Epichloë

"Choke disease" redirects here. For other uses, see Choke.
Epichloë
"Choke disease": Epichloë typhina stroma on bluegrass
Scientific classification
Kingdom: Fungi
Division: Ascomycota
Class: Ascomycetes
Subclass: Sordariomycetes
Order: Hypocreales
Family: Clavicipitaceae
Genus: Epichloë
(Fr.) Tul. & C. Tul
Type species
Epichloë typhina
(Fr.) Tul. & C. Tul.
Diversity
34 species, see text

Epichloë is a genus of ascomycete fungi forming an endophytic symbiosis with grasses. Grass choke disease is a symptom in grasses induced by some Epichloë species, which form spore-bearing mats (stromata) on tillers and suppress the development of their host plant's inflorescence. For most of their life cycle however, Epichloë grow in the intercellular space of stems, leaves, inflorescences, and seeds of the grass plant without incurring symptoms of disease. They provide in fact several benefits to their host, including the production of different herbivore-deterring alkaloids, increased stress resistance, and growth promotion.

Within the family Clavicipitaceae, Epichloë is embedded in a group of endophytic and plant pathogenic fungi, whose common ancestor probably derived from an animal pathogen. The genus includes both species with a sexually reproducing (teleomorphic) stage and asexual, anamorphic species. The latter were previously placed in the form genus Neotyphodium but included in Epichloë after molecular phylogenetics had shown asexual and sexual species to be intermingled in a single clade. Hybrid speciation has played an important role in the evolution of the genus.

Epichloë species are ecologically significant through their effects on host plants. Their presence has been shown to alter the composition of plant communities and food webs. Grass varieties, especially of tall fescue and ryegrass, with symbiotic Epichloë endophyte strains, are commercialised and used e.g. for turf.

Taxonomy

Elias Fries, in 1849, first defined Epichloë as a subgenus of Cordyceps.[1] As type species, he designated Cordyceps typhina,[1] originally described by Christiaan Hendrik Persoon.[2] The brothers Charles and Louis René Tulasne then raised the subgenus to genus rank in 1865.[3] Epichloë typhina would remain the only species in the genus until the discovery of fungal grass endophytes causing livestock intoxications in the 1970s and 80s, which stimulated the description of new species.[4] Several species from Africa and Asia developing stromata on grasses were split off as separate genus Parepichloë in 1998.[5]

Many Epichloë species have forms that reproduce asexually, and several purely asexual species are closely related to them. These anamorphs were long classified separately: Morgan-Jones and Gams (1982) collected them in a section (Albo-lanosa) of genus Acremonium.[6] In a molecular phylogenetic study in 1996, Glenn and colleagues found that genus to be polyphyletic and proposed the new genus Neotyphodium for the anamorphic species related to Epichloë.[7] A number of species continued to be described in both genera until Leuchtmann and colleagues (2014) included most of the form genus Neotyphodium in Epichloë.[4] Phylogenetic studies had shown both genera to be intermingled, and the nomenclatural code required since 2011 that one single name be used for all stages of development of a fungal species. Only Neotyphodium starrii, of unclear status, and N. chilense, which is unrelated, were excluded from Epichloë.[4]

Species

As of 2016, there are 34 accepted species in the genus, with several subspecies and varieties described. Several taxa (flagged with an asterisk below) are only known as anamorphic forms, most of which have previously been classified in Neotyphodium.[4]

  • var. lolii*
  • Epichloë funkii*
  • Epichloë gansuensis*
  • var. inebrians*
  • Epichloë glyceriae
  • Epichloë guerinii*
  • Epichloë hordelymi
  • Epichloë liyangensis
  • Epichloë melicicola*
  • Epichloë mollis*
  • Epichloë occultans*
  • Epichloë pampeana*
  • Epichloë schardlii*
  • Epichloë sibirica*
  • Epichloë siegelii*
  • Epichloë sinica*
  • Epichloë sinofestucae*
  • Epichloë stromatolonga*
  • Epichloë sylvatica
  • subsp. pollinensis
  • Epichloë tembladerae*
  • Epichloë typhina
  • var. ammophilae*
  • subsp. clarkii
  • subsp. poae
  • var. aonikenkana
  • var. canariensis
  • var. huerfana*
  • Epichloë uncinata*

