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BackgroundImmune checkpoint blockade (ICB) is a clinically proven concept to treat cancer. Still, a majority of patients with cancer including those with poorly immune infiltrated ‘cold’ tumors are resistant to currently available ICB therapies. Cytotoxic T lymphocyte-associated antigen-4 (CTLA-4) is one of few clinically validated targets for ICB, but toxicities linked to efficacy in approved αCTLA-4 regimens have restricted their use and precluded full therapeutic dosing. At a mechanistic level, accumulating preclinical and clinical data indicate dual mechanisms for αCTLA-4; ICB and regulatory T cell (Treg) depletion are both thought to contribute efficacy and toxicity in available, systemic, αCTLA-4 regimens. Accordingly, strategies to deliver highly effective, yet safe αCTLA-4 therapies have been lacking. Here we assess and identify spatially restricted exposure to a novel strongly Treg-depleting, checkpoint-blocking, vectorized αCTLA-4, as a highly efficacious and potentially safe strategy to target CTLA-4.MethodsA novel human IgG1 CTLA-4 antibody (4-E03) was identified using function-first screening for monoclonal antibodies (mAbs) and targets associated with superior Treg-depleting activity. A tumor-selective oncolytic vaccinia vector was then engineered to encode this novel, strongly Treg-depleting, checkpoint-blocking, αCTLA-4 antibody or a matching surrogate antibody, and Granulocyte-macrophage colony-stimulating factor (GM-CSF) (VVGM-αCTLA-4).ResultsThe identified 4-E03 antibody showed significantly stronger Treg depletion, but equipotent checkpoint blockade, compared with clinically validated αCTLA-4 ipilimumab against CTLA-4-expressing Treg cells in a humanized mouse model in vivo. Intratumoral administration of VVGM-αCTLA-4 achieved tumor-restricted CTLA-4 receptor saturation and Treg depletion, which elicited antigen cross-presentation and stronger systemic expansion of tumor-specific CD8+ T cells and antitumor immunity compared with systemic αCTLA-4 antibody therapy. Efficacy correlated with FcγR-mediated intratumoral Treg depletion. Remarkably, in a clinically relevant mouse model resistant to systemic ICB, intratumoral VVGM-αCTLA-4 synergized with αPD-1 to reject cold tumors.ConclusionOur findings demonstrate in vivo proof of concept for spatial restriction of Treg depletion-optimized immune checkpoint blocking, vectorized αCTLA-4 as a highly effective and safe strategy to target CTLA-4. A clinical trial evaluating intratumoral VVGM-αhCTLA-4 (BT-001) alone and in combination with αPD-1 in metastatic or advanced solid tumors has commenced.

BackgroundThe pleiotropic TNF-α:TNFR axis plays a central role in the immune system. TNFR2 has been proposed to be both essential for the survival of T regs, as well as providing important co-stimulatory signals for T cell activation and memory generation. In addition, the therapeutic potential of targeting TNFR2 for cancer treatment has been previously indicated. To gain further insight, we characterized the biophysical properties and in vitro and in vivo activities of human and mouse α-TNFR2-specific antibodies designed to agonize the receptor.MethodsA human lead candidate (BI-1910) and a mouse surrogate (mBI-1910) α-TNFR2 were identified. Agonistic activity on T cells were demonstrated for both antibodies in vitro. mBI-1910 showed potent anti-tumor activity both as a single agent and in combination with anti-PD1 in multiple immunocompetent tumor models. The antibody showed co-stimulation through TNFR2, which enhanced T cell activation and induced CD8+ T cell-dependent anti-tumor effects. These findings were confirmed using BI-1910 in human TNFR2 transgenic mice.To address safety, a GLP toxicological study was performed in cynomolgus macaques. Three doses (1, 5, and 25 mg/kg) were given weekly for four consecutive weeks followed by a recovery period of eight weeks. In addition, cytokine release was studied in T cell stimulation assays and in a humanized mouse model. In parallel, multiple immune stimulation assays were studied in vitro using human cells to establish EC50 values and a clear relationship with dose, receptor occupancy and immune cell activation.ResultsFour administrations