Tanmoy Mondal1,2, Gururaj N Shivange1,2, Rachisan Gt Tihagam2, Evan Lyerly1,2,3, Michael Battista1,2,3, Divpriya Talwar1,2,3, Roxanna Mosavian1,2,3, Karol Urbanek1,2, Narmeen S Rashid4, J Chuck Harrell4, Paula D Bos4, Edward B Stelow5, M Sharon Stack6, Sanchita Bhatnagar2,7, Jogender Tushir-Singh1,2,7,8. 1. Laboratory of Novel Biologics, University of Virginia, Charlottesville, VA, USA. 2. Department of Biochemistry and Molecular Genetics, University of Virginia, Charlottesville, VA, USA. 3. Undergraduate Research Program, University of Virginia, Charlottesville, VA, USA. 4. Department of Pathology, Massey Cancer Center, VCU, Richmond, VA, USA. 5. Department of Pathology, University of Virginia, Charlottesville, VA, USA. 6. Harper Cancer Research Institute, University of Notre Dame, Notre Dame, IN, USA. 7. University of Virginia Cancer Center and Medical School, Charlottesville, VA, USA. 8. DoD Ovarian Cancer Academy Early Career Investigator, Charlottesville, VA, USA.
Abstract
Lack of effective immune infiltration represents a significant barrier to immunotherapy in solid tumors. Thus, solid tumor-enriched death receptor-5 (DR5) activating antibodies, which generates tumor debulking by extrinsic apoptotic cytotoxicity, remains a crucial alternate therapeutic strategy. Over past few decades, many DR5 antibodies moved to clinical trials after successfully controlling tumors in immunodeficient tumor xenografts. However, DR5 antibodies failed to significantly improve survival in phase-II trials, leading in efforts to generate second generation of DR5 agonists to supersize apoptotic cytotoxicity in tumors. Here we have discovered that clinical DR5 antibodies activate an unexpected immunosuppressive PD-L1 stabilization pathway, which potentially had contributed to their limited success in clinics. The DR5 agonist stimulated caspase-8 signaling not only activates ROCK1 but also undermines proteasome function, both of which contributes to increased PD-L1 stability on tumor cell surface. Targeting DR5-ROCK1-PD-L1 axis markedly increases immune effector T-cell function, promotes tumor regression, and improves overall survival in animal models. These insights have identified a potential clinically viable combinatorial strategy to revive solid cancer immunotherapy using death receptor agonism.
Lack of effective immune infiltration represents a significant barrier to immunotherapy in solid tumors. Thus, solid n>an class="Disease">tumor-enriched death receptor-5 (DR5) activating antibodies, which generates tumor debulking by extrinsic apoptotic cytotoxicity, remains a crucial alternate therapeutic strategy. Over past few decades, many DR5 antibodies moved to clinical trials after successfully controlling tumors in immunodeficient tumor xenografts. However, DR5 antibodies failed to significantly improve survival in phase-II trials, leading in efforts to generate second generation of DR5 agonists to supersize apoptotic cytotoxicity in tumors. Here we have discovered that clinical DR5 antibodies activate an unexpected immunosuppressive PD-L1 stabilization pathway, which potentially had contributed to their limited success in clinics. The DR5 agonist stimulated caspase-8 signaling not only activates ROCK1 but also undermines proteasome function, both of which contributes to increased PD-L1 stability on tumor cell surface. Targeting DR5-ROCK1-PD-L1 axis markedly increases immune effector T-cell function, promotes tumor regression, and improves overall survival in animal models. These insights have identified a potential clinically viable combinatorial strategy to revive solid cancer immunotherapy using death receptor agonism.
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