fbpx
Wikipedia

Nematode

January 31, 2023

This article is about the organism. For the infection, see Helminthiasis.

The nematodes (/ˈnɛmətdz/ NEM-ə-tohdz or NEEM- Greek: Νηματώδη; Latin: Nematoda) or roundworms constitute the phylum Nematoda (also called Nemathelminthes),[2][3] with plant-parasitic nematodes also known as eelworms.[4] They are a diverse animal phylum inhabiting a broad range of environments. Less formally, they are categorized as Helminths, but are taxonomically classified along with arthropods, tardigrades and other moulting animals in the clade Ecdysozoa, and unlike flatworms, have tubular digestive systems with openings at both ends. Like tardigrades, they have a reduced number of Hox genes, but their sister phylum Nematomorpha has kept the ancestral protostome Hox genotype, which shows that the reduction has occurred within the nematode phylum.[5]

Nematode
Temporal range: Precambrian–Recent[1]
Caenorhabditis elegans,
a model species of roundworm
Scientific classification
Kingdom: Animalia
Subkingdom: Eumetazoa
Clade: ParaHoxozoa
Clade: Bilateria
Clade: Nephrozoa
(unranked): Protostomia
Superphylum: Ecdysozoa
Clade: Nematoida
Phylum: Nematoda
Diesing, 1861
Classes

(see text)

Synonyms
  • Nematodes Burmeister, 1837
  • Nematoidea sensu stricto Cobb, 1919
  • Nemates Cobb, 1919
  • Nemata Cobb, 1919 emend.

Nematode species can be difficult to distinguish from one another. Consequently, estimates of the number of nematode species described to date vary by author and may change rapidly over time. A 2013 survey of animal biodiversity published in the mega journal Zootaxa puts this figure at over 25,000.[6][7] Estimates of the total number of extant species are subject to even greater variation. A widely referenced[8] article published in 1993 estimated there may be over 1 million species of nematode.[9] A subsequent publication challenged this claim, estimating the figure to be at least 40,000 species.[10] Although the highest estimates (up to 100 million species) have since been deprecated, estimates supported by rarefaction curves,[11][12] together with the use of DNA barcoding[13] and the increasing acknowledgment of widespread cryptic species among nematodes,[14] have placed the figure closer to 1 million species.[15]

Nematodes have successfully adapted to nearly every ecosystem: from marine (salt) to fresh water, soils, from the polar regions to the tropics, as well as the highest to the lowest of elevations. They are ubiquitous in freshwater, marine, and terrestrial environments, where they often outnumber other animals in both individual and species counts, and are found in locations as diverse as mountains, deserts, and oceanic trenches. They are found in every part of the earth's lithosphere,[16] even at great depths, 0.9–3.6 km (3,000–12,000 ft) below the surface of the Earth in gold mines in South Africa.[17][18][19][20][21] They represent 90% of all animals on the ocean floor.[22] In total, 4.4 × 1020 nematodes inhabit the Earth's topsoil, or approximately 60 billion for each human, with the highest densities observed in tundra and boreal forests.[23] Their numerical dominance, often exceeding a million individuals per square meter and accounting for about 80% of all individual animals on earth, their diversity of lifecycles, and their presence at various trophic levels point to an important role in many ecosystems.[23][24] They have been shown to play crucial roles in polar ecosystems.[25][26] The roughly 2,271 genera are placed in 256 families.[27] The many parasitic forms include pathogens in most plants and animals. A third of the genera occur as parasites of vertebrates; about 35 nematode species occur in humans.[27]

Nathan Cobb, a nematologist, described the ubiquity of nematodes on Earth thus:

In short, if all the matter in the universe except the nematodes were swept away, our world would still be dimly recognizable, and if, as disembodied spirits, we could then investigate it, we should find its mountains, hills, vales, rivers, lakes, and oceans represented by a film of nematodes. The location of towns would be decipherable since, for every massing of human beings, there would be a corresponding massing of certain nematodes. Trees would still stand in ghostly rows representing our streets and highways. The location of the various plants and animals would still be decipherable, and, had we sufficient knowledge, in many cases even their species could be determined by an examination of their erstwhile nematode parasites.[28]

Etymology

The word nematode comes from the Modern Latin compound of nemat- "thread" (from Greek nema, genitive nematos "thread," from stem of nein "to spin"; see needle) + -odes "like, of the nature of" (see -oid).

Taxonomy and systematics

See also: List of nematode families
 
Eophasma jurasicum, a fossilized nematode
 
Caenorhabditis elegans
 
Rhabditia
 
Unidentified Anisakidae (Ascaridina: Ascaridoidea)
 
Oxyuridae Threadworm
 
Spiruridae Dirofilaria immitis

History

In 1758, Linnaeus described some nematode genera (e.g., Ascaris), then included in the Vermes.

The name of the group Nematoda, informally called "nematodes", came from Nematoidea, originally defined by Karl Rudolphi (1808),[29] from Ancient Greek νῆμα (nêma, nêmatos, 'thread') and -eiδἠς (-eidēs, 'species'). It was treated as family Nematodes by Burmeister (1837).[29]

At its origin, the "Nematoidea" erroneously included Nematodes and Nematomorpha, attributed by von Siebold (1843). Along with Acanthocephala, Trematoda, and Cestoidea, it formed the obsolete group Entozoa,[30] created by Rudolphi (1808).[31] They were also classed along with Acanthocephala in the obsolete phylum Nemathelminthes by Gegenbaur (1859).

In 1861, K. M. Diesing treated the group as order Nematoda.[29] In 1877, the taxon Nematoidea, including the family Gordiidae (horsehair worms), was promoted to the rank of phylum by Ray Lankester. The first clear distinction between the nemas and gordiids was realized by Vejdovsky when he named a group to contain the horsehair worms the order Nematomorpha. In 1919, Nathan Cobb proposed that nematodes should be recognized alone as a phylum.[32] He argued they should be called "nema" in English rather than "nematodes" and defined the taxon Nemates (later emended as Nemata, Latin plural of nema), listing Nematoidea sensu restricto as a synonym.

However, in 1910, Grobben proposed the phylum Aschelminthes and the nematodes were included in as class Nematoda along with class Rotifera, class Gastrotricha, class Kinorhyncha, class Priapulida, and class Nematomorpha (The phylum was later revived and modified by Libbie Henrietta Hyman in 1951 as Pseudoceolomata, but remained similar). In 1932, Potts elevated the class Nematoda to the level of phylum, leaving the name the same. Despite Potts' classification being equivalent to Cobbs', both names have been used (and are still used today) and Nematode became a popular term in zoological science.[33]

Since Cobb was the first to include nematodes in a particular phylum separated from Nematomorpha, some researchers consider the valid taxon name to be Nemates or Nemata, rather than Nematoda,[34] because of the zoological rule that gives priority to the first used term in case of synonyms.

Phylogeny

The phylogenetic relationships of the nematodes and their close relatives among the protostomian Metazoa are unresolved. Traditionally, they were held to be a lineage of their own, but in the 1990s, they were proposed to form the group Ecdysozoa together with moulting animals, such as arthropods. The identity of the closest living relatives of the Nematoda has always been considered to be well resolved. Morphological characters and molecular phylogenies agree with placement of the roundworms as a sister taxon to the parasitic Nematomorpha; together, they make up the Nematoida. Along with the Scalidophora (formerly Cephalorhyncha), the Nematoida form the clade Cycloneuralia, but much disagreement occurs both between and among the available morphological and molecular data. The Cycloneuralia or the Introverta—depending on the validity of the former—are often ranked as a superphylum.[35]

Nematode systematics

Due to the lack of knowledge regarding many nematodes, their systematics is contentious. An early and influential classification was proposed by Chitwood and Chitwood[36]—later revised by Chitwood[37]—who divided the phylum into two classes—Aphasmidia and Phasmidia. These were later renamed Adenophorea (gland bearers) and Secernentea (secretors), respectively.[38] The Secernentea share several characteristics, including the presence of phasmids, a pair of sensory organs located in the lateral posterior region, and this was used as the basis for this division. This scheme was adhered to in many later classifications, though the Adenophorea were not in a uniform group.

Initial studies of incomplete DNA sequences[39] suggested the existence of five clades:[40]

The Secernentea seem to be a natural group of close relatives, while the "Adenophorea" appear to be a paraphyletic assemblage of roundworms that retain a good number of ancestral traits. The old Enoplia do not seem to be monophyletic, either, but do contain two distinct lineages. The old group "Chromadoria" seems to be another paraphyletic assemblage, with the Monhysterida representing a very ancient minor group of nematodes. Among the Secernentea, the Diplogasteria may need to be united with the Rhabditia, while the Tylenchia might be paraphyletic with the Rhabditia.[41]

The understanding of roundworm systematics and phylogeny as of 2002 is summarised below:

Phylum Nematoda

Later work has suggested the presence of 12 clades.[42] The Secernentea—a group that includes virtually all major animal and plant 'nematode' parasites—apparently arose from within the Adenophorea.

In 2019, a study identified one conserved signature indel (CSI) found exclusively in members of the phylum Nematoda through comparative genetic analyses.[43] The CSI consists of a single amino acid insertion within a conserved region of a Na(+)/H(+) exchange regulatory factor protein NRFL-1 and is a molecular marker that distinguishes the phylum from other species.[43]

A major effort by a collaborative wiki called 959 Nematode Genomes is underway to improve the systematics of this phylum.[44]

An analysis of the mitochondrial DNA suggests that the following groupings are valid[45]

In 2022 a new classification of the entire phylum Nematoda was presented by M. Hodda. It was based on current molecular, developmental and morphological evidence.[46]

Anatomy

 
Internal anatomy of a male C. elegans nematode

Nematodes are very small, slender worms: typically about 5 to 100 µm thick, and 0.1 to 2.5 mm long.[47] The smallest nematodes are microscopic, while free-living species can reach as much as 5 cm (2 in), and some parasitic species are larger still, reaching over 1 m (3 ft) in length.[48]: 271  The body is often ornamented with ridges, rings, bristles, or other distinctive structures.[49]

The head of a nematode is relatively distinct. Whereas the rest of the body is bilaterally symmetrical, the head is radially symmetrical, with sensory bristles and, in many cases, solid 'head-shields' radiating outwards around the mouth. The mouth has either three or six lips, which often bear a series of teeth on their inner edges. An adhesive 'caudal gland' is often found at the tip of the tail.[50]

The epidermis is either a syncytium or a single layer of cells, and is covered by a thick collagenous cuticle. The cuticle is often of a complex structure and may have two or three distinct layers. Underneath the epidermis lies a layer of longitudinal muscle cells. The relatively rigid cuticle works with the muscles to create a hydroskeleton, as nematodes lack circumferential muscles. Projections run from the inner surface of muscle cells towards the nerve cords; this is a unique arrangement in the animal kingdom, in which nerve cells normally extend fibers into the muscles rather than vice versa.[50]

Digestive system

The oral cavity is lined with cuticle, which is often strengthened with structures, such as ridges, especially in carnivorous species, which may bear a number of teeth. The mouth often includes a sharp stylet, which the animal can thrust into its prey. In some species, the stylet is hollow and can be used to suck liquids from plants or animals.[50]

