Botrytis cinerea

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Botrytis cinerea is a necrotrophic fungus that affects many plant species, although its most notable hosts may be wine grapes. In viticulture, it is commonly known as "botrytis bunch rot"; in horticulture, it is usually called "grey mould" or "gray mold".

Botrytis cinerea
Botrytis cinerea infection on strawberry
Scientific classification Edit this classification
Domain: Eukaryota
Kingdom: Fungi
Division: Ascomycota
Class: Leotiomycetes
Order: Helotiales
Family: Sclerotiniaceae
Genus: Botrytis
Species:
B. cinerea
Binomial name
Botrytis cinerea
Pers. (1794)

The fungus gives rise to two different kinds of infections on grapes. The first, grey rot, is the result of consistently wet or humid conditions, and typically results in the loss of the affected bunches. The second, noble rot, occurs when drier conditions follow wetter, and can result in distinctive sweet dessert wines, such as Sauternes, the Aszú of Tokaji, or Grasă de Cotnari.[1] The species name Botrytis cinerea is derived from the Latin for "grapes like ashes"; although poetic, the "grapes" refers to the bunching of the fungal spores on their conidiophores, and "ashes" just refers to the greyish colour of the spores en masse.[citation needed] The fungus is usually referred to by its anamorph (asexual form) name, because the sexual phase is rarely observed. The teleomorph (sexual form) is an ascomycete, Botryotinia fuckeliana, also known as Botryotinia cinerea (see taxonomy box).

Etymology

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"Botrytis" is derived from the Ancient Greek botrys (βότρυς) meaning "grapes",[2] combined with the Neo-Latin suffix -itis for disease. Botryotinia fuckeliana was named by mycologist Heinrich Anton de Bary in honor of another mycologist, Karl Wilhelm Gottlieb Leopold Fuckel. Synonyms for the sexual stage are:

  • Botrytis fuckeliana N.F. Buchw., (1949)
  • Botrytis gemella (Bonord.) Sacc., (1881)
  • Botrytis grisea (Schwein.) Fr., (1832)
  • Botrytis vulgaris (Pers.) Fr., (1832)
  • Haplaria grisea Link, (1809)
  • fuckeliana de Bary
  • Phymatotrichum gemellum Bonord., (1851)
  • Polyactis vulgaris Pers., (1809)
  • Sclerotinia fuckeliana (de Bary) Fuckel, (1870)

Hosts and symptoms

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Hosts

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The disease, gray mold, affects more than 200 dicotyledonous plant species and a few monocotyledonous plants found in temperate and subtropical regions, and potentially over a thousand species.[3][4] Serious economic losses can be a result of this disease to both field and greenhouse grown crops. The causal agent, Botrytis cinerea can infect mature or senescent tissues, plants prior to harvest, or seedlings. There is a wide variety of hosts infected by this pathogen including protein crops, fiber crops, oil crops, and horticultural crops. Horticultural crops include vegetables (examples are chickpeas, lettuce, broccoli, and beans) and small fruit crops (examples are grape, strawberry, raspberry, and blackberry[5]), these are most severely affected and devastated by gray mold.[3] Plant organs affected include fruits, flowers, leaves, storage organs, and shoots.

Symptoms and signs

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Symptoms vary across plant organs and tissues. B. cinerea is a soft rot that will have a collapsed and water soaked appearance on soft fruit and leaves. Brown lesions may develop slowly on undeveloped fruit.[6] Twigs infected with gray mold will die back. Blossoms will cause fruit drop and injury, such as ridging on developing and mature fruit.[7] Symptoms are visible at wound sites where the fungus begins to rot the plant. Gray masses with a velvety appearance are conidia on the plant tissues are a sign of plant pathogen.[7] These conidia are asexual spores that will continue to infect the plant and surrounding hosts throughout the growing season making this a polycyclic disease.

Plants can produce localized lesions when a pathogen attacks. An oxidative burst causes hypersensitive cell death called a hypersensitive response (HR).[8] This soft rot can trigger HR to assist in colonization. Botrytis cinerea, as a necrotrophic pathogen, exploits the dead tissue for its pathogenicity or its ability to cause disease. Susceptible plants cannot use the HR to protect against B. cinerea.

