fbpx
Wikipedia

Tobacco mosaic virus

November 26, 2023

Tobacco mosaic virus (TMV) is a positive-sense single-stranded RNA virus species in the genus Tobamovirus that infects a wide range of plants, especially tobacco and other members of the family Solanaceae. The infection causes characteristic patterns, such as "mosaic"-like mottling and discoloration on the leaves (hence the name). TMV was the first virus to be discovered. Although it was known from the late 19th century that a non-bacterial infectious disease was damaging tobacco crops, it was not until 1930 that the infectious agent was determined to be a virus. It is the first pathogen identified as a virus. The virus was crystallised by Wendell Meredith Stanley. It has a similar size to the largest synthetic molecule, known as PG5.[1]

Tobacco mosaic virus
Transmission electron micrograph of TMV particles negative stained to enhance visibility at 160,000× magnification
Virus classification
(unranked): Virus
Realm: Riboviria
Kingdom: Orthornavirae
Phylum: Kitrinoviricota
Class: Alsuviricetes
Order: Martellivirales
Family: Virgaviridae
Genus: Tobamovirus
Species:
Tobacco mosaic virus

History edit

In 1886, Adolf Mayer first described the tobacco mosaic disease that could be transferred between plants, similar to bacterial infections.[2][3] In 1892, Dmitri Ivanovsky gave the first concrete evidence for the existence of a non-bacterial infectious agent, showing that infected sap remained infectious even after filtering through the finest Chamberland filters.[3][4] Later, in 1903, Ivanovsky published a paper describing abnormal crystal intracellular inclusions in the host cells of the affected tobacco plants and argued the connection between these inclusions and the infectious agent.[5] However, Ivanovsky remained rather convinced, despite repeated failures to produce evidence, that the causal agent was an unculturable bacterium, too small to be retained on the employed Chamberland filters and to be detected in the light microscope. In 1898, Martinus Beijerinck independently replicated Ivanovsky's filtration experiments and then showed that the infectious agent was able to reproduce and multiply in the host cells of the tobacco plant.[3][6] Beijerinck adopted the term of "virus" to indicate that the causal agent of tobacco mosaic disease was of non-bacterial nature. Tobacco mosaic virus was the first virus to be crystallized. It was achieved by Wendell Meredith Stanley in 1935 who also showed that TMV remains active even after crystallization.[3] For his work, he was awarded 1/4 of the Nobel Prize in Chemistry in 1946,[7][8] even though it was later shown some of his conclusions (in particular, that the crystals were pure protein, and assembled by autocatalysis) were incorrect.[9] The first electron microscopical images of TMV were made in 1939 by Gustav Kausche, Edgar Pfankuch and Helmut Ruska – the brother of Nobel Prize winner Ernst Ruska.[10] In 1955, Heinz Fraenkel-Conrat and Robley Williams showed that purified TMV RNA and its capsid (coat) protein assemble by themselves to functional viruses, indicating that this is the most stable structure (the one with the lowest free energy). The crystallographer Rosalind Franklin worked for Stanley for about a month at Berkeley, and later designed and built a model of TMV for the 1958 World's Fair at Brussels. In 1958, she speculated that the virus was hollow, not solid, and hypothesized that the RNA of TMV is single-stranded.[11] This conjecture was proven to be correct after her death and is now known to be the + strand.[12] The investigations of tobacco mosaic disease and subsequent discovery of its viral nature were instrumental in the establishment of the general concepts of virology.[3]

Structure edit

 
Schematic model of TMV: 1. nucleic acid (RNA), 2. capsomer protein (protomer), 3. capsid

