Neosomy

Last updated May 19, 2024

Neosomy is the formation of new external structure in an active stage of an invertebrate, in a taxon that normally only changes during moulting. It occurs in nematodes and a wide range of arthropods, especially those with symbiotic lifestyles.^[1]

Examples

Acari

Larvae of some chiggers can increase in size massively via neosomy, such as Vatacarus (from sea kraits) enlarging by 1500 times or more, and Riedlinia (from bats) by up to 750 times.^[1]

Other mites with neosomatic larvae include Trombidium , Eutrombidium and the aquatic Eylais and Hydrachna .^[3]

In ticks of family Ixodidae, the larvae, nymphs and adult females show neosomy. This involves an initial period where the tick thickens its cuticle and slowly gains weight, then a rapid engorgement (increasing the tick's size by as much as 100 times) that returns the cuticle to its original thickness. In the soft ticks (Argasidae), neosomy usually occurs in larvae only.^[1]

Insects

Females of some flea species in superfamilies Pulicoidea, Vermipsylloidea and Malacopsylloidea are neosomatic. For example, an adult female Tunga monositus starts out at 1 mm long and, after feeding and growing, increases in volume by 1000 times, becomes circular in shape and forms anterior lobes that the head is retracted between (for protection).^[4]

Similar to the aforementioned fleas, bat flies of genus Ascodipteron have females which attach to a host, then lose their limbs and transform into neosomes, with the head and thorax withdrawn into a swollen abdomen.^[5]

Neosomatic termite queen K8085-21.jpg — Neosomatic termite queen

Neosomy occurs in queen termites and in queen ants of certain species. Queen termites include the largest neosomes among terrestrial arthropods, with some exceeding 12.5 cm in length.^[1]

Termite-associated species of phorid flies and rove beetles have neosomatic females. In rove beetles, some genera have neosomatic males as well as females, and neosomy in some genera results in an abdomen that resembles a termite.^[1]

Crustaceans

Parasitic copepods, such as Lernaea , Collipravus , and Lernaeenicus , exhibit neosomy. In some of the more extreme instances, neosomes vary greatly in shape within a species.^[1]

Purposes

Neosomy is a mechanism that allows a symbiote to better exploit abundant food. It increases the reproductive potential of females. For example, a female ixodid tick can usually lay thousands of eggs at once, compared to the few hundred eggs of a female non-neosomatic argasid.^[1]

There are also other possible purposes. In Termitomimus and Nasutimimus rove beetles, the abdomen is similar in shape to a termite nymph and may be used in tactile mimicry.^[6]

Related Research Articles

Ecdysis is the moulting of the cuticle in many invertebrates of the clade Ecdysozoa. Since the cuticle of these animals typically forms a largely inelastic exoskeleton, it is shed during growth and a new, larger covering is formed. The remnants of the old, empty exoskeleton are called exuviae.

Ticks are parasitic arachnids of the order Ixodida. They are part of the mite superorder Parasitiformes. Adult ticks are approximately 3 to 5 mm in length depending on age, sex, species, and "fullness". Ticks are external parasites, living by feeding on the blood of mammals, birds, and sometimes reptiles and amphibians. The timing of the origin of ticks is uncertain, though the oldest known tick fossils are from the Cretaceous period, around 100 million years old. Ticks are widely distributed around the world, especially in warm, humid climates.

Pseudoscorpions, also known as false scorpions or book scorpions, are small, scorpion-like arachnids belonging to the order Pseudoscorpiones, also known as Pseudoscorpionida or Chelonethida.

Mites are small arachnids. Mites span two large orders of arachnids, the Acariformes and the Parasitiformes, which were historically grouped together in the subclass Acari. However, most recent genetic analyses do not recover the two as each other's closest relative within Arachnida, rendering the group non-monophyletic. Most mites are tiny, less than 1 mm (0.04 in) in length, and have a simple, unsegmented body plan. The small size of most species makes them easily overlooked; some species live in water, many live in soil as decomposers, others live on plants, sometimes creating galls, while others are predators or parasites. This last type includes the commercially destructive Varroa parasite of honey bees, as well as scabies mites of humans. Most species are harmless to humans, but a few are associated with allergies or may transmit diseases.

The rove beetles are a family (Staphylinidae) of beetles, primarily distinguished by their short elytra that typically leave more than half of their abdominal segments exposed. With over 66,000 species in thousands of genera, the group is the largest family in the beetle order, and one of the largest families of organisms. It is an ancient group, with fossilized rove beetles known from the Triassic, 200 million years ago, and possibly even earlier if the genus Leehermania proves to be a member of this family. They are an ecologically and morphologically diverse group of beetles, and commonly encountered in terrestrial ecosystems.

