Zinc is required for a wide variety of cellular functions and plays a key role in bacterial metabolism and virulence. However, Zn can also be toxic and, therefore, its influx is tightly regulated. The high affinity zinc uptake transporter ZnuABC is the main Zn influx system in Salmonella enterica under conditions of Zn starvation. It has been shown that deletion of the gene encoding for its periplasmic subunit ZnuA significantly affects S. Typhimurium growth rate and virulence, highlighting the importance of this system in the host-pathogen interaction. To gain further insight into the mechanisms involved in Zn influx regulation, we characterized the main alterations in the ionome and proteome of S. Typhimurium wild type and znuA mutant strains grown either under Zn starvation or under Zn-replete conditions. We found significant differences in the element profile and protein expression that were reversed by Zn supplementation. In particular, several of the differentially regulated proteins are predicted to be metal-binding proteins. Interestingly, their over-expression in the znuA mutant strain strictly depends on Zn starvation and correlates with the differences found at the ionome level. In conclusion, our data demonstrate that inhibition of Zn influx has relevant effects either on the bacterial ionome or proteome and shed new light on the role of the ZnuABC system and Zn influx in S. Typhimurium pathogenicity.

Phenotypic profile linked to inhibition of the major Zn influx system in Salmonella enterica: proteomics and ionomics investigations

CIAVARDELLI, DOMENICO;LIPOMA, Mario;
2011

Abstract

Zinc is required for a wide variety of cellular functions and plays a key role in bacterial metabolism and virulence. However, Zn can also be toxic and, therefore, its influx is tightly regulated. The high affinity zinc uptake transporter ZnuABC is the main Zn influx system in Salmonella enterica under conditions of Zn starvation. It has been shown that deletion of the gene encoding for its periplasmic subunit ZnuA significantly affects S. Typhimurium growth rate and virulence, highlighting the importance of this system in the host-pathogen interaction. To gain further insight into the mechanisms involved in Zn influx regulation, we characterized the main alterations in the ionome and proteome of S. Typhimurium wild type and znuA mutant strains grown either under Zn starvation or under Zn-replete conditions. We found significant differences in the element profile and protein expression that were reversed by Zn supplementation. In particular, several of the differentially regulated proteins are predicted to be metal-binding proteins. Interestingly, their over-expression in the znuA mutant strain strictly depends on Zn starvation and correlates with the differences found at the ionome level. In conclusion, our data demonstrate that inhibition of Zn influx has relevant effects either on the bacterial ionome or proteome and shed new light on the role of the ZnuABC system and Zn influx in S. Typhimurium pathogenicity.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11387/9924
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