of BI-1910 to cynomolgus macaques were well tolerated at all doses, with no associated clinical signs and no signs of cytokine release. Pharmacokinetic studies demonstrated an expected human IgG half-life at receptor-saturating doses. Interestingly, there was a clear dose-dependent T cell activation, evidenced by an increase in several T cell activation markers and a shift from naïve to effector memory T cells supporting the proposed mode-of action. Importantly, the nature of BI-1910-induced T cell activation in cynomolgus macaques closely mirrored that in TNFR2 humanized mice, in which clear anti-tumor effects were also demonstrated.ConclusionsThe strong similarities in BI-1910 induced immune response between mice and cynomolgus macaques shows promise that similar T cell activation and following anti-tumor effects will occur also in humans. Collectively, these studies support the upcoming phase I/II study in solid cancer patients planned to start in H2 2023.Ethics ApprovalAll data utilizing human blood or animals was approved by an ethic committé before the experiments were started.Experiments using human blood were approved by the Regional committé for ethichs approval in Lund, Sweden ID numbers 2018/37 and 2010/356The murine experiments were approved by the Ethical committé of animal experiment in Lund and Malmö, Sweden ID numbers 5.8.18–19686/2022; 5.8.18–03333-2020; 5.8.18–02934-2020; 5.8.18–17196-2018The non-human primate experiments were approved by Charles River Laboratories Evreux Ethics Committee (CEC), France, ID number 2850398

BackgroundBI-1808 is a human IgG1 monoclonal antibody targeting TNFR2 by blocking the interaction of TNFR2 with its ligand TNF-α, confering FcγR-dependent depletion of intratumoral Tregs and mediating expansion of intratumoral CD8+ T cells. Upon co-administration of BI-1808 and anti-PD-1 surrogate antibodies to immunocompetent tumor-bearing mice, with partial sensitivity to checkpoint blockade, complete cures were observed in all treated mice, indicating a potentially synergistic activity.MethodsSafety and tolerability of BI-1808 as a single agent and in combination with pembrolizumab is currently investigated in the Phase 1/2a trial 19-BI-1808–01 in patients with advanced malignancies or cutaneous T-cell lymphoma (CTCL). The trial consists of Phase 1 Parts A and B (dose escalation with single agent and combination with pembrolizumab, respectively), and Phase 2a Parts A and B (dose expansion with single agent and combination therapy, respectively). Dose escalation uses a modified toxicity probability interval-2 protocol (mTPI-2), investigating ascending dose levels of 25–1000 mg every three weeks (Q3W). Dose escalation aims to select both single agent RP2D and combination RP2D of BI-1808 for Phase 2a.Patients are sampled for pharmacokinetics (PK) of BI-1808, antidrug-antibodies and pharmacodynamics including lymphocyte subsets, regulatory T cells, memory T-cells, soluble TNFR2 serum concentration (sTNFR2) and BI-1808 receptor occupancy (RO).ResultsAs of June 19th, 2023, 24 subjects with various advanced solid malignancies received doses of up to 1000 mg BI-1808 as single-agent treatment, and 7 subject received 225 mg doses of BI-1808 with pembrolizumab.Across the completed monotherapy arm, no Grade 3/4 AEs, AEs related to BI-1808 and no DLTs were observed. No MTD was defined. The number of potentially related AEs of Gr 1/2 are evenly distributed across the dose range, with no target system organ class of special notice identified. Best clinical response recorded are stable disease (SD) in 7/19 evaluable patients in the monotherapy arm. The first dose cohort for BI-1808 at 225 mg in combination with pembrolizumab is currently ongoing.BI-1808 exhibits a non-linear PK. At doses > 675 mg Q3W, t½ was approximately 1 week resulting in accumulation of drug, with complete RO throughout the dosing interval.ConclusionsPreliminary data from the BI-1808 monotherapy arm from the clinical trial 19-BI-1808–01 is promising. BI-1808 has a favorable safety profile, with no DLTs observed. SD was observed in 7/19 evaluable patients. Doses of 675 mg and higher are expected to provide complete RO throughout the dose interval, and will be further explored in Ph2a.

