Ulcerative colitis (UC) is a chronic inflammatory disease that elevates an individual's risk of colon cancer. After 30 years, ten to twenty percent of patients with chronic ulcerative colitis have developed colon cancer. The current recommendations for patient management entail annual endoscopic surveillance with procurement of multiple biopsies, which are histologically assessed by a pathologist for signs of neoplasia. For cancer detection to be useful, it must occur during a narrow window of time between when a local tumor becomes large enough to have a high probability of being sampled but before it has spread to elsewhere in the body and become untreatable. Because of this limitation, endoscopy must be relatively frequent and sampling relatively extensive, making current surveillance techniques, expensive, time consuming and impractical for many individuals. We have recently demonstrated that DNA sequence alterations at mutational hotspots can be used to track abnormal patterns of clonal cell growth in normal-appearing tissues throughout the entire colon of UC patients harboring localized cancers, but not in those with similarly inflamed colons without cancer or precancerous lesions. In a blinded pilot study, in which we screened for clonal mutations at polyguanine tracts in random biopsies from UC patients'colons, we were able to distinguish UC patients with cancer and precancerous lesions (11 patients, 61 mutations) from age and disease-duration matched patients who were cancer/dysplasia free (8 patients 2 mutations) with 100% sensitivity and 92% specificity using only five samples per patient. Our proposed studies will further characterize and validate the association between mutations in polyguanine tracts in DNA with the development of colon cancer in UC. We will enhance our assay throughput and sensitivity through optimal selection of genomic mutational hotspots and technical improvements using both conventional and next-generation sequencing technology. We will determine if our mutational markers can be detected in biopsies prior to the histological detection of precancerous lesions or tumors by histology. In addition, we will determine the changes that occur in colon cells that generate mutations in polyguanine tracts. These cellular alterations may provide new targets to prevent the emergence of colon cancers in ulcerative colitis. Our studies should reduce the cost and the number of patients requiring extensive cancer surveillance and ultimately may be applicable for the early detection of a variety of inflammation-driven cancers.

Public Health Relevance

Many chronic inflammatory diseases increase a patient's risk of cancer, requiring these individuals to be closely monitored for emerging tumors. Current techniques for cancer surveillance are insufficiently sensitive, time-consuming and costly. We propose to develop better methods for identifying early cancers with greater ease and at less cost using state-of-the-art DNA sequencing technology that can be rapidly commercialized for translation to patient care settings.

National Institute of Health (NIH)
National Cancer Institute (NCI)
Research Project (R01)
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Cancer Genetics Study Section (CG)
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Wagner, Paul D
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University of Washington
Schools of Medicine
United States
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Kennedy, Scott R; Schmitt, Michael W; Fox, Edward J et al. (2014) Detecting ultralow-frequency mutations by Duplex Sequencing. Nat Protoc 9:2586-606
Fox, Edward J; Loeb, Lawrence A (2014) Cancer: One cell at a time. Nature 512:143-4
Salk, Jesse J; Bansal, Aasthaa; Lai, Lisa A et al. (2013) Clonal expansions and short telomeres are associated with neoplasia in early-onset, but not late-onset, ulcerative colitis. Inflamm Bowel Dis 19:2593-602
Fox, Edward J; Prindle, Marc J; Loeb, Lawrence A (2013) Do mutator mutations fuel tumorigenesis? Cancer Metastasis Rev 32:353-61