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Plasmopara viticola

February 16, 2024

Plasmopara viticola, the causal agent of grapevine downy mildew, is a heterothallic oomycete that overwinters as oospores in leaf litter and soil. In the spring, oospores germinate to produce macrosporangia, which under wet condition release zoospores. Zoospores are splashed by rain into the canopy, where they swim to and infect through stomata. After 7–10 days, yellow lesions appear on foliage. During favorable weather the lesions sporulate and new secondary infections occur.[5]

Plasmopara viticola
Scientific classification
Domain: Eukaryota
Clade: Diaphoretickes
Clade: SAR
Clade: Stramenopiles
Phylum: Oomycota
Order: Peronosporales
Family: Peronosporaceae
Genus: Plasmopara
Species:
P. viticola
Binomial name
Plasmopara viticola
(Berk. & M.A. Curtis) Berl. & De Toni, (1888)
Synonyms[1][2][3][4]
  • Botrytis viticola Berk. & M.A. Curtis, (1848)
  • Peronospora viticola (Berk. & M.A. Curtis) de Bary, (1863)
  • Plasmopara amurensis Prots., (1946)
  • Rhysotheca viticola (Berk. & M.A. Curtis) G.W. Wilson, (1907)

Description edit

Plasmopara viticola, also known as grape downy mildew, is considered to be the most devastating disease of grapevines in climates with relatively warm and humid summers. It was first observed in 1834 by Schweinitz on Vitis aestivalis in the southeastern United States.[6] Shortly after this first observation, the pathogen was introduced to European countries where it played a devastating role in the yield and production of their grapes, and consequently their wine. France was among the first of the European countries to gain experience in dealing with the pathogen. Within just a few years of the pathogen's introduction the French attempted to graft American root stock to their own vines in order to produce a more resistant strain of grape. Depending on the year, production of grapes in France has been estimated to have been reduced by as much as 50%.[1] Because of numbers and results like these, downy mildew has been considered the most devastating disease of a filamentous pathogen to affect European vineyards.[3][2][7] When comparing three grape producers in Europe, including some fields that were treated with fungicides or other management strategies, the economic losses ranged from ~2000 euros per hectare to ~4250 euros per hectare.

Symptoms cover a fairly large range depending mostly on the host. Common symptoms include necrosis of the stem or shoot, discoloration including brown spotting (lesions) and yellowish-green tips of the leaves. Grapes may exhibit sporangia and sporangiophores, appearing as white to gray coat on the outer surface.

Downy mildew has a specific set of environmental conditions to reproduce and infect. A warm, moist, and humid environment is required. Studies in Sicily have shown optimum time for oospore germination is between the end of February and the middle of March.[4] With this understanding, if fungicides are used just before optimum conditions occur, they have proven to be an effective control method of the pathogen. Other control methods include proper watering, and a good location where the plant can receive continual sunlight.

Disease cycle edit

Oospores, the sexual structures of Plasmopara viticola, are produced in late summer. The pathogen can survive winter as oospores in host tissue like dead leaves on the vineyard floor. There they can survive up to 3–5 years, possibly up to 10 years.[8] Oospores may also be released from decaying plant material on soil surfaces.

The "rule of thumb", 10:10:24, refers to the required environmental condition for primary infection. At least 10mm rainfall (or irrigation) is needed while the temperature should be 10 °C or more over 24 hours.[8] Under favorable conditions, oospores would germinate.

In spring the oospores would produce sporangia, which then produce zoospores, the swimming spores. Zoospores and sporangia can be dispersed by rain and wind to some lower tissue of the grapevines.

Sporangia can decline in viability over time. After 10 days in a 15°C humid chamber sporangia will die. Sporangia that are exposed to direct light for over 15 minutes will not survive.[9] [10]

Once the zoospores are produced and land on the host plant tissue, the primary infection would occur. Primary infection is from soil to vine. Zoospores encyst and then germinate. The germ tubes would be formed and then invade into the plant tissue via stomates.[11] After infection, there would be oil spots on the leaf surface.

Active oil spots are necessary for secondary infection and sporangia are responsible for this process. Secondary infection is from leaf to leaf, shoot, inflorescence, berries, and stalk.[8] The sporangia, seen as the white fungal-like organism on the downside of the leaves, are produced after a warm and high humid night.[11] The sporangia can then be dispersed by wind or rain to occur secondary infections. Sporangia is the asexual reproduction structure, which then produce sporangiophores.[8] The secondary infection is repeatable as long as under suitable conditions.[5]

Hosts and symptoms edit

 
Sporangia and sporangiophores protruding from the stomates of the grape berries

The hosts of Plasmopara viticola includes the species Vitis vinifera and all cultivars within the species. It also can affect any interspecific hybrids within the Vitis genus. There is also some susceptibility in the Vitis labrusca species, ranging from highly susceptible to resistant. The European cultivar is most susceptible to the pathogen, as it lacks evolutionary resistance that the American varieties have, because the pathogen originated in the Americas and was later transmitted into Europe.[12] North American species are also susceptible but varies from high susceptibility to resistance. In the regions with high annual rainfall, the grapevines may suffer more from this disease.[5]

Leaves edit

The first symptom of downy mildew of grapes usually can be seen on leaves after 5 to 7 days of primary infection. Early in the season (spring), Yellow circular spots with oily appearances is going to present on foliage along with the veinlets. Note that, in some red grape varieties, the spots may in red color. The young oil-spots are surrounded by brown-yellow halos. As the oil-spots get mature, the halo would fade. As the oil spots age and develop, infected tissue would become necrotic and nonreproductive, due to cell death.[5] If under appropriate weather conditions, a larger number of oil-spots can develop, expand, and cover most of the leaf surfaces.

