Evaluation on the pathogenicity of genetically engineered Salmonella Gallinarum biovar Gallinarum strains harbouring mutations in metabolism-related genes naturally inactivated in S. Gallinarum biovar Pullorum genomes

Fowl typhoid, caused by Salmonella Gallinarum biovar Gallinarum, is an infectious disease which elicits high mortality into a flock of susceptible birds whereas S. Gallinarum biovar Pullorum, the aetiological agent of pullorum disease, infects poultry of commercial importance with which such a bacterium sets off a more permissive host-pathogen interaction. Little is known about the molecular mechanisms driving these distinct interplays with the host. Herein, we aimed at investigating the effect of partial deletions in the idnT (L-idonate / D-gluconate transporter), idnO (5-ketogluconase reductase) and ccmH (heme liase involved in the c-type cytochrome maturation) coding sequences on S. Gallinarum 287/91 (SG287/91) pathogenicity since they are conserved pseudogenes in S. Pullorum genomes. SG∆idnTO, SG∆ccmH and SG∆ccmHidnTO mutant strains were constructed through a one-step inactivation technique, known as Lambda-Red-mediated recombination, and tested on two independent experiments by using a commercial brown egg-producing layer line susceptible to fowl typhoid. On the experiment 1, no changing was observed in the pathogenicity of the mutant strains upon oral inoculation as the infected animals developed typical fowl typhoid clinical signs and died along 12 days post-infection (dpi). In spite of causing 100% mortality, SG∆idnTO and SG∆ccmHidnTO killed all the animals within 48 hours since the clinical signs appearance while SG287/91 did so in 6 days, indicating an increased virulence by these mutant strains. On the experiment 2 every mutant strain were able to invade the host system from the intestine albeit SG∆idnTO and SG∆ccmHidnTO were recovered from livers and SG∆idnTO alone from spleens at higher numbers than was SG287/91, supporting the hypothesis of increased virulence for those clones harbouring the idnTO mutation. Despite the results above, CXCLi2 and IL6 transcription levels during infection by SG∆idnTO and SG∆ccmHidnTO were similar to that induced by SG287/91 in caecal tonsils at 1 and 3 dpi and in spleens at 3 dpi. In contrast, SG∆ccmH trended to stimulate CXCLi2 and IL6 transcription in caecal tonsils at 1 dpi when compared to the negative, control group whereas SG287/91 tended to suppress it, but no statistical significance was found for such an observation. IFNγ mRNA were augmented for all S. Gallinarum strains, mutant or not, but without statistical difference amongst them. These findings indicate that gene decay into idnTO, and at a lesser extent, into ccmH sequences might lead to the loss of fitness by S. Gallinarum, raising an explanation for their maintenance on this bacterium chromosome when the opposite happens to S. Pullorum. Studying the pathogenicity of a S. Pullorum strain possessing both the idnTO and ccmH genes in its genome could bring to light the reasons whereby such genes were negatively selected by this microorganism. (AU)