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Rust (fungus)

February 15, 2024

Rusts are fungal plant pathogens of the order Pucciniales (previously known as Uredinales) causing plant fungal diseases.

Rusts
Example of wheat leaf from a disease differential of Puccinia recondita f.sp. tritici
Scientific classification
Domain: Eukaryota
Kingdom: Fungi
Division: Basidiomycota
Class: Pucciniomycetes
Order: Pucciniales
Families

An estimated 168 rust genera and approximately 7,000 species, more than half of which belong to the genus Puccinia, are currently accepted.[3] Rust fungi are highly specialized plant pathogens with several unique features. Taken as a group, rust fungi are diverse and affect many kinds of plants. However, each species has a range of hosts and cannot be transmitted to non-host plants. In addition, most rust fungi cannot be grown easily in pure culture.

Most species of rust fungi are able to infect two different plant hosts in different stages of its life cycle, and may produce up to five morphologically and cytologically distinct spore-producing structures viz., spermogonia, aecia, uredinia, telia, and basidia in successive stages of reproduction.[4] Each spore type is very host specific, and can typically infect only one kind of plant.

Rust fungi are obligate plant pathogens that only infect living plants. Infections begin when a spore lands on the plant surface, germinates, and invades its host. Infection is limited to plant parts such as leaves, petioles, tender shoots, stem, fruits, etc.[3] Plants with severe rust infection may appear stunted, chlorotic (yellowed), or may display signs of infection such as rust fruiting bodies. Rust fungi grow intracellularly, and make spore-producing fruiting bodies within or, more often, on the surfaces of affected plant parts.[3] Some rust species form perennial systemic infections that may cause plant deformities such as growth retardation, witch's broom, stem canker, galls, or hypertrophy of affected plant parts.

Rusts get their name because they are most commonly observed as deposits of powdery rust-coloured or brown spores on plant surfaces. The Roman agricultural festival Robigalia (April 25) has ancient origins in combating wheat rust.[5]

Impacts edit

Rusts are among the most harmful pathogens to agriculture, horticulture and forestry. Rust fungi are major concerns and limiting factors for successful cultivation of agricultural and forest crops.[citation needed] White pine blister rust, wheat stem rust, soybean rust, and coffee rust are examples of notoriously damaging threats to economically important crops.[3] Climate change may increase the prevalence of some rust species while causing others to decline through increased CO2 and O3, changes to temperature and humidity, and enhanced spore dispersal due to more frequent extreme weather events.[6]

Life cycle edit

All rusts are obligate parasites, meaning that they require a living host to complete their life cycle. They generally do not kill the host plant but can severely reduce growth and yield.[7] Cereal crops can be devastated in one season; oak trees infected in the main stem within their first five years by the rust Cronartium quercuum often die.[8]

 
Germinating urediniospore of Puccinia graminis, model from the late 19th century, Botanical Museum Greifswald

Rust fungi can produce up to five spore types from corresponding fruiting body types during their life cycle, depending on the species. Roman numerals have traditionally been used to refer to these morphological types.

  • 0-Pycniospores (Spermatia) from Pycnidia. These serve mainly as haploid gametes in heterothallic rusts.
  • I-Aeciospores from Aecia. These serve mainly as non-repeating, dikaryotic, asexual spores, and go on to infect the primary host.
  • II-Urediniospores from Uredia (Uredinia). These serve as repeating dikaryotic vegetative spores. These spores are referred to as the repeating stage because they can cause auto-infection on the primary host, re-infecting the same host on which the spores were produced. They are often profuse, red/orange, and a prominent sign of rust disease.
  • III-Teliospores from Telia. These dikaryotic spores are often the survival/overwintering stage of the life cycle. They usually do not infect a plant directly; instead they germinate to produce basidia and basidiospores.
  • IV-Basidiospores from Teliospores. These windborne haploid spores often infect the alternate host in Spring.[9][10] They are rarely observed outside of the laboratory.

Rust fungi are often categorized by their life cycle. Three basic types of life cycles are recognized based on the number of spore types as macrocyclic, demicyclic, and microcyclic.[3] The macrocyclic life cycle has all spore states, the demicyclic lacks the uredinial state, and the microcyclic cycle lacks the basidial, pycnial, and the aecial states, thus possess only uredinia and telia. Spermagonia may be absent from each type but especially the microcyclic life cycle. In macrocyclic and demicyclic life cycles, the rust may be either host alternating (heteroecious) (i.e., the aecial stage is on one kind of plant but the telial stage on a different and unrelated plant), or single-host (autoecious) (i.e., the aecial and telial states on the same plant host).[3] Heteroecious rust fungi require two unrelated hosts to complete their life cycle, with the primary host being infected by aeciospores and the alternate host being infected by basidiospores. This can be contrasted with an autoecious fungus, such as Puccinia porri, which can complete all parts of its life cycle on a single host species.[9] Understanding the life cycles of rust fungi allows for proper disease management.[11]