The oral cavity opens into a muscular, sucking pharynx, also lined with cuticle. Digestive glands are found in this region of the gut, producing enzymes that start to break down the food. In stylet-bearing species, these may even be injected into the prey.[50]

No stomach is present, with the pharynx connecting directly to a muscleless intestine that forms the main length of the gut. This produces further enzymes, and also absorbs nutrients through its single-cell-thick lining. The last portion of the intestine is lined by cuticle, forming a rectum, which expels waste through the anus just below and in front of the tip of the tail. The movement of food through the digestive system is the result of the body movements of the worm. The intestine has valves or sphincters at either end to help control the movement of food through the body.[50]

Excretory system

Nitrogenous waste is excreted in the form of ammonia through the body wall, and is not associated with any specific organs. However, the structures for excreting salt to maintain osmoregulation are typically more complex.[50]

In many marine nematodes, one or two unicellular 'renette glands' excrete salt through a pore on the underside of the animal, close to the pharynx. In most other nematodes, these specialized cells have been replaced by an organ consisting of two parallel ducts connected by a single transverse duct. This transverse duct opens into a common canal that runs to the excretory pore.[50]

Nervous system

See also: Muscle arms

At the anterior end of the animal a dense, circular nerve ring which serves as the brain surrounds the pharynx.[50] From this ring six labial papillary nerve cords extend anteriorly, while six nerve cords; a large ventral, a smaller dorsal and two pairs of sublateral cords extend posteriorly.[51] Each nerve lies within a cord of connective tissue lying beneath the cuticle and between the muscle cells. The ventral nerve is the largest, and has a double structure forward of the excretory pore. The dorsal nerve is responsible for motor control, while the lateral nerves are sensory, and the ventral combines both functions.[50]

The nervous system is also the only place in the nematode body that contains cilia, which are all nonmotile and with a sensory function.[52][53]

The bodies of nematodes are covered in numerous sensory bristles and papillae that together provide a sense of touch. Behind the sensory bristles on the head lie two small pits, or 'amphids'. These are well supplied with nerve cells and are probably chemoreception organs. A few aquatic nematodes possess what appear to be pigmented eye-spots, but whether or not these are actually sensory in nature is unclear.[50]

Reproduction

 
Extremity of a male nematode showing the spicule, used for copulation, bar = 100 µm[54]

Most nematode species are dioecious, with separate male and female individuals, though some, such as Caenorhabditis elegans, are androdioecious, consisting of hermaphrodites and rare males. Both sexes possess one or two tubular gonads. In males, the sperm are produced at the end of the gonad and migrate along its length as they mature. The testis opens into a relatively wide seminal vesicle and then during intercourse into a glandular and muscular ejaculatory duct associated with the vas deferens and cloaca. In females, the ovaries each open into an oviduct (in hermaphrodites, the eggs enter a spermatheca first) and then a glandular uterus. The uteri both open into a common vulva/vagina, usually located in the middle of the morphologically ventral surface.[50]

Reproduction is usually sexual, though hermaphrodites are capable of self-fertilization. Males are usually smaller than females or hermaphrodites (often much smaller) and often have a characteristically bent or fan-shaped tail. During copulation, one or more chitinized spicules move out of the cloaca and are inserted into the genital pore of the female. Amoeboid sperm crawl along the spicule into the female worm. Nematode sperm is thought to be the only eukaryotic cell without the globular protein G-actin.

Eggs may be embryonated or unembryonated when passed by the female, meaning their fertilized eggs may not yet be developed. A few species are known to be ovoviviparous. The eggs are protected by an outer shell, secreted by the uterus. In free-living roundworms, the eggs hatch into larvae, which appear essentially identical to the adults, except for an underdeveloped reproductive system; in parasitic roundworms, the lifecycle is often much more complicated.[50]

Nematodes as a whole possess a wide range of modes of reproduction.[55] Some nematodes, such as Heterorhabditis spp., undergo a process called endotokia matricida: intrauterine birth causing maternal death.[56] Some nematodes are hermaphroditic, and keep their self-fertilized eggs inside the uterus until they hatch. The juvenile nematodes then ingest the parent nematode. This process is significantly promoted in environments with a low food supply.[56]

The nematode model species C. elegans, C. briggsae, and Pristionchus pacificus, among other species, exhibit androdioecy,[57] which is otherwise very rare among animals. The single genus Meloidogyne (root-knot nematodes) exhibits a range of reproductive modes, including sexual reproduction, facultative sexuality (in which most, but not all, generations reproduce asexually), and both meiotic and mitotic parthenogenesis.

The genus Mesorhabditis exhibits an unusual form of parthenogenesis, in which sperm-producing males copulate with females, but the sperm do not fuse with the ovum. Contact with the sperm is essential for the ovum to begin dividing, but because no fusion of the cells occurs, the male contributes no genetic material to the offspring, which are essentially clones of the female.[50]

Free-living species

Different free-living species feed on materials as varied as bacteria, algae, fungi, small animals, fecal matter, dead organisms, and living tissues. Free-living marine nematodes are important and abundant members of the meiobenthos. They play an important role in the decomposition process, aid in recycling of nutrients in marine environments, and are sensitive to changes in the environment caused by pollution. One roundworm of note, C. elegans, lives in the soil and has found much use as a model organism. C. elegans has had its entire genome sequenced, the developmental fate of every cell determined, and every neuron mapped.

Parasitic species

 
Eggs (mostly nematodes) from stools of wild primates

Nematodes that commonly parasitise humans include ascarids (Ascaris), filarias, hookworms, pinworms (Enterobius), and whipworms (Trichuris trichiura). The species Trichinella spiralis, commonly known as the 'trichina worm', occurs in rats, pigs, bears, and humans, and is responsible for the disease trichinosis. Baylisascaris usually infests wild animals, but can be deadly to humans, as well. Dirofilaria immitis is known for causing heartworm disease by inhabiting the hearts, arteries, and lungs of dogs and some cats. Haemonchus contortus is one of the most abundant infectious agents in sheep around the world, causing great economic damage to sheep. In contrast, entomopathogenic nematodes parasitize insects and are mostly considered beneficial by humans, but some attack beneficial insects.

One form of nematode is entirely dependent upon fig wasps, which are the sole source of fig fertilization. They prey upon the wasps, riding them from the ripe fig of the wasp's birth to the fig flower of its death, where they kill the wasp, and their offspring await the birth of the next generation of wasps as the fig ripens.

 
Colorized electron micrograph of soybean cyst nematode (Heterodera sp.) and egg

A newly discovered parasitic tetradonematid nematode, Myrmeconema neotropicum, apparently induces fruit mimicry in the tropical ant Cephalotes atratus. Infected ants develop bright red gasters (abdomens), tend to be more sluggish, and walk with their gasters in a conspicuous elevated position. These changes likely cause frugivorous birds to confuse the infected ants for berries, and eat them. Parasite eggs passed in the bird's feces are subsequently collected by foraging C. atratus and are fed to their larvae, thus completing the lifecycle of M. neotropicum.[58]

Similarly, multiple varieties of nematodes have been found in the abdominal cavities of the primitively social sweat bee, Lasioglossum zephyrus. Inside the female body, the nematode hinders ovarian development and renders the bee less active, thus less effective in pollen collection.[59]

Agriculture and horticulture

Depending on its species, a nematode may be beneficial or detrimental to plant health. From agricultural and horticulture perspectives, the two categories of nematodes are the predatory ones, which kill garden pests; and the pest nematodes, which attack plants, or act as vectors spreading plant viruses between crop plants.[60] Predatory nematodes include Phasmarhabditis hermaphrodita which is a lethal parasite of gastropods such as slugs and snails.[61] Some members of the genus Steinernema such as Steinernema carpocapsae and Steinernema riobrave are generalist parasites of webworms, cutworms, armyworms, girdlers, some weevils, wood-borers and corn earworm moths.[62] These organisms are grown commercially as biological pest control agents which can be used as an alternative to pesticides; their use is considered very safe.[63] Plant-parasitic nematodes include several groups causing severe crop losses, taking 10% of crops worldwide every year.[64] The most common genera are Aphelenchoides (foliar nematodes), Ditylenchus, Globodera (potato cyst nematodes), Heterodera (soybean cyst nematodes), Longidorus, Meloidogyne (root-knot nematodes), Nacobbus, Pratylenchus (lesion nematodes), Trichodorus, and Xiphinema (dagger nematodes). Several phytoparasitic nematode species cause histological damages to roots, including the formation of visible galls (e.g. by root-knot nematodes), which are useful characters for their diagnostic in the field. Some nematode species transmit plant viruses through their feeding activity on roots. One of them is Xiphinema index, vector of grapevine fanleaf virus, an important disease of grapes, another one is Xiphinema diversicaudatum, vector of arabis mosaic virus. Other nematodes attack bark and forest trees. The most important representative of this group is Bursaphelenchus xylophilus, the pine wood nematode, present in Asia and America and recently discovered in Europe.

Greenhouse growers use beneficial nematodes to control fungus gnats, the nematodes enter the larva of the gnats by way of their anus, mouth, and spiracles (breathing pores) and then release a bacteria which kills the gnat larvae; commonly used nematode species to control pests on greenhouse crops include Steinernema feltiae for fungus gnats and western flower thrips, Steinernema carpocapsae used to control shore flies, Steinernema kraussei for control of black vine weevils, and Heterorhabditis bacteriophora to control beetle larvae.[65]

Rotations of plants with nematode-resistant species or varieties is one means of managing parasitic nematode infestations. For example, marigolds, grown over one or more seasons (the effect is cumulative), can be used to control nematodes.[66] Another is treatment with natural antagonists such as the fungus Gliocladium roseum. Chitosan, a natural biocontrol, elicits plant defense responses to destroy parasitic cyst nematodes on roots of soybean, corn, sugar beet, potato, and tomato crops without harming beneficial nematodes in the soil.[67] Soil steaming is an efficient method to kill nematodes before planting a crop, but indiscriminately eliminates both harmful and beneficial soil fauna.