After a warmer and humid night, a white downy fungal growth (sporangia) would be abundant on the downsides of the leaves and other infected plant areas. The severely infected portion could die. Severely infected leaves may drop from the plant.[11]

The pathogen may also attack the old leaves in late summer.[11] The infected old leaves may present a mosaic pattern with yellow to red-brown spots on the upside of the leaves' surface.

Other parts edit

The shoots of the plant can also be infected and shown as the same oily patches. After a warm humid night, these oily patches may also sporulate and be covered with white fungal growth.[8] The shoots are may also be distorted or curled after infection.

The grape fruits may also have the symptoms in the later season. The infected berries would turn brown, wither, and then die finally. The infected green fruit may turn light brown and purple. White fungal growth(sporulation) can abundant on the grapes during humid weather. Infected grapes are easy to detach from the pedicles.[11] However, the fruits become resistant to infection around 2–3 week after blooming, excluding the rachis. The rachis becomes resistant only around 2 months after blooming.

If the young bunch stalk is infected, oily brown sites can be seen. The infected inflorescence or bunches would wither rapidly. Infected inflorescence would eventually turn to brown, which means the death of the bunches.[8]

Pathogenesis edit

 
Lemon-shaped sporangia of Plasmopara viticola
 
Sporangium and spores of Plasmopara viticola

The disease development of grape downy mildew is known to be heavily reliant on the efficiency of the asexual propagation cycles. Kiefer et al. (2002) demonstrated that the early development of Plasmopara viticola is regulated specifically and coordinately by unknown factors originating from the host grapevine plant Vitis vinifera.[13] The host factors influence the pathogen development in three ways: (i) accelerating the release of zoospores from mature sporangia, (ii) coordinating the morphogenesis of the germ tube through the reorientation of the polarity of the zoospores during the attachment to the host cell, and (iii) targeting the zoospores to the stomata by active chemotaxis from the open substomatal cavity.[13] The expression of pathogenesis-related (PR) genes by the host plant V.vinifera during the infection of P.viticola has been investigated over the years. The expressions of PR-2, PR-3 and PR-4 genes are induced in the grapevine host during pathogen infection, which encode for cell wall-degrading enzymes B-1,3-glucanase (PR-2) and chitinases (PR-3 and PR-4).[14] It was previously understood that oomycetes differ from true fungi by the presence of cellulose in the oomycetes' cell walls as opposed to chitin in true fungi. However, it was found that chitin synthesis is regulated during in planta growth and asexual propagation of P.viticola and this is further demonstrated by the presence of chitin on the cell walls of the hyphae, sporangiophores and sporangia of the grape downy mildew pathogen.[15] Hence, both the cell wall-degrading enzymes are synthesized by the host grapevine plant specifically to target and degrade the cell walls of the oomycete pathogen.[14] In addition, the upregulation of the PR-9 gene that encodes for peroxidase, which is a reactive oxygen species is associated with the systemic acquired defense of the grapevine host.[14] The roles of other constitutively expressed PR genes during P.viticola infection such as PR-5, PR-1 and PR-10 genes remain ambiguous. PR-5 is involved in the synthesis of thaumatin-like proteins and osmotins, which are believed to inhibit the spore germination and germ tube growth of Plasmopara viticola by creating transmembrane pores.[14]

Management edit

The history of downy mildew control began with an accidental discovery in 1882.[16] In order to prevent passersby from eating from grapevines close to the road, Pierre-Marie-Alexis Millardet sprayed those vines with a mixture of copper sulfate and lime, which was both seeable and awful-tasting.[16] He then noticed that the treated grapevines did not show any symptoms of downy mildew, whereas the rest of the vineyard was infected by the disease.[16] After further studies, Millardet published the recommended treatment of the grapevines against the downy mildew in 1885 in which he proposed the use of 8:15:100 of copper sulfate: hydrated lime: water mixture in the treatment (later named as Bordeaux mixture after the Bordeaux region where Millardet conducted the research).[16] The treatment of Bordeaux mixture against the downy mildew was well-received globally due to its strong adhesion to the leaves, its long perseverance in the vineyard, and its color, which allows for observable distribution of the treatment.[16]

Copper-based control methods are still commonly used today. As science became more precise, the amounts of copper-sulfate used in solution were optimized for best control of the Higher concentrations of copper-sulfate (3–4%) are recommended for high risk conditions, while low concentrations (1–1.5%) are for low risk conditions. The risk of susceptibility for the plant is highly correlated with the season.[12] Most of the ineffectiveness in fungicide use is correlated with spraying at inappropriate times. It is necessary to spray right before budding in the spring. Furthermore, coating the entire leaf with a film of the fungicide is necessary for control; thinning the foliage makes achieving an entire coat possible.[12] However, overusing chemical controls with copper can create harmful non-target effects. Copper can negatively impact the biological diversity in the soil and groundwater. [17]

Unlike in Vitis vinifera, there is a wide range of susceptibility to downy mildew among Vitis interspecific hybrids. For example, among North American grapevine species, Vitis aestivalis and Vitis labrusca are moderately susceptible while Vitis cordifolia, Vitis rupestris and Vitis rotundifolia are relatively resistant.[6] Certain Vitis interspecific hybrid cultivars display organ-specific resistance. For example, leaves of Aurore and Delaware cultivars are moderate to highly susceptible, whereas their fruit are highly resistant to downy mildew.[6] Another example is the cultivar Chancellor in which the leaves exhibit moderate levels of resistance to downy mildew, while the clusters, tendrils and shoot tips are highly susceptible to the disease.[6] Several new European cultivars such as Regent have been developed from progeny of crosses between V. vinifera and resistant North American species in an effort to incorporate the most desirable qualities of both parental branches.

