Effect of a novel anti-PD-1-proIL-2 bifunctional fusion protein on potent anti-tumor activity via PD-1 checkpoint inhibition and conditional IL-2R agonism.

Abstract

e14697 Background: HD IL-2 was approved by FDA for metastatic melanoma (mM) and renal cell carcinoma (mRCC) but the treatment is associated with severe toxicities. PD-1 blockade has improved the overall survival, but only in 20-30% of cancer patients and many of them experience frequent relapses. Interestingly, HD IL-2 therapy displayed durable anti-tumor activity in mM and mRCC patients who progressed on anti-PD-1. Furthermore, combination therapy of IL-2 and pembrolizumab in mRCC has shown durable 70% response rate, while the ORR of monotherapy is 20% and 33% for IL-2 and pembrolizumab, respectively. Thus, combining IL-2 receptor activation and PD-1 blockade may represent a promising strategy in the post PD-1 era to overcome the resistance and improve the clinical efficacy. PTX-912 is a novel bifunctional PD-1-proIL-2v fusion protein designed to simultaneously harness PD-1 blockade and PD-1-cis directed IL-2R agonism conditionally in TME without the peripheral toxicities associated with IL-2. Methods: The biological functions were demonstrated in human PBMC assays. Anti-tumor efficacy and biomarker studies were evaluated in mouse / human PBMC xenograft models. Tox studies were performed in NHP. Results: PTX-912 shows dose-dependent inhibition of PD-1 pathway measured by GM-CSF and IFNgamma production in an MLR assay. Protease activated PTX-912, but not the intact drug, stimulates the phosphorylation of STAT5 of NK and T cells, the proliferation of CD8 T cells as well as the cytokine production in human whole blood. The potency of pSTAT5 by protease activated product is enhanced by > 10 folds on PD-1+ T cells than T cells without PD-1. When tested in mouse tumor models resistant to PD-1 blockade, PTX-912 demonstrated high potency of tumor inhibition at as low as 0.1 mg/kg dose. In contrast, non-targeted proIL-2v at molar equivalent or higher dose showed minimal antitumor effect in either monotherapy or combination with anti-PD-1. Analysis of PTX-912 treated mice showed increased tumor infiltrating CD4+ and CD8+ T cells, including PD-1+Tcf-1+ and PD-1+ IL-18Ra+TIM3- CD8+ T cells, referred to “stem-like” progenitor effector cells and “better” effector cells, respectively. Activation of the IL-2v in PTX-912 was observed in mouse tumor tissues but not in the plasma. In monkey GLP-compliant 4-week repeat-dose toxicity study, PTX-912 demonstrated excellent safety profiles without overt irAEs that are characteristic of IL-2. Conclusions: Our preclinical data demonstrated that PTX-912 effectively stimulated the expansion and reinvigoration of antigen specific T cells in the tumor tissue resulting in strong anti-tumor efficacy while it did not cause significant peripheral toxicity. Phase 1 clinical trial of PD-1-proIL-2v is planned to start in early 2024 to evaluate the safety, pharmacokinetics and anti-tumor activity in patients with advanced solid tumors.