Wheat leaf rust | |
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Common names | Brown rust Leaf rust |
Causal agents | Puccinia triticina |
Hosts | wheat |
EPPO Code | PUCCRT |
Distribution | Worldwide |
Wheat leaf rust | |
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Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Fungi |
Division: | Basidiomycota |
Class: | Pucciniomycetes |
Order: | Pucciniales |
Family: | Pucciniaceae |
Genus: | Puccinia |
Species: | P. triticina |
Binomial name | |
Puccinia triticina Erikss. (1899) | |
Synonyms | |
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Wheat leaf rust (Puccinia triticina) is a fungal disease that affects wheat, barley, rye stems, leaves and grains. In temperate zones it is destructive on winter wheat because the pathogen overwinters. Infections can lead up to 20% yield loss. The pathogen is a Puccinia rust fungus. It is the most prevalent of all the wheat rust diseases, occurring in most wheat-growing regions. [1] It causes serious epidemics in North America, Mexico and South America and is a devastating seasonal disease in India. P. triticina is heteroecious, requiring two distinct hosts (alternate hosts). [1] [2]
Plant breeders have tried to improve yield quantities in crops like wheat from the beginning of agriculture. From the 20th century, breeding for resistance against disease proved to be as important for total wheat production as breeding for increase in yield. The use of a single resistance gene against various pests and diseases plays a major role in resistance breeding for cultivated crops. The earliest single resistance gene was identified as effective against yellow rust. Numerous single genes for leaf rust resistance have since been identified.
Leaf rust resistance gene is an effective adult-plant resistance gene that increases resistance of plants against P. recondita f.sp. tritici (UVPrt2 or UVPrt13) infections, especially when combined with genes Lr13 and gene Lr34 (Kloppers & Pretorius, 1997 [3] ). Lr37 originates from the French cultivar VPM1 (Dyck & Lukow, 1988 [4] ). The line RL6081, developed in Canada for Lr37 resistance, showed seedling and adult-plant resistance to leaf, yellow and stem rust. Crosses between the French cultivars will therefore introduce this gene into local germplasm, raising the genetic variation of South African cultivars.
Molecular techniques have been used to estimate genetic distances among different wheat cultivars. With the genetic distances known predictions can be made for the best combinations concerning the two foreign genotypes carrying gene Lr37, VPMI and RL6081 and local South African cultivars. This is especially important in wheat with its low genetic variation. The gene will be transferred with the least amount of backcrossing to cultivars genetically closest to each other, generation similar genetic offspring to the recurrent parent, but with gene Lr37 present. Genetic distances between near isogenic lines (NILs) for a particular gene will give an indication of how many loci, amplified with molecular techniques, need to be compared to locate putative markers linked to the gene.[ citation needed ]
The Puccinia species causing wheat leaf rust has been called by at least six different names since 1882, when G. Winter (1882) described the Puccinia rubigo-vera. [5] During this time, wheat leaf rust was interpreted as a specialized form of P. rubigo-vera. Later, Eriksson and Henning (1894) classified the fungi as P. dispersa f.sp. tritici.[ citation needed ] In 1899, Eriksson concluded that the rust should be considered a separate authentic species. Due to this, he described the fungi as P. triticina.[ citation needed ] This name was used by Gauemann (1959) in his comprehensive book about rust fungi of middle Europe. [6] [ page needed ]
Mains (1933) was among the first scientists to use a species name with a broad species concept for wheat leaf rust. He considered P. Rubigo-vera a current name and posited that 32 binomials were synonyms of that species. [7] George Baker Cummins and Ralph Merrill Caldwell (1956) built off the broad species concept and also discussed the validity of P. rubigo-vera, which was based on a uredinial-stage basionym. Finally, they introduced P. recondita as the oldest valid name for grass-based rusts, including wheat leaf rust. [8] Their idea and publication was followed by Wilson & Henderson (1966) in another comprehensive rust flora (viz. British Rust Flora). Wilson and Henderson (1966) also used a broad species concept for P. recondita and divided this broad species into 11 different formae speciales. The accepted name for wheat leaf rust in their flora was P. recondita f.sp. tritici. [9] Cummins (1971), in his rust monograph for Poaceae, introduced an ultra-broad species concept for P. recondita and listed 52 binomials as its synonyms. [10]
A stream of thought opposite to broad morphologically-based concepts also gained traction among uredinologists. This idea was introduced into the classification of graminicolous rust fungi by Urban (1969), who believed a taxonomic name should reflect both morphology and ecology of a species. In his paper, Urban introduced P. perplexans var. triticina as an appropriate name for wheat leaf rust. [11] Savile (1984) was also among the uredinologists who believed in narrowing the species concept. He considered P. triticina as an authentic taxonomic name for wheat leaf rust. [12] Meanwhile, as his research continued Urban considered morphological, ecological, and field experiences while studying wheat leaf rust, coming to consider the fungi as a part of the species Puccinia persistens with its aecial stage on Ranunculaceae members, totally different from P. recondita, which produces its aecial stage on Boraginaceae family members. His final name for this rust was P. persistens subsp. triticina. [13] Molecular and morphological studies proved Urban's taxonomy for wheat leaf rust to be correct. [14]
Wheat leaf rust spreads via airborne spores. Five types of spores are formed in the life cycle: Urediniospores, teliospores, and basidiospores develop on wheat plants and pycniospores and aeciospores develop on the alternate hosts. [15] The germination process requires moisture, and works best at 100% humidity. Optimum temperature for germination is between 15–20 °C (59–68 °F). Before sporulation, wheat plants appear completely asymptomatic.
