Abstract
Streptococcus pneumoniae (Spn) colonizes the nasopharynx of children and the elderly but also kills millions worldwide yearly. The secondary bile acid metabolite, deoxycholic acid (DoC), affects the viability of human pathogens but also plays multiple roles in host physiology. We assessed in vitro the antimicrobial activity of DoC and investigated its potential to eradicate Spn colonization using an ex vivo model of human nasopharyngeal colonization and an in vivo mouse model of colonization. At a physiological concentration DoC (0.5 mg/ml; 1.27 mM) killed all tested Spn strains (N=48) two h post-inoculation. The ex-vivo model of nasopharyngeal colonization showed that DoC eradicated colonization by Spn strains as soon as 10 min post-exposure. The mechanism of action did not involve activation of autolysis since the autolysis-defective double mutants ΔlytAΔlytC and ΔspxBΔlctO were as susceptible to DoC as was the wild-type (WT). Oral streptococcal species (N=20), however, were not susceptible to DoC (0.5 mg/ml). Unlike trimethoprim, whose spontaneous resistance frequency (srF) for TIGR4 or EF3030 was ≥1×10−9, no spontaneous resistance was observed with DoC (srF≥1×10−12). Finally, the efficacy of DoC to eradicate Spn colonization was assessed in vivo using a topical route via intranasal (i.n.) administration and as a prophylactic treatment. Mice challenged with Spn EF3030 carried a median of 4.05×105 cfu/ml four days post-inoculation compared to 6.67×104 cfu/ml for mice treated with DoC. Mice in the prophylactic group had a ∼99% reduction of the pneumococcal density (median, 2.61 ×103 cfu/ml). Thus, DoC, an endogenous human bile salt, has therapeutic potential against Spn.