Biology

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Conidiophore
 
Petri dish with a ring of visible sclerotia (dark brown balls)

Botrytis cinerea is characterized by abundant hyaline conidia (asexual spores) borne on grey, branching tree-like conidiophores. The fungus also produces highly resistant sclerotia as survival structures in older cultures. It overwinters as sclerotia or intact mycelia, both of which germinate in spring to produce conidiophores. The conidia, dispersed by wind and by rain-water, cause new infections. B. cinerea performs an asexual cycle over the summer season.[citation needed]

Different strains show considerable genetic variability.[citation needed]

Gliocladium roseum is a fungal parasite of B. cinerea.[9]

The hypothetical protein BcKMO was shown to positively regulate growth and development. It showed a great similarity to the kynurenine 3-monooxygenase encoding gene in eukaryotes.[citation needed]

Overexpression of the gene atrB produces altered versions of the transcription factor mrr1, which in turn confer a multiple fungicide resistance phenotype known as MDR1.[5] An even higher overexpression yields mrr1 composed partly of Δ497V/L, yielding MDR1h phenotypes with even more anilinopyrimidine- and phenylpyrrole- resistance.[5]

Environment

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Gray mold favors moist, humid, and warm environmental conditions between 65–75 °F (18–24 °C).[10] Temperature, relative humidity, and wetness duration produce a conducive environment that is favorable for inoculation of mycelium or conidia.[11] Controlled environments, such as crop production greenhouses, provide the moisture and high temperatures that favor the spreading and development of the pathogen B. cinerea.

Standing water on plant leaf surfaces provides a place for spores to germinate.[12] Humid conditions can result from improper irrigation practice, plants placed too close together, or the structure of the greenhouse not allowing for efficient ventilation and air flow. Ventilation at night significantly reduces the incidence of gray mold.[13]

Melanized sclerotium allows B. cinerea to survive for years in the soil. Sclerotia and the asexual conidia spores contribute to the widespread infection of the pathogen.[14]

A low pH is preferred by the gray mold to perform well. B. cinerea can acidify its environment by secreting organic acids, like oxalic acid.[14] By acidifying its surroundings, cell wall degrading enzymes (CWDEs) are enhanced, plant-protection enzymes are inhibited, stomatal closure is deregulated, and pH signaling is mediated to facilitate its pathogenesis.[14]

Viticulture

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Manifesting as noble rot on Riesling

In the Botrytis infection known as "noble rot" (pourriture noble in French, or Edelfäule in German), the fungus removes water from the grapes, leaving behind a higher percent of solids, such as sugars, fruit acids and minerals. This results in a more intense, concentrated final product. The wine is often said to have an aroma of honeysuckle and a bitter finish on the palate.

A distinct fermentation process initially caused by nature, the combination of geology, climate and specific weather led to the particular balance of beneficial fungus while leaving enough of the grape intact for harvesting. The Chateau d'Yquem is the only Premier Cru Supérieur Sauternes, largely due to the vineyard's susceptibility to noble rot.

Botrytis complicates the fermentation process during winemaking. Botrytis produces an anti-fungal compound that kills yeast and often results in the fermentation stopping before the wine has accumulated sufficient levels of alcohol.[15]

Botrytis bunch rot is another condition of grapes caused by B. cinerea that causes great losses for the wine industry. It is always present on the fruitset, however, it requires a wound to start a bunch rot infection. Wounds can come from insects, wind, accidental damage, etc. To control botrytis bunch rot there are a number of fungicides available on the market. Generally, these should be applied at bloom, bunch closure and veraison (the most important being the bloom application). Some winemakers are known to use the German method of fermentation and prefer having a 5% bunch rot rate in their grapes and will usually hold the grapes on the vine a week longer than normal.

Horticulture

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Botrytis cinerea affects many other plants.

Strawberries

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It is economically important on soft fruits such as strawberries and bulb crops.[16] Unlike wine grapes, the affected strawberries are not edible and are discarded. To minimize infection in strawberry fields, good ventilation around the berries is important to prevent moisture being trapped among leaves and berries. A number of bacteria have been proven to act as natural antagonists to B. cinerea in controlled studies.[16]

Other plants

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Botryotinia fuckeliana on a Goudreinet apple

In greenhouse horticulture, Botrytis cinerea is well known as a cause of considerable damage in tomatoes.

The infection also affects rhubarb, snowdrops, white meadowfoam, western hemlock,[17] Douglas-fir,[18] cannabis,[19][20] and Lactuca sativa.[21] UV-C treatment against B. cinerea was investigated by Vàsquez et al., 2017. They find it increases phenylalanine ammonia-lyase activity and production of phenolics. This in turn decreases L. sativa's susceptibility.[21] Potassium bicarbonate-based fungicide may be used.[citation needed]

Human disease

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Botrytis cinerea mold on grapes may cause "winegrower's lung", a rare form of hypersensitivity pneumonitis (a respiratory allergic reaction in predisposed individuals).