The golden nematode Globodera rostochiensis is a particularly harmful variety of nematode pest that has resulted in quarantines and crop failures worldwide. CSIRO has found a 13- to 14-fold reduction of nematode population densities in plots having Indian mustard Brassica juncea green manure or seed meal in the soil.[68]

Epidemiology

 
Disability-adjusted life year for intestinal nematode infections per 100,000 in 2002.
    <  25
  25–50
  50–75
  75–100
  100–120
  120–140
  140–160
  160–180
  180–200
  200–220
  220–240
    >  240
  no data

A number of intestinal nematodes cause diseases affecting human beings, including ascariasis, trichuriasis, and hookworm disease. Filarial nematodes cause filariases. Furthermore, studies have shown that parasitic nematodes infect American eels causing damage to the eel's swim bladder,[69] dairy animals like cattle and buffalo,[70] and all species of sheep.[71]

Gastrointestinal nematode infections in humans are common, with approximately 50% of the global population being affected. Developing countries are most heavily impacted, in part due to lack of access to medical care.[72]

Soil ecosystems

Further information: Soil ecology

About 90% of nematodes reside in the top 15 cm (6") of soil. Nematodes do not decompose organic matter, but, instead, are parasitic and free-living organisms that feed on living material. Nematodes can effectively regulate bacterial population and community composition—they may eat up to 5,000 bacteria per minute. Also, nematodes can play an important role in the nitrogen cycle by way of nitrogen mineralization.[47]

One group of carnivorous fungi, the nematophagous fungi, are predators of soil nematodes.[73] They set enticements for the nematodes in the form of lassos or adhesive structures.[74][75][76]

Survivability

Nematode worms (C. elegans), part of an ongoing research project conducted on the 2003 Space Shuttle Columbia mission STS-107, survived the re-entry breakup. It is believed to be the first known life form to survive a virtually unprotected atmospheric descent to Earth's surface.[77][78] In a research project published in 2012, it was found that the Antarctic Nematodes (P. davidi) was able to withstand intracellular freezing depending on how well it was fed. When compared between fed and starved nematodes, the survival rate increased in the fed group and decreased in the starved group.[79]