Wheat (Triticum aestivum), durum (T. turgidum var. durum), domesticated emmer (T. dicoccon) and wild emmer (T. dicoccoides), Aegilops speltoides , jointed goatgrass ( Ae. cylindrica ), and triticale (X Triticosecale). [2]
Several of the Ranunculaceae serve as alternate hosts, but rarely. This does not occur with the same frequency as with stem rust and barberry. [H 1] Thalictrum speciosissimum (synonym T. flavum glaucum) and Isopyrum fumaroides . [2]
P. triticina has an asexual and sexual life-cycle phase. To complete its sexual phase, P. triticina requires a second host ( Thalictrum flavum glaucum ) [2] on which it will overwinter. In places where Thalictrum does not grow, such as Australia, the pathogen will only undergo its asexual life cycle and will overwinter as mycelium or uredinia. The germination process requires moisture and temperatures between 15–20 °C (59–68 °F). After around 10–14 days of infection, the fungi will begin to sporulate and the symptoms will become visible on the wheat leaves.[ citation needed ]
Location is an important characteristic in the spread of wheat rust. In some places wheat rust can easily flourish and spread. In other areas, the environment is marginally suited for the disease. Urediniospores of the wheat rusts initiate germination within one to three hours of contact with free moisture over a range of temperatures depending on the rust. Urediniospores are produced in large numbers and can be blown considerable distances by the wind, but most urediniospores are deposited close to their source under the influence of gravity. Urediniospores are relatively resilient and can survive in the field away from host plants for periods of several weeks. They can withstand freezing if their moisture content is lowered to 20 to 30 percent. Viability rapidly decreases at moisture contents of more than 50 percent. Long-distance spread of urediniospores is influenced by wind patterns and by the latitude. In general, spores move west to east due to the winds resulting from the rotation of Earth. At progressively higher latitudes, winds tend to become more southerly in the Northern Hemisphere and more northerly in the Southern Hemisphere. Puccinia triticina can survive the same environmental conditions as the wheat leaf, provided infection but no sporulation has occurred. The fungus can infect in less than three hours in the presence of moisture and temperatures below 20 °C (68 °F); however, more infections occur with longer exposure to moisture. [16] [17]
For the 2020 season, USDA ARS's Cereal Disease Laboratory found 36 races in North America: BBBQD, LBDSG, LCDJG, LCDSG, MBDSD, MBTNB, MCDSB, MCDSD, MCJSB, MCTNB, MLPSD, MNPSD, MPPSD, MPTSD, MSBJG, TBBGS, TBBJS, TBRKG, TBTDB, TBTNB, TCBGS, TCGJG, TCJTB, TCSQB, TCTBB, TCTNB, TCTQB, TDBGS, TFPSB, TFTSB, TGBGS, TNBGJ, TNBGS, TNBJJ, TNBJS, and TPBGJ. [18] [19]
Between 1992 and 2002, of the most common cultivars in Northern European production, almost all provided seedling resistance against most pathotypes. About 1/3 of these cultivars were confirmed to carry as-yet unidentified Lrs. A few cultivars were resistant to most pathotypes, and one to all of them. The most common Lrs were: Lr13, Lr14a, and Lr26, with Lr2a, Lr3, Lr10, Lr17, and Lr23 occurring rarely. A few particular cultivars were extremely popular, 'Ritmo' for example being >50% of hectares/acreage in 1998 and 99. Across the entire surveyed period (92-02) the most popular were: ‘Pepital’ (Lr10+Lr13), ‘Haven’ (Lr26), ‘Hussar’ (Lr26), ‘Ritmo’ (Lr13), ‘Lynx’ (Lr17+Lr26), ‘Kris’ (Lr10+Lr13), ‘Terra’ (Lr13), ‘Sleipner’ and ‘Hereward’. (For spring wheat specifically, ‘Dragon’ (Lr14a), ‘Leguan’ (Lr14a) and ‘Vinjett’ (Lr14a).) [20]
Small brown pustules develop on the leaf blades in a random scatter distribution. They may group into patches in serious cases. Onset of the disease is slow but accelerated in temperatures above 15 °C (59 °F), making it a disease of the mature cereal plant in summer, usually too late to cause significant damage in temperate areas. Losses of between 5 and 20% are normal but may reach 50% in severe cases. Symptoms can range in severity from barely aesthetic to completely overrun on the leaf surface. On barberry leaf the disease appears as powdery yellow spots with aecia being dispersed from the underside of the leaf.
