Study of genomic variation to identify biomarkers and novel therapeutic targets in colorectal tumors

Colorectal cancer is one of the more frequent tumor types in the world. To select the appropriate treatment course, it is necessary to develop more precise diagnostic approaches. The current availability of high throughput genome sequencing methods allows for a comprehensive characterization of the structural and sequence alterations present in each tumor. The use of tumor genome sequencing in a personalized setting can result in tumor specific biomarkers that help evaluate response to treatment and the presence of residual disease, improving the clinical management of these patients, and also reveal sequence alterations in genes capable of serving as new therapeutic targets. In this study we developed an efficient bioinformatics pipeline to identify biomarkers based on the existing structural alterations in rectal tumor genomes, eliminating the need to sequence the matched normal genome and therefore reducing the cost for this approach. The biomarkers found for each of the six patients were used to evaluate the presence of residual disease after treatment through the detection of circulating tumor DNA in plasma samples collected at different points during the treatment. Sequencing tumor genomes with low coverage is therefore a viable and promising alternative to follow up rectal cancer patient\'s response to treatment. In the second part of this study, the analysis of colorectal cancer cell lines revealed a large quantity of point mutations (SNVs and InDels) in genes coding for proteins located in the cell surface (surfaceome). These alterations in the surfaceome indicate potential new drug targets and altered pathways in this type of tumor. Furthermore, these point mutations are also responsible for the generation of new epitopes with immunogenic potential and these new epitopes can be applied as personalized tumor vaccines and had previously been proposed as a therapeutic alternative. The presence of new epitopes, especially in the cell lines with elevated mutation rates (resulting from MSI and mutations in DNA mismatch-repair genes or POLE), suggests a potential use of immune checkpoint target drugs in patients with tumors that share these genetic characteristics. With a large-scale bioinformatics approach, we detected new tumor epitopes resulting from point mutations, present in most of the cell lines used. The analysis of gene expression data puts into perspective both the somatic mutations found and which targets are promising as well as the development of therapies based on vaccines derived from tumor epitopes. In conclusion, the study of genomic alterations in primary tumors and colorectal cancer cell lines allowed the detection of structural variations that were used as personalized biomarkers in patients with rectal tumors as well as the identification of genes containing point mutations in colorectal cancer cell lines, that reveal potential new therapeutic targets to be explored in the clinical setting. (AU)