See also

References

  1. ^ "Nematode Fossils—Nematoda". The Virtual Fossil Museum.
  2. ^ . Archived from the original on 2017-10-06. Retrieved 2016-02-25.
  3. ^ Garcia, Lynne (29 October 1999). "Classification of Human Parasites, Vectors, and Similar Organisms". Clinical Infectious Diseases. Los Angeles, California: Department of Pathology and Laboratory Medicine, UCLA Medical Center. 29 (4): 734–6. doi:10.1086/520425. PMID 10589879.
  4. ^ Hay, Frank. "Nematodes - the good, the bad and the ugly". APS News & Views. American Phytopathological Society. Retrieved 28 November 2020.
  5. ^ Baker, Emily A.; Woollard, Alison (2019). "How Weird is the Worm? Evolution of the Developmental Gene Toolkit in Caenorhabditis elegans". Journal of Developmental Biology. 7 (4): 19. doi:10.3390/jdb7040019. PMC 6956190. PMID 31569401.
  6. ^ Hodda, M (2011). "Phylum Nematoda Cobb, 1932. In: Zhang, Z.-Q. (Ed.) Animal biodiversity: An outline of higher-level classification and survey of taxonomic richness". Zootaxa. 3148: 63–95. doi:10.11646/zootaxa.3148.1.11.
  7. ^ Zhang, Z (2013). "Animal biodiversity: An update of classification and diversity in 2013. In: Zhang, Z.-Q. (Ed.) Animal Biodiversity: An Outline of Higher-level Classification and Survey of Taxonomic Richness (Addenda 2013)". Zootaxa. 3703 (1): 5–11. doi:10.11646/zootaxa.3703.1.3.
  8. ^ "Recent developments in marine benthic biodiversity research". ResearchGate. Retrieved 5 November 2018.
  9. ^ Lambshead, PJD (1993). "Recent developments in marine benthic biodiversity research". Oceanis. 19 (6): 5–24.
  10. ^ Anderson, Roy C. (8 February 2000). Nematode Parasites of Vertebrates: Their Development and Transmission. CABI. pp. 1–2. ISBN 9780851994215. Estimates of 500,000 to a million species have no basis in fact.
  11. ^ Lambshead PJ, Boucher G (2003). "Marine nematode deep-sea biodiversity—hyperdiverse or hype?". Journal of Biogeography. 30 (4): 475–485. doi:10.1046/j.1365-2699.2003.00843.x. S2CID 86504164.
  12. ^ Qing X, Bert W (2019). "Family Tylenchidae (Nematoda): an overview and perspectives". Organisms Diversity & Evolution. 19 (3): 391–408. doi:10.1007/s13127-019-00404-4. S2CID 190873905.
  13. ^ Floyd R, Abebe E, Papert A, Blaxter M (2002). "Molecular barcodes for soil nematode identification". Molecular Ecology. 11 (4): 839–850. doi:10.1046/j.1365-294X.2002.01485.x. PMID 11972769. S2CID 12955921.
  14. ^ Derycke S, Sheibani Tezerji R, Rigaux A, Moens T (2012). "Investigating the ecology and evolution of cryptic marine nematode species through quantitative real-time PCR of the ribosomal ITS region". Molecular Ecology Resources. 12 (4): 607–619. doi:10.1111/j.1755-0998.2012.03128.x. hdl:1854/LU-3127487. PMID 22385909. S2CID 4818657.
  15. ^ Blaxter, Mark (2016). "Imagining Sisyphus happy: DNA barcoding and the unnamed majority". Philosophical Transactions of the Royal Society of London B. 371 (1702): 20150329. doi:10.1098/rstb.2015.0329. PMC 4971181. PMID 27481781.
  16. ^ Borgonie G, García-Moyano A, Litthauer D, Bert W, Bester A, van Heerden E, Möller C, Erasmus M, Onstott TC (June 2011). "Nematoda from the terrestrial deep subsurface of South Africa". Nature. 474 (7349): 79–82. Bibcode:2011Natur.474...79B. doi:10.1038/nature09974. hdl:1854/LU-1269676. PMID 21637257. S2CID 4399763.
  17. ^ Lemonick MD (8 June 2011). . Time. ISSN 0040-781X. Archived from the original on 10 June 2011. Retrieved 8 June 2011.
  18. ^ Bhanoo SN (1 June 2011). "Nematode found in mine is first subsurface multicellular organism". The New York Times. ISSN 0362-4331. Retrieved 13 June 2011.
  19. ^ "Gold mine". Nature. 474 (7349): 6. June 2011. doi:10.1038/474006b. PMID 21637213.
  20. ^ Drake N (1 June 2011). "Subterranean worms from hell: Nature News". Nature News. doi:10.1038/news.2011.342. Retrieved 13 June 2011.
  21. ^ Borgonie G, García-Moyano A, Litthauer D, Bert W, Bester A, van Heerden E, Möller C, Erasmus M, Onstott TC (2 June 2011). "Nematoda from the terrestrial deep subsurface of South Africa". Nature. 474 (7349): 79–82. Bibcode:2011Natur.474...79B. doi:10.1038/nature09974. hdl:1854/LU-1269676. ISSN 0028-0836. PMID 21637257. S2CID 4399763.
  22. ^ Danovaro R, Gambi C, Dell'Anno A, Corinaldesi C, Fraschetti S, Vanreusel A, Vincx M, Gooday AJ (January 2008). "Exponential decline of deep-sea ecosystem functioning linked to benthic biodiversity loss". Curr. Biol. 18 (1): 1–8. doi:10.1016/j.cub.2007.11.056. PMID 18164201. S2CID 15272791.
    • "Deep-sea species' loss could lead to oceans' collapse, study suggests". EurekAlert! (Press release). 27 December 2007.
  23. ^ a b van den Hoogen, Johan; Geisen, Stefan; Routh, Devin; Ferris, Howard; Traunspurger, Walter; Wardle, David A.; de Goede, Ron G. M.; Adams, Byron J.; Ahmad, Wasim (2019-07-24). . Nature. 572 (7768): 194–198. Bibcode:2019Natur.572..194V. doi:10.1038/s41586-019-1418-6. hdl:20.500.11755/c8c7bc6a-585c-4a13-9e36-4851939c1b10. ISSN 0028-0836. PMID 31341281. S2CID 198492891. Archived from the original on 2020-03-02. Retrieved 2019-12-10.
  24. ^ Platt HM (1994). "foreword". In Lorenzen S, Lorenzen SA (eds.). The phylogenetic systematics of freeliving nematodes. London, UK: The Ray Society. ISBN 978-0-903874-22-9.
  25. ^ Cary, S. Craig; Green, T. G. Allan; Storey, Bryan C.; Sparrow, Ashley D.; Hogg, Ian D.; Katurji, Marwan; Zawar-Reza, Peyman; Jones, Irfon; Stichbury, Glen A. (2019-02-15). "Biotic interactions are an unexpected yet critical control on the complexity of an abiotically driven polar ecosystem". Communications Biology. 2 (1): 62. doi:10.1038/s42003-018-0274-5. ISSN 2399-3642. PMC 6377621. PMID 30793041.
  26. ^ Adams, Byron J.; Wall, Diana H.; Storey, Bryan C.; Green, T. G. Allan; Barrett, John E.; S. Craig Cary; Hopkins, David W.; Lee, Charles K.; Bottos, Eric M. (2019-02-15). "Nematodes in a polar desert reveal the relative role of biotic interactions in the coexistence of soil animals". Communications Biology. 2 (1): 63. doi:10.1038/s42003-018-0260-y. ISSN 2399-3642. PMC 6377602. PMID 30793042.
  27. ^ a b Roy C. Anderson (8 February 2000). Nematode Parasites of Vertebrates: Their development and transmission. CABI. p. 1. ISBN 978-0-85199-786-5.
  28. ^ Cobb, Nathan (1914). . Yearbook. United States Department of Agriculture. pp. 472, 457–490. Archived from the original on 9 June 2016. Retrieved 25 September 2012. Quote on p. 472.
  29. ^ a b c Chitwood BG (1957). "The English word "Nema" revised". Systematic Biology. 4 (45): 1619. doi:10.2307/sysbio/6.4.184.
  30. ^ Siddiqi MR (2000). Tylenchida: parasites of plants and insects. Wallingford, Oxon, UK: CABI Pub. ISBN 978-0-85199-202-0.
  31. ^ Schmidt-Rhaesa A (2014). "Gastrotricha, Cycloneuralia and Gnathifera: General History and Phylogeny". In Schmidt-Rhaesa A (ed.). Handbook of Zoology (founded by W. Kükenthal). Vol. 1, Nematomorpha, Priapulida, Kinorhyncha, Loricifera. Berlin, Boston: de Gruyter.
  32. ^ Cobb NA (1919). "The orders and classes of nemas". Contrib. Sci. Nematol. 8: 213–216.
  33. ^ Wilson, E. O. . Plant and insect parasitic nematodes. Archived from the original on 30 April 2018. Retrieved 29 April 2018.
  34. ^ "ITIS report: Nematoda". Itis.gov. Retrieved 12 June 2012.
  35. ^ "Bilateria". Tree of Life Web Project. Tree of Life Web Project. 2002. Retrieved 2 November 2008.
  36. ^ Chitwood BG, Chitwood MB (1933). "The characters of a protonematode". J Parasitol. 20: 130.
  37. ^ Chitwood BG (1937). "A revised classification of the Nematoda". Papers on Helminthology published in commemoration of the 30 year Jubileum of ... K.J. Skrjabin ... Moscow: All-Union Lenin Academy of Agricultural Sciences. pp. 67–79.
  38. ^ Chitwood BG (1958). "The designation of official names for higher taxa of invertebrates". Bull Zool Nomencl. 15: 860–895. doi:10.5962/bhl.part.19410.
  39. ^ Coghlan, A. (7 Sep 2005). (PDF). WormBook: 1–15. doi:10.1895/wormbook.1.15.1. PMC 4781476. PMID 18050393. Archived from the original (PDF) on 5 March 2016. Retrieved 13 January 2016.
  40. ^ Blaxter ML, De Ley P, Garey JR, Liu LX, Scheldeman P, Vierstraete A, Vanfleteren JR, Mackey LY, Dorris M, Frisse LM, Vida JT, Thomas WK (March 1998). "A molecular evolutionary framework for the phylum Nematoda". Nature. 392 (6671): 71–75. Bibcode:1998Natur.392...71B. doi:10.1038/32160. PMID 9510248. S2CID 4301939.
  41. ^ "Nematoda". Tree of Life Web Project. Tree of Life Web Project. 2002. Retrieved 2 November 2008.
  42. ^ Holterman M, van der Wurff A, van den Elsen S, van Megen H, Bongers T, Holovachov O, Bakker J, Helder J (2006). "Phylum-wide analysis of SSU rDNA reveals deep phylogenetic relationships among nematodes and accelerated evolution toward crown Clades". Mol Biol Evol. 23 (9): 1792–1800. doi:10.1093/molbev/msl044. PMID 16790472.
  43. ^ a b Khadka, Bijendra; Chatterjee, Tonuka; Gupta, Bhagwati P.; Gupta, Radhey S. (2019-09-24). "Genomic Analyses Identify Novel Molecular Signatures Specific for the Caenorhabditis and other Nematode Taxa Providing Novel Means for Genetic and Biochemical Studies". Genes. 10 (10): 739. doi:10.3390/genes10100739. ISSN 2073-4425. PMC 6826867. PMID 31554175.
  44. ^ . Nematodes.org. 11 November 2011. Archived from the original on 5 August 2015. Retrieved 12 June 2012.
  45. ^ Liu GH, Shao R, Li JY, Zhou DH, Li H, Zhu XQ (2013). "The complete mitochondrial genomes of three parasitic nematodes of birds: a unique gene order and insights into nematode phylogeny". BMC Genomics. 14 (1): 414. doi:10.1186/1471-2164-14-414. PMC 3693896. PMID 23800363.
  46. ^ Hodda, M. (2022). "Phylum Nematoda: a classification, catalogue and index of valid genera, with a census of valid species". Zootaxa. 5114 (1): 1–289. doi:10.11646/zootaxa.5114.1.1. PMID 35391386.
  47. ^ a b Nyle C. Brady & Ray R. Weil (2009). Elements of the Nature and Properties of Soils (3rd ed.). Prentice Hall. ISBN 9780135014332.
  48. ^ Ruppert EE, Fox RS, Barnes RD (2004). Invertebrate Zoology: A Functional Evolutionary Approach (7th ed.). Belmont, California: Brooks/Cole. ISBN 978-0-03-025982-1.
  49. ^ Weischer B, Brown DJ (2000). An Introduction to Nematodes: General Nematology. Sofia, Bulgaria: Pensoft. pp. 75–76. ISBN 978-954-642-087-9.
  50. ^ a b c d e f g h i j k l m Barnes RG (1980). Invertebrate zoology. Philadelphia: Sanders College. ISBN 978-0-03-056747-6.
  51. ^ Free-living Marine Nematodes from the East China Sea
  52. ^ "The sensory cilia of Caenorhabditis elegans". www.wormbook.org.
  53. ^ Kavlie, RG; Kernan, MJ; Eberl, DF (May 2010). "Hearing in Drosophila requires TilB, a conserved protein associated with ciliary motility". Genetics. 185 (1): 177–88. doi:10.1534/genetics.110.114009. PMC 2870953. PMID 20215474.
  54. ^ Lalošević, V.; Lalošević, D.; Capo, I.; Simin, V.; Galfi, A.; Traversa, D. (2013). "High infection rate of zoonotic Eucoleus aerophilus infection in foxes from Serbia". Parasite. 20: 3. doi:10.1051/parasite/2012003. PMC 3718516. PMID 23340229.
  55. ^ Bell G (1982). The masterpiece of nature: the evolution and genetics of sexuality. Berkeley: University of California Press. ISBN 978-0-520-04583-5.
  56. ^ a b Johnigk SA, Ehlers RU (1999). "Endotokia matricida in hermaphrodites of Heterorhabditis spp. and the effect of the food supply". Nematology. 1 (7–8): 717–726. doi:10.1163/156854199508748. ISSN 1388-5545. S2CID 85279418.
  57. ^ Haag ES, Helder J, Mooijman PJ, Yin D, Hu S (2018). "The Evolution of Uniparental Reproduction in Rhabditina Nematodes: Phylogenetic Patterns, Developmental Causes, and Surprising Consequences". In Leonard, J.L. (ed.). Transitions Between Sexual Systems. Springer. pp. 99–122. doi:10.1007/978-3-319-94139-4_4. ISBN 978-3-319-94137-0.
  58. ^ Yanoviak SP, Kaspari M, Dudley R, Poinar G (April 2008). "Parasite-induced fruit mimicry in a tropical canopy ant". Am. Nat. 171 (4): 536–44. doi:10.1086/528968. PMID 18279076. S2CID 23857167.
  59. ^ Batra, Suzanne W. T. (1965-10-01). "Organisms associated with Lasioglossum zephyrum (Hymenoptera: Halictidae)". Journal of the Kansas Entomological Society. 38 (4): 367–389. JSTOR 25083474.
  60. ^ Purcell M, Johnson MW, Lebeck LM, Hara AH (1992). "Biological Control of Helicoverpa zea (Lepidoptera: Noctuidae) with Steinernema carpocapsae (Rhabditida: Steinernematidae) in Corn Used as a Trap Crop". Environmental Entomology. 21 (6): 1441–1447. doi:10.1093/ee/21.6.1441.{{cite journal}}: CS1 maint: uses authors parameter (link)
  61. ^ Wilson, M. J.; Glen, D. M.; George, S. K. (January 1993). "The rhabditid nematode Phasmarhabditis hermaphrodita as a potential biological control agent for slugs". Biocontrol Science and Technology. 3 (4): 503–511. doi:10.1080/09583159309355306.
  62. ^ Rajamani, Meenatchi; Negi, Aditi (2021). "Biopesticides for Pest Management". Sustainable Bioeconomy: 239–266. doi:10.1007/978-981-15-7321-7_11. ISBN 978-981-15-7320-0. S2CID 228845133.
  63. ^ Ehlers, R.-U.; Hokkanen, H. M. T. (September 1996). "Insect Biocontrol with Non-endemic Entomopathogenic Nematodes (Steinernema and Heterorhabditis spp.): Conclusions and Recommendations of a Combined OECD and COST Workshop on Scientific and Regulatory Policy Issues". Biocontrol Science and Technology. 6 (3): 295–302. doi:10.1080/09583159631280.
  64. ^ Smiley RW, Dababat AA, Iqbal S, Jones MG, Maafi ZT, Peng D, Subbotin SA, Waeyenberge L (2017). "Cereal Cyst Nematodes: A Complex and Destructive Group of Heterodera Species". Plant Disease. American Phytopathological Society. 101 (10): 1692–1720. doi:10.1094/pdis-03-17-0355-fe. ISSN 0191-2917. PMID 30676930.
  65. ^ Kloosterman, Stephen (April 2022). "Small Soldiers". Green House Product News. Vol. 32, no. 4. pp. 26–29.
  66. ^ Riotte L (1975). Secrets of companion planting for successful gardening. p. 7.
  67. ^ US application 2008072494, Stoner RJ, Linden JC, "Micronutrient elicitor for treating nematodes in field crops", published 2008-03-27 
  68. ^ Loothfar R, Tony S (22 March 2005). "Suppression of root knot nematode (Meloidogyne javanica) after incorporation of Indian mustard cv. Nemfix as green manure and seed meal in vineyards". Australasian Plant Pathology. 34 (1): 77–83. doi:10.1071/AP04081. S2CID 24299033. Retrieved 14 June 2010.
  69. ^ Warshafsky, Z. T., Tuckey, T. D., Vogelbein, W. K., Latour, R. J., & Wargo, A. R. (2019). Temporal, spatial, and biological variation of nematode epidemiology in American eels. Canadian Journal of Fisheries & Aquatic Sciences, 76(10), 1808–1818. https://doi.org/10.1139/cjfas-2018-0136
  70. ^ Jithendran, & Bhat, T. . (1999). Epidemiology of Parasitoses in Dairy Animals in the North West Humid Himalayan Region of India with Particular Reference to Gastrointestinal Nematodes. Tropical Animal Health and Production, 31(4), 205–214. https://doi.org/10.1023/A:1005263009921
  71. ^ Morgan, & van Dijk, J. (2012). Climate and the epidemiology of gastrointestinal nematode infections of sheep in Europe. Veterinary Parasitology, 189(1), 8–14. https://doi.org/10.1016/j.vetpar.2012.03.028
  72. ^ Stepek, Gillian; Buttle, David J; Duce, Ian R; Behnke, Jerzy M (October 2006). "Human gastrointestinal nematode infections: are new control methods required?". International Journal of Experimental Pathology. 87 (5): 325–341. doi:10.1111/j.1365-2613.2006.00495.x. ISSN 0959-9673. PMC 2517378. PMID 16965561.
  73. ^ Nosowitz, Fan (2021-02-08). "How California Crops Fought Off a Pest Without Using Pesticide". Modern Farmer. Retrieved 2021-02-15.
  74. ^ Pramer C (1964). "Nematode-trapping fungi". Science. 144 (3617): 382–388. Bibcode:1964Sci...144..382P. doi:10.1126/science.144.3617.382. PMID 14169325.
  75. ^ Hauser JT (December 1985). "Nematode-trapping fungi" (PDF). Carnivorous Plant Newsletter. 14 (1): 8–11.
  76. ^ Ahrén D, Ursing BM, Tunlid A (1998). "Phylogeny of nematode-trapping fungi based on 18S rDNA sequences". FEMS Microbiology Letters. 158 (2): 179–184. doi:10.1016/s0378-1097(97)00519-3. PMID 9465391.
  77. ^ . Astrobiology Magazine. Jan 1, 2006. Archived from the original on March 4, 2016. Retrieved January 12, 2016.{{cite magazine}}: CS1 maint: unfit URL (link)
  78. ^ Szewczyk, Nathaniel J.; Mancinelli, Rocco L.; McLamb, William; Reed, David; Blumberg, Baruch S.; Conley, Catharine A. (December 2005). "Caenorhabditis elegans Survives Atmospheric Breakup of STS–107, Space Shuttle Columbia". Astrobiology. 5 (6): 690–705. Bibcode:2005AsBio...5..690S. doi:10.1089/ast.2005.5.690. PMID 16379525.
  79. ^ Raymond, Mélianie R.; Wharton, David A. (February 2013). "The ability of the Antarctic nematode Panagrolaimus davidi to survive intracellular freezing is dependent upon nutritional status". Journal of Comparative Physiology B. 183 (2): 181–188. doi:10.1007/s00360-012-0697-0. ISSN 0174-1578. PMID 22836298. S2CID 17294698.

