Phytophthora capsici

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Phytophthora capsici
Phytophthora Blight on Pumpkin.jpg
Symptom of blight on a pumpkin plant
Scientific classification OOjs UI icon edit-ltr.svg
Kingdom: Chromista
Phylum: Oomycota
Order: Peronosporales
Family: Peronosporaceae
Genus: Phytophthora
Species:
P. capsici
Binomial name
Phytophthora capsici
Leonian, (1922)
Synonyms
  • Phytophthora parasitica var. capsici(Leonian) Sarej., s(1936)

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 [1] In Greek, Phytophthora capsici means "plant destroyer of capsicums". [2] P. capsici has a wide range of hosts including members of the families Solanaceae and Cucurbitaceae as well as Fabaceae.

Contents

Hosts

Under field conditions, P. capsici has been found to affect a wide range of hosts in the families Cucurbitaceae, Fabaceae, and Solanaceae, including: cantaloupe, cucumber, watermelon, bell pepper, tomato, snap beans, and lima beans. [3]

Although beans, lima beans, and soybeans were previously thought to be immune to P. capsici, in 2000 and 2001, "Phytophthora capsici was isolated from five commercial cultivars of lima bean in Delaware, Maryland, and New Jersey. It was also recently isolated from commercial snap beans in northern Michigan." [4]

Symptoms

General Symptoms

General symptoms on the solanaceous crops and cucurbits include seed rot and seedling blight which discolors the roots and causes seedlings to topple over. Preemergence and postemergence damping-off are also possible symptoms that may occur.

Bean

Include water-soaked foliage, stem and pod necrosis. [5]

Pepper

Infection of the pepper commonly starts at the soil line leading to symptoms of dark, water soaked areas on the stem. Dark lesions of the stem may girdle the plant resulting in death. Roots of the pepper plant appear brown and mushy. Leaf spots start out small and become water soaked, and as time progresses may enlarge turn tan and crack. Blighting of new leaves may also take place. The fruit of the pepper is infected through the stem giving way to water soaked areas on the fruit that are overgrown by signs of the pathogen which appear as, "white-gray, cottony, fungal-like growth" (hyphae). The fruit mummifies and stays attached to the stem. [5]

P. capsici blight on lower stem of a bell pepper plant. P. capsici blight on sweet pepper.jpg
P. capsici blight on lower stem of a bell pepper plant.

Eggplant

Solanum melongena : Fruit rot is the primary symptom of the eggplant. A dark brown area of the fruit expands into a light tan region. Signs of fungal-like growth may be seen on the lesions. [5]

Tomato

Solanum lycopersicum : P. capsici can cause crown infections, leaf spot, and foliar blight in tomato. The plant may eventually topple over from the crown rot. Fruit rot with patterns of concentric rings is another possible symptom. [5]

Squash

Foliar blight with rapidly expanding water soaked regions and fruit rot are common symptoms on susceptible species of summer and winter squash varieties. These lead to dieback of shoot tips, wilting, shoot rot, and plant death. White fungal growth is also a sign of the pathogen in squash. [5]

Watermelon

Foliar symptoms are less common in watermelon than squash, but the leaves are still susceptible. Fruit rot is more common eventually leading to a total decay of the fruit. [5]

Pumpkin

P. capsici causes pre- and post-emergence damping off of seedlings. It also causes vine blight contributing to developing water soaked lesions on the vine which start off as dark olive-colored and soon turn dark brown. This leads to rapid collapse and death of foliage above the lesions. Similar lesions may appear on the leaves and petioles of the pumpkin. Fruit rot is also a very common symptom. [6]

Cantelope

Similar symptoms to that of the watermelon. [5]

Cucumber

Symptoms of the cucumber are similar to that of other cucurbits, but do not include crown gall as a symptom.

