Immune evasion pathways and the design of dendritic cell-based cancer vaccines.
Abstract
Emerging data is suggesting that the process of dendritic cell (DC) tolerization is
an important step in tumorigenesis. Our understanding of the networks within the tumor
microenvironment that functionally tolerize DC function is evolving while methods
for genetically manipulating DC populations in situ continue to develop. A more intimate
understanding of the paracrine signaling pathways which mediate immune evasion by
subverting DC function promises to provide novel strategies for improving the clinical
efficacy of DC-based cancer vaccines. This will likely require a better understanding
of both the antigen expression profile and the immune evasion network of the tumor
and its associated stromal tissues.
Type
Journal articlePermalink
https://hdl.handle.net/10161/13295Collections
More Info
Show full item recordScholars@Duke
Brent A. Hanks
Associate Professor of Medicine
We are interested in understanding the mechanisms that cancers have evolved to suppress
the generation of tumor antigen-specific immune responses and how this knowledge can
be exploited for the development of novel and more effective cancer immunotherapy
strategies. This work involves the utilization of both autochthonous transgenic tumor
model systems as well as clinical specimens to develop novel strategies to enhance
the efficacy of immunotherapies while also developing predictive biomarkers
Articles written by Duke faculty are made available through the campus open access policy. For more information see: Duke Open Access Policy
Rights for Collection: Scholarly Articles
Works are deposited here by their authors, and represent their research and opinions, not that of Duke University. Some materials and descriptions may include offensive content. More info