Further reading

  • Atkinson, H.J. (1973). "The respiratory physiology of the marine nematodes Enoplus brevis (Bastian) and E. communis (Bastian): I. The influence of oxygen tension and body size" (PDF). J. Exp. Biol. 59 (1): 255–266. doi:10.1242/jeb.59.1.255.
  • "Worms survived Columbia disaster". BBC News. 1 May 2003. Retrieved 4 Nov 2008.
  • Gubanov, N.M. (1951). "Giant nematoda from the placenta of Cetacea; Placentonema gigantissima nov. gen., nov. sp". Proc. USSR Acad. Sci. 77 (6): 1123–1125. [in Russian].
  • Kaya, Harry K.; et al. (1993). "An Overview of Insect-Parasitic and Entomopathogenic Nematodes". In Bedding, R.A. (ed.). Nematodes and the Biological Control of Insect Pests. Csiro Publishing. ISBN 9780643105911.
  • . Merck Veterinary Manual (MVM). 2006. Archived from the original on 3 March 2016. Retrieved 10 February 2007.
  • White JG, Southgate E, Thomson JN, Brenner S (August 1976). "The structure of the ventral nerve cord of Caenorhabditis elegans". Philos. Trans. R. Soc. Lond. B Biol. Sci. 275 (938): 327–348. Bibcode:1976RSPTB.275..327W. doi:10.1098/rstb.1976.0086. PMID 8806.
  • Lee, Donald L, ed. (2010). The biology of nematodes. London: Taylor & Francis. ISBN 978-0415272117. Retrieved 16 December 2014.
  • De Ley P, Blaxter M (2004). "A new system for Nematoda: combining morphological characters with molecular trees, and translating clades into ranks and taxa". In R Cook, DJ Hunt (eds.). Nematology Monographs and Perspectives. Vol. 2. E.J. Brill, Leiden. pp. 633–653.

External links

 
Wikimedia Commons has media related to Nematoda.
 
Wikisource has the text of the 1911 Encyclopædia Britannica article "Nematoda".

