Genetic susceptibility plays a significant role in glioma development. An individual with two or more first- and/or second-degree affected relatives has a two-fold increased risk of the disease. We were the first to suggest mutations in POT1 (Protection of Telomeres 1) as causative in familial glioma (FG). We have now established the presence of POT1 mutations in 5 different families, providing the strongest evidence of its role in glioma. However, we do not yet have direct functional evidence that loss of POT1 is causal in glioma leaving few options for carrier surveillance or potential treatment targets. We are currently able to explain the genetic basis of glioma in up to 12% of our families, using highly stringent criteria for calling a mutation deleterious and causal. In contrast, the majority of our families remain unexplained though several candidate genes have emerged as `suspects of interest (SOIs)'. We propose a data-driven, knowledge-based, computational approach to guide candidate gene selection for functional characterization. In order to further our efforts to explain the genetic basis of FG we propose two specific aims to: Identify new gene candidates that may cause FG through WGS (Aim 1). We will identify SNVs, small indels, and structural variants in both coding and noncoding regions of the genome, intensively annotate those variants using more than 50 data sources, and we will rank these variants using multiple criteria based on their likelihood to cause disease. In addition to the 270 FG cases (from 203 FG families) with sequence data already available, we will also sequence an additional 100 cases (from 100 families) already collected in our Glioma International Case-Control Study with a reported family history using Gliogene criteria, and 200 newly recruited cases (from 100 families) with a strong family history of glioma to enhance our discovery. ). We will molecularly characterize tumor samples when available to enable analysis of our cohort by tumor subtype.
The second aim i s to functionally validate SOIs to include: A) POT1 mutations identified in additional families and B) newly discovered FG susceptibility genes (SOIs) from Aim 1 using our novel experimental mouse stem cell spheres and mouse models of gliomagenesis.To determine the functional contributions of POT1 and novel mutations identified in our WGS studies, we will evaluate these genes in glioma mouse models using CRISPR gene editing technology. This study has the strong potential for delineating the genetic basis of glioma for genetic testing of high-risk families; success will offer insight on the underlying biology of glioma for future work on early detection and targeted treatment.

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The overall goal of this proposal is to identify new gene candidates that might cause familial glioma and to conduct functional validation using mouse models. We will use CRISPR gene editing technology to functionalize POT1 and other newly discovered mutations. This study will contribute to our understanding of gliomagenesis, and provide information on potential pathways or molecular events that lead to familial glioma.

National Institute of Health (NIH)
National Cancer Institute (NCI)
Research Project (R01)
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Cancer, Heart, and Sleep Epidemiology B Study Section (CHSB)
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Rotunno, Melissa
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Baylor College of Medicine
Internal Medicine/Medicine
Schools of Medicine
United States
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