Setosphaeria turcica

Last updated

Setosphaeria turcica
Conidia of Exserohilum turcicum.jpg
Scientific classification
Kingdom:
Phylum:
Class:
Subclass:
Order:
Family:
Genus:
Species:
S. turcica
Binomial name
Setosphaeria turcica
(Luttr.) K.J. Leonard & Suggs, (1974)
Synonyms

Bipolaris turcica(Pass.) Shoemaker, (1959)
Drechslera turcica(Pass.) Subram. & B.L. Jain, (1966)
Exserohilum turcicum(Pass.) K.J. Leonard & Suggs, (1974)
Helminthosporium inconspicuumCooke & Ellis, (1878)
Helminthosporium turcicumPass., (1876)
Keissleriella turcica(Luttr.) Arx, Gen. (1970)
Luttrellia turcica(Pass.) Khokhr. [as 'Lutrellia'], (1978)
Trichometasphaeria turcicaLuttr., (1958)

Contents

Setosphaeria turcica (anamorph Exserohilum turcicum; formerly known as Helminthosporium turcicum) is the causal agent of northern corn leaf blight in maize. It is a serious fungal disease prevalent in cooler climates and tropical highlands wherever corn is grown. It is characterized by large cigar shaped necrotic lesions that develop on the leaves due to the polyketide metabolite monocerin.

Races

Races of S. turcica are named for the maize R genes which are not effective against them. [1] For example, the maize gene Ht1 does not confer resistance against a Race 1 isolate, while genes Ht2 and/or Ht3 do. In contrast, genes Ht2 and HtN do not confer resistance against a Race 2N isolate, while gene Ht1 does. Isolates which do not overcome any known R gene are termed Race 0.

Race 1, which overcomes the Ht1 resistance gene, was originally discovered in Hawaii in 1973. [2] By the time it was first noted in the continental United States, in Indiana in 1980, it was already quite prevalent across the entire state. [3] Genotyping of isolates sampled from the eastern United States later revealed that while Race 0 was predominant in the mid-1970s, Race 1 spread rapidly, becoming the most prevalent race in the region by the mid-1990s. [4]

Mating type

S. turcica is a heterothallic fungus, meaning that a single isolate cannot mate with itself. Instead, two isolates with complementary mating type genes are required for sexual reproduction. The "perfect stage" (sexual stage or teleomorph) was first described in 1958. [5] A single mating-type locus was identified the next year [6]

The mating-type locus of S. turcica follows the same naming convention as other filamentous ascomycetes: the locus is known as MAT1, while the two idiomorphs (genes at this locus which are not alleles, as they do not derive from a common ancestor) are known as MAT1-1 and MAT1-2 [7]

Genotyping of S. turcica populations has shown that sexual reproduction in a given population might be commonplace, extremely rare, or anywhere in between. Genotyping of 264 isolates of S. turcica from temperate and tropical regions found that tropical populations had very high genetic diversity, an equal proportion of the two mating types, and low amounts of linkage disequilibrium between different genetic loci, all suggestive of frequent sexual mating and recombination. In temperate populations, in contrast, there was low genetic diversity, high amounts of linkage disequilibrium, and a single dominant mating type, which suggests infrequent sexual mating. [8]

Related Research Articles

<span class="mw-page-title-main">Ascomycota</span> Division or phylum of fungi

Ascomycota is a phylum of the kingdom Fungi that, together with the Basidiomycota, forms the subkingdom Dikarya. Its members are commonly known as the sac fungi or ascomycetes. It is the largest phylum of Fungi, with over 64,000 species. The defining feature of this fungal group is the "ascus", a microscopic sexual structure in which nonmotile spores, called ascospores, are formed. However, some species of Ascomycota are asexual and thus do not form asci or ascospores. Familiar examples of sac fungi include morels, truffles, brewers' and bakers' yeast, dead man's fingers, and cup fungi. The fungal symbionts in the majority of lichens such as Cladonia belong to the Ascomycota.

<i>Phytophthora infestans</i> Species of single-celled organism

Phytophthora infestans is an oomycete or water mold, a fungus-like microorganism that causes the serious potato and tomato disease known as late blight or potato blight. Early blight, caused by Alternaria solani, is also often called "potato blight". Late blight was a major culprit in the 1840s European, the 1845–1852 Irish, and the 1846 Highland potato famines. The organism can also infect some other members of the Solanaceae. The pathogen is favored by moist, cool environments: sporulation is optimal at 12–18 °C (54–64 °F) in water-saturated or nearly saturated environments, and zoospore production is favored at temperatures below 15 °C (59 °F). Lesion growth rates are typically optimal at a slightly warmer temperature range of 20 to 24 °C.