Life cycle and growth

Blue-stained large plant cells with smaller hyphae visible between them
Epichloë coenophiala hyphae between tall fescue leaf cells

Epichloë species are specialized to form and maintain systemic, constitutive (long-term) symbioses with plants, often with limited or no disease incurred on the host.[8] The best-studied of these symbionts are associated with the grasses and sedges, in which they infect the leaves and other aerial tissues by growing between the plant cells (endophytic growth) or on the surface above or beneath the cuticle (epiphytic growth). An individual infected plant will generally bear only a single genetic individual clavicipitaceous symbiont, so the plant-fungus system constitutes a genetic unit called a symbiotum (pl. symbiota).

Symptoms and signs of the fungal infection, if manifested at all, only occur on a specific tissue or site of the host tiller, where the fungal stroma or sclerotium emerges. The stroma (pl. stromata) is a mycelial cushion that gives rise first to asexual spores (conidia), then to the sexual fruiting bodies (ascocarps; perithecia). Sclerotia are hard resting structures that later (after incubation on the ground) germinate to form stipate stromata. Depending on the fungus species, the host tissues on which stromata or sclerotia are produced may be young inflorescences and surrounding leaves, individual florets, nodes, or small segments of the leaves. Young stromata are hyaline (colorless), and as they mature they turn dark gray, black, or yellow-orange. Mature stromata eject meiotically derived spores (ascospores), which are ejected into the atmosphere and initiate new plant infections (horizontal transmission). In some cases no stroma or sclerotium is produced, but the fungus infects seeds produced by the infected plant, and is thereby transmitted vertically to the next host generation. Most Epichloë species and all of their asexual derivatives, the Neotyphodium species, can vertically transmit.

The taxonomic dichotomy is especially interesting in this group of symbionts, because vegetative propagation of fungal mycelium occurs by vertical transmission, i.e., fungal growth into newly developing host tillers (=individual grass plants). Importantly, all Neotyphodium and some Epichloë species infect new grass plants solely by growing into the seeds of their grass hosts, and infecting the growing seedling.[9][10] Manifestation of the sexual state — which only occurs in Epichloë species — causes "choke disease", a condition in which grass inflorescences are engulfed by rapid fungal outgrowth forming a stroma. The fungal stroma suppresses host seed production and culminates in the ejection of meiospores (ascospores) that mediate horizontal (contagious) transmission of the fungus to new plants.[9] So, the two transmission modes exclude each other, although in many grass-Epichloë symbiota the fungus actually displays both transmission modes simultaneously, by choking some tillers and transmitting in seeds produced by unchoked tillers.

While being obligate symbionts in nature, most epichloae are readily culturable in the laboratory on culture media such as potato dextrose agar or a minimal salts broth supplemented with thiamine, sugars or sugar alcohols, and organic nitrogen or ammonium.[11]

Epichloë species are commonly spread by flies of the genus Botanophila. The flies lay their eggs in the growing fungal tissues and the larvae feed on them.[12]

Evolution

The epichloae display a number of central features that suggest a very strong and ancient association with their grass hosts. The symbiosis appears to have existed already during the early grass evolution that has spawned today's pooid grasses. This is suggested by phylogenetic studies indicating preponderance of codivergence of Neotyphodium/Epichloë species with the grass hosts they inhabit.[13] Growth of the fungal symbiont is very tightly regulated within its grass host, indicated by a largely unbranched mycelial morphology and remarkable synchrony of grass leaf and hyphal extension of the fungus;[14][15] the latter seems to occur via a mechanism that involves stretch-induced or intercalary elongation of the endophyte's hyphae, a process so far not found in any other fungal species, indicating specialized adaptation of the fungus to the dynamic growth environment inside its host.[16] A complex NADPH oxidase enzyme-based ROS-generating system in epichloae is indispensable for maintenance of this growth synchrony. Thus, it has been demonstrated that deletion of genes encoding these enzymes in Epichloë festucae causes severely disordered fungal growth in grass tissues and even death of the grass plant.[17][18]

