Curly top

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Curly top of common bean caused by Beet curly top virus Beet curly top virus geminiviridae common bean.jpg
Curly top of common bean caused by Beet curly top virus

Curly top [1] is a viral disease that affects many crops. This disease causes plants to become smaller in size, have shriveled petals and leaves, and are twisted and pulled out of shape. They are often caused by curtoviruses (genus Curtovirus ), members of the virus family Geminiviridae . This disease is important in western United States, such as California, Utah, Washington, and Idaho.

Contents

Curly top is characterized by stunting of the plant and deformation of leaves and fruit. The petioles and blades of the leaves curl, twist, and become discolored. [2]

Discovery of Curly Top

Knowledge of curly top's early history in the United States is limited owing to its sharing similar symptoms with other diseases and disorders. [9] According to C. O. Townsend, George G. Hedgecock with the USDA reported that, on several occasions before 1888, he observed damaging outbreaks of a disease presumed to be curly top from garden beets in Nebraska. In 1897, George Austin stated that the Utah Sugar Company suffered overwhelming losses near Lehi, UT from an unidentified disorder resembling curly top.

The disease also was noticed in California in the 1890s, with severe losses reported from the newly emerging sugar beet industry in that state. By 1900, it had been noted throughout all western states where sugar beets were grown, suggesting it was already widely distributed before it was first recognized or studied as a distinct disease.

This hypothesis is conceivable because the first description of the beet leafhopper on sugar beets was made from the western slope of Colorado in 1895 by C. P. Gillette and C. F. Baker. As early as 1905, E. D. Ball suspected the beet leafhopper in the spread and development of sugar beet curly top disease in Utah. However, he did not attribute the appearance of the disease to any viral or pathogenic entity, figuring that the damage was directly caused by the feeding injury induced by the insect.

It was not until 1915 that the relationship between the vector and the virus in causing disease was irrefutably established by P. A. Boucquet and W. J. Hartung. They showed that after leafhoppers taken from the wild with no previous contact with sugar beets were allowed to feed on beets, no disease ensued. But when they were allowed to feed on beets with symptoms of curly top for 3–7 days, curly top symptoms appeared on previously healthy beets after leafhoppers were transferred and granted time to feed.

The discovery of curly top transmission by leafhoppers strongly suggested a viral etiology; however, the pathogen's identity was not formally established until the 1970s. The typically low concentration of virus particles within infected plants made isolation and purification difficult. Therefore, it was not until 1974 that a virus was formally proven to be the cause of the disease, after advancements in virus purification were made and the characteristic twinned particles of geminiviruses were observed with electron microscopy.

Strains

There are many strains of curly top virus. They are CA/Logan = California/Logan, CO = Colorado, Kim1 = Kimberly1, [10] LH71 = Leafhopper 71, Mld = Mild, PeCT = Pepper curly top, PeYD = Pepper yellow dwarf, Svr = Severe (formerly CFH), SvrPep = Severe pepper, SpCT = Spinach curly top, and Wor = Worland.

Structure and replication

The genome of curtoviruses consists of a single circular ssDNA component of 2.9–3.0 kb, encoding six to seven proteins. [11] The three ORFs encoded on the virion-sense strand are the coat protein (CP, ORF V1), which encapsidates the virion-sense ssDNA and is involved in virus movement and insect vector transmission, a movement protein (MP, ORF V2), and V3, which is involved in the regulation of the relative levels of ssDNA and dsDNA. The complementary-sense strand encodes the replication-associated protein (Rep, ORF C1), which is required for the initiation of viral DNA replication, the C2 protein (ORF C2), which acts as a pathogenicity factor in some hosts, a replication enhancer protein (REn, ORF C3), and the C4 protein (ORF C4), which is an important symptom determinant implicated in cell-cycle control (Hanley-Bowdoin et al., 2013). Nucleotide sequence comparisons suggest that curtoviruses and begomoviruses diverged after a recombination event altered insect vector specificity (Rybicki 1994).

Vector Behavior and Disease Epidemiology

Before the development of commercialized agriculture in the western United States, the native flora did not support large, economically damaging populations of the beet leafhopper. Conditions favoring the insect modified this dynamic with the changes in agriculture, including sporadic, intermittent farming and overgrazing of rangeland. This series of factors resulted in the disappearance of previously stable plant populations that were replaced by various winter and summer annual weed species. The weed hosts that succeeded the original plant species included mustards (Brassica spp.), Russian thistle (Salsola tragus), filaree (Erodium spp.), and Plantago spp. These widespread weeds became the preferred leafhopper hosts resulting in more frequent and severe epidemics.