Note that, berries become resistant to infection after 2 to 3 weeks after bloom, other parts of the plants may remain susceptible 2 months after bloom.[18]

Cultural management edit

Reduce the risk of disease when establishing the vineyards. This practice includes choosing the location, drainage, soil, and irrigation system.[18]

Avoid the distribution of infected soil and plant tissue from equipment.[8] Carefully clean the equipment or change equipment after used in the infected areas. Also, carefully clean the boots or clothes after entering the infected areas.

Canopy management practices, such as low planting density, vine trimming, and hedging, and later shoot thinning, can improve the air movement and make the leaves drier.[8]

Genetic resistances edit

Investigating in wild grape varieties to increase the genetic resistance. Develop the breeding of disease-resistant cultivars.[19] Resistant cultivars can be useful and efficient to avoid infection.

Monitoring edit

Automatic weather stations can be established for monitoring and predicting weather events. Collecting data from temperature, rainfall, leaf wetness, and humidity.[8]

Chemical control edit

Pre-infection fungicides prevent the zoospores to enter the leaf stomates. Also, post-infection fungicides can be used as soon as possible after infection to kill the pathogen tissues inside the leaves.[8] Chemical pesticides are useful methods to control this pathogen and downy mildew.[19]

Biological control edit

Biological agents, like Epicoccum nigrum link, can inhibit the spread of spores of Plasmopara viticola.[20] Microorganisms can be used to biocontrol plant disease. However, microbial control agents do not work well. [19] A recent study (2020) has shown that the bacteria Ochrobactrum sp. may be a promising future biological control. However, there are no reports of the grape industry that have used the bacteria Ochrobactrum sp. as a control of grape downy mildew.[21]

Taxonomy edit

In 1848, Berkeley and Curtis made reference to a downy mildew on grapevines, and, in a footnote, named it Botryis viticola.[22] However, Botryis viticola was a nomen nudum.[23] It was later transferred to Peronospora and then to Plasmopara. In 1907, Wilson erected Rhysotheca with P. viticola as the type;[24] however, the name Rhysotheca viticola never caught on.[22] In 1946, a strain on Vitis amurensis was raised to the species level as P. amurensis. In 1955, Golovina named the varieties americana, aneurensis, and parthica. In 1951, Alice Săvulescu and Traian Săvulescu named the formae speciales viniferae-ampelopsidis, aestivalis-labruscae, and silvestris based on host and morphology.[25] Later authors synonymized all these names back into P. viticola.[22] A population level analysis of P. viticola from the United States of America revealed the presence of four lineages that correspond to the host that could be distinguished based on molecular phylogenetics, morphology, and cross-inoculation experiments: P. viticola f. sp. quinquefolia, P. viticola f. sp. vinifera, P. viticola f. sp. aestivalis, and P. viticola f. sp. riparia.[26] Further study recognized an additional lineage: P. viticola clade vulpina.[27] The lineage Plasmopara f. sp. quinquefolia has been named Plasmopara muralis.[27]