January 31, 2023
nematode, this, article, about, organism, infection, helminthiasis, nematodes, tohdz, neem, greek, Νηματώδη, latin, nematoda, roundworms, constitute, phylum, nematoda, also, called, nemathelminthes, with, plant, parasitic, nematodes, also, known, eelworms, the. This article is about the organism For the infection see Helminthiasis The nematodes ˈ n ɛ m e t oʊ d z NEM e tohdz or NEEM Greek Nhmatwdh Latin Nematoda or roundworms constitute the phylum Nematoda also called Nemathelminthes 2 3 with plant parasitic nematodes also known as eelworms 4 They are a diverse animal phylum inhabiting a broad range of environments Less formally they are categorized as Helminths but are taxonomically classified along with arthropods tardigrades and other moulting animals in the clade Ecdysozoa and unlike flatworms have tubular digestive systems with openings at both ends Like tardigrades they have a reduced number of Hox genes but their sister phylum Nematomorpha has kept the ancestral protostome Hox genotype which shows that the reduction has occurred within the nematode phylum 5 NematodeTemporal range Precambrian Recent 1 PreꞒ Ꞓ O S D C P T J K Pg NCaenorhabditis elegans a model species of roundwormScientific classificationKingdom AnimaliaSubkingdom EumetazoaClade ParaHoxozoaClade BilateriaClade Nephrozoa unranked ProtostomiaSuperphylum EcdysozoaClade NematoidaPhylum NematodaDiesing 1861ClassesChromadorea Enoplea Secernentea see text SynonymsNematodes Burmeister 1837 Nematoidea sensu stricto Cobb 1919 Nemates Cobb 1919 Nemata Cobb 1919 emend Nematode species can be difficult to distinguish from one another Consequently estimates of the number of nematode species described to date vary by author and may change rapidly over time A 2013 survey of animal biodiversity published in the mega journal Zootaxa puts this figure at over 25 000 6 7 Estimates of the total number of extant species are subject to even greater variation A widely referenced 8 article published in 1993 estimated there may be over 1 million species of nematode 9 A subsequent publication challenged this claim estimating the figure to be at least 40 000 species 10 Although the highest estimates up to 100 million species have since been deprecated estimates supported by rarefaction curves 11 12 together with the use of DNA barcoding 13 and the increasing acknowledgment of widespread cryptic species among nematodes 14 have placed the figure closer to 1 million species 15 Nematodes have successfully adapted to nearly every ecosystem from marine salt to fresh water soils from the polar regions to the tropics as well as the highest to the lowest of elevations They are ubiquitous in freshwater marine and terrestrial environments where they often outnumber other animals in both individual and species counts and are found in locations as diverse as mountains deserts and oceanic trenches They are found in every part of the earth s lithosphere 16 even at great depths 0 9 3 6 km 3 000 12 000 ft below the surface of the Earth in gold mines in South Africa 17 18 19 20 21 They represent 90 of all animals on the ocean floor 22 In total 4 4 1020 nematodes inhabit the Earth s topsoil or approximately 60 billion for each human with the highest densities observed in tundra and boreal forests 23 Their numerical dominance often exceeding a million individuals per square meter and accounting for about 80 of all individual animals on earth their diversity of lifecycles and their presence at various trophic levels point to an important role in many ecosystems 23 24 They have been shown to play crucial roles in polar ecosystems 25 26 The roughly 2 271 genera are placed in 256 families 27 The many parasitic forms include pathogens in most plants and animals A third of the genera occur as parasites of vertebrates about 35 nematode species occur in humans 27 Nathan Cobb a nematologist described the ubiquity of nematodes on Earth thus In short if all the matter in the universe except the nematodes were swept away our world would still be dimly recognizable and if as disembodied spirits we could then investigate it we should find its mountains hills vales rivers lakes and oceans represented by a film of nematodes The location of towns would be decipherable since for every massing of human beings there would be a corresponding massing of certain nematodes Trees would still stand in ghostly rows representing our streets and highways The location of the various plants and animals would still be decipherable and had we sufficient knowledge in many cases even their species could be determined by an examination of their erstwhile nematode parasites 28 Contents 1 Etymology 2 Taxonomy and systematics 2 1 History 2 2 Phylogeny 2 3 Nematode systematics 3 Anatomy 3 1 Digestive system 3 2 Excretory system 3 3 Nervous system 4 Reproduction 5 Free living species 6 Parasitic species 6 1 Agriculture and horticulture 7 Epidemiology 8 Soil ecosystems 9 Survivability 10 See also 11 References 12 Further reading 13 External linksEtymology EditThe word nematode comes from the Modern Latin compound of nemat thread from Greek nema genitive nematos thread from stem of nein to spin see needle odes like of the nature of see oid Taxonomy and systematics EditSee also List of nematode families Eophasma jurasicum a fossilized nematode Caenorhabditis elegans Rhabditia Nippostrongylus brasiliensis Unidentified Anisakidae Ascaridina Ascaridoidea Oxyuridae Threadworm Spiruridae Dirofilaria immitis History Edit In 1758 Linnaeus described some nematode genera e g Ascaris then included in the Vermes The name of the group Nematoda informally called nematodes came from Nematoidea originally defined by Karl Rudolphi 1808 29 from Ancient Greek nῆma nema nematos thread and eidἠs eides species It was treated as family Nematodes by Burmeister 1837 29 At its origin the Nematoidea erroneously included Nematodes and Nematomorpha attributed by von Siebold 1843 Along with Acanthocephala Trematoda and Cestoidea it formed the obsolete group Entozoa 30 created by Rudolphi 1808 31 They were also classed along with Acanthocephala in the obsolete phylum Nemathelminthes by Gegenbaur 1859 In 1861 K M Diesing treated the group as order Nematoda 29 In 1877 the taxon Nematoidea including the family Gordiidae horsehair worms was promoted to the rank of phylum by Ray Lankester The first clear distinction between the nemas and gordiids was realized by Vejdovsky when he named a group to contain the horsehair worms the order Nematomorpha In 1919 Nathan Cobb proposed that nematodes should be recognized alone as a phylum 32 He argued they should be called nema in English rather than nematodes and defined the taxon Nemates later emended as Nemata Latin plural of nema listing Nematoidea sensu restricto as a synonym However in 1910 Grobben proposed the phylum Aschelminthes and the nematodes were included in as class Nematoda along with class Rotifera class Gastrotricha class Kinorhyncha class Priapulida and class Nematomorpha The phylum was later revived and modified by Libbie Henrietta Hyman in 1951 as Pseudoceolomata but remained similar In 1932 Potts elevated the class Nematoda to the level of phylum leaving the name the same Despite Potts classification being equivalent to Cobbs both names have been used and are still used today and Nematode became a popular term in zoological science 33 Since Cobb was the first to include nematodes in a particular phylum separated from Nematomorpha some researchers consider the valid taxon name to be Nemates or Nemata rather than Nematoda 34 because of the zoological rule that gives priority to the first used term in case of synonyms Phylogeny Edit The phylogenetic relationships of the nematodes and their close relatives among the protostomian Metazoa are unresolved Traditionally they were held to be a lineage of their own but in the 1990s they were proposed to form the group Ecdysozoa together with moulting animals such as arthropods The identity of the closest living relatives of the Nematoda has always been considered to be well resolved Morphological characters and molecular phylogenies agree with placement of the roundworms as a sister taxon to the parasitic Nematomorpha together they make up the Nematoida Along with the Scalidophora formerly Cephalorhyncha the Nematoida form the clade Cycloneuralia but much disagreement occurs both between and among the available morphological and molecular data The Cycloneuralia or the Introverta depending on the validity of the former are often ranked as a superphylum 35 Nematode systematics Edit Due to the lack of knowledge regarding many nematodes their systematics is contentious An early and influential classification was proposed by Chitwood and Chitwood 36 later revised by Chitwood 37 who divided the phylum into two classes Aphasmidia and Phasmidia These were later renamed Adenophorea gland bearers and Secernentea secretors respectively 38 The Secernentea share several characteristics including the presence of phasmids a pair of sensory organs located in the lateral posterior region and this was used as the basis for this division This scheme was adhered to in many later classifications though the Adenophorea were not in a uniform group Initial studies of incomplete DNA sequences 39 suggested the existence of five clades 40 Dorylaimida Enoplia Spirurina Tylenchina RhabditinaThe Secernentea seem to be a natural group of close relatives while the Adenophorea appear to be a paraphyletic assemblage of roundworms that retain a good number of ancestral traits The old Enoplia do not seem to be monophyletic either but do contain two distinct lineages The old group Chromadoria seems to be another paraphyletic assemblage with the Monhysterida representing a very ancient minor group of nematodes Among the Secernentea the Diplogasteria may need to be united with the Rhabditia while the Tylenchia might be paraphyletic with the Rhabditia 41 The understanding of roundworm systematics and phylogeny as of 2002 is summarised below Phylum Nematoda Basal order Monhysterida Class Dorylaimida Class Enoplea Class Secernentea Subclass Diplogasteria disputed Subclass Rhabditia paraphyletic Subclass Spiruria Subclass Tylenchia disputed Chromadorea assemblageLater work has suggested the presence of 12 clades 42 The Secernentea a group that includes virtually all major animal and plant nematode parasites apparently arose from within the Adenophorea In 2019 a study identified one conserved signature indel CSI found exclusively in members of the phylum Nematoda through comparative genetic analyses 43 The CSI consists of a single amino acid insertion within a conserved region of a Na H exchange regulatory factor protein NRFL 1 and is a molecular marker that distinguishes the phylum from other species 43 A major effort by a collaborative wiki called 959 Nematode Genomes is underway to improve the systematics of this phylum 44 An analysis of the mitochondrial DNA suggests that the following groupings are valid 45 subclass Dorylaimia orders Rhabditida Trichinellida and Mermithida suborder Rhabditina infraorders Spiruromorpha and OxyuridomorphaIn 2022 a new classification of the entire phylum Nematoda was presented by M Hodda It was based on current molecular developmental and morphological evidence 46 Anatomy Edit Internal anatomy of a male C elegans nematode Nematodes are very small slender worms typically about 5 to 100 µm thick and 0 1 to 2 5 mm long 47 The smallest nematodes are microscopic while free living species can reach as much as 5 cm 2 in and some parasitic species are larger still reaching over 1 m 3 ft in length 48 271 The body is often ornamented with ridges rings bristles or other distinctive structures 49 The head of a nematode is relatively distinct Whereas the rest of the body is bilaterally symmetrical the head is radially symmetrical with sensory bristles and in many cases solid head shields radiating outwards around the mouth The mouth has either three or six lips which often bear a series of teeth on their inner edges An adhesive caudal gland is often found at the tip of the tail 50 The epidermis is either a syncytium or a single layer of cells and is covered by a thick collagenous cuticle The cuticle is often of a complex structure and may have two or three distinct layers Underneath the epidermis lies a layer of longitudinal muscle cells The relatively rigid cuticle works with the muscles to create a hydroskeleton as nematodes lack circumferential muscles Projections run from the inner surface of muscle cells towards the nerve cords this is a unique arrangement in the animal kingdom in which nerve cells normally extend fibers into the muscles rather than vice versa 50 Digestive system Edit The oral cavity is lined with cuticle which is often strengthened with structures such as ridges especially in carnivorous species which may bear a number of teeth The mouth often includes a sharp stylet which the animal can thrust into its prey In some species the stylet is hollow and can be used to suck liquids from plants or animals 50 The oral cavity opens into a muscular sucking pharynx also lined with cuticle Digestive glands are found in this region of the gut producing enzymes that start to break down the food In stylet bearing species these may even be injected into the prey 50 No stomach is present with the pharynx connecting directly to a muscleless intestine that forms the main length of the gut This produces further enzymes and also absorbs nutrients through its single cell thick lining The last portion of the intestine is lined by cuticle forming a rectum which expels waste through the anus just below and in front of the tip of the tail The movement of food through the digestive system is the result of the body movements of the worm The intestine has valves or sphincters at either end to help control the movement of food through the body 50 Excretory system Edit Nitrogenous waste is excreted in the form of ammonia through the body wall and is not associated with any specific organs However the structures for excreting salt to maintain osmoregulation are typically more complex 50 In many marine nematodes one or two unicellular renette glands excrete salt through a pore on the underside of the animal close to the pharynx In most other nematodes these specialized cells have been replaced by an organ consisting of two parallel ducts connected by a single transverse duct This transverse duct opens into a common canal that runs to the excretory pore 50 Nervous system Edit See also Muscle arms At the anterior end of the animal a dense circular nerve ring which serves as the brain surrounds the pharynx 50 From this ring six labial papillary nerve cords extend anteriorly while six nerve cords a large ventral a smaller dorsal and two pairs of sublateral cords extend posteriorly 51 Each nerve lies within a cord of connective tissue lying beneath the cuticle and between the muscle cells The ventral