Biology:Mucoromycotina

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Short description: Subphylum of fungi

Mucoromycotina
Mature sporangium of a Mucor sp. fungus.jpg
A sporangium of a Mucoralean fungus
Scientific classification e
Domain: Eukaryota
Kingdom: Fungi
Division: Mucoromycota
Subdivision: Mucoromycotina
Benny
Orders

Mucoromycotina is a subphylum of uncertain placement in Fungi. It was considered part of the phylum Zygomycota, but recent phylogenetic studies have shown that it was polyphyletic and thus split into several groups, it is now thought to be a paraphyletic grouping. Mucoromycotina is currently composed of 3 orders, 61 genera, and 325 species. Some common characteristics seen throughout the species include: development of coenocytic mycelium, saprotrophic lifestyles, and filamentous.

History

Zygomycete fungi were originally only ascribed to the phylum Zygomycota. Such classifications were based on physiological characteristics with little genetic support. A genetic study of Zygomycete fungi performed in 2016 showed that further classification of the group was possible, thus splitting it into Zoopagomycota, Entomophthoromycota, Kickxellomycotina, and Mucoromycotina. The study put these groups as being sister to Dikarya, but without further research, their exact locations in Fungi remain unknown. Many of the questions regarding these groups stem from the difficulty of collecting and growing them in culture, so the current groupings are based on the few that have been successfully collected and which could undergo genomic testing with a certain level of accuracy.[1][2][3]

Taxonomy

The exact placement of Mucoromycotina is currently unknown. It currently resides in the subphyla incertae sedis, alongside Zoopagomycota, Entomophthoromycota, and Kickxellomycotina, whose’ placements are also currently unknown.  These groups originally comprised Zygomycota alongside others that were assigned to Glomeromycota, which was elevated to phylum in 2001. These groups are sister to Dikarya, which contains Ascomycota and Basidiomycota.

Studies have currently divided Mucoromycotina into 3 orders: Endognales, Mucorales, and Mortierellales. All three orders contain species that are saprotrophic, with others forming relationships with other organisms. There are still many questions regarding Mucoromycotina and the organisms that compose it, owing to limited collected samples.

Orders

Endogonales

Main page: Biology:Endogonales

This order currently contains 2 families, (Endogonaceae and Densosporaceae) 7 genera, and 40 species. Not much is known about this order, other than readily noticeable characteristics. They produce subterranean sporocarps, which are ingested by small mammals attracted by the fetid odor they produce. Cultured specimens have shown that they produce coenocytic mycelium, and can be saprotrophic or mycorrhizal. This order was first described in 1931 by Jacz. & P.A.Jacz.[4], after being monographed in 1922 by Thaxter.[5] 

Mucorales

Main page: Biology:Mucorales

Often referred to as pin molds, members of this order produce sporangia held up on hyphae, called sporangiophores. There are currently 13 families in this order, divided into 56 genera, and approximately 300 species.  They can be parasitic or saprotrophic in nature and reproduce asexually. Much is known about this order since some of the species cause damage to stored food, with several others causing mycosis in immune compromised individuals. The order was proposed in 1878 by van Tieghem, as the examined samples did not fit in with what was Entomophthorales at the time.

Mortierellales

Main page: Biology:Mortierellales

Previously considered a family of Mucorales, it was suggested as its own order in 1998. At the time it only contained 2 genera, one of which remains. What is known is that species in this order can be parasitic or saprotrophic in nature. Cultured specimens show that they produce a fine mycelium, with branched sporangia, and produce a garlic-like odor. They are widespread, showing up in soil samples from many different locations. The most studied genera in this order is Mortierella, which contains species that cause crown rot in strawberries. There are currently 6 families and 13 described genera, with more than 100 species.

Mortierella polycephala was the first species described in 1863 by Coemans, and named after M. Du Mortier, the president of Société de Botanique de Belgique. Dissophora decumbens, the second, wasn't described until 1914, and the most recent was Lobosporangium transversal described in 2004.

Ecology

The species described in this subphylum have evolved 3 main lifestyles: saprotrophic, mycorrhizal, or parasitic. Saprotrophic species are involved in decomposition of organic matter, mycorrhizal species form symbiotic relationships with plants, and parasitic species form harmful symbiotic relationships with other organisms.

Saprotrophs

Saprotrophs breakdown decomposing matter into different components: proteins into amino acids, lipids into fatty acids and glycerol, and starches into disaccharides. The species responsible usually require excess water, oxygen, pH less than 7, and low temperatures. It is the most extreme of environments, where few other organisms live as well, that they are found.

