Project description:Somatic mosaicism for DNA copy number alterations (SMC-CNA) is defined as gain or loss of chromosomal segments in mitotic cells within a single organism. As cells harboring SMC-CNA have the potential to undergo clonal expansion, SMC-CNA may be present in a substantial portion of cells in differentiated human tissues and may contribute to the predisposition of these cells to genetic disease including cancer. We characterized gross genomic alterations (>500 kbp) in uninvolved glandular tissue from 59 breast cancer patients and matched samples of primary tumors and lymph node metastases. Array based comparative genomic hybridization experiments showed 10% (6/59) of patients harbored 1 - 359 large SMC-CNA (mean: 1328 kbp; median: 961 kbp) in uninvolved glandular tissue. SMC-CNA were partially recurrent in tumors, albeit with considerable contribution of stochastic SMC-can, indicating genomic destabilization. Therefore, we hypothesized that the observed genomic destabilization is predetermined by mutations in genes related to maintenance of genomic integrity. Targeted resequencing of 301 known predisposition and somatic driver loci revealed mutations in the following genes: BRCA1 (p.Gln1756Profs*74, p.Arg504Cys), BRCA2 (p.Asn3124Ile), NCOR1 (p.Pro1570Glnfs*45), PALB2 (p.Ser500Pro) and TP53 (p.Arg306*). We demonstrated that gross SMC-CNA may be present in a substantial portion of glandular tissue cells, which are distant from that of the tumor cells, and may co-occur with point mutations in crucial cancer predisposing or somatic driver genes. Taken together, this highlights temporal and spatial neoplastic potential of uninvolved glandular tissue from breast cancer patients. Characterization of gross genomic alterations (>500 kbp) in uninvolved glandular tissue from 59 breast cancer patients and in the matched samples of primary tumors and lymph node metastases. Corresponding peripheral blood lekocyte DNA, a pool of female DNA (Promega), or uninvolved glandular tissue DNA was used as reference. No biological replicates are included.

Project description:Somatic mosaicism for DNA copy number alterations (SMC-CNA) is defined as gain or loss of chromosomal segments in mitotic cells within a single organism. As cells harboring SMC-CNA have the potential to undergo clonal expansion, SMC-CNA may be present in a substantial portion of cells in differentiated human tissues and may contribute to the predisposition of these cells to genetic disease including cancer. We characterized gross genomic alterations (>500 kbp) in uninvolved glandular tissue from 59 breast cancer patients and matched samples of primary tumors and lymph node metastases. Array based comparative genomic hybridization experiments showed 10% (6/59) of patients harbored 1 - 359 large SMC-CNA (mean: 1328 kbp; median: 961 kbp) in uninvolved glandular tissue. SMC-CNA were partially recurrent in tumors, albeit with considerable contribution of stochastic SMC-can, indicating genomic destabilization. Therefore, we hypothesized that the observed genomic destabilization is predetermined by mutations in genes related to maintenance of genomic integrity. Targeted resequencing of 301 known predisposition and somatic driver loci revealed mutations in the following genes: BRCA1 (p.Gln1756Profs*74, p.Arg504Cys), BRCA2 (p.Asn3124Ile), NCOR1 (p.Pro1570Glnfs*45), PALB2 (p.Ser500Pro) and TP53 (p.Arg306*). We demonstrated that gross SMC-CNA may be present in a substantial portion of glandular tissue cells, which are distant from that of the tumor cells, and may co-occur with point mutations in crucial cancer predisposing or somatic driver genes. Taken together, this highlights temporal and spatial neoplastic potential of uninvolved glandular tissue from breast cancer patients.

Project description:Somatic mosaicism for DNA copy number alterations (SMC-CNA) is defined as gain or loss of chromosomal segments in mitotic cells within a single organism. As cells harboring SMC-CNA have the potential to undergo clonal expansion, SMC-CNA may be present in a substantial portion of cells in differentiated human tissues and may contribute to the predisposition of these cells to genetic disease including cancer. We characterized gross genomic alterations (>500 kbp) in uninvolved glandular tissue from 59 breast cancer patients and matched samples of primary tumors and lymph node metastases. Array based comparative genomic hybridization experiments showed 10% (6/59) of patients harbored 1 - 359 large SMC-CNA (mean: 1328 kbp; median: 961 kbp) in uninvolved glandular tissue. SMC-CNA were partially recurrent in tumors, albeit with considerable contribution of stochastic SMC-can, indicating genomic destabilization. Therefore, we hypothesized that the observed genomic destabilization is predetermined by mutations in genes related to maintenance of genomic integrity. Targeted resequencing of 301 known predisposition and somatic driver loci revealed mutations in the following genes: BRCA1 (p.Gln1756Profs*74, p.Arg504Cys), BRCA2 (p.Asn3124Ile), NCOR1 (p.Pro1570Glnfs*45), PALB2 (p.Ser500Pro) and TP53 (p.Arg306*). We demonstrated that gross SMC-CNA may be present in a substantial portion of glandular tissue cells, which are distant from that of the tumor cells, and may co-occur with point mutations in crucial cancer predisposing or somatic driver genes. Taken together, this highlights temporal and spatial neoplastic potential of uninvolved glandular tissue from breast cancer patients.