Molecular phylogenetic evidence demonstrates that asexual Epichloë species are derived either from individual Epichloë species, or more commonly, from hybrids with at least two ancestral Epichloë species.[19][20]

Bioactive compounds

(toxicity or feeding deterrence) against insect and mammalian herbivores.[21]

Many Neotyphodium endophytes produce a diverse range of natural product compounds with biological activities against a broad range of herbivores.[22][23] Ergoline alkaloids (which are ergot alkaloids, named after the ergot fungus, Claviceps purpurea, a close relative of the epichloae) are characterized by a ring system derived from 4-prenyl tryptophan.[24] Among the most abundant ergot alkaloids in epichloë-symbiotic grasses is ergovaline, comprising an ergoline moiety attached to a bicyclic tripeptide containing the amino acids L-proline, L-alanine, and L-valine. Key genes and enzymes for ergot alkaloid biosynthesis have been identified in epichloae and include dmaW, encoding dimethylallyl-tryptophan synthase and lpsA, a non-ribosomal peptide synthetase.[24]

N-formylloline, an insecticidal alkaloid produced in several Neotyphodium–grass symbiota.

Another group of epichloë alkaloids are the indole-diterpenoids, such as lolitrem B, which are produced from the activity of several enzymes, including prenyltransferases and various monooxygenases.[25] Both the ergoline and indole-diterpenoid alkaloids have biological activity against mammalian herbivores, and also activity against some insects.[22] Peramine is a pyrrolopyrazine alkaloid thought to be biosynthesized from the guanidinium-group-containing amino acid L-arginine, and pyrrolidine-5-carboxylate, a precursor of L-proline,[26] and is an insect-feeding deterrent. The loline alkaloids[27] are 1-aminopyrrolizidines with an oxygen atom linking bridgehead carbons 2 and 7, and are biosynthesized from the amino acids L-proline and L-homoserine.[28] The lolines have insecticidal and insect-deterrent activities comparable to nicotine.[27] Loline accumulation is strongly induced in young growing tissues[29] or by damage to the plant-fungus symbiotum.[30] Many, but not all, epichloae produce up to three classes of these alkaloids in various combinations and amounts.[22] Recently it has been shown that Epichloë uncinata infection and loline content afford Festulolium grasses protection from black beetle (Heteronychus arator).[31]

Like the Neotyphodium species, many species in Epichloë produce biologically active alkaloids, such as ergot alkaloids, indole-diterpenoids (e.g., lolitrem B), loline alkaloids, and the unusual guanidinium alkaloid, peramine.[22] Because of their close relationships and shared biological properties, members of these two genera are collectively called epichloae (singular = epichloë).

Ecology

Effects on the grass plant

It has been proposed that vertically transmitted symbionts should evolve to be mutualists since their reproductive fitness is intimately tied to that of their hosts.[32] In fact, some positive effects of epichloae on their host plants include increased growth, drought tolerance, and herbivore and pathogen resistance.[9][33] Resistance against herbivores has been attributed to alkaloids produced by the symbiotic epichloae.[22] Although grass-epichloë symbioses have been widely recognized to be mutualistic in many wild and cultivated grasses, the interactions can be highly variable and sometimes antagonistic, especially under nutrient-poor conditions in the soil.[34]

Ecosystem dynamics

Due to the relatively large number of grass species harboring epichloae and the variety of environments in which they occur, the mechanisms underlying beneficial or antagonistic outcomes of epichloë-grass symbioses are difficult to delineate in natural and also agricultural environments.[9][35] Some studies suggest a relationship between grazing by herbivores and increased epichloë infestation of the grasses on which they feed,[36][37] whereas others indicate a complex interplay between plant species and fungal symbionts in response to herbivory or environmental conditions.[38] The strong anti-herbivore activities of several bioactive compounds produced by the epichloae [22][26] and relatively modest direct effects of the epichloae on plant growth and physiology[39][40] suggest that these compounds play a major role in the persistence of the symbiosis.