Parasitism

Parasitic species seen in Mucorales and Mortierellales cause infections in crops and immune compromised animals.

A common infection of plants by some species in Mucorales is referred to as crown rot or stem rot, common symptoms are: rotting near the soil line, rotting on one side or on lateral branches.  Treatment is difficult if not caught in its early stages, and usually results in the death of the plant. Crown rot is seen in cereal plants (wheat, barley), with experiments from 2015 showing crop losses at 0.01 t/ha per unit increase in crown rot index or more. In addition to cereal plants, crown rot is seen in strawberries and other such low growing plants.

Mycorrhizal

Mycorrhizal, literally “fungus-root”, interactions are symbioses between fungi and plants. Such interactions are based on nutrient acquisition and sharing, the fungi increases the range over which nutrients are gathered and the plant provides materials that the fungi cannot produce. There are two main types of interactions: arbuscular endomycorrhizal, and ectomycorrhizal.  Arbuscular endomycorrhizal interactions are when the fungi is allowed to enter the plant, and inhabit special cells. The fungi produce structures that look like trees, called “arbuscules,” inside these cells.  Ectomycorrhizal interactions are similar symbioses, however the fungi are not allowed into any plant cells, though they may grow between them.

Plant-microbe interactions

Endogonales

A new genus proposed in 2017, Jimgerdemannia, contains species with an ectomycorrhizal trophic mode. Further research is needed to understand these species. Several studies have observed fossils of some potential members forming mycorrhizal interactions with ancient plants.

The genus Endogone is important in nutrient-deficient soils, such as sand dunes. The presence of species in this genus stabilizes the soil and provides some assistance to dune plants.[6]

Mucorales

Some species in the genus Mucor are well known for causing crown rot in cereal plants and damage to stored foods.

Mortierellales

The majority of the species in this group are saprotrophic, and thus form no known relationships with plants. They do however play a role in nutrient transfer through the breakdown of decaying organic matter. The few that are parasitic are only so for animals and not plants.

Evolution

A genome study of Rhizophagus irregularis performed in 2013 supported the hypothesis that Glomeromycota was responsible for early plant-fungi symbiotic relationships.[7] A paper released in 2015 suggests that a Mucoromycotina species formed a symbiotic relationships with liverworts during the Paleozoic era, which may have been the first plant-fungi symbiotic relationship.[6]

Phylogenetic studies have been unable to place Mucoromycotina in any definitive location within fungi, however some research has suggested that the lineage is fairly old. Due to recent advancements allowing for better phylogenetic studies, species assigned to closely related groups are being reassigned to Mucoromycotina, one such species being Rhizophagus irregularis.

Broader implications

Phylogeny

With the improvement of phylogenetic studies, the placement of several established groups in fungi have been called into question. There is some debate regarding the relationship between Mucoromycotina and Glomeromycota, with some species currently in Glomeromycota being moved to Mucoromycotina.

Environment

The genus Endogone in Endogonales, contains species that grow in sand dunes, aiding the plants that grow in the nutrient-poor soils. The mycelium that is formed also plays a role in soil stabilization, preventing erosion. Other species produce fruiting bodies that are included in the diets of various small rodent species.

Species found in Mortierella of Mortierellales have roles in decomposition of organic matter. Some species are among the first to colonize new roots, and others have shared a relationship with spruce trees, though the exact nature in unknown.

Disease

Crown rot

Crown rot is a plant disease caused by species in Mucorales.[8] The disease is characterized by rotting tissue at or near where the stem meets the soil. Treatment is difficult if not caught in its early stages, and usually results in the death of the plant. Crown rot is seen in cereal plants (wheat, barley), with experiments from 2015 showing crop losses at 0.01 t/ha per unit increase in crown rot index or more. In addition to cereal plants, crown rot is seen in strawberries and other such low growing plants.

Zygomycosis

Main page: Medicine:Zygomycosis

Fungal infection seen in animals with compromised immune systems, meaning the host is already sick before the fungus invades and inhabits the body. Also referred to as Mucoromycosis, depending on the species.

Uses

A study was conducted examining insecticidal properties of several fungi species, Mortierella was included.[9] The study focused on species isolated from Antarctica, with the intention of identifying potentially useful adaptations. They found that the Mortierella species examined was shown to have some insecticidal properties against waxmoth and housefly larvae. Further research is needed to determine the process by which this is possible, and potential usefulness.