Varietal resistance is important. Fungicides are commonly used. [H 2] Chemical control with triazole fungicides may be useful for control of infections up to ear emergence but is difficult to justify economically in attacks after this stage. Control often is not as common as prevention through the development of genetically-resilient varieties and the removal of common barberry. Cultivars are the best method of controlling the disease and have been utilized for over 100 years. However, resistance linked to single genes has been made ineffective by the pathogen adapting to new cultures. This is why destruction of alternate hosts is key to control. Early-maturing cultivars as well as spring wheat should be sown as early as possible to avoid peak rust periods. Self-sown wheat (volunteers) should be destroyed as not to further spread urediniospores at the end of harvest. [21] [22] [ tone ]
Because Lr34 , Lr46 , and Lr67 are non-specific, they should not be used in race analysis of this pathogen. [24]
Even the use of varieties with gene stacks has often failed against Pt/Prt due to individual deployment of the same genes in other varieties in the same area. [24] Slow rusting may be the answer. [24]
Rusts are fungal plant pathogens of the order Pucciniales causing plant fungal diseases.
Soybean rust is a disease that affects soybeans and other legumes. It is caused by two types of fungi, Phakopsora pachyrhizi, commonly known as Asian soybean rust, and Phakopsora meibomiae, commonly known as New World soybean rust. P. meibomiae is the weaker pathogen of the two and generally does not cause widespread problems. The disease has been reported across Asia, Australia, Africa, South America and the United States.
Magnaporthe grisea, also known as rice blast fungus, rice rotten neck, rice seedling blight, blast of rice, oval leaf spot of graminea, pitting disease, ryegrass blast, Johnson spot, neck blast, wheat blast and Imochi (稲熱), is a plant-pathogenic fungus and model organism that causes a serious disease affecting rice. It is now known that M. grisea consists of a cryptic species complex containing at least two biological species that have clear genetic differences and do not interbreed. Complex members isolated from Digitaria have been more narrowly defined as M. grisea. The remaining members of the complex isolated from rice and a variety of other hosts have been renamed Magnaporthe oryzae, within the same M. grisea complex. Confusion on which of these two names to use for the rice blast pathogen remains, as both are now used by different authors.
Stem rust, also known as cereal rust, black rust, red rust or red dust, is caused by the fungus Puccinia graminis, which causes significant disease in cereal crops. Crop species that are affected by the disease include bread wheat, durum wheat, barley and triticale. These diseases have affected cereal farming throughout history. The annual recurrence of stem rust of wheat in North Indian plains was discovered by K.C. Mehta. Since the 1950s, wheat strains bred to be resistant to stem rust have become available. Fungicides effective against stem rust are available as well.
This is a glossary of some of the terms used in phytopathology.
Puccinia hordei is a species of rust fungus. A plant pathogen, it can cause leaf rust of barley, also known as brown rust of barley. It was originally found on the dry leaves of Hordeum vulgare in Germany.
Ug99 is a lineage of wheat stem rust, which is present in wheat fields in several countries in Africa and the Middle East and is predicted to spread rapidly through these regions and possibly further afield, potentially causing a wheat production disaster that would affect food security worldwide. In 2005 the noted green revolution pioneer Norman Borlaug brought great attention to the problem, and most subsequent efforts can be traced to his advocacy. It can cause up to 100% crop losses and is virulent against many resistance genes which have previously protected wheat against stem rust.
Alternaria triticina is a fungal plant pathogen that causes leaf blight on wheat. A. triticina is responsible for the largest leaf blight issue in wheat and also causes disease in other major cereal grain crops. It was first identified in India in 1962 and still causes significant yield loss to wheat crops on the Indian subcontinent. The disease is caused by a fungal pathogen and causes necrotic leaf lesions and in severe cases shriveling of the leaves.