References

  1. 1 2 Fries, E.M. (1849). Summa vegetabilium Scandinaviae (in Latin). Stockholm, Leipzig: Bonnier. p. 572.
  2. Persoon, C.H. (1798). Icones et Descriptiones Fungorum Minus Cognitorum (in Latin). Leipzig: Bibliopolii Breitkopf-Haerteliani impensis.
  3. Tulasne, L.R.; Tulasne, C. (1865). Selecta Fungorum Carpologia: Nectriei – Phacidiei – Pezizei (in Latin). 3.
  4. 1 2 3 4 Leuchtmann, A.; Bacon, C. W.; Schardl, C. L.; White, J. F.; Tadych, M. (2014). "Nomenclatural realignment of Neotyphodium species with genus Epichloë" (PDF). Mycologia. 106 (2): 202–215. doi:10.3852/13-251. ISSN 0027-5514.
  5. White, J.F.; Reddy, P.V. (1998). "Examination of Structure and Molecular Phylogenetic Relationships of Some Graminicolous Symbionts in Genera Epichloe and Parepichloe". Mycologia. 90 (2): 226. doi:10.2307/3761298. ISSN 0027-5514. JSTOR 3761298.
  6. Morgan-Jones, G.; Gams, W. (1982). "Notes on hyphomycetes. XLI. An endophyte of Festuca arundinacea and the anamorph of Epichloe typhina, new taxa in one of two new sections of Acremonium". Mycotaxon. 15: 311–318. ISSN 0093-4666.
  7. Glenn AE, Bacon CW, Price R, Hanlin RT (1996). "Molecular phylogeny of Acremonium and its taxonomic implications". Mycologia. Mycological Society of America. 88 (3): 369–383. doi:10.2307/3760878. JSTOR 3760878.
  8. Spatafora JW, Sung GH, Sung JM, Hywel-Jones NL, White JF Jr (2007). "Phylogenetic evidence for an animal pathogen origin of ergot and the grass endophytes". Mol. Ecol. 16 (8): 1701–1711. doi:10.1111/j.1365-294X.2007.03225.x. PMID 17402984.
  9. 1 2 3 4 Schardl CL, Leuchtmann A, Spiering MJ (2004). "Symbioses of grasses with seedborne fungal endophytes". Annu Rev Plant Biol. 55: 315–340. doi:10.1146/annurev.arplant.55.031903.141735. PMID 15377223.
  10. Freeman EM (1904). "The seed fungus of Lolium temulentum L., the darnel". Philosophical Transactions of the Royal Society of London, Series B. 196: 1–27. doi:10.1098/rstb.1904.0001.
  11. Blankenship JD, Spiering MJ, Wilkinson HH, Fannin FF, Bush LP, Schardl CL (2001). "Production of loline alkaloids by the grass endophyte, Neotyphodium uncinatum, in defined media". Phytochemistry. 58 (3): 395–401. doi:10.1016/S0031-9422(01)00272-2. PMID 11557071.
  12. Górzyńska, K.; et al. (2010). "An unusual BotanophilaEpichloë association in a population of orchardgrass (Dactylis glomerata) in Poland". Journal of Natural History. 44 (45-46): 2817–24. doi:10.1111/j.1570-7458.2006.00518.x.
  13. Schardl CL, Craven KD, Speakman S, Stromberg A, Lindstrom A, Yoshida R (2008). "A novel test for host-symbiont codivergence indicates ancient origin of fungal endophytes in grasses.". Syst Biol. 57 (3): 483–498. doi:10.1080/10635150802172184. PMID 18570040.
  14. Tan YY, Spiering MJ, Scott V, Lane GA, Christensen MJ, Schmid J (2001). "In planta regulation of extension of an endophytic fungus and maintenance of high metabolic rates in its mycelium in the absence of apical extension". Appl. Environ. Microbiol. 67 (12): 5377–5383. doi:10.1128/AEM.67.12.5377-5383.2001. PMC 93319Freely accessible. PMID 11722882.
  15. Christensen MJ, Bennett RJ, Schmid J (2002). "Growth of Epichloë/Neotyphodium and p-endophytes in leaves of Lolium and Festuca grasses". Mycol. Res. 96: 93–106. doi:10.1017/S095375620100510X.
