Alternaria triticina | |
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Scientific classification | |
Domain: | Eukaryota |
Kingdom: | Fungi |
Division: | Ascomycota |
Class: | Dothideomycetes |
Order: | Pleosporales |
Family: | Pleosporaceae |
Genus: | Alternaria |
Species: | A. triticina |
Binomial name | |
Alternaria triticina Prasada & Prabhu (1963) | |
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 [1] 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.
Successful inoculation of A. triticina has been repeatedly confirmed in Triticum turgidum subsp. Durum (durum wheat) and Triticum aestivum (common wheat, bread wheat) with bread wheat varieties showing more severe infection. [2] Barley, sorghum, triticale, oats, rye, and millet have all been experimentally colonized, but field-level infection is restricted to varieties of durum and bread wheat. [3] [2] Infection will only occur on hosts older than three weeks with symptoms appearing at 7–8 weeks of age. [2] [4] [5]
Lesions will start as oval-shaped scars on the lower leaves and infect more leaves as the plant grows. Later in the season, the lesions enlarge and coalesce, becoming darker and forming chlorotic margins around the necrotic lesions. [6] If the infection becomes sufficiently severe and widespread, the entire field will exhibit a burnt appearance. Depending on the initial concentration of inoculum and environmental conditions, infection can spread to the leaf sheath, stem, awns, and glumes. Spike infections lead to infected seed. These seeds may exhibit no symptoms, or they may become brown and shriveled. In either case, they will contain the disease-spreading agent successfully to the next season. [2] [5]
In addition to symptoms derived from nutrient extraction, A. triticina releases several nonspecific toxins, often resulting in chlorotic leaf flag streaks. [7]
Lesions are not easily differentiated from those of other leaf blight pathogens. However, they will have black powder of conidia and not pycnidia or perithecia common to some leaf lesion fungi, which distinguishes it from many ascomycete pathogens of wheat and cereal grains. [2]
The fungus overwinters largely as seed-born spores. [2] These asexual spores multiply in the soil and transfer primary inoculum to susceptible plant leaves through direct soil contact or by soil that is splashed onto the lowest leaves in rainfall or irrigation. At this point, the polycyclic nature of A. triticina is evident when conidia, the secondary inoculum are produced. Conidia germinate in temperatures between 20–25 °C (68–77 °F) and with 10 hours of water film on the leaves or 48 hours of humidity greater than 90%. [2] Conidia germinate, producing 2-4 germ tubes, each with an appressorium and penetration peg. Hyphae infect via direct penetration and proliferate inter- and intra-cellularly. Hyphae reach the deep mesophyll tissue within 72 hours of inoculation. Mycelium will spread to the epidermis and parenchyma tissue but not so deep as to infect the vasculature. Leaf tissue thickness becomes greatly reduced and chloroplasts of infected cells grow larger and irregularly shaped. Mycelium will produce conidiophores which extend out of host tissue stomata and bear conidia either singly or in chains. [2] These conidia serve as secondary inoculum for further infections within the season. Lesions appear between 2–5 days after inoculation. [4] [7] Infections in the seed head produce spores for the next season. Conidia in leaf and stem tissue can survive in debris, but its viability is greatly reduced when left on top of the soil surface or in hot, wet environments; their survival is limited to 2 months on the soil surface and 4 months when buried. [2]
The wide array of chemical, cultural, and biological inhibitions of leaf blight of wheat make both conventional and organic management reliable and economic. Infection of wheat and other cereal varieties can be prevented with the selection of resistant cultivar and planting of clean, disease-free seed. Seeds can also be treated with chemical agents or with hot water treatments. Biological methods, such as soil treatments of Bacillus spp. or fluorescent pseudomonads have proven effective. [5] The fungi Trichoderma viride , T. harzianum and Pseudomonas fluorescens all exhibit antagonistic growth against A. triticina hyphae in vitro and led to significantly higher yields in treated versus control plants infected with the leaf blight. [5]
Once infection is detected, foliar fungicides, such as mancozeb, ziram, copper oxychloride, and propineb, can prevent further infection from secondary inoculum. One common recommendation for control in India is 2 applications of copperoxychloride + Mancozeb 15 days apart. If overwintering of plant debris conidia is a concern, leaving residues on the soil surface is recommended, as burying of residue increases its likelihood of survival to the next season. Delaying tillage for several months can also help with plant debris inoculum. [2] [5]
Leaf blight of wheat via Alternaria triticina is “one of the most important foliar diseases of wheat in India”. [2] As the world's second largest producer of wheat, trailing only China, India produces 8.7% of the world wheat supply and dedicates 13% of cultivated land to wheat production. [8] With production levels so important to the agriculture sector of India, leaf blight of wheat is a major concern for growers and other stakeholders. Infection can lead to a 46-75% weight reduction of individual grains with yield losses reaching 60%. In the 1960s, India saw widespread, heavy wheat yield losses due to A. triticina with the introduction of a popular Mexican rust-resistant wheat variety. [2] [7] It is not uncommon to see yield losses of 20% attributed to Alternaria leaf blight of wheat.
