Spermatogenesis is a complex series of processes that involves (1) the maintenance of a renewable pool of diploid stem cells within a niche, (2) the mitotic expansion of a subpopulation of stem cells committed to the spermatogenic pathway, and (3) the differentiation of diploid cells into highly specialized, haploid spermatozoa through meiotic and post-meiotic cellular transformations. Drosophila melanogaster is a desirable model for studying spermatogenesis, as similarities exist between mammalian and fly spermatogenesis. Like mammals, flies maintain a spermatogenic stem cell niche; the steps involved in mammalian spermatogenesis are mimicked in flies, with the main difference being that fly sperm develop within cysts rather than an epithelial cell layer. Here, we report a reliable robust system for culturing whole testes and individual spermatogenic cysts obtained from mid- to late-pupal stages of Drosophila pseudoobscura. D. pseudoobscura testes can be easily distinguished in later pupal stages because of their intense red pigmentation and are easily handled because of their simple ellipsoidal morphology. Cultured cysts are comparable in length to cysts obtained from adult flies, and motility is consistently achieved in vitro. This system not only offers a method for dissecting the mechanisms involved in meiotic and post-meiotic cellular transformations, but also can be used for the study of signaling during spermatogenesis.
The dismal prognosis of patients diagnosed with metastatic cancer points to our limited arsenal of effective anticancer and anti-metastasis therapies. Chemotherapy, radiation and targeted therapies are largely ineffective against metastatic cancer, resulting in the deaths of more than half million cancer patients each year. Oncogenic EGFR/HER2/K-RAS/B-RAF pathway activation is a major menace that drives aggressive cancer cell dissemination, tumor invasion and systemic metastasis. Therefore, finding novel approaches and new drug targets to inhibit hyperactive EGFR/HER2/K-RAS/B-RAF signaling is an urgent goal and major challenge in the struggle against metastatic diseases. Guided by the insights and principles learned from the evolutionarily conserved RAS signal transduction cascade in Drosophila, we targeted the most downstream signaling module in the EGFR/HER2/K-RAS/B-RAF signaling pathway, the SIAH-dependent proteolytic machinery. SIAHs are the human homologs of Seven-In-Absentia (SINA), a highly conserved RING E3 ligase, an essential downstream signaling module and a critical “gatekeeper” required for proper EGFR/HER2/K-RAS/B-RAF signal transduction. We found that inhibiting SIAH function is highly effective in halting cancer cell dissemination, altering cell adhesion and motility, inhibiting tumor invasion and cancer metastasis of human cancer cells. Importantly, our anti-SIAH-based anticancer strategy is effective in reducing tumor burdens in the late-stage and aggressive tumor growth and metastasis in the preclinical models. These exciting results and new findings demonstrate that SIAH is a highly attractive, mechanistically logical and great therapeutic target for developing novel anti-ERBB/K-RAS/B-RAF and anticancer therapies against invasive and metastatic cancer. Through our work, SIAH has emerged as a new, potent and promising drug target against metastatic diseases. As a highly evolutionarily conserved E3 ligase and the most downstream “gatekeeper” of EGFR/HER2/K-RAS/B-RAF signaling pathway, SIAH is ideally and logically positioned to become a next-generation anticancer and anti-metastasis drug target in the clinic. By simultaneously attacking the tumor-driving and metastasis-promoting ERBB/K-RAS signaling pathway using multi-pronged synergistic inhibitions at upstream (EGFR/HER2 membrane receptors), midstream (K-RAS/B-RAF/MEK/mTOR) and downstream (SIAH E3 ligase) signaling modules, we aim to make a difference and save lives from the deadliest forms of human metastatic cancers in the future. Citation Format: Amy H. Tang, Yang Liao, Minglei Bian, Vasilena Zheleva, Zena M. Urban, Monicah M. Njogu, Xiaofei Gao, Oscar A. Gonzalez, Justin J. Odanga, Bruce E. Knudsen, Roger R. Perry, Richard A. Hoefer, Thomas C. Smyrk, Gloria M. Petersen. Make a difference and save lives in human metastatic cancer by attacking the Achilles heel in the oncogenic ERBB/K-RAS signaling pathway. [abstract]. In: Proceedings of the AACR Special Conference on Tumor Invasion and Metastasis; Jan 20-23, 2013; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2013;73(3 Suppl):Abstract nr A88.
