The Candidate Antimalarial Drug MMV665909 Causes Oxygen-Dependent mRNA Mistranslation and Synergizes with Quinoline-Derived Antimalarials

Vallières, Cindy; Avery, Simon V.

doi:10.1128/aac.00459-17

Cited by 9 publications

(8 citation statements)

References 62 publications

(100 reference statements)

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“…In contrast to the observed rescue of Cu sensitivity via overexpression of Yah1 ( Figures 1 B and 1C) or of pro-oxidant action via Rli1 ( Alhebshi et al., 2012 , Laleve et al., 2016 , Vallieres and Avery, 2017 ), increased expression of nonessential FeS proteins is known potentially to exacerbate ROS stress. This is because of the increased pool of labile FeS which, following turnover (e.g., ROS mediated), leads to the accumulation of free Fe and further potential for ROS stress via Fe-catalyzed Fenton chemistry ( Keyer and Imlay, 1996 , Liochev and Fridovich, 1999 ).…”

Section: Resultscontrasting

confidence: 56%

Mitochondrial Ferredoxin Determines Vulnerability of Cells to Copper Excess

Vallières

Holland

Avery

2017

Cell Chemical Biology

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SummaryThe essential micronutrient copper is tightly regulated in organisms, as environmental exposure or homeostasis defects can cause toxicity and neurodegenerative disease. The principal target(s) of copper toxicity have not been pinpointed, but one key effect is impaired supply of iron-sulfur (FeS) clusters to the essential protein Rli1 (ABCE1). Here, to find upstream FeS biosynthesis/delivery protein(s) responsible for this, we compared copper sensitivity of yeast-overexpressing candidate targets. Overexpression of the mitochondrial ferredoxin Yah1 produced copper hyper-resistance. 55Fe turnover assays revealed that FeS integrity of Yah1 was particularly vulnerable to copper among the test proteins. Furthermore, destabilization of the FeS domain of Yah1 produced copper hypersensitivity, and YAH1 overexpression rescued Rli1 dysfunction. This copper-resistance function was conserved in the human ferredoxin, Fdx2. The data indicate that the essential mitochondrial ferredoxin is an important copper target, determining a tipping point where plentiful copper supply becomes excessive. This knowledge could help in tackling copper-related diseases.

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Section: Resultscontrasting

confidence: 56%

Mitochondrial Ferredoxin Determines Vulnerability of Cells to Copper Excess

Vallières

Holland

Avery

2017

Cell Chemical Biology

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“…Quinoline-containing compounds are known to provoke reactive oxygen species (ROS) production ( Radfar et al, 2008 ; Tafazoli and O’Brien, 2009 ; Laleve et al, 2016 ). As ROS may in turn promote oxidation of RNA or of proteins involved in translation ( Ling and Soll, 2010 ; Vallieres and Avery, 2017b ), alternative potential causes of mistranslation, we tested whether the synergy between quinine + hygromycin (associated with elevated mistranslation) could be suppressed by the absence of oxygen. However, synergy was slightly enhanced rather than rescued under anaerobic growth conditions ( Figure 9C ).…”

Section: Resultsmentioning

confidence: 99%

“…One limitation could relate to the apparent drug concentrations needed to control fungal growth, as addressed in the next paragraph. One pertinent point concerning quinine is that common quinine analogs, albeit typically more expensive than quinine, can have much lower effective MICs against fungi ( Table 1 ; Vallieres and Avery, 2017b ).…”

Section: Discussionmentioning

confidence: 99%

Novel Combinations of Agents Targeting Translation That Synergistically Inhibit Fungal Pathogens

