Increased cancer cell motility constitutes a root cause of end organ destruction and mortality, but its complex regulation represents a barrier to precision targeting. We use the unique characteristics of small molecules to probe and selectively modulate cell motility. By coupling efficient chemical synthesis routes to multiple upfront in parallel phenotypic screens, we identify that KBU2046 inhibits cell motility and cell invasion in vitro. Across three different murine models of human prostate and breast cancer, KBU2046 inhibits metastasis, decreases bone destruction, and prolongs survival at nanomolar blood concentrations after oral administration. Comprehensive molecular, cellular and systemic-level assays all support a high level of selectivity. KBU2046 binds chaperone heterocomplexes, selectively alters binding of client proteins that regulate motility, and lacks all the hallmarks of classical chaperone inhibitors, including toxicity. We identify a unique cell motility regulatory mechanism and synthesize a targeted therapeutic, providing a platform to pursue studies in humans.
Prostate cancer (PCa) is the most common form of cancer in American men. Mortality from PCa is caused by the movement of cancer cells from the primary organ to form metastatic tumors at distant sites. Heat shock protein 27 (HSP27) is known to increase human PCa cell invasion and its overexpression is associated with metastatic disease. The role of HSP27 in driving PCa cell movement from the prostate to distant metastatic sites is unknown. Increased HSP27 expression increased metastasis as well as primary tumor mass. In vitro studies further examined the mechanism of HSP27-induced metastatic behavior. HSP27 did not affect cell detachment, adhesion, or migration, but did increase cell invasion. Cell invasion was dependent upon matrix metalloproteinase 2 (MMP-2), whose expression was increased by HSP27. In vivo, HSP27 induced commensurate changes in MMP-2 expression in tumors. These findings demonstrate that HSP27 drives metastatic spread of cancer cells from the prostate to distant sites, does so across a continuum of expression levels, and identifies HSP27-driven increases in MMP-2 expression as functionally relevant. These findings add to prior studies demonstrating that HSP27 increases PCa cell motility, growth and survival. Together, they demonstrate that HSP27 plays an important role in PCa progression.
Prostate cancer (PCa) is the second leading cause of cancer death in the US. Death from PCa primarily results from metastasis. Mitogen-activated protein kinase kinase 4 (MAP2K4) is overexpressed in invasive PCa lesions in humans, and can be inhibited by small molecule therapeutics that demonstrate favorable activity in phase II studies. However, MAP2K4's role in regulating metastatic behavior is controversial and unknown. To investigate, we engineered human PCa cell lines which overexpress either wild type or constitutive active MAP2K4. Orthotopic implantation into mice demonstrated MAP2K4 increases formation of distant metastasis. Constitutive active MAP2K4, though not wild type, increases tumor size and circulating tumor cells in the blood and bone marrow. Complementary in vitro studies establish stable MAP2K4 overexpression promotes cell invasion, but does not affect cell growth or migration. MAP2K4 overexpression increases the expression of heat shock protein 27 (HSP27) protein and protease production, with the largest effect upon matrix metalloproteinase 2 (MMP-2), both in vitro and in mouse tumor samples. Further, MAP2K4-mediated increases in cell invasion are dependent upon heat shock protein 27 (HSP27) and MMP-2, but not upon MAP2K4's immediate downstream targets, p38 MAPK or JNK. We demonstrate that MAP2K4 increases human PCa metastasis, and prolonged over expression induces long term changes in cell signaling pathways leading to independence from p38 MAPK and JNK. These findings provide a mechanistic explanation for human studies linking increases in HSP27 and MMP-2 to progression to metastatic disease. MAP2K4 is validated as an important therapeutic target for inhibiting human PCa metastasis.
Epidemiological evidence, preclinical studies and prospective phase II studies in humans indicate that the isoflavone, genistein, will inhibit the conversion of human prostate cells to an invasive, and ultimately, a metastatic phenotype. Though promising, genistein exerts many additional effects that have the potential for future toxicity in humans. We therefore sought to discover a new drug with improved efficacy and most importantly, with high specificity. Starting from an isoflavone chemical scaffold, we employed a fragment-based chemical synthesis diversification approach, and coupled it to three in vitro screens: 1) cell invasion (efficacy), 2) cell growth inhibition (an indicator of general toxicity), and 3) several measures of estrogenic activity. From multiple synthesis/biological assay iterations we developed a refined structure-activity relationship map, thereby leading us to discover KBU2046. KBU2046 represents a new and chemically distinct class of bioactive compounds. It has greater anti-invasion efficacy than genistein, and more importantly, no cell toxicity or estrogenic activity. Extensive toxicity studies in mice were negative. At low nanomolar blood concentrations, KBU2046 will prevent orthotopically implanted human prostate cancer cells from forming metastasis in a dose-responsive fashion. In summary, we have successfully discovered and developed a compound that prevents progression to a metastatic phenotype for human prostate cancer. We are in the process of bringing KBU2046 into the clinic, with the goal of preventing death from the second most common cause of cancer related death in men. Citation Information: Cancer Prev Res 2010;3(12 Suppl):B58.
Prostate cancer (PCa) is the most commonly diagnosed form of cancer among American men, and the second leading cause of all cancer-related deaths. PCa death is caused by the process of metastasis. In order to metastasize, tumor cells must acquire a series of phenotypic alterations, collectively known as the metastatic cascade. We have demonstrated that the small heat-shock protein, HSP27, affects key early steps of the metastatic cascade, and therefore may be a regulator of human PCa metastasis. HSP27 protein expression increases during PCa progression. It is phosphorylated in response to signaling from transforming growth factor-β (TGF-β), which in turn increases matrix metalloproteinase 2 (MMP-2) and cell invasion in vitro. We now demonstrate that HSP27 does not affect human PCa cell adhesion, cell detachment or cell migration, all of which contribute to the composite function of cell invasion. We went on to show that proteolysis by MMPs is necessary for HSP27-driven cell invasion by demonstrating that it was abrogated Marimastat, a broad-spectrum MMP inhibitor. By orthotopically implanting HSP27 variant human PCa cell lines, we demonstrated that HSP27 increases metastasis in a murine model. We also found that HSP27 increased tumor size. HSP27 increases human PCa metastasis and tumor growth in vivo. These findings provide a mechanistic explanation for the poor prognosis associated with increased HSP27 expression in human prostate tissue. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 5331. doi:1538-7445.AM2012-5331
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