Project description:Replication protein A1 (RPA1) is a single-stranded DNA binding protein that is known to participate in DNA replication, recombination and damage repair. However, little is known about RPA1’s role in controlling chromatin architecture and gene transcription. Further, physiological functions of RPA1 in mouse tissues still remain exclusive. Here we show that Rpa1 heterozygous mice developed age-depended fatty liver disease and are more susceptible to hepatic steatosis in response to high-fat diet. Liver specific deletion of Rpa1 impairs fatty acid oxidation, leading to hepatic steatosis and high incidence of hepatocellular carcinoma. Transcriptome analysis identified down-regulation of fatty acid oxidation related genes. Cleavage Under Targets and Tagmentation (CUT&Tag) and Assay for transposase-accessible chromatin using sequencing (ATAC-seq) revealed that RPA1 binds and regulates chromatin accessibility in regulatory regions of a group of genes involved in lipid metabolism in liver. Further, down-regulation of RPA1 was found in patients with fatty liver disease. Thus, our results not only established that RPA1 is critical controller of chromatin architecture and regulator of gene transcription, but also provided new insights into the epigenetic mechanism of fatty liver disease, which could inform future therapy.

Project description:Transcription factor access to regulatory elements is prevented by the nucleosome. Heat shock factor 1 (HSF1) is a winged helix transcription factor that plays roles in control and stressed conditions by gaining access to target elements, but mechanisms of HSF1 access have not been well known in mammalian cells. We show a physical interaction between the wing motif of human HSF1 and replication protein A (RPA), which is involved in DNA metabolism. Depletion of RPA1 abolishes HSF1 access to the promoter of HSP70 in unstressed conditions, and delays its rapid activation in response to heat shock. The HSF1-RPA complex leads preloading of RNA polymerase II and opens chromatin structure by recruiting a histone chaperone FACT. Furthermore, this interaction is required for melanoma cell proliferation. These results provide a mechanistic basis for constitutive HSF1 access to nucleosomal DNA, which is important for both basal and inducible gene expression. To examine whether the HSF1-RPA complex regulates the expression of genes, mRNA levels in MEFs with/without HSF1- or RPA1-shRNA were analyzed by DNA microarray analysis using GeneChip Mouse Gene 1.0 ST Arrays (Affymetrix).

Project description:RPA1 Remodels Liver Chromatin Architecture to Maintain Lipid Metabolic Homeostasis

Project description:Transcription factor access to regulatory elements is prevented by the nucleosome. Heat shock factor 1 (HSF1) is a winged helix transcription factor that plays roles in control and stressed conditions by gaining access to target elements, but mechanisms of HSF1 access have not been well known in mammalian cells. We show a physical interaction between the wing motif of human HSF1 and replication protein A (RPA), which is involved in DNA metabolism. Depletion of RPA1 abolishes HSF1 access to the promoter of HSP70 in unstressed conditions, and delays its rapid activation in response to heat shock. The HSF1-RPA complex leads preloading of RNA polymerase II and opens chromatin structure by recruiting a histone chaperone FACT. Furthermore, this interaction is required for melanoma cell proliferation. These results provide a mechanistic basis for constitutive HSF1 access to nucleosomal DNA, which is important for both basal and inducible gene expression.

Project description:The peripheral T cell pool is maintained at dynamic homeostasis throughout life. This is achieved through fine-tuning of thymic output and self-renewal of naïve T cells. Dysregulation of T cell homeostasis has been implicated in autoimmune diseases, yet little is known about the homeostatic mechanisms. Here, we report that the replication protein A1 (RPA1) is upregulated during T cell activation. Utilizing T cell-specific Rpa1-deficient (Rpa1fl/fl Cd4-cre) mice, we find that loss of Rpa1 restrains peripheral CD8+ T cell population and limits TCR repertoire diversity. Clinical analysis reveals that the mRNA level of RPA1 is reduced in patients with ulcerative colitis. Accordingly, Rpa1fl/fl Cd4-cre mice exhibit increased susceptibility to inflammatory diseases, including colitis and hepatitis. Mechanistically, RPA1 deficiency triggers necroptotic T cell death following TCR engagement, which in turn results in damage-associated molecular patterns (DAMPs) leakage and leukocyte recruitment, consequently exacerbating inflammatory damage. These studies thus uncover that RPA1 acts as a guardian of T cell clonal expansion that is essential for T cell homeostasis.

Project description:As a single strand DNA binding protein, RPA1 participates various cellular processes including DNA replication and DNA repair.However, the role of RPA1 in T cell is largely unknown. We generate a mice model in which RPA1 was specifically deleted in T cell. Through single cell RNA sequencing, we reveal the immune landscape in RPA1 conditional knockout mice.

Project description:As a single strand DNA binding protein, RPA1 participates in various cellular processes including DNA replication and DNA repair. However, the role of RPA1 in T cells is largely unknown. We generated a mouse model in which RPA1 was specifically deleted in T cells. Through single cell RNA sequencing, we reveal the immune landscape in RPA1 conditional knockout mice.

Project description:As a single strand DNA binding protein, RPA1 participates in various cellular processes including DNA replication and DNA repair. However, the role of RPA1 in T cells is largely unknown. We generated a mouse model in which RPA1 was specifically deleted in T cells. Through single cell RNA sequencing, we reveal the immune landscape in RPA1 conditional knockout mice.

Project description:SLFN11 sensitizes cancer cells to a broad range of DNA-targeted therapies. Here we show that, in response to replication stress induced by camptothecin, SLFN11 tightly binds chromatin at stressed replication foci via RPA1 together with the replication helicase subunit MCM3. Unlike ATR, SLFN11 neither interferes with the loading of CDC45 and PCNA nor inhibits the initiation of DNA replication but selectively blocks fork progression while inducing chromatin opening across replication initiation sites. The ATPase domain of SLFN11 is required for chromatin opening, replication block and cell death but not for the tight binding of SLFN11 to chromatin. Replication stress by the CHK1 inhibitor Prexasertib also recruits SLFN11 to nascent replicating DNA together with CDC45 and PCNA. We conclude that SLFN11 is recruited to stressed replication forks carrying extended RPA filaments where it blocks replication by changing chromatin structure across replication sites.

Project description:SLFN11 sensitizes cancer cells to a broad range of DNA-targeted therapies. Here we show that, in response to replication stress induced by camptothecin, SLFN11 tightly binds chromatin at stressed replication foci via RPA1 together with the replication helicase subunit MCM3. Unlike ATR, SLFN11 neither interferes with the loading of CDC45 and PCNA nor inhibits the initiation of DNA replication but selectively blocks fork progression while inducing chromatin opening across replication initiation sites. The ATPase domain of SLFN11 is required for chromatin opening, replication block and cell death but not for the tight binding of SLFN11 to chromatin. Replication stress by the CHK1 inhibitor Prexasertib also recruits SLFN11 to nascent replicating DNA together with CDC45 and PCNA. We conclude that SLFN11 is recruited to stressed replication forks carrying extended RPA filaments where it blocks replication by changing chromatin structure across replication sites.