  16. Christensen MJ, Bennett RJ, Ansari HA, Koga H, Johnson RD, Bryan GT, Simpson WR, Koolaard JP, Nickless EM, Voisey CR (2008). "Epichloë endophytes grow by intercalary hyphal extension in elongating grass leaves". Fungal Genet. Biol. 45 (2): 84–93. doi:10.1016/j.fgb.2007.07.013. PMID 17919950.
  17. Tanaka A, Christensen MJ, Takemoto D, Park P, Scott B (2006). "Reactive oxygen species play a role in regulating a fungus-perennial ryegrass mutualistic interaction". Plant Cell. 18 (4): 1052–1066. doi:10.1105/tpc.105.039263. PMC 1425850Freely accessible. PMID 16517760.
  18. Takemoto D, Tanaka A, Scott B (2006). "A p67Phox-like regulator is recruited to control hyphal branching in a fungal-grass mutualistic symbiosis". Plant Cell. 18 (10): 2807–2821. doi:10.1105/tpc.106.046169. PMC 1626622Freely accessible. PMID 17041146.
  19. Tsai HF, Liu JS, Staben C, Christensen MJ, Latch GC, Siegel MR, Schardl CL (1994). "Evolutionary diversification of fungal endophytes of tall fescue grass by hybridization with Epichloë species". Proc. Natl. Acad. Sci. USA. 91 (7): 2542–2546. doi:10.1073/pnas.91.7.2542. PMC 43405Freely accessible. PMID 8172623.
  20. Moon CD, Craven KD, Leuchtmann A, Clement SL, Schardl CL (2004). "Prevalence of interspecific hybrids amongst asexual fungal endophytes of grasses". Molec Ecol. 13 (6): 1455–1467. doi:10.1111/j.1365-294X.2004.02138.x. PMID 15140090.
  21. Roberts CA, West CP, Spiers DE, eds (2005). Neotyphodium in Cool-Season Grasses. Blackwell. ISBN 978-0-8138-0189-6.
  22. 1 2 3 4 5 6 Bush LP, Wilkinson HH, Schardl CL (1997). "Bioprotective Alkaloids of Grass-Fungal Endophyte Symbioses". Plant Physiol. 114 (1): 1–7. doi:10.1104/pp.114.1.1. PMC 158272Freely accessible. PMID 12223685.
  23. Scott B (2001). "Epichloë endophytes: fungal symbionts of grasses". Curr. Opin. Microbiol. 4 (4): 393–398. doi:10.1016/S1369-5274(00)00224-1. PMID 11495800.
  24. 1 2 Schardl CL, Panaccione DG, Tudzynski P (2006). "Ergot alkaloids – biology and molecular biology". The Alkaloids: Chemistry and Biology. 63: 45–86. doi:10.1016/S1099-4831(06)63002-2. PMID 17133714.
  25. Young CA, Felitti S, Shields K, Spangenberg G, Johnson RD, Bryan GT, Saikia S, Scott B (2006). "A complex gene cluster for indole-diterpene biosynthesis in the grass endophyte Neotyphodium lolii". Fungal Genet Biol. 43 (10): 679–693. doi:10.1016/j.fgb.2006.04.004. PMID 16765617.
  26. 1 2 Tanaka A, Tapper BA; Popay A, Parker; EJ, Scott B (2005). "A symbiosis expressed non-ribosomal peptide synthetase from a mutualistic fungal endophyte of perennial ryegrass confers protection to the symbiotum from insect herbivory". Mol. Microbiol. 57 (4): 1036–1050. doi:10.1111/j.1365-2958.2005.04747.x. PMID 16091042.
  27. 1 2 Schardl CL, Grossman RB, Nagabhyru P, Faulkner JR, Mallik UP (2007). "Loline alkaloids: currencies of mutualism". Phytochemistry. 68 (7): 980–996. doi:10.1016/j.phytochem.2007.01.010. PMID 17346759.
  28. Blankenship JD, Houseknecht JB, Pal S, Bush LP, Grossman RB, Schardl CL (2005). "Biosynthetic precursors of fungal pyrrolizidines, the loline alkaloids". Chembiochem. 6 (6): 1016–1022. doi:10.1002/cbic.200400327. PMID 15861432.
