Pythium aphanidermatum

Last updated

Pythium aphanidermatum
Scientific classification OOjs UI icon edit-ltr.svg
Domain: Eukaryota
Clade: Diaphoretickes
Clade: SAR
Clade: Stramenopiles
Phylum: Oomycota
Order: Peronosporales
Family: Pythiaceae
Genus: Pythium
Species:
P. aphanidermatum
Binomial name
Pythium aphanidermatum
(Edson) Fitzp., (1923)
Synonyms

Nematosporangium aphanidermatum(Edson) Fitzp., Mycologia 15: 168 (1923)
Rheosporangium aphanidermatumEdson, (1915)

Contents

Pythium aphanidermatum is a soil borne [1] plant pathogen. Pythium is a genus in the class Oomycetes, which are also known as water molds. Oomycetes are not true fungi, as their cell walls are made of cellulose instead of chitin, they are diploid in their vegetative state, and they form coenocytic hyphae (lacking crosswalls). [2] Also, they reproduce asexually with motile biflagelette zoospores that require water to move towards and infect a host. Sexually, they reproduce with structures called antheridia, oogonia, and oospores.

Hosts

Pythium aphanidermatum has a wide host range, and can have an economic impact on the cultivation of soybeans, [3] beets, peppers, chrysanthemum, cucurbits, cotton and turf-grasses, [1] however, because P. aphanidermatum requires warmer temperatures, it is often seen in greenhouses [4] and has a large impact in poinsettia production. [5] It is a major cause of root rot in papaya production [6] in subtropical areas. While this is almost exclusively a plant pathogen, there is one documented case of P. aphanidermatum infecting a human being injured in the Afghanistan conflict. [7]

Symptoms

Pythium aphanidermatum is responsible for pre- and post-emergence damping off. Pre-emergence damping off is when the seed is infected prior to germination. This can result in poor or no germination, and is observable as a browning or rotting of the seed. [8] Post-emergence damping off takes place after germination and results in a thinning, water-soaked stem near the plant collar, which eventually causes the collapse of the plant. [5] P. aphanidermatum can also cause root rot. Symptoms of root rot include stunted growth, chlorotic leaves, leaf drop, and wilting. The infection begins at the root tip, and can cause the infected region to lose its protective outer layer, exposing the inner root to other pathogens. [1]

Disease cycle

Pythium aphanidermatum overwinters in the soil as oospores, hyphae and/or sporangia. [1] Oospores can produce a germ tube and infect the plant directly, or, if the environment is favorable (that is an adequate amount of water is present), the oospore may produce sporangia, which in turn produce motile, biflagallete zoospores that swim to the host plant, encyst, and germinate. [1] [9] This infection can occur on seeds, which can rot, or produce a weak seedling. If it infects the roots of a seedling, the mycelium will grow throughout the plant tissue, releasing digestive enzymes which break down plant cell walls allowing the pathogen to absorb the nutrients, [10] effectively killing the plant over time. P. aphanidermatum is a polycyclic disease [11] A polycyclic plant pathogen has several life cycles during a season, meaning it can reinfect the host plant, or travel to another plant. After infection, several things can happen that spreads the infection: 1)More asexual structures form, including sporangiophores and sporangia, which release more zoospores which can reinfect the host plant, or move to other plants. 2)There can also be sexual reproduction when two different mating hyphal types meet, creating an oogonium (female structure), and an antheridium (male structure). [12] This results in genetic recombination and exists as an oospore-the original overwintering stage of the pathogen.

