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Thrips

May 06, 2023

For the type genus, see Thrips (genus).
"Thunderbug" redirects here. For the NHL mascot, see List of National Hockey League mascots. For the girl group, see Thunderbugs (band).

Thrips (order Thysanoptera) are minute (mostly 1 mm (0.039 in) long or less), slender insects with fringed wings and unique asymmetrical mouthparts. Entomologists have described approximately 6,000 species. They fly only weakly and their feathery wings are unsuitable for conventional flight; instead, thrips exploit an unusual mechanism, clap and fling, to create lift using an unsteady circulation pattern with transient vortices near the wings.

Thrips
Temporal range: 299–0 Ma Permian – recent
Winged and wingless forms
Scientific classification
Kingdom: Animalia
Phylum: Arthropoda
Class: Insecta
(unranked): Eumetabola
(unranked): Paraneoptera
Order: Thysanoptera
Haliday, 1836
Suborders & Families

Terebrantia

Adiheterothripidae
Aeolothripidae
Fauriellidae
† Hemithripidae
Heterothripidae
† Jezzinothripidae
† Karataothripidae
Melanthripidae
Merothripidae
† Scudderothripidae
Stenurothripidae
Thripidae
† Triassothripidae
Uzelothripidae

Tubulifera

Phlaeothripidae
† Rohrthripidae
Synonyms

Physopoda[1]

Thrips are a functionally diverse group, with nearly half of the known species being fungivorous.[2] A small proportion of species of thrips are serious pests of commercially important crops.[3] Some of these serve as vectors for over 20 viruses that cause plant disease, especially the Tospoviruses. Many flower-dwelling species bring benefits as pollinators,[4] with some predatory thrips feeding on small insects or mites.[5] In the right conditions, such as in greenhouses, invasive species can exponentially increase in population size and form large swarms because of a lack of natural predators coupled with their ability to reproduce asexually, making them destructive to crops. Due to their cryptic nature, thrips may aggregate in household objects such as furniture, bedding and computer monitors – in the latter case by forcing their way in between the LCD and its glass covering.[6] Their identification to species by standard morphological characteristics is often challenging.

Etymology

The first recorded mention of thrips is from the 17th century and a sketch was made by Philippo Bonanni, a Catholic priest, in 1691. Swedish entomologist Baron Charles De Geer described two species in the genus Physapus in 1744 and Linnaeus in 1746 added a third species and named this group of insects Thrips. In 1836 the Irish entomologist Alexander Henry Haliday described 41 species in 11 genera and proposed the order name of Thysanoptera. The first monograph on the group was published in 1895 by Heinrich Uzel who is considered the father of Thysanoptera studies.[7][1]

The generic and English name thrips is a direct transliteration of the ancient Greek θρίψ, thrips, meaning "woodworm".[8] Like some other animal names such as sheep, deer, and moose, in English the word thrips is both the singular and plural forms, so there may be many thrips or a single thrips. Other common names for thrips include thunderflies, thunderbugs, storm flies, thunderblights, storm bugs, corn fleas, corn flies, corn lice, freckle bugs, harvest bugs, and physopods.[9][10][11] The older group name "physopoda" is with reference to the bladder like tips to the tarsi of the legs. The name of the order Thysanoptera is constructed from the ancient Greek words θύσανος, thysanos, "tassel or fringe", and πτερόν, pteron, "wing", for the insects' fringed wings.[12][13][14]

Morphology

 
Typical Tubulifera thrips: the feathery wings are unsuitable for the leading edge vortex flight of most other insects, but support clap and fling flight.
 
Leaf suffering from thrips

Thrips are small hemimetabolic insects with a distinctive cigar-shaped body plan. They are elongated with transversely constricted bodies. They range in size from 0.5 to 14 mm (0.02 to 0.55 in) in length for the larger predatory thrips, but most thrips are about 1 mm in length. Flight-capable thrips have two similar, strap-like pairs of wings with a fringe of bristles. The wings are folded back over the body at rest. Their legs usually end in two tarsal segments with a bladder-like structure known as an "arolium" at the pretarsus. This structure can be everted by means of hemolymph pressure, enabling the insect to walk on vertical surfaces.[15][16] They have compound eyes consisting of a small number of ommatidia and three ocelli or simple eyes on the head.[17]

 
Asymmetric mouthparts of Heliothrips

Thrips have asymmetrical mouthparts unique to the group. Unlike the Hemiptera (true bugs), the right mandible of thrips is reduced and vestigial – and in some species completely absent.[18] The left mandible is used briefly to cut into the food plant; saliva is injected and the maxillary stylets, which form a tube, are then inserted and the semi-digested food pumped from ruptured cells. This process leaves cells destroyed or collapsed, and a distinctive silvery or bronze scarring on the surfaces of the stems or leaves where the thrips have fed.[19]

Thysanoptera is divided into two suborders, Terebrantia and Tubulifera; these can be distinguished by morphological, behavioral, and developmental characteristics. Tubulifera consists of a single family, Phlaeothripidae; members can be identified by their characteristic tube-shaped apical abdominal segment, egg-laying atop the surface of leaves, and three "pupal" stages. In the Phlaeothripidae, the males are often larger than females and a range of sizes may be found within a population. The largest recorded phlaeothripid species is about 14 mm long. Females of the eight families of the Terebrantia all possess the eponymous saw-like (see terebra) ovipositor on the anteapical abdominal segment, lay eggs singly within plant tissue, and have two "pupal" stages. In most Terebrantia, the males are smaller than females. The family Uzelothripidae has a single species and it is unique in having a whip-like terminal antennal segment.[17]

Evolution

The earliest fossils of thrips date back to the Permian (Permothrips longipennis). By the Early Cretaceous, true thrips became much more abundant.[20] The extant family Merothripidae most resembles these ancestral Thysanoptera, and is probably basal to the order.[21] There are currently over six thousand species of thrips recognized, grouped into 777 extant and sixty fossil genera.[22]

Phylogeny

Thrips are generally considered to be the sister group to Hemiptera (bugs).[23]

The phylogeny of thrips families has been little studied. A preliminary analysis in 2013 of 37 species using 3 genes, as well as a phylogeny based on ribosomal DNA and three proteins in 2012, supports the monophyly of the two suborders, Tubulifera and Terebrantia. In Terebrantia, Melanothripidae may be sister to all other families, but other relationships remain unclear. In Tubulifera, the Phlaeothripidae and its subfamily Idolothripinae are monophyletic. The two largest thrips subfamilies, Phlaeothripinae and Thripinae, are paraphyletic and need further work to determine their structure. The internal relationships from these analyses are shown in the cladogram.[24][25]

Thysanoptera

Taxonomy

The following families are currently (2013) recognized:[25][26][17]