et al. 2018

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A range of fungicides or antifungals are currently deployed to control fungi in agriculture or medicine, but resistance to current agents is growing so new approaches and molecular targets are urgently needed. Recently, different aminoglycoside antibiotics combined with particular transport inhibitors were found to produce strong, synergistic growth-inhibition of fungi, by synergistically increasing the error rate of mRNA translation. Here, focusing on translation fidelity as a novel target for combinatorial antifungal treatment, we tested the hypothesis that alternative combinations of agents known to affect the availability of functional amino acids would synergistically inhibit growth of major fungal pathogens. We screened 172 novel combinations against three phytopathogens (Rhizoctonia solani, Zymoseptoria tritici, and Botrytis cinerea) and three human pathogens (Cryptococcus neoformans, Candida albicans, and Aspergillus fumigatus), showing that 48 combinations inhibited strongly the growth of the pathogens; the growth inhibition effect was significantly greater with the agents combined than by a simple product of their individual effects at the same doses. Of these, 23 combinations were effective against more than one pathogen, including combinations comprising food-and-drug approved compounds, e.g., quinine with bicarbonate, and quinine with hygromycin. These combinations [fractional inhibitory combination (FIC) index ≤0.5] gave up to 100% reduction of fungal growth yield at concentrations of agents which, individually, had negligible effect. No synergy was evident against bacterial, plant or mammalian cells, indicating specificity for fungi. Mode-of-action analyses for quinine + hygromycin indicated that synergistic mistranslation was the antifungal mechanism. That mechanism was not universal as bicarbonate exacerbated quinine action by increasing drug uptake. The study unveils chemical combinations and a target process with potential for control of diverse fungal pathogens, and suggests repurposing possibilities for several current therapeutics.

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“…The development of new antifungal drugs raises challenges such as the high costs and the time required for development and licensing of new compounds. To circumvent the slowness and cost of developing new drugs, the screening of chemical libraries and repurposing of drugs that are already commercialized for other purposes is a great opportunity to discover new antifungal compounds (62,64,67,71,(91)(92)(93).…”

Section: Discussionmentioning

confidence: 99%

“…for development and licensing of new compounds. To circumvent the slowness and cost of developing new drugs, the screening of chemical libraries and repurposing of drugs that are already commercialized for other purposes is a great opportunity to discover new antifungal compounds(62,64,67,71,(91)(92)(93).Here we screened the growth of A. fumigatus in the presence of compounds present in two drug libraries and identified 10 compounds, among them five compounds already known as inhibitors of fungal growth including two azolederivatives (econazole nitrate, and oxiconazole nitrate), fluvastatin, that inhibits ergosterol biosynthesis, and iodoquinol and miltefosine, drugs with an unknown mechanism of action. To our knowledge, the other five identified compounds (mesoridazine, cisapride, indinavir sulfate, enalaprilat, and vincristine sulfate) are novel as antifungal agents and have not been reported before.…”

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confidence: 99%

Screening of chemical libraries for new antifungal drugs against Aspergillus fumigatus reveals the potential mechanism of action of miltefosine

Mac

et al. 2021

Preprint

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Aspergillus fumigatus is an important fungal pathogen and the main etiological agent of aspergillosis, a disease characterized by a noninvasive process that can evolve to a more severe clinical manifestation called invasive pulmonary aspergillosis (IPA) in immunocompromised patients. The antifungal arsenal to threat aspergillosis is very restricted. Azoles are the main therapeutic approach to control IPA, but the emergence of azole-resistant A. fumigatus isolates has significantly increased over the last decades. Therefore, new strategies are necessary to combat aspergillosis and drug repurposing has emerged as an efficient and alternative approach for identifying new antifungal drugs. Here, we used a screening approach to analyze A. fumigatus in vitro susceptibility to 1,127 compounds. A. fumigatus was more susceptible to 10 compounds, including miltefosine, a drug that displayed fungicidal activity against A. fumigatus. By screening an A. fumigatus transcription factor null library, we identified a single mutant, which has the rmiA (resistant to miltefosine) gene deleted, conferring a phenotype of susceptibility to miltefosine. The transcriptional profiling (RNA-seq) of the wild-type and the ΔrmiA strains and the Chromatin Immunoprecipitation coupled to next generation sequencing (ChIP-Seq) of a RmiA-tagged strain exposed to miltefosine revealed genes of the sphingolipids pathway that are directly or indirectly regulated by RmiA. Sphingolipids analysis demonstrated that the mutant has overall decreased levels of sphingolipids when growing in the presence of miltefosine. The identification of RmiA represents the first genetic element described and characterized which plays a direct role in miltefosine response in fungi.

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The Candidate Antimalarial Drug MMV665909 Causes Oxygen-Dependent mRNA Mistranslation and Synergizes with Quinoline-Derived Antimalarials

Cited by 9 publications

References 62 publications

Mitochondrial Ferredoxin Determines Vulnerability of Cells to Copper Excess

Mitochondrial Ferredoxin Determines Vulnerability of Cells to Copper Excess

Novel Combinations of Agents Targeting Translation That Synergistically Inhibit Fungal Pathogens

Screening of chemical libraries for new antifungal drugs against Aspergillus fumigatus reveals the potential mechanism of action of miltefosine

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