Biology:Take-all

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Short description: Fungal plant disease

Take-all
Take-all.jpg
Wheat plants displaying symptoms of take-all root disease.
Scientific classification edit
Domain: Eukaryota
Kingdom: Fungi
Division: Ascomycota
Class: Sordariomycetes
Order: Magnaporthales
Family: Magnaporthaceae
Genus: Gaeumannomyces
Species:
Trinomial name
Gaeumannomyces tritici subsp. '
Hernández-Restrepo et al (2016)
Synonyms

Ophiobolus graminis var tritici, Gaeumannomyces graminis var "tritici"

Take all
Causal agentsGaeumannomyces tritici
Hostswheat and barley

Take-all is a plant disease affecting the roots of grass and cereal plants in temperate climates caused by the fungus Gaeumannomyces tritici (previously known as Gaeumannomyces graminis var. tritici).[1] All varieties of wheat and barley are susceptible. It is an important disease in winter wheat in Western Europe particularly, and is favoured by conditions of intensive production and monoculture.

The disease

The pathogen survives in the soil on infected cereal and grass residues. The fungus infects the root tissue of young plants and can spread from plant to plant in the form of hyphae growing through the soil which is why the disease is often seen in patches. The fungus blocks the conductive tissue of the plants and reduces water uptake. Early symptoms of the disease include yellowing and stunting, tillering is reduced and plants mature prematurely and often exhibit bleached seed heads. The affected roots are blackened and the plants are easy to pull from the soil.[2] These symptoms give rise to an alternative name for the disease, "whiteheads". Yield loss levels of 40 to 50% are often recorded in severe attacks.

Although disease levels are normally low in the first wheat crop in a rotation, the fungal inoculum builds up in the soil nearby wheat roots, which is known as take-all inoculum build-up (TAB). In the ensuing 2–4 years disease levels increase, which may be followed by take-all decline (TAD).

Control

Chemical control measures have traditionally had little success, although a modern seed treatment shows promise. Crop nutrition imbalances exacerbate the disease, as does excessive liming. Modern varieties are stiff and short-strawed which allows relatively high spring nitrogen applications without serious lodging. This can limit damage from the disease.

The most appropriate control measure is the use of a clean one-year break crop of a non-cereal crop. This reduces the fungus to an acceptably low soil contamination level in about 10 months although stray volunteer grasses may reduce any beneficial effects.

Experiments performed on the famous "Broadbalk" field at Rothamsted Research where continuous monoculture winter wheat is grown, show that take-all build-up (TAB) occurs in successive crops to reach a peak in the 3rd to 5th cropping year, after which the disease declines (TAD), ultimately restoring yields to 80 to 90% of 1st and 2nd year levels. The decline cycle is destroyed by the introduction of a crop other than wheat or barley.

Although no resistant wheat varieties are currently commercially available, it has been found that wheat lines differ in their capacity to build-up take-all inoculum in the soil during their first year of a rotation.[3] The Low-TAB trait influences disease severity and wheat yield in second wheats,[4] and it is associated to changes in the rhizosphere microbiome.[5][6] The genetic mechanism of the Low-TAB is still unknown, but the low TAB can still be exploited by farmers, making short wheat rotations more profitable.

Some wheat relatives such as strains of T. monococcum have comparable resistance to wheat varieties that have already been bred for resistance,[7] but genetic analysis suggests that they have different genetic bases for this, both different from wheat cultivars[7] and also from each other.[7] This may be a useful genetic resource to draw upon for introgression into wheat.[7]