In the fall as crops senesce, the leafhopper vector moves to breeding areas in the foothills away from cultivated fields, overwintering on various biennials and perennials. Winter rainfall results in the germination and emergence of several annuals that serve as sites of leafhopper reproduction. The leafhopper moves to these annual plant species and lays eggs. In spring as plants in breeding areas dry, the leafhopper moves back to agricultural lands. The severity of infection depends on climatic factors affecting the presence of weed hosts, the prevalence and severity of the pathogen, and the reproductive capacity and migration of leafhoppers.

Host Range

Curly top virus, have a very wide host range within dicot plants, including over 300 species in 44 plant families (Strausbaugh et al., 2008). [12] The most common infected hosts include sugar beets (for which the disease was first named), follow by tomatoes, [13] peppers, beans, potatoes, spinach, cucurbits, cabbage, alfalfa, and many ornamentals. [14] The virus seems to be restricted to trees with broad leaves, because no single-leafed plants were identified as the host of this virus.

Transmission

The usual agent is Beet Curly Top Virus (BCTV).  BCTV is transmitted to from plant to plant by the beet leafhopper (Circulifer tenellus). Both the virus and the beet leafhopper have very wide host ranges. Once acquired by the leafhopper, BCTV is carried for the rest of the leafhopper's life, so long-distance spread is common. Infected plants will spread all over the field. The beet leafhopper acquires the virus from infected crop plants or weeds such as wild mustards and Russian thistle. Beet leafhopper only need few minutes in feeding period to transfer the virus into new plants. Plants begin to show symptoms about 7 to 14 days after they are first infected by a leafhopper. Tomato is not a preferred host for the beet leafhopper; however, the leafhoppers transmit the virus to tomato while sampling it.

Affected plants do not recover and die or remain stunted without giving fruit.

Symptoms

Disease signs in young buds are curly, discolored leaves, yellow speckled, severe disease will cause buds to be sagged, trees are shortened, the ability to produce very few fruits, abnormal fruits and malt taste.

Due to the pathogen's confinement within phloem tissues, necrosis, degeneration, and death of the periderm and phloem cells adjacent to sieve tubes ensue. Phloem necrosis also is easily observed as dark concentric rings or linear streaks in cross section or longitudinal section of the taproot, respectively.

Economic Effects of Curly Top

Although crop failures are rare today, curly top is still a potentially problematic issue for sugar beet production in several areas of the western United States. The disease has been for the most part confined to the western half of the North American continent and is generally more severe west of the continental divide. It does occur sporadically in the beet-growing areas of the high plains east of the Rocky Mountains, but is not often an economically limiting factor.

After 1900 curly top rapidly emerged as a threat to American sugar beet production in the west. It crippled and seriously threatened the survival of the new sugar beet industry in the first three decades of the 20th century. This one disease was responsible for the closure of numerous processing plants across this growing region, in a similar manner to the impact of the cyst nematode on the European continent in the latter half of the 19th century. Its damage also directly contributed to wild fluctuations in sugar prices due to varying supply and demand relationships, causing the cultivation of beets to constantly move to new locations, leaving others abandoned. As an example, the worst year for California's Spreckles Sugar Company occurred in 1926. Following this year, the entire company very nearly closed and declared bankruptcy as a direct result of curly top, after only 7500 acres were harvested and processed.

Management

By farming methods

By physical methods

Using foil hanging from the treetops to create reflective light to repel the insect sting.

Control

There are no chemicals available for controlling the virus, but several cultural practices can help reduce or eliminate infections such as:


Related Research Articles

<span class="mw-page-title-main">Plant pathology</span> Scientific study of plant diseases

Plant pathology is the scientific study of diseases in plants caused by pathogens and environmental conditions. Organisms that cause infectious disease include fungi, oomycetes, bacteria, viruses, viroids, virus-like organisms, phytoplasmas, protozoa, nematodes and parasitic plants. Not included are ectoparasites like insects, mites, vertebrate, or other pests that affect plant health by eating plant tissues and causing injury that may admit plant pathogens. Plant pathology also involves the study of pathogen identification, disease etiology, disease cycles, economic impact, plant disease epidemiology, plant disease resistance, how plant diseases affect humans and animals, pathosystem genetics, and management of plant diseases.

