Thymol Induces Conidial Apoptosis in Aspergillus flavus via

Jul 25, 2018 - Liang-bin Hu , Fang-Fang Ban , hongbo li , Pan-Pan Qian , Qing-Shan Shen , Yan-Yan Zhao , Hai-Zhen Mo , and Xiaohui Zhou. J. Agric...
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Bioactive Constituents, Metabolites, and Functions

Thymol Induces Conidial Apoptosis in Aspergillus flavus via Stimulating K+ Eruption Liang-bin Hu, Fang-Fang Ban, hongbo li, Pan-Pan Qian, QingShan Shen, Yan-Yan Zhao, Hai-Zhen Mo, and Xiaohui Zhou J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b02117 • Publication Date (Web): 25 Jul 2018 Downloaded from http://pubs.acs.org on July 30, 2018

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Journal of Agricultural and Food Chemistry

Thymol Induces Conidial Apoptosis in Aspergillus flavus via Stimulating K+ Eruption Liang-Bin Hua , Fang-Fang Bana, Hong-Bo Lia, Pan-Pan Qiana, Qing-Shan Shena, Yan-Yan Zhaoa, Hai-Zhen Mo a*, Xiaohui Zhoub* a

Department of Food Science, Henan Institute of Science and Technology, Xinxiang

453003, China b

Department of Pathobiology & Veterinary Science, The University of Connecticut;

61 N. Eagleville Rd, Storrs, CT *Corresponding authors E-mail: [email protected] (HM) or [email protected] (XZ)

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ABSTRACT: Aspergillus flavus is a notorious foodborne fungus, posing significant

2

risk of hepatocellular carcinoma or aspergillosis in human. Thymol, as a food

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preservative, could efficiently kill conidia of A. flavus. However, the underlying

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mechanisms by which thymol kills A. flavus are not completely understood. With

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specific fluorescent dyes, we detected several apoptotic hallmarks including

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chromatin condensation, phosphatidylserine externalization, DNA damage,

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mitochondrial depolarization and caspase 9 activation in conidia exposed to

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200µg/ml of thymol, indicating that thymol induced a caspase-dependent conidial

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apoptosis in A. flavus. Chemical-protein interactome (CPI) and autodock analyses

10

showed that KCNAB, homologue to the β-subunit of voltage gated potassium

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channel (Kv) and aldo-keto reductase, was the potential target of thymol. Following

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studies demonsrated that thymol could activate the aldo-keto reductase activity of

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KCNAB in vitro and stimulate a transient K+ efflux in conidia as determined using a

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Port-a-Patch. Blocking K+ eruption by 4-aminopyridine (a universal inhibitor of Kv)

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could significantly alleviate thymol-mediated conidial apoptosis, indicating that

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activation of Kv was responsible for the apoptosis. Taken together, our results

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revealed a K+ efflux-mediated apoptotic pathway in A. flavus, which greatly

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contributed to the development of alternative strategy to control this pathogen.

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KEYWORDS: Aspergillus flavus, thymol, conidia, apoptosis, K+ eruption,

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Voltage-gated potassium channel

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INTRODUCTION

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Aspergillus flavus is notorious as a biological pollutant in our food material, where it

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produces the carcinogenic aflatoxin. More than 28% of the total worldwide cases of

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hepatocellular carcinoma is associated with the intake of aflatoxins 1, 2. Aflatoxins

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are also responsible for some acute poisoning, immune-system dysfunction and

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stunted growth in children 3. In addition, A. flavus causes aspergillosis in

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immunocompromised individuals 4, and is responsible for fungal rhino-sinusitis and

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fungal eye infections (endopthalmitis and keratitis) in some tropical countries (e.g.