Environment

Pythium aphanidermatum infects plants via motile zoospores, and because zoospores need to swim in order to infect the host, moist conditions facilitate the most rapid spread of the disease. [1] Temperature also has an effect on the rate of pathogen propagation. The pathogen can cause disease in cool temperatures (55–64 °F) but ideal conditions are between 86 °F and 95 °F, [2] a characteristic which distinguishes it from other Pythium species. [13] Potential host plants that are stressed are more susceptible to infection. [2] Factors that may cause stress in plants and therefore increase the likelihood of infection include high saline conditions, drought, nutrient deficiencies, and excessive moisture around the plant. [1] [2] High saline content in the soil can promote infection at lower temperature and humidity that is ideal for the pathogen. [2] Excessive nitrogen fertilization will also increase the chance of infection because the nitrogen decreases the function of the plant's innate defense response, and it also damages the ends of the roots, which are the primary mode of infection. [4] Furthermore, the medium in which plants are grown dictates affects the severity of Pythium infection. Sterile soil-less cultures are the most susceptible, while increasing soil content inhibits disease progression due to bacteria present in the soil. Finally, seedlings and plants that are germinating have greater susceptibility to the pathogen, and often experience damping off. [1]

Management

Several cultural management methods can be effective in avoiding disease caused by Pythium aphanidermatum. The pathogen thrives in a moist environment, so it is important to prevent an excessive amount of moisture from building up in the plant media [4] Irrigation that is too frequent and usage of soil that has poor drainage are common mistakes that result in inoculation. [1] In addition, poor ventilation and insufficient exposure to sunlight can cause the plants themselves to accumulate moisture, potentially spreading disease. [2] Sanitation of the soil using chemical treatment and minimizing the amount of plant debris in which the pathogen can survive is also an effective cultural practice. [13] Fungicides are also effective control methods. Systemic and contact fungicides can be used, but in order to prevent the pathogen from becoming resistant to the treatment it is best to alternate between systemic and contact substances. [2] Several chemical types can be used to manage the pathogen including acylalanines, thiadiazoles, carbamates, cinnamic acid derivatives, phosphonates, and phosphites. [5] In general, these fungicides yield best results when used for preventative purposes. [4] Biological control of the pathogen has also been successful. Bacteria and fungi can be used to treat Pythium aphanidermatum in turf, crops, and flowering greenhouse plants. [1] [2] Bacteria species include Bacillus subtilis , Candida oleophila , Enterobacter cloacae , and Pseudomonas species. Fungi include many Trichoderma species, namely T. harziamum , T. virens , and T. hamatum . [2] [5]

Importance

Damage caused by Pythium aphanidermatum is difficult to measure because it has such a wide host range and infection results in a variety of symptoms, all of which are detrimental in different ways. Damage is important and most prevalent in warm and humid regions where soils are particularly wet. Valley areas and river bottom fields are particularly susceptible to infection. [14] In general, the pathogen is especially important in crops such as maize, cotton, cereal crops, and high value horticultural crops. The pathogen is also economically important in crops that are produced both in greenhouses and by soil-less culture. Root infection and seedling damping off are responsible for a decrease in plant health and reduction in yield for economic crops. Tomato is one of the most popular vegetable crops throughout the world and it is also widely cultivated. In tomatoes, P. aphanidermatum causes significant losses in nurseries where young susceptible transplants are produced.[ citation needed ]

See also

Related Research Articles

<i>Pythium</i> Genus of single-celled organisms

Pythium is a genus of parasitic oomycetes. They were formerly classified as fungi. Most species are plant parasites, but Pythium insidiosum is an important pathogen of animals, causing pythiosis. The feet of the fungus gnat are frequently a vector for their transmission.

Phytophthora sojae is an oomycete and a soil-borne plant pathogen that causes stem and root rot of soybean. This is a prevalent disease in most soybean growing regions, and a major cause of crop loss. In wet conditions the pathogen produces zoospores that move in water and are attracted to soybean roots. Zoospores can attach to roots, germinate, and infect the plant tissues. Diseased roots develop lesions that may spread up the stem and eventually kill the entire plant. Phytophthora sojae also produces oospores that can remain dormant in the soil over the winter, or longer, and germinate when conditions are favourable. Oospores may also be spread by animals or machinery.

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

Phytophthora palmivora is an oomycete that causes bud-rot of palms, fruit-rot or kole-roga of coconut and areca nut. These are among the most serious diseases caused by fungi and moulds in South India. It occurs almost every year in Malnad, Mysore, North & South Kanara, Malabar and other areas. Similar diseases of palms are also known to occur in Sri Lanka, Mauritius, and Sumatra. The causative organism was first identified as P. palmivora by Edwin John Butler in 1917.