References edit

  1. ^ a b Hesler, Lexemuel Ray; Whetzel, Herbert Hice (1917). Manual of Fruit Diseases. The Rural Manuals, ed. by L. H. Bailey. New York: The Macmillan Company. p. 237. doi:10.5962/bhl.title.56823. OCLC 938509.
  2. ^ a b Salazar Hernández, Domingo M. (1994). "Enfermedades criptogámicas: el Mildiu (I)". Semana vitivinícola (in Spanish) (2487): 1051–1053. ISSN 0037-184X.
  3. ^ a b Pérez-Salas, Joaquín (1988). "Defensa contra el mildiu: características de la enfermedad". Semana vitivinícola (in Spanish) (2191): 3385–3387. ISSN 0037-184X.
  4. ^ a b Burruano, Santella; Ciofalo, G. (1990). "Studio della dinamica di germinazione delle oospore di Plasmopara viticola (Berk. et Curt.) Berl. et De Toni". Notiziario delle Mallattie delle Piante (in Italian). Ser. 3 (38): 274–286.
  5. ^ a b c d Kennelly, Megan M.; Gadoury, David M.; Wilcox, Wayne F.; Magarey, Peter A.; Seem, Robert C. (April 2007). "Primary infection, lesion productivity, and survival of sporangia in the grapevine downy mildew pathogen Plasmopara viticola". Phytopathology. 97 (4): 512–522. doi:10.1094/PHYTO-97-4-0512. PMID 18943292.
  6. ^ a b c d Compendium of Grape Diseases, Disorders, and Pests Second Edition. The American Phytopathological Society. 2015. pp. 46–51. ISBN 978-0-89054-479-2.
  7. ^ Pérez Marín, José Luis (1988). "Mildiu de la vid: cómo combatirlo" (PDF). Agricultura: Revista agropecuaria y ganadera (in Spanish) (676): 798–800. ISSN 0002-1334.
  8. ^ a b c d e f g h i j Taylor, Andrew (May 2021). "Downy mildew of grapevines". Government of Western Australia. Retrieved 1 May 2022.
  9. ^ Kennelly, M., Gadoury, D., Wilcox, W., Magarey, P., & Seem, R. (2007). Primary Infection, Lesion Productivity, and Survival of Sporangia in the Grapevine Downy Mildew Pathogen Plasmopara viticola. Phytopathology, 97(4), 512-522.
  10. ^ Kast, W., & Stark-Urnau, M. (1999). Survival of sporangia from Plasmopara viticola, the downy mildew of grapevine. Vitis, 38(4), 185-186.
  11. ^ a b c d e Hartman, John R.; Beale, Julie W.; Kaiser, Cheryl A. (2008). "Plant Pathology Fact Sheet: Downy Mildew of Grape" (PDF). Cooperative Extension, University of Kentucky. Retrieved 1 May 2022.
  12. ^ a b c Gessler, Cesare; Pertot, Ilaria; Perazzolli, Michele (2011). "Plasmopara viticola: a review of knowledge on downy mildew of grapevine and effective disease management". Phytopathologia Mediterranea. 50 (1): 3–44.
  13. ^ a b Kiefer, Beate; Riemann, Michael; Büche, Claudia; Kassemeyer, Hanns-Heinz; Nick, Peter (2002-07-01). "The host guides morphogenesis and stomatal targeting in the grapevine pathogen Plasmopara viticola". Planta. 215 (3): 387–393. doi:10.1007/s00425-002-0760-2. ISSN 0032-0935. PMID 12111219. S2CID 13007776.
  14. ^ a b c d Kortekamp, A. (2006-01-01). "Expression analysis of defence-related genes in grapevine leaves after inoculation with a host and a non-host pathogen". Plant Physiology and Biochemistry. 44 (1): 58–67. doi:10.1016/j.plaphy.2006.01.008. PMID 16531058.
  15. ^ Werner, Stefan; Steiner, Ulrike; Becher, Rayko; Kortekamp, Andreas; Zyprian, Eva; Deising, Holger B. (2002-03-01). "Chitin synthesis during in planta growth and asexual propagation of the cellulosic oomycete and obligate biotrophic grapevine pathogen Plasmopara viticola". FEMS Microbiology Letters. 208 (2): 169–173. doi:10.1111/j.1574-6968.2002.tb11077.x. ISSN 0378-1097. PMID 11959432.
  16. ^ a b c d e Perazzolli, Michele; Pertot, Ilaria; Gessler, Cesare (2011-05-10). "Plasmopara viticola : a review of knowledge on downy mildew of grapevine and effective disease management". Phytopathologia Mediterranea. 50 (1): 3–44. doi:10.14601/Phytopathol_Mediterr-9360 (inactive 31 January 2024). Retrieved 2015-12-30.{{cite journal}}: CS1 maint: DOI inactive as of January 2024 (link)
  17. ^ Tröster, V. (2016, May 2). Achilles' heel of grapevine downy mildew. Retrieved May 2023, from https://publikationen.bibliothek.kit.edu/1000052562
  18. ^ a b Ash, Gavin (2000). "Downy mildew of grape". The Plant Health Instructor. The American Phytopathological Society (APS). doi:10.1094/PHI-I-2000-1112-01.
  19. ^ a b c Gessler, Cesare; Pertot, Ilaria; Perazzolli, Michele (April 2011). "Plasmopara viticola: a review of knowledge on downy mildew of grapevine and effective disease management". Phytopathologia Mediterranea. 50 (1): 3–44. JSTOR 26458675.
  20. ^ Kortekamp, Andreas (1997). "Epicoccum nigrum Link: A biological control agent of Plasmopara viticola (Berk. et Curt.) Berl. et De Toni?". Vitis. 36 (4): 215–216.
  21. ^ Zang, C., Lin, Q., Xie, J., Lin, Y., Zhao, K., & Liang, C. (2020). The biological control of the grapevine downy mildew disease using ochrobactrum sp. Plant Protection Science, 56(1), 52-61.
  22. ^ a b c Hall, Geoffrey (1989). "Plasmopara viticola". Mycopathologia. 106: 209–211.
  23. ^ Stevenson, J.A. (1971). "An account of fungus exsiccati containing material from the Americas". Nova Hedwigia: 1–564.
  24. ^ Wilson, G. W. (1907). "Studies in North American Peronosporales-II. Phytophthoreae and Rhysotheceae". Bulletin of the Torrey Botanical Club. 34 (8): 387–416. doi:10.2307/2479202. JSTOR 2479202.
  25. ^ Săvulescu & Săvulescu. 1951. Studiul morfologic, biologic si sistematic al genurilor Sclerospora, Basidiophora, Plasmopara, si Peronoplasmopara.
  26. ^ Rouxel, Melanie; Mestre, Pere; Comont, Gwenaelle; Lehman, Brian L.; Schilder, Annemiek; Delmotte, Francois (2013). "Phylogenetic and experimental evidence for host-specialized cryptic species in a biotrophic oomycete". New Phytologist. 197 (1): 251–263. doi:10.1111/nph.12016. PMID 23153246.
  27. ^ a b Rouxel, Melanie; Mestre, Pere; Baudoin, Anton; Carisse, Odile; Deliere, Laurent; Ellis, Michael A.; Gadoury, David; Lu, Jiang; Nita, Mizuho; Richard-Cervera, Sylvie; Schilder, Annemiek; Delmotte, Francois (2014). "Geographic distribution of crptic species of Plasmopara viticola causing downy mildew on wild and cultivated grape in eastern North America". Phytopathology. 104 (7): 692–701. doi:10.1094/phyto-08-13-0225-r. PMID 24915427.