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India, Sudan, Kuwait, and Iran) 5, 6. As one of major constituents of essential oil in

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Monarda punctate, thymol (2-isopropyl-5-methylphenol) has been identified with

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antioxidant, antiviral, antitumor, and anti-inflamatory properties 7-10. Nevertheless,

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thymol has been mainly applied as antimicrobial agent to control a broad spectrum

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of microorganisms including Escherichia 11, Salmonella 12, Listeria 13,

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Staphylococcus 14, Actinobacillus 15, Saccharomyces 16, Candida 17, Fusarium 18 and

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etc. Mechanisms underlying its antimicrobial activity has been extensively studied

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involving the inhibition of H(+)-ATPase 19, the interruption of surface electrostatics

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of cell membrane and membrane integrity 20, the reversal of drug efflux pumps 21,

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the inhibition of telomerase activity 16 and the induction of destabilization in the

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DNA secondary structure 22. It should be noted that thymol leads to different death

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mode in different organisms via different ways 16. Thymol has been shown to

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efficiently kill conidia of A. flavus via triggering reactive oxygen species (ROS) and

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reactive nitrogen species (RNS) 23. However, the target of thymol and the death

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mode in conidia of A. flavus are unknown. In this study, we showed that thymol

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targets KCNAB to trigger K+ efflux and consequently induces A. flavus apoptosis.

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Understanding the target of thymol and the mode of cell death would greatly

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contribute to the development of alternative strategy to control A. flavus.

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MATERIALS AND METHODS

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Strains and Chemicals. Aspergillus flavus CGMCC3.2890 was purchased

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from China General Microbiological Culture Collection Center. All spores in this

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study were cultured in Sabourand Dextrose (SD) Medium containing 4% glucose, 1%

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peptone, 1.5% agar power at 30°C. For the drug treatment experiments, spores were

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harvested post thymol (Sigma) treatment for 3~9h at the concentration of 200 µg/ml.

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Thymol was dissolved in dimethylsulfoxide (DMSO) with the concentration of

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DMSO kept below 0.1% in the treatment groups. All other chemical agents were

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analytical grade.

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Detection of Conidial Apoptosis. Conidial apoptosis in A. flavus was evaluated

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by using an Apoptosis and Necrosis Assay Kit (C1056, Beyotime Institute of

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Biotechnology, China). Briefly, the conidia with different treatments were washed

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once with phosphate-buffered saline (PBS, pH 7.4), and then stained with Hoechst

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33342 (10 µg/ml) and propidium iodide (PI) (1 µg/ml) for 30min at 4°C in the dark.

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The apoptotic cells were observed with an inverted fluorescent microscope (Zeiss

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Axio Vert A1) and a flow cytometer (Beckman CytoFLEX FCM).

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Phosphatidylserine Externalization Assay and TUNEL Assay. Spores

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suspension at a density of 2×106 was exposed to 200 µg/ml thymol for 6h, and then

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collected for following assay. Conidial phosphatidylserine externalization (PS) was

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analyzed using an annexin V-FITC apoptosis detection kit (C1063, Beyotime

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Institute of Biotechnology, China), and DNA damage was analyzed using One Step

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TUNEL Apoptosis Assay Kit (C1086, Beyotime Institute of Biotechnology, China).

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All the procedures were performed following the manufacturer’s instructions. Flow

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cytometry and fluorescence microscopy were utilized to monitor the spores with

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positive fluorescence staining.

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Assay for Mitochondrial Membrane Potential. A fluorescent dye JC-1

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(C2005, Institute of Biotechnology, China) was used to analyze mitochondrial

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membrane potential (∆ψm) in conidia of A. flavus. JC-1 dye is capable of

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accumulating potential-dependently in mitochondria. At high ∆ψm, JC-1 aggregates

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and gives a red fluorescence. At low ∆ψm, it depolymerizes to monomers and emits

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green fluorescence. Mitochondrial depolarization is indicated by an increase in the

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green (529 nm)/red (590 nm) fluorescence intensity ratio. JC-1 was uploaded in the

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conidia according to its manual instruction. Corresponding fluorescence assays were

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performed by using a microreader (Thermol, Varioskan Flash) and a fluorescent

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microscope.

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Caspase 9 Activity Assay. Conidial caspase 9 activity was detected by using a

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Kit (C1157, Beyotime Institute of Biotechnology, China) containing the substrate

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(Ac-LEHD- acetyl-Leu-Glu-His-Asp p-nitroanilide) for caspase 9. Spore suspension

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of A. flavus was inoculated into the SD liquid medium with final concentration of

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2×106/mL, and then exposed to 200 µg/mL of thymol for 6h. In parallel, another

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group of spores was exposed to 20 µM of Z-VAD-FMK (a caspase inhibitor) prior to

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the addition of thymol. Subsequently, the spores were washed using PBS, and

