Antimicrobial Effect of Slightly Acidic Electrolyzed (HOCl) Water on Botrytis cinerea of Cut Rose Flowers

Ju Hwi Kim; Sang Wook Park; Young Boon Lee

doi:10.7235/HORT.20230028

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2023 Vol.41, Issue 3 Preview Page Next Page

Research Article

Antimicrobial Effect of Slightly Acidic Electrolyzed (HOCl) Water on Botrytis cinerea of Cut Rose Flowers

30 June 2023. pp. 304-314

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Abstract

This study investigates the antifungal effect of slightly acidic electrolyzed water on Botrytis cinerea, an agent that causes gray mold to appear on the cut rose flower of the type known as ‘Bubble Gum’. Petals were inoculated by spraying a spore suspension with 3 × 10⁵ spores·mL^-1 (1.2 mL per flower) which was then allowed to dry in air for an hour. The petal pulsing treatments used here were as follows: no treatment (NT, control) and HOCl treatments at concentrations of 0, 5, 10, 20, and 30 µL·L^-1 sprayed for three seconds. The treatment with 30 µL·L^-1 HOCl (27.8%) reduced B. cinerea by 71% compared to NT (94.6%) and by 68% compared to the 0 µL·L^-1 HOCl (87.9%). The vase life of cut rose flowers was lowest in the NT and highest with 30 µL·L^-1 HOCl. The disease incidence rate according to the visual index of B. cinerea decreased as the HOCl concentration was increased. The petal color did not differ among the treatments in terms of the L*, a*, and b* values, except for NT compared to the corresponding value before the postharvest treatment. NT showed the highest rate of color change as measured by the ΔE* value compared to 0 days, and the petal color remained unchanged to the greatest degree in the HOCl treatments. Electrolyte leakage from the petals was highest in NT, and there was no petal tissue damage after the HOCl treatments. The flowering rate was lowest in NT, and there were few differences among the treatments. There were no differences among the treatments in terms of the chlorophyll content, Fv/Fm, and stomatal size change rate of the leaf, indicating that the quality of the leaf was not affected. Thus, an immediate petal pulsing treatment with slightly acidic electrolyzed water is recommended to inhibit gray mold on cut rose flowers at 30 µL·L^-1 HOCl just before postharvest storage. This treatment did not cause any apparent damage to the petals or leaves.

Keywords

cut flower quality

dipping treatment

fungicides, gray mold

Rosa hybrida

petal pulsing treatment

References

Ahn SK (2015) Effects of slightly acidic electrolyzed water treatment on microbial reduction in salted young radish. Master's thesis. Chung-Ang University, Korea

An HR, Lee SY, Park PM, Kim YJ (2022) Effects of substrate water contents on post-shipping performance of Phalaenopsis. Hortic Sci Technol 40:52-62. doi:10.7235/HORT.20220006 10.7235/HORT.20220006

Bergmann BA, Dole JM (2018) Influence of essential oils on post-infection Botrytis damage in cut roses. J Environ Hort 36:45-57. doi:10.24266/JEH-D-17-0012.1 10.24266/JEH-D-17-0012.1

Choi SY, Lee AK (2020) Development of a cut rose longevity prediction model using thermography and machine learning. J Kor Hortic Sci 38:675-685. doi:10.7235/HORT.20200061 10.7235/HORT.20200061

Daugaard H (1999) Cultural methods for controlling Botrytis cinerea Pers. in strawberry. Biol Agric Hortic 16:351-361. doi:10.1080/01448765.1999.9755238 10.1080/01448765.1999.9755238

de Stigter HCM, Broekhuysen AGM (1989) Secondary gas embolism as an effect of disturbed water balance in cut roses. Acta Hortic 261:17-26. doi:10.17660/ActaHortic.1989.261.2 10.17660/ActaHortic.1989.261.2

