Wheat streak mosaic virus

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Wheat streak mosaic virus
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(A) Wheat curl mite (WCM) on a wheat leaf; (B) leaf curls caused by WCM; and (C) WSMV symptoms on wheat leaf
Virus classification OOjs UI icon edit-ltr.svg
(unranked): Virus
Realm: Riboviria
Kingdom: Orthornavirae
Phylum: Pisuviricota
Class: Stelpaviricetes
Order: Patatavirales
Family: Potyviridae
Genus: Tritimovirus
Species:
Wheat streak mosaic virus

Wheat streak mosaic virus (WSMV) is a plant pathogenic virus of the family Potyviridae that infects plants in the family Poaceae, especially wheat ( Triticum spp.); it is globally distributed and vectored by the wheat curl mite, particularly in regions where wheat is widely grown. First described in Nebraska in 1922, [1] stunted growth and the eponymous “streaks” of yellowed, non-uniform discoloration are characteristic of WSMV infection. As it has been known to cause 100% crop mortality, WSMV is a subject of ongoing scientific research.

Contents

Genome

WSMV is a flexible, rod-shaped virus composed of a positive-sense single-strand RNA genome approximately 8.5 to 12 kilobases in length, and can be either mono- or bipartite. The RNA serves as both the genome and viral messenger. The genomic RNA (or its segments) is translated into polyprotein(s) which are transformed by virus-encoded proteases into functional products. [2]

The virions of WSMV encapsidate a single molecule of positive-sense genomic RNA. The genomic RNA has a single open reading frame encoding a large polyprotein that undergoes post-translational cleavage into at least 10 mature proteins. Researchers at USDS-ARS identified that one of these proteins, P1, as a suppressor of RNA silencing. WSMV P1 was shown to bind to dsRNA to suppress host-defensive antiviral defense. [3]

Transmission

Electron micrograph of wheat curl mites on a wheat leaf Fpls-09-01098-g001.jpg
Electron micrograph of wheat curl mites on a wheat leaf

WSMV is semi-persistently [4] transmitted by the wheat curl mite (Aceria tosichella), a small, cigar-shaped arthropod that can produce a single generation within 10 days under optimum temperature- approximately 27 °C. [5] Wheat curl mites are slow crawlers, and depend on wind to disperse to other plants; they can also overwinter in abandoned infected wheat [5] or corn heads. [4] The mites also have the ability to transfer WSMV in between wheat and corn crops, allowing the virus to persist year-round. [4] One of the most important management techniques to controlling WSMV is by eliminating “volunteer”, or seedlings from the previous years’ infected crop, wheat plants. WSMV often overwinters on the seeds, and can spread to a field planted after the infected seedlings have sprouted. [6] Recently, researchers at USDA-ARS showed that WSMV infection alters gene expression of its vector, wheat curl mite, to enhance mite development and population expansion, to increase viral transmission. [7]

Agricultural importance

Depending on the location, WSMV infection has been reported to reduce yield by up to 100%; furthermore, WSMV has been shown to display synergistic interactions with other viruses (specifically Triticum mosaic virus and High plains virus), [8] further exacerbating crop yield problems. [9] WSMV infects some of the most agriculturally important members of the family Poaceae, including wheat, corn, rye, oats, barley, sorghum, and millet; additionally, some grassy weeds have been known to serve as alternate hosts. [6]

Diagnosis

Winter wheat 'Arapahoe' showing advanced symptoms with streaks coalescing into almost solid yellow areas because of WSMV infection Jipm1-00j1-fig2.png
Winter wheatArapahoe’ showing advanced symptoms with streaks coalescing into almost solid yellow areas because of WSMV infection

“Serious infection of winter wheat occurs in early fall, but symptoms usually do not develop until spring. As spring temperatures rise, symptoms become more visible and rapidly develop when daily high temperatures first exceed about 80°F for several days.” [6]

“Rolled and trapped leaves are good indicators of heavy mite populations, and their presence is useful in determining if stands of volunteer wheat are potential reservoirs of both the virus and the mite.” [6]

“A cool spring will delay the onset of severe symptoms and moderate damage, but an early, warm spring will maximize impact on the plants.” [6]

