The transition metal gallium disrupts Pseudomonas aeruginosa iron metabolism and has antimicrobial and antibiofilm activity
Yukihiro Kaneko, … , Bradley E. Britigan, Pradeep K. Singh
Yukihiro Kaneko, … , Bradley E. Britigan, Pradeep K. Singh
Published April 2, 2007
Citation Information: J Clin Invest. 2007;117(4):877-888. https://doi.org/10.1172/JCI30783.
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Research Article Infectious disease

The transition metal gallium disrupts Pseudomonas aeruginosa iron metabolism and has antimicrobial and antibiofilm activity

Abstract

A novel antiinfective approach is to exploit stresses already imposed on invading organisms by the in vivo environment. Fe metabolism is a key vulnerability of infecting bacteria because organisms require Fe for growth, and it is critical in the pathogenesis of infections. Furthermore, humans have evolved potent Fe-withholding mechanisms that can block acute infection, prevent biofilm formation leading to chronic infection, and starve bacteria that succeed in infecting the host. Here we investigate a “Trojan horse” strategy that uses the transition metal gallium to disrupt bacterial Fe metabolism and exploit the Fe stress of in vivo environments. Due to its chemical similarity to Fe, Ga can substitute for Fe in many biologic systems and inhibit Fe-dependent processes. We found that Ga inhibits Pseudomonas aeruginosa growth and biofilm formation and kills planktonic and biofilm bacteria in vitro. Ga works in part by decreasing bacterial Fe uptake and by interfering with Fe signaling by the transcriptional regulator pvdS. We also show that Ga is effective in 2 murine lung infection models. These data, along with the fact that Ga is FDA approved (for i.v. administration) and there is the dearth of new antibiotics in development, make Ga a potentially promising new therapeutic for P. aeruginosa infections.

Authors

Yukihiro Kaneko, Matthew Thoendel, Oyebode Olakanmi, Bradley E. Britigan, Pradeep K. Singh

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Figure 3

Ga inhibits growth of biofilm-forming cells, stimulates detachment, and its activity is enhanced by lactoferrin.

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Ga inhibits growth of biofilm-forming cells, stimulates detachment, and ...
(AB) The dividing time (A) and detachment rate (B) of attached bacteria were increased by 1 μM Ga(NO3)3. Time-lapse images of GFP-labeled P. aeruginosa in biofilm reactors from 4 separate experiments were collected in the presence and absence of 1 μM Ga(NO3)3. Dividing times of attached bacteria were measured by counting the number of frames between 50 cell divisions. The percentage of daughter cells detaching from the surface was determined by observing 100 daughter cells and averaging the results; *P < 0.001 versus the untreated control. (C) Ga potentiates the growth-inhibitory effects of lactoferrin. 104 planktonic P. aeruginosa were inoculated in biofilm medium with various concentrations of lactoferrin alone or lactoferrin mixed with Fe or Ga. Cultures were then grown for 24 hours, and the OD600 was measured. Fe (1 μM) blocked the growth-inhibitory effects of lactoferrin, but Ga potentiated it. Results are the mean of 3 separate experiments; error bars are SEM; *P < 0.001 versus the untreated control. (D) Ga potentiates the antibiofilm effects of lactoferrin. Confocal microscopic images of GFP-labeled P. aeruginosa grown in flow cells with biofilm medium alone and medium containing lactoferrin (20 μg/ml) or lactoferrin (20 μg/ml) plus Ga(NO3)3 (1 μM). Images are top views (x-y plane) obtained after 5 days of growth; scale bar: 50 μm. Results are representative of 3 separate experiments. See Supplemental Figure 3 for counts of attached bacteria.