Project description:Many normal tissues undergo age-related DNA methylation drift providing a quantitative measure of tissue age. However this drift has not been demonstrated in neoplastic tissues. Here we identify and validate 781 CpG-islands (CGIs) that undergo significant methylomic drift in normal colorectal tissues continue to drift in neoplasia and remain significantly correlated with one another across tissue samples. However compared with normal colon this drift advances (~3-4 fold) faster in neoplasia consistent with increased cell proliferation during neoplastic progression. Furthermore we show that the observed drift patterns are broadly consistent with modeled adenoma-carcinoma sojourn time distributions from colorectal cancer (CRC) incidence data. These results support the hypothesis that beginning with the founder premalignant cell cancer precursors frequently sojourn for decades before turning into cancer which implies that the founder cell typically arises early in life. We estimate that at least 77-89% of the observed drift variance in distal and rectal tumors is explained by stochastic variability associated with neoplastic progression while only 55% of the variance is explained for proximal tumors. However >50% of identified gene-CGI pairs in the proximal colon that undergo drift are significantly and mainly negatively correlated with cancer gene expression suggesting that methylomic drift participates in the clonal evolution of CRCs. Significance: Methylomic drift advances in colorectal neoplasia consistent with extended sojourn time distributions explaining a significant fraction of epigenetic heterogeneity in CRCs. Importantly the estimated long-duration premalignant sojourn times suggest that early dietary and lifestyle interventions may be more effective than later changes in reducing CRC incidence.

Project description: Not available

Project description:Mutational classification of colorectal cancer

Project description:Implications of epigenetic drift in colorectal neoplasia

Project description:We performed shotgun proteomics of colorectal cancer tissue and premalignant lesions using iTRAQ to identify biomarker candidate proteins for colorectal cancer.

Project description:Using miRDeep2 and a custom NGS data analysis workflow to annotate and quantify isomiRs in normal and neoplastic colorectal tissues.

Project description:Lung squamous cell carcinoma (SCC) is thought to arise from premalignant lesions in the airway epithelium, therefore studying these lesions is critical for understanding lung carcinogenesis. We performed RNA sequencing on laser-microdissected representative cell populations along the SCC pathological continuum of patient-matched normal basal cells, premalignant lesions, and tumor cells. We discovered transcriptomic changes and identified genomic pathways altered with initiation and progression of SCC within individual patients. We used immunofluorescent staining to confirm gene expression changes in premalignant lesions and tumor cells, including increased expression of SLC2A1, CEACAM5, and PTBP3 at the protein level and increased activation of MYC via nuclear translocation. Cytoband enrichment analysis revealed coordinated loss and gain of expression in chromosome 3p and 3q regions, respectively, during carcinogenesis. This is the first gene expression profiling of airway premalignant lesions with patient-matched samples that provides insight into the mechanisms of stepwise lung carcinogenesis.

Project description:Lung squamous cell carcinoma (SCC) is thought to arise from premalignant lesions in the airway epithelium, therefore studying these lesions is critical for understanding lung carcinogenesis. We performed RNA sequencing on laser-microdissected representative cell populations along the SCC pathological continuum of patient-matched normal basal cells, premalignant lesions, and tumor cells. We discovered transcriptomic changes and identified genomic pathways altered with initiation and progression of SCC within individual patients. We used immunofluorescent staining to confirm gene expression changes in premalignant lesions and tumor cells, including increased expression of SLC2A1, CEACAM5, and PTBP3 at the protein level and increased activation of MYC via nuclear translocation. Cytoband enrichment analysis revealed coordinated loss and gain of expression in chromosome 3p and 3q regions, respectively, during carcinogenesis. This is the first gene expression profiling of airway premalignant lesions with patient-matched samples that provides insight into the mechanisms of stepwise lung carcinogenesis. Profiling of mRNA expression in laser-microdissected normal airway basal cells, premalignant airway lesions, and lung SCC tumor cells by massively parallel RNA sequencing.

Project description:Colibactin, a potent genotoxin of Escherichia coli, causes DNA double strand breaks (DSBs). We investigated if colibactin creates a particular DNA damage signature in infected human cells. Genomic contexts of colibactin-induced DSBs were enriched for a distinct AT-rich hexameric sequence motif. A survey of somatic mutations at the colibactin target sites of several thousand cancer genomes revealed significant enrichment of the motif in colorectal cancers. Moreover, the exact break point location corresponded with mutational hot spots in these cancers corresponding to a distinct trinucleotide signature. This work provides evidence for a role of colibactin in the etiology of human cancer.

Project description:Cervical intraepithelial neoplasia (CIN), also known as cervical dysplasia, is premalignant lesions of the cervical squamous cell carcinoma (CSCC) that shows abnormal growth of squamous cells in the cervix epithelium. Given the evidence suggesting that differences may exist between CIN and CSCC, we hypothesize that progression may be mediated by subpopulation selection or by acquisition of additional alterations, including gene mutations or chromosomal alterations. In this study, we analyzed cervical CIN, microinvasive carcinoma (MIC) and CSCC by whole-exome sequencing and array-comparative genomic hybridization (array-CGH) and found that CIN genomes harbored fewer mutations (especially fewer driver mutations) and copy number alterations (CNAs), suggesting that additional genomic alterations might burst onto the CIN genome at the final stage of CIN progression to CSCC or an early stage of CSCC.