Cancer Genetics

The goal of the Cancer Genetics Program is to go beyond the standard genotype-phenotype correlation toward understanding cross talk between genes and non-genetic influences on genes. Genes do not act in isolation and these types of interactions impact the resulting phenotype with profound implications in human cancer.

Highlights of research by Program investigators include

• Jason Lieb’s development of method to fractionate chromatin from the yeast Saccharomyces cerevisiae into functionally distinct genomic regions. Such a method will be applicable to mammalian cells and it has the potential to be an extremely powerful new diagnostic /prognostic clinical tool.
• Chuck Perou has demonstrated that gene expression-defined cancer subtypes are predictive of overall patient survival and relapse-free survival in his cohort of patients as well as in independent cohorts.
• David Threadgill has focused on identification of modifiers of Egf receptor activity that may be useful for identifying patients that will not respond to anti-Egfr therapy. This work has lead to the development of a translational project for the GI SPORE application to investigate variation in response to Egfr inhibition.
• Dr. Terry Magnuson leads the Program and he has made significant contributions in the area of chromatin remodeling and epigenetics as well as novel approaches for functional genomics.
• The mouse models of human cancer group, led by Terry Van Dyke, has created many opportunities for those studying cancer etiology and therapy.

Recent recruitment in statistical and human genetics, as well as computational approaches, are expanding the scope of the program, particularly its impact on the population and clinical sciences. The recruitment and program leadership of core facility development and enlargement is providing additional opportunities for collaboration and participation in high priority NCI initiatives, e.g., systems biology and caBIG. In 2003, the 22 program faculty investigators have 51 grants and $10.3 million in total extramural support. Peer-reviewed research funding totals 44 grants and $9.8 million, including 17 grants ($4.1 million) from the National Cancer Institute.

Recognizing that individuals differ in their susceptibility to cancer based upon polymorphic differences in low penetrance cancer genes and that cancers progress because of accumulation of multiple genetic abnormalities, the Cancer Genetics Program Faculty have outlined five future strategic goals:

1. High penetrance cancer genes in model systems,
2. Loss of genome integrity that can lead to uncontrolled cell growth, invasion and metastasis,
3. Epigenetics and the involvement of chromatin organization in regulation of DNA metabolism,
4. Development of genome-wide strategies that depend on statistical tools to gather genome information, and
5. Quantitative genetics to identify modifier genes and gene networks.