ISB 1442 is a bispecific antibody (BsAb) using Ichnos' proprietary Bispecific Engagement by Antibodies based on the T-cell receptor (BEAT ®) platform. A fully human BsAb with anti-CD38 and CD47 binding arms, ISB 1442 was developed for the treatment of relapsed/refractory multiple myeloma (rrMM). The CD38 binding arm consists of two bi-paratopic Fabs that strongly bind to CD38 through avidity-induced interactions. The anti-CD47 arm comprises a single Fab arm designed to block the interaction between CD47 and the signal-regulatory protein alpha (SIRPα) receptor present on phagocytes (including macrophages, monocytes and dendritic cells). With this design, the CD38 Fab arm preferentially drives binding to tumor cells and enables blocking of proximal CD47 receptors on the same cell via avidity-induced binding. Hence, ISB 1442 is anticipated to induce minimal unintended effects on red blood cell (RBC) hemagglutination compared to benchmark anti-CD47 monoclonal antibodies (mAb) magrolimab. The Fc portion of ISB 1442 is engineered to enhance antibody dependent cell phagocytosis (ADCP), antibody dependent cell cytotoxicity (ADCC) and complement dependent cytotoxicity (CDC). ISB 1442 is the first-in-class with these unique molecular attributes, which are designed to overcome mechanisms of resistance to daratumumab in rrMM patients. In vitro, ISB 1442 exhibited a higher killing potency compared to benchmark daratumumab across a broad range of CD38-expressing tumor cells. Specifically, ISB 1442 showed a high potency to kill CD38 high tumor cells through CDC and a superior potency to kill CD38 low expressing tumor cells through ADCC and ADCP compared to daratumumab. Additionally, ISB 1442 showed in vitro tumor killing potency through phagocytosis comparable to magrolimab, an anti-CD47 mAb (IgG4) acting mostly through ADCP. Consistent with its molecular design, which includes a functional Fc, ISB 1442 induced more potent killing of CD38 high and CD38 low tumor cells by CDC and ADCC compared to magrolimab. To characterize the complex mechanisms of action of ISB 1442 in a single system more fully, a multiple mode of action of killing (MMoAK) in vitro assay was established where autologous macrophages and PBMCs from healthy donors were incubated with CD38 low expressing tumor cells and human serum. With this approach, tumor cells can be targeted simultaneously by NK cells from PBMCs, autologous macrophages, and complement from human serum. In MMoAK, ISB 1442 exhibited prominent tumor cell killing that was twice as high as daratumumab. The presence of soluble CD38 or RBCs, the main source of antigen sinks for CD38 and CD47, did not affect the killing potency of ISB 1442 across in vitro assays using CD38 high or CD38 low expressing tumor cells. These data suggest that the molecular design of ISB 1442 mitigates the potential risk of CD47 and CD38 antigen sink and the related side effects. On-target specificity was evaluated in vitro by measuring binding to human RBCs, induction of hemagglutination and RBC depletion, hemolysis and platelet aggregation. ISB 1442 did not cause any detectable hemolysis, RBC depletion or platelet aggregation in vitro and showed a marked reduction in human RBC hemagglutination relative to magrolimab, suggesting a more favorable on-target specificity profile. Finally, the potency of ISB 1442 was assessed in vivo in a therapeutic model of subcutaneously established Raji tumor xenograft in CB17/SCID mice which have functional complement, macrophages and NK cells of murine origin. ISB 1442 induced higher tumor growth inhibition relative to daratumumab and comparable tumor regression compared to magrolimab. In summary, we report a novel approach for the treatment for rrMM by co-targeting CD38 and CD47 using a 2+1 biparatopic bispecific antibody. Based on its unique design and multiple mechanisms of action, ISB 1442 is anticipated to enhance antitumor activity in rrMM patients relative to anti-CD38 mAbs by overcoming primary and acquired tumor escape mechanisms of resistance. Disclosures No relevant conflicts of interest to declare.
