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'''Rusts''' are plant diseases caused by [[Pathogen|pathogenic]] [[Fungus|fungi]] of the order '''Pucciniales''' (previously known as Uredinales). |
'''Rusts''' are plant diseases caused by [[Pathogen|pathogenic]] [[Fungus|fungi]] of the order '''Pucciniales''' (previously known as Uredinales). |
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An estimated 168 rust genera and approximately 7,000 species, more than half of which belong to the genus ''[[Puccinia]]'', are currently accepted. Rust fungi are highly specialized plant pathogens with several unique features. Taken as a group, rust fungi are diverse |
An estimated 168 rust genera and approximately 7,000 species, more than half of which belong to the genus ''[[Puccinia]]'', are currently accepted. Rust fungi are highly specialized plant pathogens with several unique features. Taken as a group, rust fungi are diverse to which they can thrive in high humidity environments but also not limited to desert climates. This pathogen affects many kinds of plants. Among those greatly affected are agriculture crops and forest crops (Bakkeren). However, each species has a very narrow range of hosts and cannot be transmitted to non-host plants. This is due to their biotrophic nature of their pathosystem of pathogen-host interaction in order to propagate which makes them a difficult species to culture based off of their specific genetic factors (Bakkeren). In addition, most rust fungi cannot be grown easily in pure culture. A few studies have been done to try and understand the complex life cycle of genetic manipulation on gene function interaction on ''Puccinia graminis f. sp. tritici''-, ''Puccinia triticna, Cronartium quercuum f. sp. fusiforme, Puccinia striiformis f. sp. tritici, etc.'' |
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A single species of rust fungi may be able to infect two different plant hosts in different stages of its life cycle, and may produce up to five [[Morphology (biology)|morphologically]] and [[cytologically]] distinct spore-producing structures viz., [[spermogonia]], [[aecia]], [[Uredinium|uredinia]], [[Telium|telia]], and [[basidia]] in successive stages of reproduction. Each spore type is very host specific, and can typically infect only one kind of plant. |
A single species of rust fungi may be able to infect two different plant hosts in different stages of its life cycle, and may produce up to five [[Morphology (biology)|morphologically]] and [[cytologically]] distinct spore-producing structures viz., [[spermogonia]], [[aecia]], [[Uredinium|uredinia]], [[Telium|telia]], and [[basidia]] in successive stages of reproduction. Each spore type is very host specific, and can typically infect only one kind of plant. |
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Impacts Portion |
Impacts Portion |
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Rusts are considered 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. White pine blister rust, wheat stem rust, soybean rust, and coffee rust are examples of notoriously damaging threats to economically important crops which can cause epidemics.<ref name="auto">{{cite book |author=Mohanan C. |title=Rust Fungi of Kerala |publisher=Kerala Forest Research Institute |year=2010 |isbn=978-81-85041-72-8 |location=Kerala, India |pages=148}}</ref> Studies on rust fungi continues to be an on going research today but the expansion to rust genomes have no doubtedly been catigorized to be more complex than other fungi (Bakken). Climate change can have a possible impact to |
Rusts are considered 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. White pine blister rust, wheat stem rust, soybean rust, and coffee rust are examples of notoriously damaging threats to economically important crops which can cause epidemics.<ref name="auto">{{cite book |author=Mohanan C. |title=Rust Fungi of Kerala |publisher=Kerala Forest Research Institute |year=2010 |isbn=978-81-85041-72-8 |location=Kerala, India |pages=148}}</ref> Studies on rust fungi continues to be an on going research today but the expansion to rust genomes have no doubtedly been catigorized to be more complex than other fungi (Bakken). Climate change can have a possible impact to rust fungi due to the increase in CO2 and O3, climate warming, humidity, extreme weather changes.<ref>{{Cite journal |last=Helfer |first=Stephan |date=2013-10-30 |title=Rust fungi and global change |url=https://doi.org/10.1111/nph.12570 |journal=New Phytologist |volume=201 |issue=3 |pages=770–780 |doi=10.1111/nph.12570 |issn=0028-646X}}</ref> Copied from [[Rust (fungus)]]. Depending on the type of rust fungus we could possibly see no change, declines, or even an increase from the rust pathogen. |
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== Life cycle == |
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All rusts are obligate [[Parasite|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.<ref name="csldiagnostics.co.uk2">Central Science Laboratory. (2006). Plant Healthcare: Rusts [Fact Sheet]. Retrieved from www.csldiagnostics.co.uk</ref> [[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.<ref>{{cite web |title=Rust Fungi |url=http://www.backyardnature.net/f/rusts.htm |website=www.backyardnature.net}}</ref> |
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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. |
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* 0-'''[[Pycniospores]]''' ([[Spermatia]]) from [[Pycnidia]]. These serve mainly as [[haploid]] [[Gamete|gametes]] in [[heterothallic]] rusts. |
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* I-'''[[Aeciospores]]''' from Aecia. These serve mainly as non-repeating, [[dikaryotic]], asexual spores, and go on to infect the primary host. |