Disease cycle

P. capsici is a heterothallic oomycete. The sexual types are designated as A1 and A2. Phytophthora capsici produces both a male and a female type gametangia called an antheridium (male) and an oogonium (female). The antheridium is amphigynous in the species, meaning that the antheridium may remain in this male form of the gametangia or develop into the female gametangia which is an oogonium. Karyogamy between these two types of gametangia one being from the A1 sexual type and the other of the A2 sexual type results in the formation of an overwintering oospore. [7] The oospores may directly germinate into a germ tube or indirectly germinate and give rise to sporangia which then indirectly germinates and gives rise to zoospores. Zoospores are biflagellate motile spores with one long tinsel flagella directed forward and one shorter whiplash flagella directed backward. These biflagellate zoospores are responsible for the polycyclic qualities of this disease.

Chlamydospores, found in other Phytophthora species, have not been documented on P. capsici in nature or formed on isolates that were collected from a range of hosts and locations. [8]

The life-cycle of a typical Phytophthora fungi. Phytophthora life cycle.png
The life-cycle of a typical Phytophthora fungi.
Detached sporangia of P. capsici Phytophthora capsici sporangia.jpg
Detached sporangia of P. capsici

Environment

Disease initially occurs in low areas of fields where water accumulates, often leading growers to believe that stunting and death of the cultivar is due to water logging. [4] P. capsici grows best at 80 °F (27 °C). It rapidly spreads in warm wet conditions. The asexual spore bearing structures called sporangia are spread by irrigation water, drainage water, and rain. These indirectly germinate and release zoospores. [9]

Management

Crop rotation may reduce the number of pathogens in the soil and, "a minimum of a 3 years crop rotation which alternates with non-host species is recommended to avoid build-up of P. capsici spores." Crops should also avoid conditions that would be conducive to the pathogen by using well drained soils and raised beds. [3] As stated above, "Excess moisture is the single most important component to the initial infection and subsequent spreading of Phytophthora capsici." [4] Overall, a study by K.H. Lamour and M.K. Hausbeck found that "crop rotation and mefenoxam are not likely to provide economic control". [10] Mefenoxem is the active enantiomer contained in the racemic fungicide metalaxyl used to defend against Phytophthora capsici. Sexual recombination provides the genetic diversity to promote resistance towards fungicides in P. capsici. The failure of crop rotation as a means to control P. capsici may also be due to weeds playing the role of an alternative host in the absence of common hosts. According to a study done by the University of Florida, "In Florida, and perhaps elsewhere, weeds may contribute to pathogen survival in the absence of a host crop or when propagules may not readily survive in soil or plant debris." [11] To avoid fruit rot of vegetable crops in the Cucurbitaceae, trellising cucurbit fruits and other ways to keep the fruit off the ground is a way to control secondary inoculants (zoospores) from physically being splashed from the soil onto the fruit. [4] Control of Phytophthora capsici is easier in drier climates with less rainfall such as California. In these areas, it is important to practice placing drip irrigation emitters away from the stems of pepper plants in order to reduce the incidence of crown rot in peppers. [12]

Although resistance has been developed in the cultivars Adra (Abbott and Cobb Seed Co.) and Emerald Isle (Harris Moran Seed Co.), they do not possess sufficient horticultural characteristics accepted by bell pepper growers in the U.S.. Paladin (Novartis Seed Co.) has excellent resistance to the crown rot phase of Phytophthora rot and is acceptable to most growers. Paladin does not possess resistance to the foliar phase of this disease and one must use copper fungicides along with the resistant strain for control. [13]

Importance

Phytophthora capsici was first described by Leon H. Leonian at the New Mexico Agricultural Research Station in Las Cruces in 1922. After this, issues were documented in the Arkansas River Valley of Colorado in the 1930s and 1940s. Major research was initiated by M.K. Hausbeck and K.H. Lamour when crop losses due to P. capsici threatened to bankrupt numerous vegetable producers in Michigan (which could potentially threaten 134 million dollars worth of vegetable crops). [4] P. capsici is also important on a global scale. It is potentially the most destructive disease of peppers in Spain. [14]

Related Research Articles

<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.