Dean R, Van Kan JAL, Pretorius ZA, Hammond-Kosack KE, Pietro AD, Spanu PD, Rudd JJ, Dickman M, Kahmann R, et al. (2012) The top 10 fungal pathogens in molecular plant pathology. Mol Plant Pathol 13:414-430. doi:10.1111/j.1364-3703.2011.00783.x 10.1111/j.1364-3703.2011.00783.x22471698PMC6638784

Elad Y, Kirshner B, Gotlib Y (1993) Attempts to control Botrytis cinerea on roses by pre- and postharvest treatments with biological and chemical agents. Crop prot 12:69-73. doi:10.1016/0261-2194(93)90023-C 10.1016/0261-2194(93)90023-C

Fanourakis D, Pieruschka R, Savvides A, Macnish AJ (2013) Sources of vase life variation in cut roses: A review. Postharvest Biol Technol 78:1-15. doi:10.1016/j.postharvbio.2012.12.001 10.1016/j.postharvbio.2012.12.001

Fu Y, van Silfhout A, Shahin A, Egberts R, Beers M, van der Velde A, van Houten A, van Tuyl JM, Visser RGF, et al. (2017) Genetic mapping and QTL analysis of Botrytis resistance in Gerbera hybrida. Mol Breed 37:13. doi:10.1007/s11032-016-0617-1 10.1007/s11032-016-0617-128216997PMC5285436

Goo SG, Koo J (2020) Establishment of rice Bakanae disease management using slightly acidic chlorous acid water. J Life Sci 30:178-185. doi:10.5352/JLS.2020.30.2.178 10.5352/JLS.2020.30.2.178

Goss M, Mazarura U (2013) Efficacy of post-harvest fungicide sprays and fan-drying for the control of gray mould (Botrytis cinerea) in roses (Rosacea hybridus var. annabella). J Agric Technol 9:479-486

Ha STT, Choi B, In BC (2021) Nature and regulation of Botrytis cinerea in Rosa hybrida. Flower Res J 29:129-137. doi:10.11623/frj.2021.29.3.02 10.11623/frj.2021.29.3.02

Ha STT, Jung YO, Lim JH (2020a) Pretreatment with Scutellaria baicalensis georgi extract improves the postharvest quality of cut roses (Rosa hybrida L.). Hortic Environ Biotechnol 61:511-524. doi:10.1007/s13580-020-00238-6 10.1007/s13580-020-00238-6

Ha STT, Kim YT, In BC (2020b) Assessment of preservative solutions for reducing Botrytis cinerea infection in cut roses. Flower Res J 28:279-284. doi:10.11623/frj.2020.28.4.06 10.11623/frj.2020.28.4.06

Herrera-Romero I, Ruales C, Caviedes M, Leon-Reyes A (2017) Postharvest evaluation of natural coatings and antifungal agents to control Botrytis cinerea in Rosa sp. Phytoparasitica 45:9-20. doi:10.1007/s12600-017-0565-2 10.1007/s12600-017-0565-2

Hwang KH, Hong SM, Lee YS, Lee HJ (2019) Difference of gray mold severity at roses caused by Botrytis cinerea strains. Res Plant Dis 25:16-21. doi:10.5423/RPD.2019.25.1.16 10.5423/RPD.2019.25.1.16

Issa-Zacharia A, Kamitani Y, Miwa N, Muhimbula H, Iwasaki K (2011) Application of slightly acidic electrolyzed water as a potential non-thermal food sanitizer for decontamination of fresh ready-to-eat vegetables and sprouts. Food Contol 22:601-607. doi:10.1016/j.foodcont.2010.10.011 10.1016/j.foodcont.2010.10.011

Jung BC (2002) BioWave, A study on the characteristics of photosynthetic organisms using chlorophyll fluorescence. https://www.ibric.org › myboard › view. Accessed 1 February 2023

Kim JH, Lee YB (2022) Treatment concentration of ozone and sucrose to extend the vase life of the cut rose 'Dominica'. Flower Res J 30:69-74. doi:10.11623/frj.2022.30.2.04 10.11623/frj.2022.30.2.04