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suspended with lysis buffer, followed by ultra-sonication on the ice for 20min. After

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centrifugation at 16,000g, 4°C for 15min, the supernatant was transferred to the

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precooling tube to determine the increase in absorbance at 400 nm indicating

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caspase-9 activity. The release of p-nitroanilide (pNA) was calculated based on a

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standard curve between its amount and its absorbance at 400 nm, and 1U of

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caspase-9 activity was defined as the facilitation of 1 µM of pNA release. Bioinformatics Analysis for the Potential Targets of Thymol. To identify the

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targets of thymol leading to apoptosis in A. flavus, we firstly predicted the proteins in

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human that have potential to interact with thymol through the server of DRAR-CPI

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(http://202.120.31.160/drar/) 24, 25. Some proteins associated with apoptosis were

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picked and then their homologues in A. flavus were identified. Three-dimensional

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structures of these homologues were obtained through homology modeling using

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I-TASSER (http://zhanglab.ccmb.med.umich.edu/I-TASSER/) 26. The structure of

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thymol was obtained from Pubchem database (CID: 6989). The predicted

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interactions between these homologues and thymol were modelled by Autodock 4.2

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27

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. Protein Expression and Purification. The coding sequence of KCNAB was

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cloned from the cDNA library of A. flavus which was prepared by using the Kit

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according to its instructions. Then, it was constructed into pET28a (+) vector with

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Ncol and BamHl, and transformed to E.coli Arctic Express strain by chemical

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transformation. To induce KCNAB expression in the recombination strain, 0.5 mM

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of isopropyl-β-d-thiogalactoside (IPTG) was added into bacterial culture of

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OD600=0.6~0.8, continuing incubation at 220 r/min, 37°C for 4h. The bacterial cells

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were harvested and broken by ultrasonication (400w for 20min) in lysate solution

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(20 mM Tris-HCl containing 1 mM phenylmethanesulfonyl fluoride (PMSF)

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supplemented with one tablet of bacteria protease inhibitor cocktail, pH 8.0). As

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KCNAB was mostly expressed in inclusion bodies, debris containing inclusion

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bodies was collected and washed 3 times with scrubbing solution (20 mM Tris, 1

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mM EDTA, 2 M urea, 1 M NaCl, 1% Triton X-100, pH 8.0). Inclusion bodies were

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resolved with Solution buffer (20 mM Tris, 5 mM dithiothreitol (DTT), 8 M Urea,

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pH 8.0) and dialyzed in a buffer (20 mM Tris-HCl, 0.15 M NaCl, pH 8.0) overnight.

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The purification for KCNAB was carried with the nickel ion affinity

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chromatography column (Ni-IDA -Sepharose CL-6B). KCNAB was eluted by

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elution-Buffer (20 mM Tris-HCl, 250 mM imidazole, 0.15 M NaCl, pH 8.0) and

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dialyzed in 1 M phosphate buffer (PB) (pH 7.4) overnight. The purity of KCNAB

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was evaluated by 12% SDS-PAGE, and its identity was confirmed through detecting

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the His-tag of recombinant KNCAB by western blotting with His antibody (AH158,

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Beyotime Institute of Biotechnology, China) according to its instructions.

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Aldo-keto Reductase Activity of KCNAB. The aldo-keto reductase activity of

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KCNAB was determined according to Weng et al 28 with slight modification. The

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reaction mixture of 0.4 mM NADPH, 10 mM of 4-formylbenzonitrile and 300 µg/ml

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KCNAB protein in PB (pH 7.4) was incubated at 37°C for 2h. The absorption at 340

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nm was measured by a microreader with a µDropTM plate (No. N12391). The

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reductase activity of KCNAB was indicated as a decrease of OD340nm (1U=0.01).

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Blank controls with no KCNAB were incorporated routinely and the background

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NADPH consumption was subtracted.

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Intracellular K+ Assay. Intracellular K+ level in conidia was evaluated by

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applying a K+ fluorescent indicator of PBFI-AM (C270, GeneCopoeia, USA). The

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relative intensity of fluorescence at 500nm excited by 340 nm and 380 nm were

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time-course recorded by a microreader, respectively. The ration between them at

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each time point was calculated, and its curves indicated the dynamical changes of K+

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level in conidia. Flow cytometry was also used to evaluate the changes of K+ level in

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conidia. To decipher the K+ distribution in conidia, double staining including PBFI

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and JC-1 was performed and K+ distribution was evaluated by using a confocal laser

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scanning microscope (Zeiss LSM 180). All these fluorescent probes were loaded into

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conidia 1h prior to the addition of thymol and incubated in the dark at 37°C.