  • Adiheterothripidae Shumsher, 1946 (11 genera)
  • Aeolothripidae Uzel, 1895 (29 genera) – banded thrips and broad-winged thrips
  • Fauriellidae Priesner, 1949 (four genera)
  • †Hemithripidae Bagnall, 1923 (one fossil genus, Hemithrips with 15 species)
  • Heterothripidae Bagnall, 1912 (seven genera, restricted to the New World)
  • †Jezzinothripidae zur Strassen, 1973 (included by some authors in Merothripidae)
  • †Karataothripidae Sharov, 1972 (one fossil species, Karataothrips jurassicus)
  • Melanthripidae Bagnall, 1913 (six genera of flower feeders)
  • Merothripidae Hood, 1914 (five genera, mostly Neotropical and feeding on dry-wood fungi) – large-legged thrips
  • †Scudderothripidae zur Strassen, 1973 (included by some authors in Stenurothripidae)
  • Thripidae Stephens, 1829 (292 genera in four subfamilies, flower living) – common thrips
  • †Triassothripidae Grimaldi & Shmakov, 2004 (two fossil genera)
  • Uzelothripidae Hood, 1952 (one species, Uzelothrips scabrosus)
  • Phlaeothripidae Uzel, 1895 (447 genera in two subfamilies, fungal hyphae and spore feeders)

The identification of thrips to species is challenging as types are maintained as slide preparations of varying quality over time. There is also considerable variability leading to many species being misidentified. Molecular sequence based approaches have increasingly been applied to their identification.[27][28]

Biology

 
The Australian rainforest shrub Myrsine (Rapanea) howittiana is pollinated by Thrips setipennis.

Feeding

Thrips are believed to have descended from a fungus-feeding ancestor during the Mesozoic,[20] and many groups still feed upon and inadvertently redistribute fungal spores. These live among leaf litter or on dead wood and are important members of the ecosystem, their diet often being supplemented with pollen. Other species are primitively eusocial and form plant galls and still others are predatory on mites and other thrips.[13] Two species of Aulacothrips, A. tenuis and A. levinotus, have been found to be ectoparasites on aetalionid and membracid plant-hoppers in Brazil.[29]

Mirothrips arbiter has been found in paper wasp nests in Brazil. The eggs of the hosts including Mischocyttarus atramentarius, Mischocyttarus cassununga and Polistes versicolor are eaten by the thrips.[30] Thrips, especially in the family Aeolothripidae, are also predators, and are considered beneficial in the management of pests like the codling moths.[31]

Most research has focused on thrips species that feed on economically significant crops. Some species are predatory, but most of them feed on pollen and the chloroplasts harvested from the outer layer of plant epidermal and mesophyll cells. They prefer tender parts of the plant, such as buds, flowers and new leaves.[32][33] Besides feeding on plant tissues, the common blossom thrips feeds on pollen grains and on the eggs of mites. When the larva supplements its diet in this way, its development time and mortality is reduced, and adult females that consume mite eggs increase their fecundity and longevity.[34]

Pollination

 
Coffee tree leaves rolled up by Hoplandrothrips (Phlaeothripidae) damage

Some flower-feeding thrips pollinate the flowers they are feeding on, and some authors suspect that they may have been among the first insects to evolve a pollinating relationship with their host plants.[35] Scirtothrips dorsalis carries pollen of commercially important chili peppers.[36][37][38] Darwin found that thrips could not be kept out by any netting when he conducted experiments by keeping away larger pollinators.[39]Thrips setipennis is the sole pollinator of Wilkiea huegeliana, a small, unisexual annually flowering tree or shrub in the rainforests of eastern Australia. T. setipennis serves as an obligate pollinator for other Australian rainforest plant species, including Myrsine howittiana and M. variabilis.[40] The genus Cycadothrips is a specialist pollinator of cycads, the cones of which are adapted for pollination by small insects.[41] Thrips are likewise the primary pollinators of heathers in the family Ericaceae,[42] and play a significant role in the pollination of pointleaf manzanita. Electron microscopy has shown thrips carrying pollen grains adhering to their backs, and their fringed wings are perfectly capable of allowing them to fly from plant to plant.[41]

Damage to plants

Thrips can cause damage during feeding.[43] This impact may fall across a broad selection of prey items, as there is considerable breadth in host affinity across the order, and even within a species, varying degrees of fidelity to a host.[32][44] Family Thripidae in particular is notorious for members with broad host ranges, and the majority of pest thrips come from this family.[45][46] For example, Thrips tabaci damages crops of onions, potatoes, tobacco, and cotton.[33][47]

 
Eusocial colonies of Kladothrips cause and live in galls on Acacia trees.

Some species of thrips create galls, almost always in leaf tissue. These may occur as curls, rolls or folds, or as alterations to the expansion of tissues causing distortion to leaf blades. More complex examples cause rosettes, pouches and horns. Most of these species occur in the tropics and sub-tropics, and the structures of the galls are diagnostic of the species involved.[48] A radiation of thrips species seems to have taken place on Acacia trees in Australia; some of these species cause galls in the petioles, sometimes fixing two leaf stalks together, while other species live in every available crevice in the bark. In Casuarina in the same country, some species have invaded stems, creating long-lasting woody galls.[49]

Social behaviour

While poorly documented, chemical communication is believed to be important to the group.[50] Anal secretions are produced in the hindgut,[51] and released along the posterior setae as predator deterrents[51][52] In Australia, aggregations of male common blossom thrips have been observed on the petals of Hibiscus rosa-sinensis and Gossypium hirsutum; females were attracted to these groups so it seems likely that the males were producing pheromones.[53]

In the phlaeothripids that feed on fungi, males compete to protect and mate with females, and then defend the egg-mass. Males fight by flicking their rivals away with their abdomen, and may kill with their foretarsal teeth. Small males may sneak in to mate while the larger males are busy fighting. In the Merothripidae and in the Aeolothripidae, males are again polymorphic with large and small forms, and probably also compete for mates, so the strategy may well be ancestral among the Thysanoptera.[17]

Many thrips form galls on plants when feeding or laying their eggs. Some of the gall-forming Phlaeothripidae, such as genera Kladothrips[54] and Oncothrips,[55] form eusocial groups similar to ant colonies, with reproductive queens and nonreproductive soldier castes.[56][57][58]

Flight

Further information: Insect flight § Clap and fling

Most insects create lift by the stiff-winged mechanism of insect flight with steady state aerodynamics; this creates a leading edge vortex continuously as the wing moves. The feathery wings of thrips, however, generate lift by clap and fling, a mechanism discovered by the Danish zoologist Torkel Weis-Fogh in 1973. In the clap part of the cycle, the wings approach each other over the insect's back, creating a circulation of air which sets up vortices and generates useful forces on the wings. The leading edges of the wings touch, and the wings rotate around their leading edges, bringing them together in the "clap". The wings close, expelling air from between them, giving more useful thrust. The wings rotate around their trailing edges to begin the "fling", creating useful forces. The leading edges move apart, making air rush in between them and setting up new vortices, generating more force on the wings. The trailing edge vortices, however, cancel each other out with opposing flows. Weis-Fogh suggested that this cancellation might help the circulation of air to grow more rapidly, by shutting down the Wagner effect which would otherwise counteract the growth of the circulation.[59][60][61][62]

  • Clap and fling flight mechanism after Sane 2003
  •  

    Clap 1: wings close over back

  •  

    Clap 2: leading edges touch, wing rotates around leading edge, vortices form

  •  

    Clap 3: trailing edges close, vortices shed, wings close giving thrust

  • Black circle and heavy line: wing (rachis and bristles); Black (curved) arrows: flow; Blue arrows: induced velocity; Orange arrows: net force on wing
  •  

