Biology:Taphrina deformans

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Short description: Species of fungus

Taphrina deformans
Taphrina deformans 1.jpg
Scientific classification edit
Domain: Eukaryota
Kingdom: Fungi
Division: Ascomycota
Class: Taphrinomycetes
Order: Taphrinales
Family: Taphrinaceae
Genus: Taphrina
Species:
T. deformans
Binomial name
Taphrina deformans
(Berk.) Tul. (1866)
Synonyms
  • Ascomyces deformans Berk. (1860)
  • Exoascus deformans (Berk.) Fuckel (1870)
  • Exoascus amygdali Jacz. (1926)
  • Taphrina amygdali (Jacz.) Mix (1936)

Taphrina deformans is a fungus and plant pathogen, and a causal agent[s] of peach leaf curl.[1] Peach trees infected with T. deformans will experience leaf puckering and distortion, acquiring a characteristic downward and inward curl. Leaves will also undergo chlorosis, turning a pale green or yellow, and later show a red or purple tint.[2] Fruit can either drop prematurely or show surface distortions.[3] Severe infection can also produce lesions on the flowers.[2] The host tree will experience defoliation if the leaves are badly diseased. If a seedling is severely infected, it may die.[4] Almond trees display similar symptoms.[2]

Taphrina deformans

Life cycle

Taphrina deformans infects species of the genus Prunus (including P. amygdalus (almond) and P. persica (peach)).[5] It is best known as the causative agent of peach leaf curl in peaches and nectarines. It has been observed that this fungus also infects the fruits of some South American trees like Ocotea puberula, Nectandra megapotamica and other Lauraceae species. An additional form has been identified which infects apricots. Some researchers posit that these forms are separate varieties altogether, which is supported by recent genetic evidence based on hybridization. Furthermore, almond strains of T. deformans seem to be unable to induce peach leaf curl on peach trees, and vice versa.[2]

Infected leaves develop a whitish bloom as the infection progresses. This bloom consists of asci that break through the cuticle of the leaf by way of lysis.[6] One ascus contains eight ascospores, which are ejected in early summer and moved by rain and wind. This fungus is believed to survive the winter by staying on the surface of the new host plant, such as on bark or buds.[7] In the spring, new buds are infected by the conidia as the leaves emerge from the buds. The disease does not occur every year, as it requires a minimum of 3mm of rainfall followed by at least 12 days during which the developing conidia remain damp and at temperatures below 19 °C.[8][9] The fungus has higher infection rates following cooler, damper winters.[9]

Taphrina deformans hyphae growing in intercellular spaces secrete polysaccharide-degrading enzymes, such as cellulase, causing partial dissolution of the host cell wall. This process also results in changes in the plasma membrane.[6] T. deformans also produces the auxin indole-3-acetic acid from L-tryptophan via indole-3-pyruvic acid and indole-3-acetaldehyde. This process is thought to be responsible for the hyperplastic effect of the infection.[10]

Peach leaf curl management

Because infection depends on a wet environment, appropriate irrigation of crops can help control pathogen dispersal. Although some sources also suggest thinning fruit to control the spread of disease,[3] sanitation and culturing practices alone are insufficient to manage the pathogen.[2] Fungicide is preferred; chlorothalonil and ziram are favored, and copper is an organic option.[4] Fungicide application requires the correct timing and complete coverage of the crop.[11] It is recommended that growers spray fungicides after leaf-fall, or after 90% senescence of leaves. In wetter climates, where multiple sprays may be necessary, spraying is recommended in the late fall and in late winter or early spring.[3] Post-infection spraying of fungicide is inadequate to control the disease.[11]

Although most commercial cultivars are susceptible, there are several genotypes of Prunus persica that have been identified as resistant to infection by T. deformans.[12] These resistant genotypes appear to use molecular and biochemical mechanisms to manage the spread and development of the disease.[13] For example, chlorogenic acid, which is known to have antifungal activity in vitro, is present in resistant strains but not susceptible strains. The chloroplasts are also activated as a site of defense signaling.[12] Additionally, upregulation of the pattern of accumulation of isochorismate synthase indicates increased salicylic acid production. The activation of salicylic acid-dependent pathways suggests a mechanism to achieve systemic acquired resistance.[13]