Further reading edit

  • Corio-Costet, Marie-France (2012). Fungicide Resistance in Plasmopara viticola in France and Anti-Resistance Measures (PDF) (12th ed.). CABI. pp. 157–177. ISBN 9781845939052.
  • Gobbin, Davide; Rumbou, Artemis; Linde, Celeste C.; Gessler, Cesare (November 2006). "Population genetic structure of Plasmopara viticola after 125 years of colonization in European vineyards". Molecular Plant Pathology. 7 (6): 519–531. doi:10.1111/j.1364-3703.2006.00357.x. PMID 20507466.
  • Puopolo, G.; Cimmino, A.; Palmieri, M.C. (October 2014). "Lysobacter capsici AZ78 produces cyclo(L-Pro-L-Tyr), a 2,5-diketopiperazine with toxic activity against sporangia of Phytophthora infestans and Plasmopara viticola". Journal of Applied Microbiology. 117 (4): 1168–1180. doi:10.1111/jam.12611. hdl:11572/227185. PMID 25066530. S2CID 7788785.

External links edit

  • Contributions of oospore inoculum to epidemics of grapevine downy mildew (Plasmopara viticola)

February 16, 2024
plasmopara, viticola, causal, agent, grapevine, downy, mildew, heterothallic, oomycete, that, overwinters, oospores, leaf, litter, soil, spring, oospores, germinate, produce, macrosporangia, which, under, condition, release, zoospores, zoospores, splashed, rai. Plasmopara viticola the causal agent of grapevine downy mildew is a heterothallic oomycete that overwinters as oospores in leaf litter and soil In the spring oospores germinate to produce macrosporangia which under wet condition release zoospores Zoospores are splashed by rain into the canopy where they swim to and infect through stomata After 7 10 days yellow lesions appear on foliage During favorable weather the lesions sporulate and new secondary infections occur 5 Plasmopara viticolaScientific classificationDomain EukaryotaClade DiaphoretickesClade SARClade StramenopilesPhylum OomycotaOrder PeronosporalesFamily PeronosporaceaeGenus PlasmoparaSpecies P viticolaBinomial namePlasmopara viticola Berk amp M A Curtis Berl amp De Toni 1888 Synonyms 1 2 3 4 Botrytis viticola Berk amp M A Curtis 1848 Peronospora viticola Berk amp M A Curtis de Bary 1863 Plasmopara amurensis Prots 1946 Rhysotheca viticola Berk amp M A Curtis G W Wilson 1907 Contents 1 Description 2 Disease cycle 3 Hosts and symptoms 3 1 Leaves 3 2 Other parts 4 Pathogenesis 5 Management 5 1 Cultural management 5 2 Genetic resistances 5 3 Monitoring 5 4 Chemical control 5 5 Biological control 6 Taxonomy 7 References 8 Further reading 9 External linksDescription editPlasmopara viticola also known as grape downy mildew is considered to be the most devastating disease of grapevines in climates with relatively warm and humid summers It was first observed in 1834 by Schweinitz on Vitis aestivalis in the southeastern United States 6 Shortly after this first observation the pathogen was introduced to European countries where it played a devastating role in the yield and production of their grapes and consequently their wine France was among the first of the European countries to gain experience in dealing with the pathogen Within just a few years of the pathogen s introduction the French attempted to graft American root stock to their own vines in order to produce a more resistant strain of grape Depending on the year production of grapes in France has been estimated to have been reduced by as much as 50 1 Because of numbers and results like these downy mildew has been considered the most devastating disease of a filamentous pathogen to affect European vineyards 3 2 7 When comparing three grape producers in Europe including some fields that were treated with fungicides or other management strategies the economic losses ranged from 2000 euros per hectare to 4250 euros per hectare Symptoms cover a fairly large range depending mostly on the host Common symptoms include necrosis of the stem or shoot discoloration including brown spotting lesions and yellowish green tips of the leaves Grapes may exhibit sporangia and sporangiophores appearing as white to gray coat on the outer surface Downy mildew has a specific set of environmental conditions to reproduce and infect A warm moist and humid environment is required Studies in Sicily have shown optimum time for oospore germination is between the end of February and the middle of March 4 With this understanding if fungicides are used just before optimum conditions occur they have proven to be an effective control method of the pathogen Other control methods include proper watering and a good location where the plant can receive continual sunlight Disease cycle editOospores the sexual structures of Plasmopara viticola are produced in late summer The pathogen can survive winter as oospores in host tissue like dead leaves on the vineyard floor There they can survive up to 3 5 years possibly up to 10 years 8 Oospores may also be released from decaying plant material on soil surfaces The rule of thumb 10 10 24 refers to the required environmental condition for primary infection At least 10mm rainfall or irrigation is needed while the temperature should be 10 C or more over 24 hours 8 Under favorable conditions oospores would germinate In spring the oospores would produce sporangia which then produce zoospores the swimming spores Zoospores and sporangia can be dispersed by rain and wind to some lower tissue of the grapevines Sporangia can decline in viability over time After 10 days in a 15 C humid chamber sporangia will die Sporangia that are exposed to direct light for over 15 minutes will not survive 9 10 Once the zoospores are produced and land on the host plant tissue the primary infection would occur Primary infection is from soil to vine Zoospores encyst and then germinate The germ tubes would be formed and then invade into the plant tissue via stomates 11 After infection there would be oil spots on the leaf surface Active oil spots are necessary for secondary infection and sporangia are responsible for this process Secondary infection is from leaf to leaf shoot inflorescence berries