    Fling 1: wings rotate around trailing edge to fling apart

  •  

    Fling 2: leading edge moves away, air rushes in, increasing lift

  •  

    Fling 3: new vortex forms at leading edge, trailing edge vortices cancel each other, perhaps helping flow to grow faster (Weis-Fogh 1973)

Apart from active flight, thrips, even wingless ones, can also be picked up by winds and transferred long distances. During warm and humid weather, adults may climb to the tips of plants to leap and catch air current. Wind-aided dispersal of species has been recorded over 1600 km of sea between Australia and South Island of New Zealand.[17] It has been suggested that some bird species may also be involved in the dispersal of thrips. Thrips are picked up along with grass in the nests of birds and can be transported by the birds.[63]

A hazard of flight for very small insects such as thrips is the possibility of being trapped by water. Thrips have non-wetting bodies and have the ability to ascend a meniscus by arching their bodies and working their way head-first and upwards along the water surface in order to escape.[64]

Life cycle

 
Thrips nymph.
Scale bar is 0.5 mm

Thrips lay extremely small eggs, about 0.2 mm long. Females of the suborder Terebrantia cut slits in plant tissue with their ovipositor, and insert their eggs, one per slit. Females of the suborder Tubulifera lay their eggs singly or in small groups on the outside surfaces of plants.[65]

Thrips are hemimetabolous, metamorphosing gradually to the adult form. The first two instars, called larvae or nymphs, are like small wingless adults (often confused with springtails) without genitalia; these feed on plant tissue. In the Terebrantia, the third and fourth instars, and in the Tubulifera also a fifth instar, are non-feeding resting stages similar to pupae: in these stages, the body's organs are reshaped, and wing-buds and genitalia are formed.[65] The adult stage can be reached in around 8–15 days; adults can live for around 45 days.[66] Adults have both winged and wingless forms; in the grass thrips Anaphothrips obscurus, for example, the winged form makes up 90% of the population in spring (in temperate zones), while the wingless form makes up 98% of the population late in the summer.[67] Thrips can survive the winter as adults or through egg or pupal diapause.[17]

Thrips are haplodiploid with haploid males (from unfertilised eggs, as in Hymenoptera) and diploid females capable of parthenogenesis (reproducing without fertilisation), many species using arrhenotoky, a few using thelytoky.[68] In Pezothrips kellyanus females hatch from larger eggs than males, possibly because they are more likely to be fertilized.[69] The sex-determining bacterial endosymbiont Wolbachia is a factor that affects the reproductive mode.[44][68][70] Several normally bisexual species have become established in the United States with only females present.[68][71]

Human impact

 
A tomato infected with the thrips-borne Tospovirus, tomato spotted wilt virus

As pests

 
Ponticulothrips diospyrosi on finger

Many thrips are pests of commercial crops due to the damage they cause by feeding on developing flowers or vegetables, causing discoloration, deformities, and reduced marketability of the crop. Some thrips serve as vectors for plant diseases, such as tospoviruses.[72] Over 20 plant-infecting viruses are known to be transmitted by thrips, but perversely, less than a dozen of the described species are known to vector tospoviruses.[73] These enveloped viruses are considered among some of the most damaging of emerging plant pathogens around the world, with those vector species having an outsized impact on human agriculture. Virus members include the tomato spotted wilt virus and the impatiens necrotic spot viruses. The western flower thrips, Frankliniella occidentalis, has spread until it now has a worldwide distribution, and is the primary vector of plant diseases caused by tospoviruses.[74] Other viruses that they spread include the genera Ilarvirus, (Alpha|Beta|Gamma)carmovirus, Sobemovirus and Machlomovirus.[75] Their small size and predisposition towards enclosed places makes them difficult to detect by phytosanitary inspection, while their eggs, laid inside plant tissue, are well-protected from pesticide sprays.[66] When coupled with the increasing globalization of trade and the growth of greenhouse agriculture, thrips, unsurprisingly, are among the fastest growing group of invasive species in the world. Examples include F. occidentalis, Thrips simplex, and Thrips palmi.[76]

Flower-feeding thrips are routinely attracted to bright floral colors (including white, blue, and especially yellow), and will land and attempt to feed. It is not uncommon for some species (e.g., Frankliniella tritici and Limothrips cerealium) to "bite" humans under such circumstances. Although no species feed on blood and no known animal disease is transmitted by thrips, some skin irritation has been described.[77]

Management

 
A robberfly preying on thrips

Thrips develop resistance to insecticides easily and there is constant research on how to control them. This makes thrips ideal as models for testing the effectiveness of new pesticides and methods.[78]

Due to their small sizes and high rates of reproduction, thrips are difficult to control using classical biological control. Suitable predators must be small and slender enough to penetrate the crevices where thrips hide while feeding, and they must also prey extensively on eggs and larvae to be effective. Only two families of parasitoid Hymenoptera parasitize eggs and larvae, the Eulophidae and the Trichogrammatidae. Other biocontrol agents of adults and larvae include anthocorid bugs of genus Orius, and phytoseiid mites. Biological insecticides such as the fungi Beauveria bassiana and Verticillium lecanii can kill thrips at all life-cycle stages.[79] Insecticidal soap spray is effective against thrips. It is commercially available or can be made of certain types of household soap. Scientists in Japan report that significant reductions in larva and adult melon thrips occur when plants are illuminated with red light.[80]

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External links

 
Wikimedia Commons has media related to Thysanoptera.
 
Wikispecies has information related to Thysanoptera.
  • Thrips of the World checklist
  • Thrips species wiki
  • Thrips images from the "Pests and Diseases Image Library (PaDIL)" of Australia
  • University of California Pest Management Guidelines for Thrips
  • University of California Thrips Identification
  • CISR: Center for Invasive Species Research Fact Sheets
    • Avocado Thrips
    • Western Flower Thrips
    • Myoporum Thrips
  • Thrips links on the UF / IFAS Featured Creatures Web site
    • Frankliniella schultzei, common blossom thrips (Thripidae)
    • Heliothrips haemorrhoidalis , greenhouse thrips (Thripidae)
    • Scirtothrips dorsalis, chilli thrips (Thripidae)
    • Selenothrips rubrocinctus, redbanded thrips (Thripidae)
    • Thrips palmi, melon thrips (Thripidae)
    • Thrips simplex, gladiolus thrips (Thripidae)