Tobacco mosaic virus has a rod-like appearance. Its capsid is made from 2130 molecules of coat protein and one molecule of genomic single strand RNA, 6400 bases long. The coat protein self-assembles into the rod-like helical structure (16.3 proteins per helix turn) around the RNA, which forms a hairpin loop structure (see the electron micrograph above). The structural organization of the virus gives stability.[13] The protein monomer consists of 158 amino acids which are assembled into four main alpha-helices, which are joined by a prominent loop proximal to the axis of the virion. Virions are ~300 nm in length and ~18 nm in diameter.[14] Negatively stained electron microphotographs show a distinct inner channel of radius ~2 nm. The RNA is located at a radius of ~4 nm and is protected from the action of cellular enzymes by the coat protein.[15] X-ray fiber diffraction structure of the intact virus was studied based on an electron density map at 3.6 Å resolution.[16] Inside the capsid helix, near the core, is the coiled RNA molecule, which is made up of 6,395 ±10 nucleotides.[17][18] The structure of the virus plays an important role in the recognition of the viral DNA. This happens due to the formation of an obligatory intermediate produced from a protein allows the virus to recognize a specific RNA hairpin structure.[19] The intermediate induces the nucleation of TMV self-assembly by binding with the hairpin structure.[20]

Genome edit

 
Genome of tobacco mosaic virus

The TMV genome consists of a 6.3–6.5 kbp single-stranded (ss) RNA. The 3’-terminus has a tRNA-like structure, and the 5’-terminus has a methylated nucleotide cap. (m7G5’pppG).[21] The genome encodes 4 open reading frames (ORFs), two of which produce a single protein due to ribosomal readthrough of a leaky UAG stop codon. The 4 genes encode a replicase (with methyltransferase [MT] and RNA helicase [Hel] domains), an RNA-dependent RNA polymerase, a so-called movement protein (MP) and a capsid protein (CP).[22] The coding sequence starts with the first reading frame, which is 69 nucleotides away from the 5' end of the RNA.[23] The noncoding region at the 5' end can be varied in different individual virions, but there hasn't been any variation found between virions in the noncoding region at the 3' end.[23]

Physicochemical properties edit

TMV is a thermostable virus. On a dried leaf, it can withstand up to 50 °C (120 degree Fahrenheit) for 30 minutes.[24]

TMV has an index of refraction of about 1.57.[25]

Disease cycle edit

TMV does not have a distinct overwintering structure. Rather, it will over-winter in infected tobacco stalks and leaves in the soil, on the surface of contaminated seed (TMV can even survive in contaminated tobacco products for many years, so smokers can accidentally transmit it by touch, although not in the smoke itself).[26][27] With the direct contact with host plants through its vectors (normally insects such as aphids and leafhoppers), TMV will go through the infection process and then the replication process.

Infection and transmission edit

After its multiplication, it enters the neighboring cells through plasmodesmata. The infection does not spread through contact with insects,[28] but instead spreads by direct contact to the neighboring cells. For its smooth entry, TMV produces a 30 kDa movement protein called P30 which enlarges the plasmodesmata. TMV most likely moves from cell-to-cell as a complex of the RNA, P30, and replicate proteins.

It can also spread through phloem for longer distance movement within the plant. Moreover, TMV can be transmitted from one plant to another by direct contact. Although TMV does not have defined transmission vectors, the virus can be easily transmitted from the infected hosts to the healthy plants by human handling.

Replication edit

Following entry into its host via mechanical inoculation, TMV uncoats itself to release its viral [+]RNA strand. As uncoating occurs, the MetHel:Pol gene is translated to make the capping enzyme MetHel and the RNA Polymerase. Then the viral genome will further replicate to produce multiple mRNAs via a [-]RNA intermediate primed by the tRNAHIS at the [+]RNA 3' end. The resulting mRNAs encode several proteins, including the coat protein and an RNA-dependent RNA polymerase (RdRp), as well as the movement protein. Thus TMV can replicate its own genome.

After the coat protein and RNA genome of TMV have been synthesized, they spontaneously assemble into complete TMV virions in a highly organized process. The protomers come together to form disks or 'lockwashers' composed of two layers of protomers arranged in a helix. The helical capsid grows by the addition of protomers to the end of the rod. As the rod lengthens, the RNA passes through a channel in its center and forms a loop at the growing end. In this way the RNA can easily fit as a spiral into the interior of the helical capsid.[29]