Host plant–rust fungus relationship edit

There are definite patterns of relationship with host plant groups and the rust fungi that parasitize them. Some genera of rust fungi, especially Puccinia and Uromyces, comprise species that are capable of parasitizing plants of many families.[citation needed] Other rust genera appear to be restricted to certain plant groups.[citation needed] Host restriction may, in heteroecious species, apply to both phases of life cycle or to only one phase.[3] As with many pathogen/host pairs, rusts are often in gene-for-gene relationships with their plants. This rust-plant gene-for-gene interaction differs somewhat from other gene-for-gene situations and has its own quirks and agronomic significance. Rust fungi decrease photosynthesis and elicit the emissions of different stress volatiles with increasing severity of infection.[12]

Infection process edit

The spores of rust fungi may be dispersed by wind, water or insect vectors.[13] When a spore encounters a susceptible plant, it can germinate and infect plant tissues. A rust spores typically germinates on a plant surface, growing a short hypha called a germ tube. This germ tube may locate a stoma by a touch responsive process known as thigmotropism. This involves orienting to ridges created by epidermal cells on the leaf surface, and growing directionally until it encounters a stoma.[14]

 
Rust hypha attacking stoma (1600x magnification)

Over the stoma, a hyphal tip produces an infection structure called an appressorium. From the underside of an appressorium, a slender hypha grows downward to infect plant cells.[15] It is thought that the whole process is mediated by stretch-sensitive calcium ion channels located in the tip of the hypha, which produce electric currents and alter gene expression, inducing appressorium formation.[16]

Once the fungus has invaded the plant, it grows into plant mesophyll cells, producing specialized hyphae known as haustoria. The haustoria penetrate cell walls but not cell membranes: plant cell membranes invaginate around the main haustorial body forming a space known as the extra-haustorial matrix. An iron and phosphorus rich neck band bridges the plant and fungal membranes in the space between the cells for water flow, known as the apoplast, thus preventing the nutrients reaching the plant's cells. The haustorium contains amino acid- and hexose sugar- transporters and H+-ATPases which are used for active transport of nutrients from the plant, nourishing the fungus.[17] The fungus continues growing, penetrating more and more plant cells, until spore growth occurs. The process repeats every 10 – 14 days, producing numerous spores that can be spread to other parts of the same plant, or to new hosts.

Common rust fungi in agriculture edit

[9][11][18]

Management edit

Research edit

Efforts to control rusts began to be scientifically based in the 20th century.[21] Elvin C. Stakman initiated the scientific study of host resistance, which had heretofore been poorly understood and handled by individual growers as part of the breeding process.[21] Stakman was followed by H. H. Flor's extensive discoveries of rust genetics.[21] In order to study rust metabolics, Tervet et al., 1951 developed the Cyclone Separator.[21] The cyclone separator uses the cyclonic separation mechanism to allow the mechanised collection of spores for study – Cherry & Peet 1966's improved version gathers even more efficiently.[21] This device was first put to work testing the composition of the spores themselves, especially substances coating the outside of the spores which signal population density.[21] When detected they help prevent crowding.[21]

Gene cloning and other methods of genetic engineering can provide a much wider range of R genes and other sources of rust resistance – with reduced delay before deployment – if regulation of genetic engineering permits.[22]

Control edit

The control methods of rust fungus diseases depend largely on the life cycle of the particular pathogen. The following are examples of disease management plans used to control macrocyclic and demicyclic diseases:

Macrocyclic disease: Developing a management plan for this type of disease depends largely on whether the urediniospores (rarely termed the "repeating stage") occur on the economically important host plant or the alternate host.[citation needed] For example, the repeating stage in white pine blister rust disease does not occur on white pines but on the alternate host, Ribes spp. During August and September Ribes spp. give rise to teliospores which infect white pines. Removal of the alternate host disrupts the life cycle of the rust fungi Cronartium ribicola, preventing the formation of basidiospores which infect the primary host. Although spores from white pines cannot infect other white pines, survival spores may overwinter on infected pines and reinfect Ribes spp. the following season. Infected tissue is removed from white pines and strict quarantines of Ribes spp. are maintained in high risk areas.[citation needed]

Puccinia graminis is a macrocyclic heteroecious fungus that causes wheat stem rust disease.[citation needed] The sexual stage in this fungus occurs on the alternate host – barberry – and not wheat. The durable spore type produced on the alternate host allows the disease to persist in wheat even in more inhospitable environments. Planting resistant crops will prevent disease, however, virulence mutations will give rise to new strains of fungi that overcome plant resistance.[citation needed] Although the disease cannot be stopped by removal of the alternate host, the life cycle is disrupted and the rate of evolution is decreased because of reduced genetic recombination. This allows resistance bred crops to remain effective for a longer period of time.[9][23]

Demicyclic disease: Because there is no repeating stage in the life cycle of demicyclic fungi, removal of the primary or the alternate host will disrupt the disease cycle.[citation needed] This method, however, is not highly effective in managing all demicyclic diseases. Cedar-apple rust disease, for example, can persist despite removal of one of the hosts since spores can be disseminated from long distances. The severity of cedar-apple rust disease can be managed by removal of basidiospore producing galls from junipers or the application of protective fungicides to junipers.[24]

