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Drosophila suzukii

January 01, 1970

Drosophila suzukii, commonly called the spotted wing drosophila or SWD, is a fruit fly. D. suzukii, originally from southeast Asia, is becoming a major pest species in America and Europe, because it infests fruit early during the ripening stage, in contrast with other Drosophila species that infest only rotting fruit.[2]

Drosophila suzukii
Male and female
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
Order: Diptera
Family: Drosophilidae
Genus: Drosophila
Subgenus: Sophophora
Species group: melanogaster
Species subgroup: suzukii
Species:
D. suzukii
Binomial name
Drosophila suzukii
(Matsumura, 1931)[1]

Native to east Asia, D. suzukii was first described in 1931 by Shōnen Matsumura, it was observed in Japan as early as 1916 by T. Kanzawa.[3]

D. suzukii is a fruit crop pest and is a serious economic threat to soft summer fruit; i.e., cherries, blueberries, raspberries, blackberries, peaches, nectarines, apricots, grapes, and others.[4] Research investigating the specific threat D. suzukii poses to these fruit is ongoing.[5]

Description edit

Like other members of the Drosophilidae, D. suzukii is small, approximately 2 to 3.5 millimetres (564 to 964 in) in length and 5 to 6.5 millimetres (1364 to 14 in) in wingspan [3] and looks like its fruit and vinegar fly relatives. Its body is yellow to brown with darker bands on the abdomen and it has red eyes. The male has a distinct dark spot near the tip of each wing; females do not have the spotted wing. The foreleg of the male sports dark bands on the first and second tarsi. The female has a long, sharp, serrated ovipositor.[6] The larvae are small, white, and cylindrical reaching 3.5 millimetres (964 in) in length.[4]

When first observed in a new region, D. suzukii has often been confused with the western cherry fruit fly (Rhagoletis indifferens) and was given the short-lasting name cherry vinegar fly.[7] The cherry fruit fly is significantly larger than D. suzukii (up to 5 millimetres (1364 in)) and has a pattern of dark bands on its wings instead of the telltale spot of D. suzukii. The telltale spots on the wings of male D. suzukii have earned it the common name "spotted wing drosophila" (SWD).

Unlike its vinegar fly relatives which are primarily attracted to rotting or fermented fruit, female D. suzukii attack fresh, ripe fruit by using their saw-like ovipositor to lay eggs under the fruit's soft skin. The larvae hatch and grow in the fruit, destroying the fruit's commercial value. Economic impacts are significant; losses from large scale infestation (20% loss) across the US alone could equate to farm gate impacts > $500M.[8][9]

D. suzukii has a slow rate of evolution due to its lower number of generations per year, because it enters winter diapause.[10]

Distribution edit

Native to southeast Asia, D. suzukii was first described in 1931 by Matsumura. Observed in Japan as early as 1916 by T. Kanzawa,[3] it was widely observed throughout parts of Japan, Korea, and China by the early 1930s.[3] By the 1980s, the "fruit fly" with the spotted wings was seen in Hawaii. It first appeared in North America in central California in August 2008,[4] then was found in Oregon and Washington State by Lee et al., 2011[11]: 369  in the Pacific Northwest in 2009,[12] and is now widespread throughout California's coastal counties,[9] western Oregon, western Washington,[4] and parts of British Columbia[13] and Florida.[14] During the summer of 2010 the fly was discovered for the first time in South Carolina, North Carolina,[15] Louisiana,[16] and Utah.[17] In Fall 2010 the fly was also discovered in Michigan[18] and Wisconsin.[19] The fly was first discovered in the northeastern states in 2011[20] and in Minnesota[21] and Idaho[11]: 369  in 2012. As D. suzukii continues to spread, most of the states will most likely observe it. The pest has also been found in Europe, including the countries of Belgium, Italy, France, and Spain.[22][23]

Lifecycle edit

The lifespan of D. suzukii varies greatly between generations; from a few weeks to ten months.[3] Generations hatched early in the year have shorter lifespans than generations hatched after September.[3] Research shows that many of the males and most of the females of the late-hatching generations overwinter in captivity—some living as long as 300 days. Only adults overwinter successfully in the research conducted thus far. In Washington state, D. suzukii has been observed in association with two exotic and well-established species of blackberry, Rubus armeniacus (= Rubus discolor) and Rubus laciniatus (the Himalayan and Evergreen Blackberries, respectively.).[4] The fly has been observed reproducing on many other species of soft-skinned wild fruit, however, research is still ongoing to determine the quality of individual species as reproductive hosts.

Adults emerge from overwintering when temperatures reach approximately 10 °C (50 °F) (and 268 degree days).[4] The fertilized female searches for ripe fruit, lands on the fruit, inserts its serrated ovipositor to pierce the skin and deposits a clutch of 1 to 3 eggs per insertion. Females will oviposit on many fruits and in regions of scarce fruit, many females will oviposit on the same fruit. In captivity in Japan, research shows up to 13 generations of D. suzukii may hatch per season. A female may lay as many as 300 eggs during its lifespan. With as many as 13 generations per season, and the ability for the female to lay up to 300 eggs each, the potential population size of D. suzukii is huge. It is also important to note that males of D. suzukii become sterile at 30 °C (86 °F) and population size may be limited in regions that reach that temperature.

