Cancers may be treated more effectively with Y-traps, a new class of immunotherapeutic agents that can act against cancers that are resistant to current treatments with immune checkpoint inhibitors.
- A new class of immunotherapeutic agents has been invented.
- These agents are called Y-traps as they trap Y-shaped antibodies.
- Y-traps can unleash agents of the immune system to treat cancers that have become resistant to other treatments.
The research team finds that a major reason for the failure of immune checkpoint inhibitors is the ability of tumors to produce transforming growth factor-B (TGFB). TGFB plays a key role in immune regulation and development of immunosuppressive regulatory T cells (Tregs). Using Insilico Medicine software, the team found that TGFB pathway activation in various cancers is highly correlated with FOXP3, the signature of Tregs. Tumors are frequently infiltrated by Tregs, and this is strongly correlated with poor outcome in multiple cancer types.
Y-traps - the new class of immunotherapeutic agents
To address this challenge, the team invented Y-traps, a new class of bifunctional immunotherapeutic agents consisting of a targeting antibody (shaped like a "Y"), fused to a "trap" that disables an immunosuppressive molecule. To sequester TGFB, they engineered a trap based on the natural receptor to TGFB. They created two different types of Y-traps: one consisting of a CTLA-4 antibody fused to a TGFB trap, and another consisting of a PD-L1 antibody fused to a TGFB trap.
They used the CTLA4-targeted Y-trap to specifically turn off and delete Tregs. "This Y-trap not only disables CTLA-4 function, but disrupts the TGFB feedback loop that is necessary for induction and maintenance of Tregs in the tumor," says Atul Bedi, M.D., associate professor at Johns Hopkins University School of Medicine and senior author of the study.
While the clinically-used CTLA-4 antibody, ipilimumab, could not decrease Tregs in these tumors, the CTLA4-targeted Y-trap was strikingly effective at reducing Tregs and activating antitumor immunity. Most significantly, the Y-trap was remarkably effective at inhibiting the growth and spread of tumors that were unresponsive to treatment with ipilimumab and pembrolizumab, a PD-1 antibody used in the clinic.
What the Y-traps offer to oncology
Bedi and colleagues demonstrated that the PD-L1 targeted Y-Trap is significantly more effective in inhibiting tumor growth compared to clinically-used PD-L1 antibodies, atezolizumab and avelumab. Moreover, the PD-L1-targeted Y-trap was able to curtail the growth of tumors that do not respond to PD-L1 or PD-1 antibodies.
"Since these mechanisms of immune dysfunction are shared across many types of cancer, the Y-trap approach could have broad impact for improving cancer immunotherapy," says Bedi.
"This approach appears to be an innovative strategy, and an exciting technical accomplishment to target multiple suppressive mechanisms in the tumor microenvironment," says Robert Ferris, MD, Ph.D, professor of oncology at the University of Pittsburgh, who was not connected with the study. "I look forward to seeing its translation into the clinic."
Bedi envisions using Y-traps not only for treatment of advanced, metastatic disease, but also in the neoadjuvant setting to elicit a vaccine effect, that is, giving them to patients before surgery to prevent recurrence of the disease.
References:
- Rajani Ravi, Kimberly A. Noonan et al. Bifunctional Immune Checkpoint-targeted Antibody-ligand Traps that Simultaneously Disable TGFβ Enhance The Efficacy of cancer Immunotherapy, Nature Communications doi:10.1038/s41467-017-02696-6
Source-Eurekalert