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Rodney Stewart

Positions:
Assistant Professor - Oncological Sciences Investigator - Huntsman Cancer Institute

Phone: (801)587-5567
Lab Phone:
Fax:
Email: rodney.stewart@hci.utah.edu
Admin. Contact: Norma Haas (801)587-4719

Office Address:
3245 Huntsman Cancer Institute

Mailing Address:
Huntsman Cancer Institute
2000 Circle of Hope
Salt Lake City, UT 84112-5550

Research Description:

My laboratory studies mechanisms underlying cell survival and migration during embryogenesis and disease. We are particularly interested in embryonic signaling pathways that are re-activated in tumors to promote cancer metastasis. An excellent model of cell migration during development is the neural crest, a multipotent cell population that migrates extensively in the vertebrate embryo to generate a variety of cell types, including pigment cells, neurons, glia and elements of the craniofacial skeleton. Neural crest progenitors are initially generated in the neuroepithelium of the neural tube, so they must first undergo an epithelial-mesenchymal transition (EMT) to form premigratory neural crest cells. These cells then divide and navigate through a number of embryonic tissues that secrete potential pro-apoptotic signals, before arriving at their final destination to differentiate. Thus, neural crest cells have evolved mechanisms to coordinate a number of cellular processes that involve regulation of cell survival, proliferation and migration, as well as modifications of cell-cell adhesion that involve dynamic interactions with the extracellular matrix. Disrupting these processes during human development causes a number of congenital diseases (neurocristopathies), and cancers, such as melanoma and neuroblastoma. Importantly, recent studies have shown that ‘re-activation’ of neural crest transcription factors in primary tumors promotes tumor invasiveness and metastasis.

To study neural crest migration and metastasis, we use the zebrafish model because the optically clear embryos and adult pigment mutants allow fluorescently labeled cells and tumors to be monitored using real-time imaging techniques. In addition, the molecular pathways underlying mammalian embryonic development are highly conserved in zebrafish, and a number of zebrafish models of human diseases are now established, including neural crest-derived cancers. Also, cell transplantation experiments can be performed in embryos and adult fish, allowing cell autonomous and non-autonomous mechanisms of cell migration and metastasis to be investigated. Thus, the attributes of the zebrafish system provide a unique opportunity to determine how developmental mechanisms that control cell migration during development are subverted in pediatric diseases and cancer metastasis. Current projects are:

1. Identify genes that function downstream of Foxd3 that regulate neural crest migration and survival. Foxd3 is a transcription factor essential for stem cell survival and neural crest migration, but the targets of Foxd3 are unknown. This project aims to identify the Foxd3 targets using both genetic and biochemical analyses in zebrafish and human cell culture.
2. Analysis of new neural crest mutants in zebrafish. We have isolated a number of recessive ENU-induced mutants with different neural crest migration, differentiation or survival phenotypes. The aim of this project is to clone the genes affected in these mutants and determine the molecular mechanism(s) underlying the migration phenotypes.
3. Generate metastasis models in zebrafish. Metastasis results from a multi-step process requiring the acquisition and selection of multiple genetic and epigenetic lesions within the unstable cancer genome. The aim of this project is to generate zebrafish metastasis models of neural crest-derived tumors, such as melanoma, neuroblastoma and schwannoma using genetic approaches with established mutant and transgenic lines.

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1. Smolen GA, Schott BJ, Stewart RA, Diederichs S, Muir B, Provencher HL, Look AT, Sgroi DC, Peterson RT, Haber DA. (2007). A Rap GTPase interactor, RADIL, mediates migration of neural crest precursors. Genes Dev. 21(17): 2131-6.
2. Stewart, RA., Arduini, BL., Berghmans, S., George, RE., Kanki, JP., Henion, PD and Look, AT. (2006). Zebrafish foxd3 is selectively required for neural crest sublineage determination, migration and survival. Dev. Biology 292: 174-188
3. Berghmans, S., Jette, C., Langenau, D., Hsu, K., Stewart, RA., Look, A.T., and Kanki, J.P. (2005). Making Waves in Cancer Research: New Models in the Zebrafish. Biotechniques 39:227-37.
4. Stewart,, RA., Look, AT., Kanki, JP. and Henion, PD. (2004). Development of the Peripheral Sympathetic Nervous System in Zebrafish. Zebrafish, 2nd Edition. Methods in Cell Biol. Vol. 76.

Figure:

Zebrafish neural crest-derived tumor.

Research Keywords:
Cancer, Metastasis, Zebrafish, Migration, Neural Crest