Impact of ocean acidification and warming on the feeding behaviour of two gastropod species
Increased atmospheric CO2 produced by anthropogenic activities will be absorbed by the oceans over the next century causing ocean acidification and changes in the seawater carbonate chemistry. Elevated CO2 causes sublethal physiological and behavioural responses on the locomotion and foraging behaviour of marine organisms. This study aims to investigate the independent and synergistic effects of long term exposure to low pH and increased temperature on the feeding behaviour of two gastropod species, Hexaplex trunculus and Nassarius nitidus, both in adults and juveniles. Gastropods were maintained under controlled conditions of temperature (ambient = 20°C, increased = 23°C) and pH (ambient = 8, low = 7.6) for 2.5 years. The percentage of animals which successfully reached their food, the response time until gastropods began moving, the total duration until they reached food and the total distance covered, were measured. Speed and path index (i.e how straightforward the movement is) were estimated as means of foraging efficiency. Increased temperature (under ambient pH) resulted in faster responses, a shorter duration until food was reached and a higher speed in H. trunculus adults. H. trunculus (both adults and juveniles) were less successful in reaching their food source under low pH and ambient temperature in comparison to all other treatments. The response time, duration, speed and path index were not affected by low pH (at ambient or increased temperature) for H. trunculus adults and juveniles, as well as for N. nitidus. The foraging performance of juveniles hatched and developed under low pH (either at ambient or increased temperature) was more effective than adults of the same species, thus indicating a degree of acclimation. Also, the scavenger N. nitidus was more successful and responded faster in reaching carrion than the predator H. trunculus, whereas no significant effects were observed for N. nitidus under low pH.
ISB 1442 is a fully human bispecific antibody (BsAb) using BEAT (Bispecific Engagement by Antibodies based on the T-cell receptor) platform to target CD38 and CD47 as treatment for CD38+ malignancies, including multiple myeloma (MM). ISB 1442 is designed with a bi-paratopic anti-CD38 arm that strongly binds to CD38+ tumor cells and an anti-CD47 arm made of a single Fab designed to block interaction between CD47 and the signal-regulatory protein alpha (SIRPα) with low affinity. This approach is expected to induce minimal unintended effects on red blood cells (RBC) compared to anti-CD47 monoclonal antibody (mAb) magrolimab as it enables the CD47 binding only upon avidity induced CD38 crosslinking. The Fc portion of ISB 1442 is engineered to enhance antibody dependent cell phagocytosis (ADCP), antibody dependent cell cytotoxicity (ADCC) and complement dependent cytotoxicity (CDC). In vitro, ISB 1442 exhibited higher killing potency compared to daratumumab across a range of CD38-expressing tumor cells. Additionally, ISB 1442 showed in vitro tumor killing potency through phagocytosis comparable to magrolimab, acting mostly through ADCP. To assess the complex mechanisms of action of ISB 1442 in a single system, a multiple mode of action of killing (MMoAK) assay was established to allow for simultaneous killing by natural killer cells, autologous macrophages, as well as complement from human serum. In the MMoAK assay, ISB 1442 exhibited tumor cell killing that was twice as high as daratumumab. In vivo, in a therapeutic model of subcutaneously established Raji tumor xenograft in CB17/SCID mice, ISB 1442 induced higher tumor growth inhibition than daratumumab and comparable tumor regression to magrolimab. On-target specificity was evaluated in vitro in human and monkey whole blood assays. ISB 1442 did not cause any detectable hemolysis, RBC depletion or platelet aggregation and showed markedly lower RBC hemagglutination relative to magrolimab, suggesting a more favorable on-target specificity profile in humans. On the contrary, due to the higher expression of CD38 in monkey RBC compared to human, ISB 1442 showed more pronounced binding on RBC than magrolimab, suggesting that monkey is a more sensitive species than human for toxicological evaluation of CD38-targeted therapies. Finally, by integrating in vitro pharmacology data along with available clinical information on benchmark antibodies, a quantitative systems pharmacology model was developed to simulate potential efficacious dose range in MM. In summary, we report a novel approach for the treatment for CD38+ cancers by co-targeting CD38 and CD47. Based on its unique design and multiple mechanisms of action, ISB 1442 is anticipated to enhance antitumor activity by overcoming known primary and acquired tumor escape mechanisms of resistance relative to daratumumab. Citation Format: Stefano Sammicheli, Camille Grandclement, Elie Dheilly, Maria Panagopoulou, Evangelia Martini, Perrine Suere, Blandine Pouleau, Carole Estoppey, Julia Frei, Jeremy Loyau, Thierry Monney, Adam Drake, Alain Rubod, Marie Agnes Doucey, Vinu Menon, Venkatesha Udupa, Sunitha GN, Daniel Rasmussen, Jeppe Koch Olsen, Roberto Gionannini, Girish Gudi, Ankita Srivastava, Cyril Konto, Mario Perro. ISB 1442, a first-in-class CD38 and CD47 bispecific antibody innate cell modulator for the treatment of CD38+ malignancies [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2022; 2022 Apr 8-13. Philadelphia (PA): AACR; Cancer Res 2022;82(12_Suppl):Abstract nr 2903.
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