Kim YR, Kim JH, Lee YB (2022) Pulsing treatment of slightly acidic hypochlorous water to extend the vase life of cut rose 'Bubble Gum'. Flower Res J 30:205-210. doi:10.11623/frj.2022.30.4.05 10.11623/frj.2022.30.4.05

Kim YS, Park IS, Ha SD (2009) Application sanitizer for the control of microorganisms in food. Food Sci Industry 44:467-471

Korea Society for Floricultural Science (KSFS) (2021) Floriculture. Worldscience, Korea, pp 261-262

Kumar N, Srivastava GC, Dixit K (2008) Hormonal regulation of flower senescence in roses (Rosa hybrida L.). Plant Growth Regul 55:65-71. doi:10.1007/s10725-008-9259-6 10.1007/s10725-008-9259-6

Lee JH, Choi JW, Hong YP, Kwon OH (2016) Hot water dipping on reduction of grey mold (Botrytis cinerea) in cut rose 'Antique Curl'. Flower Res J 24:304-311. doi:10.10.11623/frj.2016.24.4.09 10.11623/frj.2016.24.4.09

Lee JH, Yoon JW, Oh SI, Lee AK (2020) Relationship between cultivation environment and postharvest quality of cut rose 'Lovely lydia'. J Kor Hortic 38:263-270 doi:10.7235/HORT.20200025 10.7235/HORT.20200025

Lee JS, Han KS, Park JH, Cheong SR, Jang HI (2006) Control of gray mold (Botrytis cinerea) on roses by pre-and Post-harvest treatments with agricultural chemicals. Res Plant Dis 12:249-253. doi:10.5423/RPD.2006.12.3.249 10.5423/RPD.2006.12.3.249

Lee JS, Park CH, Seo JK, Jung JH, Jung BY, Kim YY, Kim KW (2005) Floriculture quality keeping or process. Wizvalley, Seoul, Korea, pp 70-147

Lee YB, Kim WS (2020) ClO₂dipping treatment inhibits gray mold on cut rose flowers during storage. The Hort J 89:496-501. doi:10.2503/hortj.UTD-138 10.2503/hortj.UTD-138

Lim SH, Kim JK, Kim DH, Sohn SH, Lee JY, Kim YM, Ha SH (2011) Flower color modification by manipulating flavonoid biosynthetic pathway. Hortic Sci Technol 29:511-522

Mari M, Francesco AD, Bertolini P (2014) Control of fruit postharvest diseases: old issues and innovative approaches. Stewart Postharvest Rev 1:1-4. doi:10.2212/spr.2014.1.1 10.2212/spr.2014.1.1

McGuire RG (1992) Reporting of objective color measurements. Hortic Sci 27:1254-1255. doi:10.21273/HORTSCI.27.12.1254 10.21273/HORTSCI.27.12.1254

Meir S, Droby S, Davidson H, Alsevia S, Cohen L, Horev B, Philosoph-Hadas S (1998) Suppression of Botrytis rot in cut rose flowers by postharvest application of methyl jasmonate. Postharvest Biol Technol 13:235-243. doi:10.1016/S0925-5214(98)00017-9 10.1016/S0925-5214(98)00017-9

Ministry of Agriculture, Food and Rural Affairs (MAFRA) (2022) Flower cultivation status in 2021. pp 42-43

Park KH, Park HT (2006) A competitiveness and promotion subjects of Korean roses in Japanese flower markets. Kor J of Agr Mgt and Policy 33:495-518

Park KY, Kim YS (2022) Analysis of domestic cut rose varieties and phylogenetic preference: focusing on cut roses fostered by the national institute of horticultural and herbal science. J Kor Soc Floral Art & Design 46:131-147. doi:10.52706/KSFAD.46.8 10.52706/KSFAD.46.8

Roberts AV, Debener T, Gudin S (2003) Encyclopedia of rose science. 1st ed, Elsvier, USA 10.1016/B0-12-227620-5/90003-X

