Abstract 2378: Differential exhaustion on cytokine release (DECREASE) by ERY974, a novel T-cell-redirecting antibody targeting glypican-3: A new type of T-cell exhaustion

Background: T cell-redirecting antibody (TRAB), which bispecifically binds to CD3 and tumor antigen, is a key player in next-generation cancer immunotherapy (CIT). Because TRAB can redirect T cells regardless of their TCR specificity, it is expected to be efficacious in immune checkpoint inhibitor-resistant tumors. The CD19-targeting bispecific T cell engager, blinatumomab, has been used for the treatment of blood cancers, and CEA-TCB and IMCgp100 have shown promising clinical efficacy in solid tumors as well. ERY974 is another promising TRAB targeting glypican-3 (GPC3) and a phase 1 study is in progress (Ishiguro et al., Sci Transl Med 2017). On the other hand, cytokine release syndrome (CRS) has been recognized as a common side effect of TRAB. Thus, mitigation of CRS is an urgent issue. Intra-patient step-up dosing regimens have been incorporated in clinical trials to reduce cytokine release, but the mechanism behind this phenomenon remains elusive. In this study, we pre-clinically explored the phenomenon and its mechanism by using ERY974. Method & Results: GPC3-expressing human cancer cells were incubated with human PBMCs and ERY974. The incubated PBMCs were harvested and mixed with newly prepared GPC3-expressing cancer cells and higher doses of ERY974. The pre-treated PBMCs showed reduced cytokine production compared to that without pre-treatment, while maintaining the same level of T cell-dependent cellular cytotoxicity (TDCC). Comprehensive gene expression analysis of the pre-treated PBMCs was also conducted. A murine cancer cell line expressing human GPC3 was established and implanted into immune competent mice. A mouse surrogate version of ERY974 (mERY974) was first administered at a low dose expected to elicit weak anti-tumor activity, and mice were then treated with a higher dose of mERY974. Anti-tumor activity was similar regardless of the pre-treatment, but plasma cytokine levels were shown to be reduced in the pre-treated mice upon administration of the higher dose of mERY974. Conclusion: Cytokine production following the high-dose ERY974 treatment was mitigated by the low-dose pre-treatment in vitro and in vivo. Cytotoxic activity did not decrease in this setting, thus demonstrating that the pre-treatment selectively suppressed only cytokine production. It is well known that repeated stimulation of TCR leads to T-cell exhaustion. The phenomenon we observed here can also be characterized as a sort of exhaustion, but is quite unconventional. Thus, we propose a new type of exhaustion and suggest calling it ‘Differential exhaustion on cytokine release (DECREASE)’. Management of CRS is critical for the clinical use of TRAB. A detailed analysis of the mechanism of DECREASE currently in progress, is expected to contribute to the development of desired dosing regimens for this new type of CIT agent. Citation Format: Mayumi Hoshino, Yuji Sano, Yasuko Kinoshita, Yumiko Azuma, Toshiaki Tsunenari, Yoko Kayukawa, Mizuho Noguchi, Takahiro Ishiguro, Shohei Kishishita, Noriaki Sawada, Mika Endo, Junichi Nezu. Differential exhaustion on cytokine release (DECREASE) by ERY974, a novel T-cell-redirecting antibody targeting glypican-3: A new type of T-cell exhaustion [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 2378.