Home control edit

Rust diseases are very hard to treat. Fungicides, such as Mancozeb, may help but may never eradicate the disease.[citation needed] Some organic preventative solutions are available and sulphur powder is known to stop spore germination. High standards of hygiene, good soil drainage, and careful watering may minimize problems. Any appearance of rust must be immediately dealt with by removing and burning all affected leaves.[citation needed] Composting, or leaving infected vegetation on the ground will spread the disease.[citation needed]

Commercial control edit

In some large acreage crops, fungicides are applied by air. The process is expensive and fungicide application is best reserved for seasons when foliar diseases are severe. Research indicates, the higher the foliar disease severity, the greater the return from the use of fungicides.[25] Southern corn rust disease, can be confused with common rust. Southern rust's distinguishing characteristic is that pustules form mostly on the upper leaf surface and spores are more orange in color. Southern rust spreads more quickly and has a higher economic impact when hot, humid weather conditions persist. Timely fungicide applications to control southern rust are more crucial than with common rust.[26]

A variety of preventative methods can be employed for rust diseases:

  • High moisture levels may exacerbate rust disease symptoms. The avoidance of overhead watering at night, using drip irrigation, reducing crop density, and using fans to circulate air flow may decrease disease severity.
  • The use of rust resistant plant varieties
  • Crop rotation can break the disease cycle because many rusts are host specific and do not persist long without their host.
  • Inspection of imported plants and cuttings for symptoms. It is important to continuously observe the plants because rust diseases have a latent period (plant has the disease but shows no symptoms).
  • Use of disease-free seed can reduce incidence for some rusts[23]

Host plants affected edit

It is probable that most plant species are affected by some species of rust.[citation needed] Rusts are often named after a host species that they infect. For example; Puccinia xanthii infects the flowering plant cocklebur (Xanthium). Recently, a total of 95 rust fungi belonging to 25 genera associated with 117 forest plant species belonging to 80 host genera under 43 host families were reported from the Western Ghats, Kerala, India.[3] Rust fungi include:

Rust infected host genera include:[3]

Some of the better known hosts include:

Hyperparasites of rusts edit

In the family Sphaeropsidaceae of Sphaeropsidales fungi, species of the genus Darluca are hyperparasites on rusts.[27]

Gallery edit

  •  
    Rust fungus on a leaf, under low magnification.
  •  
    Urediniospores of a rust fungus.
  •  
    Diagram representing the infection process of rust fungi
  •  
    Rust fungus, Puccinia urticata on the surface of a nettle leaf
  •  
    Rust on onions