Host and symptoms edit

 
Tobacco mosaic virus symptoms on tobacco
 
Tobacco mosaic virus symptoms on orchid

Like other plant pathogenic viruses, TMV has a very wide host range and has different effects depending on the host being infected. Tobacco mosaic virus has been known to cause a production loss for flue cured tobacco of up to two percent in North Carolina.[30] It is known to infect members of nine plant families, and at least 125 individual species, including tobacco, tomato, pepper (all members of the Solanaceae), cucumbers, a number of ornamental flowers,[31] and beans including Phaseolus vulgaris and Vigna unguiculata.[32] There are many different strains. The first symptom of this virus disease is a light green coloration between the veins of young leaves. This is followed quickly by the development of a "mosaic" or mottled pattern of light and dark green areas in the leaves. Rugosity may also be seen where the infected plant leaves display small localized random wrinkles. These symptoms develop quickly and are more pronounced on younger leaves. Its infection does not result in plant death, but if infection occurs early in the season, plants are stunted. Lower leaves are subjected to "mosaic burn" especially during periods of hot and dry weather. In these cases, large dead areas develop in the leaves. This constitutes one of the most destructive phases of Tobacco mosaic virus infection. Infected leaves may be crinkled, puckered, or elongated. However, if TMV infects crops like grape and apple, it is almost symptomless. TMV is able to infect and complete its replication cycle in a plant pathogenic fungus,TMV is able to enter and replicate in cells of C. acutatum, C. clavatum, and C. theobromicola, which may not be an exception, although it has neither been found nor probably searched for in nature.[33]

Environment edit

TMV is one of the most stable viruses and has a wide survival range. As long as the surrounding temperature remains below approximately 40 degrees Celsius, TMV can sustain its stable form. All it needs is a host to infect. If necessary, greenhouses and botanical gardens would provide the most favorable condition for TMV to spread out, due to the high population density of possible hosts and the constant temperature throughout the year. It also could be useful to culture TMV in vitro in sap because it can survive up to 3000 days.[34]

Treatment and management edit

One of the common control methods for TMV is sanitation, which includes removing infected plants and washing hands in between each planting. Crop rotation should also be employed to avoid infected soil/seed beds for at least two years. As for any plant disease, looking for resistant strains against TMV may also be advised. Furthermore, the cross protection method can be administered, where the stronger strain of TMV infection is inhibited by infecting the host plant with a mild strain of TMV, similar to the effect of a vaccine.

In the past ten years, the application of genetic engineering on a host plant genome has been developed to allow the host plant to produce the TMV coat protein within their cells. It was hypothesized that the TMV genome will be re-coated rapidly upon entering the host cell, thus it prevents the initiation of TMV replication. Later it was found that the mechanism that protects the host from viral genome insertion is through gene silencing.[35]

TMV is inhibited by a product of the myxomycete slime mold Physarum polycephalum. Both tobacco and the beans P. vulgaris and V. sinensis suffered almost no lesioning in vitro from TMV when treated with a P. polycephalum extract.[32]

Research has shown that Bacillus spp. can be used to reduce the severity of symptoms from TMV in tobacco plants. In the study, treated tobacco plants had more growth and less build-up of TMV virions than tobacco plants that hadn't been treated.[36]

A research has been conducted by H.Fraenkel-Conrat to show the influence of acetic acid on the Tobacco Mosaic Virus. According to the research, 67% acetic acid resulted as degradation of the virus.[37]

Another possible source of prevention for TMV is the use of salicylic acid. A study completed by a research team at the University of Cambridge found that treating plants with salicylic acid reduced the amount of TMV viral RNAs and viral coat protein present in the tobacco plants. Their research showed that salicylic acid most likely was disrupting replication and transcription and more specifically, the RdRp complex.[38]

A research was conducted and revealed that humans have antibodies against Tobacco Mosaic Virus.[39]

Scientific and environmental impact edit

 
TMV virus: super resolution light microscopy

The large amount of literature about TMV and its choice for many pioneering investigations in structural biology (including X-ray diffraction), virus assembly and disassembly, and so on, are fundamentally due to the large quantities that can be obtained, plus the fact that it does not infect animals. After growing several hundred infected tobacco plants in a greenhouse, followed by a few simple laboratory procedures, a scientist can produce several grams of the virus.[40] In fact, tobacco mosaic virus is so proliferate that the inclusion bodies can be seen with only a light microscope.[28]

