited, we analyzed purified Arabidopsis thaliana sperm and vegetative cells – the cell types that comprise pollen – with mutations in the DRM, CMT2 and CMT3 methyltransferases.

Project description:In flowering plants, silencing of transposable elements (TEs) is achieved by the installation of DNA methylation and histone modifications. 24-nt long small-interfering RNAs (siRNAs) guide the deposition of DNA methylation through RNA-directed DNA methylation (RdDM), which can be maintained independently of siRNAs in coordination with H3K9me2. In most angiosperms, RdDM is ubiquitously expressed in vegetative and sexual reproductive tissues. Spirodela polyrhiza (Lemnaceae), represents an exception with low levels of DNA methylation, very low expression of RdDM and near absence of 24-nt siRNAs during its clonal vegetative propagation. Moreover, some components of RdDM, DNA methylation maintenance and RNA silencing are absent from the genome. By investigating the distribution of epigenetic marks on TEs, we show that Spirodela epigenome is shaped by the loss of DNA methylation and H3K9me2 as TEs decay. Nonetheless, such abundant TE remnants remain silenced and marked by H3K9me1. In contrast, scarce, relatively intact TEs display high levels of DNA methylation, H3K9me2 and siRNAs whose patterns resemble those of TEs subjected to RdDM in other angiosperms. Furthermore, despite the absence of DCL2 in duckweeds, Spirodela can produce 22-nt siRNAs, not only from TEs, but from diverse sources of double-stranded (ds)RNA. Our data suggests that RdDM might still be functional during vegetative clonal growth, albeit tissue or developmentally regulated, and highlights the use of alternative models to further understand and explore the diversity of silencing pathways in plants.

Project description:Background: The small RNAs that Transposable Elements generate are vastly different when they are transcriptionally silenced compared to when they are transcriptionally activated. We performed the deep sequencing of small RNAs in a number of small RNA biogenesis mutants in both Transposable Element-silenced and Transposable Element-active epigenome backgrounds. Results: We found that Transposable Elements generate large amounts of 21-22nt siRNAs only when they are transcriptionally active. These 21-22nt siRNAs are incorporated into the AGO6 protein. Conclusion: Ago6 is the key protein that bridges the post-transcriptional degradation of Transposable Element mRNAs and the establishment of DNA methylation.

Project description:The non-methylable cytosine analogs, 5-azacytidine and zebularine, are widely used to disrupt DNA methyltransferase activity and reduce genomic DNA methylation. In this study, whole-genome bisulfite sequencing is used to construct maps of DNA methylation with single base pair resolution in Arabidopsis thaliana seedlings treated with each demethylating agent. We find that 5-azacytidine and zebularine-treated seedlings have nearly indistinguishable patterns of DNA methylation genome-wide and that 5-azacytidine, despite being more unstable in aqueous solution, has a slightly greater demethylating effect at higher concentrations across the genome. Transcriptome analyses revealed a substantial number of up-regulated genes and transposable element genes, particularly CACTA-like elements, demonstrating that chemical demethylating agents have a disproportionately large effect on loci that are silenced by DNA methylation.