The Australian Industry Biosecurity plan for the Grains Industry rated A. triticina a risk rating of HIGH for the years 2004 and 2009 and thus they have created a contingency plan for the containment of the disease. [5] The fungus is a quarantine pathogen and has prompted New Zealand, Brazil, and South Africa to impose regulations on the importation of wheat, requiring freedom statements from the area before reaccepting imports. [5] [6] A. triticina has been found in Argentina, southern Italy, parts of southwestern Asia, North Africa, Greece, the Middle East, and several other eastern European countries. [3] [2]
Glomerella graminicola is an economically important crop parasite affecting both wheat and maize where it causes the plant disease Anthracnose Leaf Blight.
Alternaria alternata is a fungus causing leaf spots, rots, and blights on many plant parts, and other diseases. It is an opportunistic pathogen on over 380 host species of plant.
Ascochyta is a genus of ascomycete fungi, containing several species that are pathogenic to plants, particularly cereal crops. The taxonomy of this genus is still incomplete. The genus was first described in 1830 by Marie-Anne Libert, who regarded the spores as minute asci and the cell contents as spherical spores. Numerous revisions to the members of the genus and its description were made for the next several years. Species that are plant pathogenic on cereals include, A. hordei, A. graminea, A. sorghi, A. tritici. Symptoms are usually elliptical spots that are initially chlorotic and later become a necrotic brown. Management includes fungicide applications and sanitation of diseased plant tissue debris.
Alternaria carthami is a necrotrophic plant pathogen of safflower. The fungus is in the order Pleosporales and family Pleosporaceae. It was first isolated in India, has spread globally and can have devastating effects on safflower yield, and resultant oilseed production. A. carthami is known to be seed-borne and appears as irregular brown lesions on safflower leaves and stems.
Alternaria dauci is a plant pathogen. The English name of the disease it incites is "carrot leaf blight".
Alternaria solani is a fungal pathogen that produces a disease in tomato and potato plants called early blight. The pathogen produces distinctive "bullseye" patterned leaf spots and can also cause stem lesions and fruit rot on tomato and tuber blight on potato. Despite the name "early," foliar symptoms usually occur on older leaves. If uncontrolled, early blight can cause significant yield reductions. Primary methods of controlling this disease include preventing long periods of wetness on leaf surfaces and applying fungicides. Early blight can also be caused by Alternaria tomatophila, which is more virulent on stems and leaves of tomato plants than Alternaria solani.
Peronospora manshurica is a plant pathogen. It is a widespread disease on the leaves of soybeans and other crop plants. The fungi is commonly referred to as downy mildew, "leafspot", or "leaf-spot".
Phomopsis obscurans is a common fungus found in strawberry plants, which causes the disease of leaf blight. Common symptoms caused by the pathogen begin as small circular reddish-purple spots and enlarge to form V-shaped lesions that follow the vasculature of the plant's leaves. Although the fungus infects leaves early in the growing season when the plants are beginning to develop, leaf blight symptoms are most apparent on older plants towards the end of the growing season. The disease can weaken strawberry plants through the destruction of foliage, which results in reduced yields. In years highly favorable for disease development, leaf blight can ultimately lead to the death of the strawberry plants. A favorable environment for the growth and development of the Phomopsis obscurans pathogen is that of high temperature, high inoculum density, a long period of exposure to moisture, and immature host tissue. In the case of disease management, a conjunction of cultural practices is the most effective way of reducing the infection.
Peronosclerospora sorghi is a plant pathogen. It is the causal agent of sorghum downy mildew. The pathogen is a fungal-like protist in the oomycota, or water mold, class. Peronosclerospora sorghi infects susceptible plants though sexual oospores, which survive in the soil, and asexual sporangia which are disseminated by wind. Symptoms of sorghum downy mildew include chlorosis, shredding of leaves, and death. Peronosclerospora sorghi infects maize and sorghum around the world, but causes the most severe yield reductions in Africa. The disease is controlled mainly through genetic resistance, chemical control, crop rotation, and strategic timing of planting.
