Rates of Chlamydia trachomatis sexually transmitted infection are stable or increasing and these infections incur billions in medical costs annually worldwide. Vaccines for these pathogens are needed but our limited understanding of how Chlamydia species evade the immune system and target different tissues of their hosts has hindered progress towards this goal. Strain- and species-specific Chlamydia genes that circumvent host interferon stimulated defenses, and other interferon independent genes that mediate ability of these organisms to invade different tissues, may be linked to differences in the pathogenesis of closely-related C. trachomatis isolates. However, most of these genes have not been identified because methods for genetic manipulation of these pathogens have only been recently developed.
In aim one of our study we will use forward genetic screens, new genetic mapping tools and mouse models to identify genes that a mouse-adapted C. trachomatis relative uses to evade immunity and infect different tissues in mice and dissect how these function. Similar approaches will be used in aim 2 to identify and characterize the functions of C. trachomatis genes that mediate the ability of these organisms to attach to, invade and avoid immune responses in representative cells from different human tissues.
Intracellular bacteria in the genus Chlamydia are human pathogens and are common causes of preventable blindness and sexually transmitted infections. We propose to genetically modify these pathogens to determine how they avoid the immune systems of their hosts and cause disease. Insights from this study will help design vaccines that could prevent chlamydial disease.
