Synergetic Antimicrobial Activity and Mechanism of Clotrimazole-Linked CO-Releasing Molecules

Mendes, Sofia S; Marques, Joana; Mesterházy, Edit; Straetener, Jan; Arts, Melina; Pissarro, Teresa; Reginold, Jorgina; Berscheid, Anne; Bornikoel, Jan; Kluj, Robert Maria; Mayer, Christoph; Oesterhelt, Filipp; Friães, Sofia; Royo, Beatriz; Schneider, Tanja; Brötz‐Oesterhelt, Heike; Romão, Carlos C.; Saraiva, Lı́gia M.

doi:10.1021/acsbiomedchemau.2c00007

Cited by 32 publications

(73 citation statements)

References 72 publications

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“…ranging from ca. -9 to -11 kcal/mol) are fully consistent with the experimental results reported by Wenzel et al [31] and Mendes et al [48], in that inhibition of these proteins would lead to membrane disorganization and affect peptidoglycan/wall biosynthesis [76,[80][81][82][83][84].…”

Section: Molecular Docking Study -Membrane Bound S Aureus Proteinssupporting

confidence: 90%

“…compound 14 in Figure 4, targets the cytoplasmic membrane of Bacillus subtilis, affecting its architecture and disrupting essential cellular processes taking place at the membrane, such as respiration, and cell wall biosynthesis and integrity [31]. Similarly Mendes et al have shown that the mechanism of action of the fac-[Re(CO)3(bpy)(ctz)] + complex (17 in Figure 4, where ctz = the drug clotrimazole) involves a sequence of events initiated by membrane insertion, followed by membrane disorganization, inhibition of peptidoglycan biosynthesis, and break down of the membrane potential [48].…”

Section: Molecular Docking Study -Membrane Bound S Aureus Proteinsmentioning

confidence: 92%

“…We found that none of the dicarbonyl complexes showed antimicrobial potential. Only compounds 4b, 5b and 11 were weakly active against S. aureus strains, but their MIC values (25 and 50 µM, respectively) are much higher than active rhenium complexes 13-19 (Figure 4) [32,33,[48][49][50]. [33]; complex 14 [32]; complexes 15, 16, 18 and 19 [49,50]; complex 17 [48].…”

Section: Antimicrobial Properties Of Complexesmentioning

confidence: 97%

“…In the last decade, complexes of virtually all transition metals have been evaluated as antimicrobial agents [25][26][27][28], with rhenium (Re), among others [29,30], showing promising potential for new antibiotic development [31][32][33][34]. While some transition metal complexes [35][36][37][38][39][40], predominantly of group 8 [41][42][43] and 9 [44][45][46][47], act against Gram-negative bacteria, carbonyl rhenium complexes have demonstrated very potent activity towards Gram-positive pathogens, particularly towards Staphylococcus aureus involving both methicillin-resistant (MRSA) and methicillin-sensitive (MSSA) strains [32][33][34][48][49][50].…”

Section: Introductionmentioning

confidence: 99%

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Antimicrobial Activity of Rhenium Di- and Tricarbonyl Diimine Complexes: Insights on Membrane-Bound S. aureus Proteins Binding

Schindler

Cortat

Nedyalkova

et al. 2022

Preprint

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Antimicrobial resistance is one of the major human health threats with significant impact on the global economy. Antibiotics are becoming increasingly ineffective as drug-resistance spreads, imposing an urgent need for new and innovative antimicrobial agents. Metal complexes are an untapped source of antimicrobial potential. Rhenium complexes, amongst others, are particularly attractive due to their low in vivo toxicity and high antimicrobial activity, but little is known about their targets and mechanism of action. In this study, a series of rhenium di- and tricarbonyl diimine complexes was prepared and evaluated for their antimicrobial potential against 8 dif-ferent microorganisms comprising Gram-negative and -positive bacteria. Our data showed that none of the Re dicarbonyl or neutral tricarbonyl species have either bactericidal or bacteriostatic potential. In order to identify possible targets of the molecules, and thus possibly understand the observed differences in the antimicrobial efficacy of the molecules, we computationally evaluated the binding affinity of active and inactive complexes against structurally characterized membrane bound S. aureus proteins. The computational analysis indicates two possible major targets for this class of compounds, namely lipoteichoic acids flippase (LtaA) and lipoprotein signal peptidase II (LspA). Our results, consistent with published in vitro studies, will be useful for future design of rhenium tricarbonyl diimine-based antibiotics.