and stalk 8 The sporangia seen as the white fungal like organism on the downside of the leaves are produced after a warm and high humid night 11 The sporangia can then be dispersed by wind or rain to occur secondary infections Sporangia is the asexual reproduction structure which then produce sporangiophores 8 The secondary infection is repeatable as long as under suitable conditions 5 Hosts and symptoms edit nbsp Sporangia and sporangiophores protruding from the stomates of the grape berriesThe hosts of Plasmopara viticola includes the species Vitis vinifera and all cultivars within the species It also can affect any interspecific hybrids within the Vitis genus There is also some susceptibility in the Vitis labrusca species ranging from highly susceptible to resistant The European cultivar is most susceptible to the pathogen as it lacks evolutionary resistance that the American varieties have because the pathogen originated in the Americas and was later transmitted into Europe 12 North American species are also susceptible but varies from high susceptibility to resistance In the regions with high annual rainfall the grapevines may suffer more from this disease 5 Leaves edit The first symptom of downy mildew of grapes usually can be seen on leaves after 5 to 7 days of primary infection Early in the season spring Yellow circular spots with oily appearances is going to present on foliage along with the veinlets Note that in some red grape varieties the spots may in red color The young oil spots are surrounded by brown yellow halos As the oil spots get mature the halo would fade As the oil spots age and develop infected tissue would become necrotic and nonreproductive due to cell death 5 If under appropriate weather conditions a larger number of oil spots can develop expand and cover most of the leaf surfaces After a warmer and humid night a white downy fungal growth sporangia would be abundant on the downsides of the leaves and other infected plant areas The severely infected portion could die Severely infected leaves may drop from the plant 11 The pathogen may also attack the old leaves in late summer 11 The infected old leaves may present a mosaic pattern with yellow to red brown spots on the upside of the leaves surface Other parts edit The shoots of the plant can also be infected and shown as the same oily patches After a warm humid night these oily patches may also sporulate and be covered with white fungal growth 8 The shoots are may also be distorted or curled after infection The grape fruits may also have the symptoms in the later season The infected berries would turn brown wither and then die finally The infected green fruit may turn light brown and purple White fungal growth sporulation can abundant on the grapes during humid weather Infected grapes are easy to detach from the pedicles 11 However the fruits become resistant to infection around 2 3 week after blooming excluding the rachis The rachis becomes resistant only around 2 months after blooming If the young bunch stalk is infected oily brown sites can be seen The infected inflorescence or bunches would wither rapidly Infected inflorescence would eventually turn to brown which means the death of the bunches 8 Pathogenesis edit nbsp Lemon shaped sporangia of Plasmopara viticola nbsp Sporangium and spores of Plasmopara viticolaThe disease development of grape downy mildew is known to be heavily reliant on the efficiency of the asexual propagation cycles Kiefer et al 2002 demonstrated that the early development of Plasmopara viticola is regulated specifically and coordinately by unknown factors originating from the host grapevine plant Vitis vinifera 13 The host factors influence the pathogen development in three ways i accelerating the release of zoospores from mature sporangia ii coordinating the morphogenesis of the germ tube through the reorientation of the polarity of the zoospores during the attachment to the host cell and iii targeting the zoospores to the stomata by active chemotaxis from the open substomatal cavity 13 The expression of pathogenesis related PR genes by the host plant V vinifera during the infection of P viticola has been investigated over the years The expressions of PR 2 PR 3 and PR 4 genes are induced in the grapevine host during pathogen infection which encode for cell wall degrading enzymes B 1 3 glucanase PR 2 and chitinases PR 3 and PR 4 14 It was previously understood that oomycetes differ from true fungi by the presence of cellulose in the oomycetes cell walls as opposed to chitin in true fungi However it was found that chitin synthesis is regulated during in planta growth and asexual propagation of P viticola and this is further demonstrated by the presence of chitin on the cell walls of the hyphae sporangiophores and sporangia of the grape downy mildew pathogen 15 Hence both the cell wall degrading enzymes are synthesized by the host grapevine plant specifically to target and degrade the cell walls of the oomycete pathogen 14 In addition the upregulation of the PR 9 gene that encodes for peroxidase which is a reactive oxygen species is associated with the systemic acquired defense of the grapevine host 14 The roles of other constitutively expressed PR genes during P viticola infection such as PR 5 PR 1 and PR 10 genes remain ambiguous PR 5 is involved in the synthesis of thaumatin like proteins and osmotins which are believed to inhibit the spore germination and germ tube growth of Plasmopara viticola by creating transmembrane pores 14 Management editThe history of downy mildew control began with an accidental discovery in 1882 16 In order to prevent passersby from eating from grapevines close to the road Pierre Marie Alexis Millardet sprayed those vines with a mixture of copper sulfate and lime which was both seeable and awful tasting 16 He then noticed that the treated grapevines did not show any symptoms of downy mildew whereas the rest of the vineyard was infected by the disease 16 After further studies