Tobacco streak virus explained

Tobacco streak virus (TSV) is a plant pathogenic virus of the family Bromoviridae, in the genus Ilarvirus. It has a wide host range, with at least 200 susceptible species.[1] TSV is generally more problematic in the tropics or warmer climates. TSV does not generally lead to epidemics, with the exception of sunflowers in India and Australia, and peanuts in India.[2]

Host and symptoms

TSV has been reported worldwide in North and South America, Europe, India, Japan, Australia, New Zealand and South America.[3] TSV has a wide host range including both monocots and dicots. Economically important crop hosts include peanuts, sunflower, soybean, cranberry, cotton, chickpea and mung beans.[4] As with many plant viruses, diagnosis is very difficult because TSV has very wide host range and has different effects depending on the host being infected. Symptoms of TSV may include black streaks on stems and leaves, stunted growth, chlorosis, leaf mosaic, lodging, and deformed growing tips, to name a few.[5] On tobacco plants, TSV causes chlorosis, with a unique pattern of white or dark necrotic leaf tissue close to the veins of the leaf. As its name implies, necrotic streaks are found on leaf veins of infected plants. Symptoms are strongly influenced by temperature. For example, plants experiencing a temperature of 20 °C will develop small necrotic spots while at temperatures above 30 °C, necrotic spots will become large necrotic arcs. Symptoms are not sufficient to correctly identify TSV - serology and PCR techniques are required.

Disease cycle

TSV purified from infected plants consists of a ss-RNA genome encapsulated by spheroid particles made up of coat protein subunits. The coat protein subunits play a key role in the life cycle of the virus. Once the virus has penetrated into the host cells, it uncoats and releases its viral genomic RNA into the cytoplasm and expressed proteins replicate. After replication, the dsRNA genome is synthesized from genomic ssRNA.[6] Subgenomic RNA4 is translated producing capsid proteins and the new virus particles are assembled. The coat protein of TSV plays an important role in its life cycle. It protects the viral genome and plays a role in cell to cell movement. Once the virus becomes systemic, it can be transmitted by vectors. TSV requires a living plant to survive for a period of time. The virus may be transmitted by thrips vector, mechanical damage, pollen or dodder.

Environment

Severe outbreaks of TSV typically occur under climatic conditions that allow large thrips populations to develop and when large quantities of pollen are being produced by the host plant. These conditions generally occur in warmer months but are dependent on rainfall and weeds in the field.[7]

Modes of Transmission:

Management

Control for TSV is difficult, and there are no chemical controls available for the virus. The best management practices are to maintain good sanitation, purchase certified seed, control insects that serve as vectors, and provide barrier crops.[10]

Sanitation: Remove plant debris after harvest or any plant material that may serve as a source of inoculum. Due to its wide host range, TSV may also infect many weed species, so keeping fields free of weeds is a good control strategy.

Chemical Control: Preventative control of disease dispersal may be possible if insecticide is sprayed for the trips vector. Barrier Crops: One common form of management for viruses is to plant a desirable host for thrips around the cropping system. The thrips will insert their stylet and "clean" off any virus on their stylet before moving to the target crop.

Barrier Crops: One common form of management for viruses is to plant a desirable host for thrips around the cropping system. The thrips will insert their stylet and "clean" off any virus on their stylet before moving to the target crop.[11]

External links

Affected organisms

External links

Notes and References

  1. Web site: Viral Diseases. Lima. Tatiana. Tatiana Lima & Fernanda Viana, Souza Cruz.
  2. Web site: CABI - Invasive Species Compedium.
  3. Web site: Descriptions of Plant Viruses. Tobacco streak virus. Scott. S.W.. December 2001. Clemson University, Department of Plant Pathology and Physiology. 2017-12-14.
  4. Gulati A., Alapati K., Murthy A., Savithri HS., Murthy MR.. February 2016. Structural studies on tobacco streak virus coat protein: Insights into the pleomorphic nature of ilarviruses. J Struct Biol. 193 . 2 . 95–105. 26706030. 10.1016/j.jsb.2015.12.007.
  5. Web site: Viral Diseases. Tatiana Lima & Fernanda Viana.
  6. Web site: Ilarvirus. ViralZone.expasy.org. 2017-12-14.
  7. Web site: TOBACCO STREAK VIRUS IN GRAIN AND PULSE CROPS IN QUEENSLAND. Grains Research and Development Corporation. en-AU. 2017-12-14.
  8. Rabedeaux. P. F.. Gaska. J. M.. Kurtzweil. N. C.. Grau. C. R.. Seasonal Progression and Agronomic Impact ofTobacco streak viruson Soybean in Wisconsin. Plant Disease. 89. 4. 391–396. 10.1094/pd-89-0391. 30795455. 2005. free.
  9. Web site: Show DPV. Antoniw. John. www.dpvweb.net. 2017-12-14.
  10. News: Stop Tobacco Streak Virus From Taking Hold Of Your Vegetables. 2014-12-25. Growing Produce. 2017-12-14. en-US.
  11. M. Sharman, J.E. Thomas, D.M. Persley. May 2015. Natural host range, thrips and seed transmission of distinct Tobacco streak virus strains in Queensland, Australia. Annals of Applied Biology. 167. 2. 197–207. 10.1111/aab.12218.