Importance

Peach leaf curl is present wherever peaches or nectarines are grown.[2] The economic impact of the disease varies regionally, as pathogen spread and symptom severity depends on environmental factors. In the United States, $2.5 to 3 million dollars are lost because of peach leaf curl. Sixty to ninety percent of peach shoots in Italy can be infected by T. deformans.[14] Although peach leaf curl is mostly manageable with fungicide spraying in dry climates,[4] improper timing or incomplete coverage of the crop can result in control failure.[11] Wetter climates which require multiple applications of fungicide will be more susceptible to human error.[4] Additionally, unexpected winter warming can allow the pathogen to establish itself within buds before the late winter or early spring application of fungicide.[3] Without fungicides, or through control failure, the disease can result in total yield loss, along with the stunting and death of shoots. Yield loss can result from tree defoliation, leading to decreased photosynthesis, and from infection of fruit, which decreases marketability.[4]

Taphrina deformans genome

Taphrina deformans genome has been sequenced.[14] The genome carries characteristic genes that are important for the plant infection process.

References

  1. Peach leaf curl, Taphrina deformans at West Virginia University
  2. 2.0 2.1 2.2 2.3 2.4 2.5 Fonseca, Álvaro; Rodrigues, Manuel (2011). "Taphrina Fries". The Yeasts (5th ed.). pp. 823–858. doi:10.1016/B978-0-444-52149-1.00073-2. 
  3. 3.0 3.1 3.2 3.3 Peter, Kari (May 2017). "Disease of the Month: Peach Leaf Curl". https://extension.psu.edu/disease-of-the-month-peach-leaf-curl. 
  4. 4.0 4.1 4.2 4.3 4.4 United States Department of Agriculture (1999). "Crop profile for peaches in California". https://ucanr.edu/datastoreFiles/391-419.pdf. 
  5. Mix AJ. (1956). “Notes on Some Species of Taphrina”. Transactions of the Kansas Academy of Science 59 (4): 465-482
  6. 6.0 6.1 Bassi M, Conti GG, & Barbieri N. (1984). “Cell wall degradation by Taphrina deformans in host leaf cells.” Mycopathologia 88 (2-3) 115–125
  7. Gray, William D.. The Relation of Fungi to Human Affairs. New York: Henry Holt and Company, Inc., 1959. Print.
  8. Rossi V, Bolognesi M, Languasco L, & Giosuè S. (2006). “Influence of Environmental Conditions on Infection of Peach Shoots by Taphrina deformansEcology and Epidemiology 96 (2) 155-163
  9. 9.0 9.1 Smith, S.E. What is Peach Leaf Curl? 2009. WiseGEEK. 14 Apr 2009 <http://www.wisegeek.com/what-is-peach-leaf-curl.htm>
  10. Yamada Y, Tsukamoto H, Shiraishi T, Nomura T, & Oku H. (1990). “Detection of Indoleacetic Acid Biosynthesis in Some Species of Taphrina Causing Hyperplastic Diseases in Plants” Annals of the Phytopathological Society of Japan. 56 532–540
  11. 11.0 11.1 11.2 Tate, K.G. (Fall 1991). "Fungicides, rates, and timing for leaf curl control on nectarine". New Zealand Journal of Crop and Horticultural Science 19 (3): 291–295. doi:10.1080/01140671.1991.10421813. 
  12. 12.0 12.1 Svetaz, Laura; Goldy, Camila (Fall 2017). "Comparative proteomic and metabolomics studies between Prunus persica genotypes resistant and susceptible to Taphrina deformans suggest a molecular basis of resistance". Plant Physiology and Biochemistry 144: 245–255. doi:10.1016/j.plaphy.2017.06.022. PMID 28651230. 
  13. 13.0 13.1 Svetaz, Laura (Winter 2017). "Unraveling early events in the Taphrina deformans-Prunus persica interaction: an insight into the differential responses in resistant and susceptible genotypes". Plant, Cell & Environment 40 (8): 1456–1473. doi:10.1111/pce.12942. PMID 28244594. 
  14. 14.0 14.1 Cisse, O. H., J. M. Almeida, A. Fonseca, A. A. Kumar, J. Salojarvi, K. Overmyer, P. M. Hauser and M. Pagni (2013). “Genome sequencing of the plant pathogen Taphrina deformans, the causal agent of peach leaf curl." MBio 4(3) e00055-00013.

External links

  • Taphrina deformans at Fungal Databases [1]

Wikidata ☰ Q2022500 entry