Abstract
Botrytis cinerea, which causes grey mould, infects fruit of a number of horticultural crops during their development but then remains latent until the ripening process when the disease manifests. However, how B. cinerea grows in capsicum fruit after harvest has not been fully characterised. The present research has examined the growth of B. cinerea in fruit of two cultivars of capsicum (cv. Aries and cv. Papri Queen) that were inoculated either before or after harvest. Three concentrations of conidial suspensions (104, 105 and 106 conidia mL−1) were used to inoculate flowers at three preharvest stages – anthesis, 3 days after anthesis (DAA) and 6 DAA, and fruit at three postharvest ripening stages – deep green (DG), breaker red (BR) and red (R). Inoculation with water served as a control. Rot development was then monitored daily during postharvest storage at 10 °C by measuring the length and width of lesions. Cv. Aries was more susceptible to B. cinerea than cv. Papri Queen regardless of whether inoculation occurred preharvest or postharvest. Flowers often died when inoculated at anthesis. Regardless of cultivar, as inoculum concentration increased the number of flowers that died also increased. However, disease development on fruit was not affected by inoculum concentration or the timing of inoculation before harvest. When fruit were inoculated after harvest, grey mould developed most rapidly in BR fruit of cv. Papri Queen and in R fruit of cv. Aries. The understanding of infection of B. cinerea revealed by this research and its implications for disease management are discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adrian M, Jeandet P, Veneau J, Weston LA, Bessis R (1997) Biological activity of resveratrol, a stilbenic compound from grapevines, against Botrytis cinerea, the causal agent for gray mold. J Chem Ecol 23:1689–1702
Babalar M, Asghari M, Talaei A, Khosroshahi A (2007) Effect of pre-and postharvest salicylic acid treatment on ethylene production, fungal decay and overall quality of Selva strawberry fruit. Food Chem 105:449–453
Bais AJ, Murphy PJ, Dry IB (2000) The molecular regulation of stilbene phytoalexin biosynthesis in Vitis vinifera during grape berry development. Funct Plant Biol 27:723
Baker KF (1957) The U.C. system for producing healthy container-grown plants: University of California, Agricultural Experimental Station Manual 23
Barkai-Golan R, Lavy-Meir G (1989) Effects of ethylene on the susceptibility to Botrytis cinerea infection of different tomato genotypes. Ann Appl Biol 114:391–396
Bristow P, McNicol R, Williamson B (1986) Infection of strawberry flowers by Botrytis cinerea and its relevance to grey mould development. Ann Appl Biol 109:545–554
Cantu D, Blanco-Ulate B, Yang L, Labavitch JM, Bennett AB, Powell ALT (2009) Ripening-regulated susceptibility of tomato fruit to Botrytis cinerea requires NOR but not RIN or ethylene. Plant Physiol 150:1434–1449
Conforti F, Statti GA, Menichini F (2007) Chemical and biological variability of hot pepper fruits (Capsicum annuum var. acuminatum L.) in relation to maturity stage. Food Chem 102:1096–1104
Cota I, Troncoso-Rojas R, Sotelo-Mundo R, Sánchez-Estrada A, Tiznado-Hernández M (2007) Chitinase and β-1, 3-glucanase enzymatic activities in response to infection by Alternaria alternata evaluated in two stages of development in different tomato fruit varieties. Sci Hortic 112:42–50
Dashwood E, Fox R (1988) Infection of flowers and fruits of red raspberry by Botrytis cinerea. Plant Pathol 37:423–430
