Mononchoides fortidens

Mononchoides fortidens
Scientific classification
Domain:	Eukaryota
Kingdom:	Animalia
Phylum:	Nematoda
Class:	Chromadorea
Order:	Rhabditida
Family:	Diplogasteridae
Genus:	Mononchoides
Species:	M. fortidens
Binomial name
	Mononchoides fortidens; Schuurmans Stekhoven, 1951

Last updated February 18, 2024

Mononchoides fortidens, of the order Diplogasterida, is a free-living predacious nematode that feeds on both nematodes and bacteria .^[1]The predatory behavior of this nematode presents the opportunity to use it as a bio-control agent against other plant parasitic nematodes. It has been shown to have a preference for the second stage juveniles of Meloidogyne incognita .^[2]

Distribution and morphology

M. fortidens may be found in decomposing organic manure.^[1] Morphological features include lips with setose papillae, large amphid apertures, and a mobile claw-like tooth. The female is diovarial and amphidelphic, while the male is without bursa and has nine pairs of genital papillae.^[3] The tails of both the male and female are filiform^[3]

Predatory behavior

M. fortidens prefers small, slow moving prey.^[2] Once they’ve pierced the cuticle, they feed by cutting and sucking or swallowing their prey whole.^[4] They have also been shown to aggregate and feed from prey in groups. This positive aggregation response may be in part due to prey secretions/attractions that M. fortidens senses.^[5] Other factors affecting attraction include prey number, temperature, starvation, and distance between predator and prey.^[5] Bilgrami and Jairajpuri^[5] found that attraction to prey improved when prey number increased and when M. fortidens was starved for 12 days. Predation of Meloidogyne incognita by M. fortidens plateaued at temperatures between 30 and 35°C^[5]

Bio-control applications

The use of predatory nematodes as a biological control agent for plant-parasitic nematodes was suggested by Cobb.^[6]M. fortidens is a reasonable choice for bio-control due to its short life cycle and easy culturability.^[7]M. fortidens was used in experiments investigating their potential as a bio-control for the root-knot nematode Meloidogyne arenaria in tomato.^[1] Khan and Kim^[1] found that the final population of M. arenaria decreased exponentially with increasing application densities of M. fortidens. When pots were treated with M. fortidens 7 days prior to planting, plant growth increased while root galling and final populations of M. arenaria decreased significantly^[1]

Related Research Articles

Root-knot nematodes are plant-parasitic nematodes from the genus Meloidogyne. They exist in soil in areas with hot climates or short winters. About 2000 plants worldwide are susceptible to infection by root-knot nematodes and they cause approximately 5% of global crop loss. Root-knot nematode larvae infect plant roots, causing the development of root-knot galls that drain the plant's photosynthate and nutrients. Infection of young plants may be lethal, while infection of mature plants causes decreased yield.

Meloidogyne incognita, also known as the southern root-nematode or cotton root-knot nematode is a plant-parasitic roundworm in the family Heteroderidae. This nematode is one of the four most common species worldwide and has numerous hosts. It typically incites large, usually irregular galls on roots as a result of parasitism.

Meloidogyne arenaria is a species of plant pathogenic nematodes. This nematode is also known as the peanut root knot nematode. The word "Meloidogyne" is derived from two Greek words that mean "apple-shaped" and "female". The peanut root knot nematode, M. arenaria is one of the "major" Meloidogyne species because of its worldwide economic importance. M. arenaria is a predominant nematode species in the United States attacking peanut in Alabama, Florida, Georgia, and Texas. The most damaging nematode species for peanut in the USA is M. arenaria race 1 and losses can exceed 50% in severely infested fields. Among the several Meloidogyne species that have been characterized, M. arenaria is the most variable both morphologically and cytologically. In 1949, two races of this nematode had been identified, race 1 which reproduces on peanut and race 2 which cannot do so. However, in a recent study, three races were described. López-Pérez et al (2011) had also studied populations of M. arenaria race 2, which reproduces on tomato plants carrying the Mi gene and race 3, which reproduces on both resistant pepper and tomato.