<span class="mw-page-title-main">Waxy corn</span> Type of field corn

Waxy corn or glutinous corn is a type of field corn characterized by its sticky texture when cooked as a result of larger amounts of amylopectin. The corn was first described from a specimen from China in 1909. As this plant showed many peculiar traits, the American breeders long used it as a genetic marker to tag the existence of hidden genes in other maize breeding programs. In 1922 a researcher found that the endosperm of waxy maize contained only amylopectin and no amylose starch molecule in opposition to normal dent corn varieties that contain both. Until World War II, the main source of starch in the United States was tapioca, but when Japan severed the supply lines of the U.S., they forced processors to turn to waxy maize. Amylopectin or waxy starch is now used mainly in food products, but also in the textile, adhesive, corrugating and paper industry.

<span class="mw-page-title-main">Mating in fungi</span> Combination of genetic material between compatible mating types

Fungi are a diverse group of organisms that employ a huge variety of reproductive strategies, ranging from fully asexual to almost exclusively sexual species. Most species can reproduce both sexually and asexually, alternating between haploid and diploid forms. This contrasts with most multicellular eukaryotes such as mammals, where the adults are usually diploid and produce haploid gametes which combine to form the next generation. In fungi, both haploid and diploid forms can reproduce – haploid individuals can undergo asexual reproduction while diploid forms can produce gametes that combine to give rise to the next generation.

<span class="mw-page-title-main">Stem rust</span> Fungus disease of cereal crops

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.

In genetics, a selective sweep is the process through which a new beneficial mutation that increases its frequency and becomes fixed in the population leads to the reduction or elimination of genetic variation among nucleotide sequences that are near the mutation. In selective sweep, positive selection causes the new mutation to reach fixation so quickly that linked alleles can "hitchhike" and also become fixed.

Mating types are the microorganism equivalent to sexes in multicellular lifeforms and are thought to be the ancestor to distinct sexes. They also occur in macro-organisms such as fungi.

Spot blotch is a leaf disease of wheat caused by Cochliobolus sativus. Cochliobolus sativus also infects other plant parts and in conjunction with other pathogens causes common root rot and black point.

Huntiella moniliformis is a saprobic fungal species that was previously accommodated in the Ceratocystis genus. Due to morphological, molecular and ecological differences, it was recently allocated to the newly described Huntiella genus. Species belonging to this genus typically do not cause disease on plants with the exception of H. bhutanensis. These species are almost always found on freshly cut timber or wounded trees.

<i>Cochliobolus carbonum</i> Species of fungus

Cochliobolus carbonum is one of more than 40 species of filamentous ascomycetes belonging to the genus Cochliobolus. This pathogen has a worldwide distribution, with reports from Australia, Brazil, Cambodia, Canada, China, Congo, Denmark, Egypt, India, Kenya, New Zealand, Nigeria, Solomon Islands, and the United States. Cochliobolus carbonum is one of the most aggressive members of this genus infecting sorghum, corn and apple. As one of the most devastating pathogens of sweet corn, C. carbonum causes Northern leaf spot and ear rot disease while the asexual stage causes Helminthosporium corn leaf spot. Cochliobolus carbonum is pathogenic to all organs of the corn plant including root, stalk, ear, kernel, and sheath. However, symptoms of infection show distinct manifestations in different plant parts: whole plant - seedling blight affects the whole plant, leaf discoloration and mycelial growth, black fungal spores and lesions appear on inflorescences and glumes, and grain covered with very dark brown to black mycelium which gives a characteristic charcoal appearance due to the production of conidia.

<i>Maize dwarf mosaic virus</i> Species of plant pathogenic virus

Maize dwarf mosaic virus (MDMV) is a pathogenic plant virus of the family Potyviridae. Depending on the corn plant’s growth stage, the virus can have severe implications to the corn plant’s development which can also result in economic consequences to the producer of the crop.

Homothallic refers to the possession, within a single organism, of the resources to reproduce sexually; i.e., having male and female reproductive structures on the same thallus. The opposite sexual functions are performed by different cells of a single mycelium.

<span class="mw-page-title-main">Plant disease resistance</span> Ability of a plant to stand up to trouble

Plant disease resistance protects plants from pathogens in two ways: by pre-formed structures and chemicals, and by infection-induced responses of the immune system. Relative to a susceptible plant, disease resistance is the reduction of pathogen growth on or in the plant, while the term disease tolerance describes plants that exhibit little disease damage despite substantial pathogen levels. Disease outcome is determined by the three-way interaction of the pathogen, the plant and the environmental conditions.

