B. pertussis is the etiological agent of whooping cough, a highly contagious respiratory disease which remains uncontrolled worldwide. Understanding how this pathogen responds to the environmental changes and adapts to different niches found inside the host might contribute to gain insight into bacterial pathogenesis. Comparative analyses of previous transcriptomic and proteomic data suggested that post-transcriptional regulatory mechanisms modulate B. pertussis virulence in response to iron availability. Iron scarcity represents one of the major stresses faced by bacterial pathogens inside the host. In this study, we used gel-free nanoLC-MS/MS-based proteomics to investigate whether Hfq, a highly conserved post-transcriptional regulatory protein, is involved in B. pertussis adaptation to low iron environment. To this end, we compared the protein profiles of wild type B. pertussis and its isogenic hfq deletion mutant strain under iron-replete and iron-depleted conditions. Almost of 33% of the proteins identified under iron starvation was found to be Hfq-dependent. Among them, proteins involved in oxidative stress tolerance and virulence factors that play a key role in the early steps of host colonization and bacterial persistence inside the host cells. Altogether these results suggest that Hfq shapes the infective phenotype of B. pertussis. SIGNIFICANCE: In the last years, it became evident that post-transcriptional regulation of gene expression in ba cteria plays a central role in host-pathogen interactions. Hfq is a bacterial protein that regulates gene expression at post-transcriptional level found pivotal in the establishment of successful infections. In this study, we investigated the role of Hfq in Bordetella pertussis response to iron starvation, one of the main stresses imposed by the host. The data demonstrate that Hfq regulates the abundance of a significant number of B. pertussis proteins in response to iron starvation. Among them, virulence factors and proteins involved in oxidative stress tolerance, key players in host colonization and intracellular bacterial survival. Altogether, our results suggest a relevant role of Hfq in B. pertussis adaptation to the different niches found inside the host eventually granting bacterial pathogenesis.
Bordetella pertussis, the causative agent of whooping cough, has the capability to survive inside the host cells. This process requires efficient adaptation of the pathogen to the intracellular environment and the associated stress. Among the proteins produced by the intracellular B. pertussis we identified a protein (BP0414) that shares homology with MgtC, a protein which was previously shown to be involved in the intracellular survival of other pathogens. To explore if BP0414 plays a role in B. pertussis intracellular survival a mutant strain defective in the production of this protein was constructed. Using standard in vitro growth conditions we found that BP0414 is required for B. pertussis growth under low magnesium availability or low pH, two environmental conditions that this pathogen might face within the host cell. Intracellular survival studies showed that MgtC is indeed involved in B. pertussis viability inside the macrophages. The use of bafilomycin A1, which inhibits phagosome acidification, abolished the survival defect of the mgtC deficient mutant strain suggesting that in intracellular B. pertussis the role of MgtC protein is mainly related to the bacterial adaptation to the acidic conditions found inside the of phagosomes. Overall, this work provides an insight into the importance of MgtC in B. pertussis pathogenesis and its contribution to bacterial survival within immune cells.
- MeSH
- Bacterial Proteins genetics metabolism MeSH
- Bordetella pertussis drug effects genetics growth & development metabolism MeSH
- Escherichia coli MeSH
- Magnesium metabolism MeSH
- Enzyme Inhibitors pharmacology MeSH
- Cations, Divalent metabolism MeSH
- Hydrogen-Ion Concentration MeSH
- Humans MeSH
- Macrophages drug effects microbiology pathology MeSH
- Macrolides pharmacology MeSH
- Mutation MeSH
- Sequence Homology, Amino Acid MeSH
- THP-1 Cells MeSH
- Check Tag
- Humans MeSH
- Publication type
- Journal Article MeSH
- Research Support, Non-U.S. Gov't MeSH
UNLABELLED: Previous studies have shown that B. pertussis survives inside human macrophages in non-acidic compartments with characteristics of early endosomes. In order to gain new insight into the biology of B. pertussis survival in host cells, we have analyzed the adaptation of the bacterial proteome during intracellular infection. The proteome of B. pertussis 3 h and 48 h after infection of human macrophage-like THP-1 cells was examined by nano-liquid chromatography combined with tandem MS and compared to the protein profile of extracellular B. pertussis growing in the same cell culture medium. Compared with extracellular bacteria, almost 300 proteins out of 762 identified proteins displayed altered levels in intracellular B. pertussis. Functional analyses of the proteins displaying altered abundance revealed enrichment of proteins involved in stress response, iron uptake, cellular metabolism, transcriptional regulation, and virulence. To our knowledge, this is the first analysis of the B. pertussis proteome during adaptation to the intramacrophage environment and the data provide new clues for understanding B. pertussis adaptation and pathogenesis. BIOLOGICAL SIGNIFICANCE: B. pertussis is a respiratory pathogen that has adapted exclusively to the human host. Despite high vaccination rates, whooping cough remains a serious threat to human health and its incidence has been increasing in recent years in vaccinated populations. The mechanisms that allow this pathogen to evade immune clearance, persist in the host, and cause a prolonged paroxysmal cough are still poorly understood. Recent studies regarding B. pertussis survival inside host cells and the cellular response to this bacterial infection indicate that B. pertussis may have an intracellular phase during infection which probably contributes to persistence and vaccine failure. In this study we provide the first global proteome profile of B. pertussis within macrophages. The data provide novel insights into the adaptive responses elicited by these bacteria for physiological adaptation to the host environment.