James D. Watson, in his memoir The Double Helix, cites his x-ray investigation of TMV's helical structure as an important step in deducing the nature of the DNA molecule.[41]

Applications edit

Plant viruses can be used to engineer viral vectors, tools commonly used by molecular biologists to deliver genetic material into plant cells; they are also sources of biomaterials and nanotechnology devices.[42][43] Viral vectors based on TMV include those of the magnICON and TRBO plant expression technologies.[43][44] Due to its cylindrical shape, high aspect ratio, self-assembling nature, and ability to incorporate metal coatings (nickel and cobalt) into its shell, TMV is an ideal candidate to be incorporated into battery electrodes.[45] Addition of TMV to a battery electrode increases the reactive surface area by an order of magnitude, resulting in an increase in the battery's capacity by up to six times compared to a planar electrode geometry.[45][46] The TMV-based vector also enabled C. acutatum to transiently express exogenous GFP up to six subcultures and for at least 2 mo after infection, without the need to develop transformation technology, RNAi can be expressed in the phytopathogenic fungus Colletotrichum acutatum by VIGS using a recombinant vector based on TMV in which the ORF of the gene encoding the green fluorescent protein (GFP) was transcribed in fungal cells from a duplicate of the TMV coat protein (CP) subgenomic mRNA promoter and demonstrated that the approach could be used to obtain foreign protein expression in fungi.[33]

