Comparative analysis of immune cells activation and cytotoxicity upon exposure pathogen and glycoconjugates

Peripheral mononuclear cells (PMNC) including macrophages are key players in the immune responses against pathogens. Any infection could be attenuated if PMNC would be activated and capable to kill pathogen on exposure. It was shown that glycoconjugates (GCs) play an important role in adhesion to, activation, and recognition of pathogens. Nitric oxide (NO) is a regulatory molecule released by immune cells against pathogens that include bacteria, protozoa, helminthes, and fungi. NO is a highly reactive and diffusible molecule that controls replication or intracellular killing of pathogens during infection and immune responses against infections caused by pathogens. Avirulent Bacillus anthracis Sterne spores were used as a model in our study. The purpose of this study was two-fold: A) to analyze PMNC activation through NO production and B) to determine the cytotoxicity effect based on lactate dehydrogenase (LDH) upon exposure to pathogen exerted by GCs. The latter were used "prior to," "during," and "following" PMNC exposure to pathogen in order to modulate immune responses to spores during phagocytosis. Post-phagocytosis study involved the assessment of NO and LDH release by macrophages upon exposure to spores. Results have shown that untreated PMNC released low levels of NO. However, in the presence of GCs, PMNC were activated and produced high levels of NO under all experimental conditions. In addition, the results showed that GC1, GC3 are capable of increasing PMNC activity as evidenced by higher NO levels under the "prior," "during" and "following" to pathogen exposure conditions. On the other hand, GCs were capable of controlling cytotoxicity and decreased LDH levels during phagocytosis of spores. Our findings suggest that GCs stimulate NO production by activating PMNC and decrease cytotoxicity caused by pathogens on PMNC. © 2010 American Institute of Physics.