Inhibition of Phagocytic Killing of Escherichia coli in Drosophila Hemocytes by RNA Chaperone Hfq.

An RNA chaperone of Escherichia coli, called host factor required for phage Qß RNA replication (Hfq), forms a complex with small noncoding RNAs to facilitate their binding to target mRNA for the alteration of translation efficiency and stability. Although the role of Hfq in the virulence and drug resistance of bacteria has been suggested, how this RNA chaperone controls the infectious state remains unknown. In the present study, we addressed this issue using Drosophila melanogaster as a host for bacterial infection. In an assay for abdominal infection using adult flies, an E. coli strain with mutation in hfq was eliminated earlier, whereas flies survived longer compared with infection with a parental strain. The same was true with flies deficient in humoral responses, but the mutant phenotypes were not observed when a fly line with impaired hemocyte phagocytosis was infected. The results from an assay for phagocytosis in vitro revealed that Hfq inhibits the killing of E. coli by Drosophila phagocytes after engulfment. Furthermore, Hfq seemed to exert this action partly through enhancing the expression of σ(38), a stress-responsive σ factor that was previously shown to be involved in the inhibition of phagocytic killing of E. coli, by a posttranscriptional mechanism. Our study indicates that the RNA chaperone Hfq contributes to the persistent infection of E. coli by maintaining the expression of bacterial genes, including one coding for σ(38), that help bacteria evade host immunity.

Role for σ38 in prolonged survival of Escherichia coli in Drosophila melanogaster.

Bacteria adapt themselves to host environments by altering the pattern of gene expression. The promoter-recognizing subunit σ of bacterial RNA polymerase plays a major role in the selection of genes to be transcribed. Among seven σ factors of Escherichia coli, σ(38) is responsible for the transcription of genes in the stationary phase and under stressful conditions. We found a transient increase of σ(38) when E. coli was injected into the hemocoel of Drosophila melanogaster. The loss of σ(38) made E. coli rapidly eliminated in flies, and flies infected with σ(38)-lacking E. coli stayed alive longer than those infected with the parental strain. This was also observed in fly lines defective in humoral immune responses, but not in flies in which phagocytosis was impaired. The lack of σ(38) did not influence the susceptibility of E. coli to phagocytosis, but made them vulnerable to killing after engulfment. The changes caused by the loss of σ(38) were recovered by the forced expression of σ(38)-encoding rpoS as well as σ(38)-regulated katE and katG coding for enzymes that detoxify reactive oxygen species. These results collectively suggested that σ(38) contributes to the prolonged survival of E. coli in Drosophila by inducing the production of enzymes that protect bacteria from killing in phagocytes. Considering the similarity in the mechanism of innate immunity against invading bacteria between fruit flies and humans, the products of these genes could be new targets for the development of more effective antibacterial remedies.

Involvement of EnvZ-OmpR two-component system in virulence control of Escherichia coli in Drosophila melanogaster.

Bacteria adapt to environmental changes by altering gene expression patterns with the aid of signal transduction machinery called the two-component regulatory system (TCS), which consists of two protein components, a sensor kinase and response regulator. We examined the role of the TCS in bacterial adaptation to host environments using genetically tractable organisms, Escherichia coli as a pathogen and Drosophila melanogaster as a host. To determine the strength of the transcription promoters of TCS-encoding genes in Drosophila, adult flies were infected with a series of E. coli strains that expressed GFP driven by the promoters of genes coding for 27 sensor kinases and 32 response regulators of E. coli TCS followed by the measurement of fluorescence intensities. We further analyzed EnvZ-OmpR among the TCS encoded by genes having stronger promoters. A mutant E. coli strain lacking EnvZ-OmpR had a higher pathogenic effect on fly survival than that of the parental strain, and the forced expression of envZ and ompR in the mutant strain lowered its pathogenicity. The lack of EnvZ-OmpR did not affect the growth of E. coli in a culture medium as well as the level of colony-formable E. coli in flies. An increase in E. coli virulence with the loss of EnvZ-OmpR was observed in flies defective in an Imd-mediated humoral response, and both the mutant and parental strains were equally engulfed by hemocytes in vitro. These results suggest that EnvZ-OmpR mitigated the virulence of E. coli in Drosophila by a mechanism not accompanied by a change of bacterial burden. This behavior of E. coli is most likely a bacterial strategy to achieve persistent infection.