  29. Zhang, DX, Nagabhyru, P, Schardl CL (2009). "Regulation of a chemical defense against herbivory produced by symbiotic fungi in grass plants". Plant Physiology. 150 (2): 1072–1082. doi:10.1104/pp.109.138222. PMC 2689992Freely accessible. PMID 19403726.
  30. Gonthier DJ, Sullivan TJ, Brown KL, Wurtzel B, Lawal R, VandenOever K, Buchan Z, Bultman TL (2008). "Stroma-forming endophyte Epichloe glyceriae provides wound-inducible herbivore resistance to its grass host". Oikos. 117: 629–633. doi:10.1111/j.0030-1299.2008.16483.x.
  31. Barker GM; Patchett BJ; Cameron NE (2014). "Epichloë uncinata infection and loline content afford Festulolium grasses protection from black beetle (Heteronychus arator). Landcare Research, Hamilton, New Zealand & Cropmark Seeds Ltd, Christchurch, New Zealand 20 Dec 2014.". New Zealand Journal of Agricultural Research. 58: 35–56. doi:10.1080/00288233.2014.978480.
  32. Ewald PW (1987). "Transmission modes and evolution of the parasitism-mutualism continuum". Ann NY Acad Sci. 503: 295–306. doi:10.1111/j.1749-6632.1987.tb40616.x. PMID 3304078.
  33. Malinowski DP, Belesky DP (2000). "Adaptations of endophyte-infected cool-season grasses to environmental stresses: mechanisms of drought and mineral stress tolerance". Crop Sci. 40: 923–940. doi:10.2135/cropsci2000.404923x.
  34. Saikkonen K, Ion D, Gyllenberg M (2002). "The persistence of vertically transmitted fungi in grass metapopulations". Proc Biol Sci. 269 (1498): 1397–1403. doi:10.1098/rspb.2002.2006. PMC 1691040Freely accessible. PMID 12079664.
  35. Saikkonen K, Lehtonen P, Helander M, Koricheva J, Faeth SH (2006). "Model systems in ecology: dissecting the endophyte-grass literature". Trends Plant Sci. 11 (9): 428–433. doi:10.1016/j.tplants.2006.07.001. PMID 16890473.
  36. Clay K, Holah J, Rudgers JA (2005). "Herbivores cause a rapid increase in hereditary symbiosis and alter plant community composition". Proc. Natl. Acad. Sci. USA. 102 (35): 12465–12470. doi:10.1073/pnas.0503059102. PMC 1194913Freely accessible. PMID 16116093.
  37. Kohn S, Hik DS (2007). "Herbivory mediates grass-endophyte relationships". Ecology. 88 (11): 2752–2757. doi:10.1890/06-1958.1. PMID 18051643.
  38. Granath G, Vicari M, Bazely DR, Ball JP, Puentes A, Rakocevic T (2007). "Variation in the abundance of fungal endophytes in fescue grasses along altitudinal and grazing gradients". Ecography. 3: 422–430. doi:10.1111/j.0906-7590.2007.05027.x.
  39. Hahn H, McManus MT, Warnstorff K, Monahan BJ, Young CA, Davies E, Tapper BA, Scott, B (2007). "Neotyphodium fungal endophytes confer physiological protection to perennial ryegrass (Lolium perenne L.) subjected to a water deficit". Env. Exp. Bot. 63: 183–199. doi:10.1016/j.envexpbot.2007.10.021.
  40. Hunt MG.; Rasmussen S; Newton PCD; Parsons AJ; Newman JA (2005). "Near-term impacts of elevated CO2, nitrogen and fungal endophyte-infection on Lolium perenne L. growth, chemical composition and alkaloid production". Plant Cell Environ. 28: 1345–1354. doi:10.1111/j.1365-3040.2005.01367.x.

External links

Epichloë in Index Fungorum

Epichloë in MycoBank.

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