Oncogenic EGFR/HER2/K-RAS activation is known to reduce focal adhesion and cell attachment, alter cell junction, and increase cell motility during normal tissue development as well as tumor invasion and cancer metastasis. Deciphering the mechanisms that promote cancer cell dissemination and metastasis in response to oncogenic ERBB/K-RAS “pathway” activation and finding novel targets for inhibiting invasion and metastasis remains an important goal in cancer biology. SIAH2, the human homologue of a highly conserved RING-domain E3 ubiquitin ligase SINA that is the most downstream signal modulator identified in Drosophila RAS signaling pathway, is critically required for proper mammalian ERBB/K-RAS signal transduction. SIAH2 insufficiency was shown to impede oncogenic K-RAS signal transduction, thereby obstructing K-RAS-driven tumorigenesis and metastasis in the preclinical models. However, the exact molecular mechanism of SIAH2 function downstream of the oncogenic ERBB/K-RAS activation remains to be characterized in human cancer cells. In this study, we use immunoprecipitation to isolate novel SIAH2-interacting proteins from multiple highly aggressive human cancer cells with oncogenic K-RAS hyperactivation. Three LIM-domain focal adhesion proteins (Trip6/FHL2/LPXN) were identified by Mass Spectrometry analysis, and their interactions with SIAH2 were verified biochemically by bi-directional co-immunoprecipitation (co-IP). Trip6/FHL2/LPXN has been reported to play important roles in cell focal adhesion formation and cell migration. We demonstrated that SIAH2 biochemically interacts with, ubiquitinates and thereby causes the degradation of these LIM domain proteins, demonstrating that TRIP6, FHL2 and LPXN are bona fide SIAH2 substrates in vivo. Our immunofluorescence (IF) staining results showed that SIAH2-deficiency disrupts Trip6/FHL2/LPXN localization at the focal adhesion site, results in defects in focal adhesion, cell junction, cell attachment and cell motility. Conversely, ectopic expression of TRIP6, FHL2 and LPXN can partially rescue SIAH2-deficient cancer cells from the pronounced defects in cell motility, cell death and tumor growth. The discovery that SIAH2 directly modulates focal adhesion may provide a novel molecular mechanism to explain the well-documented increases in cancer cell dissemination, tumor invasion and metastasis in response to ERBB/K-RAS pathway activation in human cancer cells. We may have uncovered a novel function of SIAH in modulating focal adhesion and cell junction in human cancer cells. By circumventing EGFR/HER2/K-RAS signaling pathway at its most downstream signaling module, we hope to validate and develop novel anti-SIAH-based anti-K-RAS anticancer therapies against oncogenic K-RAS-driven tumors in the future. Citation Format: Ming Bian, Yang Liao, Rebecca L. Schmidt, Monicah M. Njogu, Rie Takahashi, Zandra E. Walton, Amy H. Tang. Inhibiting SIAH2 E3 ligase function disrupts focal adhesion and cell junction, inhibits cell mobility and attachment, and blocks tumor invasion and metastasis in oncogenic K-Ras-driven tumors. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 1965. doi:10.1158/1538-7445.AM2014-1965
Introduction: The RAS signaling pathway is an important growth-promoting pathway that controls cell proliferation and survival in multicellular organisms. During oncogenesis, activation of EGFR/HER2/K-RAS signaling pathway reduces focal adhesion, increases cell motility, promote tumorigenesis and accelerate tumor invasion and metastasis. SIAH2, which is the human homologue of a highly conserved family of RING-domain E3 ubiquitin ligase, is a key downstream signaling component which is essential for RAS signal transduction. We noticed that SIAH2 can regulate cell migration, tumorigenesis and metastasis by unknown mechanisms. Methods: Using HIV-based lentiviral system, we introduced an anti-SIAH molecule, the proteolysis-deficient mutant form of SIAH2 (SIAH2PD), into multiple types of human cancer cell lines. The changes of cell morphology, focal adhesion and adherens junction were examined by immunofluorescence (IF) staining. Images were captured on day 3 post infection experiments to show the changes in cell focal adhesion/junction. Using lentiviral system, we introduced exogenous LIM-domain proteins into human cancer cell lines which already expressed SIAH2PD, and then check the cell focal adhesion rescue by immunofluorescence staining. Results: We identified and validated three proteins that interact with SIAH2, contain LIM domains, and regulate focal adhesion and cell attachment. Through in vitro and in vivo experiments, we show that SIAH2 binds, ubiquitinates and degrades thyroid receptor-interacting protein 6 (TRIP6), Four-and-a-half LIM domain protein 2 (FHL2) and Leupaxin (LPXN), indicating that these evolutionarily conserved LIM-domain proteins are bona fide SIAH2 substrates and their double zinc finger motif might serve as a degron signal for SIAH2 E3 ligase. Our staining results showed that SIAH-deficiency would disrupt Trip6/FHL2/LPXN localization at the focal adhesion site, and inhibit cell motility. By introducing exogenous Trip6/FHL2/LPXN proteins into cancer cells, the focal adhesion deficiency and cell death caused by SIAHPD can be rescued, and the ability of cell migration and tumor initiation can be restored. Conclusions: We show that in cancer cells, SIAH2 antagonizes TRIP6, FHL2 and LPXN in modulating focal adhesions and cell motility. This interaction could be important in cell dissemination, invasion and metastasis. The suppression of cell motility and tumorigenesis in response to SIAH-deficiency could provide a new molecular mechanism to reveal the importance of RAS/SIAH signaling pathway in cancer cells. By circumventing this essential cell growth signaling pathway in cancer, we hope to develop novel anti-SIAH-based therapeutic drugs, which may help to inhibit cancer cell dissemination, invasion and metastasis. Citation Format: Minglei Bian, Yang Liao, Monicah Njogu, Rebecca Schmidt, Rie Takahashi, Zandra Walton, Amy H. Tang. SIAH2 E3 ligase targets LIM-domain proteins for degradation to modulate focal adhesion and cell motility. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 5049.
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