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Robert Matusik, Ph.D.

In North America, one in ten men is diagnosed with prostate cancer. Prostate cancer starts as an androgen dependent disease that progresses to an androgen independent cancer. The androgen independent tumors fail therapy. One of the major impediments to prostate cancer research is that no appropriate animal model system adequately displays the recognized stages of human prostatic disease. Further, no new therapeutic approaches have been developed after current therapy fails. Our laboratory has developed the probasin (PB) gene as a model system for androgen action, to establish new transgenic animal models for prostate cancer, and to test new therapeutic approaches for treatment.

The androgen receptor (AR) can function through similar cis-acting DNA elements similar to the palindromic glucocorticoid response element; however, recent data has shown that distinct AR elements (ARE) exist and function via cooperative interactions of multiple elements in the PB promoter. Further, since the PB promoter directs prostate specific expression in transgenic mice, it has become a model to dissect the key cis-acting DNA elements that control prostate-specific gene expression. Our laboratory has designed new PB promoters that target high levels of transgene expression to the prostate. These new promoters now serve to create new animal models for prostate cancer and to develop gene therapy vectors that will target a therapeutic gene(s) in the treatment of prostate cancer.

The PB promoter has been linked to oncogenes and growth factors to create new transgenic mouse models for prostate cancer. Transgenic mice carrying PB-oncogenes develop various stages of disease including prostatic precursor lesions that advance to an adenocarcinoma and then to high grade metastatic cancer. Gene expression profiles are being analyzed in these animal models to identify the key genes involved in tumor progression. By identifying the genes that are responsible for tumor progression, we can develop new targets for therapeutic intervention. .

 

Publications

PubMedID Citation
19281768 Li X, Wang Y, Sharif-Afshar AR, Uwamariya C, Yi A, Ishii K, Hayward SW, Matusik RJ, Bhowmick NA. Urothelial transdifferentiation to prostate epithelia is mediated by paracrine TGF-beta signaling. (2008) Differentiation 77: 95-102
18991257 Yu X, Wang Y, Jiang M, Bierie B, Roy-Burman P, Shen MM, Taketo MM, Wills M, Matusik RJ. Activation of beta-Catenin in mouse prostate causes HGPIN and continuous prostate growth after castration. () Prostate 69: 249-62
18721942 Anumanthan G, Makari JH, Honea L, Thomas JC, Wills ML, Bhowmick NA, Adams MC, Hayward SW, Matusik RJ, Brock JW, Pope JC. Directed differentiation of bone marrow derived mesenchymal stem cells into bladder urothelium. (2008) J Urol 180: 1778-83
18701501 Jin RJ, Lho Y, Connelly L, Wang Y, Yu X, Saint Jean L, Case TC, Ellwood-Yen K, Sawyers CL, Bhowmick NA, Blackwell TS, Yull FE, Matusik RJ. The nuclear factor-kappaB pathway controls the progression of prostate cancer to androgen-independent growth. () Cancer Res 68: 6762-9
18004726 Gupta A, Wang Y, Browne C, Kim S, Case T, Paul M, Wills ML, Matusik RJ. Neuroendocrine differentiation in the 12T-10 transgenic prostate mouse model mimics endocrine differentiation of pancreatic beta cells. () Prostate 68: 50-60

You can also view publications listed at PubMed.

VCSCB Faculty Investigators

Stacey S. Huppert
Assistant Professor
Patricia A. Labosky
Associate Professor
Mark A. Magnuson
Director


VCSCB Faculty Members

Scott Baldwin
Director & Professor
Aaron Bowman
Assistant Professor
Kevin C Ess
Assistant Professor
Guoqiang Gu
Assistant Professor
Antonis Hatzopoulos
Associate Professor
Scott Hiebert
Professor
Charles Hong
Assistant Professor
Robert Matusik
Professor
Douglas P. Mortlock
Assistant Professor
Lance Prince
Assistant Professor
Chris Wright
Professor
Sandra Zinkel
Assistant Professor