The larvae grow inside the fruit. The oviposition site is visible in many fruit by a small pore scar in the skin of the fruit often called a "sting". After 1 or 2 days, the area around the "sting" softens and depresses creating an increasingly visible blemish.[4] The depressions may also exude fluid which may attract infection by secondary bacterial and fungal pathogens.[9] Larvae may leave the fruit, or remain inside it, to pupate.

Economic impact edit

The economic impact of D. suzukii on fruit crops is negative and significantly affects a wide variety of summer fruit in the United States including cherries,[9][11]: 369  blueberries,[9][11]: 369  grapes,[9] nectarines,[9] pears,[9] plums,[9] pluots,[9] peaches,[9] raspberries,[11]: 369  and strawberries,[9] and blackberries.[11]: 369  Damage was first noticed in North America in the western states of California, Oregon, and Washington in 2008; yield loss estimates from that year vary widely, with negligible loss in some areas to 80% loss in others depending on location and crop.[9] The $500 million actual loss due to pest damage in 2008—the first year D. suzukii was observed in California—is an indication of the potential damage the pest can cause upon introduction to a new location. Economic losses have now been reported across North America and in Europe as the fly has spread to new areas. In 2015 it is estimated that national economic loss for producers in the United States was $700 million.[24] Future losses may decrease as growers learn how to better control the pest, or may keep increasing as the fly continues to spread.

Agricultural management edit

 
Red plastic cup used as a homemade trap for monitoring

Due to the impact of D. suzukii on soft fruits, farmers have started to monitor and control it. There are different types of traps, both commercial and home-made, that are effective in monitoring it. Traps that use apple cider vinegar with a bait made of whole wheat dough have been successful for farmers for both capture and monitoring.[25] Farmers are advised to place these traps in a shaded area as soon as the first fruit is set and to not remove them until the end of harvest. The traps should be checked once a week and farmers should look for the spot on the wing of the males to determine if D. suzukii is present.[26]

In areas where D. suzukii has already been established or where its activity has been monitored, there are different ways to control it. One way to manage D. suzukii is to remove the infested fruit and place it in a plastic bag in the garbage. This method is effective from removing D. suzukii from gardens and small areas but is difficult for farmers with larger operations to do this. Farmers can also harvest their soft fruit early which reduces the exposure of fruit to D. suzukii and the likelihood of damage.[27]

Farmers have the option of both conventional and organic sprays[28] to control D. suzukii. Timing of the sprays is important to effectively controlling it. Since D. suzukii is more active in the morning and evening those are the best times to control it.[29] Sprays should be in place prior to egg laying and the coverage needs to be thorough because adults often hide in dense portion of the canopy. Depending on the variety of soft fruit and laws in different states and countries, there are many types of organic and conventional sprays that are effective. Different laws and pre-harvest date intervals need to be kept in mind when choosing a type of spray. Most types of sprays need to be applied each week, at a minimum. To prevent resistance to certain sprays, farmers must rotate among different insecticides.[30]

Parasitoids edit

Genetic engineering edit

There is ongoing research into population control methods using gene editing. Since 2017, biotechnology startup Agragene has been developing an approach that uses CRISPR on fly embryos to knock out two genes—one that sterilizes male flies, the other which prevents the females from hatching. Once hatched, the male flies would be released to mate with wild females, who would then lay sterile eggs. The company estimates releasing four to five sterile males to every one wild male per generation would be necessary to control a population. Because of the species' short lifespan, multiple weekly releases per season could be required for an effective deterrent. In May 2023, USDA and company researchers began greenhouse testing of the technique with the aim of deploying field tests in 2024.[39][40]

Researchers at North Carolina State University have been developing a technique that also uses CRISPR to modify a gene essential to female sexual development that renders them unable to lay eggs. The male flies, however, remain fertile and pass the mutated gene to future generations when they mate with unmodified females. This has the potential benefit of not requiring multiple releases like the Agragene method does. The researchers estimate that a release of one modified fly to every four wild flies would control populations within 10 generations, or about 20 weeks.[39][41][42]

Predators edit

Predators of this species include earwigs,[43] damsel bugs,[43] spiders,[43] ants,[43] and Orius ("minute pirate bugs")[43] especially O. insidiosus.[43][44] Other likely predators are ground beetles (Carabidae),[43] crickets,[43] green lacewings' larvae,[43] rove beetles (Staphylinidae) especially Dalotia coriaria,[43] birds,[43][45] and mammals.[43][45]

Microbiome edit

Drosophila suzukii, like all insects, is host to a variety of microorganisms. The intestinal bacterial communities of adult and larval D. suzukii collected in its invasive range (USA), were found to be simple and mostly dominated by Tatumella spp. (Enterobacteriaceae).[46] This fly is also infected with a variety of viruses in the wild. Whilst sharing some natural viruses with its close relative D. melanogaster, D. suzukii also harbours a number of unique viruses specific to it alone.[47] Yeasts also form an important part of the Drosophila microbiome, with a mutualistic relationships to yeast being described in other Drosophila species.[48][49][50] The yeast species found to be most frequently associated with D. suzukii were Hanseniaspora uvarum, Metschnikowia pulcherrima, Pichia terricola, and P. kluyveri.[51] Although certain fungal pathogens have been shown to experimentally infect D. suzukii,[52][53][54] the wild fungal infections of D. suzukii remain to be explored comprehensively.

