Project description:Single-cell combinatorial indexing (sci-) methods have addressed major limitations of throughput and cost for many single cell modalities. With the incorporation of linear amplification and 3-level barcoding in our suite of methods called sci-L3, we further addressed the limitations of uniformity in single cell genome amplification. Here, we build on the generalizability of sci-L3 by extending it to template strand sequencing (sci-L3-Strand-seq), genome conformation capture (sci-L3-Hi-C), and the joint profiling of RNA and chromatin accessibility (sci-L3-RNA/ATAC). We demonstrate the ease of adapting sci-L3 to these new modalities by only requiring a single-step modification of the original protocol. As a proof-of-principle, we show our ability to detect sister chromatid exchanges, genome compartmentalization, and cell state specific features in thousands of single cells. We anticipate sci-L3 to be compatible with additional modalities, including DNA methylation (sci-MET) and chromatin associated factors (CUT&Tag), and ultimately enable a multi-omics readout of them.

Project description:High-throughput linear amplification for single-cell template strand sequencing with sci-L3-Strand-seq

Project description:We report the development of a novel strand-specific ChIP-seq strategy and application of this strategy in studying genome instability events We examined vulnerable genomic sites by applying strand-specific ChIP-seq of Rad52 to S. pombe haploid mutants showing elevated level of genome instability.

Project description:Piwi-interacting RNAs (piRNAs) guide Piwi Argonautes to suppress transposon activity in animal gonads. Known piRNA populations are extremely complex, with millions of individual sequences present in a single organism. Despite this complexity, specific Piwi proteins incorporate piRNAs with distinct nucleotide- and transposon strand-biases (antisense or sense) of unknown origin. Here we examined the contribution of structural domains in Piwi proteins towards defining these biases. We report the first crystal structure of the MID domain from a Piwi Argonaute and use docking experiments to show its ability to specify recognition of 5M-bM-^@M-2 uridine (1U-bias) of piRNAs. Mutational analyses reveal the importance of 5M-bM-^@M-^Y end-recognition within the MID domain for piRNA biogenesis in vivo. Finally, domain-swapping experiments uncover an unexpected role for the MID-PIWI module of a Piwi protein in dictating the strand-orientation of its bound piRNAs. Our work identifies structural features that allow distinguishing individual Piwi members during piRNA biogenesis Immunoprecipitated small RNA were purified from Bmn4 cells for preparation of high-throughput sequencing libraries.

Project description:Piwi-interacting RNAs (piRNAs) guide Piwi Argonautes to suppress transposon activity in animal gonads. Known piRNA populations are extremely complex, with millions of individual sequences present in a single organism. Despite this complexity, specific Piwi proteins incorporate piRNAs with distinct nucleotide- and transposon strand-biases (antisense or sense) of unknown origin. Here we examined the contribution of structural domains in Piwi proteins towards defining these biases. We report the first crystal structure of the MID domain from a Piwi Argonaute and use docking experiments to show its ability to specify recognition of 5′ uridine (1U-bias) of piRNAs. Mutational analyses reveal the importance of 5’ end-recognition within the MID domain for piRNA biogenesis in vivo. Finally, domain-swapping experiments uncover an unexpected role for the MID-PIWI module of a Piwi protein in dictating the strand-orientation of its bound piRNAs. Our work identifies structural features that allow distinguishing individual Piwi members during piRNA biogenesis

Project description:We report the development of a novel strand-specific ChIP-seq strategy and application of this strategy in studying genome instability events

Project description:Insertions and deletions (indels) are common sources of structural variation, and insertions originating from spontaneous DNA lesions are frequent in cancer. We developed a highly sensitive assay (Indel-Seq) to monitor rearrangements in human cells at the TRIM37 acceptor locus that reports indels stemming from experimentallyinduced and spontaneous genome instability. Templated insertions, which derive from sequences genome-wide, require contact between donor and acceptor loci, homologous recombination, and are stimulated by DNA end-processing. Insertions are facilitated by transcription and involve a DNA/RNA hybrid intermediate. Indel-Seq reveals that insertions are generated via multiple pathways. The broken acceptor site anneals with a resected DNA break or invades the displaced strand of a transcription bubble or R-loop followed by DNA synthesis, displacement and then ligation by nonhomologous end-joining. Our studies identify transcription-coupled insertions as a critical source of spontaneous genome instability that are distinct from cut-and-paste events

Project description:BACKGROUND: Deletion of the chromatin remodeler CHD1 is a common genomic alteration found in human prostate cancers (PCas). CHD1 loss represents a distinct PCa subtype characterized by SPOP mutation and higher genomic instability [1-3]. However, the role of CHD1 in PCa development in vivo and its clinical utility remain unclear. DESIGN: To study the role of CHD1 in PCa development and its loss in clinical management, we generated a genetically engineered mouse model with prostate-specific deletion of murine Chd1 as well as isogenic CHD1 WT and homozygous deleted human benign and PCa lines. We also developed patient-derived organoid cultures and screened patients with metastatic PCa for CHD1 loss. RESULTS: We demonstrate that CHD1 loss sensitizes cells to DNA damage and causes a synthetic lethal response to DNA damaging therapy in vivo, ex vivo and in a patient with metastatic PCa. Mechanistically, CHD1 loss leads to decreased error-free homologous recombination (HR) repair, which is compensated by increased error-prone non-homologous end joining (NHEJ) repair for DNA double-strand break (DSB) repair. CONCLUSIONS: Our study provides the first in vivo and in patient evidence supporting the role of CHD1 in DSB repair and in response to DNA damaging therapy. We uncover mechanistic insights that CHD1 modulates the choice between HR and NHEJ and suggest that CHD1 loss may contribute to genomic instability seen in this subset of PCa patients.

Project description:Non-homologous end-joining (NHEJ) plays an important role in double-strand break (DSB) repair of DNA. Recent studies have shown that the error patterns of NHEJ are strongly biased by sequence context, but these studies were based on relatively few templates. To investigate this more thoroughly, we systematically profiled ~1.16 million independent mutational events resulting from CRISPR/Cas9-mediated cleavage and NHEJ-mediated DSB repair of 6,872 synthetic target sequences, introduced into a human cell line via lentiviral infection. We find that: 1) insertions are dominated by 1 bp events templated by sequence immediately upstream of the cleavage site, 2) deletions are predominantly associated with microhomology, and 3) targets exhibit variable but reproducible diversity with respect to the number and relative frequency of the mutational outcomes to which they give rise. From these data, we trained a model (Lindel) that uses local sequence context to predict the distribution of mutational outcomes. Exploiting the bias of NHEJ outcomes towards microhomology mediated events, we demonstrate the programming of deletion patterns by introducing microhomology to specific locations in the vicinity of the DSB site. We anticipate that our results will inform investigations of DSB repair mechanisms as well as the design of CRISPR/Cas9 experiments for diverse applications including genome-wide screens, gene therapy, lineage tracing and molecular recording.

Project description:HUMAN POLD3 COORDINATES LEADING AND LAGGING STRAND IN MITOTIC DNA SYNTHESIS