The Antifungal Peptide MCh-AMP1 Derived From Matricaria chamomilla Inhibits Candida albicans Growth via Inducing ROS Generation and Altering Fungal Cell Membrane Permeability

The rise of antifungal drug resistance in species responsible for life threatening candidiasis is considered as an increasing challenge for the public health. MCh-AMP1 has previously been reported as a natural peptide from L. flowers with broad-spectrum antifungal activity against human pathogenic m...

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Bibliographic Details
Published in:Frontiers in microbiology 2020-01, Vol.10, p.3150-3150
Main Authors: Seyedjavadi, Sima Sadat, Khani, Soghra, Eslamifar, Ali, Ajdary, Soheila, Goudarzi, Mehdi, Halabian, Raheleh, Akbari, Reza, Zare-Zardini, Hadi, Imani Fooladi, Abbas Ali, Amani, Jafar, Razzaghi-Abyaneh, Mehdi
Format: Article
Language:English
Subjects:
antifungal activity
antifungal peptides
Candida albicans
electron microscopy
Microbiology
peptide synthesis
time killing assay
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Summary:The rise of antifungal drug resistance in species responsible for life threatening candidiasis is considered as an increasing challenge for the public health. MCh-AMP1 has previously been reported as a natural peptide from L. flowers with broad-spectrum antifungal activity against human pathogenic molds and yeasts. In the current study, the mode of action of synthetic MCh-AMP1 was investigated against , the major etiologic agent of life-threatening nosocomial candidiasis at cellular and molecular levels. ATCC 10231 was cultured in presence of various concentrations of MCh-AMP1 (16-64 μg/mL) and its mode of action was investigated using plasma membrane permeabilization assays, reactive oxygen species (ROS) induction, potassium ion leakage and ultrastructural analyses by electron microscopy. MCh-AMP1 showed fungicidal activity against at the concentrations of 32 and 64 μg/mL. The peptide increased fungal cell membrane permeability as evidenced by elevating of PI uptake and induced potassium leakage from the yeast cells. ROS production was induced by the peptide inside the fungal cells to a maximum of 64.8% at the concentration of 64 μg/mL. Scanning electron microscopy observations showed cell deformation as shrinkage and folding of treated yeast cells. Transmission electron microscopy showed detachment of plasma membrane from the cell wall, cell depletion and massive destruction of intracellular organelles and cell membrane of the fungal cells. Our results demonstrated that MCh-AMP1 caused cell death via increasing cell membrane permeability and inducing ROS production. Therefore, MCh-AMP1 could be considered as a promising therapeutic agent to combat infections.
ISSN:1664-302X
1664-302X
DOI:10.3389/fmicb.2019.03150