Mutation of hilD in a Salmonella Derby lineage linked to swine adaptation and reduced risk to human health

Jennifer R Tanner,Robert A Kingsley,Stefano Pongolini,Martina Tambassi,Erika Scaltriti,Marina Morganti,Luca Bolzoni,Gaëtan Thilliez,Chiara Bracchi,Gabriele Casadei,Melissa Berni

doi:10.1038/s41598-020-78443-7

Abstract

Salmonella enterica variants exhibit diverse host adaptation, outcome of infection, and associated risk to food safety. Analysis of the distribution of Salmonella enterica serovar Derby (S. Derby) subtypes in human and swine identified isolates with a distinct PFGE profile that were significantly under-represented in human infections, consistent with further host adaptation to swine. Here we show that isolates with this PFGE profile form a distinct phylogenetic sub-clade within S. Derby and exhibit a profound reduction in invasion of human epithelial cells, and a relatively small reduction in swine epithelial cells. A single missense mutation in hilD, that encodes the master-regulator of the Salmonella Pathogenicity Island 1 (SPI-1), was present in the adapted lineage. The missense mutation resulted in a loss of function of HilD that accounted for reduced invasion in human epithelial cells. The relatively small impact of the mutation on interaction with swine cells was consistent with an alternative mechanism of invasion in this pathogen-host combination.

Highlights

We investigated a specialized case of host adaption of a S
The Salmonella Pathogenicity Island 1 (SPI-1) pathway, considered essential for the pathogenesis of Salmonella infection, does not explain the infection of swine cells, suggesting that an alternative mechanism is involved in this host
Our results show that changes in host adaptation at the population level may occur due to a single nsSNP in the master regulator of SPI-1

Summary

Introduction

We investigated a specialized case of host adaption of a S. Derby ST40 lineage that has resulted in further adaptation to the swine host and decreased risk to human infection. Derby surveillance (446 isolates from 2012 to 2017), identified a specific PFGE profile that was significantly less likely to be isolated from human infections than from swine compared to isolates of other PFGE profiles of S. This swine adapted type showed altered interactions with swine and human epithelial cells in vitro, compared to isolates with closely related PFGE profiles. We found that a single amino acid residue substitution in HilD, the master-regulator of SPI-113, characteristic of the swine adapted PFGE profile, is responsible for the altered interaction with host cells

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Results

Conclusion