Tokunagayusurika akamusi

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Tokunagayusurika akamusi
Chironomidae Non-biting Midge.jpg
Scientific classification
Kingdom:
Animalia
Phylum:
Arthropoda
Class:
Insecta
Order:
Diptera
Suborder:
Nematocera
Infraorder:
Culicomorpha
Superfamily:
Chironomoidea
Family:
Chironomidae
Genus:
Tokunagayusurika
Species:
T. akamusi
Binomial name
Tokunagayusurika akamusi
(Tokunaga 1938)
Mosquito comparison Mosquito Tasmania.jpg
Mosquito comparison

Tokunagayusurika akamusi is a midge fly species of the family Chironomidae , commonly called "nonbiting midges" or "lake flies."

Contents

Discovered by Tokunaga in 1938, the species is common to eutrophic lakes in Japan. [1] The midge family is very similar to the mosquito family in morphology, except that they do not feed on human blood.

The larvae are commonly called bloodworms and are used as fishing bait in Japan. [2] Their larvae are scavengers for organic materials at the bottom of freshwater bodies. Adult midges rarely feed since they only emerge during fall and live up to a few weeks. As adult male midges emerge, they form large swarms that make dance-like movements in the air to facilitate mating, so as to attract females to approach the swarms. Such swarming behavior helps facilitate mating, but is also a severe nuisance to Japanese local residents, as well as tourists in areas close to eutrophic lakes or polluted water bodies in Japan.

Taxonomy

Tokunagayusurika akamusi is in the family of Chironomidae and in the order Diptera . The most ancient families of flies are midges, mosquitoes, and others in their broad subgroup of flies. The family name, Chironomidae, is derived from the Greek word for "pantomimist" which describes someone who pantomimes, for the fly's typical posture of having its forelegs held out in front of its body. [3] More than 7,300 species in this family have been described scientifically. [3]

Description

Adult T. akamusi has a body length of 8 to 9.5 millimetres (0.31 to 0.37 in), and is dark grey to black in color. [2] As true flies, the species has only one pair of wings. Adult midges look very similar to mosquitoes in that their bodies are slender and dainty. Both species have long, narrow wings and long, thin legs. Male midges often have feathery antennae which sense the high-pitched sounds made by female wings. However, it is possible to distinguish them from mosquitos because they do not have scales on their wings like mosquitoes do, and they tend to hold their first pair of legs forward when at rest, as opposed to outward as mosquitoes do. Additionally, midges do not bite, corresponding to the name nonbiting midge. [3]

Distribution and habitat

Lake Biwa, where midge larvae can be found. Lake Biwa.jpg
Lake Biwa, where midge larvae can be found.

Midge larvae live at the bottom of lakes, ponds, and other freshwater bodies. They usually use fine sediment and mucus to construct tubes to live in. Adult midges are common near freshwater bodies, as females lay eggs and new generations of larvae live and emerge from there. [3] In Japan, adults generally emerge during October and November. [2] However, the time of emergence also varies, depending on the lake and its water temperature. For instance, at the shores of Lake Biwa, the largest freshwater lake in Japan, midges emerge from November to early December. [4]

Life History

The life history of T. akamusi consists of four stages: egg, larva, and adult. Most of its lifetime is spent in the larval stage at the bottom of freshwater bodies, which spans from 1 to 3 years. Midge larvae are commonly called bloodworms, because of their red color from the hemoglobin molecules inside their long, thin, cylindrical bodies. The body is usually curved and has segments and a distinctly separated head, which is typically of a darker color than the rest of the body. [5] They are often used as baits in fishing. When they emerge as adults, they usually only live for a few weeks. [3] The species typically emerges in autumn, and its emergence depends on the temperature of the bottom water in the lakes. It usually takes place when the temperature of the bottom water is in the range of 10 to 18 degrees Celsius. The species is once studied in Lake Suwa and Lake Kasumigaura, where 99 percent of cumulative emergence took place in between the temperature 10.2 and 14.2 degrees Celsius and 1 percent cumulative emergence in between 15.3 and 18.1 degrees Celsius. The study has concluded that a decrease in bottom water temperature could trigger the emergence of T. akamusi and a further decrease below 10 degrees Celsius could terminate the pupation. [6]

Bloodworm: the larval stage of a midge fly. Bloodworm.jpg
Bloodworm: the larval stage of a midge fly.