BackgroundThe pleiotropic TNF-alpha:TNFR axis plays a central role in the immune system. While the cellular expression of TNFR1 is broad, TNFR2 expression is mainly restricted to immune cells. The therapeutic potential of targeting TNFR2 for cancer treatment has been previously indicated and to gain further insight, we characterized a wide panel antibodies, generated from the n-CoDeR F.I.R.S.T™ target and antibody discovery platform. We identified parallel human and mouse TNFR2 specific, complete ligand (TNF-alpha) blocking antibodies and could show potent anti-tumor activity in several immune-competent models, both as single agent and in combination with anti-PD1 using a BI-1808 murine surrogate. The mechanism-of-action was shown to be FcgR dependent and likely mediated through a combination of intra-tumor T reg depletion, CD8+ T cell expansion and modulation of tumor-associated myeloid cells. These findings were confirmed using BI-1808 in a humanized mouse model.MethodsTo address safety of the human lead-candidate BI-1808 two toxicological studies were performed in cynomolgus monkeys. The first study was a dose-range-finding study and the second a GLP study where three doses (2, 20 and 200 mg/kg) were given weekly for four consecutive weeks followed by a recovery period of eight weeks. In addition, cytokine release was further studied in T cell stimulation assays and in a humanized mouse model. Moreover, the BI-1808 murine surrogate was used to study the relationship between dose, receptor occupancy (RO) and efficacy in immune competent mouse cancer experimental models.ResultsFour weekly administrations of BI-1808 to cynomolgus monkeys were well tolerated at all doses, with no associated clinical signs, and no histopathological changes. Non-adverse and reversible increases in neutrophil counts and decreases in T cells were observed at all dose levels. No drug-related adverse events were observed and consequently the NOAEL for BI-1808 was determined to be 200 mg/kg. Pharmacokinetic studies demonstrated an expected half-life of two weeks at receptor saturation. There were no indications of cytokine release in any of the systems tested. Finally, we could show that to achieve max therapeutic effect, sustained RO was needed for approximately two weeks, covering the time it takes to generate a full adaptive Immune response.ConclusionsThere is a clear association between RO and therapeutic effect and BI-1808 is well tolerated at doses associated with high and sustained RO. Collectively, these studies were used to determine the starting dose in upcoming phase I/II study in solid cancer aiming for first-patient in during December 2020.Ethics ApprovalThe study on cynomolgous monkeys was conducted by Citox/Charles River Laboratories in compliance with animal health regulations, in particular: Council Directive No. 2010/63/EU of 22 September 2010 and French decree No. 2013-118 of 01 February 2013 on the protection of animals used for scientific purposes. Studies in mice were approved by the Swedish Animal Experiment Ethics Board, ethical permit/ethical license numbers 5.2.18-17196/2018 and 5.8.18-03333/2020

Mucosal tissues contain large numbers of memory CD4+ T cells that, through T-cell receptor-dependent interactions with antigen-presenting cells, are believed to have a key role in barrier defense and maintenance of tissue integrity. Here we identify a major subset of memory CD4+ T cells at barrier surfaces that coexpress interleukin-18 receptor alpha (IL-18Rα) and death receptor-3 (DR3), and display innate lymphocyte functionality. The cytokines IL-15 or the DR3 ligand tumor necrosis factor (TNF)-like cytokine 1A (TL1a) induced memory IL-18Rα+DR3+CD4+ T cells to produce interferon-γ, TNF-α, IL-6, IL-5, IL-13, granulocyte–macrophage colony-stimulating factor (GM-CSF), and IL-22 in the presence of IL-12/IL-18. TL1a synergized with IL-15 to enhance this response, while suppressing IL-15-induced IL-10 production. TL1a- and IL-15-mediated cytokine induction required the presence of IL-18, whereas induction of IL-5, IL-13, GM-CSF, and IL-22 was IL-12 independent. IL-18Rα+DR3+CD4+ T cells with similar functionality were present in human skin, nasal polyps, and, in particular, the intestine, where in chronic inflammation they localized with IL-18-producing cells in lymphoid aggregates. Collectively, these results suggest that human memory IL-18Rα+DR3+ CD4+ T cells may contribute to antigen-independent innate responses at barrier surfaces.