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Automated Patch-clamp Recording. The protoplasts of A. flavus were

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prepared according to Woloshuk 29. Whole cell patch clamp recordings were

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conducted according to Nanion’s standard procedure for the Port-a-Patch (Nanion,

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Germany). Chips with single-hole medium resistance (~10 MΩ) were used for the

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recording of protoplasts. The external perfusion system was also used. After

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initiating the experiment, cell catching, sealing, whole-cell formation, liquid

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application, recording, and data acquisition were performed sequentially. Currents

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were recorded every 0.7s by 500ms voltage ramps from -80 mV to + 80 mV.

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Currents were elicited by application of thymol via the external perfusion system.

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Thymol was made as a 200 mg/ml stock in DMSO and diluted in external recording

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solution to the concentrations indicated. A representative trace of three repeats of

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each experiment was shown.

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Statistics Analysis. All assay were repeated independently at least 3 times and

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experimental date were represented as mean ± SD. The data between two different

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treatments were compared statistically by Student’s t-test. The differences were

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considered significant at P < 0.05.

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RESULTS

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Thymol Induced Conidial Apoptosis in A. flavus.

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In order to explore the conidial death mode in response to thymol, we employed

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a conidial staining with Hoechst 33342/PI. Usually, PI can only enter the dying cells

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leading to a positive staining, and Hoechst 33342 staining is denser in dying or

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apoptotic cells due to condensed conidial chromatin. Thus, Hoechst 33342-enhanced,

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but not PI-positive conidia, were judged as apoptosis. As shown by flow cytometry,

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very limited shifting in red fluorescence (PI-DNA excitation ) distribution of conidia

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occurred when exposed to thymol for even 9h (Figure 1A). However significant

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shifting in blue fluorescence (Hoechst 33342-DNA excitation) distribution could be

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observed since 3h post the exposure to thymol (Figure 1B). By counting, blue

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fluorescent cells were induced in approximately 40% of conidia with 3h exposure to

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thymol, and in over 80% of conidia within 6 h exposure (Figure 1C). Fluorescent

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microscopy further confirmed that thymol led to weak changes in red fluorescence

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but a significantly enhanced blue fluorescence of conidia (Figure S1). Besides

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chromatin condensation, PS as one of characteristics of apoptosis was analyzed with

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an Annexin V-FITC assay. Through flow cytometry, we showed that conidia with

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Annexin staining (FITC fluorescence) was significantly increased when exposed to

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thymol for 6h (Figure 1D). Enhanced conidial green fluorescence was also observed

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by fluorescent microscopy (Figure S2) after exposure to thymol. These results

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indicated positive PS in conidia exposed to thymol for 6h. During apoptosis

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chromosomal DNA could be cleaved into oligo-nucleosomal size fragments, which

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is also a biochemical hallmark of apoptosis 30. By the TUNEL assay in situ,

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positively-shifted conidial distribution in fluorescence (FITC) (Figure 1E) and much

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stronger green fluorescence (Figure S3) could be observed on conidia exposed to

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thymol through flow cytometry and fluorescent microscopy, respectively. This

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indicated the occurrence of DNA cleavage in conidia exposed to thymol for 6h. The

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mitochondrion plays an important role in the execution phase of apoptosis 31. A

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distinctive feature of the early stages of apoptosis is the disruption of active

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mitochondria leading to alteration in membrane potential 32, 33. JC-1 dye is utilized to

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manifest mitochondrial depolarization occurring in apoptosis indicated as an increase

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in the green (529 nm)/red (590 nm) fluorescence intensity ratio. Our results showed

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that thymol treatment led to a significant increase in conidial green/red fluorescence

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intensity ratio (Figure 1F). Fluorescence microscopy showed that conidia was almost

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green after treatment with thymol (Figure S4), indicating that exposure to thymol led

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to the occurrence of mitochondrial depolarization in conidia. Taken together, these

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results showed that conidia of A. flavus undergo apoptosis after treatment with

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thymol.