Millardet published the recommended treatment of the grapevines against the downy mildew in 1885 in which he proposed the use of 8 15 100 of copper sulfate hydrated lime water mixture in the treatment later named as Bordeaux mixture after the Bordeaux region where Millardet conducted the research 16 The treatment of Bordeaux mixture against the downy mildew was well received globally due to its strong adhesion to the leaves its long perseverance in the vineyard and its color which allows for observable distribution of the treatment 16 Copper based control methods are still commonly used today As science became more precise the amounts of copper sulfate used in solution were optimized for best control of the Higher concentrations of copper sulfate 3 4 are recommended for high risk conditions while low concentrations 1 1 5 are for low risk conditions The risk of susceptibility for the plant is highly correlated with the season 12 Most of the ineffectiveness in fungicide use is correlated with spraying at inappropriate times It is necessary to spray right before budding in the spring Furthermore coating the entire leaf with a film of the fungicide is necessary for control thinning the foliage makes achieving an entire coat possible 12 However overusing chemical controls with copper can create harmful non target effects Copper can negatively impact the biological diversity in the soil and groundwater 17 Unlike in Vitis vinifera there is a wide range of susceptibility to downy mildew among Vitis interspecific hybrids For example among North American grapevine species Vitis aestivalis and Vitis labrusca are moderately susceptible while Vitis cordifolia Vitis rupestris and Vitis rotundifolia are relatively resistant 6 Certain Vitis interspecific hybrid cultivars display organ specific resistance For example leaves of Aurore and Delaware cultivars are moderate to highly susceptible whereas their fruit are highly resistant to downy mildew 6 Another example is the cultivar Chancellor in which the leaves exhibit moderate levels of resistance to downy mildew while the clusters tendrils and shoot tips are highly susceptible to the disease 6 Several new European cultivars such as Regent have been developed from progeny of crosses between V vinifera and resistant North American species in an effort to incorporate the most desirable qualities of both parental branches Note that berries become resistant to infection after 2 to 3 weeks after bloom other parts of the plants may remain susceptible 2 months after bloom 18 Cultural management edit Reduce the risk of disease when establishing the vineyards This practice includes choosing the location drainage soil and irrigation system 18 Avoid the distribution of infected soil and plant tissue from equipment 8 Carefully clean the equipment or change equipment after used in the infected areas Also carefully clean the boots or clothes after entering the infected areas Canopy management practices such as low planting density vine trimming and hedging and later shoot thinning can improve the air movement and make the leaves drier 8 Genetic resistances edit Investigating in wild grape varieties to increase the genetic resistance Develop the breeding of disease resistant cultivars 19 Resistant cultivars can be useful and efficient to avoid infection Monitoring edit Automatic weather stations can be established for monitoring and predicting weather events Collecting data from temperature rainfall leaf wetness and humidity 8 Chemical control edit Pre infection fungicides prevent the zoospores to enter the leaf stomates Also post infection fungicides can be used as soon as possible after infection to kill the pathogen tissues inside the leaves 8 Chemical pesticides are useful methods to control this pathogen and downy mildew 19 Biological control edit Biological agents like Epicoccum nigrum link can inhibit the spread of spores of Plasmopara viticola 20 Microorganisms can be used to biocontrol plant disease However microbial control agents do not work well 19 A recent study 2020 has shown that the bacteria Ochrobactrum sp may be a promising future biological control However there are no reports of the grape industry that have used the bacteria Ochrobactrum sp as a control of grape downy mildew 21 Taxonomy editIn 1848 Berkeley and Curtis made reference to a downy mildew on grapevines and in a footnote named it Botryis viticola 22 However Botryis viticola was a nomen nudum 23 It was later transferred to Peronospora and then to Plasmopara In 1907 Wilson erected Rhysotheca with P viticola as the type 24 however the name Rhysotheca viticola never caught on 22 In 1946 a strain on Vitis amurensis was raised to the species level as P amurensis In 1955 Golovina named the varieties americana aneurensis and parthica In 1951 Alice Săvulescu and Traian Săvulescu named the formae speciales viniferae ampelopsidis aestivalis labruscae and silvestris based on host and morphology 25 Later authors synonymized all these names back into P viticola 22 A population level analysis of P viticola from the United States of America revealed the presence of four lineages that correspond to the host that could be distinguished based on molecular phylogenetics morphology and cross inoculation experiments P viticola f sp quinquefolia P viticola f sp vinifera P viticola f sp aestivalis and P viticola f sp riparia 26 Further study recognized an additional lineage P viticola clade vulpina 27 The lineage Plasmopara f sp quinquefolia has been named Plasmopara muralis 27 References edit a b Hesler Lexemuel Ray Whetzel Herbert Hice 1917 Manual of Fruit Diseases The Rural Manuals ed by L H Bailey New York The Macmillan Company p 237 doi 10 5962 bhl title 56823 OCLC 938509 a b Salazar Hernandez Domingo M 1994 Enfermedades criptogamicas el Mildiu I Semana vitivinicola in Spanish 2487 1051 1053 ISSN 0037 184X a b Perez Salas Joaquin 1988 Defensa contra el mildiu caracteristicas de la enfermedad Semana vitivinicola in Spanish 