See also edit

References edit

  1. ^ a b c d e f g Aime, M. C.; McTaggart, A. R. (2021). "A higher-rank classification for rust fungi, with notes on genera". Fungal Systematics and Evolution. 7: 21–47. doi:10.3114/fuse.2021.07.02. PMC 8165960. PMID 34124616.
  2. ^ "Species Fungorum - Search Page". www.speciesfungorum.org. from the original on 9 October 2023. Retrieved 27 October 2022.
  3. ^ a b c d e f g h i Mohanan, C. (2010). Rust Fungi of Kerala. Kerala, India: Kerala Forest Research Institute. p. 148. ISBN 978-81-85041-72-8.
  4. ^ Kolmer, James A; Ordonez, Maria E; Groth, James V (2001). eLS. John Wiley & Sons, Ltd. doi:10.1002/9780470015902.a0021264. ISBN 9780470015902. S2CID 1434349.
  5. ^ Evans, R. (2007). Utopia Antiqua: Readings of the Golden Age and Decline at Rome. Taylor & Francis. ISBN 978-1-134-48787-5. from the original on 2023-10-09. Retrieved 2018-01-12.
  6. ^ Helfer, Stephan (2013-10-30). "Rust fungi and global change". New Phytologist. 201 (3): 770–780. doi:10.1111/nph.12570. ISSN 0028-646X. PMID 24558651.
  7. ^ Central Science Laboratory. (2006). Plant Healthcare: Rusts [Fact Sheet]. Retrieved from www.csldiagnostics.co.uk
  8. ^ "Rust Fungi". www.backyardnature.net. from the original on 2010-09-17. Retrieved 2010-08-06.
  9. ^ a b c d Schumann, G. & D'Arcy, C. (2010). Essential plant pathology. APS Press
  10. ^ Scott, K.J, & Chakravorty, A.K., (1982), The Rust fungi. Academic Press.
  11. ^ a b Peterson, R., (1974). The Rust Fungus Life Cycle. The Botanical Review. 40(4), 453-513.
  12. ^ Sulaiman Eve, Hassan Y; Runno-Paurson; Kaurilind, Eve; Niinemets, Ülo (2023). "Differential impact of crown rust (Puccinia coronata) infection on photosynthesis and volatile emissions in the primary host Avena sativa and the alternate host Rhamnus frangula". Journal of Experimental Botany. 74 (6): 2029–2046. doi:10.1093/jxb/erad001. PMID 36610799.
  13. ^ Craigie, J.H. (1931). Phytopathology, 21,1001
  14. ^ Dickinson, M. Molecular Plant Pathology. 2003.
  15. ^ Deising, H.B., S. Werner, and M. Wernitz, The role of fungal appressoria in plant infection. Microbes Infect, 2000. 2(13): p. 1631-41.
  16. ^ Zhou, X.L., et al., A mechanosensitive channel in whole cells and in membrane patches of the fungus Uromyces. Science, 1991. 253(5026): p. 1415.
  17. ^ Voegele, R.T. and K. Mendgen, Rust haustoria: nutrient uptake and beyond. New Phytologist, 2003. 159(1): p. 93-100.
  18. ^ Cornell University. (2010). Daylily rust: Puccinia hemerocallidis [Fact sheet]. Retrieved from http://plantclinic.cornell.edu 2010-08-18 at the Wayback Machine
  19. ^ Hooker, Arthur L (1967). "The Genetics and Expression of Resistance in Plants to Rusts of the Genus Puccinia". Annu. Rev. Phytopathol. 5 (1): 163–178. doi:10.1146/annurev.py.05.090167.001115.
  20. ^ Hurtado-Gonzales, O. P.; Valentini, G.; Gilio, T. A.; Martins, A. M.; Song, Q.; Pastor-Corrales, M. A. (2016). "Fine Mapping of Ur-3, a Historically Important Rust Resistance Locus in Common Bean". G3: Genes, Genomes, Genetics. 7 (2): 557–569. doi:10.1534/g3.116.036061. PMC 5295601. PMID 28031244.
  21. ^ a b c d e f g Staples, Richard (2000). "Research on the Rust Fungi During the Twentieth Century". Annual Review of Phytopathology. Annual Reviews. 38 (1): 49–69. doi:10.1146/annurev.phyto.38.1.49. ISSN 0066-4286. PMID 11701836. S2CID 4861612.
  22. ^ Dracatos, Peter M.; Lu, Jing; Sánchez‐Martín, Javier; Wulff, Brande B.H. (2023). "Resistance that stacks up: engineering rust and mildew disease control in the cereal crops wheat and barley". Plant Biotechnology Journal. 21 (10): 1938–1951. doi:10.1111/pbi.14106. PMC 10502761. PMID 37494504. S2CID 260201756.
  23. ^ a b Marsalis, M. & Goldberg, N. (2006). Leaf, Stem, And Stripe Rust Diseases of Wheat. [Fact sheet]. New Mexico State University. http://pubs.nmsu.edu/_a/A415/ 2022-11-27 at the Wayback Machine
  24. ^ Wallis, C. & Lewandowski, D. (2008). Cedar Rust Diseases of Ornamental Plants. [Fact Sheet]. Ohio State University. https://woodlandstewards.osu.edu/sites/woodlands/files/d6/files/pubfiles/3055%20cedar%20rust.pdf 2021-01-07 at the Wayback Machine
  25. ^ "Stopsoybeanrust.com". www.stopsoybeanrust.com. from the original on 2018-06-12. Retrieved 2010-08-06.
  26. ^ "Common Corn Rust". www.channel.com. from the original on 2019-12-16. Retrieved 2019-12-16.
  27. ^ faculty.ucr.edu 2016-03-03 at the Wayback Machine (retrieved December 2015)
  28. ^ Thompson, Clive. "How Rust went from a side project to the world's most-loved programming language". MIT Technology Review. from the original on 15 February 2023. Retrieved 15 February 2023.