Gallery edit

References edit

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External links edit

 
Wikispecies has information related to Drosophila suzukii.
 
Wikimedia Commons has media related to Drosophila suzukii.
  • Pest Alert: Spotted Wing Drosophila, Oregon Department of Agriculture
  • Oregon State University horticulture site
  • Washington State University
  • Michigan State University Spotted Wing Drosophila site
  • Spotted wing drosophila on the UF / IFAS Featured Creatures Web site
  • Species Profile - Spotted Wing Drosophila (Drosophila suzukii), National Invasive Species Information Center, United States National Agricultural Library.
  • "EMERGING PEST: Spotted-Wing Drosophila-A Berry and Stone Fruit Pest". Pacific Northwest Pest Management Handbooks. 2016-03-28. Retrieved 2020-12-15.
  • "Spotted Wing Drosophila". Oregon State University College of Agricultural Sciences. Retrieved 2020-12-15.

Further reading edit

  • Bellamy, David E.; Sisterson, Mark S.; Walse, Spencer S. (2013). "Quantifying Host Potentials: Indexing Postharvest Fresh Fruits for Spotted Wing Drosophila, Drosophila suzukii". PLOS ONE. 8 (4): 1–10. Bibcode:2013PLoSO...861227B. doi:10.1371/journal.pone.0061227. PMC 3625224. PMID 23593439.
  • Hamby, Kelly A.; Kwok, Rosanna S.; Zalom, Frank G.; Chiu, Joanna C. (2013). "Integrating Circadian Activity and Gene Expression Profiles to Predict Chronotoxicity of Drosophila suzukii Response to Insecticides". PLOS ONE. 8 (7): 1–14. Bibcode:2013PLoSO...868472H. doi:10.1371/journal.pone.0068472. PMC 3702611. PMID 23861907.
  • Mazzoni, Valerio; Anfora, Gianfranco; Virant-Doberlet, Meta (2013). "Substrate Vibrations During Courtship in Three Drosophila species". PLOS ONE. 8 (11): 1–8. Bibcode:2013PLoSO...880708M. doi:10.1371/journal.pone.0080708. PMC 3829934. PMID 24260459.
  • Kacsoh, Balint Z.; Schlenke, Todd A. (2012). "High Hemocyte Load is Associated with Increased Resistance Against Parasitoids in Drosophila suzukii, a Relative of D. melanogaster". PLOS ONE. 7 (4): 1–16. Bibcode:2012PLoSO...734721K. doi:10.1371/journal.pone.0034721. PMC 3328493. PMID 22529929.