References edit

  1. ^ "The Largest Molecule Ever Made Could Be Used to Deliver Drugs". Popular Science. 2019-03-18. Retrieved 2021-05-09.
  2. ^ Mayer A (1886). "Über die Mosaikkrankheit des Tabaks". Die Landwirtschaftliche Versuchs-stationen (in German). 32: 451–467. Translated into English in Johnson J, ed. (1942). "Concerning the mosaic disease of tobacco" (PDF). Phytopathological Classics. St. Paul, Minnesota: American Phytopathological Society. 7: 11–24.
  3. ^ a b c d e Zaitlin M (1998). "The Discovery of the Causal Agent of the Tobacco Mosaic Disease" (PDF). In Kung SD, Yang SF (eds.). Discoveries in Plant Biology. Hong Kong: World Publishing Co. pp. 105–110. ISBN 978-981-02-1313-8.
  4. ^ Iwanowski D (1892). "Über die Mosaikkrankheit der Tabakspflanze". Bulletin Scientifique Publié Par l'Académie Impériale des Sciences de Saint-Pétersbourg / Nouvelle Serie III (in German and Russian). 35: 67–70. Translated into English in Johnson J, ed. (1942). "Concerning the mosaic disease of the tobacco plant". Phytopathological Classics. St. Paul, Minnesota: American Phytopathological Society. 7: 27–30.
  5. ^ Iwanowski D (1903). "Über die Mosaikkrankheit der Tabakspflanze". Zeitschrift für Pflanzenkrankheiten und Pflanzenschutz (in German). 13 (1): 1–41. JSTOR 43221892.
  6. ^ Beijerinck MW (1898). "Über ein Contagium vivum fluidum als Ursache der Fleckenkrankheit der Tabaksblätter" (PDF). Verhandelingen der Koninklijke Akademie van Wetenschappen te Amsterdam (in German). 65: 1–22. Translated into English in Johnson J, ed. (1942). "Contagium vivum fluidum as the cause of spot disease in tobacco leaves". Phytopathological Classics. St. Paul, Minnesota: American Phytopathological Society. 7: 33–52.
  7. ^ "Wendell M. Stanley – Biographical". nobelprize.org.
  8. ^ "The Nobel Prize in Chemistry 1946". NobelPrize.org. Retrieved 2019-12-03.
  9. ^ Kay LE (September 1986). "W. M. Stanley's crystallization of the tobacco mosaic virus, 1930–1940". Isis; an International Review Devoted to the History of Science and Its Cultural Influences. 77 (288): 450–72. doi:10.1086/354205. JSTOR 231608. PMID 3533840. S2CID 37003363.
  10. ^ Kausche GA, Pfankuch E, Ruska H (May 1939). "Die Sichtbarmachung von pflanzlichem Virus im Übermikroskop". Naturwissenschaften. 27 (18): 292–9. Bibcode:1939NW.....27..292K. doi:10.1007/BF01493353. S2CID 206795712.
  11. ^ Maddox B (2002). Rosalind Franklin, the Dark Lady of DNA. Harper Collins. ISBN 978-0-06-018407-0.
  12. ^ Zaitlin M (1984). Brunt AA, Crabtree K, Dallwitz MJ, Gibbs AJ, Watson L, Zurcher EJ (eds.). . Plant Viruses Online: Descriptions and Lists from the VIDE Database. Archived from the original on 2009-10-01.
  13. ^ Caspar DL (January 1964). Anfinsen CB, Anson ML, Edsall JT (eds.). "Assembly and Stability of the Tobacco Mosaic Virus Particle". Advances in Protein Chemistry. Academic Press. 18: 37–121. doi:10.1016/S0065-3233(08)60268-5. ISBN 9780120342181. PMID 14151998.
  14. ^ Stryer L (1988). Biochemistry. San Francisco: W.H. Freeman. ISBN 978-0-7167-1843-7.
  15. ^ Klug A (March 1999). "The tobacco mosaic virus particle: structure and assembly". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 354 (1383): 531–5. doi:10.1098/rstb.1999.0404. PMC 1692534. PMID 10212932.
  16. ^ PDB: 1VTM​; Namba K, Stubbs G (March 1986). "Structure of tobacco mosaic virus at 3.6 A resolution: implications for assembly". Science. 231 (4744): 1401–6. doi:10.1126/science.3952490. PMID 3952490.
  17. ^ Goelet P, Lomonossoff GP, Butler PJ, Akam ME, Gait MJ, Karn J (October 1982). "Nucleotide sequence of tobacco mosaic virus RNA". Proceedings of the National Academy of Sciences of the United States of America. 79 (19): 5818–22. Bibcode:1982PNAS...79.5818G. doi:10.1073/pnas.79.19.5818. PMC 347001. PMID 6964389.
  18. ^ "Sequence: V01408.1". European Nucleotide Archive. EMBL- EBI. Retrieved 28 March 2020. International central site for archiving nucleic acid sequence. The reference standard in international science.
  19. ^ Klug A (March 1999). "The tobacco mosaic virus particle: structure and assembly". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 354 (1383): 531–535. doi:10.1098/rstb.1999.0404. PMC 1692534. PMID 10212932.
  20. ^ Butler PJ (March 1999). "Self-assembly of tobacco mosaic virus: the role of an intermediate aggregate in generating both specificity and speed". Philosophical Transactions of the Royal Society of London. Series B, Biological Sciences. 354 (1383): 537–550. doi:10.1098/rstb.1999.0405. PMC 1692540. PMID 10212933.
  21. ^ "Tobamovirus". Expasy Viralzone. SIB Swiss Institute of Bioinformatics.
  22. ^ Gergerich RC, Dolja VV (2006). "Introduction to Plant Viruses, the Invisible Foe". The Plant Health Instructor. doi:10.1094/PHI-I-2006-0414-01.
