[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.5423/PPJ.OA.07.2020.0141

Synergistic Interactions of Schizostatin Identified from Schizophyllum commune with Demethylation Inhibitor Fungicides

Park, Min Young (Department of Biosystems and Biotechnology, Korea University Graduate School)
Jeon, Byeong Jun (Department of Biosystems and Biotechnology, Korea University Graduate School)
Kang, Ji Eun (Department of Biosystems and Biotechnology, Korea University Graduate School)
Kim, Beom Seok (Department of Biosystems and Biotechnology, Korea University Graduate School)

Publication Information

The Plant Pathology Journal / v.36, no.6, 2020 , pp. 579-590 More about this Journal

Abstract

Botrytis cinerea, which causes gray mold disease in more than 200 plant species, is an economically important pathogen that is mainly controlled by synthetic fungicides. Synergistic fungicide mixtures can help reduce fungicide residues in the environment and mitigate the development of fungicide-resistant strains. In this study, we screened microbial culture extracts on Botrytis cinerea to identify an antifungal synergist for tebuconazole. Among the 4,006 microbial extracts screened in this study, the culture extract from Schizophyllum commune displayed the most enhanced activity with a sub-lethal dosage of tebuconazole, and the active ingredient was identified as schizostatin. In combination with 5 ㎍/ml tebuconazole, schizostatin (1 ㎍/ml) showed disease control efficacy against gray mold on tomato leaf similar to that achieved with 20 ㎍/ml tebuconazole treatment alone. Interestingly, schizostatin showed demethylation inhibitor (DMI)-specific synergistic interactions in the crossed-paper strip assay using commercial fungicides. In a checkerboard assay with schizostatin and DMIs, the fractional inhibitory concentration values were 0.0938-0.375. To assess the molecular mechanisms underlying this synergism, the transcription levels of the ergosterol biosynthetic genes were observed in response to DMIs, schizostatin, and their mixtures. Treatment with DMIs increased the erg11 (the target gene of DMI fungicides) expression level 15.4-56.6-fold. However, treatment with a mixture of schizostatin and DMIs evidently reverted erg11 transcription levels to the pre-DMI treatment levels. These results show the potential of schizostatin as a natural antifungal synergist that can reduce the dose of DMIs applied in the field without compromising the disease control efficacy of the fungicides.