Food resources

Midge larvae are scavengers and eat a variety of organic matter. Adult midges, however, rarely take in anything but moisture (honeydew, flower nectar, etc.). They have short proboscis, unlike mosquitoes, and do not bite humans. [3]

Mating

The mating system of T. akamusi consists of two alternative tactics–one is swarming and the other is ground searching. Swarming is when males wait for mates in an aerial swarm in the air. Ground searching is when males actively search for mates on vegetation. [7] A study on males’ wing length and their mating tactics has found that large males tended to form groups in swarms, where the larger males among the swarming males mated with more females. Here, male body sizes are determined by their longer wing lengths. Small males, however, tended to find mates through ground searching, and this pattern seemed stronger when large males already formed groups in swarming. The study also looked at the wing asymmetry in males and found that males who have extremely asymmetric wings (wings of very different lengths) were less successful at mating. [7] When male midges search for females, their antennae respond to the unique frequency of the sound made by female wingbeats. Observers have reported that singing a particular musical note, clapping hands, or making certain sudden noises can cause an entire swarm of these flies to suddenly leap upward or closer to the sound, or wild disarray in their collective movements. [3]

Swarming

Swarming Behavior Swarm of midges Lacreek NWR (12842933365).jpg
Swarming Behavior

Male midges are famous for aggregating in big swarms that “dance” in the air. Such cloud-like swarms often form in early evening when the sun is getting low, at the tip of a bush, on a hilltop, over a pool of water, or even sometimes above a person. The forming of such swarms is not out of instinct, but an adaptive behavior – a “consensus” – between the individuals within the swarms. There is also a pattern within each swarm that explains the “dancing.” Each individual midge in the swarm flies to the farthest upwind edge of the marker zone, and then slowly flows to the downwind side, followed by flying back to the upwind edge. Together, it looks like all individual midges are tied to the marker, “like tiny balloons.” [3] Swarming serves multiple purposes, including the facilitation of mating. However, it is also suggested that swarming is a ritual, because there is rarely any male midge by itself and not in a swarm. This could have formed due to the benefit of lowering inbreeding by having males of various genes gathering in one spot. [3]

Wing movements

Certain "gnat-like midges" beat their wings more than 1,000 cycles per second (more than 1,000 Hz), making them the fastest wingbeats in the world. However, these "midges" are in the genus of Forcipomyia , commonly called biting midges. Within the common midge family, on the other hand, 650 and 700 Hz sets the general range of wingbeat frequencies. Though slower than biting midges, their wing movements are still extremely fast. Such wing movements, hovering, and other aerodynamic feats are only possible because of the flies' asynchronous muscle systems. Their muscle systems are asynchronous because there is not a direct correlation between each muscle contraction and a wing flap. Instead, the muscle contractions cause changes in the shape of the thorax of the midges, which facilitates the extremely fast movements of their wings. [3]

Enemies

A large variety of animals feed on midge larvae and adults, making midges prey to these animals. One example of a midge enemy is the dragonfly, which often flies repeatedly through midge swarms to capture midges for nutrients. [3]

Genomes

Hemoglobin Hemoglobin 1hho.gif
Hemoglobin

There have been several extensive studies on the hemoglobin of the aquatic midge 4th-instar larvae as a potential biomarker for monitoring environmental contaminants. [8] In T. akamusi, the hemoglobin from 4th-instar larva consists of eleven individual components (IA, IB, II, III, IV, V, VIA, VIB, VII, VIII, IX) on a DEAE-cellulose column. The eleven components can be divided into two different types based on their spectroscopic features: normal type (N-type) and low type (L-type). The most distinctive difference between the two seems to be the presence or absence of the distal (E7) histidine residue, which is important to the stability of the bound dioxygen. The homology test for 40 N-terminal amino acid residues of all eleven components also demonstrates that T. akamusi hemoglobin consists of two different clusters. This further shows a very early separation of the N-type and L-type in the phylogenetic tree. [1]

