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Peptide Conformation Constrainment Technology and Novel Mucosal Adjuvants to

$276,501U19FY2010AINIH

University Of Maryland Baltimore, Baltimore MD

Investigators

Linked publications & trials

Abstract

Vaccination is one of the most successful and cost-effective ways of preventing infectious disease. The development of effective vaccines for infections of the gastrointestinal tract however has been disappointing. The need for these vaccines is crucial since diarrheal diseases due to infectious agents of the gut are the second leading infectious cause of death in infants and young children world wide. Some of the Infectious agents that cause diarrheal diseases include rotavirus, pathogenic Escherichia coli, Shigella spp., Salmonella spp., Cryptosporidium pan/urn, Entamoeba histolytica, and Vibrio cholera. The reason for the lack of suitable vaccines for enteric pathogens is the lack of an effective adjuvant that can be delivered orally with the vaccine to increase its potency at stimulating an immune response. Most experimental oral adjuvants are ineffective or maintain some degree of toxicity. To address this problem, we propose to couple synthetic peptides from enteric pathogens to a safe and stable adjuvant, aluminum oxide nanoparticles for oral immunization. The peptides will be coupled to the nanoparticles in a way that preserves their native conformation in order to optimize the immune response to recognize the native pathogen. Since very few small animal models of enteric disease and immunity exist, we will use the human pathogen Helicobacter pylori (H. pylori) to infect the mouse gastric mucosa and we will test this technology by 1) Identifying epitopes on H. pylori CagL that are crucial for binding of the bacteria to host cells using an antibody blocking assay with human cell lines, 2) Testing the ability of those CagL epitopes, coupled to aluminum oxide nanoparticles, to induce protective immunity when delivered to mice prior to challenge, 3) Testing the ability of those CagL epitopes, coupled to aluminum oxide nanoparticles, to induce antibodies that block pathogenic and carcinogenic events due to H. pylori infection, and 4) Evaluating the antibody response of infected human subjects to determine if these blocking antibodies are induced by natural infection in order to determine if the induction of these antibodies by vaccination would be beneficial to human patients. A reduction of infection, inflammation, or carcinogenesis in the H. pylori model by immunization with stable, targeted peptide epitopes coupled to nanoparticles would provide compelling evidence for subsequent applications against other enteric bacterial infections in humans that induce significant world wide morbidity and mortality.

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