Problems

A recurring problem with study of this phylum, is the difficulty in culturing specimens. Many of the species identified and used in phylogenetic studies, or others, have been collected in the field with few of them being cultured in labs.[10] Such an issue impacts the ability to produce extensive phylogenetic trees, resulting in the currently unknown location of the phylum in fungi.

References

  1. Voigt, Kerstin; Wöstemeyer, Johannes (2001-05-30). "Phylogeny and origin of 82 zygomycetes from all 54 genera of the Mucorales and Mortierellales based on combined analysis of actin and translation elongation factor EF-1α genes" (in en). Gene 270 (1–2): 113–120. doi:10.1016/S0378-1119(01)00464-4. ISSN 0378-1119. PMID 11404008. 
  2. Wagner, L.; Stielow, B.; Hoffmann, K.; Petkovits, T.; Papp, T.; Vágvölgyi, C.; de Hoog, G. S.; Verkley, G. et al. (2013). "A comprehensive molecular phylogeny of the Mortierellales (Mortierellomycotina) based on nuclear ribosomal DNA" (in en). Persoonia 30: 77–93. doi:10.3767/003158513X666268. PMID 24027348. 
  3. Spatafora, J. W.; Chang, Y.; Benny, G. L.; Lazarus, K.; Smith, M. E.; Berbee, M. L.; Bonito, G.; Corradi, N. et al. (2016). "A phylum-level phylogenetic classification of zygomycete fungi based on genome-scale data". Mycologia 108 (5): 1028–1046. doi:10.3852/16-042. PMID 27738200. 
  4. Jaczewski, A.A.; Jaczewski, P.A. (1931). "Определитель грибов. Совершенные грибы (диплоидные стадии). 3-е изд. [Вып. 1]. Фикомицеты. [Keys to Fungi. Perfect Fungi (diploid stages).". in Doweld, Alexander (in Russian). Phycomycetes. (3 ed.). Moscow-Leningrad: Gosudarstvennoe Izdateľstvo sel'skokhozjaistvennoj i kolkhozno-kooperativnoj literatury. p. 294. 
  5. Académie Royale De Belgique (1974-06-01). "Bulletin de la classe des sciences" (in en). Vacuum 24 (6): 263. doi:10.1016/0042-207X(74)93129-7. ISSN 0042-207X. 
  6. 6.0 6.1 Desirò, Alessandro; Rimington, William R.; Jacob, Alison; Pol, Natalie Vande; Smith, Matthew E.; Trappe, James M.; Bidartondo, Martin I.; Bonito, Gregory (2017). "Multigene phylogeny of Endogonales, an early diverging lineage of fungi associated with plants". IMA Fungus 8 (2): 245–257. doi:10.5598/imafungus.2017.08.02.03. PMID 29242774. 
  7. Field, Katie J.; Rimington, William R.; Bidartondo, Martin I.; Allinson, Kate E.; Beerling, David J.; Cameron, Duncan D.; Duckett, Jeffrey G.; Leake, Jonathan R. et al. (2015). "First evidence of mutualism between ancient plant lineages (Haplomitriopsida liverworts) and Mucoromycotina fungi and its response to simulated Palaeozoic changes in atmospheric CO2" (in en). New Phytologist 205 (2): 743–756. doi:10.1111/nph.13024. ISSN 1469-8137. PMID 25230098. 
  8. Forknall, Clayton; Simpfendorfer, Steve; Kelly, Alison. "Crown rot yield loss response curves" (in en-AU). https://grdc.com.au/resources-and-publications/grdc-update-papers/tab-content/grdc-update-papers/2017/03/crown-rot-yield-loss-response-curves. 
  9. Edgington, Steven; Thompson, Emma; Moore, Dave; Hughes, Kevin A.; Bridge, Paul (2014-06-09). "Investigating the insecticidal potential of Geomyces (Myxotrichaceae: Helotiales) and Mortierella (Mortierellacea: Mortierellales) isolated from Antarctica". SpringerPlus 3 (1): 289. doi:10.1186/2193-1801-3-289. ISSN 2193-1801. PMID 25013747. 
  10. Yang, Mina; Lee, Jang Ho; Kim, Young-Kwon; Ki, Chang-Seok; Huh, Hee Jae; Lee, Nam Yong (2016). "Identification of Mucorales From Clinical Specimens: A 4-Year Experience in a Single Institution" (in English). Annals of Laboratory Medicine 36 (1): 60–3. doi:10.3343/alm.2016.36.1.60. ISSN 2234-3806. PMID 26522761. 

Wikidata ☰ Q135453 entry