Interactions with humans

Fishing baits

Bloodworms (midge larvae) can be used as fishing baits, and are widely sold on markets in Japan. [2]

Midge allergy

Because of the distinctive mating system that male midges adopt, midges form large swarms in the air whenever they emerge during the mating season. Their emergence lines up with seasonal human allergic reactions, such as asthma and allergic rhinitis and has thus been suspected to cause seasonal human allergic reactions. [9]

Nuisance

Tokunagayusurika akamusi midges are attracted to lights, both indoor and outside. They emerge from eutrophic lakes, as well as polluted water bodies in Japan. According to multiple studies in Japan, they have become intolerable because they pose a serious nuisance and hurt the economies. [10] In the Lake Suwa area, massive swarms of adult midges of T. akamusi frequently occur after they emerge, and cause problems in the daily life of local residents and for the tourists as well. In the area, the emergence peaks each year around mid October. They also form swarms around and often land on windows, walls, and the laundry people have hung outside. They also swarm around wherever food is displayed outside, including food stands, restaurants, and grocery stores. Because of the problems they cause to the residents, the government often receives many complaints and are tasked with finding solutions. [2]

Related Research Articles

Fly Order of insects

Flies are insects of the order Diptera, the name being derived from the Greek δι- di- "two", and πτερόν pteron "wing". Insects of this order use only a single pair of wings to fly, the hindwings having evolved into advanced mechanosensory organs known as halteres, which act as high-speed sensors of rotational movement and allow dipterans to perform advanced aerobatics. Diptera is a large order containing an estimated 1,000,000 species including horse-flies, crane flies, hoverflies and others, although only about 125,000 species have been described.

Crane fly Family of flies

Crane fly is a common name referring to any member of the insect family Tipulidae. Cylindrotominae, Limoniinae, and Pediciinae have been ranked as subfamilies of Tipulidae by most authors, though occasionally elevated to family rank. In the most recent classifications, only Pediciidae is now ranked as a separate family, due to considerations of paraphyly. In colloquial speech, crane flies are sometimes known as "mosquito hawks" or "daddy longlegs",. The larvae of crane flies are known commonly as leatherjackets.

Midge Index of animals with the same common name

A midge is any small fly, including species in several families of non-mosquito Nematoceran Diptera. Midges are found on practically every land area outside permanently arid deserts and the frigid zones. Some midges, such as many Phlebotominae and Simuliidae, are vectors of various diseases. Many others play useful roles as prey items for insectivores, such as various frogs and swallows. Others are important as detritivores, and form part of various nutrient cycles. The habits of midges vary greatly from species to species, though within any particular family, midges commonly have similar ecological roles.

<i>Leptoconops torrens</i> Species of fly

Leptoconops torrens is a species of small biting flies in the no-see-um family Ceratopogonidae. They were first mentioned in writing by Charles Henry Tyler Townsend in 1893. The name Leptoconops carteri is a junior synonym of L. torrens. They are prevalent in the southwestern and southeastern areas of the United States. In early stages of life, L. torrens flies dwell in soil, then emerge to feed and breed as fully developed adults.

Nematocera Suborder of flies

The Nematocera are a suborder of elongated flies with thin, segmented antennae and mostly aquatic larvae. Major families in the suborder include the mosquitoes, crane flies, gnats, black flies, and a group of families described as midges.

Chironomidae Family of flies

The Chironomidae comprise a family of nematoceran flies with a global distribution. They are closely related to the Ceratopogonidae, Simuliidae, and Thaumaleidae. Many species superficially resemble mosquitoes, but they lack the wing scales and elongated mouthparts of the Culicidae. An example of mosquito-resembling species is Tokunagayusurika akamusi.

Chaoboridae Family of flies

Chaoboridae, commonly known as phantom midges or glassworms, is a family of fairly common midges with a cosmopolitan distribution. They are closely related to the Corethrellidae and Chironomidae; the adults are differentiated through peculiarities in wing venation.