Alternaria dianthi, sometimes known as carnation blight, is a fungal pathogen of the genus Dianthus. Alternaria dianthi infections begin as small circular or ovular spots on leaves and stems, which can be red, purple, brown, yellow or gray.
Alternaria helianthi is a fungal plant pathogen causing a disease in sunflowers known as Alternaria blight of sunflower.
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.
Ascochyta blights occur throughout the world and can be of significant economic importance. Three fungi contribute to the ascochyta blight disease complex of pea. Ascochyta pinodes causes Mycosphaerella blight. Ascochyta pinodella causes Ascochyta foot rot, and Ascochyta pisi causes Ascochyta blight and pod spot. Of the three fungi, Ascochyta pinodes is of the most importance. These diseases are conducive under wet and humid conditions and can cause a yield loss of up to fifty percent if left uncontrolled. The best method to control ascochyta blights of pea is to reduce the amount of primary inoculum through sanitation, crop-rotation, and altering the sowing date. Other methods—chemical control, biological control, and development of resistant varieties—may also be used to effectively control ascochyta diseases.
Southern corn leaf blight (SCLB) is a fungal disease of maize caused by the plant pathogen Bipolaris maydis.
Alternaria black spot of canola or grey leaf spot is an ascomycete fungal disease caused by a group of pathogens including: Alternaria brassicae, A. alternata and A. raphani. This pathogen is characterized by dark, sunken lesions of various size on all parts of the plant, including the leaves, stem, and pods. Its primary economic host is canola. In its early stages it only affects the plants slightly by reducing photosynthesis, however as the plant matures it can cause damage to the seeds and more, reducing oil yield as well.
Botrytis squamosa is a fungus that causes leaf blight on onion that is distinctly characterized by the two stages – leaf spotting followed by blighting. The pathogen is an ascomycete that belongs to the family Sclerotiniaceae in the order Helotiales. The lesions start out as whitish streaks and take on a yellow tinge as they mature. They cause yield losses up to 30%. This fungus is endemic to the USA and has also been reported in Europe, Asia, and Australia. Typical management of this disease includes chemical fungicides with significant efforts being made to establish a means of biological control.
Alternaria brassicicola is a fungal necrotrophic plant pathogen that causes black spot disease on a wide range of hosts, particularly in the genus of Brassica, including a number of economically important crops such as cabbage, Chinese cabbage, cauliflower, oilseeds, broccoli and canola. Although mainly known as a significant plant pathogen, it also contributes to various respiratory allergic conditions such as asthma and rhinoconjunctivitis. Despite the presence of mating genes, no sexual reproductive stage has been reported for this fungus. In terms of geography, it is most likely to be found in tropical and sub-tropical regions, but also in places with high rain and humidity such as Poland. It has also been found in Taiwan and Israel. Its main mode of propagation is vegetative. The resulting conidia reside in the soil, air and water. These spores are extremely resilient and can overwinter on crop debris and overwintering herbaceous plants.
Alternaria leaf spot or Alternaria leaf blight are a group of fungal diseases in plants, that have a variety of hosts. The diseases infects common garden plants, such as cabbage, and are caused by several closely related species of fungi. Some of these fungal species target specific plants, while others have been known to target plant families. One commercially relevant plant genus that can be affected by Alternaria Leaf Spot is Brassica, as the cosmetic issues caused by symptomatic lesions can lead to rejection of crops by distributors and buyers. When certain crops such as cauliflower and broccoli are infected, the heads deteriorate and there is a complete loss of marketability. Secondary soft-rotting organisms can infect stored cabbage that has been affected by Alternaria Leaf Spot by entering through symptomatic lesions. Alternaria Leaf Spot diseases that affect Brassica species are caused by the pathogens Alternaria brassicae and Alternaria brassicicola.
Rice-sheath blight is a disease caused by Rhizoctonia solani, a basidiomycete, that causes major limitations on rice production in India and other countries of Asia. It is also a problem in the southern US, where rice is also produced. It can decrease yield up to 50%, and reduce its quality. It causes lesions on the rice plant, and can also cause pre- and post-emergence seedling blight, banded leaf blight, panicle infection and spotted seed.