Project description:Chromosomes must correctly fold in eukaryotic nuclei for proper genome function. Eukaryotic organisms hierarchically organize their genomes: in the fungus Neurospora crassa, chromatin fiber loops compact into Topologically Associated Domain (TAD)-like structures that are anchored by heterochromatic region aggregates. However, insufficient information exists on how histone post-translational modifications, including acetylation, impact genome organization. In Neurospora, the HCHC (HDA-1, CDP-2, HP1, CHAP) complex deacetylates heterochromatic regions including centromeres: loss of individual HCHC members increases centromeric acetylation and cytosine methylation. Here, we evaluate the role of the HCHC complex on genome organization using chromosome conformation capture with high-throughput sequencing (Hi-C) in Δcdp-2 or Δchap deletion strains. CDP-2 loss increases interactions between intra- and inter-chromosomal heterochromatic regions, while removal of CHAP decreases heterochromatic region compaction. Individual HCHC mutants exhibit different histone PTM patterns genome-wide: in Dcdp-2, heterochromatic H4K16 acetylation is increased, yet some heterochromatic regions lose H3K9 trimethylation, which locally increases inter-heterochromatin contacts; CHAP loss produces minimal acetylation changes but increases H3K9me3 enrichment in heterochromatin. Furthermore, deletion of the DIM-2 DNA methyltransferase in a Δcdp-2 background causes extensive genome disorder, as heterochromatic-euchromatic contacts increase despite additional H3K9me3 enrichment. Our results highlight how enhanced cytosine methylation ensures heterochromatic compartmentalization when silenced regions are acetylated.

Project description:Whole-Genome Bisulfite Sequencing of HCHC mutants To extend our understanding of the role of the HCHC complex in Neurospora, we carried out whole-genome bisulfite sequencing (WGBS) of cdp-2, chap, and hda-1 mutants.  Consistent with prior analyses, the WGBS revealed both hypomethylated and hypermethylated regions in the three HCHC mutants while the ; sequences with a lower Combined RIP Index (CRI) tend to show reduced methylation in the mutants, while sequences with higher CRI scores show increased methylation. Analysis of the WGBS data also demonstrated that shorter methylated regions, regardless of their degree of methylation in wild type, commonly have reduced methylation in the HCHC mutants, while longer methylated sequences tend to have elevated methylation.  In addition, the borders of normally methylated regions typically lose methylation and show a contraction of boundary methylation in the HCHC mutants.  Sequences near telomeres that are normally methylated were found to lose methylation in the mutants, while most of the increased DNA methylation of the three HCHC mutants is found at centromeres. CHAP in vitro DNA-affinity purification HT-seq and CHAP DamID-Seq To test whether the CHAP AT-hook motifs bind AT-rich RIP’d DNA, we performed in vitro DNA-affinity purification with the recombinant CHAP-N-terminus (1-274 residues) containing the two AT-hook motifs and analyzed the purified DNA with high throughput sequencing (HT-Seq). To complement this approach, we also assessed binding of CHAP in vivo with DamID-seq using the CHAP-Dam strain. Together, these techniques gave us a detailed genomic view of the specific localization and binding of CHAP to AT-rich RIP’d DNA, which is nearly coincident with methylated DNA regions.

Project description:Cytosine methylation, a fundamental form of epigenetic regulation, is found in many eukaryotes and plays a significant role in cancer and other diseases. Using the genetically tractable model organism Neurospora crassa, we have identified genes that when mutated, cause the strains to be defective in methylation (dim). The process of DNA methylation in Neurospora has been shown to be dependent on DCDC, a five-member complex that directs the histone methyltransferase DIM-5 to tri-methylate Lysine 9 on histone H3 (H3K9me3). This mark is recognized by HP1, which directs DIM-2 to methylate DNA. In contrast, the HCHC complex employs HDA-1, CDP-2, HP1, and CHAP to deacetylate that same residue on H3. While we know a good deal about DNA methylation, it is still unclear whether we have identified all the genes involved in the process. Thus, we continued our search for dim mutants, using a selection for reactivation of silenced drug resistance genes. Interestingly, we predominantly identified known dim genes, including dim-5, dim-7, dim-8, dim-9, hpo, chap, cdp-2, and hda-1. Using a Sanger sequencing-based approach, we identified mutations in these known dim genes, presumably responsible for the Dim- phenotype; many mutations were unique point mutants that could compromise protein activity or structure, or impact protein-protein interactions. For mutants in which the gene was not placed into a complementation group, we employed a bulk segregant analysis and whole genome sequencing approach to identify additional mutations in known DNA methylation genes, including hH3 and dim-1, as well as a novel dim mutant: dim-10, a fungal-specific protein that may work with DCDC for H3K9me3 catalysis. Not only will this dim mutant collection be a useful resource to investigate the roles of these dim genes and their protein products in DNA methylation, but the isolation of a novel dim gene by a forward genetics approach provides an exciting avenue of research into how incipient heterochromatin formation is achieved.

