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  1. SKP2 inactivation suppresses prostate tumorigenesis by mediating JARID1B ubiquitination. Lu W, Liu S, Li B, Xie Y, Adhiambo C, Yang Q, Ballard BR, Nakayama KI, Matusik RJ, Chen Z (2015) Oncotarget 6(2): 771-88
    › Primary publication · 25596733 (PubMed) · PMC4359254 (PubMed Central)
  2. Inhibition of NF-kappa B signaling restores responsiveness of castrate-resistant prostate cancer cells to anti-androgen treatment by decreasing androgen receptor-variant expression. Jin R, Yamashita H, Yu X, Wang J, Franco OE, Wang Y, Hayward SW, Matusik RJ (2015) Oncogene 34(28): 3700-10
    › Primary publication · 25220414 (PubMed) · PMC4362792 (PubMed Central)
  3. SOX2 expression in the developing, adult, as well as, diseased prostate. Yu X, Cates JM, Morrissey C, You C, Grabowska MM, Zhang J, DeGraff DJ, Strand DW, Franco OE, Lin-Tsai O, Hayward SW, Matusik RJ (2014) Prostate Cancer Prostatic Dis 17(4): 301-9
    › Primary publication · 25091041 (PubMed) · PMC4227931 (PubMed Central)
  4. Slug regulates E-cadherin repression via p19Arf in prostate tumorigenesis. Xie Y, Liu S, Lu W, Yang Q, Williams KD, Binhazim AA, Carver BS, Matusik RJ, Chen Z (2014) Mol Oncol 8(7): 1355-64
    › Primary publication · 24910389 (PubMed) · PMC4198473 (PubMed Central)
  5. Skp2 regulates androgen receptor through ubiquitin-mediated degradation independent of Akt/mTOR pathways in prostate cancer. Li B, Lu W, Yang Q, Yu X, Matusik RJ, Chen Z (2014) Prostate 74(4): 421-32
    › Primary publication · 24347472 (PubMed) · PMC4062570 (PubMed Central)
  6. NF-κB gene signature predicts prostate cancer progression. Jin R, Yi Y, Yull FE, Blackwell TS, Clark PE, Koyama T, Smith JA, Matusik RJ (2014) Cancer Res 74(10): 2763-72
    › Primary publication · 24686169 (PubMed) · PMC4024337 (PubMed Central)
  7. NFI transcription factors interact with FOXA1 to regulate prostate-specific gene expression. Grabowska MM, Elliott AD, DeGraff DJ, Anderson PD, Anumanthan G, Yamashita H, Sun Q, Friedman DB, Hachey DL, Yu X, Sheehan JH, Ahn JM, Raj GV, Piston DW, Gronostajski RM, Matusik RJ (2014) Mol Endocrinol 28(6): 949-64
    › Primary publication · 24801505 (PubMed) · PMC4042066 (PubMed Central)
  8. Mouse models of prostate cancer: picking the best model for the question. Grabowska MM, DeGraff DJ, Yu X, Jin RJ, Chen Z, Borowsky AD, Matusik RJ (2014) Cancer Metastasis Rev 33(2-3): 377-97
    › Primary publication · 24452759 (PubMed) · PMC4108581 (PubMed Central)
  9. FOXA1 deletion in luminal epithelium causes prostatic hyperplasia and alteration of differentiated phenotype. DeGraff DJ, Grabowska MM, Case TC, Yu X, Herrick MK, Hayward WJ, Strand DW, Cates JM, Hayward SW, Gao N, Walter MA, Buttyan R, Yi Y, Kaestner KH, Matusik RJ (2014) Lab Invest 94(7): 726-39
    › Primary publication · 24840332 (PubMed) · PMC4451837 (PubMed Central)
  10. Activation of Wnt/β-catenin signaling in a subpopulation of murine prostate luminal epithelial cells induces high grade prostate intraepithelial neoplasia. Valkenburg KC, Yu X, De Marzo AM, Spiering TJ, Matusik RJ, Williams BO (2014) Prostate 74(15): 1506-20
    › Primary publication · 25175604 (PubMed) · PMC4175140 (PubMed Central)