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* 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. |
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* 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. |
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* IV-'''[[Basidiospores]]''' from [[Teliospores]]. These windborne haploid spores often infect the alternate host in Spring.<ref name="Schumann, G. 2010">Schumann, G. & D'Arcy, C. (2010). Essential plant pathology. APS Press</ref><ref>Scott, K.J, & Chakravorty, A.K., (1982), The Rust fungi. Academic Press.</ref> They are rarely observed outside of the [[laboratory]]. |
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Host Plant-Rust Fungus Relationship Portion |
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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. These two species are considered to be some of the critical drivers for their diversification through their co-evolution with their host due to the fact they are not limited to one plant group that influences heavily on plants and vegetation (Helfer). Other rust genera appear to be restricted to certain plant groups. Host restriction may, in [[heteroecious]] species, apply to both phases of life cycle or to only one phase.<ref name="auto2">{{cite book |author=Mohanan C. |title=Rust Fungi of Kerala |publisher=Kerala Forest Research Institute |year=2010 |isbn=978-81-85041-72-8 |location=Kerala, India |pages=148}}</ref> This pathogen relationship usually happens within short generation times (weeks to months), but depending on a host plant that that generates within months or serval years this can be detrimental. For example Herbaceous plants and trees that have long generational growth times are more often slower at reproducing to reach full growth that adaptation/evolution towards the host declines the overall fitness loss to the species (Helfer). As with many pathogen/host pairs, rusts are often in [[Gene-for-gene relationship|gene-for-gene relationships]] with their plants. This [[Gene-for-gene interactions in rust fungi|rust-plant gene-for-gene interaction]] differs somewhat from other gene-for-gene situations and has its own quirks and agronomic significance. The host parasitic relationship begin through the stomata then by penetration to enter the epidermal cell wall to germinate. Once successful the pathogen will begin to use its' host to reduce the hosts' carbon sequestration and metabolizing photosyntheses for their own benefit (Helfer). |
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== Infection process == |
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<ref>Dickinson, M. Molecular Plant Pathology. 2003.</ref> |
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The spores of rust fungi may be dispersed by wind, water or [[insect]] vectors.<ref>Craigie, J.H. (1931). ''Phytopathology'', 21,1001</ref> Dispersal usually happens by the wind to which can spread up to 300m or more depending on wind current (Kinloch, 2003). 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 [[Epidermis (botany)|epidermal cells]] on the leaf surface, and growing directionally until it encounters a stoma.Life cycle Portion |
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<ref>{{cite web |title=Rust Fungi |url=http://www.backyardnature.net/f/rusts.htm |website=www.backyardnature.net}}</ref> |
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All rusts are obligate [[Parasite|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.<ref name="csldiagnostics.co.uk">Central Science Laboratory. (2006). Plant Healthcare: Rusts [Fact Sheet]. Retrieved from www.csldiagnostics.co.uk</ref> Many rust fungi have annual life cycles (Helfer). [[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. |
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==== Commercial control ==== |
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<ref>{{Cite web |title=Common Corn Rust |url=https://www.channel.com/en-us/agronomy/common-corn-rust.html |website=www.channel.com}}</ref> |
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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.<ref>{{cite web |title=Stopsoybeanrust.com |url=http://www.stopsoybeanrust.com/viewStory.asp?StoryID=1140 |website=www.stopsoybeanrust.com}}</ref> 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. Rust control to minimize infection or epidemic have also been used as a reversal strategy to fight invasive species an area as a biocontrol agent to increase native species to flourish as well (Rayachhetry et al., 2001). |
Revision as of 03:53, 3 April 2022
This my Sandbox for the intro to Rust fungus.
Rusts are plant diseases caused by pathogenic fungi of the order Pucciniales (previously known as Uredinales).
An estimated 168 rust genera and approximately 7,000 species, more than half of which belong to the genus Puccinia, are currently accepted. Rust fungi are highly specialized plant pathogens with several unique features. Taken as a group, rust fungi are diverse to which they can thrive in high humidity environments but also not limited to desert climates. This pathogen affects many kinds of plants. Among those greatly affected are agriculture crops and forest crops (Bakkeren). However, each species has a very narrow range of hosts and cannot be transmitted to non-host plants. This is due to their biotrophic nature of their pathosystem of pathogen-host interaction in order to propagate which makes them a difficult species to culture based off of their specific genetic factors (Bakkeren). In addition, most rust fungi cannot be grown easily in pure culture. A few studies have been done to try and understand the complex life cycle of genetic manipulation on gene function interaction on Puccinia graminis f. sp. tritici-, Puccinia triticna, Cronartium quercuum f. sp. fusiforme, Puccinia striiformis f. sp. tritici, etc.
