Abstract
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. SignificanceIn 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.
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