Aphanomyces euteiches is a water mould, or oomycete, plant pathogen responsible for the disease Aphanomyces root rot. The species Aphanomyces euteiches can infect a variety of legumes. Symptoms of the disease can differ among hosts but generally include reduced root volume and function, leading to stunting and chlorotic foliage. Aphanomyces root rot is an important agricultural disease in the United States, Europe, Australia, New Zealand, and Japan. Management includes using resistant crop varieties and having good soil drainage, as well as testing soil for the pathogen to avoid infected fields.

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

Phytophthora cactorum is a fungal-like plant pathogen belonging to the Oomycota phylum. It is the causal agent of root rot on rhododendron and many other species, as well as leather rot of strawberries.

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

Phytophthora medicaginis is an oomycete plant pathogen that causes root rot in alfalfa and chickpea. It is a major disease of these plants and is found wherever they are grown. P. medicaginis causes failure of stand establishment because of seedling death. Phytophthora medicaginis is part of a species complex with Phytophthora megasperma.

Phytophthora nicotianae or black shank is an oomycete belonging to the order Peronosporales and family Peronosporaceae.

Pythium irregulare is a soil borne oomycete plant pathogen. Oomycetes, also known as "water molds", are fungal-like protists. They are fungal-like because of their similar life cycles, but differ in that the resting stage is diploid, they have coenocytic hyphae, a larger genome, cellulose in their cell walls instead of chitin, and contain zoospores and oospores.

Pythium ultimum is a plant pathogen. It causes damping off and root rot diseases of hundreds of diverse plant hosts including corn, soybean, potato, wheat, fir, and many ornamental species. P. ultimum belongs to the peronosporalean lineage of oomycetes, along with other important plant pathogens such as Phytophthora spp. and many genera of downy mildews. P. ultimum is a frequent inhabitant of fields, freshwater ponds, and decomposing vegetation in most areas of the world. Contributing to the widespread distribution and persistence of P. ultimum is its ability to grow saprotrophically in soil and plant residue. This trait is also exhibited by most Pythium spp. but not by the related Phytophthora spp., which can only colonize living plant hosts.

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

Phytophthora erythroseptica—also known as pink rot along with several other species of Phytophthora—is a plant pathogen. It infects potatoes causing their tubers to turn pink and damages leaves. It also infects tulips (Tulipa) damaging their leaves and shoots.

Pythium graminicola is a plant pathogen infecting cereals.

Pythium myriotylum is a soil-borne oomycete necrotroph that has a broad host range, this means that it can infect a wide range of plants.

Pythium volutum is a plant pathogen infecting wheat, barley, and turfgrass. It is known to be sensitive to some of the compounds typically present in selective media commonly used for isolating Pythium spp., so isolation may require alternative methods.

Sclerophthora macrospora is a protist plant pathogen of the class Oomycota. It causes downy mildew on a vast number of cereal crops including oats, rice, maize, and wheat as well as varieties of turf grass. The common names of the diseases associated with Sclerophthora macrospora include "crazy top disease" on maize and yellow tuft disease on turf grass. The disease is present all over the world, but it is especially persistent in Europe.

<i>Albugo</i> Genus of plant-parasitic oomycetes

Albugo is a genus of plant-parasitic oomycetes. Those are not true fungi (Eumycota), although many discussions of this organism still treat it as a fungus. The taxonomy of this genus is incomplete, but several species are plant pathogens. Albugo is one of three genera currently described in the family Albuginaceae, the taxonomy of many species is still in flux.

Aphanomyces cochlioides is a plant pathogen that can affect commodity crops like spinach, Swiss chard, beets and related species. In spinach the pathogen is responsible for the black root "rot" that can damage plants.

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

Phytophthora capsici is an oomycete plant pathogen that causes blight and fruit rot of peppers and other important commercial crops. It was first described by L. Leonian at the New Mexico State University Agricultural Experiment Station in Las Cruces in 1922 on a crop of chili peppers. In 1967, a study by M. M. Satour and E. E. Butler found 45 species of cultivated plants and weeds susceptible to P. capsici In Greek, Phytophthora capsici means "plant destroyer of capsicums". P. capsici has a wide range of hosts including members of the families Solanaceae and Cucurbitaceae as well as Fabaceae.