Project description:Genome organization is essential for proper function, including gene expression. In metazoan genome organization, chromatin loops and Topologically Associated Domains (TADs) facilitate local gene clustering, while chromosomes form distinct nuclear territories characterized by compartmentalization of silent heterochromatin at the nuclear periphery and active euchromatin in the nucleus center. A similar hierarchical organization occurs in the fungus Neurospora crassa where its seven chromosomes form a Rabl conformation, where heterochromatic centromeres and telomeres independently cluster at the nuclear membrane, while interspersed heterochromatic loci in Neurospora aggregate across megabases of linear genomic distance for forming TAD-like structures. However, the role of individual heterochromatic loci in normal genome organization and function is unknown. Here, we examined the genome organization of a Neurospora strain harboring a ~41 kilobase facultative (temporarily silent) heterochromatic region deletion, as well as the genome organization of a strain deleted of a ~110 kilobase permanently silent constitutive heterochromatic region. While the facultative heterochromatin deletion had little effect on local chromatin structure, the constitutive heterochromatin deletion altered local TAD-like structures, gene expression, and the predicted 3D genome structure by qualitatively repositioning genes into the nucleus center. Our work elucidates the role of individual heterochromatic regions for genome organization and function.

Project description:Genome organization is essential for proper function, including gene expression. In metazoan genome organization, chromatin loops and Topologically Associated Domains (TADs) facilitate local gene clustering, while chromosomes form distinct nuclear territories characterized by compartmentalization of silent heterochromatin at the nuclear periphery and active euchromatin in the nucleus center. A similar hierarchical organization occurs in the fungus Neurospora crassa where its seven chromosomes form a Rabl conformation, where heterochromatic centromeres and telomeres independently cluster at the nuclear membrane, while interspersed heterochromatic loci in Neurospora aggregate across megabases of linear genomic distance for forming TAD-like structures. However, the role of individual heterochromatic loci in normal genome organization and function is unknown. Here, we examined the genome organization of a Neurospora strain harboring a ~41 kilobase facultative (temporarily silent) heterochromatic region deletion, as well as the genome organization of a strain deleted of a ~110 kilobase permanently silent constitutive heterochromatic region. While the facultative heterochromatin deletion had little effect on local chromatin structure, the constitutive heterochromatin deletion altered local TAD-like structures, gene expression, and the predicted 3D genome structure by qualitatively repositioning genes into the nucleus center. Our work elucidates the role of individual heterochromatic regions for genome organization and function.

Project description:Genome organization is essential for proper function, including gene expression. In metazoan genome organization, chromatin loops and Topologically Associated Domains (TADs) facilitate local gene clustering, while chromosomes form distinct nuclear territories characterized by compartmentalization of silent heterochromatin at the nuclear periphery and active euchromatin in the nucleus center. A similar hierarchical organization occurs in the fungus Neurospora crassa where its seven chromosomes form a Rabl conformation, where heterochromatic centromeres and telomeres independently cluster at the nuclear membrane, while interspersed heterochromatic loci in Neurospora aggregate across megabases of linear genomic distance for forming TAD-like structures. However, the role of individual heterochromatic loci in normal genome organization and function is unknown. Here, we examined the genome organization of a Neurospora strain harboring a ~41 kilobase facultative (temporarily silent) heterochromatic region deletion, as well as the genome organization of a strain deleted of a ~110 kilobase permanently silent constitutive heterochromatic region. While the facultative heterochromatin deletion had little effect on local chromatin structure, the constitutive heterochromatin deletion altered local TAD-like structures, gene expression, and the predicted 3D genome structure by qualitatively repositioning genes into the nucleus center. Our work elucidates the role of individual heterochromatic regions for genome organization and function.

