Introduction: The TraT protein is a multifunctional virulence factor that is encoded by conjugative F-like plasmids. A majority of multidrug-resistant uropathogenic Escherichia coli (UPEC) carry F-like plasmids and thus encode for this TraT factor. In non-pathogenic E. coli, TraT is a highly expressed outer membrane lipoprotein that protects the bacterial cell from excessive rounds of plasmid transfer, from a few bacteriophages, and from the host innate immune response via serum complement killing. Our objectives in this study were (1) to measure the protective effect of TraT in UPEC background and (2) to establish whether extracellular TraT domain is sufficient to provide serum resistance.
Methods: We used conjugation to transfer the model F’ plasmid in different E. coli backgrounds. Recombinant extracellular soluble domain TraT33-244 was purified from BL21(DE3) E. coli strain using Ni-affinity chromatography. Exponentially growing E. coli cultures with and without traT-encoding plasmids or the purified TraT domain were subjected to different doses of blood serum for 2 hours at 37°C. Viable cells were quantified as colony forming units by plating serial dilutions at 0 and 2 hours after addition of serum.
Results: The traT-encoding plasmid provides variable level of protection that depends on serum type, bacterial cells, time, and ratios of bacteria and serum, and can reach several orders of magnitude. We have developed a method of expression and purification of soluble TraT33-244 protein and showed that this extracellular domain forms stable oligomers in solution with five-to-six subunits. Testing this purified extracellular domain in serum resistance assays revealed that it is insufficient to exhibit the full protective action of TraT.
Conclusions: In this study, we measured the protective effect of traT-encoding plasmid F’ in model E. coli strains, which displayed strong but variable serum resistance. The extracellular soluble domain of TraT protein oligomerizes, but does not strongly protect against serum killing when added to bacterial cells in trans. These results suggest that membrane localization, N-terminus, or lipidation itself are important for function of the TraT factor. Overall, this study sets the stage for further investigation into the mechanism of how TraT assists UPEC bacteria in evading innate immune responses within the host organism.
Source of Funding: The University of Alabama in Huntsville startup funds to Tatyana Sysoeva.
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