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

Phytophthora is a genus of plant-damaging oomycetes, whose member species are capable of causing enormous economic losses on crops worldwide, as well as environmental damage in natural ecosystems. The cell wall of Phytophthora is made up of cellulose. The genus was first described by Heinrich Anton de Bary in 1875. Approximately 210 species have been described, although 100–500 undiscovered Phytophthora species are estimated to exist.

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.

Glomerella graminicola is an economically important crop parasite affecting both wheat and maize where it causes the plant disease Anthracnose Leaf Blight.

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

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

<i>Alternaria solani</i> Species of fungus

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.

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This article summarizes different crops, what common fungal problems they have, and how fungicide should be used in order to mitigate damage and crop loss. This page also covers how specific fungal infections affect crops present in the United States.

<i>Xanthomonas campestris</i> pv. <i>vesicatoria</i> Species of bacterium

Xanthomonas campestris pv. vesicatoria is a bacterium that causes bacterial leaf spot (BLS) on peppers and tomatoes. It is a gram-negative and rod-shaped. It causes symptoms throughout the above-ground portion of the plant including leaf spots, fruit spots and stem cankers. Since this bacterium cannot live in soil for more than a few weeks and survives as inoculum on plant debris, removal of dead plant material and chemical applications to living plants are considered effective control mechanisms.

Gummy stem blight is a cucurbit-rot disease caused by the fungal plant pathogen Didymella bryoniae. Gummy stem blight can affect a host at any stage of growth in its development and affects all parts of the host including leaves, stems and fruits. Symptoms generally consist of circular dark tan lesions that blight the leaf, water soaked leaves, stem cankers, and gummy brown ooze that exudes from cankers, giving it the name gummy stem blight. Gummy stem blight reduces yields of edible cucurbits by devastating the vines and leaves and rotting the fruits. There are various methods to control gummy stem blight, including use of treated seed, crop rotation, using preventative fungicides, eradication of diseased material, and deep plowing previous debris.

Collar rot is a symptomatically described disease that is usually caused by any one of various fungal and oomycete plant pathogens. It is present where the pathogen causes a lesion localized at or about the collet between the stem and the root. The lesions develop around the stem eventually forming a "collar". Observationally, collar rot grades into "basal stem rot", and with some pathogens is the first phase of "basal stem rot" often followed by "root rot". Collar rot is most often observed in seedings grown in infected soil. The pathogens that cause collar rot may be species or genera specific. But generalist pathogens such as Agroathelia rolfsii are known to attack over 200 different species. While bacteria caused collar rot is not common, trees infected with Fire blight may develop collar rot. Non-parasitic collar rot may be caused by winter damage.

Buckeye rot of tomato is caused by three species of pathogens in the genus Phytophthora: P. nicotianae var. parasitica, P. capsici, and P. drechsleri. It is an oomycete that thrives in warm, wet conditions and lives in the soil. It is characterized by a bull’s eye pattern of dark brown rotting on the tomato fruit, and affects fruit that is close to, or lying on the soil. The easiest management is to keep the plant out of contact with the soil, although other chemical methods can be very effective. This disease commonly occurs in the southeast and south central areas of the United States. The disease has affected a large portion of crop yield in the United States as well as India. The relatively small genome size of Phytophthora parasitica compared to Phytophthora infestans gives researchers the unique ability to further examine its ability to cause disease.

Phytophthora hydropathica is an oomycete plant pathogen that is found in aquatic environments such as irrigation and river water. The pathogen was previously classified as P. drechsleri Dre II before being categorized as its own distinct species. P. hydropathica has been primarily found in association with ornamental plant nurseries. The pathogen has been isolated throughout the Southern United States, as well as internationally in Mexico, Italy, and Spain.

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.

<i>Agroathelia rolfsii</i> Pathogen fungus

Agroathelia rolfsii is a corticioid fungus in the order Amylocorticiales. It is a facultative plant pathogen and is the causal agent of "southern blight" disease in crops.