External links edit

  •   Media related to Pucciniales at Wikimedia Commons

February 15, 2024
rust, fungus, rusts, fungal, plant, pathogens, order, pucciniales, previously, known, uredinales, causing, plant, fungal, diseases, rustsexample, wheat, leaf, from, disease, differential, puccinia, recondita, triticiscientific, classificationdomain, eukaryotak. Rusts are fungal plant pathogens of the order Pucciniales previously known as Uredinales causing plant fungal diseases RustsExample of wheat leaf from a disease differential of Puccinia recondita f sp triticiScientific classificationDomain EukaryotaKingdom FungiDivision BasidiomycotaClass PucciniomycetesOrder PuccinialesFamiliesAraucariomycetaceae 1 Chaconiaceae Coleosporiaceae Cronartiaceae Crossopsoraceae 1 Gymnosporangiaceae Melampsoraceae Milesinaceae 1 Ochropsoraceae 1 Phakopsoraceae Phragmidiaceae Pileolariaceae Pucciniaceae Pucciniosiraceae Pucciniastraceae Raveneliaceae Rogerpetersoniaceae 1 Skierkaceae 2 Sphaerophragmiaceae Tranzscheliaceae 1 Uropyxidaceae Zaghouaniaceae incorporating Mikronegeriaceae 1 mitosporic Pucciniales and incertae sedisAn estimated 168 rust genera and approximately 7 000 species more than half of which belong to the genus Puccinia are currently accepted 3 Rust fungi are highly specialized plant pathogens with several unique features Taken as a group rust fungi are diverse and affect many kinds of plants However each species has a range of hosts and cannot be transmitted to non host plants In addition most rust fungi cannot be grown easily in pure culture Most species of rust fungi are able to infect two different plant hosts in different stages of its life cycle and may produce up to five morphologically and cytologically distinct spore producing structures viz spermogonia aecia uredinia telia and basidia in successive stages of reproduction 4 Each spore type is very host specific and can typically infect only one kind of plant Rust fungi are obligate plant pathogens that only infect living plants Infections begin when a spore lands on the plant surface germinates and invades its host Infection is limited to plant parts such as leaves petioles tender shoots stem fruits etc 3 Plants with severe rust infection may appear stunted chlorotic yellowed or may display signs of infection such as rust fruiting bodies Rust fungi grow intracellularly and make spore producing fruiting bodies within or more often on the surfaces of affected plant parts 3 Some rust species form perennial systemic infections that may cause plant deformities such as growth retardation witch s broom stem canker galls or hypertrophy of affected plant parts Rusts get their name because they are most commonly observed as deposits of powdery rust coloured or brown spores on plant surfaces The Roman agricultural festival Robigalia April 25 has ancient origins in combating wheat rust 5 Contents 1 Impacts 2 Life cycle 3 Host plant rust fungus relationship 4 Infection process 5 Common rust fungi in agriculture 6 Management 6 1 Research 6 2 Control 6 2 1 Home control 6 2 2 Commercial control 6 3 Host plants affected 7 Hyperparasites of rusts 8 Gallery 9 See also 10 References 11 External linksImpacts editThis section needs additional citations for verification Please help improve this article by adding citations to reliable sources in this section Unsourced material may be challenged and removed October 2023 Learn how and when to remove this template message Rusts are among the most harmful pathogens to agriculture horticulture and forestry Rust fungi are major concerns and limiting factors for successful cultivation of agricultural and forest crops citation needed White pine blister rust wheat stem rust soybean rust and coffee rust are examples of notoriously damaging threats to economically important crops 3 Climate change may increase the prevalence of some rust species while causing others to decline through increased CO2 and O3 changes to temperature and humidity and enhanced spore dispersal due to more frequent extreme weather events 6 Life cycle editAll rusts are obligate parasites meaning that they require a living host to complete their life cycle They generally do not kill the host plant but can severely reduce growth and yield 7 Cereal crops can be devastated in one season oak trees infected in the main stem within their first five years by the rust Cronartium quercuum often die 8 nbsp Germinating urediniospore of Puccinia graminis model from the late 19th century Botanical Museum GreifswaldRust fungi can produce up to five spore types from corresponding fruiting body types during their life cycle depending on the species Roman numerals have traditionally been used to refer to these morphological types 0 Pycniospores Spermatia from Pycnidia These serve mainly as haploid gametes in heterothallic rusts I Aeciospores from Aecia These serve mainly as non repeating dikaryotic asexual spores and go on to infect the primary host II Urediniospores from Uredia Uredinia These serve as repeating dikaryotic vegetative spores These spores are referred to as the repeating stage because they can cause auto infection on the primary host re infecting the same host on which the spores were produced They are often profuse red orange and a prominent sign of rust disease III Teliospores from Telia These dikaryotic spores are often the survival overwintering stage of the life cycle They usually do not infect a plant directly instead they germinate to produce basidia and basidiospores IV Basidiospores from Teliospores These windborne haploid spores often infect the alternate host in Spring 9 10 They are rarely observed outside of the laboratory Rust fungi are often categorized by their life cycle Three basic types of life cycles are recognized based on the number of spore types as macrocyclic demicyclic and microcyclic 3 The macrocyclic life cycle has all spore states the demicyclic lacks the