January 01, 1970
drosophila, suzukii, commonly, called, spotted, wing, drosophila, fruit, suzukii, originally, from, southeast, asia, becoming, major, pest, species, america, europe, because, infests, fruit, early, during, ripening, stage, contrast, with, other, drosophila, sp. Drosophila suzukii commonly called the spotted wing drosophila or SWD is a fruit fly D suzukii originally from southeast Asia is becoming a major pest species in America and Europe because it infests fruit early during the ripening stage in contrast with other Drosophila species that infest only rotting fruit 2 Drosophila suzukii Male and female Scientific classification Domain Eukaryota Kingdom Animalia Phylum Arthropoda Class Insecta Order Diptera Family Drosophilidae Genus Drosophila Subgenus Sophophora Species group melanogaster Species subgroup suzukii Species D suzukii Binomial name Drosophila suzukii Matsumura 1931 1 Native to east Asia D suzukii was first described in 1931 by Shōnen Matsumura it was observed in Japan as early as 1916 by T Kanzawa 3 D suzukii is a fruit crop pest and is a serious economic threat to soft summer fruit i e cherries blueberries raspberries blackberries peaches nectarines apricots grapes and others 4 Research investigating the specific threat D suzukii poses to these fruit is ongoing 5 Contents 1 Description 2 Distribution 3 Lifecycle 4 Economic impact 5 Agricultural management 5 1 Parasitoids 5 2 Genetic engineering 6 Predators 7 Microbiome 8 Gallery 9 References 10 External links 11 Further readingDescription editLike other members of the Drosophilidae D suzukii is small approximately 2 to 3 5 millimetres 5 64 to 9 64 in in length and 5 to 6 5 millimetres 13 64 to 1 4 in in wingspan 3 and looks like its fruit and vinegar fly relatives Its body is yellow to brown with darker bands on the abdomen and it has red eyes The male has a distinct dark spot near the tip of each wing females do not have the spotted wing The foreleg of the male sports dark bands on the first and second tarsi The female has a long sharp serrated ovipositor 6 The larvae are small white and cylindrical reaching 3 5 millimetres 9 64 in in length 4 When first observed in a new region D suzukii has often been confused with the western cherry fruit fly Rhagoletis indifferens and was given the short lasting name cherry vinegar fly 7 The cherry fruit fly is significantly larger than D suzukii up to 5 millimetres 13 64 in and has a pattern of dark bands on its wings instead of the telltale spot of D suzukii The telltale spots on the wings of male D suzukii have earned it the common name spotted wing drosophila SWD Unlike its vinegar fly relatives which are primarily attracted to rotting or fermented fruit female D suzukii attack fresh ripe fruit by using their saw like ovipositor to lay eggs under the fruit s soft skin The larvae hatch and grow in the fruit destroying the fruit s commercial value Economic impacts are significant losses from large scale infestation 20 loss across the US alone could equate to farm gate impacts gt 500M 8 9 D suzukii has a slow rate of evolution due to its lower number of generations per year because it enters winter diapause 10 Distribution editNative to southeast Asia D suzukii was first described in 1931 by Matsumura Observed in Japan as early as 1916 by T Kanzawa 3 it was widely observed throughout parts of Japan Korea and China by the early 1930s 3 By the 1980s the fruit fly with the spotted wings was seen in Hawaii It first appeared in North America in central California in August 2008 4 then was found in Oregon and Washington State by Lee et al 2011 11 369 in the Pacific Northwest in 2009 12 and is now widespread throughout California s coastal counties 9 western Oregon western Washington 4 and parts of British Columbia 13 and Florida 14 During the summer of 2010 the fly was discovered for the first time in South Carolina North Carolina 15 Louisiana 16 and Utah 17 In Fall 2010 the fly was also discovered in Michigan 18 and Wisconsin 19 The fly was first discovered in the northeastern states in 2011 20 and in Minnesota 21 and Idaho 11 369 in 2012 As D suzukii continues to spread most of the states will most likely observe it The pest has also been found in Europe including the countries of Belgium Italy France and Spain 22 23 Lifecycle editThe lifespan of D suzukii varies greatly between generations from a few weeks to ten months 3 Generations hatched early in the year have shorter lifespans than generations hatched after September 3 Research shows that many of the males and most of the females of the late hatching generations overwinter in captivity some living as long as 300 days Only adults overwinter successfully in the research conducted thus far In Washington state D suzukii has been observed in association with two exotic and well established species of blackberry Rubus armeniacus Rubus discolor and Rubus laciniatus the Himalayan and Evergreen Blackberries respectively 4 The fly has been observed reproducing on many other species of soft skinned wild fruit however research is still ongoing to determine the quality of individual species as reproductive hosts Adults emerge from overwintering when temperatures reach approximately 10 C 50 F and 268 degree days 4 The fertilized female searches for ripe fruit lands on the fruit inserts its serrated ovipositor to pierce the skin and deposits a clutch of 1 to 3 eggs per insertion Females will oviposit on many fruits and in regions of scarce fruit many females will oviposit on the same fruit In captivity in Japan research shows up to 13 generations of D suzukii may