Bioengineering Bacterially Derived Immunomodulants: A Therapeutic Approach to Inflammatory Bowel Disease.

Bacterial enteric pathogens have evolved efficient mechanisms to suppress mammalian inflammatory and immunoregulatory pathways. By exploiting the evolutionary relationship between the gut and pathogenic bacteria, we have developed a potential mucosal therapeutic. Our findings suggest that engineered preparations of the Salmonella acetyltransferase, AvrA, suppress acute inflammatory responses such as those observed in inflammatory bowel disease (IBD). We created 125 nm diameter cross-linked protein nanoparticles directly from AvrA and carrier protein to deliver AvrA in the absence of Salmonella. AvrA nanoparticles are internalized in vitro and in vivo into barrier epithelial and lamina propria monocytic cells. AvrA nanoparticles inhibit inflammatory signaling and confer cytoprotection in vitro, and in murine colitis models, we observe decreased clinical and histological indices of inflammation. Thus, we have combined naturally evolved immunomodulatory proteins with modern bioengineering to produce AvrA nanoparticles, a potential treatment for IBD.

Bacterial Effector Nanoparticles as Breast Cancer Therapeutics.

Bacterial pathogens trigger cell death by a variety of mechanisms, including injection of effector proteins. Effector proteins have great potential as anticancer agents because they efficiently subvert a variety of eukaryotic signaling pathways involved in cancer development, drug resistance, and metastasis. In breast cancer, MAPK and NFκB pathways are known to be dysregulated. YopJ, an effector from Yersinia pestis, downregulates MAPK and NFκB pathways to induce cell death in specific cell types. We expressed YopJ in Escherichia coli as a fusion protein with glutathione S-transferase (GST), forming self-assembled protein nanoparticles with diameters of 100 nm. YopJ-GST nanoparticles efficiently delivered protein to cells, replacing the need for the pathogen secretion mechanism for effector delivery to cells. These nanoparticles induced dose and time dependent death in SKBR-3 breast cancer cells. After 72 h, 97% of cells died, significantly more than with the same molar dose of doxorubicin. Treatment with sublethal doses of nanoparticles decreased cell migration in vitro and downregulated the MAPK ERK 1/2 pathway, which has been correlated to metastasis. Exposure to a panel of breast cancer cell lines showed that YopJ-GST nanoparticles are cytotoxic to different subtypes, including doxorubicin resistant cells. However, they were not cytotoxic to NIH/3T3 fibroblasts or HeLa cells. Thus, YopJ-GST nanoparticles demonstrate the potential of effector proteins as breast cancer therapeutics with selective cytotoxicity and the capacity to decrease metastatic predictive behaviors.