2191 3385 3387 ISSN 0037 184X a b Burruano Santella Ciofalo G 1990 Studio della dinamica di germinazione delle oospore di Plasmopara viticola Berk et Curt Berl et De Toni Notiziario delle Mallattie delle Piante in Italian Ser 3 38 274 286 a b c d Kennelly Megan M Gadoury David M Wilcox Wayne F Magarey Peter A Seem Robert C April 2007 Primary infection lesion productivity and survival of sporangia in the grapevine downy mildew pathogen Plasmopara viticola Phytopathology 97 4 512 522 doi 10 1094 PHYTO 97 4 0512 PMID 18943292 a b c d Compendium of Grape Diseases Disorders and Pests Second Edition The American Phytopathological Society 2015 pp 46 51 ISBN 978 0 89054 479 2 Perez Marin Jose Luis 1988 Mildiu de la vid como combatirlo PDF Agricultura Revista agropecuaria y ganadera in Spanish 676 798 800 ISSN 0002 1334 a b c d e f g h i j Taylor Andrew May 2021 Downy mildew of grapevines Government of Western Australia Retrieved 1 May 2022 Kennelly M Gadoury D Wilcox W Magarey P amp Seem R 2007 Primary Infection Lesion Productivity and Survival of Sporangia in the Grapevine Downy Mildew Pathogen Plasmopara viticola Phytopathology 97 4 512 522 Kast W amp Stark Urnau M 1999 Survival of sporangia from Plasmopara viticola the downy mildew of grapevine Vitis 38 4 185 186 a b c d e Hartman John R Beale Julie W Kaiser Cheryl A 2008 Plant Pathology Fact Sheet Downy Mildew of Grape PDF Cooperative Extension University of Kentucky Retrieved 1 May 2022 a b c Gessler Cesare Pertot Ilaria Perazzolli Michele 2011 Plasmopara viticola a review of knowledge on downy mildew of grapevine and effective disease management Phytopathologia Mediterranea 50 1 3 44 a b Kiefer Beate Riemann Michael Buche Claudia Kassemeyer Hanns Heinz Nick Peter 2002 07 01 The host guides morphogenesis and stomatal targeting in the grapevine pathogen Plasmopara viticola Planta 215 3 387 393 doi 10 1007 s00425 002 0760 2 ISSN 0032 0935 PMID 12111219 S2CID 13007776 a b c d Kortekamp A 2006 01 01 Expression analysis of defence related genes in grapevine leaves after inoculation with a host and a non host pathogen Plant Physiology and Biochemistry 44 1 58 67 doi 10 1016 j plaphy 2006 01 008 PMID 16531058 Werner Stefan Steiner Ulrike Becher Rayko Kortekamp Andreas Zyprian Eva Deising Holger B 2002 03 01 Chitin synthesis during in planta growth and asexual propagation of the cellulosic oomycete and obligate biotrophic grapevine pathogen Plasmopara viticola FEMS Microbiology Letters 208 2 169 173 doi 10 1111 j 1574 6968 2002 tb11077 x ISSN 0378 1097 PMID 11959432 a b c d e Perazzolli Michele Pertot Ilaria Gessler Cesare 2011 05 10 Plasmopara viticola a review of knowledge on downy mildew of grapevine and effective disease management Phytopathologia Mediterranea 50 1 3 44 doi 10 14601 Phytopathol Mediterr 9360 inactive 31 January 2024 Retrieved 2015 12 30 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint DOI inactive as of January 2024 link Troster V 2016 May 2 Achilles heel of grapevine downy mildew Retrieved May 2023 from https publikationen bibliothek kit edu 1000052562 a b Ash Gavin 2000 Downy mildew of grape The Plant Health Instructor The American Phytopathological Society APS doi 10 1094 PHI I 2000 1112 01 a b c Gessler Cesare Pertot Ilaria Perazzolli Michele April 2011 Plasmopara viticola a review of knowledge on downy mildew of grapevine and effective disease management Phytopathologia Mediterranea 50 1 3 44 JSTOR 26458675 Kortekamp Andreas 1997 Epicoccum nigrum Link A biological control agent of Plasmopara viticola Berk et Curt Berl et De Toni Vitis 36 4 215 216 Zang C Lin Q Xie J Lin Y Zhao K amp Liang C 2020 The biological control of the grapevine downy mildew disease using ochrobactrum sp Plant Protection Science 56 1 52 61 a b c Hall Geoffrey 1989 Plasmopara viticola Mycopathologia 106 209 211 Stevenson J A 1971 An account of fungus exsiccati containing material from the Americas Nova Hedwigia 1 564 Wilson G W 1907 Studies in North American Peronosporales II Phytophthoreae and Rhysotheceae Bulletin of the Torrey Botanical Club 34 8 387 416 doi 10 2307 2479202 JSTOR 2479202 Săvulescu amp Săvulescu 1951 Studiul morfologic biologic si sistematic al genurilor Sclerospora Basidiophora Plasmopara si Peronoplasmopara Rouxel Melanie Mestre Pere Comont Gwenaelle Lehman Brian L Schilder Annemiek Delmotte Francois 2013 Phylogenetic and experimental evidence for host specialized cryptic species in a biotrophic oomycete New Phytologist 197 1 251 263 doi 10 1111 nph 12016 PMID 23153246 a b Rouxel Melanie Mestre Pere Baudoin Anton Carisse Odile Deliere Laurent Ellis Michael A Gadoury David Lu Jiang Nita Mizuho Richard Cervera Sylvie Schilder Annemiek Delmotte Francois 2014 Geographic distribution of crptic species of Plasmopara viticola causing downy mildew on wild and cultivated grape in eastern North America Phytopathology 104 7 692 701 doi 10 1094 phyto 08 13 0225 r PMID 24915427 Further reading editCorio Costet Marie France 2012 Fungicide Resistance in Plasmopara viticola in France and Anti Resistance Measures PDF 12th ed CABI pp 157 177 ISBN 9781845939052 Gobbin Davide Rumbou Artemis Linde Celeste C Gessler Cesare November 2006 Population genetic structure of Plasmopara viticola after 125 years of colonization in European vineyards Molecular Plant Pathology 7 6 519 531 doi 10 1111 j 1364 3703 2006 00357 x PMID 20507466 Puopolo G Cimmino A Palmieri M C October 2014 Lysobacter capsici AZ78 produces cyclo L Pro L Tyr a 2 5 diketopiperazine with toxic activity against sporangia of Phytophthora infestans and Plasmopara viticola Journal of Applied Microbiology 117 4 1168 1180 doi 10 1111 jam 12611 hdl 11572 227185 PMID 25066530 S2CID 7788785 External links editPlasmopara viticola Contributions of oospore inoculum to epidemics of grapevine downy mildew Plasmopara viticola Retrieved from https en wikipedia org w index php title Plasmopara viticola amp oldid 1201990381, wikipedia, wiki, book, books, library,

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