hatch per season A female may lay as many as 300 eggs during its lifespan With as many as 13 generations per season and the ability for the female to lay up to 300 eggs each the potential population size of D suzukii is huge It is also important to note that males of D suzukii become sterile at 30 C 86 F and population size may be limited in regions that reach that temperature The larvae grow inside the fruit The oviposition site is visible in many fruit by a small pore scar in the skin of the fruit often called a sting After 1 or 2 days the area around the sting softens and depresses creating an increasingly visible blemish 4 The depressions may also exude fluid which may attract infection by secondary bacterial and fungal pathogens 9 Larvae may leave the fruit or remain inside it to pupate Economic impact editThe economic impact of D suzukii on fruit crops is negative and significantly affects a wide variety of summer fruit in the United States including cherries 9 11 369 blueberries 9 11 369 grapes 9 nectarines 9 pears 9 plums 9 pluots 9 peaches 9 raspberries 11 369 and strawberries 9 and blackberries 11 369 Damage was first noticed in North America in the western states of California Oregon and Washington in 2008 yield loss estimates from that year vary widely with negligible loss in some areas to 80 loss in others depending on location and crop 9 The 500 million actual loss due to pest damage in 2008 the first year D suzukii was observed in California is an indication of the potential damage the pest can cause upon introduction to a new location Economic losses have now been reported across North America and in Europe as the fly has spread to new areas In 2015 it is estimated that national economic loss for producers in the United States was 700 million 24 Future losses may decrease as growers learn how to better control the pest or may keep increasing as the fly continues to spread Agricultural management edit nbsp Red plastic cup used as a homemade trap for monitoring Due to the impact of D suzukii on soft fruits farmers have started to monitor and control it There are different types of traps both commercial and home made that are effective in monitoring it Traps that use apple cider vinegar with a bait made of whole wheat dough have been successful for farmers for both capture and monitoring 25 Farmers are advised to place these traps in a shaded area as soon as the first fruit is set and to not remove them until the end of harvest The traps should be checked once a week and farmers should look for the spot on the wing of the males to determine if D suzukii is present 26 In areas where D suzukii has already been established or where its activity has been monitored there are different ways to control it One way to manage D suzukii is to remove the infested fruit and place it in a plastic bag in the garbage This method is effective from removing D suzukii from gardens and small areas but is difficult for farmers with larger operations to do this Farmers can also harvest their soft fruit early which reduces the exposure of fruit to D suzukii and the likelihood of damage 27 Farmers have the option of both conventional and organic sprays 28 to control D suzukii Timing of the sprays is important to effectively controlling it Since D suzukii is more active in the morning and evening those are the best times to control it 29 Sprays should be in place prior to egg laying and the coverage needs to be thorough because adults often hide in dense portion of the canopy Depending on the variety of soft fruit and laws in different states and countries there are many types of organic and conventional sprays that are effective Different laws and pre harvest date intervals need to be kept in mind when choosing a type of spray Most types of sprays need to be applied each week at a minimum To prevent resistance to certain sprays farmers must rotate among different insecticides 30 Parasitoids edit Ganaspis The United States Department of Agriculture s Animal and Plant Health Inspection Service has approved and the biocontrol committee of the North American Plant Protection Organization has recommended the use of Ganaspis brasiliensis as a biocontrol for D suzukii 31 G brasiliensis has been widely studied by others as a potential biocontrol for D suzukii 32 33 However there is some dispute as to whether it is G brasiliensis that attacks D suzukii or whether this is the D suzukii specialized host race of Ganaspis xanthopoda 34 35 Asobara A brevicauda 32 33 A elongata 33 A japonica the most common in South Korea 32 33 A leveri 32 33 A mesocauda 33 A triangulata 33 A unicolorata 33 Leptopilina L decemflagella 33 L j formosana 32 L japonica 34 32 First captured in November 2020 as bycatch from a Vespa mandarinia trap in Washington State 36 37 38 the first find of this species in the United States 36 37 38 This may help to control D suzukii in North America 36 37 38 L j japonica 32 Unspecified Leptopilina likely a sp nov by Buffington 32 Leptolamina spp 33 Unspecified new Figitidae genus related to Leptolamina 33 Pachycrepoideus vindemiae 32 33 Trichopria drosophilae 32 33 Areotetes striatiferus Yunnan Province China 32 Tanycarpa chors Japan two locations in China 32 Genetic engineering edit There is ongoing research into population control methods using gene editing Since 2017 biotechnology startup Agragene has been developing an approach that uses CRISPR on fly embryos to knock out two genes one that sterilizes male flies the other which prevents the females from hatching Once hatched the male flies would be released to mate with wild females