Aphelenchoides ritzemabosi is a plant pathogenic nematode. It was first scientifically described in 1890 in England. This nematode has a wide host range. Among the most important species affected are Chrysanthemums and strawberries. A. ritzemabosi is a migratory foliar feeding nematode. It can feed both ectoparasitically and endoparasitically, with the later causing the most significant damage. When adequate moisture is present, this nematode enters the leaves and feeds from inside the tissue. Typical damage is characterized by necrotic zones between the veins of the leaves. Its lifecycle is short; only ten days from egg to mature adult. A single female can lay as many as 3,500 eggs. This pest can be difficult to control. Host plant resistance, hot water treatments, and predatory mites are recommended.

Meloidogyne javanica is a species of plant-pathogenic nematodes. It is one of the tropical root-knot nematodes and a major agricultural pest in many countries. It has many hosts. Meloidogyne javanica reproduces by obligatory mitotic parthenogenesis (apomixis).

Pratylenchus brachyurus is a plant parasitic nematode.

Tylenchorhynchus claytoni is a plant pathogenic nematode.

Mesocriconema xenoplax is a species of plant parasitic nematodes. Nematodes of this particular species are collectively called ring nematodes.

There are many plant-parasitic species in the root-knot nematode genus (Meloidogyne) that attack coffee such as M. incognita, M. arenaria, M. exigua, M. javanica and M. coffeicola. Study has already shown interspecific variability coffee, in which show how this species can be adapting to new hosts and environments.

Heterodera sacchari, the sugarcane cyst nematode, mitotic parthenogenic sedentary endoparasitic nematode. This plant-parasitic nematode infects the roots of sugarcane, and the female nematode eventually becomes a thick-walled cyst filled with eggs. Aboveground symptoms are species specific and are similar to those caused by other Heterodera species. Symptoms include: stunted and chlorotic plants, and reduced root growth. Seedlings may be killed in heavily infested soils.

Nematophagous fungi are carnivorous fungi specialized in trapping and digesting nematodes. Around 160 species are known. Species exist that live inside the nematodes from the beginning and others that catch them, mostly with glue traps or in rings, some of which constrict on contact. Some species possess both types of traps. Another technique is to stun the nematodes using toxins, a method employed by Coprinus comatus, Stropharia rugosoannulata, and the family Pleurotaceae. The habit of feeding on nematodes has arisen many times among fungi, as is demonstrated by the fact that nematophagous species are found in all major fungal groups. Nematophagous fungi can be useful in controlling those nematodes that eat crops. Purpureocillium, for example, can be used as a bio-nematicide.

<span class="mw-page-title-main">Nematode</span> Phylum of worms with tubular digestive systems with openings at both ends

The nematodes, roundworms or eelworms constitute the phylum Nematoda. They are a diverse animal phylum inhabiting a broad range of environments. Most species are free-living, feeding on microorganisms, but there are many that are parasitic. The parasitic worms (helminths) are the cause of soil-transmitted helminthiases.

Purpureocillium lilacinum is a species of filamentous fungus in the family Ophiocordycipitaceae. It has been isolated from a wide range of habitats, including cultivated and uncultivated soils, forests, grassland, deserts, estuarine sediments and sewage sludge, and insects. It has also been found in nematode eggs, and occasionally from females of root-knot and cyst nematodes. In addition, it has frequently been detected in the rhizosphere of many crops. The species can grow at a wide range of temperatures – from 8 to 38 °C for a few isolates, with optimal growth in the range 26 to 30 °C. It also has a wide pH tolerance and can grow on a variety of substrates. P. lilacinum has shown promising results for use as a biocontrol agent to control the growth of destructive root-knot nematodes.

Mononchoides is a quite common genus in the phylum of the Nematoda and by far the most diverse genus of the family of the Diplogasteridae. It has been described to live in various terrestrial habitats and is often associated with compost, dung, mud, other decaying materials and different kinds of beetles. Some have even been described from fresh water and marine habitats. In 2011, a new species has been described by Steel et al. This species was isolated from compost during the composting process and was named Mononchoides composticola.

Hoplolaimus galeatus is a plant pathogenic nematode.

Paratrichodorus is a genus of terrestrial root feeding (stubby-root) nematodes in the Trichodoridae family (trichorids), being one of five genera. They are economically important plant parasites and virus vectors. The females are didelphic, and are distributed worldwide.

Diphtherophorina is a suborder of terrestrial nematodes, being one of three that constitute suborder Triplonchida.

Trichodoridae is a family of terrestrial root feeding nematodes, being one of two that constitute suborder Triplonchida. They are economically important plant parasites and virus vectors.

