Blocking Antibodies Targeting the CD39/CD73 Immunosuppressive Pathway Unleash Immune Responses in Combination Cancer Therapies.

Immune checkpoint inhibitors have revolutionized cancer treatment. However, many cancers are resistant to ICIs, and the targeting of additional inhibitory signals is crucial for limiting tumor evasion. The production of adenosine via the sequential activity of CD39 and CD73 ectoenzymes participates to the generation of an immunosuppressive tumor microenvironment. In order to disrupt the adenosine pathway, we generated two antibodies, IPH5201 and IPH5301, targeting human membrane-associated and soluble forms of CD39 and CD73, respectively, and efficiently blocking the hydrolysis of immunogenic ATP into immunosuppressive adenosine. These antibodies promoted antitumor immunity by stimulating dendritic cells and macrophages and by restoring the activation of T cells isolated from cancer patients. In a human CD39 knockin mouse preclinical model, IPH5201 increased the anti-tumor activity of the ATP-inducing chemotherapeutic drug oxaliplatin. These results support the use of anti-CD39 and anti-CD73 monoclonal antibodies and their combination with immune checkpoint inhibitors and chemotherapies in cancer.

Olesoxime protects embryonic cortical neurons from camptothecin intoxication by a mechanism distinct from BDNF.

BACKGROUND AND PURPOSE: Olesoxime is a small cholesterol-oxime promoting rat embryonic motor neurons survival in the absence of trophic factors. Because olesoxime can substitute for neurotrophic factors in many situations, and to gain further understanding of its mechanism of action, we wondered if it could prevent neuronal death induced by camptothecin (CPT) and compared its effects with those of brain-derived neurotrophic factor (BDNF). EXPERIMENTAL APPROACH: E17 rat embryonic cortical neurons were treated with olesoxime, BDNF or vehicle and intoxicated with CPT. Caspase-dependent and caspase-independent death pathways along with pro-survival pathways activation were explored. KEY RESULTS: As previously reported for BDNF, olesoxime dose-dependently delayed CPT-induced cell death. Both compounds acted downstream of p53 activation preventing cytochrome c release and caspases activation. When caspase activation was blocked, both olesoxime and BDNF provided additional neuroprotective effect, potentially through the prevention of apoptosis-inducing factor release from mitochondria. While BDNF activates both the PI3K/Akt and the ERK pathway, olesoxime induced only a late activation of the ERK pathways, which did not seem to play a major role in its neuroprotection against CPT. Rather, our results favour preserved mitochondrial membrane integrity by olesoxime. CONCLUSIONS AND IMPLICATIONS: Albeit different, olesoxime and BDNF mechanisms for neuroprotection converge to preserve mitochondrial function. These findings emphasize the importance of targeting the mitochondria in the process of neurodegeneration. Importantly olesoxime, by mimicking neurotrophin pro-survival activities without impacting PI3K/Akt and ERK signalling, may have greater therapeutic potential in many diseases where neurotrophins were considered as a therapeutic solution.