Project description:Uninvolved tissue taken at the time of primary surgical resection of an adenocarcinoma. Uninvolved status determined by surgical margin and gross appearance, not pathology

Project description:Uninvolved tissue taken at the time of primary surgical resection of an adenocarcinoma. Uninvolved status determined by surgical margin and gross appearance, not pathology 35 biologically distinct samples, no replicates, no controls

Project description:Despite relevant clinical and/or familial presentations suggesting a hereditary predisposition (early-onset, multiple primary tumors, familial aggregation), targeted genomic analysis based on the phenotype are often non contributive. As somatic cancer genes are limited, the hypothesis is that the targeted next-generation sequencing of 200 genes, selected for their implications in cancers may contribute to the understanding of many selected patients’ presentation by the identification of germline deleterious mutations, and may identified phenotype overlapping and/or mosaicisms. The focus will be put on early-onset breast, ovarian, colorectal cancer or pediatric cancers and multiple primary tumors.

Project description:Single nucleotide polymorphism (SNP) microarrays are commonly applied to tumors to identify genomic regions with copy number alterations (CNA) or loss of heterozygosity (LOH). However, in typical tumor specimens collected in clinical studies, up to 60% of the DNA derives from stromal cells with a normal genome, resulting in attenuated sensitivity to true somatic aberrations in the tumor. Here we describe SNPfilter, a model-based method to decompose SNP array data from heterogeneous tumor specimens into their corresponding normal and tumor profiles. Unlike existing methods, SNPfilter does not require paired normal control data. We assessed the performance of this method using SNP array data representing cancer cell lines with aberrant genomes, B-cell lymphoblastoid cell lines with normal genomes, and defined mixtures of the two. In the pure tumor samples, SNPfilter identified CNA and LOH regions with accuracy similar to existing methods. In the mixture samples containing 40–80% tumor genomic DNA, SNPfilter yielded prediction sensitivity superior to existing methods. Thus, SNPfilter provides a powerful tool for discovery of clinically relevant somatic aberrations in tumor genomes.

Project description:To define clonal evolution of somatic copy number alterations (CNAs) in chronic lymphocytic leukemia (CLL), sequential samples of 103 individuals were investigated by SNP-array analysis for appearance of novel CNAs. Patients were enrolled on the CLL8 trial and uniformly received fludarabine, cyclophosphamide +/- rituximab (FC/FCR). Comparing two sequential samples prior to therapy (N=27, a median of 2.9 years apart), CNA evolution occurred in 19% of cases. In contrast, when comparing treatment‑initiation and relapse genomic profiles (a median of 3.6 years apart), CNA evolution was seen in 40% of cases. This suggested association of FC(R) treatment with higher rate of CNA evolution. The only clinical feature significantly associated with CNA evolution was FCR therapy compared with FC (OR=2.806, p=0.024). As this might be related to narrower evolutionary bottlenecks imposed by the more effective FCR therapy, which could execute more selection pressure, we examined matched minimal residual disease data. We found CNA evolution more frequently in cases with CLL cell numbers rapidly receding in early phases of treatment. Finally, we observed frequent rises of TP53 mutant/deficient clones with therapy (N=19, 22%) that were associated with decreased overall survival (p=0.016). These results demonstrated that re-examination of TP53 status upon relapse provides important information.

Project description:Clonal hematopoiesis (CH) is an independent risk factor for atherosclerotic cardiovascular disease. Murine models of CH suggest a central role of inflammasomes and IL-1β in accelerated atherosclerosis and plaque destabilization. Here we show using scRNAseq in human carotid plaques that inflammasome components are enriched in macrophages, while the receptor for IL-1β is enriched in fibroblasts and smooth muscle cells (SMCs). To address the role of inflammatory crosstalk in features of plaque destabilization, we conducted SMC fate mapping in mice modeling Jak2VF or Tet2 CH treated with IL-1β antibodies. Unexpectedly, this treatment minimally affected SMC differentiation, leading instead to a prominent expansion of fibroblast-like cells. Depletion of fibroblasts from mice treated with IL-1β antibody resulted in thinner fibrous caps. Conversely, genetic inactivation of Jak2VF during plaque regression promoted fibroblasts accumulation and fibrous cap thickening. Our studies suggest that suppression of inflammasomes promotes plaque stabilization by recruiting fibroblast-like cells to the fibrous cap.

Project description:Clonal hematopoiesis (CH) is an independent risk factor for atherosclerotic cardiovascular disease. Murine models of CH suggest a central role of inflammasomes and IL-1β in accelerated atherosclerosis and plaque destabilization. Here we show using scRNAseq in human carotid plaques that inflammasome components are enriched in macrophages, while the receptor for IL-1β is enriched in fibroblasts and smooth muscle cells (SMCs). To address the role of inflammatory crosstalk in features of plaque destabilization, we conducted SMC fate mapping in mice modeling Jak2VF or Tet2 CH treated with IL-1β antibodies. Unexpectedly, this treatment minimally affected SMC differentiation, leading instead to a prominent expansion of fibroblast-like cells. Depletion of fibroblasts from mice treated with IL-1β antibody resulted in thinner fibrous caps. Conversely, genetic inactivation of Jak2VF during plaque regression promoted fibroblasts accumulation and fibrous cap thickening. Our studies suggest that suppression of inflammasomes promotes plaque stabilization by recruiting fibroblast-like cells to the fibrous cap.