Bibionidae Family of flies

Bibionidae is a family of flies (Diptera) containing approximately 650–700 species worldwide.

<i>Chironomus plumosus</i> Species of fly

Chironomus plumosus, also known as the buzzer midge, is a species of nonbiting midge (Chironomidae) that occurs throughout areas in the Northern Hemisphere.

Halocladius is a genus of halophilic, non-biting midges in the subfamily Orthocladiinae of the bloodworm family (Chironomidae). They inhabit seashores and saline inland waters of the Northern Hemisphere. Wing length is 1.5–3.5 mm (0.06–0.14 in). Two subgenera have been described: Halocladius and Psammocladius.

Stictochironomus is a genus of non-biting midges in the subfamily Chironominae of the bloodworm family Chironomidae. Members of this genus often have strongly marked wings and legs. The larvae of these midges may also have distinct dark patterns on the dorsal side of the head capsule. They live in sand and other sediments in a variety of fresh water habitats in densities of several hundred per square meter.

Zavrelia is a genus of European non-biting midges in the subfamily Chironominae of the bloodworm family Chironomidae.

Chloroperlidae Family of stoneflies

Chloroperlidae are a family of stoneflies, commonly known as green stoneflies, with more than 200 species and 22 genera. They appear green to yellow in colour, and are popularly used among fisherman as bait for trout fishing. Green stoneflies live in the benthic zone of the cold streams and rivers of five continents and four zoogeographical regions, emerging from the water to live in the riparian zone as adults. They are sensitive to pollutants, making them an indicator species for determining the quality of water bodies. Chloroperlidae are hemimetabolous, having no pupal stage, but instead hatch from eggs as nymphs and mature directly into adults. They are omnivorous, feeding on small organisms and plant particles, and become more carnivorous as they mature. The classification of Chloroperlidae is contested, with some believing that they should be considered as members of different orders, as opposed to the order Plecoptera that they currently belong to.

Diptera is an order of winged insects commonly known as flies. Diptera, which are one of the most successful groups of organisms on Earth, are very diverse biologically. None are truly marine but they occupy virtually every terrestrial niche. Many have co-evolved in association with plants and animals. The Diptera are a very significant group in the decomposition and degeneration of plant and animal matter, are instrumental in the breakdown and release of nutrients back into the soil, and whose larvae supplement the diet of higher agrarian organisms. They are also an important component in food chains.

<i>Pontomyia</i> Genus of flies

Pontomyia is a genus of flightless marine midges belonging to the subfamily Chironominae in the Chironomidae family. Insects in marine environments are extremely rare while flightlessness, extreme sexual dimorphism, and an extremely short adult life span contribute to making these midges unusual among insects. They are known from the shores of islands in the Indian, Atlantic and Pacific Oceans.

Chironomus riparius, also known as Chironomus thummi and commonly known as the harlequin fly, is a species of non-biting midge. Their larvae are known by the common name of blood worm due to their red colouration. It is common in both North America and Europe. The species was described in 1804 by Johann Wilhelm Meigen. C. riparius has been used extensively as a model for genome structure analysis in insects and is also used in toxicology tests and functional developmental genetic studies. Both their adult and larval forms have been implicated as disease vectors but are also an important part of freshwater food chains.

Gnat Any of many species of tiny flying insects in the dipterid suborder Nematocera

A gnat is any of many species of tiny flying insects in the dipterid suborder Nematocera, especially those in the families Mycetophilidae, Anisopodidae and Sciaridae. They can be both biting and non-biting. Most often they fly in large numbers, called clouds. "Gnat" is a loose descriptive category rather than a phylogenetic or other technical term, so there is no scientific consensus on what constitutes a gnat. Some entomologists consider only non-biting flies to be gnats. Certain universities and institutes also distinguish eye gnats: the Smithsonian Institution describes them as "non-biting flies, no bigger than a few grains of salt, ... attracted to fluids secreted by your eyes".

<i>Chironomus zealandicus</i> Species of midge

Chironomus zealandicus, commonly known as the New Zealand midge, common midge, or non-biting midge, is an insect of the Chironomidae family that is endemic to New Zealand. The worm-like larvae are known to fisherman and have a common name of blood worm due to their red color and elongated blood gills.