May 06, 2023
thrips, type, genus, genus, thunderbug, redirects, here, mascot, list, national, hockey, league, mascots, girl, group, thunderbugs, band, order, thysanoptera, minute, mostly, long, less, slender, insects, with, fringed, wings, unique, asymmetrical, mouthparts,. For the type genus see Thrips genus Thunderbug redirects here For the NHL mascot see List of National Hockey League mascots For the girl group see Thunderbugs band Thrips order Thysanoptera are minute mostly 1 mm 0 039 in long or less slender insects with fringed wings and unique asymmetrical mouthparts Entomologists have described approximately 6 000 species They fly only weakly and their feathery wings are unsuitable for conventional flight instead thrips exploit an unusual mechanism clap and fling to create lift using an unsteady circulation pattern with transient vortices near the wings ThripsTemporal range 299 0 Ma PreꞒ Ꞓ O S D C P T J K Pg N Permian recentWinged and wingless formsScientific classificationKingdom AnimaliaPhylum ArthropodaClass Insecta unranked Eumetabola unranked ParaneopteraOrder ThysanopteraHaliday 1836Suborders amp FamiliesTerebrantia Adiheterothripidae Aeolothripidae Fauriellidae Hemithripidae Heterothripidae Jezzinothripidae Karataothripidae Melanthripidae Merothripidae Scudderothripidae Stenurothripidae Thripidae Triassothripidae UzelothripidaeTubulifera Phlaeothripidae RohrthripidaeSynonymsPhysopoda 1 Thrips are a functionally diverse group with nearly half of the known species being fungivorous 2 A small proportion of species of thrips are serious pests of commercially important crops 3 Some of these serve as vectors for over 20 viruses that cause plant disease especially the Tospoviruses Many flower dwelling species bring benefits as pollinators 4 with some predatory thrips feeding on small insects or mites 5 In the right conditions such as in greenhouses invasive species can exponentially increase in population size and form large swarms because of a lack of natural predators coupled with their ability to reproduce asexually making them destructive to crops Due to their cryptic nature thrips may aggregate in household objects such as furniture bedding and computer monitors in the latter case by forcing their way in between the LCD and its glass covering 6 Their identification to species by standard morphological characteristics is often challenging Contents 1 Etymology 2 Morphology 3 Evolution 3 1 Phylogeny 3 2 Taxonomy 4 Biology 4 1 Feeding 4 2 Pollination 4 3 Damage to plants 4 4 Social behaviour 4 5 Flight 4 6 Life cycle 5 Human impact 5 1 As pests 5 2 Management 6 References 7 External linksEtymology EditThe first recorded mention of thrips is from the 17th century and a sketch was made by Philippo Bonanni a Catholic priest in 1691 Swedish entomologist Baron Charles De Geer described two species in the genus Physapus in 1744 and Linnaeus in 1746 added a third species and named this group of insects Thrips In 1836 the Irish entomologist Alexander Henry Haliday described 41 species in 11 genera and proposed the order name of Thysanoptera The first monograph on the group was published in 1895 by Heinrich Uzel who is considered the father of Thysanoptera studies 7 1 The generic and English name thrips is a direct transliteration of the ancient Greek 8rips thrips meaning woodworm 8 Like some other animal names such as sheep deer and moose in English the word thrips is both the singular and plural forms so there may be many thrips or a single thrips Other common names for thrips include thunderflies thunderbugs storm flies thunderblights storm bugs corn fleas corn flies corn lice freckle bugs harvest bugs and physopods 9 10 11 The older group name physopoda is with reference to the bladder like tips to the tarsi of the legs The name of the order Thysanoptera is constructed from the ancient Greek words 8ysanos thysanos tassel or fringe and pteron pteron wing for the insects fringed wings 12 13 14 Morphology Edit Typical Tubulifera thrips the feathery wings are unsuitable for the leading edge vortex flight of most other insects but support clap and fling flight Leaf suffering from thrips Thrips are small hemimetabolic insects with a distinctive cigar shaped body plan They are elongated with transversely constricted bodies They range in size from 0 5 to 14 mm 0 02 to 0 55 in in length for the larger predatory thrips but most thrips are about 1 mm in length Flight capable thrips have two similar strap like pairs of wings with a fringe of bristles The wings are folded back over the body at rest Their legs usually end in two tarsal segments with a bladder like structure known as an arolium at the pretarsus This structure can be everted by means of hemolymph pressure enabling the insect to walk on vertical surfaces 15 16 They have compound eyes consisting of a small number of ommatidia and three ocelli or simple eyes on the head 17 Asymmetric mouthparts of Heliothrips Thrips have asymmetrical mouthparts unique to the group Unlike the Hemiptera true bugs the right mandible of thrips is reduced and vestigial and in some species completely absent 18 The left mandible is used briefly to cut into the food plant saliva is injected and the maxillary stylets which form a tube are then inserted and the semi digested food pumped from ruptured cells This process leaves cells destroyed or collapsed and a distinctive silvery or bronze scarring on the surfaces of the stems or leaves where the thrips have fed 19 Thysanoptera is divided into two suborders Terebrantia and Tubulifera these can be distinguished by morphological behavioral and developmental characteristics Tubulifera consists of a single family Phlaeothripidae members can be identified by their characteristic tube shaped apical abdominal segment egg laying atop the surface of leaves and three pupal stages In the Phlaeothripidae the males are often larger than females and a range of sizes may be found within a population The largest recorded phlaeothripid species is about 14 mm long Females of the eight families of the Terebrantia all possess the eponymous saw like see terebra ovipositor on the anteapical abdominal segment lay eggs singly within plant tissue and have two pupal stages In most Terebrantia the males are smaller than females The family Uzelothripidae has a single species and it is unique in having a whip like terminal antennal segment 17 Evolution EditThe earliest fossils of thrips date back to the Permian Permothrips longipennis By the Early Cretaceous true thrips became much more abundant 20 The extant family Merothripidae most resembles these ancestral Thysanoptera and is probably basal to the order 21 There are currently over six thousand species of thrips recognized grouped into 777 extant and sixty fossil genera 22 Phylogeny Edit Thrips are generally considered to be the sister group to Hemiptera bugs 23 The phylogeny of thrips families has been little studied A preliminary analysis in 2013 of 37 species using 3 genes as well as a phylogeny based on ribosomal DNA and three proteins in 2012 supports the monophyly of the two suborders Tubulifera and Terebrantia In Terebrantia Melanothripidae may be sister to all other families but other relationships remain unclear In Tubulifera the Phlaeothripidae and its subfamily Idolothripinae are monophyletic The two largest thrips subfamilies Phlaeothripinae