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Section: Molecular Docking Study -Membrane Bound S Aureus Proteinssupporting

confidence: 90%

Section: Molecular Docking Study -Membrane Bound S Aureus Proteinsmentioning

confidence: 92%

Section: Antimicrobial Properties Of Complexesmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Antimicrobial Activity of Rhenium Di- and Tricarbonyl Diimine Complexes: Insights on Membrane-Bound S. aureus Proteins Binding

Schindler

Cortat

Nedyalkova

et al. 2022

Preprint

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“…The few in-depth studies on the mechanism of action of metallobiotics in recent years have indicated that metal compounds are likely to affect multiple targets inside of microbes. 17,26,[112][113] This makes them well suited to avoid rapid resistance development but also increases the difficulty in narrowing down their exact mode of action. 114 On behalf of CO-ADD we invite researchers around the world to submit their (well characterized) metal complexes for antimicrobial testing to advance our collective knowledge on this promising and underexplored compound class.…”

Section: Discussionmentioning

confidence: 99%

Metal Complexes as Antifungals? – From a Crowd-Sourced Compound Library to First In Vivo Experiments

Frei

Elliott

Kan

et al. 2022

Preprint

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There are currently fewer than ten antifungal drugs in clinical development, but new fungal strains, which are resistant to most current antifungals are spreading rapidly across the world. To prevent a second resistance crisis, new classes of antifungal drugs are urgently needed. Metal complexes have proven to be promising candidates for novel antibiotics, but so far, few compounds have been explored for their potential application as antifungal agents. In this work we report the evaluation of 1039 metal-containing compounds that were screened by the Community for Open Antimicrobial Drug Discovery (CO-ADD). We show that 20.9% of all metal compounds tested have antimicrobial activity against two representative Candida and Cryptococcus strains, compared with only 1.1% of the >300,000 purely organic molecules tested through CO-ADD. We identified 90 metal compounds (8.7%) that show antifungal activity while not displaying any cytotoxicity against mammalian cell lines or haemolytic properties at similar concentrations. The structures of 21 metal complexes which display high antifungal activity (MIC ≤ 1.25 µM) are discussed and evaluated further against a broad panel of yeasts. Most of these have not been evaluated for antifungal activity. Eleven of these metal complexes were tested for toxicity in the Galleria mellonella moth larvae model, revealing that only one compound showed signs of toxicity at the highest injected concentration. Lastly, we demonstrated that the organo-Pt(II) cyclooctadiene complex Pt1 significantly reduces fungal load in an in vivo G. mellonella infection model. These findings showcase that the structural and chemical diversity of metal-based compounds can be an invaluable tool in the development of new drugs against infectious diseases.

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Harnessing Transition Metal Scaffolds for Targeted Antibacterial Therapy

Weng,

Tan,

Koh

et al. 2023

Angewandte Chemie

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Antimicrobial resistance, caused by persistent adaptation and growing resistance of pathogenic bacteria to overprescribed antibiotics, poses one of the most serious and urgent threats to global public health. The limited pipeline of experimental antibiotics in development further exacerbates this looming crisis and new drugs with alternative modes of action is needed to tackle evolving pathogenic adaptation and mutation. Transition metal complexes can replenish this diminishing stockpile of drug candidates by providing compounds with unique properties that are not easily accessible by pure organic scaffolds. We spotlight four emerging strategies to harness these unique properties to develop new targeted antibacterial agents.

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Synergetic Antimicrobial Activity and Mechanism of Clotrimazole-Linked CO-Releasing Molecules

Cited by 32 publications

References 72 publications

Antimicrobial Activity of Rhenium Di- and Tricarbonyl Diimine Complexes: Insights on Membrane-Bound S. aureus Proteins Binding

Antimicrobial Activity of Rhenium Di- and Tricarbonyl Diimine Complexes: Insights on Membrane-Bound S. aureus Proteins Binding

Metal Complexes as Antifungals? – From a Crowd-Sourced Compound Library to First In Vivo Experiments

Harnessing Transition Metal Scaffolds for Targeted Antibacterial Therapy

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