BackgroundMetastatic breast cancer exhibits diverse and rapidly evolving intra- and inter-tumor heterogeneity. Patients with similar clinical presentations often display distinct tumor responses to standard of care (SOC) therapies. Genome landscape studies indicate that EGFR/HER2/RAS “pathway” activation is highly prevalent in malignant breast cancers. The identification of therapy-responsive and prognostic biomarkers is paramount important to stratify patients and guide therapies in clinical oncology and personalized medicine.MethodsIn this study, we analyzed matched pairs of tumor specimens collected from 182 patients who received neoadjuvant systemic therapies (NST). Statistical analyses were conducted to determine whether EGFR/HER2/RAS pathway biomarkers and clinicopathological predictors, alone and in combination, are prognostic in breast cancer.FindingsSIAH and EGFR outperform ER, PR, HER2 and Ki67 as two logical, sensitive and prognostic biomarkers in metastatic breast cancer. We found that increased SIAH and EGFR expression correlated with advanced pathological stage and aggressive molecular subtypes. Both SIAH expression post-NST and NST-induced changes in EGFR expression in invasive mammary tumors are associated with tumor regression and increased survival, whereas ER, PR, and HER2 were not. These results suggest that SIAH and EGFR are two prognostic biomarkers in breast cancer with lymph node metastases.InterpretationThe discovery of incorporating tumor heterogeneity-independent and growth-sensitive RAS pathway biomarkers, SIAH and EGFR, whose altered expression can be used to estimate therapeutic efficacy, detect emergence of resistant clones, forecast tumor regression, differentiate among partial responders, and predict patient survival in the neoadjuvant setting, has a clear clinical implication in personalizing breast cancer therapy.FundingThis work was supported by the (A.H. Tang); (MF14S-009-LS to A.H. Tang), and (CA140550 to A.H. Tang).
Oncogenic K-RAS activation is a major menace that drives aggressive tumor progression and metastasis in 30% of all human cancer. Currently, there are no effective therapies to treat stage III and IV metastatic human cancers with oncogenic K-RAS hyperactivation that often confer drug resistance, aggressive tumor growth, systemic metastasis, and poor clinical outcome. Therefore, finding novel approaches and new drug targets to inhibit oncogenic K-RAS pathway activation is an urgent goal and the major challenge in cancer therapy and anti-K-RAS-based drug development. Instead of targeting an upstream signaling module such as EGFR/HER2/K-RAS/B-RAF, we targeted the most downstream signaling module in the oncogenic K-RAS signaling pathway called the SIAH-dependent proteolytic machinery. SIAHs are the human homologs of Seven-In-Absentia (SINA), an evolutionarily conserved RING E3 ligase - the most downstream signaling module and a critical “gatekeeper” required for proper RAS signal transduction. Guided by the insights and fundamental principles learned from the Drosophila RAS signal transduction, we conducted preclinical studies to dissect SIAH function in promoting the oncogenic K-RAS-driven tumorigenesis and metastasis in human cancer. We found that (1) SIAH is a new biomarker reflective of oncogenic K-RAS activation in human cancer, and (2) SIAH loss-of-function is highly effective to block tumorigenesis and metastasis against the well-established, end-stage and metastatic pancreatic cancer and triple negative breast cancer (TNBC). These findings demonstrate that SIAH is an attractive and logical new therapeutic target for developing novel and effective anti-K-RAS and anticancer therapy against metastatic human cancer. Through our work, SIAH has emerged as a promising new drug target against oncogenic K-RAS hyperactivation in metastatic human cancer cells. Using anti-SIAH molecules to block oncogenic K-RAS signaling in human cancer is an excellent example of science going “from the bench (basic research in fruit flies) to the bedside (preclinical studies and ultimately clinical trials)”. As a highly evolutionarily conserved E3 ligase that is the most downstream and the most conserved “signaling gatekeeper” in the oncogenic K-RAS signaling network, SIAH is uniquely and strategically positioned to become a great and logical anti-K-RAS drug target. Our preclinical studies have demonstrated that “SIAH-dependent proteolysis” is indeed an Achilles' heel in metastatic human cancer cells. Knowledge gained from our preclinical study has promising translational values. Anti-SIAH-based small molecule inhibitors are likely to aid in expanding our limited arsenal