and Thripinae are paraphyletic and need further work to determine their structure The internal relationships from these analyses are shown in the cladogram 24 25 Thysanoptera Terebrantia Melanthripidaeother TerebrantiaTubulifera PhlaeothripidaeTaxonomy Edit The following families are currently 2013 recognized 25 26 17 Suborder Terebrantia Adult Franklinothrips vespiformis Aeolothripidae a widely distributed tropical speciesAdiheterothripidae Shumsher 1946 11 genera Aeolothripidae Uzel 1895 29 genera banded thrips and broad winged thrips Fauriellidae Priesner 1949 four genera Hemithripidae Bagnall 1923 one fossil genus Hemithrips with 15 species Heterothripidae Bagnall 1912 seven genera restricted to the New World Jezzinothripidae zur Strassen 1973 included by some authors in Merothripidae Karataothripidae Sharov 1972 one fossil species Karataothrips jurassicus Melanthripidae Bagnall 1913 six genera of flower feeders Merothripidae Hood 1914 five genera mostly Neotropical and feeding on dry wood fungi large legged thrips Scudderothripidae zur Strassen 1973 included by some authors in Stenurothripidae Thripidae Stephens 1829 292 genera in four subfamilies flower living common thrips Triassothripidae Grimaldi amp Shmakov 2004 two fossil genera Uzelothripidae Hood 1952 one species Uzelothrips scabrosus Suborder TubuliferaPhlaeothripidae Uzel 1895 447 genera in two subfamilies fungal hyphae and spore feeders The identification of thrips to species is challenging as types are maintained as slide preparations of varying quality over time There is also considerable variability leading to many species being misidentified Molecular sequence based approaches have increasingly been applied to their identification 27 28 Biology Edit The Australian rainforest shrub Myrsine Rapanea howittiana is pollinated by Thrips setipennis Feeding Edit Thrips are believed to have descended from a fungus feeding ancestor during the Mesozoic 20 and many groups still feed upon and inadvertently redistribute fungal spores These live among leaf litter or on dead wood and are important members of the ecosystem their diet often being supplemented with pollen Other species are primitively eusocial and form plant galls and still others are predatory on mites and other thrips 13 Two species of Aulacothrips A tenuis and A levinotus have been found to be ectoparasites on aetalionid and membracid plant hoppers in Brazil 29 Mirothrips arbiter has been found in paper wasp nests in Brazil The eggs of the hosts including Mischocyttarus atramentarius Mischocyttarus cassununga and Polistes versicolor are eaten by the thrips 30 Thrips especially in the family Aeolothripidae are also predators and are considered beneficial in the management of pests like the codling moths 31 Most research has focused on thrips species that feed on economically significant crops Some species are predatory but most of them feed on pollen and the chloroplasts harvested from the outer layer of plant epidermal and mesophyll cells They prefer tender parts of the plant such as buds flowers and new leaves 32 33 Besides feeding on plant tissues the common blossom thrips feeds on pollen grains and on the eggs of mites When the larva supplements its diet in this way its development time and mortality is reduced and adult females that consume mite eggs increase their fecundity and longevity 34 Pollination Edit Coffee tree leaves rolled up by Hoplandrothrips Phlaeothripidae damage Some flower feeding thrips pollinate the flowers they are feeding on and some authors suspect that they may have been among the first insects to evolve a pollinating relationship with their host plants 35 Scirtothrips dorsalis carries pollen of commercially important chili peppers 36 37 38 Darwin found that thrips could not be kept out by any netting when he conducted experiments by keeping away larger pollinators 39 Thrips setipennis is the sole pollinator of Wilkiea huegeliana a small unisexual annually flowering tree or shrub in the rainforests of eastern Australia T setipennis serves as an obligate pollinator for other Australian rainforest plant species including Myrsine howittiana and M variabilis 40 The genus Cycadothrips is a specialist pollinator of cycads the cones of which are adapted for pollination by small insects 41 Thrips are likewise the primary pollinators of heathers in the family Ericaceae 42 and play a significant role in the pollination of pointleaf manzanita Electron microscopy has shown thrips carrying pollen grains adhering to their backs and their fringed wings are perfectly capable of allowing them to fly from plant to plant 41 Damage to plants Edit Thrips can cause damage during feeding 43 This impact may fall across a broad selection of prey items as there is considerable breadth in host affinity across the order and even within a species varying degrees of fidelity to a host 32 44 Family Thripidae in particular is notorious for members with broad host ranges and the majority of pest thrips come from this family 45 46 For example Thrips tabaci damages crops of onions potatoes tobacco and cotton 33 47 Eusocial colonies of Kladothrips cause and live in galls on Acacia trees Some species of thrips create galls almost always in leaf tissue These may occur as curls rolls or folds or as alterations to the expansion of tissues causing distortion to leaf blades More complex examples cause rosettes pouches and horns Most of these species occur in the tropics and sub tropics and the structures of the galls are diagnostic of the species involved 48 A radiation of thrips species seems to have taken place on Acacia trees in Australia some of these species cause galls in the petioles sometimes fixing two leaf stalks together while other species live in every available crevice in the bark In Casuarina in the same country some species have invaded stems creating long lasting woody galls 49 Social behaviour Edit While poorly documented chemical communication is believed to be important to the group 50 Anal secretions are produced in the hindgut 51 and released along the posterior setae as predator deterrents 51 52 In Australia aggregations of male common blossom thrips have been observed on the petals of Hibiscus rosa sinensis and Gossypium hirsutum females were attracted to these groups so it seems likely that the males were producing pheromones 53 In the phlaeothripids that feed on fungi males compete to protect and mate with females and then defend the egg mass Males fight by flicking their rivals away with their abdomen and may kill with their foretarsal teeth Small males may sneak in to mate while the larger males are busy fighting In the Merothripidae and in the Aeolothripidae males are again polymorphic with large and small forms and probably also compete for mates so the strategy may well be ancestral among the Thysanoptera 17 Many thrips form galls on plants when feeding or laying their eggs Some of the gall forming Phlaeothripidae such as genera Kladothrips 54 and Oncothrips 55 form eusocial groups similar to ant colonies with reproductive queens and nonreproductive soldier castes 56 57 58 Flight Edit Further information Insect flight Clap and fling Most insects create lift by the stiff winged mechanism of insect flight with steady state aerodynamics this creates a leading edge vortex continuously as the wing moves The feathery