Keywords

Botrytis cinerea; demethylation inhibitors; gray mold; schizostatin; synergistic interaction;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Sharma, M., Manoharlal, R., Negi, A. S. and Prasad, R. 2010. Synergistic anticandidal activity of pure polyphenol curcumin I in combination with azoles and polyenes generates reactive oxygen species leading to apoptosis. FEMS Yeast Res. 10:570-578.
2	Sharma, M., Manoharlal, R., Shukla, S., Puri, N., Prasad, T., Ambudkar, S. V. and Prasad, R. 2009. Curcumin modulates efflux mediated by yeast ABC multidrug transporters and is synergistic with antifungals. Antimicrob. Agents Chemother. 53:3256-3265. DOI
3	Sun, L., Sun, S., Cheng, A., Wu, X., Zhang, Y. and Lou, H. 2009. In vitro activities of retigeric acid B alone and in combination with azole antifungal agents against Candida albicans. Antimicrob. Agents Chemother. 53:1586-1591. DOI
4	Tanimoto, T., Onodera, K., Hosoya, T., Takamatsu, Y., Kinoshita, T., Tago, K., Kogen, H., Fujioka, T., Hamano, K. and Tsujita, Y. 1996. Schizostatin, a novel squalene synthase inhibitor produced by the mushroom, Schizophyllum commune. I. Taxonomy, fermentation, isolation, physico-chemical properties and biological activities. J. Antibiot. 49:617-623. DOI
5	Zeun, R. and Buchenauer, H. 1991. Synergistic effects of pyrazophos and propiconazole against Pyrenophora teres. J. Plant Dis. Prot. 98:661-668 (in German).
6	Ziogas, B. N. and Malandrakis, A. A. 2015. Sterol biosynthesis inhibitors: C14 demethylation (DMIs). In: Fungicide resistance in plant pathogens, eds. by H. Ishii and D. W. Hollomon, pp. 199-216. Springer, Tokyo, Japan.
7	Joseph-Horne, T. and Hollomon, D. W. 1997. Molecular mecha-nisms of azole resistance in fungi. FEMS Microbiol. Lett.149:141-149. DOI
8	Ahmad, A., Wani, M. Y., Khan, A., Manzoor, N. and Molepo, J. 2015. Synergistic interactions of eugenol-tosylate and its congeners with fluconazole against Candida albicans. PLoS ONE 10:e0145053. DOI
9	De Medeiros Barbosa, I., da Costa Medeiros, J. A., de Oliveira, K. A. R., Gomes-Neto, N. J., Tavares, J. F., Magnani, M. and de Souza, E. L. 2016. Efficacy of the combined application of oregano and rosemary essential oils for the control of Escherichia coli, Listeria monocytogenes and Salmonella Enteritidis in leafy vegetables. Food Control 59:468-477. DOI
10	Doke, S. K., Raut, J. S., Dhawale, S. and Karuppayil, S. M. 2014. Sensitization of Candida albicans biofilms to fluconazole by terpenoids of plant origin. J. Gen. Appl. Microbiol. 60:163-168. DOI
11	Dutta, S., Woo, E.-E., Yu, S.-M., Nagendran, R., Yun, B.-S. and Lee, Y. H. 2019. Control of anthracnose and gray mold in pepper plants using culture extract of white-rot fungus and active compound schizostatin. Mycobiology 47:87-96. DOI
12	Holb, I. J. and Schnabel, G. 2008. The benefits of combining elemental sulfur with a DMI fungicide to control Monilinia fructicola isolates resistant to propiconazole. Pest Manag. Sci. 64:156-164. DOI
13	Tanaka, Y. and Omura, S. 1993. Agroactive compounds of microbial origin. Annu. Rev. Microbiol. 47:57-87. DOI
14	Fillinger, S. and Elad, Y. 2016. Botrytis: the fungus, the pathogen and its management in agricultural systems. Springer International Publishing, Cham, Switzerland. 486 pp.
15	Gisi, U., Binder, H. and Rimbach, E. 1985. Synergistic interactions of fungicides with different modes of action. Trans. Br. Mycol. Soc. 85:299-306. DOI
16	Hayashi, K., Schoonbeek, H.-J. and De Waard, M. A. 2003. Modulators of membrane drug transporters potentiate the activity of the DMI fungicide oxpoconazole against Botrytis cinerea. Pest Manag. Sci. 59:294-302. DOI
17	Henry, K. W., Nickels, J. T. and Edlind, T. D. 2000. Upregulation of ERG genes in Candida species by azoles and other sterol biosynthesis inhibitors. Antimicrob. Agents Chemother. 44:2693-2700. DOI