nerve is the largest and has a double structure forward of the excretory pore The dorsal nerve is responsible for motor control while the lateral nerves are sensory and the ventral combines both functions 50 The nervous system is also the only place in the nematode body that contains cilia which are all nonmotile and with a sensory function 52 53 The bodies of nematodes are covered in numerous sensory bristles and papillae that together provide a sense of touch Behind the sensory bristles on the head lie two small pits or amphids These are well supplied with nerve cells and are probably chemoreception organs A few aquatic nematodes possess what appear to be pigmented eye spots but whether or not these are actually sensory in nature is unclear 50 Reproduction Edit Extremity of a male nematode showing the spicule used for copulation bar 100 µm 54 Most nematode species are dioecious with separate male and female individuals though some such as Caenorhabditis elegans are androdioecious consisting of hermaphrodites and rare males Both sexes possess one or two tubular gonads In males the sperm are produced at the end of the gonad and migrate along its length as they mature The testis opens into a relatively wide seminal vesicle and then during intercourse into a glandular and muscular ejaculatory duct associated with the vas deferens and cloaca In females the ovaries each open into an oviduct in hermaphrodites the eggs enter a spermatheca first and then a glandular uterus The uteri both open into a common vulva vagina usually located in the middle of the morphologically ventral surface 50 Reproduction is usually sexual though hermaphrodites are capable of self fertilization Males are usually smaller than females or hermaphrodites often much smaller and often have a characteristically bent or fan shaped tail During copulation one or more chitinized spicules move out of the cloaca and are inserted into the genital pore of the female Amoeboid sperm crawl along the spicule into the female worm Nematode sperm is thought to be the only eukaryotic cell without the globular protein G actin Eggs may be embryonated or unembryonated when passed by the female meaning their fertilized eggs may not yet be developed A few species are known to be ovoviviparous The eggs are protected by an outer shell secreted by the uterus In free living roundworms the eggs hatch into larvae which appear essentially identical to the adults except for an underdeveloped reproductive system in parasitic roundworms the lifecycle is often much more complicated 50 Nematodes as a whole possess a wide range of modes of reproduction 55 Some nematodes such as Heterorhabditis spp undergo a process called endotokia matricida intrauterine birth causing maternal death 56 Some nematodes are hermaphroditic and keep their self fertilized eggs inside the uterus until they hatch The juvenile nematodes then ingest the parent nematode This process is significantly promoted in environments with a low food supply 56 The nematode model species C elegans C briggsae and Pristionchus pacificus among other species exhibit androdioecy 57 which is otherwise very rare among animals The single genus Meloidogyne root knot nematodes exhibits a range of reproductive modes including sexual reproduction facultative sexuality in which most but not all generations reproduce asexually and both meiotic and mitotic parthenogenesis The genus Mesorhabditis exhibits an unusual form of parthenogenesis in which sperm producing males copulate with females but the sperm do not fuse with the ovum Contact with the sperm is essential for the ovum to begin dividing but because no fusion of the cells occurs the male contributes no genetic material to the offspring which are essentially clones of the female 50 Free living species EditDifferent free living species feed on materials as varied as bacteria algae fungi small animals fecal matter dead organisms and living tissues Free living marine nematodes are important and abundant members of the meiobenthos They play an important role in the decomposition process aid in recycling of nutrients in marine environments and are sensitive to changes in the environment caused by pollution One roundworm of note C elegans lives in the soil and has found much use as a model organism C elegans has had its entire genome sequenced the developmental fate of every cell determined and every neuron mapped Parasitic species Edit Eggs mostly nematodes from stools of wild primates Nematodes that commonly parasitise humans include ascarids Ascaris filarias hookworms pinworms Enterobius and whipworms Trichuris trichiura The species Trichinella spiralis commonly known as the trichina worm occurs in rats pigs bears and humans and is responsible for the disease trichinosis Baylisascaris usually infests wild animals but can be deadly to humans as well Dirofilaria immitis is known for causing heartworm disease by inhabiting the hearts arteries and lungs of dogs and some cats Haemonchus contortus is one of the most abundant infectious agents in sheep around the world causing great economic damage to sheep In contrast entomopathogenic nematodes parasitize insects and are mostly considered beneficial by humans but some attack beneficial insects One form of nematode is entirely dependent upon fig wasps which are the sole source of fig fertilization They prey upon the wasps riding them from the ripe fig of the wasp s birth to the fig flower of its death where they kill the wasp and their offspring await the birth of the next generation of wasps as the fig ripens Colorized electron micrograph of soybean cyst nematode Heterodera sp and egg A newly discovered parasitic tetradonematid nematode Myrmeconema neotropicum apparently induces fruit mimicry in the tropical ant Cephalotes atratus Infected ants develop bright red gasters abdomens tend to be more sluggish and walk with their gasters in a conspicuous elevated position These changes likely cause frugivorous birds to confuse the infected ants for berries and eat them Parasite eggs passed in the bird s feces are subsequently collected by foraging C atratus and are fed to their larvae thus completing the lifecycle of M neotropicum 58 Similarly multiple varieties of nematodes have been found in the abdominal cavities of the primitively social sweat bee Lasioglossum zephyrus Inside the female body the nematode hinders ovarian development and renders the bee less active thus less effective in pollen collection 59 Agriculture and horticulture Edit Depending on its species a nematode may be beneficial or detrimental to plant health From agricultural and horticulture perspectives the two categories of nematodes are the predatory ones which kill garden pests and the pest nematodes which attack plants or act as vectors spreading plant viruses between crop plants 60 Predatory nematodes include Phasmarhabditis hermaphrodita which is a lethal parasite of gastropods such as slugs and snails 61 Some members of the genus Steinernema such as Steinernema carpocapsae and Steinernema riobrave are generalist parasites of webworms cutworms armyworms girdlers some weevils wood borers and corn earworm moths 62 These organisms are grown commercially as biological pest control agents which can be used as an alternative to pesticides their use is considered very safe 63 Plant parasitic nematodes include several groups causing severe crop losses taking 10 of crops worldwide every year 64 The most common genera are Aphelenchoides foliar nematodes Ditylenchus Globodera potato cyst nematodes Heterodera soybean cyst nematodes Longidorus Meloidogyne root knot nematodes Nacobbus Pratylenchus lesion nematodes Trichodorus and Xiphinema dagger nematodes Several phytoparasitic nematode species cause histological damages to roots including the formation of visible galls e g by root knot nematodes which are useful characters for their diagnostic in the field Some nematode species transmit plant viruses through their feeding activity on roots One of them is Xiphinema index vector of grapevine fanleaf virus an important disease of grapes another one is Xiphinema diversicaudatum vector of arabis mosaic virus Other nematodes attack bark and forest trees The most important representative of this group is Bursaphelenchus xylophilus the pine wood nematode present in Asia and America and recently discovered in Europe Greenhouse growers use beneficial nematodes to control fungus gnats the nematodes enter the larva of the gnats by way of their anus mouth and spiracles breathing pores and then release a bacteria which kills the gnat larvae commonly used nematode species to control pests on greenhouse crops include Steinernema feltiae for fungus gnats and western flower thrips Steinernema carpocapsae used to control shore flies Steinernema kraussei for control of black vine weevils and Heterorhabditis bacteriophora to control beetle larvae 65 Rotations of plants with nematode resistant species or varieties is one means of managing parasitic nematode infestations For example marigolds grown over one or more seasons the effect is cumulative can be used to control nematodes 66 Another is treatment with natural antagonists such as the fungus Gliocladium roseum Chitosan a natural biocontrol elicits plant defense responses to destroy parasitic cyst nematodes on roots of soybean corn sugar beet potato and tomato crops without harming beneficial nematodes in the soil 67 Soil steaming is an efficient method to kill nematodes before planting a crop but indiscriminately eliminates both harmful and beneficial soil fauna The golden nematode Globodera rostochiensis is a particularly harmful variety of nematode pest that has resulted in quarantines and crop failures worldwide CSIRO has found a 13 to 14 fold reduction of nematode population densities in plots having Indian mustard Brassica juncea green manure or seed meal in the soil 68 Epidemiology Edit Disability adjusted life year for intestinal nematode infections per 100 000 in 2002 lt 25 25 50 50 75 75 100 100 120 120 140 140 160 160 180 180 200 200 220 220 240 gt 240 no data source source source source source source Anthelmintic effect of papain on Heligmosomoides bakeri A number of intestinal nematodes cause diseases affecting human beings including ascariasis trichuriasis and hookworm disease Filarial nematodes cause filariases Furthermore studies have shown that parasitic nematodes infect American eels causing damage to the eel s swim bladder 69 dairy animals like cattle and buffalo 70 and all species of sheep 71 Gastrointestinal nematode infections in humans are common with approximately 50 of the global population being affected Developing countries are most heavily impacted in part due to lack of access to medical care 72 Soil ecosystems EditFurther information Soil ecology About 90 of nematodes reside in the top 15 cm 6 of soil Nematodes do not decompose organic matter but instead are parasitic and free living organisms that feed on living material Nematodes can effectively regulate bacterial population and community composition they may eat up to 5 000 bacteria per minute Also nematodes can play an important role in the nitrogen cycle by way of nitrogen mineralization 47 One group of carnivorous fungi the nematophagous fungi are predators of soil nematodes 73 They set enticements for the nematodes in the form of lassos or adhesive structures 74 75 76 Survivability EditNematode worms C elegans part of an ongoing research project conducted on the 2003 Space Shuttle Columbia mission STS 107 survived the re entry breakup It is believed to be the first known life form to survive a virtually unprotected atmospheric descent to Earth s surface 77 78 In a research project published in 2012 it was found that the Antarctic Nematodes P davidi was able to withstand intracellular freezing depending on how well it was fed When compared between fed and starved nematodes the survival rate increased in the fed group and decreased in the starved group 79 See also EditBiological pest control Controlling pests using other organisms Capillaria Genus of roundworms List of organic gardening and farming topics List of parasites of humans Soil food web Toxocariasis Illness of humans caused by larvae of the dog or the cat roundworm A helminth infection of humans caused by the dog or cat roundworm Toxocara canis or Toxocara cati Worm bagging Process where nematode larvae hatch within consume and emerge from the parentReferences Edit Nematode Fossils Nematoda The Virtual Fossil Museum Classification of Animal Parasites Archived from the original on 2017 10 06 Retrieved 2016 02 25 Garcia Lynne 29 October 1999 Classification of Human Parasites Vectors and Similar Organisms Clinical Infectious Diseases Los Angeles California Department of Pathology and Laboratory Medicine UCLA Medical Center 29 4 734 6 doi 10 1086 520425 PMID 10589879 Hay Frank Nematodes the good the bad and the ugly APS News amp Views American Phytopathological Society Retrieved 28 November 2020 Baker Emily A Woollard Alison 2019 How Weird is the Worm Evolution of the Developmental Gene Toolkit in Caenorhabditis elegans Journal of Developmental Biology 7 4 19 doi 10 3390 jdb7040019 PMC 6956190 PMID 31569401 Hodda M 2011 Phylum Nematoda Cobb 1932 In Zhang Z Q Ed Animal biodiversity An outline of higher level classification and survey of taxonomic richness Zootaxa 3148 63 95 doi 10 11646 zootaxa 3148 1 11 Zhang Z 2013 Animal biodiversity An update of classification and diversity in 2013 In Zhang Z Q Ed Animal Biodiversity An Outline of Higher level Classification and Survey of Taxonomic Richness Addenda 2013 Zootaxa 3703 1 5 11 doi 10 11646 zootaxa 3703 1 3 Recent developments in marine benthic biodiversity research ResearchGate Retrieved 5 November 2018 Lambshead PJD 1993 Recent developments in marine benthic biodiversity research Oceanis 19 6 5 24 Anderson Roy C 8 February 2000 Nematode Parasites of Vertebrates Their Development and Transmission CABI pp 1 2 ISBN 9780851994215 Estimates of 500 000 to a million species have no basis in fact Lambshead PJ Boucher G 2003 Marine nematode deep sea biodiversity hyperdiverse or hype Journal of Biogeography 30 4 475 485 doi 10 1046 j 1365 2699 2003 00843 x S2CID 86504164 Qing X Bert W 2019 Family Tylenchidae Nematoda an overview and perspectives Organisms Diversity amp Evolution 19 3 391 408 doi 10 1007 s13127 019 00404 4 S2CID 190873905 Floyd R Abebe E Papert A Blaxter M 2002 Molecular barcodes for soil nematode identification Molecular Ecology 11 4 839 850 doi 10 1046 j 1365 294X 2002 01485 x PMID 11972769 S2CID 12955921 Derycke S Sheibani Tezerji R Rigaux A Moens T 2012 Investigating the ecology and evolution of cryptic marine nematode species through quantitative real time PCR of the ribosomal ITS region Molecular Ecology Resources 12 4 607 619 doi 10 1111 j 1755 0998 2012 03128 x hdl 1854 LU 3127487 PMID 22385909 S2CID 4818657 Blaxter Mark 2016 Imagining Sisyphus happy DNA