wings of thrips however generate lift by clap and fling a mechanism discovered by the Danish zoologist Torkel Weis Fogh in 1973 In the clap part of the cycle the wings approach each other over the insect s back creating a circulation of air which sets up vortices and generates useful forces on the wings The leading edges of the wings touch and the wings rotate around their leading edges bringing them together in the clap The wings close expelling air from between them giving more useful thrust The wings rotate around their trailing edges to begin the fling creating useful forces The leading edges move apart making air rush in between them and setting up new vortices generating more force on the wings The trailing edge vortices however cancel each other out with opposing flows Weis Fogh suggested that this cancellation might help the circulation of air to grow more rapidly by shutting down the Wagner effect which would otherwise counteract the growth of the circulation 59 60 61 62 Clap and fling flight mechanism after Sane 2003 Clap 1 wings close over back Clap 2 leading edges touch wing rotates around leading edge vortices form Clap 3 trailing edges close vortices shed wings close giving thrustBlack circle and heavy line wing rachis and bristles Black curved arrows flow Blue arrows induced velocity Orange arrows net force on wing Fling 1 wings rotate around trailing edge to fling apart Fling 2 leading edge moves away air rushes in increasing lift Fling 3 new vortex forms at leading edge trailing edge vortices cancel each other perhaps helping flow to grow faster Weis Fogh 1973 Apart from active flight thrips even wingless ones can also be picked up by winds and transferred long distances During warm and humid weather adults may climb to the tips of plants to leap and catch air current Wind aided dispersal of species has been recorded over 1600 km of sea between Australia and South Island of New Zealand 17 It has been suggested that some bird species may also be involved in the dispersal of thrips Thrips are picked up along with grass in the nests of birds and can be transported by the birds 63 A hazard of flight for very small insects such as thrips is the possibility of being trapped by water Thrips have non wetting bodies and have the ability to ascend a meniscus by arching their bodies and working their way head first and upwards along the water surface in order to escape 64 Life cycle Edit Thrips nymph Scale bar is 0 5 mm Thrips lay extremely small eggs about 0 2 mm long Females of the suborder Terebrantia cut slits in plant tissue with their ovipositor and insert their eggs one per slit Females of the suborder Tubulifera lay their eggs singly or in small groups on the outside surfaces of plants 65 Thrips are hemimetabolous metamorphosing gradually to the adult form The first two instars called larvae or nymphs are like small wingless adults often confused with springtails without genitalia these feed on plant tissue In the Terebrantia the third and fourth instars and in the Tubulifera also a fifth instar are non feeding resting stages similar to pupae in these stages the body s organs are reshaped and wing buds and genitalia are formed 65 The adult stage can be reached in around 8 15 days adults can live for around 45 days 66 Adults have both winged and wingless forms in the grass thrips Anaphothrips obscurus for example the winged form makes up 90 of the population in spring in temperate zones while the wingless form makes up 98 of the population late in the summer 67 Thrips can survive the winter as adults or through egg or pupal diapause 17 Thrips are haplodiploid with haploid males from unfertilised eggs as in Hymenoptera and diploid females capable of parthenogenesis reproducing without fertilisation many species using arrhenotoky a few using thelytoky 68 In Pezothrips kellyanus females hatch from larger eggs than males possibly because they are more likely to be fertilized 69 The sex determining bacterial endosymbiont Wolbachia is a factor that affects the reproductive mode 44 68 70 Several normally bisexual species have become established in the United States with only females present 68 71 Human impact Edit A tomato infected with the thrips borne Tospovirus tomato spotted wilt virus As pests Edit Ponticulothrips diospyrosi on finger Many thrips are pests of commercial crops due to the damage they cause by feeding on developing flowers or vegetables causing discoloration deformities and reduced marketability of the crop Some thrips serve as vectors for plant diseases such as tospoviruses 72 Over 20 plant infecting viruses are known to be transmitted by thrips but perversely less than a dozen of the described species are known to vector tospoviruses 73 These enveloped viruses are considered among some of the most damaging of emerging plant pathogens around the world with those vector species having an outsized impact on human agriculture Virus members include the tomato spotted wilt virus and the impatiens necrotic spot viruses The western flower thrips Frankliniella occidentalis has spread until it now has a worldwide distribution and is the primary vector of plant diseases caused by tospoviruses 74 Other viruses that they spread include the genera Ilarvirus Alpha Beta Gamma carmovirus Sobemovirus and Machlomovirus 75 Their small size and predisposition towards enclosed places makes them difficult to detect by phytosanitary inspection while their eggs laid inside plant tissue are well protected from pesticide sprays 66 When coupled with the increasing globalization of trade and the growth of greenhouse agriculture thrips unsurprisingly are among the fastest growing group of invasive species in the world Examples include F occidentalis Thrips simplex and Thrips palmi 76 Flower feeding thrips are routinely attracted to bright floral colors including white blue and especially yellow and will land and attempt to feed It is not uncommon for some species e g Frankliniella tritici and Limothrips cerealium to bite humans under such circumstances Although no species feed on blood and no known animal disease is transmitted by thrips some skin irritation has been described 77 Management Edit A robberfly preying on thrips Thrips develop resistance to insecticides easily and there is constant research on how to control them This makes thrips ideal as models for testing the effectiveness of new pesticides and methods 78 Due to their small sizes and high rates of reproduction thrips are difficult to control using classical biological control Suitable predators must be small and slender enough to penetrate the crevices where thrips hide while feeding and they must also prey extensively on eggs and larvae to be effective Only two families of parasitoid Hymenoptera parasitize eggs and larvae the Eulophidae and the Trichogrammatidae Other biocontrol agents of adults and larvae include anthocorid bugs of genus Orius and phytoseiid mites Biological insecticides such as the fungi Beauveria bassiana and Verticillium lecanii can kill thrips at all life cycle stages 79 Insecticidal soap spray is effective against thrips It is commercially available or can be made of certain types of household soap Scientists in Japan report that significant reductions in larva and adult melon thrips occur when plants are illuminated with red light 80 References Edit a b Fedor Peter