The nuclear lamina (NL) is a thin meshwork of filaments that lines the inner nuclear membrane, thereby providing a platform for chromatin binding and supporting genome organization. Genomic regions contacting the NL are lamina associated domains (LADs), which contain thousands of genes that are lowly transcribed, and enriched for repressive histone modifications. LADs are dynamic structures that shift spatial positioning in accordance with cell-type specific gene expression changes during differentiation and development. Furthermore, recent studies have linked the disruption of LADs and alterations in the epigenome with the onset of diseases such as cancer. Here we focus on the role of LADs and the NL in gene regulation during development and cancer.
Prokaryotes encode various host defense systems that provide protection against mobile genetic elements. Restriction–modification (R–M) and CRISPR–Cas systems mediate host defense by sequence specific targeting of invasive DNA. T-even bacteriophages employ covalent modifications of nucleobases to avoid binding and therefore cleavage of their DNA by restriction endonucleases. Here, we describe that DNA glucosylation of bacteriophage genomes affects interference of some but not all CRISPR–Cas systems. We show that glucosyl modification of 5-hydroxymethylated cytosines in the DNA of bacteriophage T4 interferes with type I-E and type II-A CRISPR–Cas systems by lowering the affinity of the Cascade and Cas9–crRNA complexes for their target DNA. On the contrary, the type V-A nuclease Cas12a (also known as Cpf1) is not impaired in binding and cleavage of glucosylated target DNA, likely due to a more open structural architecture of the protein. Our results suggest that CRISPR–Cas systems have contributed to the selective pressure on phages to develop more generic solutions to escape sequence specific host defense systems.
Protein-DNA interactions are essential to establish cell type-specific chromatin architecture and gene expression. We recently developed scDam&T-seq, a multi-omics method that can simultaneously quantify protein-DNA interactions and the transcriptome in single cells. The method effectively combines two existing methods: DamID and CEL-Seq2. DamID works through the tethering of a protein of interest (POI) to the Escherichia coli DNA adenine methyltransferase (Dam). Upon expression of this fusion protein, DNA in proximity of the POI is methylated by Dam and can be selectively digested and amplified. CEL-Seq2, on the other hand, makes use of poly-dT primers to reverse transcribe mRNA, followed by linear amplification through in vitro transcription (IVT). scDam&T-seq is the first technique capable of providing a combined readout of protein-DNA contact and transcription from single-cell samples. Once suitable cell lines have been established, the protocol can be completed in 5 days, with a throughput of hundreds to thousands of cells. The processing of raw sequencing data takes an additional 1-2 days. Our method can be used to understand the transcriptional changes a cell undergoes upon the DNA binding of a protein of interest. It can be performed in any laboratory with access to FACS, robotic and high-throughput sequencing facilities.
Summary Small RNAs trigger the formation of epialleles that are silenced across generations. Consequently, RNA-directed epimutagenesis is associated with persistent gene repression. Here, we demonstrate that small interfering RNA-induced epimutations in fission yeast are still inherited even when the silenced gene is reactivated, and descendants can reinstate the silencing phenotype that only occurred in their ancestors. This process is mediated by the deposition of a phenotypically neutral molecular mark composed of tri-methylated histone H3 lysine 9 (H3K9me3). Its stable propagation is coupled to RNAi and requires maximal binding affinity of the Clr4/Suvar39 chromodomain to H3K9me3. In wild-type cells, this mark has no visible impact on transcription but causes gene silencing if RNA polymerase-associated factor 1 complex (Paf1C) activity is impaired. In sum, our results reveal a distinct form of epigenetic memory in which cells acquire heritable, transcriptionally active epialleles that confer gene silencing upon modulation of Paf1C.
Gene expression programs result from the collective activity of many regulatory factors. To obtain insight into the mechanisms that govern gene regulation, it is imperative to study their combined mode of action and interconnectivity. However, it has been challenging to simultaneously measure a combination of these factors within one sample. Here, we introduce MAbID, a method that combines genomic profiling of many histone modifications and chromatin-binding proteins in a single reaction. MAbID employs antibody-DNA conjugates to enable genomic barcoding of chromatin at sites of epitope occupancy. This barcoding strategy allows for the combined incubation of multiple antibodies in a single sample to reveal the genomic distributions of many epigenetic states simultaneously. We used MAbID to profile both active and inactive chromatin types in human cell lines and multiplexed measurements in the same sample without loss of data quality. Moreover, we obtained joint measurements of six epitopes covering all major chromatin types in single cells during mouse in vitro neural differentiation and captured associated changes in multifactorial chromatin states. Thus, MAbID holds the potential to gain unique insights into the interplay between gene regulatory mechanisms, especially in settings with limited sample material and in single cells.
The very first days of mammalian embryonic development are accompanied by epigenetic reprogramming and extensive changes in nuclear organization. In particular, genomic regions located at the periphery of the nucleus, termed lamina-associated domains (LADs), undergo major rearrangements after fertilization. However, the role of LADs in regulating gene expression as well as the interplay with various chromatin marks during preimplantation development remains elusive. In this study, we obtained single-cell LAD profiles coupled with the corresponding gene expression readout throughout the first days of mouse development. We detect extensive cell-cell LAD variability at the 2-cell stage, which surprisingly does not seem to functionally affect gene expression. This suggests an unusual uncoupling between 3D-nuclear genome organization and gene expression during totipotent developmental stages. By analyzing LAD dynamics and chromatin states across early developmental stages in an allelic-specific manner, we identify genomic regions that transiently detach from the nuclear lamina and are enriched by non-canonical H3K27me3. Upon maternal knock-out of a component of the Polycomb repressive complex 2 and concomitant loss of H3K27me3 during early embryogenesis, these regions relocate to the lamina at the 2-cell stage. Our results suggest that H3K27me3 is the prime determinant in establishing the atypical distribution of the genome at the nuclear periphery during the first days of embryonic development. This study provides insight into the molecular mechanisms regulating nuclear organization of parental genomes during very early mammalian development.
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