Development of dual reporter imaging system for Francisella tularensis to monitor the spatio-temporal pathogenesis and vaccine efficacy

PURPOSE: Study on the pathogen and the pathogen-related disease require the information at both cellular and organism level. However, lack of appropriate high-quality antibodies and the difference between the experimental animal models make it difficult to analyze in vivo mechanism of pathogen-related diseases. For more reliable research on the infection and immune-response of pathogen-related diseases, accurate analysis is essential to provide spatiotemporal information of pathogens and immune activity to avoid false-positive or mis-interpretations. In this regards, we have developed a method for tracking Francisella tularensis in the animal model without using the specific antibodies for the F. tularensis. MATERIALS AND METHODS: A dual reporter plasmid using GFP-Lux with putative bacterioferritin promoter (pBfr) was constructed and transformed to F. tularensis live vaccine strain to generate F. tularensis LVS (FtLVS)-GFP-Lux for both fluorescence and bioluminescence imaging. For vaccination to F. tularensis infection, FtLVS and lipopolysaccharide (LPS) from FtLVS were used. RESULTS: We visualized the bacterial replication of F. tularensis in the cells using fluorescence and bioluminescence imaging, and traced the spatio-temporal process of F. tularensis pathogenesis in mice. Vaccination with LPS purified from FtLVS greatly reduced the bacterial replication of FtLVS in animal model, and the effect of vaccination was also successfully monitored with in vivo imaging. CONCLUSION: We successfully established dual reporter labeled F. tularensis for cellular and whole body imaging. Our simple and integrated imaging analysis system would provide useful information for in vivo analysis of F. tularensis infection as well as in vitro experiments, which have not been fully explained yet with various technical problems.

Current status of vaccine development for tularemia preparedness

Tularemia is a high-risk infectious disease caused by Gram-negative bacterium Francisella tularensis. Due to its high fatality at very low colony-forming units (less than 10), F. tularensis is considered as a powerful potential bioterrorism agent. Vaccine could be the most efficient way to prevent the citizen from infection of F. tularensis when the bioterrorism happens, but officially approved vaccine with both efficacy and safety is not developed yet. Research for the development of tularemia vaccine has been focusing on the live attenuated vaccine strain (LVS) for long history, still there are no LVS confirmed for the safety which should be an essential factor for general vaccination program. Furthermore the LVS did not show protection efficacy against high-risk subspecies tularensis (type A) as high as the level against subspecies holarctica (type B) in human. Though the subunit or recombinant vaccine candidates have been considered for better safety, any results did not show better prevention efficacy than the LVS candidate against F. tularensis infection. Currently there are some more trials to develop vaccine using mutant strains or nonpathogenic F. novicida strain, but it did not reveal effective candidates overwhelming the LVS either. Difference in the protection efficacy of LVS against type A strain in human and the low level protection of many subunit or recombinant vaccine candidates lead the scientists to consider the live vaccine development using type A strain could be ultimate answer for the tularemia vaccine development.

GFP-tagged E. coli shows bacterial distribution in mouse organs: pathogen tracking using fluorescence signal

PURPOSE: In vaccine efficacy evaluation, visualization of pathogens in whole organism at each time point would be able to reduce the consuming animals and provide the in vivo information within consistent background with identical organism. MATERIALS AND METHODS: Using IVIS spectrum whole live-animal imaging system, fluorescent intensity was optimized and visualized proportionately by concentrating Escherichia coli MC1061 strain which expresses GFP (E. coli-GFP) in BALB/C mice after injection. RESULTS: Local distribution of disseminated E. coli-GFP was traced in each organ by fluorescence. Detached organ showed more obvious fluorescent signal, and intestine showed strongest fluorescent signal. CONCLUSION: This in vivo imaging method using GFP-tagged pathogen strain suggest quantified infected pathogens by fluorescence intensity in whole animals can provide the information about the localization and distribution after infection.

Development of thymic lymphomas in mice disrupted of Brca2 allele in the thymus

Germ-line mutations in BRCA2 predispose to early-onset cancer. Homozygous mutant mouse, which has Brca2 truncated in exon 11 exhibit paradoxic occurrence of growth retardation and development of thymic lymphomas. However, due to its large embryonic lethality, cohort studies on the thymic lymphomas were not feasible. With the aid of Cre-loxP system, we demonstrate here that thymus-specific disruption of Brca2 allele without crossing it to p53-mutant background leads to the development of thymic lymphomas. Varying from 16 weeks to 66 weeks after birth, 25% of mice disrupted of Brca2 in the thymus died of thymic lymphomas, whereas previous report did not observe lymphomagenesis using similar Cre-loxP system. Future analysis of thymic lymphomas from these mice presented here will provide information on the cooperative mutations that are required for the BRCA2-associated pathogenesis of cancer.