A second virus that is often found in wheat and associated with wheat streak mosaic is the high plains virus (HPV). The high plains virus usually occurs along with wheat streak mosaic virus on both wheat and corn and is known to be transmitted only by the wheat curl mite. Both viruses can be positively identified by a serological test such as ELISA (Enzyme-Linked Immunosorbent Assay). [6] More recently, plants infected with WSMV are also often found to be simultaneously infected with Triticum mosaic virus, which synergistically interacts with WSMV to exacerbate yield loss. [10]

Epidemiology

WSMV survives year-round in grasses and cereals; its severity depends on weather conditions that favour the winter and summer-growing hosts and the spread from one to the other by the mite vectors. [11] WSMV is the predominant wheat-infecting virus in the American Great Plains region; [9] it is also found in Australia, where it was determined that WSMV most likely has a global spread in most wheat-growing locations due to being seed-borne. [12] The genome of WSMV has been completely sequenced, and current research is investigating plant resistance to WSMV using RNAi technology. [10]

Management

Healthy wheat (L) and stunted WSMV-infected wheat (R) Jipm1-00j1-fig3.png
Healthy wheat (L) and stunted WSMV-infected wheat (R)

Practices that have been shown to be effective at controlling WSMV include the following:

Related Research Articles

<span class="mw-page-title-main">Plant virus</span> Virus that affects plants

Plant viruses are viruses that affect plants. Like all other viruses, plant viruses are obligate intracellular parasites that do not have the molecular machinery to replicate without a host. Plant viruses can be pathogenic to vascular plants.

<i>Brome mosaic virus</i> Species of virus

Brome mosaic virus (BMV) is a small, positive-stranded, icosahedral RNA plant virus belonging to the genus Bromovirus, family Bromoviridae, in the Alphavirus-like superfamily.

<i>Potyvirus</i> Genus of positive-strand RNA viruses in the family Potyviridae

Potyvirus is a genus of positive-strand RNA viruses in the family Potyviridae. Plants serve as natural hosts. Like begomoviruses, members of this genus may cause significant losses in agricultural, pastoral, horticultural, and ornamental crops. More than 200 species of aphids spread potyviruses, and most are from the subfamily Aphidinae. The genus contains 190 species and potyviruses account for about thirty percent of all currently known plant viruses.

<i>Abacarus hystrix</i> Species of mite

Abacarus hystrix, the cereal rust mite or grain rust mite, belongs to the family Eriophyidae. They are extremely small with adults measuring up to 1 millimetre in length and only have four legs at the front of the body. Viewing by the human eye requires a 10 – 20X lens. The adult mites are usually yellow but also have been seen to be white or orange. The cereal rust mite was first found on Elymus repens, a very common perennial grass species. It has now been found on more than 60 grass species including oats, barley, wheat and ryegrass, found in Europe, North America, South Africa and Australia. Mites migrate primarily through wind movement and are usually found on the highest basal sections of the top two leaf blades. Abacarus hystrix produces up to twenty overlapping generations per year in South Australian perennial pastures, indicating that the species breeds quite rapidly. It has been noted that the cereal rust mite can cause losses in yield of up to 30-70%.

<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.

Panicum mosaic virus (PMV) is a positive-sense single-stranded RNA viral pathogen that infects plant species in the panicoid tribe of the grass family, Poaceae. The pathogen was first identified in Kansas in 1953 and most commonly causes disease on select cultivars of turf grass, switchgrass, and millet. The disease most commonly associated with the panicum mosaic virus pathogen is St. Augustine Decline Syndrome, which infects species of turf grass and causes chlorotic mottling. In addition to St. Augustine Decline, panicum mosaic virus is responsible for chlorotic streaking and mild green mosaicking in select cultivars of switchgrass and millet.

Soil-borne wheat mosaic virus is a rod-shaped plant pathogen that can cause severe stunting and mosaic in susceptible wheat, barley and rye cultivars. The disease has often been misdiagnosed as a nutritional problem, but this has actually allowed in part for the fortuitous visual selection by breeding programs of resistant genotypes. Soil-borne wheat mosaic virus is part of the genus Furovirus. Members of this genus are characterized by rigid rod-shaped particles and positive sense RNA genomes consisting of two molecules that are packaged into separate particles that code for either replication, mobility, structure or defense against the host. The virus is spread by a fungal-like protist, Polymyxa graminis, whose asexual secondary and sexual primary cycles help the virus spread. The disease produces secondary symptoms from the root cell infection. The disease is a serious contributor to loss in crop yield.