of novel anti-K-RAS-based anticancer therapies. By attacking the oncogenic K-RAS 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 in parallel, we will be in a position to control the late-stage, relapsed and metastatic human cancers by shutting down the hyperactivated K-RAS signaling transduction cascades in cancer cells in the future. Citation Format: Minglei Bian, Yang Liao, Vasilena Zheleva, Zena Urban, Monicah Njogu, Justin J. Odanga, Andrew J. Isbell, Roger R. Perry, Richard A. Hoefer, Thomas C. Smyrk, Gloria M. Petersen, Amy H. Tang. Attacking the most downstream “gatekeeper,” the SIAH-dependent proteolytic machinery, in the oncogenic ERBB/K-RAS signaling pathway to block tumorigenesis and control metastasis in human cancer. [abstract]. In: Proceedings of the AACR Special Conference on RAS Oncogenes: From Biology to Therapy; Feb 24-27, 2014; Lake Buena Vista, FL. Philadelphia (PA): AACR; Mol Cancer Res 2014;12(12 Suppl):Abstract nr A26. doi: 10.1158/1557-3125.RASONC14-A26
Hyperactive ERBB/K-RAS signaling is a major menace that drives aggressive tumor growth and metastasis in human cancer. Currently, there are no effective ways to treat late-stage and relapsed human cancers that have oncogenic ERBB/K-RAS mutations that often confer drug resistance, aggressive tumor growth, systemic metastasis, and poor clinical outcome. Therefore, finding novel approaches and new drug targets to inhibit oncogenic ERBB/K-RAS activation is an urgent goal and the major challenge in cancer therapy and treatment. Instead of targeting an upstream signaling module such as EGFR/HER2/KRAS/B-RAF, we targeted the most downstream signaling module in the EGFR/HER2/K-RAS pathway called the SIAH-dependent proteolytic machinery. SIAHs are the human homologs of Seven-In-Absentia (SINA), an evolutionarily conserved RING E3 ligase, an essential downstream signaling module and a critical “gatekeeper” required for proper EGFR/HER2/K-RAS/B-RAF signal transduction. Guided by the insights and fundamental principles learned from the Drosophila RAS signaling pathway, we conducted preclinical studies to dissect SIAH function in the context of ERBB/K-RAS-mediated tumorigenesis and metastasis in human cancer cells and human cancer biospecimens. We found that (1) SIAH is a great prognostic and predictive biomarker for human cancer, and (2) inhibiting SIAH function is highly effective to block tumorigenesis and metastasis against the well-established, late-stage and metastatic pancreatic cancer and triple negative breast cancer (TNBC). These findings demonstrate that SIAH is an attractive and logical new therapeutic target for novel anti-ERBB/oncogenic K-RAS and anticancer therapy in human cancer. Through our work, SIAH has emerged as a new and effective drug target against oncogenic ERBB/K-RAS activation in human cancer cells. Using anti-SIAH molecules to block K-RAS signaling in human cancer is an excellent example of science going “from the bench (basic research in fruit flies) to the bedside (preclinical studies and ultimately clinical trials)”. As a highly evolutionarily conserved E3 ligase and the most downstream “gatekeeper” of EGFR/HER2/K-RAS/B-RAF signaling pathway, SIAH is uniquely and logically positioned to become a next-generation anti-ERBB/anti-K-RAS drug target. Our preclinical studies have demonstrated that “SIAH-dependent proteolysis” is indeed an Achilles' heel in human cancer. Knowledge gained from our study has great promise and immediate translational values. Anti-SIAH-based small molecule inhibitors may aid in expanding our arsenal of novel anticancer therapies. By attacking the oncogenic ERBB/K-RAS/B-RAF 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 in parallel, we will be in a position to control the late-stage, relapsed and metastatic human cancers. If successful, we hope to develop anti-SIAH-based therapy and translate our findings to the cancer clinics to treat cancer patients with metastatic diseases in the near future. Citation Format: Minglei Bian, Yang Liao, Vasilena Zheleva, Xiaofei Gao, Zena M. Urban, Monicah M. Njogu, Justin J. Odanga, Andrew J. Isbell, Rebecca L. Schmidt, Rie Takahashi, Roger R. Perry, Richard A. Hoefer, Thomas C. Smyrk, Gloria M. Petersen, Amy H. Tang. Attacking the most downstream “gatekeeper” signaling module in the oncogenic ERBB/K-RAS signaling pathway to block tumorigenesis and metastasis in human cancer. [abstract]. In: Proceedings of the Third AACR International Conference on Frontiers in Basic Cancer Research; Sep 18-22, 2013; National Harbor, MD. Philadelphia (PA): AACR; Cancer Res 2013;73(19 Suppl):Abstract nr C62.
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