Project description:Primary skin fibroblasts from HGPS patients and an age-matched control wild-type individuals were challenged in a standard transformation assay by retroviral introduction of TERT (T), V12-HRAS (R) and SV40 large and small T antigens (S). TERT-Immortalized cell lines from the same sources were also generated. Abstract: Advanced age and DNA damage accumulation are strong risk factors for cancer. The premature-aging disorder Hutchinson Gilford Progeria Syndrome (HGPS) provides a unique opportunity to study the interplay between DNA damage and aging-associated tumor mechanisms, since HGPS patients do not develop tumors despite elevated levels of DNA damage. Here, we have used HGPS patient cells to identify a protective mechanism to oncogenesis. We find that HGPS cells are resistant to neo-plastic transformation. This resistance is mediated by the bromodomain protein BRD4, which exhibits altered genome-wide binding patterns in transformation-resistant cells leading to inhibition of oncogenic de-differentiation. BRD4 also in-hibits, albeit to a lower extent, the tumorigenic potential of transformed cells from healthy individuals and BRD4-mediated tumor protection is clinically relevant, since a BRD4 gene signature predicts positive clinical outcome in breast and lung cancer. Our results demonstrate a protective function for BRD4 and suggest tissue-specific functions for BRD4 in tumorigenesis. 2 independent cell lines are included for each of the 4 groups (TERT-WT, TRS-WT, TERT-HGPS and TRS-HGPS)

Project description:Primary skin fibroblasts from a HGPS patient and an age-matched control wild-type individual were challenged in a standard transformation assay by retroviral introduction of TERT (T), V12-HRAS (R) and SV40 large and small T antigens (S). Knock-down of BRD4 in this TRS-HGPS cell line (TRS-HGPS-shBRD4) was achieved by retroviral introduction of independent shRNAs (shBRD4-1 to -3) Abstract: Advanced age and DNA damage accumulation are strong risk factors for cancer. The premature-aging disorder Hutchinson Gilford Progeria Syndrome (HGPS) provides a unique opportunity to study the interplay between DNA damage and aging-associated tumor mechanisms, since HGPS patients do not develop tumors despite elevated levels of DNA damage. Here, we have used HGPS patient cells to identify a protective mechanism to oncogenesis. We find that HGPS cells are resistant to neo-plastic transformation. This resistance is mediated by the bromodomain protein BRD4, which exhibits altered genome-wide binding patterns in transformation-resistant cells leading to inhibition of oncogenic de-differentiation. BRD4 also in-hibits, albeit to a lower extent, the tumorigenic potential of transformed cells from healthy individuals and BRD4-mediated tumor protection is clinically relevant, since a BRD4 gene signature predicts positive clinical outcome in breast and lung cancer. Our results demonstrate a protective function for BRD4 and suggest tissue-specific functions for BRD4 in tumorigenesis. 2 biological replicates are included for TRS-WT and TRS-HGPS cell lines. 3 biological replicates are included for TRS-HGPS-shBRD4 (derived from 3 independent shRNAs against BRD4)

Project description:Primary skin fibroblasts from a HGPS patient and an age-matched control wild-type individual were challenged in a standard transformation assay by retroviral introduction of TERT (T), V12-HRAS (R) and SV40 large and small T antigens (S). Knock-down of BRD4 in this TRS-HGPS cell line (TRS-HGPS-shBRD4) was achieved by retroviral introduction of independent shRNAs (shBRD4-1 to -3) Abstract: Advanced age and DNA damage accumulation are strong risk factors for cancer. The premature-aging disorder Hutchinson Gilford Progeria Syndrome (HGPS) provides a unique opportunity to study the interplay between DNA damage and aging-associated tumor mechanisms, since HGPS patients do not develop tumors despite elevated levels of DNA damage. Here, we have used HGPS patient cells to identify a protective mechanism to oncogenesis. We find that HGPS cells are resistant to neo-plastic transformation. This resistance is mediated by the bromodomain protein BRD4, which exhibits altered genome-wide binding patterns in transformation-resistant cells leading to inhibition of oncogenic de-differentiation. BRD4 also in-hibits, albeit to a lower extent, the tumorigenic potential of transformed cells from healthy individuals and BRD4-mediated tumor protection is clinically relevant, since a BRD4 gene signature predicts positive clinical outcome in breast and lung cancer. Our results demonstrate a protective function for BRD4 and suggest tissue-specific functions for BRD4 in tumorigenesis.

Project description:Analysis of BRD4 ChIP-seq data of two types of human transformed fibroblasts (WT and HGPS) to identify specific and common binding sites for BRD4. Transformed cell lines were obtained by retroviral introduction of TERT (T), V12-HRAS (R) and SV40 large and small T antigens (S) of primary skin fibroblasts for HGPS patients (TRS-HGPS) and age-matched control wild-type individuals (TRS-WT) Abstract: Advanced age and DNA damage accumulation are strong risk factors for cancer. The premature-aging disorder Hutchinson Gilford Progeria Syndrome (HGPS) provides a unique opportunity to study the interplay between DNA damage and aging-associated tumor mechanisms, since HGPS patients do not develop tumors despite elevated levels of DNA damage. Here, we have used HGPS patient cells to identify a protective mechanism to oncogenesis. We find that HGPS cells are resistant to neo-plastic transformation. This resistance is mediated by the bromodomain protein BRD4, which exhibits altered genome-wide binding patterns in transformation-resistant cells leading to inhibition of oncogenic de-differentiation. BRD4 also in-hibits, albeit to a lower extent, the tumorigenic potential of transformed cells from healthy individuals and BRD4-mediated tumor protection is clinically relevant, since a BRD4 gene signature predicts positive clinical outcome in breast and lung cancer. Our results demonstrate a protective function for BRD4 and suggest tissue-specific functions for BRD4 in tumorigenesis. Examination of BRD4 binding events in TRS-WT and TRS-HGPS fibroblasts (2 independent cell lines in each group)