  23. ^ a b Goelet P, Lomonossoff GP, Butler PJ, Akam ME, Gait MJ, Karn J (October 1982). "Nucleotide sequence of tobacco mosaic virus RNA". Proceedings of the National Academy of Sciences of the United States of America. 79 (19): 5818–5822. Bibcode:1982PNAS...79.5818G. doi:10.1073/pnas.79.19.5818. PMC 347001. PMID 6964389.
  24. ^ Islam W, Qasim M, Ali N, Tayyab M, Chen S, Wang L (Jan 16, 2018). "Management of Tobacco Mosaic Virus through Natural Metabolites" (PDF). Records of Natural Products: 404.
  25. ^ Ashkin A, Dziedzic JM (March 1987). "Optical trapping and manipulation of viruses and bacteria". Science. 235 (4795): 1517–20. Bibcode:1987Sci...235.1517A. doi:10.1126/science.3547653. PMID 3547653.
  26. ^ "Is smoking harmful to plants?". OSU Extension Service. Ohio State University. 2018-05-02. Retrieved 2021-03-06.
  27. ^ "Tobacco Mosaic Virus (TMV)". Penn State Extension. Penn State College of Agricultural Sciences. Retrieved 2021-03-06.
  28. ^ a b "Tobacco Mosaic Virus: Pioneering Research for a Century". academic.oup.com. Retrieved 2022-10-09.
  29. ^ Woolverton C, Willey J, Sherwood L (2008). Prescott's Microbiology (7th ed.). Boston: McGraw Hill Higher Education. pp. 464–5. ISBN 978-0-07-110231-5.
  30. ^ Melton TA (2001). . North Carolina Cooperative Extension Service. Archived from the original on 2005-12-01. Retrieved 2009-02-21.
  31. ^ Pfleger FL, Zeyen RJ. . University of Minnesota. Archived from the original on 2012-06-14.
  32. ^ a b Mayhew DE, Ford RE (1971). "An Inhibitor of Tobacco Mosaic Virus Produced by Physarum polycephalum". Phytopathology. American Phytopathological Society. 61 (6): 636. doi:10.1094/phyto-61-636. ISSN 0031-949X.
  33. ^ a b Mascia, Tiziana; Nigro, Franco; Abdallah, Alì; Ferrara, Massimo; De Stradis, Angelo; Faedda, Roberto; Palukaitis, Peter; Gallitelli, Donato (18 March 2014). "Gene silencing and gene expression in phytopathogenic fungi using a plant virus vector". Proceedings of the National Academy of Sciences. 111 (11): 4291–4296. Bibcode:2014PNAS..111.4291M. doi:10.1073/pnas.1315668111. PMC 3964105. PMID 24594602.
  34. ^ Creager AN, Scholthof KB, Citovsky V, Scholthof HB (March 1999). "Tobacco mosaic virus. Pioneering research for a century". The Plant Cell. 11 (3): 301–308. doi:10.1105/tpc.11.3.301. PMC 1464663. PMID 10072391.
  35. ^ Agrios G (2005). Plant Pathology (5th ed.). Burlington, MA: Elsevier Academic Press. p. 320. ISBN 978-0-12-044565-3.
  36. ^ Wang S (2009-10-28). "Molecular Mechanism of Plant Growth Promotion and Induced Systemic Resistance to Tobacco Mosaic Virus by Bacillus spp". Journal of Microbiology and Biotechnology. 19 (10): 1250–1258. doi:10.4014/jmb.0901.008. PMID 19884788.
  37. ^ Fraenkel-Conrat H (August 1957). "Degradation of tobacco mosaic virus with acetic acid". Virology. 4 (1): 1–4. doi:10.1016/0042-6822(57)90038-7. ISSN 0042-6822. PMID 13456355.
  38. ^ Chivasa S, Murphy AM, Naylor M, Carr JP (April 1997). "Salicylic Acid Interferes with Tobacco Mosaic Virus Replication via a Novel Salicylhydroxamic Acid-Sensitive Mechanism". The Plant Cell. 9 (4): 547–557. doi:10.1105/tpc.9.4.547. PMC 156938. PMID 12237364.
  39. ^ Liu R, Vaishnav RA, Roberts AM, Friedland RP (2013). "Humans have antibodies against a plant virus: evidence from tobacco mosaic virus". PLOS ONE. 8 (4): e60621. Bibcode:2013PLoSO...860621L. doi:10.1371/journal.pone.0060621. PMC 3615994. PMID 23573274.
  40. ^ Rollinson, Shirley, personal communication
  41. ^ Watson JD (2012-11-06). "chapters 16, 18". The Annotated and Illustrated Double Helix. Simon and Schuster. ISBN 978-1-4767-1549-0.
  42. ^ Pasin F, Menzel W, Daròs JA (June 2019). "Harnessed viruses in the age of metagenomics and synthetic biology: an update on infectious clone assembly and biotechnologies of plant viruses". Plant Biotechnology Journal. 17 (6): 1010–1026. doi:10.1111/pbi.13084. PMC 6523588. PMID 30677208.
  43. ^ a b Abrahamian P, Hammond RW, Hammond J (June 2020). "Plant Virus-Derived Vectors: Applications in Agricultural and Medical Biotechnology". Annual Review of Virology. 7 (1): 513–535. doi:10.1146/annurev-virology-010720-054958. PMID 32520661. S2CID 219588089.
  44. ^ Lindbo JA (December 2007). "TRBO: a high-efficiency tobacco mosaic virus RNA-based overexpression vector". Plant Physiology. 145 (4): 1232–40. doi:10.1104/pp.107.106377. PMC 2151719. PMID 17720752.
  45. ^ a b Gerasopoulos K, McCarthy M, Royston E, Culver JN, Ghodssi R (January 13–17, 2008). Microbatteries with Tobacco Mosaic Virus Templated Electrodes. 2008 IEEE 21st International Conference on Micro Electro Mechanical Systems. Proceedings, IEEE Micro Electro Mechanical Systems. Tucson, USA. pp. 960–963. doi:10.1109/MEMSYS.2008.4443817. ISBN 978-1-4244-1792-6.
  46. ^ Atanasova P, Rothenstein D, Schneider JJ, Hoffmann RC, Dilfer S, Eiben S, et al. (November 2011). "Virus-templated synthesis of ZnO nanostructures and formation of field-effect transistors". Advanced Materials. 23 (42): 4918–22. Bibcode:2011AdM....23.4918A. doi:10.1002/adma.201102900. PMID 21959928. S2CID 205242233.

