Group B Streptococcal Peptide Mimetic Vaccine
Glee, Pati M.   
Ligocyte Pharmaceuticals, Inc., Bozeman, MT, United States

Group B streptococcus (GBS) causes invasive infections of newborns, pregnant women and adults with underlying medical conditions, such as diabetes or cancer. Despite antibiotic treatment, estimated case fatality rates of 5-20% in neonates and 15-32% in adults establish the prevention of GBS infections as a public health priority. Peptide immunogens that mimic the structure of GBS capsular polysacharide (CPS) antigens would provide an alternate vaccine strategy, compared to currently tested CPS-conjugates for induction of maternal antibodies to prevent neonatal infection. The long-term goal of the proposed research is to develop a multi-valent peptide mimotope vaccine for prevention of GBS infections caused by the predominant serotypes Ia, Ib, II, III, and V. The proposed work is a direct extension of research identifying peptides that mimic type III CPS. Phase I use anti-CPS antibodies to select phage libraries to identify peptides that bind uniquely to the antibodies; and to determine whether the selected peptides are true mimotopes of the CPS. Phase II innovative vaccine approaches utilizing peptide mimotopes of microbial polysaccharides offer the design and development of T-dependent immune responses and better immunologic memory for prevention of disease.

Proposed Commercial Applications

A successful GBS vaccine incorporated into prenatal care would the most cost-effective prevention of GBS infection in newborns. The vaccine would have a large market potential among child-bearing women and possibly adults with underlying medical conditions. In addition, the generation of serotype-specific monoclonal antibody reagents and serotype-specific peptide mimetics could be marked as diagnostic and epidemiological research tools. The proposed 3D pulse sequence family will e made available for MRI scanners of all major MR hardware manufacturers equipped with high- performance gradient systems, it will help 3D MRI to become a major diagnostic tool in modern radiology and in-vivo imaging research in general by overcoming many of the obstacles, such as the long acquisition time, that are holding back current 3D MRI techniques.