who would then lay sterile eggs The company estimates releasing four to five sterile males to every one wild male per generation would be necessary to control a population Because of the species short lifespan multiple weekly releases per season could be required for an effective deterrent In May 2023 USDA and company researchers began greenhouse testing of the technique with the aim of deploying field tests in 2024 39 40 Researchers at North Carolina State University have been developing a technique that also uses CRISPR to modify a gene essential to female sexual development that renders them unable to lay eggs The male flies however remain fertile and pass the mutated gene to future generations when they mate with unmodified females This has the potential benefit of not requiring multiple releases like the Agragene method does The researchers estimate that a release of one modified fly to every four wild flies would control populations within 10 generations or about 20 weeks 39 41 42 Predators editPredators of this species include earwigs 43 damsel bugs 43 spiders 43 ants 43 and Orius minute pirate bugs 43 especially O insidiosus 43 44 Other likely predators are ground beetles Carabidae 43 crickets 43 green lacewings larvae 43 rove beetles Staphylinidae especially Dalotia coriaria 43 birds 43 45 and mammals 43 45 Microbiome editDrosophila suzukii like all insects is host to a variety of microorganisms The intestinal bacterial communities of adult and larval D suzukii collected in its invasive range USA were found to be simple and mostly dominated by Tatumella spp Enterobacteriaceae 46 This fly is also infected with a variety of viruses in the wild Whilst sharing some natural viruses with its close relative D melanogaster D suzukii also harbours a number of unique viruses specific to it alone 47 Yeasts also form an important part of the Drosophila microbiome with a mutualistic relationships to yeast being described in other Drosophila species 48 49 50 The yeast species found to be most frequently associated with D suzukii were Hanseniaspora uvarum Metschnikowia pulcherrima Pichia terricola and P kluyveri 51 Although certain fungal pathogens have been shown to experimentally infect D suzukii 52 53 54 the wild fungal infections of D suzukii remain to be explored comprehensively Gallery edit nbsp Male note the dark spots near his wing tips nbsp Female her wings are without spots nbsp Male nbsp Electron microscope image of the ovipositor of a female nbsp Cherry with oviposition scars nbsp Larva under compound microscopeReferences edit Matsumura S 1931 6000 illustrated insects of Japan Empire in Japanese Tokyo Japan Toko Shoin pp 1689 367 Walsh Douglas B Bolda Mark P Goodhue Rachael E Dreves Amy J Lee Jana Bruck Denny J Walton Vaughn M O Neal Sally D Zalom Frank G 2011 Drosophila suzukii Diptera Drosophilidae invasive pest of ripening soft fruit expanding its geographic range and damage potential Journal of Integrated Pest Management 2 1 G1 G7 doi 10 1603 IPM10010 S2CID 86098875 a b c d e f Kanzawa T 1939 Report Translated from Japanese by Shinji Kawaii a b c d e f g Walsh D Press Release Washington State University 2009 Archived August 6 2010 at the Wayback Machine Herring P Grant funds help regional effort to combat spotted wing drosophila 29 April 2010 http extension oregonstate edu news story php S No 729 amp storyType news McEvey Shane 13 February 2017 High resolution diagnostic images of Drosophila suzukii Diptera Drosophilidae Figshare doi 10 6084 m9 figshare 4644793 v1 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Spotted Wing Drosophila Drosophila suzukii A New Pest in California UC IPM Online 10 Apr 2010 http www ipm ucdavis edu EXOTIC drosophila html Archived 2016 04 30 at the Wayback Machine Fountain Michelle T Badiee Amir Hemer Sebastian Delgado Alvaro Mangan Michael Dowding Colin Davis Frederick Pearson Simon 2020 The use of light spectrum blocking films to reduce populations of Drosophila suzukii Matsumura in fruit crops Scientific Reports 10 1 15358 Bibcode 2020NatSR 1015358F doi 10 1038 s41598 020 72074 8 PMC 7506528 PMID 32958797 a b c d e f g h i j k l m Bolda Mark P Goodhue Rachael E Zalom Frank G January February 2010 Spotted Wing Drosophila Potential Economic Impact of Newly Established Pest Agricultural and Resource Economics Update ARE Update 13 3 Giannini Foundation of Agricultural Economics University of California 5 8 Ometto Lino Cestaro Alessandro Ramasamy Sukanya Grassi Alberto Revadi Santosh Siozios Stefanos Moretto Marco Fontana Paolo Varotto Claudio Pisani Davide Dekker Teun Wrobel Nicola Viola Roberto Pertot Ilaria Cavalieri Duccio Blaxter Mark Anfora Gianfranco Rota Stabelli Omar 2013 03 15 Linking Genomics and Ecology to Investigate the Complex Evolution of an Invasive Drosophila Pest Genome Biology and Evolution 5 4 Oxford University Press OUP 745 757 doi 10 1093 gbe evt034 ISSN 1759 6653 PMC 3641628 PMID 23501831 a b c d e f Poland Therese M Patel Weynand Toral Finch Deborah M Miniat Chelcy Ford Hayes Deborah C Lopez Vanessa M eds 2021 Invasive Species in Forests and Rangelands of the United States Cham Switzerland Springer International Publishing pp xlii 455 ill 20 b w 67 col ISBN 978 3 030 45366 4 ISBN 978 3 030 45369 5 ISBN 978 3 030 45367 1 Stop The Invasion Spotted Wing Drosophila PDF Washington Invasive Species Council 2017 They re known to have been in the Pacific Northwest since 2009 Spotted Wing Drosophila Fruit Fly Pest Alert British Columbia Ministry of Agriculture and Lands December 2009 http www agf gov bc ca cropprot swd htm Archived 2010 03 28 at the Wayback Machine