Immunotherapy with engineered bacteria by targeting the STING pathway for anti-tumor immunity.

Synthetic biology is a powerful tool to create therapeutics which can be rationally designed to enable unique and combinatorial functionalities. Here we utilize non-pathogenic E coli Nissle as a versatile platform for the development of a living biotherapeutic for the treatment of cancer. The engineered bacterial strain, referred to as SYNB1891, targets STING-activation to phagocytic antigen-presenting cells (APCs) in the tumor and activates complementary innate immune pathways. SYNB1891 treatment results in efficacious antitumor immunity with the formation of immunological memory in murine tumor models and robust activation of human APCs. SYNB1891 is designed to meet manufacturability and regulatory requirements with built in biocontainment features which do not compromise its efficacy. This work provides a roadmap for the development of future therapeutics and demonstrates the transformative potential of synthetic biology for the treatment of human disease when drug development criteria are incorporated into the design process for a living medicine.

Partial and transient modulation of the CD3-T-cell receptor complex, elicited by low-dose regimens of monoclonal anti-CD3, is sufficient to induce disease remission in non-obese diabetic mice.

It has been established that a total of 250 microg of monoclonal anti-mouse CD3 F(ab')(2) fragments, administered daily (50 microg per dose), induces remission of diabetes in the non-obese diabetic (NOD) mouse model of autoimmune diabetes by preventing beta cells from undergoing further autoimmune attack. We evaluated lower-dose regimens of monoclonal anti-CD3 F(ab')(2) in diabetic NOD mice for their efficacy and associated pharmacodynamic (PD) effects, including CD3-T-cell receptor (TCR) complex modulation, complete blood counts and proportions of circulating CD4(+), CD8(+) and CD4(+) FoxP3(+) T cells. Four doses of 2 microg (total dose 8 microg) induced 53% remission of diabetes, similarly to the 250 microg dose regimen, whereas four doses of 1 microg induced only 16% remission. While the 250 microg dose regimen produced nearly complete and sustained modulation of the CD3 -TCR complex, lower doses, spaced 3 days apart, which induced similar remission rates, elicited patterns of transient and partial modulation. In treated mice, the proportions of circulating CD4(+) and CD8(+) T cells decreased, whereas the proportions of CD4(+) FoxP3(+) T cells increased; these effects were transient. Mice with greater residual beta-cell function, estimated using blood glucose and C-peptide levels at the initiation of treatment, were more likely to enter remission than mice with more advanced disease. Thus, lower doses of monoclonal anti-CD3 that produced only partial and transient modulation of the CD3-TCR complex induced remission rates comparable to higher doses of monoclonal anti-CD3. Accordingly, in a clinical setting, lower-dose regimens may be efficacious and may also improve the safety profile of therapy with monoclonal anti-CD3, potentially including reductions in cytokine release-related syndromes and maintenance of pathogen-specific immunosurveillance during treatment.