| dc.description.abstract |
<p>Over the past several decades, many genes have been discovered that govern important
functions in the development of a variety of different cancers. However, biological
insight from the list of genes is still limited and the underlying mechanisms that
occur in the cell during tumorigenesis have not been well established. Studying cancer
progression in terms of the oncogenic pathways that are responsible for specific actions
that change normal cells into tumors is a means for bringing insight onto these issues.
The work presented here will uncover mechanisms that are occurring at the pathway
level that first initiate tumor formation and then continue through cancer progression
and finally metastasis. This knowledge will allow for drug treatment that is better
targeted towards an individual.</p><p>Microarray technology has allowed for the collection
of gene expression datasets from clinical cancer and other studies. These datasets
can be used to study how expression levels of individual genes or groups of related
genes are altered in individuals from different phenotypic groups. Statistical methods
exist which assay pathway enrichment by phenotypic class but do not describe individual
variation.
In order to study this individual variation, we developed a formal statistical method
called ASSESS which measures the enrichment of a gene set in each sample in an expression
dataset.</p><p>As cancer advances through the stages of initiation, progression, and
proliferation, multiple pathways experience disruptions at various times. However,
there is still much unknown on these particular pathways that evidence gene expression
changes throughout tumorigenesis. Using gene expression datasets comprised of individuals
with tumors classified by location and stage, we applied ASSESS in order to study the
data on the pathway level. We then utilized novel statistical methods to uncover the
pathways that play a role in cancer progression and in what order the pathways become
perturbed.</p><p>These analyses can give a basis for how genetic disruptions serve
to alter actions in specific cell types. The results may provide insight that will
lead to treatments of existing tumors and prevention of incipient cancers from forming.
Treatments for existing tumors will use multiple drugs to target the pathways that
show an altered state of activity.</p>
|
|