Steck G Dixon W Dean D Pest Alert Spotted Wing Drosophila a fruit pest new to North America 2009 Spotted Wing Drosophila NC Small Fruit Specialty Crop and Tobacco IPM 2010 http ncsmallfruitsipm blogspot com p spotted wing drosophila html Spotted Wing Drosophila PDF Louisiana Department of Agriculture and Forestry August 2010 Archived from the original PDF on 2011 01 12 Retrieved 2011 01 18 Davis R Alston D Vorel C Spotted Wing Drosophila September 2010 http extension usu edu files publications publication ENT 140 10 pdf Early detection program finds a new invasive pest of fruit in Michigan MSU Fruit Crop Advisory Team Alert 29 Oct 2010 Archived from the original on 2011 07 20 Retrieved 2010 10 29 Hamilton K Wisconsin Pest Bulletin 19 November 2010 Spotted Wing Drosophila IPM Working Group NortheastIPM org 2012 11 13 Retrieved 2019 11 19 Spotted Wing Drosophila Minnesota Department of Agriculture www mda state mn us Retrieved 2019 11 19 Belgian Journal of Zoology Drosophila suzukii Diptera Drosophilidae A pest species new to Belgium Link Archived 2022 03 30 at the Wayback Machine Drosophila suzukii Diptera Drosophilidae Spotted wing drosophila European and Mediterranean Plant Protection Organization January 2010 http www eppo org QUARANTINE Alert List insects drosophila suzukii htm Archived 2010 08 01 at the Wayback Machine USDA Awards 6 7 Million To Stifle Spotted Wing Drosophila Growing Produce 2015 10 20 Retrieved 2019 11 19 Monitoring Cornell Fruit Resources fruit cornell edu Retrieved 2019 11 14 Spotted wing drosophila in home gardens extension umn edu Retrieved 2019 11 14 Spotted Wing Drosophila Management Guidelines UC IPM ipm ucanr edu Retrieved 2019 11 14 Dam Doriane Molitor Daniel Beyer Marco 2019 Natural compounds for controlling Drosophila suzukii Agronomy for Sustainable Development 39 6 doi 10 1007 s13593 019 0593 z S2CID 207987437 New guide to organic management of spotted wing Drosophila released Organic Agriculture 19 June 2018 Retrieved 2019 11 14 Spotted Wing Drosophila Management Entomology entomology ca uky edu Retrieved 2019 11 14 SWD killing wasps to make their debut Good Fruit Grower 23 November 2020 Retrieved 2020 12 05 a b c d e f g h i j k l Daane Kent M Wang Xin Geng Biondi Antonio Miller Betsey Miller Jeffrey C Riedl Helmut Shearer Peter W Guerrieri Emilio Giorgini Massimo Buffington Matthew van Achterberg Kees Song Yoohan Kang Taegun Yi Hoonbok Jung Chuleui Lee Dong Woon Chung Bu Keun Hoelmer Kim A Walton Vaughn M 2016 02 10 First exploration of parasitoids of Drosophila suzukii in South Korea as potential classical biological agents Journal of Pest Science 89 3 Springer Science and Business Media LLC 823 835 doi 10 1007 s10340 016 0740 0 ISSN 1612 4758 S2CID 18151515 a b c d e f g h i j k l m Giorgini Massimo Wang Xin Geng Wang Yan Chen Fu Shou Hougardy Evelyne Zhang Hong Mei Chen Zong Qi Chen Hong Yin Liu Chen Xi Cascone Pasquale Formisano Giorgio Carvalho Gislaine A Biondi Antonio Buffington Matthew Daane Kent M Hoelmer Kim A Guerrieri Emilio 2018 12 12 Exploration for native parasitoids of Drosophila suzukii in China reveals a diversity of parasitoid species and narrow host range of the dominant parasitoid Journal of Pest Science 92 2 Springer Science and Business Media LLC 509 522 doi 10 1007 s10340 018 01068 3 ISSN 1612 4758 S2CID 54476223 a b Girod Pierre Borowiec Nicolas Buffington Matthew Chen Guohua Fang Yuan Kimura Masahito T Peris Felipo Francisco Javier Ris Nicolas Wu Hao Xiao Chun Zhang Jinping Aebi Alexandre Haye Tim Kenis Marc 2018 08 07 The parasitoid complex of D suzukii and other fruit feeding Drosophila species in Asia Scientific Reports 8 1 Springer Science and Business Media LLC 11839 Bibcode 2018NatSR 811839G doi 10 1038 s41598 018 29555 8 ISSN 2045 2322 PMC 6081417 PMID 30087364 Nomano Fumiaki Y Kasuya Nazuki Matsuura Akira Suwito Awit Mitsui Hideyuki Buffington Matthew L Kimura Masahito T 2017 05 03 Genetic differentiation of Ganaspis brasiliensis Hymenoptera Figitidae from East and Southeast Asia Applied Entomology and Zoology 52 3 Springer Science and Business Media LLC 429 437 Bibcode 2017AppEZ 52 429N doi 10 1007 s13355 017 0493 0 hdl 2115 71122 ISSN 0003 6862 S2CID 25438219 a b c ASIAN GIANT HORNET STAKEHOLDER UPDATE 17 DECEMBER 9 2020 PDF Washington State Department of Agriculture the traps also captured the first United States specimens of parasitoid wasps that prey on SWD The parasitoid larvae will live off SWD and eventually kill it Without these traps this parasitoid wasp might have gone unnoticed This information may help the development of biological control programs to potentially help manage SWD a b c Murder Hornet traps yield bonus 790 KGMI 2020 12 16 Retrieved 2020 12 16 a b c Catching hope Possible ally in fight against harmful fruit fly discovered in Asian giant hornet trap Washington State Department of Agriculture AgBriefs 14 December 2020 Retrieved 2020 12 18 a b Mullin Emily June 29 2023 Scientists Are Gene Editing Flies to Fight Crop Damage Wired ISSN 1059 1028 Archived from the original on June 29 2023 Retrieved June 29 2023 Rubbelke Nathan March 9 2023 Agtech startup Agragene relocates from San Diego to St Louis bringing with it thousands of fruit flies American City Business Journals Retrieved June 29 2023 Walling Melina June 14 2023 To fight berry busting fruit flies researchers focus on sterilizing the bugs Associated Press Retrieved June 29 2023 Yadav Amarish K Butler Cole Yamamoto Akihiko Patil Anandrao A Lloyd Alun L Scott Maxwell J 2023 06 20 CRISPR Cas9 based split homing gene drive targeting doublesex for population suppression of