<i>Soybean mosaic virus</i> Plant disease

Soybean mosaic virus (SMV) is a member of the plant virus genus Potyvirus. It infects mainly plants belonging to the family Fabaceae but has also been found infecting other economically important crops. SMV is the cause of soybean mosaic disease that occurs in all the soybean productions areas of the world. Soybean is one of the most important sources of edible oil and proteins and pathogenic infections are responsible for annual yield losses of about $4 billion in the United States. Among these pathogens, SMV is the most important and prevalent viral pathogen in soybean production worldwide. It causes yield reductions of about 8% to 35% but losses as high as 94% have been reported.

Sweet potato feathery mottle virus (SPFMV) is a member of the genus Potyvirus in the family Potyviridae. It is most widely recognized as one of the most regularly occurring causal agents of sweet potato viral disease (SPVD) and is currently observed in every continent except Antarctica. The number of locations where it is found is still increasing; generally, it is assumed that the virus is present wherever its host is. The virus has four strains that are found in varying parts of the world.

Rice stripe tenuivirus is an RNA plant pathogen of the genus Tenuivirus. It is prevalent in Japan, China, and Korea and can infect plants of the family Poaceae, which include wheat and corn. Damage from this disease causes major reductions in rice crop yield every year.

Cassava brown streak virus disease (CBSD) is a damaging disease of cassava plants, and is especially troublesome in East Africa. It was first identified in 1936 in Tanzania, and has spread to other coastal areas of East Africa, from Kenya to Mozambique. Recently, it was found that two distinct viruses are responsible for the disease: cassava brown streak virus (CBSV) and Ugandan cassava brown streak virus (UCBSV). Both have (+)ss RNA genomes, belong to the genus Ipomovirus in the family Potyviridae, and produce generally similar symptoms in infected plants. Root rot renders the cassava tuber inedible, resulting in severe loss of economic value; therefore, current research focuses on achieving cultivars that do not develop the necrotic rot. This disease is considered to be the biggest threat to food security in coastal East Africa and around the eastern lakes.

High plains disease is a viral disease afflicting wheat and maize. It is caused by the negative-sense ssRNA virus High Plains wheat mosaic emaravirus. Symptoms are similar to Wheat streak mosaic virus, with leaf veins showing yellow flecks and streaks, followed by leaf margin purpling in maize. Depending on the timing of infection, stunting and death occur. Plants can be doubly infected with high plains virus and wheat streak mosaic virus.

High Plains wheat mosaic emaravirus (WMoV), or High Plains virus (HPV) or Maize red stripe virus (MRSV/MRStV) is the causative agent of High plains disease of maize and wheat. It is spread by wheat curl mite, Aceria tosichella, which also transmits Wheat streak mosaic virus. The mite's ability to transmit a number of different viruses to cereal crops make it an economically important agricultural pest. In late June 2017 this virus was first detected in Canada, in Alberta. The Alberta samples were 99% similar to those in the USA. As Wheat streak mosaic virus is already present in Alberta, and coinfection with these two causes even more severe damage, this could cause much higher yield losses.

<i>Aceria tosichella</i> Species of mite

Aceria tosichella, commonly known as the wheat curl mite (WCM), is a global cereal pest and a vector for spreading and transmission of viruses like wheat streak mosaic virus (WSMV) and wheat mosaic virus (WMoV)

Citrus leprosis(CL) is an economically important viral disease affecting citrus crops. This emerging disease is widely distributed in South and Central America, from Argentina to Mexico. The disease is associated with up to three different non-systemic viruses, which cause similar symptoms in the citrus hosts and are transmitted by the same vector, mites of the genus Brevipalpus; although they have vastly different genomes. Citrus leprosis virus nuclear type (CiLV-N) is found in the nuclei and cytoplasm of infected cells, while Citrus leprosis virus cytoplasmic type (CiLV-C) is found in the endoplasmic reticulum. In 2012, a new virus causing similar symptoms was found in Colombia and it was named Citrus leprosis virus cytoplasmic type 2 (CiLV-C2) due to its close similarity to CiLV-C. The cytoplasmic type viruses are the most prevalent and widely distributed of the three species.