18	Jarvis, W. R. 1977. Botryotinia and Botrytis species: taxonomy, physiology and pathogenicity: a guide to the literature. Canada Department of Agriculture, Ottawa, Canada. 206 pp.
19	Kagan, I. A., Michel, A., Prause, A., Scheffler, B. E., Pace, P. and Duke, S. O. 2005. Gene transcription profiles of Saccharomy- ces cerevisiae after treatment with plant protection fungicides that inhibit ergosterol biosynthesis. Pestic. Biochem. Physiol. 82:133-153. DOI
20	Khan, M. S. A. and Ahmad, I. 2011. Antifungal activity of essential oils and their synergy with fluconazole against drugresistant strains of Aspergillus fumigatus and Trichophyton rubrum. Appl. Microbiol. Biotechnol. 90:1083-1094. DOI
21	Kuck, K.-H. 2007. QoI fungicides: resistance mechanisms and its practical importance. In: Pesticide chemistry: crop protection, public health, environmental safety, eds. by H. Ohkawa, H. Miyagawa and P. W. Lee, pp. 275-283. Wiley-VCH, Weinheim, Germany.
22	Kim, J. D., Park, M. Y., Jeon, B. J. and Kim, B. S. 2019. Disease control efficacy of 32,33-didehydroroflamycoin produced by Streptomyces rectiviolaceus strain DY46 against gray mold of tomato fruit. Sci. Rep. 9:13533. DOI
23	Gisi, U. 1996. Synergistic interaction of fungicides in mixtures. Phytopathology 86:1273-1279.
24	Kim, J. H., Faria, N. C. G., Martins, M. D. L., Chan, K. L. and Campbell, B. C. 2012. Enhancement of antimycotic activity of amphotericin B by targeting the oxidative stress response of Candida and Cryptococcus with natural dihydroxybenzaldehydes. Front. Microbiol. 3:261. DOI
25	Kim, J. H., Campbell, B. C., Mahoney, N., Chan, K. L., Molyneux, R. J. and Xiao, C. L. 2010. Use of chemosensitization to overcome fludioxonil resistance in Penicillium expansum. Lett. Appl. Microbiol. 51:177-183. DOI
26	Kogen, H., Tago, K., Kaneko, S., Hamano, K., Onodera, K., Haruyama, H., Minagawa, K., Kinoshita, T., Ishikawa, T., Tanimoto, T. and Tsujita, Y. 1996. Schizostatin, a novel squalene synthase inhibitor produced by the mushroom, Schizophyllum commune. II. Structure elucidation and total synthesis. J. Antibiot. 49:624-630. DOI
27	Leroux, P. 2007. Chemical control of Botrytis and its resistance to chemical fungicides. In: Botrytis: biology, pathology and control, eds. by Y. Elad, B. Williamson, P. Tudzynski and N. Delen, pp. 195-222. Springer, Dordrecht, Netherlands.
28	Nyilasi, I., Kocsube, S., Krizsan, K., Galgoczy, L., Pesti, M., Papp, T. and Vagvolgyi, C. 2010. In vitro synergistic interactions of the effects of various statins and azoles against some clinically important fungi. FEMS Microbiol. Lett. 307:175-184. DOI
29	Liu, X., Jiang, J., Shao, J., Yin, Y. and Ma, Z. 2010. Gene transcription profiling of Fusarium graminearum treated with an azole fungicide tebuconazole. Appl. Microbiol. Biotechnol. 85:1105-1114. DOI
30	Meletiadis, J., Mouton, J. W., Meis, J. F. M. and Verweij, P. E. 2003. In vitro drug interaction modeling of combinations of azoles with terbinafine against clinical Scedosporium prolificans isolates. Antimicrob. Agents and Chemother. 47:106-117. DOI
31	Oliver, R. P. and Hewitt, H. G. 2014. Fungicides in crop protection. 2nd ed. CABI, Wallingford, UK. 190 pp.
32	OuYang, Q., Tao, N. and Jing, G. 2016. Transcriptional profiling analysis of Penicillium digitatum, the causal agent of citrus green mold, unravels an inhibited ergosterol biosynthesis pathway in response to citral. BMC Genomics 17:599. DOI
33	Perea, S., Gonzalez, G., Fothergill, A. W., Sutton, D. A. and Rinaldi, M. G. 2002. In vitro activities of terbinafine in combination with fluconazole, itraconazole, voriconazole, and posaconazole against clinical isolates of Candida glabrata with decreased susceptibility to azoles. J. Clin. Microbiol. 40:1831-1833. DOI
34	Rogers, P. D. and Barker, K. S. 2003. Genome-wide expression profile analysis reveals coordinately regulated genes associated with stepwise acquisition of azole resistance in Candida albicans clinical isolates. Antimicrob. Agents Chemother. 47:1220-1227. DOI