Phytophthora fragariae is a fungus-like (oomycete) plant pathogen that causes red stele, otherwise known as Lanarkshire disease, in strawberries. Symptoms of red stele can include a red core in the roots, wilting of leaves, reduced flowering, stunting, and bitter fruit. The pathogen is spread via zoospores swimming through water present in the soil, released from sporangia.

Pythium dissotocum is a plant pathogen infecting strawberry and rice.

Black rot on orchids is caused by Pythium and Phytophthora species. Black rot targets a variety of orchids but Cattleya orchids are especially susceptible. Pythium ultimum and Phytophthora cactorum are known to cause black rot in orchids.

References

  1. 1 2 3 4 5 6 7 8 9 10 "Pythium aphanidermatum". Projects.ncsu.edu. Retrieved 27 April 2019.
  2. 1 2 3 4 5 6 7 8 9 "Oomycetes". Apsnet.org. Archived from the original on 21 November 2016. Retrieved 27 April 2019.
  3. Norman, A.G., ed. (1987). Soybean Physiology, Agronomy, and Utilization. Academic Press. p. 247. ISBN   9780124335622.
  4. 1 2 3 4 "Pythium root rot of Herbaceous Plants" (PDF). Purdue.edu. Retrieved 27 April 2019.
  5. 1 2 3 4 "Pest, Disease and Weed Identification". Extension.psu.edu. Retrieved 27 April 2019.
  6. N.B. Koffi, Clovis; Diallo, Hortense A.; Koudio, Justin Y.; Kelly, Paula; Buddie, Alan G.; Tymo, Lukasz M. (2 March 2010). "Occurrence of Pythium aphanidermatum root and collar rot of Papaya (Carica papaya L.) in Cote d'Ivore" (PDF). Fruit Vegetable and Cereal Science and Biotechnology. 4 (special issue 1): 62–67. Archived from the original (PDF) on 23 January 2013. Retrieved 5 December 2012.
  7. Calvano, TP; Blatz, PJ; Vento, TJ; Wickes, BL; Sutton, DA; Thompson, EH; White, CE; Renz, EM; Hospenthal, DR (2011). "Pythium aphanidermatum infection following combat trauma" (PDF). J Clin Microbiol. 49 (10): 3710–3. doi:10.1128/JCM.01209-11. PMC   3187319 . PMID   21813724. Archived from the original on September 24, 2017.
  8. "Pythium Damping-off, Root Rot and Stem Rot" (PDF). Ufl.edu. Retrieved 27 April 2019.
  9. https://web.archive.org/web/20061230052114/http://www.agf.gov.bc.ca/ornamentals/publications/pesticide/disease/damping_off.pdf. Archived from the original (PDF) on 2006-12-30. Retrieved 5 June 2022.{{cite web}}: Missing or empty |title= (help)
  10. "Management Strategies for Pythium Diseases of Greenhouse Vegetable Crops in British Columbia". 8 October 2008. Archived from the original on 2008-10-08. Retrieved 5 June 2022.
  11. Rachniyom, H.; Jaenaksorn, T. (2008). "Effect of soluble silicon and Trichoderma harzianum on the in vitro growth of Pythium aphanidermatum" (PDF). Journal of Agricultural Technology. 4 (2): 57–71.
  12. "Pythium root rots of Apiaceae and other vegetables" (PDF). Vgavic.org.au. Archived from the original (PDF) on 21 March 2015. Retrieved 27 April 2019.
  13. 1 2 "UC IPM: UC Management Guidelines for Pythium Root Rot on Floriculture and Ornamental Nurseries". Ipm.ucanr.edu. Retrieved 27 April 2019.
  14. Das, Biswanath. "Pythium Stalk Rot." Wheat Doctor. International Maize and Wheat Improvement Center, n.d. Web. 7 Nov. 2014.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.