Pyrenophora tritici-repentis (teleomorph) and Drechslera tritici-repentis (anamorph) is a necrotrophic plant pathogen of fungal origin, phylum Ascomycota. The pathogen causes a disease originally named yellow spot but now commonly called tan spot, yellow leaf spot, yellow leaf blotch or helminthosporiosis. At least eight races of the pathogen are known to occur based on their virulence on a wheat differential set.
Zymoseptoria tritici, synonyms Septoria tritici, Mycosphaerella graminicola, is a species of filamentous fungus, an ascomycete in the family Mycosphaerellaceae. It is a wheat plant pathogen causing septoria leaf blotch that is difficult to control due to resistance to multiple fungicides. The pathogen today causes one of the most important diseases of wheat.
Puccinia asparagi is the causative agent of asparagus rust. It is an autoecious fungus, meaning that all stages of its life cycle – pycniospores, aeciospores, and teliospores – all develop upon the same host plant . Rust diseases are among the most destructive plant diseases, known to cause famine following destruction of grains, vegetables, and legumes. Asparagus rust occurs wherever the plant is grown and attacks asparagus plants during and after the cutting season. Asparagus spears are usually harvested before extensive rust symptoms appear. Symptoms are first noticeable on the growing shoots in early summer as light green, oval lesions, followed by tan blister spots and black, protruding blisters later in the season. The lesions are symptoms of Puccinia asparagi during early spring, mid-summer and later summer to fall, respectively. Severe rust infections stunt or kill young asparagus shoots, causing foliage to fall prematurely, and reduce the ability of the plant to store food reserves. The Puccinia asparagi fungus accomplishes this by rust lowering the amounts of root storage metabolites. The infected plant has reduced plant vigor and yield, often leading to death in severe cases. Most rust diseases have several stages, some of which may occur on different hosts; however, in asparagus rust all the life stages occur on asparagus. Because of this, many observers mistake the different stages of the Puccinia asparagi life cycle as the presence of different diseases. The effects of Puccinia asparagi are present worldwide wherever asparagus is being grown. Asparagus rust is a serious threat to the asparagus industry.
Puccinia coronata is a plant pathogen and causal agent of oat and barley crown rust. The pathogen occurs worldwide, infecting both wild and cultivated oats. Crown rust poses a threat to barley production, because the first infections in barley occur early in the season from local inoculum. Crown rusts have evolved many different physiological races within different species in response to host resistance. Each pathogenic race can attack a specific line of plants within the species typical host. For example, there are over 290 races of P. coronata. Crops with resistant phenotypes are often released, but within a few years virulent races have arisen and P. coronata can infect them.
Puccinia recondita is a fungus species and plant pathogen belonging to the order of Pucciniales and family Pucciniaceae.
Puccinia thaliae is the causal agent of canna rust, a fungal disease of Canna. Symptoms include yellow to tan spots on the plant's leaves and stems. Initial disease symptoms will result in scattered sori, eventually covering the entirety of the leaf with coalescing postulates. Both leaf surfaces, although more predominant on the underside (abaxial) of the leaf, will show yellow to brownish spore-producing these pustulate structures, and these are the signs of the disease. Spots on the upper leaf-surface coalesce and turn to brown-to-black as the disease progresses. Infection spots will become necrotic with time, with small holes developing in older leaves. These infected leaves eventually become dry and prematurely fall.
Puccinia is a genus of fungi. All species in this genus are obligate plant pathogens and are known as rusts. The genus contains about 4000 species.
Wheat yellow rust, also known as wheat stripe rust, is one of the three major wheat rust diseases, along with stem rust of wheat and leaf rust.
Ruth Florence Allen (1879–1963) was an American botanist and plant pathologist and the first woman to earn her Ph.D. in botany from the University of Wisconsin. Her doctorate research focused on the reproduction and cell biology of ferns, particularly the phenomenon of apogamy. Later in her career, Allen shifted her focus to plant pathology. Her major contribution to the field of mycology was furthering the understanding of rust fungi, a group of economically important plant pathogens. Allen completed many studies on Puccinia graminis, once considered a catastrophically damaging disease-causing agent in cereal crops before the discovery of current management measures.
Margaret Brown Newton was a Canadian plant pathologist and mycologist internationally renowned for her pioneering research in stem rust Puccinia graminis, particularly for its effect on the staple Canadian agricultural product wheat.
Phakopsora euvitis is a rust fungus that causes disease of grape leaves. This rust fungus has been seen in regions including: Eastern Asia, Southern Asia, Southwestern Brazil, the Americas, and northern Australia. It is widely distributed in eastern and southern Asia but was first discovered on grapevines in Darwin, Australia in 2001 and was identified as Asian grapevine leaf rust by July 2007.
Puccinia sorghi, or common rust of maize, is a species of rust fungus that infects corn and species from the plant genus Oxalis.