Gallium(III)-Salophen As a Dual Inhibitor of Heme Sensing and Iron Acquisition

Overview

Journal ACS Infect Dis

Specialties Infectious Diseases
Microbiology
Pharmacology

Date 2020 Jun 20

PMID 32551497

Citations 13

Authors

Garrick Centola

Daniel J Deredge

Kellie Hom

Yong Ai

Alecia T Dent

Fengtian Xue

Angela Wilks

Affiliations

Soon will be listed here.

Abstract

is an opportunistic bacterium that causes life-threatening infections in immunocompromised patients. In infection, it uses heme as a primary iron source and senses the availability of exogenous heme through the heme assimilation system (Has), an extra cytoplasmic function σ-factor system. A secreted hemophore HasAp scavenges heme and, upon interaction with the outer-membrane receptor HasR, activates a signaling cascade, which in turn creates a positive feedback loop critical for sensing and adaptation within the host. The ability to sense and respond to heme as an iron source contributes to virulence. Consequently, the inhibition of this system will lead to a disruption in iron homeostasis, decreasing virulence. We have identified a salophen scaffold that successfully inhibits the activation of the Has signaling system while simultaneously targeting iron uptake via xenosiderophore receptors. We propose this dual mechanism wherein free Ga-salophen reduces growth through uptake and iron mimicry. A dual mechanism targeting extracellular heme signaling and uptake together with Ga-induced toxicity following active Gasalophen uptake provides a significant therapeutic advantage while reducing the propensity to develop resistance.

Citing Articles

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