J Doricova Martina Prokop Pavol Mound Laurence A 2010 Heinrich Uzel the father of Thysanoptera studies PDF Zootaxa 2645 55 63 doi 10 11646 zootaxa 2645 1 3 Morse J G and Hoddle M S 2006 Invasion Biology of Thrips Annual Review of Entomology 51 1 67 89 Mound L A Wang Z Lima E F B Marullo R Problems with the Concept of Pest among the Diversity of Pestiferous Thrips Insects 2022 13 61 Terry I Walter G H Moore C Roemer R Hull C 2007 Odor Mediated Push Pull Pollination in Cycads Science 318 5847 70 doi 10 1126 science 1145147 PMID 17916726 S2CID 24147411 Wang Z Mound L A Hussain M Arthurs S P Mao R 2022 Thysanoptera as predators their diversity and significance as biological control agents 78 12 5057 5070 What are Thunderbugs Naked Scientists 19 April 2016 Uzel Jindrich 1895 Monografie radu Thysanoptera Hradec Kralove 8rips Liddell Henry George Scott Robert A Greek English Lexicon at the Perseus Project Kobro Sverre 2011 Checklist of Nordic Thysanoptera PDF Norwegian Journal of Entomology 58 21 26 Retrieved October 25 2014 Kirk W D J 1996 Thrips Naturalists Handbooks 25 The Richmond Publishing Company Marren Peter Mabey Richard 2010 Bugs Britannica Chatto amp Windus p 141 ISBN 978 0 7011 8180 2 Thysanoptera Merriam Webster Retrieved 15 February 2017 a b Tipping C 2008 Capinera John L ed Encyclopedia of Entomology Springer Science amp Business Media pp 3769 3771 ISBN 978 1 4020 6242 1 8ysanos pteron in Liddell and Scott Gillott Cedric 2005 Entomology Springer p 234 ISBN 978 0 306 44967 3 Heming B S 1971 Functional morphology of the thysanopteran pretarsus Canadian Journal of Zoology 49 1 91 108 doi 10 1139 z71 014 PMID 5543183 a b c d e f Mound L A 2003 Thysanoptera In Resh Vincent H Carde Ring T eds Encyclopedia of Insects Academic Press pp 999 1003 ISBN 978 0 12 586990 4 Childers C C Achor D S 1989 Structure of the mouthparts of Frankliniella bispinosa Morgan Thysanoptera Thripidae In Parker B L Skinner M Lewis T eds Towards Understanding Thysanoptera Proceedings of the International Conference on Thrips Radnor PA USDA Technical Report NE 147 Chisholm I F Lewis T 2009 A new look at thrips Thysanoptera mouthparts their action and effects of feeding on plant tissue Bulletin of Entomological Research 74 4 663 675 doi 10 1017 S0007485300014048 a b Grimaldi D Shmakov A Fraser N 2004 Mesozoic Thrips and Early Evolution of the Order Thysanoptera Insecta Journal of Paleontology 78 5 941 952 doi 10 1666 0022 3360 2004 078 lt 0941 mtaeeo gt 2 0 co 2 JSTOR 4094919 S2CID 85901347 Mound L A 1997 Thrips as Crop Pests In Lewis T ed Biological diversity CAB International pp 197 215 Thrips Wiki Retrieved 19 February 2017 Li Hu et al 2015 Higher level phylogeny of paraneopteran insects inferred from mitochondrial genome sequences Scientific Reports 5 8527 Bibcode 2015NatSR 5E8527L doi 10 1038 srep08527 PMC 4336943 PMID 25704094 Terry Mark Whiting Michael 2013 Evolution of Thrips Thysanoptera Phylogenetic Patterns and Mitochondrial Genome Evolution Journal of Undergraduate Research a b Buckman Rebecca S Mound Laurence A Whiting Michael F 2012 Phylogeny of thrips Insecta Thysanoptera based on five molecular loci Systematic Entomology 38 1 123 133 doi 10 1111 j 1365 3113 2012 00650 x S2CID 84909610 Mound L A 2011 Order Thysanoptera Haliday 1836 in Zhang Z Q Ed Animal biodiversity An outline of higher level classification and survey of taxonomic richness PDF Zootaxa 3148 201 202 doi 10 11646 zootaxa 3148 1 38 Mound Laurence A 2013 Homologies and Host Plant Specificity Recurrent Problems in the Study of Thrips Florida Entomologist 96 2 318 322 doi 10 1653 024 096 0250 Rugman Jones Paul F Hoddle Mark S Mound Laurence A Stouthamer Richard 2006 Molecular Identification Key for Pest Species of Scirtothrips Thysanoptera Thripidae J Econ Entomol 99 5 1813 1819 doi 10 1093 jee 99 5 1813 PMID 17066817 Cavalleri Adriano Kaminski Lucas A 2014 Two new ectoparasitic species of Aulacothrips Hood 1952 Thysanoptera Heterothripidae associated with ant tended treehoppers Hemiptera Systematic Parasitology 89 3 271 8 doi 10 1007 s11230 014 9526 z PMID 25274260 S2CID 403014 Cavalleri Adriano De Souza Andre R Prezoto Fabio Mound Laurence A 2013 Egg predation within the nests of social wasps a new genus and species of Phlaeothripidae and evolutionary consequences of Thysanoptera invasive behaviour Biological Journal of the Linnean Society 109 2 332 341 doi 10 1111 bij 12057 Tadic M 1957 The Biology of the Codling Moth as the Basis for Its Control Univerzitet U Beogradu a b Kirk W D J 1995 Parker B L Skinner M Lewis T eds Feeding behavior and nutritional requirements Thrips Biology and Management Plenum Press pp 21 29 a b Onion Thrips NCSU Retrieved 23 February 2017 Milne M Walter G H 1997 The significance of prey in the diet of the phytophagous thrips Frankliniella schultzei Ecological Entomology 22 1 74 81 doi 10 1046 j 1365 2311 1997 00034 x S2CID 221682518 Terry I 2001 Thrips the primeval pollinators Thrips and Tospoviruses Proceedings of the 7th Annual Symposium on Thysanoptera 157 162 Sakai S 2001 Thrips pollination of androdioecious Castilla elastica Moraceae in a seasonal tropical forest American Journal of Botany 88 9 1527 1534 doi 10 2307 3558396 JSTOR 3558396 PMID 21669685 Saxena P Vijayaraghavan M R Sarbhoy R K Raizada U 1996 Pollination and gene flow in chillies with Scirtothrips dorsalis as pollen vectors Phytomorphology 46 317 327 Frame Dawn 2003 Generalist flowers biodiversity and florivory implications for angiosperm origins Taxon 52 4 681 5 doi 10 2307 3647343 JSTOR 3647343 Darwin Charles 1892 The effects of cross and self fertilization in the vegetable kingdom D Appleton amp Company p 11 Williams G A Adam P Mound L A 2001 Thrips Thysanoptera pollination in Australian subtropical rainforests with particular reference to pollination of Wilkiea huegeliana Monimiaceae Journal of Natural History 35 1 1 21 doi 10 1080 002229301447853 S2CID 216092358 a b Eliyahu Dorit McCall Andrew C Lauck Marina Trakhtenbrot Ana Bronstein Judith L 2015 Minute pollinators The role of thrips Thysanoptera as pollinators of pointleaf manzanita Arctostaphylos pungens Ericaceae Journal of Pollination Ecology 16 64 71 doi 10 26786 1920 7603 2015 10 PMC 4509684 PMID 26207155 Garcia Fayos Patricio Goldarazena Arturo 2008 The role of thrips in pollination of Arctostaphyllos uva ursi International Journal of Plant Sciences 169 6 776 781 doi 10 1086 588068 S2CID 58888285 Childers C C 1997 Lewis T ed Feeding and oviposition injuries to plants Thrips as Crop Pests CAB International pp 505 538 a b Mound L A 2005 Thysanoptera diversity and interactions Annual Review of Entomology 50 247 269 doi 10 1146 annurev ento 49 061802 123318 PMID 15355240 Bailey S F 1940 The distribution of injurious thrips in the United States Journal of Economic Entomology 33 1 133 136 doi 10 1093 jee 33 1 133 Ananthakrishnan T N 1993 Bionomics of Thrips Annual Review of Entomology 38 71 92 doi 10 1146 annurev en 38 010193 000443 Thrips tabaci onion thrips Invasive Species Compendium CABI Retrieved 24 February 2017 Jorge Nina Castro Cavalleri Adriano Bedetti Cibele Souza Isaias Rosy Mary Dos Santos 2016 A new leaf galling Holopothrips Thysanoptera Phlaeothripidae and the structural alterations on Myrcia retorta Myrtaceae Zootaxa 4200 1 174 180 doi 10 11646 zootaxa 4200 1 8 ISSN 1175 5334 PMID 27988645 Mound Laurence 2014 Austral Thysanoptera 