Mycoviruses of Botrytis cinerea

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Mycoviruses

Botrytis cinerea not only infects plants, it also hosts several mycoviruses itself (see the table/image).

A range of phenotypic alterations due to the mycoviral infection have been observed from symptomless to mild impact, or more severe phenotypic changes including reduction in pathogenicity, growth/suppression of mycelia, sporulation and sclerotia production, formation of abnormal colony sectors (Wu et al., 2010[22]) and virulence.

Management

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Botrytis cinerea can be managed through cultural, chemical, and biological practices.[23]

There are no resistant species to the gray mold rot. Gray mold can be culturally controlled by monitoring the amount and timing of fertilizer applications to reduce the amount of fruit rot. Excessive application of nitrogen will increase the incidence of disease while not improving yields.[6]

Not planting cultivars that have an upright or dense growth habit can reduce disease as these limit airflow and are favorable for the pathogen. Spacing of plants so they are not touching will increase airflow allowing the area to dry out and reduce the spread of disease. Pruning or purposeful removal of diseased, dead, or overgrown limbs on a regular schedule can also help to improve air movement.[7]

Sanitation by removing dead or dying plant tissue in the fall will decrease inoculum levels as there is no debris for the sclerotium or mycelia to overwinter. Removing debris in the spring will remove inoculum from the site. Disposal of berries during harvest that have signs and symptoms of gray mold will reduce inoculum for the following year.

Biochar, a form of charcoal, can be applied as a soil amendment to strawberry plants to reduce the severity of the fungal disease by stimulating defense pathways within the plant.[24]

Gray mold can be chemically controlled with well-timed fungicide applications starting during the first bloom. Timing can reduce the chance of resistance and will save on costs.[6]

Biological controls or microbial antagonists[citation needed] used for disease suppression, have been successfully used in Europe and Brazil in the form of fungi-like Trichoderma harzianum Rifai and Clonostachys rosea f. rosea Bainier (syn. Gliocladium roseum).[24] Trichoderma species especially, have been shown to control gray mold.

Multiple fungicide resistance is a problem in many production areas.[5]