Davey MW, Auwerkerken A, Keulemans J (2007) Relationship of apple vitamin C and antioxidant contents to harvest date and postharvest pathogen infection. J Sci Food Agric 87:802–813
Deli J, Molnár P, Matus Z, Tóth G (2001) Carotenoid composition in the fruits of red paprika (Capsicum annuum var. lycopersiciforme rubrum) during ripening: biosynthesis of carotenoids in red paprika. J Agric Food Chem 49:1517–1523
Derckel JP, Audran JC, Haye B, Lambert B, Legendre L (1998) Characterization, induction by wounding and salicylic acid, and activity against Botrytis cinerea of chitinases and β-1,3-glucanases of ripening grape berries. Physiol Plant 104:56–64
Droby A, Lichter A (2004) Post-harvest Botrytis infection: etiology, development and management. In: Elad Y, Williamson B, Tudzynski P, Delen N (eds) Botrytis: biology, pathology and control. Kluwer Academic Press, Dordrecht, pp 349–367
Eden M, Hill R, Beresford R, Stewart A (1996) The influence of inoculum concentration, relative humidity, and temperature on infection of greenhouse tomatoes by Botrytis cinerea. Plant Pathol 45:795–806
Eissa HA, Mostafa В, Hussein A (2007) Capsaicin content and quality characteristics in different local pepper varieties (Capsicum annum) and acid-brine pasteurized puree. J Food Technol 5:246–255
Elad Y, Volpin H (1993) Reduced development of grey mould (Botrytis cinerea) in bean and tomato plants by calcium nutrition. J Phytopathol 139:146–156
Fallik E, Grinberg S, Alkalai S, Lurie S (1996) The effectiveness of postharvest hot water dipping on the control of grey and black moulds in sweet red pepper (Capsicum annuum). Plant Pathol 45:644–649
Fourie J, Holz G (1994) Infection of plum and nectarine flowers by Botrytis cinerea. Plant Pathol 43:309–315
Goetz G, Fkyerat A, Métais N, Kunz M, Tabacchi R, Pezet R, Pont V (1999) Resistance factors to grey mould in grape berries: identification of some phenolics inhibitors of Botrytis cinerea stilbene oxidase. Phytochemistry 52:759–767
Halfon-Meiri A, Rylski I (1983) Internal mold caused in sweet pepper by Alternaria alternata: fungal ingress. Phytopathology 73:67–70
Horowitz S, Yarden O, Zveibil A, Freeman S (2004) Development of a robust screening method for pathogenicity of Colletotrichum spp. on strawberry seedlings enabling forward genetic studies. Plant Dis 88:845–851
Howard L, Talcott S, Brenes C, Villalon B (2000) Changes in phytochemical and antioxidant activity of selected pepper cultivars (Capsicum species) as influenced by maturity. J Agric Food Chem 48:1713–1720
Jarvis WR, Borecka H (1968) The susceptibility of strawberry flowers to infection by Borytis cinerea Pers. ex Fr. Hortic Res 8:147–154
Keller M, Viret O, Cole FM (2003) Botrytis cinerea infection in grape flowers: defense reaction, latency, and disease expression. Phytopathology 93:316–322
Kim JS, Ahn J, Lee SJ, Moon BK, Ha TY, Kim S (2011) Phytochemicals and antioxidant activity of fruits and leaves of paprika (Capsicum annuum L., var. Special) cultivated in Korea. J Food Sci 76:193–198
Lavy-Meir G, Barkai-Golan R, Kopeliovitch E (1989) Resistance of tomato ripening mutants and their hybrids to Botrytis cinerea. Plant Dis 73:967–922
Lopez-Malo A, Alzamora S, Argaiz A (1998) Vanillin and pH synergistic effects on mold growth. J Food Sci 63:143–146
Maas JL (1998) Compendium of strawberry diseases. APS Press, St Paul
McClellan W, Hewitt W (1973) Early Botrytis rot grapes: time of infection and latency of Botrytis cinerea Pers. in Vitis vinifera L. Phytopathology 63:1151–1157
McNicol R, Williamson B, Dolan A (1990) Effects of inoculation, wounding and temperature on post-harvest grey mould (Botrytis cinerea) of red raspberry. J Hortic Sci 65:157–165