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Thymol-mediated Apoptosis in A. flavus is Caspase-dependent.

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In fungi, apoptosis can be either caspase (metacaspase) dependent or

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independent 33. Caspase-9, is specific to the mitochondrial (intrinsic) pathway, and

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can act directly as an apoptotic effector molecule 33, 34. Considering mitochondrial

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disruption in conidia, we determined the activity of caspase 9 in conidia exposed to

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thymol. Our results showed that caspase 9 activity in conidia was significantly

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activated when exposed to thymol for 6h (Figure 2). The addition of its inhibitor

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(Z-VAD-FMK) prior to the exposure to thymol significantly blocked the activation

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of caspase 9 activity (Figure 2A) and alleviated the occurrence of conidial apoptosis

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in response to thymol treatment (Figure 2B). These results indicated that conidial

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apoptosis induced by thymol was caspase-dependent.

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KCNAB is a Target of Thymol Mediating Conidial Apoptosis.

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Identification of the endogenous molecular switches that trigger fungal

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apoptosis is of paramount importance 35. Receptors targeted by thymol leading to

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apoptosis were predicted through several steps as shown in Figure S5A. Firstly, we

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used chemical-protein interactome (CPI) profiles through the server DPDR-CPI to

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predict potential targets of thymol in humans. This analysis provided a list of 393

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proteins with the potential to interact with thymol. We selected voltage-gated

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potassium channel (Kv) subunit beta-2 (encoded by KCNAB2 gene; PBD ID: 1ZSX)

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for further investigation because (1) KCNAB2 has been reported involved in

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apoptosis in cancer cells, and (2) KCNAB2 has a higher predictive score to interact

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with thymol. In addition, KCNAB2 harbors dual activities including Kv regulation

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and aldo-keto reductase, and thus KCNAB2 would be more like a molecular switch

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to regulate metabolic state in response to external stimulation. More importantly, a

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KCNAB2 homologue (KCNAB; Gene ID: 7908969) exists in A. flavus. Using

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I-TASSER, the three three-dimensional structures of KCNAB were constructed

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(Figure S5B). The quality of model was assessed by SAVES, and the results showed

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that 97.7% residues of KCNAB model was in the favored and allowed region, and

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96.57% of the residues had an averaged 3D-1D score≥0.2. The overall quality factor

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of ERRAT was 94.135. The potential interactions between KCNAB and thymol were

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predicated by Autodock 4.2. The results showed that thymol potentially interacted

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with 4 amino acids of KCNAB, which were listed in the annotation tables in Figure

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S5B. To further determine the interaction between KCNAB and thymol, KCNAB was

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cloned into a pET-28a (+) vector for expression in E. coli DE3. Expressed KCNAB

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was purified on a Ni+-IDA-Sepharose CL-6B affinity column. Through SDS-PAGE,

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we showed that KCNAB was obtained at electrophoretic purity, and further western

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blotting confirmed the identity of recombinant KCNAB (Figure 3A). With NADPH

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and 4-formylbenzonitrile as substrates, the aldo-keto activity of KCNAB could be

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determined by detecting the decreasing absorbance at 340nm due to the consumption

239

of NADPH. The results showed that the addition of thymol significantly increased

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the activity of KCNAB (Figure 3B), indicating a direct interaction between KCNAB

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and thymol. Considering potential regulation of Kv by KCNAB, we monitored the

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changes of intracellular K+ level in conidia exposed to thymol with PBFI-AM, a

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cell-permeable fluorescent K+ binding probe. It was interesting that a transient

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eruption of intracellular K+ was observed after treatment with thymol using both

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microreader (Figure 4A) and flow cytometry (Figure 4B). Treatment with

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4-aminopyridine (4-Ap), a specific inhibitor of Kv, significantly mitigated the K+

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eruption in conidia in response to thymol (Figure 4A,B). What’s more important,

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4-Ap also significantly alleviated thymol-induced conidial apoptosis (Figure 4C,D).

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This strongly supported that thymol targeted a Kv system in conidia of A. flavus

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leading to apoptosis.

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Thymol Promotes K+ Efflux in Conidia of A. flavus.

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The opening of Kv channels would result in an efflux of positive charge due to

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the concentration gradient of K+ that exists across the cell surface membrane 36.