uredinial state and the microcyclic cycle lacks the basidial pycnial and the aecial states thus possess only uredinia and telia Spermagonia may be absent from each type but especially the microcyclic life cycle In macrocyclic and demicyclic life cycles the rust may be either host alternating heteroecious i e the aecial stage is on one kind of plant but the telial stage on a different and unrelated plant or single host autoecious i e the aecial and telial states on the same plant host 3 Heteroecious rust fungi require two unrelated hosts to complete their life cycle with the primary host being infected by aeciospores and the alternate host being infected by basidiospores This can be contrasted with an autoecious fungus such as Puccinia porri which can complete all parts of its life cycle on a single host species 9 Understanding the life cycles of rust fungi allows for proper disease management 11 Host plant rust fungus relationship editThere are definite patterns of relationship with host plant groups and the rust fungi that parasitize them Some genera of rust fungi especially Puccinia and Uromyces comprise species that are capable of parasitizing plants of many families citation needed Other rust genera appear to be restricted to certain plant groups citation needed Host restriction may in heteroecious species apply to both phases of life cycle or to only one phase 3 As with many pathogen host pairs rusts are often in gene for gene relationships with their plants This rust plant gene for gene interaction differs somewhat from other gene for gene situations and has its own quirks and agronomic significance Rust fungi decrease photosynthesis and elicit the emissions of different stress volatiles with increasing severity of infection 12 Infection process editThe spores of rust fungi may be dispersed by wind water or insect vectors 13 When a spore encounters a susceptible plant it can germinate and infect plant tissues A rust spores typically germinates on a plant surface growing a short hypha called a germ tube This germ tube may locate a stoma by a touch responsive process known as thigmotropism This involves orienting to ridges created by epidermal cells on the leaf surface and growing directionally until it encounters a stoma 14 nbsp Rust hypha attacking stoma 1600x magnification Over the stoma a hyphal tip produces an infection structure called an appressorium From the underside of an appressorium a slender hypha grows downward to infect plant cells 15 It is thought that the whole process is mediated by stretch sensitive calcium ion channels located in the tip of the hypha which produce electric currents and alter gene expression inducing appressorium formation 16 Once the fungus has invaded the plant it grows into plant mesophyll cells producing specialized hyphae known as haustoria The haustoria penetrate cell walls but not cell membranes plant cell membranes invaginate around the main haustorial body forming a space known as the extra haustorial matrix An iron and phosphorus rich neck band bridges the plant and fungal membranes in the space between the cells for water flow known as the apoplast thus preventing the nutrients reaching the plant s cells The haustorium contains amino acid and hexose sugar transporters and H ATPases which are used for active transport of nutrients from the plant nourishing the fungus 17 The fungus continues growing penetrating more and more plant cells until spore growth occurs The process repeats every 10 14 days producing numerous spores that can be spread to other parts of the same plant or to new hosts Common rust fungi in agriculture edit 9 11 18 Cronartium ribicola white pine blister rust the primary hosts are currants and white pines the secondary Heterocyclic and macrocyclic Gymnosporangium juniperi virginianae cedar apple rust Juniperus virginiana is the primary telial host and apple pear or hawthorn is the secondary aecial host Heteroecious and demicyclic Hemileia vastatrix coffee rust primary host is coffee plant unknown alternate host Heteroecious Phakopsora meibomiae and P pachyrhizi soybean rust primary host is soybean and various legumes Unknown alternate host Heteroecious Puccinia coronata crown rust of oats and ryegrass oats are the primary host Rhamnus spp Buckthorn is alternate host Heteroecious and macrocyclic P graminis stem rust of wheat and Kentucky bluegrass or black rust of cereals primary hosts include Kentucky bluegrass barley and wheat Common barberry is the alternate host Heteroecious and macrocyclic P hemerocallidis daylily rust daylily is primary host Patrinia sp is alternate host Heteroecious and macrocyclic P kuehnii orange rust of sugarcane P melanocephala brown rust of sugarcane P porri leek rust Autoecious P sorghi common rust of corn 19 P striiformis yellow rust of cereals P triticina brown wheat rust in grains Uromyces appendiculatus bean rust in common bean Phaseolus vulgaris 20 Management editResearch edit Efforts to control rusts began to be scientifically based in the 20th century 21 Elvin C Stakman initiated the scientific study of host resistance which had heretofore been poorly understood and handled by individual growers as part of the breeding process 21 Stakman was followed by H H Flor s extensive discoveries of rust genetics 21 In order to study rust metabolics Tervet et al 1951 developed the Cyclone Separator 21 The cyclone separator uses the cyclonic separation mechanism to allow the mechanised collection of spores for study Cherry amp Peet 1966 s improved version gathers even more efficiently 21 This device was first put to work testing the composition of the spores themselves especially substances coating the outside of the spores which signal population density 21 When detected they help prevent crowding 21 Gene cloning and other methods of genetic engineering can provide a much wider range of R genes and other sources of rust resistance