Effects of clary sage oil and its main components, linalool and linalyl acetate, on the plasma membrane of Candida albicans: an in vivo EPR study

Blaskó, Ágnes; Gazdag, Zoltán; Gróf, Pál; Máté, Gábor; Sárosi, Szilvia; Krisch, Judit; Vágvölgyi, Csaba; Makszin, Lilla; Pesti, Miklós

doi:10.1007/s10495-016-1321-7

Cited by 22 publications

(17 citation statements)

References 67 publications

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“…Our results clearly indicate the existence of oxidative stress intensity-dependent regulation of the antioxidant system. To summarize the findings related to the adverse acute toxicity effects of Lol at high (70-80%) survival rate (in the present study), these can be explained in terms of the following processes at the molecular level: (i) Lol induces damage in the plasma membrane structure, parallel with increase in membrane fluidity [5,22], (ii) Lol depresses the respiratory rate through interference with mitochondrial complexes I and II, resulting in a decrease in ATP level and cell viability [43; this study], (iii) Lol induces the accumulation of peroxides through mitochondrial-dependent O 2 •generation and membrane-dependent lipid peroxidation [12, 43; this study), which (iv) alters the concentration of the crucial antioxidant GSH and results increased GSSG content [43; this study] and (v) up-or down-regulates the activities of certain antioxidant enzymes (GR, GPx and CAT) in a concentration-dependent manner (the present study).…”

Section: Discussionmentioning

confidence: 91%

“…In chronic and long-term acute tests, (i) Lol inhibits one of the key enzymes of sterol biosynthesis [10,22,24], (ii) leading to disorganization of the plasma membrane through changes in the composition of the plasma membrane and loss of essential cell components [5,8], and (iii) the ROS-induced unbalanced redox state may contribute to a cell cycle arrest and DNA damage, resulting in apoptosis or necrosis [19,46].…”

Section: Discussionmentioning

confidence: 99%

“…A well-characterized adenine auxotroph C. albicans strain 33erg + (ATCC 44829, American Type Culture Collection Maryland, USA) was selected for the experiments [33]. This strain was the same as we applied earlier to investigate the modes of action of clary sage oil, and its main components Lol and linalyl acetate [5]. Mid-exponential phase cultures were obtained on a shaker operating at a shaking frequency of 33.3 Hz in liquid minimal medium (MM) containing 1% dextrose, 0.5% (NH 4 ) 2 SO 4 , 0.1% KH 2 PO 4 , 0.05% MgSO 4 (w/v) and 50 μg ml −1 adenine, 2 μg ml -1 biotin, 4 μg ml -1 thiamine, pH 4.1, at 30 °C.…”

Section: Strain and Culture Conditions Germ Tube Induction Assay Andmentioning

confidence: 99%

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Linalool-induced oxidative stress processes in the human pathogen Candida albicans

Máté

Kovács

Gazdag

et al. 2017

Acta Biologica Hungarica

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The present study investigated the linalool (Lol)-induced effects in acute toxicity tests in the human pathogen Candida albicans (C. albicans). Lol treatments induced reduced germ tube formation of the pathogen, which plays a crucial role in the virulence. In comparison with the untreated control, the exposure of 107 cells ml to 0.7 mM or 1.4 mM Lol for one hour induced 20% and 30% decrements, respectively, in the colony-forming ability. At the same time, these treatments caused dose-dependent decrease in the levels of superoxide anion radical and total reactive oxygen species, while there was 1.5 and 1.8-fold increases in the concentrations of peroxides and lipid peroxides, respectively, indicating oxidative stress induction in the presence of Lol. Lol treatments resulted in different adaptive modifications of the antioxidant system. In 0.7 mM-treated cells, decreased specific activities of superoxide dismutase and catalase were detected, while exposure to 1.4 mM Lol resulted in the up-regulation of catalase, glutathione reductase and glutathione peroxidases.

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Section: Discussionmentioning

confidence: 91%

Section: Discussionmentioning

confidence: 99%

Section: Strain and Culture Conditions Germ Tube Induction Assay Andmentioning

confidence: 99%

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Linalool-induced oxidative stress processes in the human pathogen Candida albicans

Máté

Kovács

Gazdag

et al. 2017

Acta Biologica Hungarica

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“…Terpenoids can function as antimicrobial agents to protect their natural hosts, with antibacterial activity occurring via disruption of the lipid membrane, resulting in the alteration of membrane organization and function [1,6]. As a result of lipophilic compounds partitioning into the lipid bilayer, damage occurs in the cell membrane by impairing vital functions (e.g., loss of ions, metabolites, lipids, and proteins; and dissipation of the pH gradient and electrical potential) [6][7][8]. Enzymes and DNA have also been mentioned as possible targets, as lipophilic compounds tend to associate with the hydrophobic core of several proteins leading to conformational changes, and consequently protein inactivation [6].…”

Section: Introductionmentioning

confidence: 99%

Prediction of Terpenoid Toxicity Based on a Quantitative Structure–Activity Relationship Model