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However, we observed an increasing intracellular K+ level using K+ probe, PBFI.

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Using confocal microscope, we were surprised to see that K+-fluorescence probe

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PBFI was circularly distributed around the cellular surface (Figure 5A). If high

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concentration of K+ gathers around the cellular surface, there should form a layer of

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high potential similar to mitochondrial intermembrane space full of H+. Therefore,

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we employed both PBFI (probe for K+) and JC-1 (membrane potential) to detect the

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K+ distribution in conidia in response to thymol. The results showed both green

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fluorescence from PBFI and red fluorescence from accumulated JC-1 were

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distributed around the cell surface after addition of thymol (Figure 5A), strongly

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suggesting that K+-PBFI probe gathered circularly inside of conidial envelope.

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Interestingly, in the absence of PBFI staining, thymol treatment led to few changes in

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JC-1 distribution in conidia in which red fluorescence was scattered in the cell space

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(Figure 5B), indicating that high potential layer was not formed upon thymol

267

treatment. Therefore, we reasoned that gathering of K+ in conidia exposed to thymol

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was due to the existence of its fluorescent probe PBFI. In order to explore the true

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movement of K+, we prepared the protoplast of A. flavus and monitored the K+ flow

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in protoplast exposed to thymol by using an automated patch-clamp recorder. A.

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flavus protoplast showed an outward K+ current under certain positive voltages,

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which showed the voltage-gated properties of Kv (Figure 6A). The I-V curves

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indicated a significant activation of Kv leading to more dramatic outward K+ current

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in response to thymol (Figure 6B). Taken together it could be concluded that thymol

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induced conidial apoptosis in A. flavus by stimulating K+ efflux via activating Kv. As

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for K+ gathering in the presence of K+ fluorescent probe, we interpreted that it is

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attributed to binding of K+ with probe. K+-probe complex could not pass the Kv

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channel, resulting in the trapped K+ gathering at the inside of the plasma membrane

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(Figure S6).

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DISCUSSION

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A. flavus vigorously produces conidia, leading to food contamination and

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human infection 4,37. Usually these conidia are relatively-resistant to stress

283

including desiccation, heat, and UV stress 38, 39, which poses a great challenge to

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eliminate them. Our results revealed that thymol could induce conidial death via

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apoptosis, which provided not only new insights into the development of strategy

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to control A. flavus contamination, but also an opportunity to further study the

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conidial death mechanism in A. flavus. To our knowledge, there are few reports

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on fungal apoptosis induced by thymol. We have detected necrosis instead of

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apoptosis in S. cerevisiae exposed to thymol 40. Thus, the mechanism underlying

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conidial apoptosis in A. flavus is different from those in other fungi by thymol.

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Sharon et al 33 proposed an apoptotic pathways in fungi wherein caspases

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cascades mediate apoptosis. However, no caspase has been identified in A. flavus

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except for metacaspase CasA and CasB. It has been reported that perillaldehyde

294

activated metacapase and mediated apoptosis in A. flavus 41. However, there was

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no evidence in that study to support the roles of metacaspase in apoptosis

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induced by perillaldehyde. Although there has been no caspase 9 present in the

297

genome of A. flavus, we still detected the activity of caspase 9 with its specific

298

substrate in vitro. This suggested there should be some homologues of caspase 9

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in A. flavus with low sequence similarities to the known caspase 9 sequences.

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Caspase 9 is considered as an important executor in mitochondrial pathway of

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apoptosis 33, and JC-1 dying indicated mitochondrial disruption in conidia

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exposed to thymol. Thus, we hypothesize that thymol induces conidial apoptosis

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via a classical mitochondrial pathway. This hypothesis was supported by our

304

results that Z-VAD-FMK that specifically inhibited the activation of caspase 9

305

could alleviate thymol-mediate conidial apoptosis.

306 307

How does thymol trigger conidial apoptosis? We identified KCNAB, a potential β-subunit of Kv in A. flavus, with great potential to interact with thymol.