barcoding and the unnamed majority Philosophical Transactions of the Royal Society of London B 371 1702 20150329 doi 10 1098 rstb 2015 0329 PMC 4971181 PMID 27481781 Borgonie G Garcia Moyano A Litthauer D Bert W Bester A van Heerden E Moller C Erasmus M Onstott TC June 2011 Nematoda from the terrestrial deep subsurface of South Africa Nature 474 7349 79 82 Bibcode 2011Natur 474 79B doi 10 1038 nature09974 hdl 1854 LU 1269676 PMID 21637257 S2CID 4399763 Lemonick MD 8 June 2011 Could worms from Hell mean there s life in space Time ISSN 0040 781X Archived from the original on 10 June 2011 Retrieved 8 June 2011 Bhanoo SN 1 June 2011 Nematode found in mine is first subsurface multicellular organism The New York Times ISSN 0362 4331 Retrieved 13 June 2011 Gold mine Nature 474 7349 6 June 2011 doi 10 1038 474006b PMID 21637213 Drake N 1 June 2011 Subterranean worms from hell Nature News Nature News doi 10 1038 news 2011 342 Retrieved 13 June 2011 Borgonie G Garcia Moyano A Litthauer D Bert W Bester A van Heerden E Moller C Erasmus M Onstott TC 2 June 2011 Nematoda from the terrestrial deep subsurface of South Africa Nature 474 7349 79 82 Bibcode 2011Natur 474 79B doi 10 1038 nature09974 hdl 1854 LU 1269676 ISSN 0028 0836 PMID 21637257 S2CID 4399763 Danovaro R Gambi C Dell Anno A Corinaldesi C Fraschetti S Vanreusel A Vincx M Gooday AJ January 2008 Exponential decline of deep sea ecosystem functioning linked to benthic biodiversity loss Curr Biol 18 1 1 8 doi 10 1016 j cub 2007 11 056 PMID 18164201 S2CID 15272791 Deep sea species loss could lead to oceans collapse study suggests EurekAlert Press release 27 December 2007 a b van den Hoogen Johan Geisen Stefan Routh Devin Ferris Howard Traunspurger Walter Wardle David A de Goede Ron G M Adams Byron J Ahmad Wasim 2019 07 24 Soil nematode abundance and functional group composition at a global scale Nature 572 7768 194 198 Bibcode 2019Natur 572 194V doi 10 1038 s41586 019 1418 6 hdl 20 500 11755 c8c7bc6a 585c 4a13 9e36 4851939c1b10 ISSN 0028 0836 PMID 31341281 S2CID 198492891 Archived from the original on 2020 03 02 Retrieved 2019 12 10 Platt HM 1994 foreword In Lorenzen S Lorenzen SA eds The phylogenetic systematics of freeliving nematodes London UK The Ray Society ISBN 978 0 903874 22 9 Cary S Craig Green T G Allan Storey Bryan C Sparrow Ashley D Hogg Ian D Katurji Marwan Zawar Reza Peyman Jones Irfon Stichbury Glen A 2019 02 15 Biotic interactions are an unexpected yet critical control on the complexity of an abiotically driven polar ecosystem Communications Biology 2 1 62 doi 10 1038 s42003 018 0274 5 ISSN 2399 3642 PMC 6377621 PMID 30793041 Adams Byron J Wall Diana H Storey Bryan C Green T G Allan Barrett John E S Craig Cary Hopkins David W Lee Charles K Bottos Eric M 2019 02 15 Nematodes in a polar desert reveal the relative role of biotic interactions in the coexistence of soil animals Communications Biology 2 1 63 doi 10 1038 s42003 018 0260 y ISSN 2399 3642 PMC 6377602 PMID 30793042 a b Roy C Anderson 8 February 2000 Nematode Parasites of Vertebrates Their development and transmission CABI p 1 ISBN 978 0 85199 786 5 Cobb Nathan 1914 Nematodes and their relationships Yearbook United States Department of Agriculture pp 472 457 490 Archived from the original on 9 June 2016 Retrieved 25 September 2012 Quote on p 472 a b c Chitwood BG 1957 The English word Nema revised Systematic Biology 4 45 1619 doi 10 2307 sysbio 6 4 184 Siddiqi MR 2000 Tylenchida parasites of plants and insects Wallingford Oxon UK CABI Pub ISBN 978 0 85199 202 0 Schmidt Rhaesa A 2014 Gastrotricha Cycloneuralia and Gnathifera General History and Phylogeny In Schmidt Rhaesa A ed Handbook of Zoology founded by W Kukenthal Vol 1 Nematomorpha Priapulida Kinorhyncha Loricifera Berlin Boston de Gruyter Cobb NA 1919 The orders and classes of nemas Contrib Sci Nematol 8 213 216 Wilson E O Phylum Nemata Plant and insect parasitic nematodes Archived from the original on 30 April 2018 Retrieved 29 April 2018 ITIS report Nematoda Itis gov Retrieved 12 June 2012 Bilateria Tree of Life Web Project Tree of Life Web Project 2002 Retrieved 2 November 2008 Chitwood BG Chitwood MB 1933 The characters of a protonematode J Parasitol 20 130 Chitwood BG 1937 A revised classification of the Nematoda Papers on Helminthology published in commemoration of the 30 year Jubileum of K J Skrjabin Moscow All Union Lenin Academy of Agricultural Sciences pp 67 79 Chitwood BG 1958 The designation of official names for higher taxa of invertebrates Bull Zool Nomencl 15 860 895 doi 10 5962 bhl part 19410 Coghlan A 7 Sep 2005 Nematode genome evolution PDF WormBook 1 15 doi 10 1895 wormbook 1 15 1 PMC 4781476 PMID 18050393 Archived from the original PDF on 5 March 2016 Retrieved 13 January 2016 Blaxter ML De Ley P Garey JR Liu LX Scheldeman P Vierstraete A Vanfleteren JR Mackey LY Dorris M Frisse LM Vida JT Thomas WK March 1998 A molecular evolutionary framework for the phylum Nematoda Nature 392 6671 71 75 Bibcode 1998Natur 392 71B doi 10 1038 32160 PMID 9510248 S2CID 4301939 Nematoda Tree of Life Web Project Tree of Life Web Project 2002 Retrieved 2 November 2008 Holterman M van der Wurff A van den Elsen S van Megen H Bongers T Holovachov O Bakker J Helder J 2006 Phylum wide analysis of SSU rDNA reveals deep phylogenetic relationships among nematodes and accelerated evolution toward crown Clades Mol Biol Evol 23 9 1792 1800 doi 10 1093 molbev msl044 PMID 16790472 a b Khadka Bijendra Chatterjee Tonuka Gupta Bhagwati P Gupta Radhey S 2019 09 24 Genomic Analyses Identify Novel Molecular Signatures Specific for the Caenorhabditis and other Nematode Taxa Providing Novel Means for Genetic and Biochemical Studies Genes 10 10 739 doi 10 3390 genes10100739 ISSN 2073 4425 PMC 6826867 PMID 31554175 959 Nematode Genomes NematodeGenomes Nematodes org 11 November 2011 Archived from the original on 5 August 2015 Retrieved 12 June 2012 Liu GH Shao R Li JY Zhou DH Li H Zhu XQ 2013 The complete mitochondrial genomes of three parasitic nematodes of birds a unique gene order and insights into nematode phylogeny BMC Genomics 14 1 414 doi 10 1186 1471 2164 14 414 PMC 3693896 PMID 23800363 Hodda M 2022 Phylum Nematoda a classification catalogue and index of valid genera with a census of valid species Zootaxa 5114 1 1 289 doi 10 11646 zootaxa 5114 1 1 PMID 35391386 a b Nyle C Brady amp Ray R Weil 2009 Elements of the Nature and Properties of Soils 3rd ed Prentice Hall ISBN 9780135014332 Ruppert EE Fox RS Barnes RD 2004 Invertebrate Zoology A Functional Evolutionary Approach 7th ed Belmont California Brooks Cole ISBN 978 0 03 025982 1 Weischer B Brown DJ 2000 An Introduction to Nematodes General Nematology Sofia Bulgaria Pensoft pp 75 76 ISBN 978 954 642 087 9 a b c d e f g h i j k l m Barnes RG 1980 Invertebrate zoology Philadelphia Sanders College ISBN 978 0 03 056747 6 Free living Marine Nematodes from the East China Sea The sensory cilia of Caenorhabditis elegans www wormbook org Kavlie RG Kernan MJ Eberl DF May 2010 Hearing in Drosophila requires TilB a conserved protein associated with ciliary motility Genetics 185 1 177 88 doi 10 1534 genetics 110 114009 PMC 2870953 PMID 20215474 Lalosevic V Lalosevic D Capo I Simin V Galfi A Traversa D 2013 High infection rate of zoonotic Eucoleus aerophilus infection in foxes from Serbia Parasite 20 3 doi 10 1051 parasite 2012003 PMC 3718516 PMID 23340229 Bell G 1982 The masterpiece of nature the evolution and genetics of sexuality Berkeley University of California Press ISBN 978 0 520 04583 5 a b Johnigk SA Ehlers RU 1999 Endotokia matricida in hermaphrodites of Heterorhabditis spp and the effect of the food supply Nematology 1 7 8 717 726 doi 10 1163 156854199508748 ISSN 1388 5545 S2CID 85279418 Haag ES Helder J Mooijman PJ Yin D Hu S 2018 The Evolution of Uniparental Reproduction in Rhabditina Nematodes Phylogenetic Patterns Developmental Causes and Surprising Consequences In Leonard J L ed Transitions Between Sexual Systems Springer pp 99 122 doi 10 1007 978 3 319 94139 4 4 ISBN 978 3 319 94137 0 Yanoviak SP Kaspari M Dudley R Poinar G April 2008 Parasite induced fruit mimicry in a tropical canopy ant Am Nat 171 4 536 44 doi 10 1086 528968 PMID 18279076 S2CID 23857167 Batra Suzanne W T 1965 10 01 Organisms associated with Lasioglossum zephyrum Hymenoptera Halictidae Journal of the Kansas Entomological Society 38 4 367 389 JSTOR 25083474 Purcell M Johnson MW Lebeck LM Hara AH 1992 Biological Control of Helicoverpa zea Lepidoptera Noctuidae with Steinernema carpocapsae Rhabditida Steinernematidae in Corn Used as a Trap Crop Environmental Entomology 21 6 1441 1447 doi 10 1093 ee 21 6 1441 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint uses authors parameter link Wilson M J Glen D M George S K January 1993 The rhabditid nematode Phasmarhabditis hermaphrodita as a potential biological control agent for slugs Biocontrol Science and Technology 3 4 503 511 doi 10 1080 09583159309355306 Rajamani Meenatchi Negi Aditi 2021 Biopesticides for Pest Management Sustainable Bioeconomy 239 266 doi 10 1007 978 981 15 7321 7 11 ISBN 978 981 15 7320 0 S2CID 228845133 Ehlers R U Hokkanen H M T September 1996 Insect Biocontrol with Non endemic Entomopathogenic Nematodes Steinernema and Heterorhabditis spp Conclusions and Recommendations of a Combined OECD and COST Workshop on Scientific and Regulatory Policy Issues Biocontrol Science and Technology 6 3 295 302 doi 10 1080 09583159631280 Smiley RW Dababat AA Iqbal S Jones MG Maafi ZT Peng D Subbotin SA Waeyenberge L 2017 Cereal Cyst Nematodes A Complex and Destructive Group of Heterodera Species Plant Disease American Phytopathological Society 101 10 1692 1720 doi 10 1094 pdis 03 17 0355 fe ISSN 0191 2917 PMID 30676930 Kloosterman Stephen April 2022 Small Soldiers Green House Product News Vol 32 no 4 pp 26 29 Riotte L 1975 Secrets of companion planting for successful gardening p 7 US application 2008072494 Stoner RJ Linden JC Micronutrient elicitor for treating nematodes in field crops published 2008 03 27 Loothfar R Tony S 22 March 2005 Suppression of root knot nematode Meloidogyne javanica after incorporation of Indian mustard cv Nemfix as green manure and seed meal in vineyards Australasian Plant Pathology 34 1 77 83 doi 10 1071 AP04081 S2CID 24299033 Retrieved 14 June 2010 Warshafsky Z T Tuckey T D Vogelbein W K Latour R J amp Wargo A R 2019 Temporal spatial and biological variation of nematode epidemiology in American eels Canadian Journal of Fisheries amp Aquatic Sciences 76 10 1808 1818 https doi org 10 1139 cjfas 2018 0136 Jithendran amp Bhat T 1999 Epidemiology of Parasitoses in Dairy Animals in the North West Humid Himalayan Region of India with Particular Reference to Gastrointestinal Nematodes Tropical Animal Health and Production 31 4 205 214 https doi org 10 1023 A 1005263009921 Morgan amp van Dijk J 2012 Climate and the epidemiology of gastrointestinal nematode infections of sheep in Europe Veterinary Parasitology 189 1 8 14 https doi org 10 1016 j vetpar 2012 03 028 Stepek Gillian Buttle David J Duce Ian R Behnke Jerzy M October 2006 Human gastrointestinal nematode infections are new control methods required International Journal of Experimental Pathology 87 5 325 341 doi 10 1111 j 1365 2613 2006 00495 x ISSN 0959 9673 PMC 2517378 PMID 16965561 Nosowitz Fan 2021 02 08 How California Crops Fought Off a Pest Without Using Pesticide Modern Farmer Retrieved 2021 02 15 Pramer C 1964 Nematode trapping fungi Science 144 3617 382 388 Bibcode 1964Sci 144 382P doi 10 1126 science 144 3617 382 PMID 14169325 Hauser JT December 1985 Nematode trapping fungi PDF Carnivorous Plant Newsletter 14 1 8 11 Ahren D Ursing BM Tunlid A 1998 Phylogeny of nematode trapping fungi based on 18S rDNA sequences FEMS Microbiology Letters 158 2 179 184 doi 10 1016 s0378 1097 97 00519 3 PMID 9465391 Columbia Survivors Astrobiology Magazine Jan 1 2006 Archived from the original on March 4 2016 Retrieved January 12 2016 a href Template Cite magazine html title Template Cite magazine cite magazine a CS1 maint unfit URL link Szewczyk Nathaniel J Mancinelli Rocco L McLamb William Reed David Blumberg Baruch S Conley Catharine A December 2005 Caenorhabditis elegans Survives Atmospheric Breakup of STS 107 Space Shuttle Columbia Astrobiology 5 6 690 705 Bibcode 2005AsBio 5 690S doi 10 1089 ast 2005 5 690 PMID 16379525 Raymond Melianie R Wharton David A February 2013 The ability of the Antarctic nematode Panagrolaimus davidi to survive intracellular freezing is dependent upon nutritional status Journal of Comparative Physiology B 183 2 181 188 doi 10 1007 s00360 012 0697 0 ISSN 0174 1578 PMID 22836298 S2CID 17294698 Further reading EditAtkinson H J 1973 The respiratory physiology of the marine nematodes Enoplus brevis Bastian and E communis Bastian I The influence of oxygen tension and body size PDF J Exp Biol 59 1 255 266 doi 10 1242 jeb 59 1 255 Worms survived Columbia disaster BBC News 1 May 2003 Retrieved 4 Nov 2008 Gubanov N M 1951 Giant nematoda from the placenta of Cetacea Placentonema gigantissima nov gen nov sp Proc USSR Acad Sci 77 6 1123 1125 in Russian Kaya Harry K et al 1993 An Overview of Insect Parasitic and Entomopathogenic Nematodes In Bedding R A ed Nematodes and the Biological Control of Insect Pests Csiro Publishing ISBN 9780643105911 Giant kidney worm infection in mink and dogs Merck Veterinary Manual MVM 2006 Archived from the original on 3 March 2016 Retrieved 10 February 2007 White JG Southgate E Thomson JN Brenner S August 1976 The structure of the ventral nerve cord of Caenorhabditis elegans Philos Trans R Soc Lond B Biol Sci 275 938 327 348 Bibcode 1976RSPTB 275 327W doi 10 1098 rstb 1976 0086 PMID 8806 Lee Donald L ed 2010 The biology of nematodes London Taylor amp Francis ISBN 978 0415272117 Retrieved 16 December 2014 De Ley P Blaxter M 2004 A new system for Nematoda combining morphological characters with molecular trees and translating clades into ranks and taxa In R Cook DJ Hunt eds Nematology Monographs and Perspectives Vol 2 E J Brill Leiden pp 633 653 External links Edit Wikimedia Commons has media related to Nematoda Wikisource has the text of the 1911 Encyclopaedia Britannica article Nematoda Harper Adams University College Nematology Research Nematodes roundworms of man http www ucmp berkeley edu phyla ecdysozoa nematoda html European Society of Nematologists Nematode net Repository of parasitic nematode sequences Archived 2015 02 14 at the Wayback Machine http webarchive loc gov all 20020914155908 http www nematodes org NeMys World free living Marine Nematodes database Nematode Virtual Library International Federation of Nematology Societies Society of Nematologists Australasian Association of Nematologists Research on nematodes and longevity Nematode on BBC Nematode worms in an aquarium Phylum Nematoda nematodes on the UF IFAS Featured Creatures Web site Retrieved from https en wikipedia org w index php title Nematode amp oldid 1136424394, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.