Project description:Analysis of BRD4 ChIP-seq data of two types of human transformed fibroblasts (WT and HGPS) to identify specific and common binding sites for BRD4. Transformed cell lines were obtained by retroviral introduction of TERT (T), V12-HRAS (R) and SV40 large and small T antigens (S) of primary skin fibroblasts for HGPS patients (TRS-HGPS) and age-matched control wild-type individuals (TRS-WT) Abstract: Advanced age and DNA damage accumulation are strong risk factors for cancer. The premature-aging disorder Hutchinson Gilford Progeria Syndrome (HGPS) provides a unique opportunity to study the interplay between DNA damage and aging-associated tumor mechanisms, since HGPS patients do not develop tumors despite elevated levels of DNA damage. Here, we have used HGPS patient cells to identify a protective mechanism to oncogenesis. We find that HGPS cells are resistant to neo-plastic transformation. This resistance is mediated by the bromodomain protein BRD4, which exhibits altered genome-wide binding patterns in transformation-resistant cells leading to inhibition of oncogenic de-differentiation. BRD4 also in-hibits, albeit to a lower extent, the tumorigenic potential of transformed cells from healthy individuals and BRD4-mediated tumor protection is clinically relevant, since a BRD4 gene signature predicts positive clinical outcome in breast and lung cancer. Our results demonstrate a protective function for BRD4 and suggest tissue-specific functions for BRD4 in tumorigenesis.

Project description:HGPS is a rare premature ageing disease, caused by a mutation in the LMNA gene, which activates a cryptic splice site, resulting in the production of a mutant lamin A isoform, called progerin. Sporadic usage of the same cryptic splice site has been observed with normal physiological aging. As it is unknown how HGPS causes premature ageing defects, we set out to determine the gene signature of both young healthy individuals, old healthy individuals, as well as HGPS patients.

Project description:Premature aging disorders provide a lens through which to study the drivers of aging. In Hutchinson-Gilford progeria syndrome (HGPS) a mutant form of the nuclear scaffold protein lamin A distorts nuclei and sequesters nuclear proteins. We used stable isotope labeling and quantitative mass spectrometry to investigate nuclear protein homeostasis in primary HGPS-derived cells.

Project description:Hutchinson-Gilford progeria syndrome (HGPS) is a rare and fatal disease manifested by premature aging and aging-related phenotypes, making it a disease model for physiological aging. The cellular machinery mediating age-associated hallmarks in HGPS remains largely unknown, resulting in limited therapeutic targets for HGPS treatment. In this study, we showed that deficiencies in mitophagy impaired mitochondrial quality and contributed to cellular phenotypes associated with aging in mesenchymal stem cells derived from HGPS patients (HGPS-MSCs). Mechanistically, we discovered that mitophagy affected the aging-related phenotypes of HGPS-MSCs by inhibiting the cGAS-STING-NF-ĸB pathway and the downstream transcription of senescence-associated secretory phenotype (SASP). Furthermore, by utilizing UMI-77, an effective inducer of mitophagy, we showed that mitophagy induction can alleviate aging-associated phenotypes in both HGPS mice and naturally aged mice. In summary, our results uncover that mitophagy defects mediate mitochondrial dysfunction and aging-associated phenotypes in HGPS models, highlight the function of mitochondrial homeostasis in HGPS progression, and suggest that mitophagy could be exploited as a promising therapeutic target for both HGPS and aging.

Project description:Premature aging disorders provide a lens through which to study the drivers of aging. In Hutchinson-Gilford progeria syndrome (HGPS) a mutant form of the nuclear scaffold protein lamin A distorts nuclei and sequesters nuclear proteins. We used stable isotope labeling and quantitative mass spectrometry to investigate nuclear protein homeostasis in primary HGPS-derived cells.

Project description:Exon level expression analysis for the HGPS pathological aging study data set to analyze the effect of progerin expression on alternative splicing in keratinocytes of HGPS mice. Analysis of the effect of pathological aging (transgenic progerin expression) on alternative splicing (AS) using exon microarrays to interrogate the differential exon usage of the entire genome of HGPS mice (postnatal day 24 and 35) and their wild-type litter mates. Our results suggests that early expression of progerin impairs developmental splicing but that as progerin accumulates, the number of genes with AS increases, similar to what is observed in aging wild-type mice. This dataset is one of the 2 datasets in the overall study. An additional data set series is available with exon expression analysis of aging wild-type mice to analyze the effect of age on alternative splicing during physiological aging. The two datasets are linked together in the SuperSeries GSE67289. A link to the SuperSeries is available at the bottom of this page. 16 skin keratinocyte samples from 2 different age groups: postnatal day 24 and postnatal day 35, from 8 HGPS samples and 8 genotype negative (wild-type) littermates.