Hosts, Symptoms, and Signs

Gaeumannomyces tritici causes disease in the roots, crown, and stem base of wheat, barley, rye, along with several grasses such as Bromegrass, Quackgrass, and Bentgrass.[8] Oats are the only cereal crops that are able to have resistance[9] being naturally resistant.[10] The majority of infected plants can withstand mild root infection and appear symptomless.[8] There are also cases where entire fields can be affected,[11] but typically premature death occurs in circular patches in the field.[12] Infected plants are identifiable through stunting, mild chlorosis (yellowing), and a decreased number of tillers, which are additional stems that develop of the main shoot of the plant.[8][13] When tillers die due to disease they are white, creating a "white-head" that can be described as a sterile environment that isn’t able to germinate.[14] Signs include perithecia that are shown in infected root and stem tissues which are black in color.[15] This blackening of the crown and stem base allow the plant to be easily pulled from the soil with no attached root system.[9] Given its name "Take-all", it has been known to destroy entire stands of wheat.[16]

Environment

Gaeumannomyces tritici is a soil borne fungus that was first identified over 100 years ago in Australia.[14] Although the disease term originated in this region of the world, it is seen throughout the world under temperate climates as well as regions with tropical climates or high elevations.[17] Given that it is an ascomycete, it favors damp climates, but can proceed to persist in dry climates where irrigation is used.[12] Take-all becomes more severe in sandy, infertile, compact, and poorly drained soils,[8] where air, and therefore soil temperatures are 11 °C to 20 °C.[12] The second half of the growing season is favorable. The pathogen favors a basic environment and increases in severity of the pathogen when the pH reaches 7. Soils deficient in nitrogen, phosphorus, and copper also intensify growth of the pathogen.[12] Therefore, liming is not a suitable form of control.[8] There have been tested areas in Larslan and Toston, Montana, where two different fungi found in particular soil have reduced the severity of take-all through mycoparasitism.[18]

Disease cycle

Gaeumannomyces tritici persists through unfavorable climates in infected host plants and host debris.[14] It can be spread from area to area through this debris.[8] There are two inoculum that contribute to the spread of the pathogen, hyphae and ascospores. Hyphae are the predominant inoculum,[14] because roots become infected as they grow through infested soil. Most of the plant-to-plant spread of take-all occurs via runner hyphae moving across "root bridges". In addition, ascospores are moved through splashing and in some instances wind.[14] The pathogen then causes whiteheads to accumulate on the top of the plant. When the plant eventually dies, the cycle repeats and the fungi once again overwinters as an ascocarp inside the host plant and plant debris.[19] This pathogen may be considered polycyclic because initial inoculum is by mycelial growth by the resting spores, ascomata. Alloinfection may be relatively less frequent within a season, yet secondary inoculum can also occur during the same season.[15]

