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线虫捕食性真菌 (Xiànchóng bǔshí xìng zhēnjūn)
Nematophagous Fungus

原始链接: https://en.wikipedia.org/wiki/Nematophagous_fungus

## 捕线虫真菌:大自然的线虫捕食者 捕线虫真菌是一个多样化的群体——超过700个物种——是专门捕获和消化线虫的食肉真菌。它们在全球各种栖息地都有发现,尤其是在氮贫瘠的土壤中,这些真菌运用着令人着迷的捕食技术。这些技术包括粘性陷阱、收缩环、使猎物麻痹的毒素,甚至寄生进入线虫卵。 像*Arthrobotrys*这样的真菌通过信息素探测线虫,仅在猎物靠近时才主动构建陷阱,从而最大限度地提高能量效率。其他真菌,如*Coprinus comatus*,使用棘状结构破坏线虫角质层后再进行消化。有些物种甚至模仿线虫的吸引物来引诱它们靠近。 这些真菌对生物害虫防治非常有价值,例如*Purpureocillium lilacinum*在控制损害农作物的根结线虫方面显示出潜力。 能够以线虫为食的能力在许多真菌类群中独立进化,突显了它们作为天然线虫调节器的生态重要性。 研究仍在继续探索它们在可持续农业方面的潜力。

这场 Hacker News 讨论围绕着**食线虫真菌**——以线虫(圆虫)为食的真菌。最初的帖子链接到维基百科上关于该主题的文章。 用户很快扩展了讨论,指出**平菇**也被认为是线虫捕食者,利用毒素捕捉猎物。然而,入侵北美的**金针菇**引起了担忧,因为它高效的杀线虫能力正在排挤本地真菌。 进一步的问题是关于这些真菌是否可以用于对抗**山毛榉叶病 (BLD)**。虽然由于病原体位于叶组织中,直接应用具有挑战性,但讨论指出研究**内生真菌**和**叶片微生物群**可能是解决问题的途径。
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原文

Carnivorous fungi specialized in trapping and digesting nematodes

A dead nematode with Harposporium anguillulae growing out of it. Numbered ticks are 122 μm apart.
A closer look at H. anguillulae from the previous image. Numbered ticks are 20 μm apart.
A fungus of the genus Arthrobotrys, showing adhesive nets which it uses to trap nematodes.  Numbered ticks are 122 μm apart.

Nematophagous fungi are carnivorous fungi specialized in trapping and digesting nematodes. More than 700 species are known.[1] 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.[2] 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.[3] Nematophagous fungi can be useful in controlling those nematodes that eat crops. Purpureocillium, for example, can be used as a bio-nematicide.

Fungi that feed on nematodes (as the most abundant and convenient prey species) mostly live in nitrogen-deficient habitats.[4] These fungi can be divided into four main groups according to the methods they use to catch their prey. Some use a mechanical means, an adhesive or a mechanical hyphal trap. Some produce a toxin and use it to immobilise the nematode. Some are parasitic, using their spores to gain entry into their prey, and some are egg parasites, inserting their hyphal tips into the eggs or cysts, or into females before the eggs are deposited.

Nematophagous fungi have been found throughout the world in a wide range of habitats and climates, but few from extreme environments. Most studied have been the species that attack the nematodes of interest to farmers, horticulturists and foresters, but there are large numbers of species as yet undescribed. The sexual stage of Orbilia occurs on rotting wood on land or in fresh water, while the asexual stage occurs in marine, fresh water and terrestrial habitats. Arthrobotrys dactyloides was the first species to be discovered in brackish water, and other species have been found on mangroves.

Nematode-trapping fungi are mostly concentrated in the upper part of the soil, in pastures, leaf litter, mangroves and certain shallow aquatic habitats. They employ techniques such as adhesive hyphal strands, adhesive knobs, adhesive nets formed from hyphal threads, loops of hyphae which tighten round any ensnared nematodes and non-constricting loops. When the nematode has been restrained, the hyphae penetrate the cuticle and the internal tissues of the nematode are devoured.

Arthrobotrys oligospora, a net-building species of fungus, can detect the presence of nematodes nearby in the soil and only builds its snares when they are present. This is presumably because building the net is a highly energy-consuming process; the fungus is alerted to the presence of the nematode by detecting the pheromones, such as ascarosides, with which the worms communicate. The fungus takes active steps to attract its prey by producing olfactory cues that mimic those used by the worm to find food and attract mates.[4] Arthrobotrys dactyloides is a species that employs a loop of hypha to catch nematodes; when one tries to pass through the ring, the loop constricts with great rapidity, trapping the prey.