Histeridae is a family of beetles commonly known as clown beetles or hister beetles. This very diverse group of beetles contains 3,900 species found worldwide. They can be easily identified by their shortened elytra that leaves two of the seven tergites exposed, and their geniculate (elbowed) antennae with clubbed ends. These predatory feeders are most active at night and will fake death if they feel threatened. This family of beetles will occupy almost any kind of niche throughout the world. Hister beetles have proved useful during forensic investigations to help in time of death estimation. Also, certain species are used in the control of livestock pests that infest dung and to control houseflies. Because they are predacious and will even eat other hister beetles, they must be isolated when collected.

An allomone is a type of semiochemical produced and released by an individual of one species that affects the behaviour of a member of another species to the benefit of the originator but not the receiver. Production of allomones is a common form of defense against predators, particularly by plant species against insect herbivores. In addition to defense, allomones are also used by organisms to obtain their prey or to hinder any surrounding competitors.

<span class="mw-page-title-main">Scenopinidae</span> Family of flies

The Scenopinidae or window flies are a small family of flies (Diptera), distributed worldwide. In buildings, they are often taken at windows, hence the common name window flies.

Ixodes ricinus, the castor bean tick, is a chiefly European species of hard-bodied tick. It may reach a length of 11 mm (0.43 in) when engorged with a blood meal, and can transmit both bacterial and viral pathogens such as the causative agents of Lyme disease and tick-borne encephalitis.

Arthropods are covered with a tough, resilient integument, cuticle or exoskeleton of chitin. Generally the exoskeleton will have thickened areas in which the chitin is reinforced or stiffened by materials such as minerals or hardened proteins. This happens in parts of the body where there is a need for rigidity or elasticity. Typically the mineral crystals, mainly calcium carbonate, are deposited among the chitin and protein molecules in a process called biomineralization. The crystals and fibres interpenetrate and reinforce each other, the minerals supplying the hardness and resistance to compression, while the chitin supplies the tensile strength. Biomineralization occurs mainly in crustaceans. In insects and arachnids, the main reinforcing materials are various proteins hardened by linking the fibres in processes called sclerotisation and the hardened proteins are called sclerotin. The dorsal tergum, ventral sternum, and the lateral pleura form the hardened plates or sclerites of a typical body segment.

Insect morphology is the study and description of the physical form of insects. The terminology used to describe insects is similar to that used for other arthropods due to their shared evolutionary history. Three physical features separate insects from other arthropods: they have a body divided into three regions, three pairs of legs, and mouthparts located outside of the head capsule. This position of the mouthparts divides them from their closest relatives, the non-insect hexapods, which include Protura, Diplura, and Collembola.

Parasitengona is a group of mites, variously ranked as a hyporder or a cohort, between the taxonomic ranks of order and family.

Hydrachnidia, also known as "water mites", Hydrachnidiae, Hydracarina or Hydrachnellae, are among the most abundant and diverse groups of benthic arthropods, composed of 6,000 described species from 57 families. As water mites of Africa, Asia, and South America have not been well-studied, the numbers are likely to be far greater. Other taxa of parasitengone mites include species with semi-aquatic habits, but only the Hydracarina are properly subaquatic. Water mites follow the general Parasitengona life cycle: active larva, inactive (calyptostasic) protonymph, active deutonymph, inactive tritonymph and active adult. Usually, larvae are parasites, while deutonymphs and adults are predators.

In the 10th edition of Systema Naturae of 1758–1759, Carl Linnaeus classified the arthropods, including insects, arachnids and crustaceans, among his class "Insecta". He described the Insecta as:

A very numerous and various class consisting of small animals, breathing through lateral spiracles, armed on all sides with a bony skin, or covered with hair; furnished with many feet, and moveable antennae, which project from the head, and are the probable instruments of sensation.

Phoresis or phoresy is a temporary commensalistic relationship when an organism attaches itself to a host organism solely for travel. It has been seen in ticks and mites since the 18th century, and in fossils 320 million years old. It is not restricted to arthropods or animals; plants with seeds that disperse by attaching themselves to animals are also considered to be phoretic.

Physogastrism or physogastry is a characteristic of certain arthropods, where the abdomen is greatly enlarged and membranous. The most common examples are the "queens" of certain species of eusocial insects such as termites, bees and ants, in which the abdomen swells in order to hold enlarged ovaries, thus increasing fecundity. This means that the queen has the ability to hold more and produce more eggs at one time. Physogastric queens produce an enormous number of eggs which can account for a significant amount of their body weight. In the termite species Macrotermes subhyalinus, eggs can make up a third of their body weight, and a 15-gram queen can produce up to 30 eggs per minute. The physogastric queens' egg production is supported by oocyte proteins supplied by the "queen body fat."

Acarophenacidae is a family of mites in the order Trombidiformes that are egg parasitoids and ectoparasites of beetles or thrips. It contains eight genera and around 40 species.

Mites are small crawling animals related to ticks and spiders. Most mites are free-living and harmless. Other mites are parasitic, and those that infest livestock animals cause many diseases that are widespread, reduce production and profit for farmers, and are expensive to control.