<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.

<span class="mw-page-title-main">Leaf spot</span> Type of area of a leaf

A leaf spot is a limited, discoloured, diseased area of a leaf that is caused by fungal, bacterial or viral plant diseases, or by injuries from nematodes, insects, environmental factors, toxicity or herbicides. These discoloured spots or lesions often have a centre of necrosis. Symptoms can overlap across causal agents, however differing signs and symptoms of certain pathogens can lead to the diagnosis of the type of leaf spot disease. Prolonged wet and humid conditions promote leaf spot disease and most pathogens are spread by wind, splashing rain or irrigation that carry the disease to other leaves.

<span class="mw-page-title-main">Leafhopper</span> Family of insects

A leafhopper is the common name for any species from the family Cicadellidae. These minute insects, colloquially known as hoppers, are plant feeders that suck plant sap from grass, shrubs, or trees. Their hind legs are modified for jumping, and are covered with hairs that facilitate the spreading of a secretion over their bodies that acts as a water repellent and carrier of pheromones. They undergo a partial metamorphosis, and have various host associations, varying from very generalized to very specific. Some species have a cosmopolitan distribution, or occur throughout the temperate and tropical regions. Some are pests or vectors of plant viruses and phytoplasmas. The family is distributed all over the world, and constitutes the second-largest hemipteran family, with at least 20,000 described species.

<i>Begomovirus</i> Genus of viruses

Begomovirus is a genus of viruses, in the family Geminiviridae. They are plant viruses that as a group have a very wide host range, infecting dicotyledonous plants. Worldwide they are responsible for a considerable amount of economic damage to many important crops such as tomatoes, beans, squash, cassava and cotton. There are 445 species in this genus.

Citrus tristeza virus (CTV) is a viral species of the genus Closterovirus that causes the most economically damaging disease to its namesake plant genus, Citrus. The disease has led to the death of millions of Citrus trees all over the world and has rendered millions of others useless for production. Farmers in Brazil and other South American countries gave it the name "tristeza", meaning sadness in Portuguese and Spanish, referring to the devastation produced by the disease in the 1930s. The virus is transmitted most efficiently by the brown citrus aphid.

<span class="mw-page-title-main">Aster yellows</span> Plant disease

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<span class="mw-page-title-main">Beet leafhopper</span> Species of insect

The beet leafhopper, also sometimes known as Neoaliturus tenellus, is a species of leafhopper which belongs to the family Cicadellidae in the order Hemiptera.

<i>Beet curly top virus</i> Species of virus

Beet curly top virus (BCTV) is a pathogenic plant virus of the family Geminiviridae, containing a single-stranded DNA. The family Geminiviridae consists of nine genera based on their host range, virus genome structure, and type of insect vector. BCTV is a Curtovirus affecting hundreds of plants. The only known vector is the beet leafhopper, which is native to the Western United States.

<i>Beet necrotic yellow vein virus</i> Species of virus

Beet necrotic yellow vein virus (BNYVV) is a plant virus, transmitted by the plasmodiophorid Polymyxa betae. The BNYVV is a member of the genus Benyvirus and is responsible for rhizomania, a disease of sugar beet that causes proliferation of thin rootlets, and leads to a smaller tap root with reduced sugar content. Infected plants are less able to take up water, and wilting can be observed during the warm period of the year. If the infection spreads to the whole plant, vein yellowing, necrosis and yellow spots appear on the leaves, giving the virus its name.

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

Cucumber mosaic virus (CMV) is a plant pathogenic virus in the family Bromoviridae. This virus has a worldwide distribution and a very wide host range, having the reputation of the widest host range of any known plant virus. It can be transmitted from plant to plant both mechanically by sap and by aphids in a stylet-borne fashion. It can also be transmitted in seeds and by the parasitic weeds, Cuscuta sp. (dodder).