The hyphae of shaggy ink caps attack nematodes
Juvenile root-knot nematode (Meloidogyne incognita) penetrating a tomato root

Some nematophagous fungi produce toxic substances which immobilise nematodes. For example, the hypha of the shaggy ink cap (Coprinus comatus) attacks the free-living soil nematode Panagrellus redivivus with a structure known as a spiny ball; this is used to damage the nematode cuticle to enable immobilisation, after which the hypha pierces the skin and digests the contents.[8]

Most endoparasitic fungi have spores that are attracted to soil nematodes and tend to congregate in the mouth region. Having penetrated the cuticle, the hyphae grow throughout the nematode, absorbing its tissues. Escape tubes emerge from these and grow through the cuticle, and in due course, further motile spores exit through these, ready to infect other nematodes. In other species of fungi, it is conidia rather than spores which are encountered by the nematode and infect it in a similar way.[9] In the case of Harposporium anguillulae, the sickle-shaped conidia are ingested by the nematode and lodge in the oesophagus or gut from where they invade the tissues.[10]

In ovoparasitic species, the hypha flattens itself against an egg, appressoria indicating that infection is imminent or underway. It then pierces the chorion and devours the embryonic nematode before producing conidiophores and moving on to nearby eggs.[11]

Some species of nematophagous fungi are being investigated for use in biological pest control. Purpureocillium lilacinum, for example, infests the plant-parasitic Meloidogyne incognita, which attacks the roots of many cultivated plants. Trials have provided varying results, with some strains being aggressive and others less pathogenic, and some strains that appeared promising in the lab proved ineffective in the field.[12] Arthrobotrys dactyloides shows promise at controlling the cosmopolitan plant-parasitic root-knot nematode Meloidogyne javanica.

Fungus

Entomopathogenic fungus

Biological pest control

  1. ^ Soares, Filipe (5 June 2018). "Nematophagous fungi: Far beyond the endoparasite, predator and ovicidal groups". Agriculture and Natural Resources. 52: 1–8. Retrieved 10 November 2024.
  2. ^ Thorn, R. Greg; Moncalvo, Jean-Marc; Reddy, C. A.; Vilgalys, Rytas (2000). "Phylogenetic Analyses and the Distribution of Nematophagy Support a Monophyletic Pleurotaceae within the Polyphyletic Pleurotoid-Lentinoid Fungi". Mycologia. 92 (2): 241–252. doi:10.2307/3761557. JSTOR 3761557.
  3. ^ Nordbring-Hertz, Birgit; Jansson, Hans-Börje; Tunlid, Anders (2011). "Nematophagous fungi". eLS. doi:10.1002/9780470015902.a0000374.pub3. ISBN 9780470016176.
  4. ^ a b Hsueh, Yen-Ping; Gronquist, Matthew R.; Schwarz, Erich M.; Nath, Ravi David; Lee, Ching-Han; Gharib, Shalha; Schroeder, Frank C.; Sternberg, Paul W. (2017). "Nematophagous fungus Arthrobotrys oligospora mimics olfactory cues of sex and food to lure its nematode prey". eLife. 6. doi:10.7554/eLife.20023. PMC 5243009. PMID 28098555.
  5. ^ Luo, H.; Liu, Y.; Fang, L.; Li, X.; Tang, N.; Zhang, K. (2007). "Coprinus comatus Damages Nematode Cuticles Mechanically with Spiny Balls and Produces Potent Toxins to Immobilize Nematodes". Applied and Environmental Microbiology. 73 (12): 3916–3923. Bibcode:2007ApEnM..73.3916L. doi:10.1128/AEM.02770-06. PMC 1932715. PMID 17449690.
  6. ^ "Nematophagous fungi: part 1". World News. 13 March 2011. Retrieved 30 September 2017.
  7. ^ Aschner, M.; Kohn, S. (1958). "The Biology of Harposporium anguillulae". Microbiology. 19 (1): 182–189. doi:10.1099/00221287-19-1-182. PMID 13575766.
  8. ^ Money, N.P. (1998). "Mechanics of invasive fungal growth and the significance of turgor in plant infection". Molecular genetics of host-specific toxins in plant disease. Kluwer Academic Publishers. pp. 261–71.
  9. ^ Jatala, P. (1986). "Biological control of plant-parasitic nematodes". Annual Review of Phytopathology. 24: 453–89. doi:10.1146/annurev.py.24.090186.002321.
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