<i>Bezzia nobilis</i> Species of fly

Bezzia nobilis is a species of biting midges in the family Ceratopogonidae. It is widely considered one of the most common Bezzia species; it is found in Eurasian regions, all over the United States, Central America, and even into South American countries like Brazil. B. nobilis seem to prefer aquatic environments; they are commonly observed in stagnant water pools in Eurasia regions and marshes in the southern United States. Adults of this species are easily distinguished by their black and yellow striped legs. Pupae are recognized by their brown bodies, abdominal spines, and respiratory horns. B. nobilis larvae are distinguished by brown heads and white bodies. Little information is known on their life cycle or mating habits. B. nobilis is a predatory species. While some research suggests they mainly feed on larvae of other insect species, experiments suggest they prefer immobile, easy prey such as dead adult flies, bacteria, and protozoa.

Chironomus annularius is a species of non-biting midge in the family Chironomidae. It is usually found in regions with bodies of fresh water but can be found in almost every environment. It tends to form "hotspots" around specific areas. The species is distinguished by the size of its chromosomes and the lack of a proboscis.

References

  1. 1 2 Fukuda, Mitsunori; Takagi, Takashi; Shikama, Keiji (1993-07-11). "Polymorphic hemoglobin from a midge larva (Tokunagayusurika akamusi) can be divided into two different types". Biochimica et Biophysica Acta (BBA) - General Subjects. 1157 (3): 185–191. doi:10.1016/0304-4165(93)90063-E. ISSN   0304-4165. PMID   8507654.
  2. 1 2 3 4 5 "Tokunagayusurika akamusiはどんな虫?Weblio辞書". www.weblio.jp. Retrieved 2019-10-26.
  3. 1 2 3 4 5 6 7 8 9 10 11 "Midges". MDC Discover Nature. Retrieved 2019-10-26.
  4. Kon, Masahiro; Otsuka, Kimio; Hidaka, Toshitaka (1986-06-01). "Mating system of Tokunagayusurika akamusi (Diptera: Chironomidae): I. Copulation in the air by swarming and on the ground by searching". Journal of Ethology. 4 (1): 49–58. doi:10.1007/BF02348252. ISSN   1439-5444.
  5. "Midge Fly Larvae". MDC Discover Nature. Retrieved 2019-10-26.
  6. Toshio Iwakuna; Yoshio Sugaya; Masayuki Yasuno (1989). "Dependence of the Autumn Emergence of Tokunagayusurika akamusi (Diptera: Chironomidae) on Water Temperature". Japanese Journal of Limnology. 50, 4: 281–288.
  7. 1 2 Takamura, K. (1999-09-01). "Wing length and asymmetry of male Tokunagayusurika akamusi chironomid midges using alternative mating tactics". Behavioral Ecology. 10 (5): 498–503. doi: 10.1093/beheco/10.5.498 .
  8. Ha, Mi-Hee; Choi, Jinhee (2008-05-01). "Effects of environmental contaminants on hemoglobin of larvae of aquatic midge, Chironomus riparius (Diptera: Chironomidae): A potential biomarker for ecotoxicity monitoring". Chemosphere. 71 (10): 1928–1936. Bibcode:2008Chmsp..71.1928H. doi:10.1016/j.chemosphere.2008.01.018. ISSN   0045-6535. PMID   18328532.
  9. Cranston, P. S. (1983). "Chironomid haemoglobins: Their detection and role in allergy to midges in the Sudan and elsewhere" (PDF). Memoirs of the Entomological Society of America: 71–87.
  10. Hirabayashi, Kimio (1991). "Studies on the Massive Flights of Chironomid Midges (Diptera: Chironomidae) as Nuisance Insects and Plans for their Control in the Lake Suwa Area, Central Japan. 1. Occurrence of massive flights of Tokunagayusurika akamusi". Nippon Eiseigaku Zasshi (Japanese Journal of Hygiene). 46 (2): 652–661. doi: 10.1265/jjh.46.652 . ISSN   0021-5082. PMID   1890773.
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