Perestrelo

Silva

Fernandes

2019

Foods

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Terpenoids, including monoterpenoids (C 10 ), norisoprenoids (C 13 ), and sesquiterpenoids (C 15 ), constitute a large group of plant-derived naturally occurring secondary metabolites with highly diverse chemical structures. A quantitative structure-activity relationship (QSAR) model to predict terpenoid toxicity and to evaluate the influence of their chemical structures was developed in this study by assessing in real time the toxicity of 27 terpenoid standards using the Gram-negative bioluminescent Vibrio fischeri. Under the test conditions, at a concentration of 1 µM, the terpenoids showed a toxicity level lower than 5%, with the exception of geraniol, citral, (S)-citronellal, geranic acid, (±)-α-terpinyl acetate, and geranyl acetone. Moreover, the standards tested displayed a toxicity level higher than 30% at concentrations of 50-100 µM, with the exception of (+)-valencene, eucalyptol, (+)-borneol, guaiazulene, β-caryophellene, and linalool oxide. Regarding the functional group, terpenoid toxicity was observed in the following order: alcohol > aldehyde~ketone > ester > hydrocarbons. The CODESSA software was employed to develop QSAR models based on the correlation of terpenoid toxicity and a pool of descriptors related to each chemical structure. The QSAR models, based on t-test values, showed that terpenoid toxicity was mainly attributed to geometric (e.g., asphericity) and electronic (e.g., maximum partial charge for a carbon (C) atom (Zefirov's partial charge (PC)) descriptors. Statistically, the most significant overall correlation was the four-parameter equation with a training coefficient and test coefficient correlation higher than 0.810 and 0.535, respectively, and a square coefficient of cross-validation (Q 2 ) higher than 0.689. According to the obtained data, the QSAR models are suitable and rapid tools to predict terpenoid toxicity in a diversity of food products.

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“…Terpenoids can function as antimicrobial agents to protect their natural hosts, with antibacterial activity occurring via disruption of the lipid membrane, resulting in alteration of membrane organization and functions [1,6]. As a result of lipophilic compounds partitioning into the lipid bilayer damage occurs in the cell membrane by impairing vital functions (e.g., ions, metabolites, lipids, and proteins loss; dissipation of the pH gradient and electrical potential) [6][7][8]. However, enzymes and DNA have also been mentioned as possible targets, as lipophilic compounds tend to associate with the hydrophobic core of several proteins leading to conformational changes, and consequently protein inactivation [6].…”

Section: Introductionmentioning

confidence: 99%

Prediction of Terpenoids Toxicity Based on Quantitative Structure-Activity Relationships Model

Perestrelo¹,

C²,

Mx³

et al. 2019

Preprint

View full text Add to dashboard Cite

Terpenoids, including monoterpenoids (C10), norisoprenoids (C13) and sesquiterpenoids (C15), constitute a large group of plant-derived naturally occurring secondary metabolites which chemical structure is highly diverse. A quantitative structure-activity relationship (QSAR) model to predict the terpenoids toxicity and to evaluate the influences of their chemical structure, was developed in this study, by assessing the toxicity of 27 terpenoid standards using Gram-negative bioluminescent Vibrio fischeri, in real time. Under the test conditions, at concentration of 1 µM, the terpenoids showed a toxicity level lower than five %, with exception of geraniol, citral, (S)-citronellal, geranic acid, (±)-α-terpinyl acetate and geranyl acetone. Moreover, the standards tested displayed a toxicity level higher than 30 % at concentration of 50 to 100 µM, with the exception of (+)-valencene, eucalyptol, (+)-borneol, guaiazulene, β-caryophellene and linalool oxide. Regarding the functional group, the terpenoids toxicity was observed in the following order: alcohol > aldehyde ~ ketone > ester > hydrocarbons. CODESSA software was employed to develop the QSAR models based on the correlation of terpenoids toxicity and a pool of descriptors related to each chemical structure. The QSAR models, based on t-test values, showed that terpenoids toxicity was mainly attributed to geometric (e.g., asphericity) and electronic (e.g., max partial charge for a C atom [Zefirov's PC]) descriptors. Statistically, the most significant overall correlation was the four-parameter equation with training and test coefficient correlation higher than 0.810 and 0.535, respectively, and square coefficient of cross-validation (Q2) higher than 0.689. According to the obtained data, the QSAR models are a suitable and a rapid tool to predict the terpenoids toxicity in a diversity of food products.

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Effects of clary sage oil and its main components, linalool and linalyl acetate, on the plasma membrane of Candida albicans: an in vivo EPR study

Cited by 22 publications

References 67 publications

Linalool-induced oxidative stress processes in the human pathogen Candida albicans

Linalool-induced oxidative stress processes in the human pathogen Candida albicans

Prediction of Terpenoid Toxicity Based on a Quantitative Structure–Activity Relationship Model

Prediction of Terpenoids Toxicity Based on Quantitative Structure-Activity Relationships Model

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