See also

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References

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  1. ^ Richards, Helen (22 December 2014). "What is... Botrytis". JFT Wines. Retrieved 24 September 2020.
  2. ^ βότρυς. Liddell, Henry George; Scott, Robert; A Greek–English Lexicon at the Perseus Project
  3. ^ a b Williamson, Brian; Tudzynski, Bettina; Tudzynski, Paul; Van Kan, Jan a. L. (2007-09-01). "Botrytis cinerea: the cause of grey mould disease". Molecular Plant Pathology. 8 (5): 561–580. doi:10.1111/j.1364-3703.2007.00417.x. ISSN 1364-3703. PMID 20507522.
  4. ^ Fillinger, Sabine; Elad, Yigal, eds. (2016). Botrytis – the Fungus, the Pathogen and its Management in Agricultural Systems. Springer International Publishing. ISBN 978-3-319-23370-3.
  5. ^ a b c d
  6. ^ a b c "Botrytis Fruit Rot / Gray Mold on Strawberry | NC State Extension Publications". content.ces.ncsu.edu. Retrieved 2017-12-11.
  7. ^ a b c "UC IPM: UC Management Guidelines for Botrytis Diseases And Disorders on Citrus". ipm.ucanr.edu. Retrieved 2017-12-11.
  8. ^ Govrin, Eri M.; Levine, Alex (2000-06-01). "The hypersensitive response facilitates plant infection by the necrotrophic pathogen Botrytis cinerea". Current Biology. 10 (13): 751–757. doi:10.1016/S0960-9822(00)00560-1. ISSN 0960-9822. PMID 10898976. S2CID 17294773.
  9. ^ Yu H, Sutton JC (1997). "Morphological development and interactions of Gliocladium roseum and Botrytis cinerea in raspberry" (PDF). Canadian Journal of Plant Pathology. 19 (3): 237–246. doi:10.1080/07060669709500518.[permanent dead link]
  10. ^ Roberts, Pamela. "Disease Management: Gray Mold on Tomato and Ghost Spot on Pepper" (PDF). IPM Floridia. Retrieved 11 December 2017.
  11. ^ Ciliberti, Nicola; Fermaud, Marc; Roudet, Jean; Rossi, Vittorio (August 2015). "Environmental Conditions Affect Botrytis cinerea Infection of Mature Grape Berries More Than the Strain or Transposon Genotype". Phytopathology. 105 (8): 1090–1096. doi:10.1094/PHYTO-10-14-0264-R. hdl:10807/69950. ISSN 0031-949X. PMID 26218433.
  12. ^ Physiological Aspects of Resistance to Botrytis cinerea. Elad, Y. and Evensen, K.. Publication 3 April 1995[1]
  13. ^ Morgan, Walter M. (1984-06-01). "The effect of night temperature and glasshouse ventilation on the incidence of Botrytis cinerea in a late-planted tomato crop". Crop Protection. 3 (2): 243–251. doi:10.1016/0261-2194(84)90058-9. ISSN 0261-2194.
  14. ^ a b c Amselem, Joelle; Cuomo, Christina A.; Kan, Jan A. L. van; Viaud, Muriel; Benito, Ernesto P.; Couloux, Arnaud; Coutinho, Pedro M.; Vries, Ronald P. de; Dyer, Paul S. (2011-08-18). "Genomic Analysis of the Necrotrophic Fungal Pathogens Sclerotinia sclerotiorum and Botrytis cinerea". PLOS Genetics. 7 (8): e1002230. doi:10.1371/journal.pgen.1002230. hdl:10871/25762. ISSN 1553-7404. PMC 3158057. PMID 21876677.
  15. ^ van Kan, Jan A. L. (May 2006). "Licensed to kill: the lifestyle of a necrotrophic plant pathogen". Trends in Plant Science. 11 (5): 247–253. doi:10.1016/j.tplants.2006.03.005. ISSN 1360-1385. PMID 16616579.
  16. ^ a b Donmez, M. F.; Esitken, A.; Yildiz, H.; Ercisli, S. Biocontrol of Botrytis Cinerea on Strawberry Fruit by Plant Growth Promoting Bacteria, The Journal of Animal & Plant Sciences, 21(4), 2011: pp. 758-763, ISSN 1018-7081.
  17. ^ Van Eerden, E. (1974, August). Growing season production of western conifers. In Proc. North American Containerized Forest Tree Seedling Symp., Denver, Colorado (pp. 93-103)
  18. ^ Brix, Holger, and H. Barker. "Rooting studies of western hemlock cuttings." (1975).
  19. ^ Lata, Hemant; ElSohly, Mahmoud A.; Chandra, Suman, eds. (2017-05-23). Cannabis Sativa L. - Botany and Biotechnology. Cham, Switzerland: Springer International. p. 275. ISBN 978-3-319-54563-9. Cannabis is highly susceptible to diseases caused by fungal growth. Densely packed buds and flowering tops hold high content of moisture that allows for infestation by molds such as Botrytis cinerea, Sclerotinia sclerotiorum, Fusarium species etc.
  20. ^ McPartland, JM; Clarke, RC; Watson, DP (2000). Hemp Diseases and Pests: Management and Biological Control: An Advanced Treatise. Wallingford, United Kingdom: CABI. p. 95. B. cinera often colonizes senescent leaves and flowers, and from these footholds it invades the rest of the plant.
  21. ^ a b Urban, L.; Chabane Sari, D.; Orsal, B.; Lopes, M.; Miranda, R.; Aarrouf, J. (2018). "UV-C light and pulsed light as alternatives to chemical and biological elicitors for stimulating plant natural defenses against fungal diseases". Scientia Horticulturae. 235. Elsevier: 452–459. doi:10.1016/j.scienta.2018.02.057. ISSN 0304-4238. S2CID 90436989.
  22. ^ Wu M. D.; Zhang L.; Li G.; Jiang D.; Ghabrial S. A. (2010). "Genome characterization of a debilitation-associated mitovirus infecting the phytopathogenic fungus Botrytis cinerea". Virology. 406 (1): 117–126. doi:10.1016/j.virol.2010.07.010. PMID 20674953.
  23. ^ McLoughlin, Austein G.; Wytinck, Nick; Walker, Philip L.; Girard, Ian J.; Rashid, Khalid Y.; Kievit, Teresa de; Fernando, W. G. Dilantha; Whyard, Steve; Belmonte, Mark F. (9 May 2018). "Identification and application of exogenous dsRNA confers plant protection against Sclerotinia sclerotiorum and Botrytis cinerea". Sci Rep. 8 (1): 7320. Bibcode:2018NatSR...8.7320M. doi:10.1038/s41598-018-25434-4. PMC 5943259. PMID 29743510.
  24. ^ a b Harel, Yael Meller; Elad, Yigal; Rav-David, Dalia; Borenstein, Menachem; Shulchani, Ran; Lew, Beni; Graber, Ellen R. (2012). "Biochar mediates systemic response of strawberry to foliar fungal pathogens". Plant and Soil. 357 (1–2): 245–257. doi:10.1007/s11104-012-1129-3. JSTOR 24370313. S2CID 16186999.
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