Symphiles are insects or other organisms which live as welcome guests in the nest of a social insect by which they are fed and guarded. The relationship between the symphile and host may be symbiotic, inquiline or parasitic.

References

1 2 3 4 5 6 7 8 Audy, J. Ralph; Radovsky, F. J.; Vercammen-Grandjean, P. H. (1972-12-20). "Neosomy: Radical Intrastadial Metamorphosis Associated With Arthropod Symbioses". Journal of Medical Entomology. 9 (6): 487–494. doi:10.1093/jmedent/9.6.487. ISSN 1938-2928. PMID 4654678.
↑ Radovsky, Frank J. (2009), "Neosomy", Encyclopedia of Insects, Elsevier, pp. 685–686, doi:10.1016/b978-0-12-374144-8.00186-7, ISBN 978-0-12-374144-8 , retrieved 2023-01-27
↑ Wohltmann, Andreas; Gabryś, Grzegorz; Mąkol, Joanna (2006), Gerecke, Reinhard (ed.), "Acari: Terrestrial Parasitengona inhabiting transient biotopes", Süßwasserfauna von Mitteleuropa, Vol. 7/2-1 Chelicerata: Araneae/Acari I (in German), Berlin, Heidelberg: Springer Berlin Heidelberg, pp. 158–240, doi:10.1007/978-3-662-55958-1_6, ISBN 978-3-662-55957-4 , retrieved 2023-01-26
↑ Rothschild, Miriam (1992). "Neosomy in fleas, and the sessile life-style". Journal of Zoology. 226 (4): 613–629. doi:10.1111/j.1469-7998.1992.tb07504.x. ISSN 0952-8369.
↑ Sun, Haoran; Ding, Liang; Yan, Liping; Pape, Thomas; Zhang, Dong (2021-04-23). "Ascodipteron sanmingensis sp. nov., a new bat fly (Hippoboscidae: streblid grade) from Fujian, China". Biodiversity Data Journal. 9: e64558. doi: 10.3897/BDJ.9.e64558 . ISSN 1314-2828. PMC 8087615 . PMID 33948101.
↑ Kistner, David H. (1968). "Revision of the African Species of the Termitophilous Tribe Corotocini (Coleoptera, Staphylinidae) II. The Genera Termitomimus Tragardh and Nasutimimus New Genus and Their Relationships". The Coleopterists Bulletin. 22 (3): 65–93. ISSN 0010-065X. JSTOR 3999251.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[:0-1] 1 2 3 4 5 6 7 8 Audy, J. Ralph; Radovsky, F. J.; Vercammen-Grandjean, P. H. (1972-12-20). "Neosomy: Radical Intrastadial Metamorphosis Associated With Arthropod Symbioses". Journal of Medical Entomology. 9 (6): 487–494. doi:10.1093/jmedent/9.6.487. ISSN 1938-2928. PMID 4654678.

[2] Radovsky, Frank J. (2009), "Neosomy", Encyclopedia of Insects, Elsevier, pp. 685–686, doi:10.1016/b978-0-12-374144-8.00186-7, ISBN 978-0-12-374144-8 , retrieved 2023-01-27

[3] Wohltmann, Andreas; Gabryś, Grzegorz; Mąkol, Joanna (2006), Gerecke, Reinhard (ed.), "Acari: Terrestrial Parasitengona inhabiting transient biotopes", Süßwasserfauna von Mitteleuropa, Vol. 7/2-1 Chelicerata: Araneae/Acari I (in German), Berlin, Heidelberg: Springer Berlin Heidelberg, pp. 158–240, doi:10.1007/978-3-662-55958-1_6, ISBN 978-3-662-55957-4 , retrieved 2023-01-26

[4] Rothschild, Miriam (1992). "Neosomy in fleas, and the sessile life-style". Journal of Zoology. 226 (4): 613–629. doi:10.1111/j.1469-7998.1992.tb07504.x. ISSN 0952-8369.

[5] Sun, Haoran; Ding, Liang; Yan, Liping; Pape, Thomas; Zhang, Dong (2021-04-23). "Ascodipteron sanmingensis sp. nov., a new bat fly (Hippoboscidae: streblid grade) from Fujian, China". Biodiversity Data Journal. 9: e64558. doi: 10.3897/BDJ.9.e64558 . ISSN 1314-2828. PMC 8087615 . PMID 33948101.

[6] Kistner, David H. (1968). "Revision of the African Species of the Termitophilous Tribe Corotocini (Coleoptera, Staphylinidae) II. The Genera Termitomimus Tragardh and Nasutimimus New Genus and Their Relationships". The Coleopterists Bulletin. 22 (3): 65–93. ISSN 0010-065X. JSTOR 3999251.

[1]

[2]

[3]

[4]

[5]

[6]