Abstract
Invasive Gram-negative bacteria often express multiple virulence-associated metal ion chelators to combat host-mediated metal deficiencies. Escherichia coli, Klebsiella, and Yersinia pestis isolates encoding the Yersinia high pathogenicity island (HPI) secrete yersiniabactin (Ybt), a metallophore originally shown to chelate iron ions during infection. However, our recent demonstration that Ybt also scavenges copper ions during infection led us to question whether it might be capable of retrieving other metals as well. Here, we find that uropathogenic E. coli also use Ybt to bind extracellular nickel ions. Using quantitative MS, we show that the canonical metal-Ybt import pathway internalizes the resulting Ni-Ybt complexes, extracts the nickel, and releases metal-free Ybt back to the extracellular space. We find that E. coli and Klebsiella direct the nickel liberated from this pathway to intracellular nickel enzymes. Thus, Ybt may provide access to nickel that is inaccessible to the conserved NikABCDE permease system. Nickel should be considered alongside iron and copper as a plausible substrate for Ybt-mediated metal import by enterobacteria during human infections.
Highlights
Invasive Gram-negative bacteria often express multiple virulence-associated metal ion chelators to combat host-mediated metal deficiencies
We find that E. coli and Klebsiella direct the nickel liberated from this pathway to intracellular nickel enzymes
In this study we examined whether uropathogenic enterobacteria use the Yersinia high pathogenicity island (HPI) to interact with nickel
Summary
Invasive Gram-negative bacteria often express multiple virulence-associated metal ion chelators to combat host-mediated metal deficiencies. UPEC retain nutritional access to Ybt-bound copper and iron by importing the metal–Ybt complexes in a controlled manner, extracting the metal, and using it to support metal-dependent cellular functions [8]. These findings implicate Ybt as an agent of nutritional passivation, a biological strategy in which metal ion toxicity is minimized and nutritional access is preserved. Transcriptional up-regulation of this system during UTI [9] is indicative of nickel deficiency during infection (10 – 12) This is consistent with nickel scarcity in human hosts, where urinary nickel content (ϳ0.04 mol per liter) is lower than that of iron (ϳ0.1 mol per liter) [13, 14]. Our findings expand the substrates of nutritional passivation by the Ybt metallophore system of uropathogenic enterobacteria to include nickel
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