Michailides TJ, Elmer PAG (2000) Botrytis gray mold of kiwifruit caused by Botrytis cinerea in the United States and New Zealand. Plant Dis 84:208–223
Navarro JM, Flores P, Garrido C, Martinez V (2006) Changes in the contents of antioxidant compounds in pepper fruits at different ripening stages, as affected by salinity. Food Chem 96:66–73
Niklis N, Sfakiotakis E, Thanassoulopoulos C (1995) Ethylene production by Botrytis cinerea, kiwifruit and Botrytis rotted kiwifruit under several storage temperatures. Acta Horticult 444:733–738
Ozdemir M, Floros JD (2004) Active food packaging technologies. Crit Rev Food Sci Nutr 44:185–193
Pezet R, Viret O, Perret C, Tabacchi R (2003) Latency of Botrytis cinerea Pers.: Fr. and biochemical studies during growth and ripening of two grape berry cultivars, respectively susceptible and resistant to grey mould. J Phytopathol 151:208–214
Pham NTT (2007) Ripening behaviour of capsicum (Capsicum annuum L.) fruit. PhD thesis, University of Adelaide, South Australia, 149 pages
Salzman RA, Tikhonova I, Bordelon BP, Hasegawa PM, Bressan RA (1998) Coordinate accumulation of antifungal proteins and hexoses constitutes a developmentally controlled defense response during fruit ripening in grape. Plant Physiol 117:465
Staats M, Van Baarlen P, Van Kan JAL (2005) Molecular phylogeny of the plant pathogenic genus Botrytis and the evolution of host specificity. Mol Biol Evol 22:333–346
Tao S, Zhang S, Tsao R, Charles MT, Yang R, Khanizadeh S (2010) In vitro antifungal activity and mode of action of selected polyphenolic antioxidants on Botrytis cinerea. Arch Phytopathol Plant Protect 43:1564–1578
Terry LA, Joyce DC, Adikaram NKB, Khambay BPS (2004) Preformed antifungal compounds in strawberry fruit and flower tissues. Postharvest Biol Technol 31:201–212
Utkhede RS, Mathur S (2005) Biological and chemical control of fruit rot in greenhouse sweet peppers (Capsicum annum L.) caused by Fusarium subglutinans. J Biol Sci 5:610–615
Villavicencio L, Blankenship SM, Sanders DC, Swallow WH (1999) Ethylene and carbon dioxide production in detached fruit of selected pepper cultivars. J Am Soc Hortic Sci 124:402–406
Volpin H, Elad Y (1991) Influence of calcium nutrition on susceptibility of rose flowers to Botrytis blight. Phytopathology 81:1390–1394
Williamson B, McNicol R, Dolan A (1987) The effect of inoculating flowers and developing fruits with Botrytis cinerea on post-harvest grey mould of red raspberry. Ann Appl Biol 111:285–294
Williamson B, Tudzynski B, Tudzynski P, Van Kan JAL (2007) Botrytis cinerea: the cause of grey mould disease. Mol Plant Pathol 8:561–580
Wurms K (2005) Susceptibility to Botrytis cinerea, and curing-induced responses of lytic enzymes and phenolics in fruit of two kiwifruit (Actinidia) cultivars. N Z J Crop Hortic Sci 33:25–34
Acknowledgments
The authors thank Monsanto Seeds and Fairbanks Seeds for supplying capsicum seeds. The first author is grateful to the Agricultural Science and Technology Project of Vietnam for awarding a PhD scholarship. We thank Sue Pederick (South Australian Research and Development Institute) for sharing her techniques for long-term storage of B. cinerea and Dr Olena Kravchuk (the University of Adelaide) for her advice about multifactorial analysis.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Le, T.D., McDonald, G., Scott, E.S. et al. Infection pathway of Botrytis cinerea in capsicum fruit (Capsicum annuum L.). Australasian Plant Pathol. 42, 449–459 (2013). https://doi.org/10.1007/s13313-013-0204-4
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s13313-013-0204-4