A single species of rust fungi may be 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. 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. 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. 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. Once infected by the host, rust fungi can easily spread through wind-dispersal which can possibly cause an epidemic, especially within agriculture species such as wheat, cereal, oats, barley, corn, beans, coffee, etc. are to name a few major food groups. Rust normally exerts itself into its' host by first infiltrating the stomate through exposure. This allows appressorium to form. Once exposed on the leaf the most important part in order for rust fungal to occur is if the host penetrates through the epidermal cell wall allowing germination to begin (Hoch). From there the pathogen goes through a detailed process to continue its' host invasion for survival.
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. Copied from Rust (fungus)
Impacts Portion
Rusts are considered 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. White pine blister rust, wheat stem rust, soybean rust, and coffee rust are examples of notoriously damaging threats to economically important crops which can cause epidemics.[1] Studies on rust fungi continues to be an on going research today but the expansion to rust genomes have no doubtedly been catigorized to be more complex than other fungi (Bakken). Climate change can have a possible impact to rust fungi due to the increase in CO2 and O3, climate warming, humidity, extreme weather changes.[2] Copied from Rust (fungus). Depending on the type of rust fungus we could possibly see no change, declines, or even an increase from the rust pathogen.
Life cycle
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.[3] 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.[4]
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.[5][6] They are rarely observed outside of the laboratory.
Host Plant-Rust Fungus Relationship Portion
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. These two species are considered to be some of the critical drivers for their diversification through their co-evolution with their host due to the fact they are not limited to one plant group that influences heavily on plants and vegetation (Helfer). Other rust genera appear to be restricted to certain plant groups. Host restriction may, in heteroecious species, apply to both phases of life cycle or to only one phase.[7] This pathogen relationship usually happens within short generation times (weeks to months), but depending on a host plant that that generates within months or serval years this can be detrimental. For example Herbaceous plants and trees that have long generational growth times are more often slower at reproducing to reach full growth that adaptation/evolution towards the host declines the overall fitness loss to the species (Helfer). 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. The host parasitic relationship begin through the stomata then by penetration to enter the epidermal cell wall to germinate. Once successful the pathogen will begin to use its' host to reduce the hosts' carbon sequestration and metabolizing photosyntheses for their own benefit (Helfer).
Infection process
The spores of rust fungi may be dispersed by wind, water or insect vectors.[9] Dispersal usually happens by the wind to which can spread up to 300m or more depending on wind current (Kinloch, 2003). 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.Life cycle Portion
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.[11] Many rust fungi have annual life cycles (Helfer). 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.
Commercial control
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.[13] 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. Rust control to minimize infection or epidemic have also been used as a reversal strategy to fight invasive species an area as a biocontrol agent to increase native species to flourish as well (Rayachhetry et al., 2001).
- ^ Mohanan C. (2010). Rust Fungi of Kerala. Kerala, India: Kerala Forest Research Institute. p. 148. ISBN 978-81-85041-72-8.
- ^ Helfer, Stephan (2013-10-30). "Rust fungi and global change". New Phytologist. 201 (3): 770–780. doi:10.1111/nph.12570. ISSN 0028-646X.
- ^ Central Science Laboratory. (2006). Plant Healthcare: Rusts [Fact Sheet]. Retrieved from www.csldiagnostics.co.uk
- ^ "Rust Fungi". www.backyardnature.net.
- ^ Schumann, G. & D'Arcy, C. (2010). Essential plant pathology. APS Press
- ^ Scott, K.J, & Chakravorty, A.K., (1982), The Rust fungi. Academic Press.
- ^ Mohanan C. (2010). Rust Fungi of Kerala. Kerala, India: Kerala Forest Research Institute. p. 148. ISBN 978-81-85041-72-8.
- ^ Dickinson, M. Molecular Plant Pathology. 2003.
- ^ Craigie, J.H. (1931). Phytopathology, 21,1001
- ^ "Rust Fungi". www.backyardnature.net.
- ^ Central Science Laboratory. (2006). Plant Healthcare: Rusts [Fact Sheet]. Retrieved from www.csldiagnostics.co.uk
- ^ "Common Corn Rust". www.channel.com.
- ^ "Stopsoybeanrust.com". www.stopsoybeanrust.com.