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Further analysis showed that thymol could activate aldo-keto reductase activity

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of the purified recombinant protein KCNAB in vitro, demonstrating that

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KCNAB directly targets KCNAB. In mammals, Kv with such a subunit is a

311

tetrameric integral membrane protein that, upon membrane depolarization, allow

312

potassium ions to flow out of a cell42. Activation of Kv and a loss of intracellular

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K+ is necessary for caspase-mediated neuronal apoptosis induced by

314

oxidant-liberated Zn2+ 43. Our results showed that thymol could stimulate K+

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efflux and blocking K+ efflux via 4-Ap could significantly alleviate

316

thymol-mediated conidial apoptosis, indicating that activation of Kv was

317

responsible for this apoptosis. Based on these results, we concluded that some

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Kv system containing KCNAB was the endogenous receptor targeted by thymol

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triggering apoptosis. Thymol-based compounds have been proved as agonists of

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transient receptor potential (TRP) family of ion channel which involved in a

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wide array of physiological functions 44. Kv activation attributed to novel

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potential of thymol as a therapeutic agent.

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It is worth to note that K+ fluorescent probes could indicate the intracellular

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K+ concentration. However, such probe may lead to a misleading interpretation

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on K+ influx or efflux as the K+-probe complex is too large to be transported

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through the cell membrane. Electrophysiological techniques based on

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auto-clamp-patch could provide more reliable data on ion influx or efflux.

328 329

Our results also confirmed that KCNAB was an aldo-keto reductase which could be activated by thymol. Such NADPH-dependent redox enzymes are

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suggested to be involved in cellular metabolism by being coupled to electrical

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signaling through ion channels 28. Although we had no evidence for the roles of

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aldo-keto reductase activity of KCNAB in conidial apoptosis, such a redox

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enzyme could sense the intracellular redox state and lead to long-lasting effects

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on Kv-α 45. Our previous studies showed that thymol induced ROS eruption in

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conidia, which was proved to involve in the conidial death 23. ROS have been

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implicated in mitochondrial dysfunction, which leads to the release of

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pro-apoptotic proteins triggering the caspase activation and apoptosis 46. It was

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interesting that blocking ROS production with the inhibitors of NADPH oxidase

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attenuated the conidial apoptosis by thymol (Figure S7), while alleviation of K+

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eruption by the inhibitor of Kv also blocked the ROS generation by thymol

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(Figure S8), suggesting that K+ efflux leads to ROS production and subsequent

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apoptosis. This was further supported by the fact that K+ eruption was stimulated

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instantly by thymol, while ROS was produced 30min after the addition of thymol

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23

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is a molecular switch that controls K+ efflux and mediates apoptosis in A. flavus

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induced by thymol, which greatly contributed to the development of alternative

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strategy against this fungal pathogen. However, little information on α-subunit of

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this Kv is available, and further studies are required to elucidate this valuable

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apoptotic pathway.

. Taken together, our research revealed an apoptotic pathway in which KCNAB

350 351

ACKNOWLEDGEMENTS

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This work is financially supported by General Project of National Natural Science

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Foundation of China (Grant No.31671952), Program for Science & Technology

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Innovation Talents in Universities of Henan Province (18HASTIT037), and Program

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for Science & Technology Innovation Team in Universities of Henan Province

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(16IRTSTHN007).

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Supporting Information

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Supplemental data including Figure S1 (Fluorescent microscopy of conidia with 6h

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exposure to thymol through double staining with Hoechst 33342 and PI), Figure S2

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(PS externalization in conidia exposed to thymol for 6h detected through fluorescent

361

microscopy with an Annexin V-FITC assay), Figure S3 (DNA damage in conidia

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exposed to thymol for 6h detected by TUNEL staining through fluorescent

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microscopy.), Figure S4 (Variation of mitochondrial potential in conidia exposed to

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thymol for 6h indicated by JC-1 through fluorescent microscopy), Figure S5

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(Predication of acceptors targeted by thymol leading to apoptosis through

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DRAR-CPI and autodock analysis), Figure S6 (Model on K+-probe complex trapped

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inside of the cells), Figure S7 (The effects of ROS blockers (PY and IMZ) on the

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conidial apoptosis induced by thymol) and Figure S8 (The effects of a Kv inhibitor

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(4-Ap) on the ROS generation in the conidia induced by thymol) (Supplemental

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Material). This material is available free of charge via the Internet at

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http://pubs.acs.org

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Figure 1. Conidial apoptosis in A. flavus induced by thymol. (A) and (B) Histograms

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DNA damage in conidia exposed to thymol for 6h detected by TUNEL staining

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