with reduced delay before deployment if regulation of genetic engineering permits 22 Control edit This section needs additional citations for verification Please help improve this article by adding citations to reliable sources in this section Unsourced material may be challenged and removed October 2023 Learn how and when to remove this template message The control methods of rust fungus diseases depend largely on the life cycle of the particular pathogen The following are examples of disease management plans used to control macrocyclic and demicyclic diseases Macrocyclic disease Developing a management plan for this type of disease depends largely on whether the urediniospores rarely termed the repeating stage occur on the economically important host plant or the alternate host citation needed For example the repeating stage in white pine blister rust disease does not occur on white pines but on the alternate host Ribes spp During August and September Ribes spp give rise to teliospores which infect white pines Removal of the alternate host disrupts the life cycle of the rust fungi Cronartium ribicola preventing the formation of basidiospores which infect the primary host Although spores from white pines cannot infect other white pines survival spores may overwinter on infected pines and reinfect Ribes spp the following season Infected tissue is removed from white pines and strict quarantines of Ribes spp are maintained in high risk areas citation needed Puccinia graminis is a macrocyclic heteroecious fungus that causes wheat stem rust disease citation needed The sexual stage in this fungus occurs on the alternate host barberry and not wheat The durable spore type produced on the alternate host allows the disease to persist in wheat even in more inhospitable environments Planting resistant crops will prevent disease however virulence mutations will give rise to new strains of fungi that overcome plant resistance citation needed Although the disease cannot be stopped by removal of the alternate host the life cycle is disrupted and the rate of evolution is decreased because of reduced genetic recombination This allows resistance bred crops to remain effective for a longer period of time 9 23 Demicyclic disease Because there is no repeating stage in the life cycle of demicyclic fungi removal of the primary or the alternate host will disrupt the disease cycle citation needed This method however is not highly effective in managing all demicyclic diseases Cedar apple rust disease for example can persist despite removal of one of the hosts since spores can be disseminated from long distances The severity of cedar apple rust disease can be managed by removal of basidiospore producing galls from junipers or the application of protective fungicides to junipers 24 Home control edit Rust diseases are very hard to treat Fungicides such as Mancozeb may help but may never eradicate the disease citation needed Some organic preventative solutions are available and sulphur powder is known to stop spore germination High standards of hygiene good soil drainage and careful watering may minimize problems Any appearance of rust must be immediately dealt with by removing and burning all affected leaves citation needed Composting or leaving infected vegetation on the ground will spread the disease citation needed Commercial control edit In some large acreage crops fungicides are applied by air The process is expensive and fungicide application is best reserved for seasons when foliar diseases are severe Research indicates the higher the foliar disease severity the greater the return from the use of fungicides 25 Southern corn rust disease can be confused with common rust Southern rust s distinguishing characteristic is that pustules form mostly on the upper leaf surface and spores are more orange in color Southern rust spreads more quickly and has a higher economic impact when hot humid weather conditions persist Timely fungicide applications to control southern rust are more crucial than with common rust 26 A variety of preventative methods can be employed for rust diseases High moisture levels may exacerbate rust disease symptoms The avoidance of overhead watering at night using drip irrigation reducing crop density and using fans to circulate air flow may decrease disease severity The use of rust resistant plant varieties Crop rotation can break the disease cycle because many rusts are host specific and do not persist long without their host Inspection of imported plants and cuttings for symptoms It is important to continuously observe the plants because rust diseases have a latent period plant has the disease but shows no symptoms Use of disease free seed can reduce incidence for some rusts 23 Host plants affected edit It is probable that most plant species are affected by some species of rust citation needed Rusts are often named after a host species that they infect For example Puccinia xanthii infects the flowering plant cocklebur Xanthium Recently a total of 95 rust fungi belonging to 25 genera associated with 117 forest plant species belonging to 80 host genera under 43 host families were reported from the Western Ghats Kerala India 3 Rust fungi include Aecidium Cerotelium Chaconia Coleosporium Crossopsora Didymopsorella Hamspora Hapalophragmidium Hemileia Kernkampella Kuehneola Kweilingia Macabuna Maravalia Melampsora Olivea Physopella Puccinia Ravenelia Uraecium Uredo Uredopeltis Uromyces Xenostele Zaghouania Rust infected host genera include 3 Acacia Acalypha Ageratina Albizia Arundinaria Bambusa Bidens Blepharis Bombax Bridelia Callicarpa Canarium Canthium Catunaragam Cinnamomum Cissus Cleistanthus Clerodendron Coffea Coix Cosmostigma Crotalaria Dalbergia Dendrocalamus Derris Diospyros Dipterocanthus Elaeagnus Elephantopus Elettaria Eragrostis Euphorbia Ficus Flacourtia Grewia Holarrhena Holoptelia Hypericum Ichnocarpus Ischaemum Jasminum