Trichodorus is a genus of terrestrial root feeding (stubby-root) nematodes in the Trichodoridae family (trichorids), being one of five genera. They are economically important plant parasites and virus vectors.

Allodiplogaster sudhausi is a free-living nematode species in the Diplogastridae family. It was described in 2008 as Koerneria sudhausi, before being moved to the genus Allodiplogaster in 2014. A. sudhausi is omnivorous. It predates on other nematodes, but can be cultured on Escherichia coli OP50 bacterium on agar.

References

1 2 3 4 5 Khan, Z.; Kim, Y.H. (October 2005). "The predatory nematode, Mononchoides fortidens (Nematoda: Diplogasterida), suppresses the root-knot nematode, Meloidogyne arenaria, in potted field soil". Biological Control. 35 (1): 78–82. doi:10.1016/j.biocontrol.2005.05.015.
1 2 Devi, Gitanjali; George, Jisna (24 February 2018). "Predatory nematodes as bio-control agent against plant-parasitic nematode-A review". Agricultural Reviews. 38 (1). doi: 10.18805/ag.R-1715 .
1 2 [nemaplex.ucdavis.edu/Taxadata/Neodidae.htm "Neodiplogastridae"]. nemaplex.ucdavis.edu.{{cite web}}: Check |url= value (help)
↑ Bilgrami, Anwar; Gaugler, Randy; Brey, Christopher (2005). "Prey preference and feeding behaviour of the diplogastrid predator Mononchoides gaugleri (Nematoda: Diplogastrida)". Nematology. 7 (3): 333–342. doi:10.1163/156854105774355563.
1 2 3 4 Jairajpuri, M.S.; Bilgrami, A.L. (1989). "Predatory Abilities of Mononchoides Longicaudatus and M. Fortidens (Nematoda: Diplogasterida) and Factors Influencing Predation". Nematologica. 35 (4): 475–488. doi:10.1163/002825989X00223.
↑ Cobb, Nathan (1917). "The mononchs: a genus of free-living predatory nematodes". Soil Science. 3: 431–486. doi:10.1097/00010694-191705000-00004. S2CID 83756576.
↑ Yeates, G.W. (1969). "Predation By Mononchoides Potohikus (Nematoda: Diplogasteridae) in Laboratory Culture". Nematologica. 15 (1): 3–9. doi:10.1163/187529269X00029.

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[khan-1] 1 2 3 4 5 Khan, Z.; Kim, Y.H. (October 2005). "The predatory nematode, Mononchoides fortidens (Nematoda: Diplogasterida), suppresses the root-knot nematode, Meloidogyne arenaria, in potted field soil". Biological Control. 35 (1): 78–82. doi:10.1016/j.biocontrol.2005.05.015.

[devi-2] 1 2 Devi, Gitanjali; George, Jisna (24 February 2018). "Predatory nematodes as bio-control agent against plant-parasitic nematode-A review". Agricultural Reviews. 38 (1). doi: 10.18805/ag.R-1715 .

[nema-3] 1 2 [nemaplex.ucdavis.edu/Taxadata/Neodidae.htm "Neodiplogastridae"]. nemaplex.ucdavis.edu.{{cite web}}: Check |url= value (help)

[4] Bilgrami, Anwar; Gaugler, Randy; Brey, Christopher (2005). "Prey preference and feeding behaviour of the diplogastrid predator Mononchoides gaugleri (Nematoda: Diplogastrida)". Nematology. 7 (3): 333–342. doi:10.1163/156854105774355563.

[bil-5] 1 2 3 4 Jairajpuri, M.S.; Bilgrami, A.L. (1989). "Predatory Abilities of Mononchoides Longicaudatus and M. Fortidens (Nematoda: Diplogasterida) and Factors Influencing Predation". Nematologica. 35 (4): 475–488. doi:10.1163/002825989X00223.

[6] Cobb, Nathan (1917). "The mononchs: a genus of free-living predatory nematodes". Soil Science. 3: 431–486. doi:10.1097/00010694-191705000-00004. S2CID 83756576.

[7] Yeates, G.W. (1969). "Predation By Mononchoides Potohikus (Nematoda: Diplogasteridae) in Laboratory Culture". Nematologica. 15 (1): 3–9. doi:10.1163/187529269X00029.

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