Maize lethal necrosis disease is a viral disease affecting maize (corn) predominantly in East Africa, Southeast Asia and South America, which was recognised in 2010. It is caused by simultaneous infection with two viruses, MCMoV and any of several Potyviridae.

Poacevirus is a genus of viruses, in the family Potyviridae. Poaceae plants serve as natural hosts. There are three species in this genus.

Cassava brown streak virus is a species of positive-strand RNA viruses in the genus Ipomovirus and family Potyviridae which infects plants. Member viruses are unique in their induction of pinwheel, or scroll-shaped inclusion bodies in the cytoplasm of infected cells. Cylindrical inclusion bodies include aggregations of virus-encoded helicase proteins. These inclusion bodies are thought to be sites of viral replication and assembly, making then an important factor in the viral lifecycle. Viruses from both the species Cassava brown streak virus and Ugandan cassava brown streak virus (UCBSV), lead to the development of Cassava Brown Streak Disease (CBSD) within cassava plants.

Eriophyes tulipae, commonly known as the dry bulb mite, is a species of mite in the genus Eriophyes. This mite feeds on members of the lily family, and has damaged garlic crops. At one time, it was also thought to feed on wheat and other grasses, but the wheat curl mite is now regarded as a different species, Aceria tosichella.

The cardamom mosaic virus (CdMV) is a mosaic virus that affects the production of green cardamom (E. cardamomum). It is a member of the genus Macluravirus (recognized under the family Potyviridae by ICTV in 1988), and is transmitted through aphids (P.caladii) and infected rhizomes, the former in a non-persistent manner.

References

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  2. "Potyviridae".
  3. Adarsh K. Gupta (2019). "Wheat streak mosaic virus P1 Binds to dsRNAs without Size and Sequence Specificity and a GW Motif Is Crucial for Suppression of RNA Silencing". Viruses. 11 (5): 472. doi: 10.3390/v11050472 . PMC   6563293 . PMID   31137615.
  4. 1 2 3 Townsend, L.; Johnson, D. & Hershman, D. "Wheat streak mosaic virus and the wheat curl mite".
  5. 1 2 3 4 5 6 "Wheat Pests".
  6. 1 2 3 4 5 6 Wegulo, S.N.; Hein, G.L.; Klein, R.N. & French, R.C. "Managing wheat streak mosaic" (PDF).
  7. Adarsh K. Gupta (2019). "Wheat streak mosaic virus alters the transcriptome of its vector, wheat curl mite (Aceria tosichella Keifer), to enhance mite development and population expansion". Journal of General Virology. 100 (5): 889–910. doi: 10.1099/jgv.0.001256 . PMID   31017568. S2CID   129942987.
  8. "Plant Pathology". Archived from the original on 2014-12-21. Retrieved 2015-11-29.
  9. 1 2 Byamukama, E.; Wegulo, S. N.; Tatineni, S.; Hein, G. L.; Graybosch, R. A.; Baenziger, P. S.; French, R. (2014). "Quantification of Yield Loss Caused by Triticum mosaic virusand Wheat streak mosaic virusin Winter Wheat Under Field Conditions". Plant Disease. 98 (1): 127–133. doi: 10.1094/PDIS-04-13-0419-RE . PMID   30708611.
  10. 1 2 "Wheat Streak Mosaic Virus" (PDF).
  11. Murray, G.M.; Knihinicki, D.; Wratten, K. & Edwards, J. "Wheat streak mosaic and the wheat curl mite" (PDF).
  12. Dwyer, Geoffrey I.; Gibbs, Mark J.; Gibbs, Adrian J.; Jones, Roger A. C. (2007). "Wheat streak mosaic virusin Australia: Relationship to Isolates from the Pacific Northwest of the USA and Its Dispersion Via Seed Transmission". Plant Disease. 91 (2): 164–170. doi:10.1094/PDIS-91-2-0164. PMID   30780999.