Justicia Loesneriella Luvunga Meiogyne Meliosma Mimusops Morus Neolitzea Ocimum Olea Oxalis Pavetta Persicaria Phyllanthus Plectranthus Plumeria Pongamia Premna Protasparagus Rubus Salix Spondia Strobilanthes Strychnos Tabernaemontana Terminalia Toddalia Trichosanthes Vernonia Vigna Wrightia Xanthophyllum Xylia Ziziphus Some of the better known hosts include Arisaema triphyllum Jack in the pulpit Avena sativa Oats Berberis vulgaris Common barberry Vicia faba Broad beans Coffea arabica Coffee Crataegus monogyna Hawthorn Chrysanthemum Cydonia Quince Euphorbia maculata Spotted Spurge Fuchsia spp Garlic Hordeum vulgare Barley Juniperus virginiana Red Cedar Juniper apple disease Juniperus communis Juniper Allium ampeloprasum Leek Malus Apple Mentha piperita Peppermint Mespilus Medlar Onion Pelargonium Primula veris Primula vulgaris Pyrus Pear Rosa spp Roses Triticum spp Wheat Oxalis spp Oxalis Secale cereale Rye Senecio vulgaris Common groundsel Xanthium canadense CockleburHyperparasites of rusts editIn the family Sphaeropsidaceae of Sphaeropsidales fungi species of the genus Darluca are hyperparasites on rusts 27 Gallery edit nbsp Rust fungus on a leaf under low magnification nbsp Urediniospores of a rust fungus nbsp Diagram representing the infection process of rust fungi nbsp Rust fungus Puccinia urticata on the surface of a nettle leaf nbsp Rust on onionsSee also edit nbsp Fungi portalStem rust Wheat leaf rust Leaf rust barley Fungus Smut fungus Soybean rust Rust programming language named after the Rust fungus 28 References edit a b c d e f g Aime M C McTaggart A R 2021 A higher rank classification for rust fungi with notes on genera Fungal Systematics and Evolution 7 21 47 doi 10 3114 fuse 2021 07 02 PMC 8165960 PMID 34124616 Species Fungorum Search Page www speciesfungorum org Archived from the original on 9 October 2023 Retrieved 27 October 2022 a b c d e f g h i Mohanan C 2010 Rust Fungi of Kerala Kerala India Kerala Forest Research Institute p 148 ISBN 978 81 85041 72 8 Kolmer James A Ordonez Maria E Groth James V 2001 eLS John Wiley amp Sons Ltd doi 10 1002 9780470015902 a0021264 ISBN 9780470015902 S2CID 1434349 Evans R 2007 Utopia Antiqua Readings of the Golden Age and Decline at Rome Taylor amp Francis ISBN 978 1 134 48787 5 Archived from the original on 2023 10 09 Retrieved 2018 01 12 Helfer Stephan 2013 10 30 Rust fungi and global change New Phytologist 201 3 770 780 doi 10 1111 nph 12570 ISSN 0028 646X PMID 24558651 Central Science Laboratory 2006 Plant Healthcare Rusts Fact Sheet Retrieved from www csldiagnostics co uk Rust Fungi www backyardnature net Archived from the original on 2010 09 17 Retrieved 2010 08 06 a b c d Schumann G amp D Arcy C 2010 Essential plant pathology APS Press Scott K J amp Chakravorty A K 1982 The Rust fungi Academic Press a b Peterson R 1974 The Rust Fungus Life Cycle The Botanical Review 40 4 453 513 Sulaiman Eve Hassan Y Runno Paurson Kaurilind Eve Niinemets Ulo 2023 Differential impact of crown rust Puccinia coronata infection on photosynthesis and volatile emissions in the primary host Avena sativa and the alternate host Rhamnus frangula Journal of Experimental Botany 74 6 2029 2046 doi 10 1093 jxb erad001 PMID 36610799 Craigie J H 1931 Phytopathology 21 1001 Dickinson M Molecular Plant Pathology 2003 Deising H B S Werner and M Wernitz The role of fungal appressoria in plant infection Microbes Infect 2000 2 13 p 1631 41 Zhou X L et al A mechanosensitive channel in whole cells and in membrane patches of the fungus Uromyces Science 1991 253 5026 p 1415 Voegele R T and K Mendgen Rust haustoria nutrient uptake and beyond New Phytologist 2003 159 1 p 93 100 Cornell University 2010 Daylily rust Puccinia hemerocallidis Fact sheet Retrieved from http plantclinic cornell edu Archived 2010 08 18 at the Wayback Machine Hooker Arthur L 1967 The Genetics and Expression of Resistance in Plants to Rusts of the Genus Puccinia Annu Rev Phytopathol 5 1 163 178 doi 10 1146 annurev py 05 090167 001115 Hurtado Gonzales O P Valentini G Gilio T A Martins A M Song Q Pastor Corrales M A 2016 Fine Mapping of Ur 3 a Historically Important Rust Resistance Locus in Common Bean G3 Genes Genomes Genetics 7 2 557 569 doi 10 1534 g3 116 036061 PMC 5295601 PMID 28031244 a b c d e f g Staples Richard 2000 Research on the Rust Fungi During the Twentieth Century Annual Review of Phytopathology Annual Reviews 38 1 49 69 doi 10 1146 annurev phyto 38 1 49 ISSN 0066 4286 PMID 11701836 S2CID 4861612 Dracatos Peter M Lu Jing Sanchez Martin Javier Wulff Brande B H 2023 Resistance that stacks up engineering rust and mildew disease control in the cereal crops wheat and barley Plant Biotechnology Journal 21 10 1938 1951 doi 10 1111 pbi 14106 PMC 10502761 PMID 37494504 S2CID 260201756 a b Marsalis M amp Goldberg N 2006 Leaf Stem And Stripe Rust Diseases of Wheat Fact sheet New Mexico State University http pubs nmsu edu a A415 Archived 2022 11 27 at the Wayback Machine Wallis C amp Lewandowski D 2008 Cedar Rust Diseases of Ornamental Plants Fact Sheet Ohio State University https woodlandstewards osu edu sites woodlands files d6 files pubfiles 3055 20cedar 20rust pdf Archived 2021 01 07 at the Wayback Machine Stopsoybeanrust com www stopsoybeanrust com Archived from the original on 2018 06 12 Retrieved 2010 08 06 Common Corn Rust www channel com Archived from the original on 2019 12 16 Retrieved 2019 12 16 faculty ucr edu Archived 2016 03 03 at the Wayback Machine retrieved December 2015 Thompson Clive How Rust went from a side project to the world s most loved programming language MIT Technology Review Archived from the original on 15 February 2023 Retrieved 15 February 2023 External links edit nbsp Media related to Pucciniales at Wikimedia Commons Retrieved from https en wikipedia org w index php title Rust fungus amp oldid 1194543908, wikipedia, wiki, book, books, library,

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