100 years of progress Australian Journal of Entomology 53 1 18 25 doi 10 1111 aen 12054 S2CID 85793869 Blum M S 1991 Parker B L Skinner M Lewis T eds Towards understanding Thysanoptera Chemical ecology of the Thysanoptera Proceedings of the International Conference on Thrips USDA Technical Report NE 147 95 108 a b Howard Dennis F Blum Murray S Fales Henry M 1983 Defense in Thrips Forbidding Fruitiness of a Lactone Science 220 4594 335 336 Bibcode 1983Sci 220 335H doi 10 1126 science 220 4594 335 ISSN 0036 8075 PMID 17732921 S2CID 24856539 Tschuch G Lindemann P Moritz G 2002 Mound L A Marullo R eds Chemical defence in thrips Thrips and Tospoviruses Proceedings of the 7th International Symposium on Thysanoptera 277 278 Milne M Walter G H Milne J R 2002 Mating Aggregations and Mating Success in the Flower Thrips Frankliniella schultzei Thysanoptera Thripidae and a Possible Role for Pheromones Journal of Insect Behavior 15 3 351 368 doi 10 1023 A 1016265109231 S2CID 23545048 Kranz B D Schwarz M P Mound L A Crespi B J 1999 Social biology and sex ratios of the eusocial gall inducing thrips Kladothrips hamiltoni Ecological Entomology 24 4 432 442 doi 10 1046 j 1365 2311 1999 00207 x S2CID 83180900 Kranz Brenda D Schwarz Michael P Wills Taryn E Chapman Thomas W Morris David C Crespi Bernard J 2001 A fully reproductive fighting morph in a soldier clade of gall inducing thrips Oncothrips morrisi Behavioral Ecology and Sociobiology 50 2 151 161 doi 10 1007 s002650100347 JSTOR 4601948 S2CID 38152512 Crespi B J Mound L A 1997 Ecology and evolution of social behaviour among Australian gall thrips and their allies In Choe J C Crespi B J eds The evolution of social behaviour of insects and arachnids Cambridge University Press pp 166 180 ISBN 978 0 521 58977 2 Chapman T W Crespi B J 1998 High relatedness and inbreeding in two species of haplodiploid eusocial thrips Insecta Thysanoptera revealed by microsatellite analysis Behavioral Ecology and Sociobiology 43 4 301 306 doi 10 1007 s002650050495 JSTOR 4601521 S2CID 32909187 Kranz Brenda D Schwarz Michael P Morris David C Crespi Bernard J 2002 Life history of Kladothrips ellobus and Oncothrips rodwayi insight into the origin and loss of soldiers in gall inducing thrips Ecological Entomology 27 1 49 57 doi 10 1046 j 1365 2311 2002 0380a x S2CID 85097661 Weis Fogh T 1973 Quick estimates of flight fitness in hovering animals including novel mechanisms for lift production Journal of Experimental Biology 59 169 230 doi 10 1242 jeb 59 1 169 Sane Sanjay P 2003 The aerodynamics of insect flight PDF The Journal of Experimental Biology 206 23 4191 4208 doi 10 1242 jeb 00663 PMID 14581590 S2CID 17453426 Wang Z Jane 2005 Dissecting Insect Flight PDF Annual Review of Fluid Mechanics 37 1 183 210 Bibcode 2005AnRFM 37 183W doi 10 1146 annurev fluid 36 050802 121940 Lighthill M J 1973 On the Weis Fogh mechanism of lift generation Journal of Fluid Mechanics 60 1 17 Bibcode 1973JFM 60 1L doi 10 1017 s0022112073000017 S2CID 123051925 Fedor Peter Doricova Martina Dubovsky Michal Kisel ak Jozef Zvarik Milan 2019 08 15 Cereal pests among nest parasites the story of barley thrips Limothrips denticornis Haliday Thysanoptera Thripidae Entomologica Fennica 21 4 221 231 doi 10 33338 ef 84532 ISSN 2489 4966 S2CID 82549305 Ortega Jimenez Victor Manuel Arriaga Ramirez Sarahi Dudley Robert 2016 Meniscus ascent by thrips Thysanoptera Biology Letters 12 9 20160279 doi 10 1098 rsbl 2016 0279 PMC 5046919 PMID 27624795 a b Gullan P J Cranston P S 2010 The Insects An Outline of Entomology 4th ed Wiley p 511 ISBN 978 1 118 84615 5 a b Smith Tina M 2015 Western Flower Thrips Management and Tospoviruses University of Massachusetts Amherst Retrieved 21 February 2017 Capinera John L 2001 Handbook of Vegetable Pests Gulf p 538 ISBN 978 0 12 158861 8 a b c van der Kooi C J Schwander T 2014 Evolution of asexuality via different mechanisms in grass thrips Thysanoptera Aptinothrips PDF Evolution 68 7 1883 1893 doi 10 1111 evo 12402 PMID 24627993 S2CID 14853526 Katlav Alihan Cook James M Riegler Markus 2020 Houslay Thomas ed Egg size mediated sex allocation and mating regulated reproductive investment in a haplodiploid thrips species Functional Ecology 35 2 485 498 doi 10 1111 1365 2435 13724 ISSN 0269 8463 S2CID 229397678 Kumm S Moritz G 2008 First detection of Wolbachia in arrhenotokous populations of thrips species Thysanoptera Thripidae and Phlaeothripidae and its role in reproduction Environmental Entomology 37 6 1422 8 doi 10 1603 0046 225X 37 6 1422 PMID 19161685 S2CID 22128201 Stannard L J 1968 The thrips or Thysanoptera of Illinois Illinois Natural History Survey 21 1 4 215 552 doi 10 21900 j inhs v29 166 Nault L R 1997 Arthropod transmission of plant viruses a new synthesis Annals of the Entomological Society of America 90 5 521 541 doi 10 1093 aesa 90 5 521 Mound L A 2001 So many thrips so few tospoviruses Thrips and Tospoviruses Proceedings of the 7th International Symposium on Thysanoptera 15 18 Morse Joseph G Hoddle Mark S 2006 Invasion Biology of Thrips Annual Review of Entomology 51 67 89 doi 10 1146 annurev ento 51 110104 151044 PMID 16332204 S2CID 14430622 Jones David R 2005 Plant Viruses Transmitted by Thrips European Journal of Plant Pathology 113 2 119 157 doi 10 1007 s10658 005 2334 1 ISSN 0929 1873 S2CID 6412752 Carlton James 2003 Invasive Species Vectors And Management Strategies Island Press pp 54 55 ISBN 978 1 61091 153 5 Childers C C Beshear R J Frantz G Nelms M 2005 A review of thrips species biting man including records in Florida and Georgia between 1986 1997 Florida Entomologist 88 4 447 451 doi 10 1653 0015 4040 2005 88 447 AROTSB 2 0 CO 2 Kivett Jessica M Cloyd Raymond A Bello Nora M 2015 Insecticide rotation programs with entomopathogenic organisms for suppression of western flower thrips Thysanoptera Thripidae adult populations under greenhouse conditions Journal of Economic Entomology 108 4 1936 1946 doi 10 1093 jee tov155 ISSN 0022 0493 PMID 26470338 S2CID 205163917 Hoddle Mark Western flower thrips in greenhouses a review of its biological control and other methods University of California Riverside Retrieved 21 February 2017 Katai Yusuke Ishikawa Ryusuke Doi Makoto Masui Shinichi 2015 Efficacy of red LED irradiation for controlling Thrips palmi in greenhouse melon cultivation Japanese Journal of Applied Entomology and Zoology 59 1 1 6 doi 10 1303 jjaez 2015 1 External links Edit Wikimedia Commons has media related to Thysanoptera Wikispecies has information related to Thysanoptera Thrips of the World checklist Thrips species wiki Thrips images from the Pests and Diseases Image Library PaDIL of Australia University of California Pest Management Guidelines for Thrips University of California Thrips Identification CISR Center for Invasive Species Research Fact Sheets Avocado Thrips Western Flower Thrips Myoporum Thrips Thrips links on the UF IFAS Featured Creatures Web site Frankliniella schultzei common blossom thrips Thripidae Heliothrips haemorrhoidalis greenhouse thrips Thripidae Scirtothrips dorsalis chilli thrips Thripidae Selenothrips rubrocinctus redbanded thrips Thripidae Thrips palmi melon thrips Thripidae Thrips simplex gladiolus thrips Thripidae Retrieved from https en wikipedia org w index php title Thrips amp oldid 1147672604, wikipedia, wiki, book, books, library,

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