Salgado-Salazar C, Shishkoff N, Daughtrey M, Plmer CL, Crouch JA (2018) Downy mildew: A serious disease threat to rose health worldwide. Plant Dis 102:1873-1882. doi:10.1094/PDIS-12-17-1968-FE 10.1094/PDIS-12-17-1968-FE30110245

Schaik M (2009) Food safety, chemicals, toxins and electrolyzed water. Aquaox company publication. http://aquaox.wordpress.com/2009/10/12/food-safety-chemicals-toxins-and-electrolyzed-water/ Accessed 1 February 2023

Song JY, Kim NR, Nam MH, Park BJ, Whang EI, Choi JM, Kim HG (2013) Fungicidal effect of slightly acidic hypochlorous water against phytopathogenic fungi. Korean J Mycol 41:274-279. doi:10.4489/KJM.2013.41.4.274 10.4489/KJM.2013.41.4.274

Usall J, Ippolito A, Sisquella M, Neri F (2016) Physical treatments to control postharvest diseases of fresh fruits and vegetables. Postharvest Biol Technol 122:30-40. doi:10.1016/j.postharvbio.2016.05.002 10.1016/j.postharvbio.2016.05.002

van Jaarsveld AJ (2018) Flower preservation method and device. US patent 9,974,309 B2

Vrind TA (2005) The Botrytis problem in figures. Acta Hort 699:99-102. doi:10.17660/ActaHortic.2005.669.11 10.17660/ActaHortic.2005.669.11

Wang C, Yuan S, Zhang W, Ng T, Ye X (2019) Buckwheat antifungal protein with biocontrol potential to inhibit fungal (Botrytis cinerea) Infection of Cherry Tomato. J Agric Food Chem 67:6748-6756. doi:10.1021/acs.jafc.9b01144 10.1021/acs.jafc.9b0114431136167

Williamson B, Duncan GH, Harrison JG, Harding LA, Elad Y, Zimand G (1995) Effect of humidity on infection of rose petals by dry-inoculated conidia of Botrytis cinerea. Mycological Res 99:1303-1310. doi:10.1016/S0953-7562(09)81212-4 10.1016/S0953-7562(09)81212-4

Yeon JY, Lee S, Lee KJ, Kim WS (2022) Flowering responses in the cut rose 'Vital' to non-optimal temperatures. Hortic Sci Technol 40:471-480. doi:10.7235/HORT.20220042 10.7235/HORT.20220042

Yi H, Rui Y, Kandemir B, Wang JZ, Anderson CT, Puri VM (2018) Mechanical effects of cellulose, xyloglucan, and pectins on stomatal guard cells of Arabidopsis thaliana. Front Plant Sci 9:1566. doi:10.3389/fpls.2018.01566 10.3389/fpls.2018.0156630455709PMC6230562

Yoon SR (2006) Studies on properties and disinfection effect of strong acidic electrolyzed water (SEW) and weak acidic electrolyzed water (WEW). MS thesis, Gangneung Nati Univ, Gangneung, Korea

Yoon SR, Lee JY, Yang JS, Ha JH (2021) Bactericidal effects of diluted slightly acidic electrolyzed water in quantitative suspension and cabbage tests. LWT-Food Sci Technol 152:112291. doi:10.1016/j.lwt.2021.112291 10.1016/j.lwt.2021.112291

Information

Publisher :KOREAN SOCIETY FOR HORTICULTURAL SCIENCE
Publisher(Ko) :한국원예학회
Journal Title :Horticultural Science and Technology
Journal Title(Ko) :원예과학기술지
Volume : 41
No :3
Pages :304-314
Received Date : 2023-02-12
Revised Date : 2023-04-04
Accepted Date : 2023-05-05
DOI :https://doi.org/10.7235/HORT.20230028

Horticultural Science and Technology 원예과학기술지 ISSN:1226-8763(Print) 2465-8588(Online)

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