the global fruit pest Drosophila suzukii Proceedings of the National Academy of Sciences 120 25 e2301525120 Bibcode 2023PNAS 12001525Y doi 10 1073 pnas 2301525120 ISSN 0027 8424 PMC 10288583 PMID 37307469 a b c d e f g h i j k l Lee Jana C Wang Xingeng Daane Kent M Hoelmer Kim A Isaacs Rufus Sial Ashfaq A Walton Vaughn M 2019 01 01 Biological Control of Spotted Wing Drosophila Diptera Drosophilidae Current and Pending Tactics Journal of Integrated Pest Management 10 1 Oxford University Press OUP 13 doi 10 1093 jipm pmz012 ISSN 2155 7470 Renkema Justin M Cuthbertson Andrew G S 2018 03 03 Impact of multiple natural enemies on immature Drosophila suzukii in strawberries and blueberries BioControl 63 5 Springer Science and Business Media LLC 719 728 Bibcode 2018BioCo 63 719R doi 10 1007 s10526 018 9874 8 ISSN 1386 6141 S2CID 3699972 a b Ballman Elissa S Collins Judith A Drummond Francis A 2017 09 27 Pupation Behavior and Predation on Drosophila suzukii Diptera Drosophilidae Pupae in Maine Wild Blueberry Fields Journal of Economic Entomology 110 6 Oxford University Press OUP 2308 2317 doi 10 1093 jee tox233 ISSN 0022 0493 PMID 29029219 Chandler James Angus James Pamela M Jospin Guillaume Lang Jenna M 2014 07 22 The bacterial communities of Drosophila suzukii collected from undamaged cherries PeerJ 2 e474 doi 10 7717 peerj 474 ISSN 2167 8359 PMC 4121540 PMID 25101226 Medd Nathan C Fellous Simon Waldron Fergal M Xuereb Anne Nakai Madoka Cross Jerry V Obbard Darren J 2018 01 01 The virome of Drosophila suzukii an invasive pest of soft fruit Virus Evolution 4 1 vey009 doi 10 1093 ve vey009 PMC 5888908 PMID 29644097 Anagnostou Christiana Dorsch Monika Rohlfs Marko 2010 07 01 Influence of dietary yeasts on Drosophila melanogaster life history traits Entomologia Experimentalis et Applicata 136 1 1 11 Bibcode 2010EEApp 136 1A doi 10 1111 j 1570 7458 2010 00997 x ISSN 1570 7458 S2CID 82266130 Starmer William T 1981 01 01 A comparison of Drosophila habitats according to the physiological attributes of the associated yeast communities Evolution 35 1 38 52 doi 10 1111 j 1558 5646 1981 tb04856 x ISSN 1558 5646 PMID 28563455 S2CID 37152729 Simmons Fred H Bradley Timothy J 1997 An analysis of resource allocation in response to dietary yeast in Drosophila melanogaster Journal of Insect Physiology 43 8 779 788 doi 10 1016 s0022 1910 97 00037 1 PMID 12770456 Hamby Kelly A Hernandez Alejandro Boundy Mills Kyria Zalom Frank G 2012 07 15 Associations of Yeasts with Spotted Wing Drosophila Drosophila suzukii Diptera Drosophilidae in Cherries and Raspberries Applied and Environmental Microbiology 78 14 4869 4873 Bibcode 2012ApEnM 78 4869H doi 10 1128 aem 00841 12 ISSN 0099 2240 PMC 3416361 PMID 22582060 Woltz J M Donahue K M Bruck D J Lee J C 2015 12 01 Efficacy of commercially available predators nematodes and fungal entomopathogens for augmentative control of Drosophila suzukii Journal of Applied Entomology 139 10 759 770 doi 10 1111 jen 12200 ISSN 1439 0418 S2CID 84245460 Cuthbertson Andrew G S Collins Debbie A Blackburn Lisa F Audsley Neil Bell Howard A 2014 06 20 Preliminary Screening of Potential Control Products against Drosophila suzukii Insects 5 2 488 498 doi 10 3390 insects5020488 PMC 4592600 PMID 26462696 Becher Paul G Jensen Rasmus E Natsopoulou Myrsini E Verschut Vasiliki Licht Henrik H De Fine 2018 03 01 Infection of Drosophila suzukii with the obligate insect pathogenic fungus Entomophthora muscae Journal of Pest Science 91 2 781 787 doi 10 1007 s10340 017 0915 3 ISSN 1612 4758 PMC 5847158 PMID 29568251 External links edit nbsp Wikispecies has information related to Drosophila suzukii nbsp Wikimedia Commons has media related to Drosophila suzukii Pest Alert Spotted Wing Drosophila Oregon Department of Agriculture Oregon State University horticulture site Washington State University Michigan State University Spotted Wing Drosophila site Spotted wing drosophila on the UF IFAS Featured Creatures Web site Species Profile Spotted Wing Drosophila Drosophila suzukii National Invasive Species Information Center United States National Agricultural Library EMERGING PEST Spotted Wing Drosophila A Berry and Stone Fruit Pest Pacific Northwest Pest Management Handbooks 2016 03 28 Retrieved 2020 12 15 Spotted Wing Drosophila Oregon State University College of Agricultural Sciences Retrieved 2020 12 15 Further reading editBellamy David E Sisterson Mark S Walse Spencer S 2013 Quantifying Host Potentials Indexing Postharvest Fresh Fruits for Spotted Wing Drosophila Drosophila suzukii PLOS ONE 8 4 1 10 Bibcode 2013PLoSO 861227B doi 10 1371 journal pone 0061227 PMC 3625224 PMID 23593439 Hamby Kelly A Kwok Rosanna S Zalom Frank G Chiu Joanna C 2013 Integrating Circadian Activity and Gene Expression Profiles to Predict Chronotoxicity of Drosophila suzukii Response to Insecticides PLOS ONE 8 7 1 14 Bibcode 2013PLoSO 868472H doi 10 1371 journal pone 0068472 PMC 3702611 PMID 23861907 Mazzoni Valerio Anfora Gianfranco Virant Doberlet Meta 2013 Substrate Vibrations During Courtship in Three Drosophila species PLOS ONE 8 11 1 8 Bibcode 2013PLoSO 880708M doi 10 1371 journal pone 0080708 PMC 3829934 PMID 24260459 Kacsoh Balint Z Schlenke Todd A 2012 High Hemocyte Load is Associated with Increased Resistance Against Parasitoids in Drosophila suzukii a Relative of D melanogaster PLOS ONE 7 4 1 16 Bibcode 2012PLoSO 734721K doi 10 1371 journal pone 0034721 PMC 3328493 PMID 22529929 Retrieved from https en wikipedia org w index php title Drosophila suzukii amp oldid 1214788116, wikipedia, wiki, book, books, library,

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