Project description:Heterochromatin is believed to be associated with increased levels of cytosine methylation. With the recent availability of genome-wide, high-resolution molecular data reflecting cytosine methylation or heterochromatic organization, such relationships can be explored systematically. As a well-defined surrogate for heterochromatin, we tested the relationship between DNA replication timing and cytosine methylation in two human cell types, unexpectedly finding that the later-replicating, more heterochromatic regions to be less methylated than early-replicating regions. When we integrated gene expression data into the study, we found that regions of increased gene expression were earlier replicating, as previously identified, and that transcription-targeted cytosine methylation (TTCM) in gene bodies accounts for the positive correlation with early replication. A Self-Organising Map (SOM) approach was able to identify genomic regions with early replication and increased methylation but lacking annotated transcripts, which would have been missed in simple two variable analyses and may encode unrecognized intergenic transcripts. We conclude that the relationship of cytosine methylation with heterochromatin is not simple, and depends on whether the genomic context is tandemly-repetitive sequences often found near centromeres, which are known to be heterochromatic and methylated, or the remaining majority of the genome, where cytosine methylation is targeted preferentially to the transcriptionally-active, euchromatic compartment of the genome. comparison of human fibroblast and GM06690

Project description:Heterochromatin is believed to be associated with increased levels of cytosine methylation. With the recent availability of genome-wide, high-resolution molecular data reflecting cytosine methylation or heterochromatic organization, such relationships can be explored systematically. As a well-defined surrogate for heterochromatin, we tested the relationship between DNA replication timing and cytosine methylation in two human cell types, unexpectedly finding that the later-replicating, more heterochromatic regions to be less methylated than early-replicating regions. When we integrated gene expression data into the study, we found that regions of increased gene expression were earlier replicating, as previously identified, and that transcription-targeted cytosine methylation (TTCM) in gene bodies accounts for the positive correlation with early replication. A Self-Organising Map (SOM) approach was able to identify genomic regions with early replication and increased methylation but lacking annotated transcripts, which would have been missed in simple two variable analyses and may encode unrecognized intergenic transcripts. We conclude that the relationship of cytosine methylation with heterochromatin is not simple, and depends on whether the genomic context is tandemly-repetitive sequences often found near centromeres, which are known to be heterochromatic and methylated, or the remaining majority of the genome, where cytosine methylation is targeted preferentially to the transcriptionally-active, euchromatic compartment of the genome.

Project description:Heterochromatin is believed to be associated with increased levels of cytosine methylation. With the recent availability of genome-wide, high-resolution molecular data reflecting cytosine methylation or heterochromatic organization, such relationships can be explored systematically. As a well-defined surrogate for heterochromatin, we tested the relationship between DNA replication timing and cytosine methylation in two human cell types, unexpectedly finding that the later-replicating, more heterochromatic regions to be less methylated than early-replicating regions. When we integrated gene expression data into the study, we found that regions of increased gene expression were earlier replicating, as previously identified, and that transcription-targeted cytosine methylation (TTCM) in gene bodies accounts for the positive correlation with early replication. A Self-Organising Map (SOM) approach was able to identify genomic regions with early replication and increased methylation but lacking annotated transcripts, which would have been missed in simple two variable analyses and may encode unrecognized intergenic transcripts. We conclude that the relationship of cytosine methylation with heterochromatin is not simple, and depends on whether the genomic context is tandemly-repetitive sequences often found near centromeres, which are known to be heterochromatic and methylated, or the remaining majority of the genome, where cytosine methylation is targeted preferentially to the transcriptionally-active, euchromatic compartment of the genome.

Project description:We report the placement of cytosine methylation from the filamentous fungus Neurospora crassa in wild type and dim-3 strains by bisulfite-sequencing. Compared to a wild type strain, the dim-3 strain has a global reduction in cytosine methylation, and this reduction in cytosine methylation is exacerbated by the supplementation of histidine to the growth medium. This global reduction in cytosine methylation results from a causative mutation in importin alpha (NUP-6), a component of the nuclear transport machinery, which severely reduces the level of the heterochromatic mark H3K9me3. NUP-6(dim-3) compromises the heterochromatic localization of several components of the DCDC, a histone H3K9 methyltransferase complex, which in turn reduces the level of Heterochromatin Protein-1 (HP1) found at heterochromatin and compromises the direct interaction between HP1 and the DNA methyltransferase dim-2. To determine whether the reduced level of cytosine methylation, as assayed by Southern blotting heterochromatic regions following digestion of genomic DNA with methylation-sensitive restriction endonucleases, is globally reduced at the A:T rich, repetitive DNA comprising heterochromatin, we performed Bisulfite-seq on a dim-3 strain (grown either in minimal medium or medium supplemented with histidine) and compared that to a wild type strain (grown in minimum medium; histidine does not reduce the levels of cytosine methylation in a wild type strain, as assayed by Southern blotting).