<i>Impatiens necrotic spot orthotospovirus</i> Species of virus

Impatiens necrotic spot orthotospovirus(INSV) is a plant pathogenic virus of the order Bunyavirales. It was originally believed to be another strain of Tomato spotted wilt virus, but genetic investigations revealed them to be separate viruses. It is a negative-strand RNA virus which has a tripartite genome. It is largely spread by the insect vector of the western flower thrips. The virus infects more than 648 species of plants including important horticultural and agricultural species such as fuchsia, tomato, orchids, and lettuce (especially romaine). As the name implies, the main symptom on plants is necrotic spots that appear on the leaves. The INSV virus infects by injecting the RNA the virus contains into the cell which then starts using the cell resources to transcribe what the virus RNA states. Viral infection can often result in the death of the plant. The disease is mainly controlled by the elimination of the western flower thrip vector and by destroying any infected plant material.

Potato mop-top virus (PMTV) is a plant pathogenic virus transmitted through the vector Spongospora subterranea that affects potatoes. PMTV belongs to family of Virgaviridae, and the genus Pomovirus. The virus was first identified in 1966 by Calvert and Harrison in Britain, and is now reported in many other potato cultivating regions of the world including U.S.A., Canada, China, Pakistan, Japan, South American countries and many parts of Europe. Many disease management systems have been found to be ineffective against the virus, although a combination of sanitation and vector controls seems to work well.

Tomato yellow leaf curl virus (TYLCV) is a DNA virus from the genus Begomovirus and the family Geminiviridae. TYLCV causes the most destructive disease of tomato, and it can be found in tropical and subtropical regions causing severe economic losses. This virus is transmitted by an insect vector from the family Aleyrodidae and order Hemiptera, the whitefly Bemisia tabaci, commonly known as the silverleaf whitefly or the sweet potato whitefly. The primary host for TYLCV is the tomato plant, and other plant hosts where TYLCV infection has been found include eggplants, potatoes, tobacco, beans, and peppers. Due to the rapid spread of TYLCV in the last few decades, there is an increased focus in research trying to understand and control this damaging pathogen. Some interesting findings include the virus being sexually transmitted from infected males to non-infected females, and an evidence that TYLCV is transovarially transmitted to offspring for two generations.

<i>Orthotospovirus</i> Genus of viruses

Orthotospovirus is a genus of negative-strand RNA viruses, in the family Tospoviridae of the order Bunyavirales, which infects plants. Tospoviruses take their name from the species Tomato spotted wilt orthotospovirus (TSWV) which was discovered in Australia in 1919. TSWV remained the only known member of the family until the early 1990s when genetic characterisation of plant viruses became more common. There are now at least twenty species in the genus with more being discovered on a regular basis. Member viruses infect over eight hundred plant species from 82 different families.

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The Citrus stubborn disease is a plant disease affecting species in the genus Citrus. Spiroplasma citri, a Mollicute bacterium species, is the causative agent of the disease. It is present in the phloem of the affected plant. Originally discovered transmitted by several leafhoppers including Circulifer tenellus and Scaphytopius nitridus in citrus-growing regions of California, it is now spread by the same hoppers in Arizona and Circulifer haematoceps in the Mediterranean region.

<span class="mw-page-title-main">Cherry X Disease</span>

Cherry X disease also known as Cherry Buckskin disease is caused by a plant pathogenic phytoplasma. Phytoplasmas are obligate parasites of plants and insects. They are specialized bacteria, characterized by their lack of a cell wall, often transmitted through insects, and are responsible for large losses in crops, fruit trees, and ornamentals. The phytoplasma causing Cherry X disease has a fairly limited host range mostly of stone fruit trees. Hosts of the pathogen include sweet cherry, sour cherry, choke cherry, peaches, nectarines, almonds, clover, and dandelion. Most commonly the pathogen is introduced into economical fruit orchards from wild choke cherry and herbaceous weed hosts. The pathogen is vectored by mountain and cherry leafhoppers. The mountain leafhopper vectors the pathogen from wild hosts to cherry orchards but does not feed on the other hosts. The cherry leafhopper feeds on cherry trees and can transmit the disease from cherry orchards to peach, nectarine, and other economic crops. Control of Cherry X disease is limited to controlling the spread, vectors, and weed hosts of the pathogen. Once the pathogen has infected a tree it is fatal and removal is necessary to stop it from becoming a reservoir for vectors.

Curtovirus is a genus of ssDNA viruses, in the family Geminiviridae. Dicotyledonous plants serve as natural hosts. Curtoviruses are transmitted by leafhoppers. There are three species in this genus. Diseases associated with this genus include: Curly top disease.

References

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