References

  1. Satour, M. M., Butler, E. E. 1967. A root and crown rot of tomato caused by Phytophthora capsici and P. parasitica. Phytopathology 57: 510-515.
  2. Boslan, Paul W. "Think Global, Breed Local: Specificity and complexity of Phytophthora capsici" Chili pepper institute, New Mexico State University Available from: http://njveg.rutgers.edu/NJpepperconference-10.23.08/assets.pepper/pdfs/01_Bosland.pdf Archived 2012-04-26 at the Wayback Machine
  3. 1 2 Lamour, K.H. and Hausbeck, M.K. vegetable.msue.msu.edu/resources/phytophthora.htm Phytophthora Root, Crown, and Fruit Rot of Vine Crops
  4. 1 2 3 4 5 Lamour, K.H. and Hausbeck, M.K., "Phytophthora capsici on Vegetable Crops: Research Progress and Management challenges", Plant Disease/Dec. 2004 Vol 88 No.12 (The American Phytopathological Society) Available from: http://www.apsnet.org/publications/plantdisease/2004/December/Pages/88_12_1292.aspx
  5. 1 2 3 4 5 6 7 Gevens, Amanda J., Roberts, Pamela D., McGovern, R.J.. Kucharek, T.A., Revised July 2008 "Vegetable Diseases Caused by Phytophthora Capsici in Florida" Florida Cooperative Extension Service, Institute of Food and Agricultural Sciences, University of Florida. Available from: http://plantpath.ifas.ufl.edu/takextpub/FactSheets/sp159.pdf
  6. Babadoost, Mohammad and Islam, Sayed Z., 2002 "Phytophthora Blight on Pumpkin" Plant Management Network Available from: http://www.plantmanagementnetwork.org/pub/php/diagnosticguide/pumpkin/
  7. Ristaino, Jean B. and Johnston, Stephan A., 1999 "Ecologically Based Approaches to Management of Phytophthora Blight on Pepper, The American Phytopathological Society Available from: http://apsjournals.apsnet.org/doi/pdf/10.1094/PDIS.1999.83.12.1080
  8. Bowers, J.H., Mitchell, D. J. 1990. http://www.apsnet.org/publications/phytopathology/backissues/Documents/1991Articles/Phyto81n02_178.PDF Relationship Between Inoculum Level and Phytophthora capsici and Mortality of Pepper.
  9. Lamour, K.H and Hausbeck, M.K, Phytophthora Root, Crown, and Fruit Rot of Vine Crops vegetable.msue.msu.edu/Resources/phytophthora.htm
  10. Reference link 1
  11. French-Monar, Ronald D., "Characterization of Phytophthora capsici Associated with Roots of Weeds on Florida Vegetable Farms", March, 2006, doi : 10.1094/PD-90-0345 Available from: http://www.mendeley.com/research/characterization-phytophthora-capsici-associated-roots-weeds-florida-vegetable-farms/
  12. Cafe- Filho, A.C, Duniway, H.M. 1996 Effect of location of drip irrigation emitter and position of Phytophthora capsici Infections in Roots on Phytophthora Root Rot of Pepper. Phytopathology 86:1364-1369 Available from: http://www.mendeley.com/research/effect-location-drip-irrigation-emitters-position-phytophthora-capsici-infections-roots-phytophthora-root-rot-pepper-1/
  13. Ristaino, Jean B. and Johnston, Stephan A., 1999 "Ecologically Based Approaches to Management of Phytophthora Blight on Peppers", The American Phytopathological Society Available from: http://www.cals.ncsu.edu/plantpath/people/faculty/ristaino/projects/Curfundedresearch/pcapecol.pdf
  14. Silver, C., Merino, F. and Diaz, J., "Diversity of Phytophthora capsici in Northwest Spain: Analysis of Virulence, Metalaxyl Response, and Molecular Characterization" Sept. 2006, Volume 90, #9 Available from: http://apsjournals.apsnet.org/doi/abs/10.1094/PD-90-1135

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