See also

References

  1. "Take-all or nothing". Studies in Mycology 83: 19–48. 2016-03-01. doi:10.1016/j.simyco.2016.06.002. PMID 27504028. 
  2. "Take-all". Hannaford. Chemtura Corporation. http://www.hannafords.com/disease.php?id=6. 
  3. McMillan, V. E.; Hammond-Kosack, K. E.; Gutteridge, R. J. (2011). "Evidence that wheat cultivars differ in their ability to build up inoculum of the take-all fungus, Gaeumannomyces graminis var. tritici, under a first wheat crop" (in en). Plant Pathology 60 (2): 200–206. doi:10.1111/j.1365-3059.2010.02375.x. ISSN 1365-3059. 
  4. McMillan, V. E.; Canning, G.; Moughan, J.; White, R. P.; Gutteridge, R. J.; Hammond-Kosack, K. E. (2018-06-22). "Exploring the resilience of wheat crops grown in short rotations through minimising the build-up of an important soil-borne fungal pathogen" (in en). Scientific Reports 8 (1): 9550. doi:10.1038/s41598-018-25511-8. ISSN 2045-2322. PMID 29934522. Bibcode2018NatSR...8.9550M. 
  5. Mehrabi, Zia; McMillan, Vanessa E.; Clark, Ian M.; Canning, Gail; Hammond-Kosack, Kim E.; Preston, Gail; Hirsch, Penny R.; Mauchline, Tim H. (2016-09-30). "Pseudomonas spp. diversity is negatively associated with suppression of the wheat take-all pathogen" (in en). Scientific Reports 6 (1): 29905. doi:10.1038/srep29905. ISSN 2045-2322. PMID 27549739. Bibcode2016NatSR...629905M. 
  6. Mauchline, T. H.; Chedom-Fotso, D.; Chandra, G.; Samuels, T.; Greenaway, N.; Backhaus, A.; McMillan, V.; Canning, G. et al. (2015). "An analysis of Pseudomonas genomic diversity in take-all infected wheat fields reveals the lasting impact of wheat cultivars on the soil microbiota" (in en). Environmental Microbiology 17 (11): 4764–4778. doi:10.1111/1462-2920.13038. ISSN 1462-2920. PMID 26337499. 
  7. 7.0 7.1 7.2 7.3 "Identifying variation in resistance to the take-all fungus, Gaeumannomyces graminis var. tritici, between different ancestral and modern wheat species". BMC Plant Biology (Springer Science and Business Media LLC) 14 (1): 212. August 2014. doi:10.1186/s12870-014-0212-8. PMID 25084989. 
  8. 8.0 8.1 8.2 8.3 8.4 8.5 "Wheat Take-All" (in en). University of Missouri Extension. https://extension2.missouri.edu/g4345. 
  9. 9.0 9.1 "Take-All Disease Fact Sheets". Soil Quality Pty Ltd. http://www.soilquality.org.au/factsheets/take-all-disease. 
  10. "Resistance of oat to 'take-all' causing fungus (Gaeumannomyces graminis var.tritici)". Chinese Science Bulletin (Springer Science and Business Media LLC) 46 (21): 1817–1819. 2001. doi:10.1007/bf02900558. ISSN 1001-6538. Bibcode2001ChSBu..46.1817L. 
  11. "Take-All of Wheat". http://bulletin.ipm.illinois.edu/pastpest/articles/199912e.html. 
  12. 12.0 12.1 12.2 12.3 "Gaeumannomyces graminis". North Carolina State University, Dept. of Plant Pathology. https://projects.ncsu.edu/cals/course/pp728/Gaeumannomyces/Gaeumannomyces_graminis.htm. 
  13. "What are wheat tillers and how do they contribute to yield" (in en-US). Ohio's Country Journal. Ohio Ag Net. https://www.ocj.com/2018/02/what-are-wheat-tillers-and-how-do-they-contribute-to-yield/. 
  14. 14.0 14.1 14.2 14.3 14.4 Compendium of wheat diseases and pests. American Phytopathological Society. 2010. ISBN 978-0-89054-385-6. OCLC 695943999. 
  15. 15.0 15.1 (in en) Soilborne Microbial Plant Pathogens and Disease Management, Volume One: Nature and Biology. CRC Press. 2019-10-08. ISBN 978-0-429-60339-6. https://books.google.com/books?id=mJazDwAAQBAJ&q=take-all+monocyclic%3F&pg=PT441. 
  16. Take-all of Wheat. May 2010. https://plantpathology.ca.uky.edu/files/ppfs-ag-sg-01.pdf. 
  17. "Take-all Diagnostic Guide". https://www.plantmanagementnetwork.org/pub/php/diagnosticguide/take-all/. 
  18. "Natural suppression of take-all disease of wheat in Montana soils" (in en). Plant and Soil 164 (1): 9–18. 1994-07-01. doi:10.1007/BF00010105. ISSN 1573-5036. 
  19. "Ascomycota, Ascomycetes & Sac Fungi". University of California Riverside. https://faculty.ucr.edu/~legneref/fungi/ascomycota.htm. 

Further reading

  • Biology and Control of Take-all. London: Academic Press. 1981. ISBN 0-12-065320-6. 
  • Cereal pests and diseases (4th ed.). Ipswich: Farming Press. 1987. ISBN 978-0-85236-164-1. 
  • Take-all disease of cereals : a regional perspective. Oxford: CAB International. 1998. ISBN 0-85199-124-6. 

External links


Wikidata ☰ Q7583798 entry