Flavescence dorée explained

Flavescence dorée
Common Names:flavescence dorée of grapevine
Causal Agents:Candidatus Phytoplasma vitis
Hosts:Vine
Vectors:Scaphoideus titanus
Eppo Codes:PHYP64
Distribution:Europe (France, Switzerland, Germany, Italy), United States, Australia
Treatment:uprooting of infected plants

Flavescence dorée (from French "Flavescence" : yellowing and "dorée" : golden) is one of the most important and damaging phytoplasma diseases of the vine with the potential to threaten vineyards.[1] The bacterial agent has recently been named Candidatus Phytoplasma vitis, and its vector is the leafhopper, Scaphoideus titanus. Infection may kill young vines and greatly reduce the productivity of old vines. It is classified as a phytoplasma disease belonging to the group generically termed grapevine yellows.[2] Occurrences are in sporadic epidemics, and varieties vary in their sensitivity to it.

There is no cure at the moment and the way to manage its spread is by uprooting infected plants and by using selective insecticides in an area-wide pest management approach in order to reduce the hemipteran vectors.

Symptoms

The incubation period between infection and obvious symptoms is usually one year or more, depending on the response of the plant to both pathogen and environmental circumstances.[1] Flavescence dorée has the following symptoms:[1]

Some plants affected with Flavescence dorée may die, some may be asymptomatic while some, depending on the grapevine variety, can recover in a process currently not completely understood.[1] The S titanus can not get the Flavescence dorée from recovered and asymptomatic plants.[1]

Tests

The Phytoplasma bacterium species responsible for the disease cannot be cultured in vitro in cell-free media. Quantitative PCR can be used for the early detection of the bacterium in the plant.

Biology

Ca. Phytoplasma vitis is part of the 16SrV group (group name: Elm yellows) in the Phytoplasma taxonomy.

History

Flavescence dorée first appeared in 1949 in the Armagnac region of south west France.[2] Its insect vector, S. titanus, was originally native to the Eastern United States and Canada and is believed to have been introduced to Europe either during World War II or earlier with American rootstock brought in to fight off phylloxera. Spreading steadily throughout France, it had by 1987 reached the wine growing regions of Cognac, Languedoc and northern and southern Rhône, and by 1992 the Loire Valley, and Bordeaux.[3] Variants of the disease are found in Switzerland, Germany, Italy, New York state, and Australia.

The period of milder winters and warmer springs and falls at the beginning of the 21st century allowed S. titanus to have longer periods to complete, which is a probable reason for the increase of its population and expansion in western, eastern and southern Europe.[1] Although Scaphoideus titanus descends from North America, flavescence dorée is not reported in USA and Canada.[4]

Management

Without control measures to manage Flavescence dorée it can infect all vines in a vineyard within only a couple of years.[1]

There is no cure at the moment and the way to manage its spread is by:[5] [6]

Complete suppression of Flavescence dorée is not possible only with insecticides because they reduce populations of S. titanus in average by about 80-95%.[1] That is why uprooting of infected plants should be combined with insecticide application.[1]

During the period of activity of adult vector it is strongly recommended to avoid any kind of mechanical or chemical control of host plants because its unavailability could drive infected vector to disperse to other noninfected plants.[7]

It has been proposed by Antoine Caudwell, a French agriculturist who was a pioneer in research on grapevine phytoplasma diseases such as flavescence dorée, to treat plant material with hot water since 1966.[8] When later works proved the effectiveness of the hot water treatment it was recognized in EU Directive and some other organizations.

See also

External links

Notes and References

  1. Maggi F, Bosco D, Galetto L, Palmano S, Marzachì C. Space-Time Point Pattern Analysis of Flavescence Dorée Epidemic in a Grapevine Field: Disease Progression and Recovery. Front Plant Sci. 2017 Jan 6;7:1987. doi: 10.3389/fpls.2016.01987. PMID 28111581; PMCID: PMC5216681.
  2. winepros.com.au. Web site: Oxford Companion to Wine. flavescence dorée. 2008-04-24. https://web.archive.org/web/20080809031411/http://www.winepros.com.au/jsp/cda/reference/oxford_entry.jsp?entry_id=1192. 2008-08-09. dead.
  3. winepros.com.au. Web site: Oxford Companion to Wine. grapevine yellows. 2008-04-24. https://web.archive.org/web/20080808112123/http://www.winepros.com.au/jsp/cda/reference/oxford_entry.jsp?entry_id=1419. 2008-08-08. dead.
  4. Book: Noubar J. Bostanian . Charles Vincent . Rufus Isaacs . 26 June 2012 . Arthropod Management in Vineyards:: Pests, Approaches, and Future Directions . Springer Science & Business Media . 258– . 9789400740327 .
  5. Hot water treatment of grapevine to control Grapevine flavescence dorée phytoplasma . EPPO Bulletin . December 2012 . 42 . 3 . 490–492 . 0250-8052 . 10.1111/epp.2594 .
  6. Gribaudo . Ivana . Ruffa . Paola . 2007 . Attempts to eliminate phytoplasmas from grapevine clones by tissue culture techniques . Bulletin of Insectology . 60 . 315–316 . 2 August 2022.
  7. Book: Assunta Bertaccini . Phyllis G Weintraub . Govind Pratap Rao . Nicola Mori . 7 March 2019 . Phytoplasmas: Plant Pathogenic Bacteria - II: Transmission and Management of Phytoplasma - Associated Diseases . Springer . 245– . 978-981-13-2832-9 .
  8. Caudwell A (1966) L'inhibitionin vivodu virus de la "flavescence dorée" par la chaleur. Etudes de virologie. Annales des Epiphyties 17:61-66.