<i>Fusarium oxysporum</i> f.sp. <i>cubense</i> Fungus, causes banana wilt/Panama disease

Fusarium oxysporum f. sp. cubense is a fungal plant pathogen that causes Panama disease of banana, also known as fusarium wilt of banana. The fungi and the related disease are responsible for widespread pressure on banana growing regions, destroying the economic viability of several commercially important banana varieties.

<span class="mw-page-title-main">Monocerin</span> Chemical compound

Monocerin is a dihydroisocoumarin and a polyketide metabolite that originates from various fungal species. It has been shown to display antifungal, plant pathogenic, and insecticidal characteristics. Monocerin has been isolated from Dreschlera monoceras, D. ravenelii, Exserohilum turcicum, and Fusarium larvarum.

<span class="mw-page-title-main">Corn grey leaf spot</span> Fungal disease of maize

Grey leaf spot (GLS) is a foliar fungal disease that affects maize, also known as corn. GLS is considered one of the most significant yield-limiting diseases of corn worldwide. There are two fungal pathogens that cause GLS: Cercospora zeae-maydis and Cercospora zeina. Symptoms seen on corn include leaf lesions, discoloration (chlorosis), and foliar blight. Distinct symptoms of GLS are rectangular, brown to gray necrotic lesions that run parallel to the leaf, spanning the spaces between the secondary leaf veins. The fungus survives in the debris of topsoil and infects healthy crops via asexual spores called conidia. Environmental conditions that best suit infection and growth include moist, humid, and warm climates. Poor airflow, low sunlight, overcrowding, improper soil nutrient and irrigation management, and poor soil drainage can all contribute to the propagation of the disease. Management techniques include crop resistance, crop rotation, residue management, use of fungicides, and weed control. The purpose of disease management is to prevent the amount of secondary disease cycles as well as to protect leaf area from damage prior to grain formation. Corn grey leaf spot is an important disease of corn production in the United States, economically significant throughout the Midwest and Mid-Atlantic regions. However, it is also prevalent in Africa, Central America, China, Europe, India, Mexico, the Philippines, northern South America, and Southeast Asia. The teleomorph of Cercospora zeae-maydis is assumed to be Mycosphaerella sp.

<span class="mw-page-title-main">Southern corn leaf blight</span> Fungal disease of maize

Southern corn leaf blight (SCLB) is a fungal disease of maize caused by the plant pathogen Bipolaris maydis.

Commonly known as Philippine downy mildew, this disease is caused by the species Peronosclerospora philippinensis of the fungal-like protist class Oomycetes, which also has members such as water molds and Phytophthora infestans, which caused the potato blight that led to the Great Irish famine.

<i>Exserohilum</i> Genus of fungi

Exserohilum is a genus of fungi in the family Pleosporaceae. The Exserohilum species are known for causing blight and human immune system diseases. The sexual reproductive states of Exserohilum species are known as Setosphaeria. The type species is Exserohilum turcicum. This genus is among three dematiaceous that are categorized for containing pathogens leading to diseases like phaeohyphomycosis.

<span class="mw-page-title-main">Northern corn leaf blight</span> Fungal disease of maize plants

Northern corn leaf blight (NCLB) or Turcicum leaf blight (TLB) is a foliar disease of corn (maize) caused by Exserohilum turcicum, the anamorph of the ascomycete Setosphaeria turcica. With its characteristic cigar-shaped lesions, this disease can cause significant yield loss in susceptible corn hybrids.

References

  1. Leonard KJ, Levy Y, Smith DR. 1989. Proposed Nomenclature for pathogen races of Exserohilum turcicum on corn. Plant Disease 73: 776-777
  2. Bergquist RR, Masias OR. 1973. Physiologic specialization in Trichometsphaeria turcica f. sp. zeae and T. turcica f. sp. sorghi in Hawaii. Phytopathology 64: 645-649
  3. Turner MT, Johnson ER. 1980. Race of Helminthosporium turcicum not controlled by Ht genetic resistance in corn in the American Corn Belt. Plant Disease 64:216-217.
  4. Ferguson LM, Carson ML. 2007. Temporal variation in Setosphaeria turcica between 1974 and 1994 and origin of races 1, 23, and 23N in the United States
  5. Luttrell, ES. 1958. The perfect stage of Helminthosporium turcicum. Phytopathology 49:159-160
  6. Nelson, RR. 1959. A major gene locus for compatibility in Trichometasphaeria turcica. Phytopathology 49:159-160.
  7. Turgeon BG, Yoder OC. 2000. Proposed nomenclature for mating type genes of filamentous Ascomycetes. Fungal Genetics and Biology 31:1-5
  8. Leonard KJ, Levy Y, Smith DR. 1989. Proposed Nomenclature for pathogen races of Exserohilum turcicum on corn. Plant Disease 73: 776-777