Further reading edit

  • Creager AN (2002). The life of a virus: tobacco mosaic virus as an experimental model, 1930–1965. Chicago: University of Chicago Press. ISBN 978-0-226-12026-3.
  • Flue-cured tobacco field manual. Winston-Salem, North Carolina: R.J. Reynolds Tobacco Company. 1995.

External links edit

 
Wikimedia Commons has media related to Tobacco mosaic virus.
  • Description of plant viruses – TMV 2007-09-26 at the Wayback Machine – contains information on symptoms, hosts species, purification etc.
  • Electron microscope image of TM

November 26, 2023
tobacco, mosaic, virus, positive, sense, single, stranded, virus, species, genus, tobamovirus, that, infects, wide, range, plants, especially, tobacco, other, members, family, solanaceae, infection, causes, characteristic, patterns, such, mosaic, like, mottlin. Tobacco mosaic virus TMV is a positive sense single stranded RNA virus species in the genus Tobamovirus that infects a wide range of plants especially tobacco and other members of the family Solanaceae The infection causes characteristic patterns such as mosaic like mottling and discoloration on the leaves hence the name TMV was the first virus to be discovered Although it was known from the late 19th century that a non bacterial infectious disease was damaging tobacco crops it was not until 1930 that the infectious agent was determined to be a virus It is the first pathogen identified as a virus The virus was crystallised by Wendell Meredith Stanley It has a similar size to the largest synthetic molecule known as PG5 1 Tobacco mosaic virusTransmission electron micrograph of TMV particles negative stained to enhance visibility at 160 000 magnificationVirus classification unranked VirusRealm RiboviriaKingdom OrthornaviraePhylum KitrinoviricotaClass AlsuviricetesOrder MartelliviralesFamily VirgaviridaeGenus TobamovirusSpecies Tobacco mosaic virus Contents 1 History 2 Structure 3 Genome 4 Physicochemical properties 5 Disease cycle 5 1 Infection and transmission 5 2 Replication 6 Host and symptoms 7 Environment 8 Treatment and management 9 Scientific and environmental impact 10 Applications 11 References 12 Further reading 13 External linksHistory editIn 1886 Adolf Mayer first described the tobacco mosaic disease that could be transferred between plants similar to bacterial infections 2 3 In 1892 Dmitri Ivanovsky gave the first concrete evidence for the existence of a non bacterial infectious agent showing that infected sap remained infectious even after filtering through the finest Chamberland filters 3 4 Later in 1903 Ivanovsky published a paper describing abnormal crystal intracellular inclusions in the host cells of the affected tobacco plants and argued the connection between these inclusions and the infectious agent 5 However Ivanovsky remained rather convinced despite repeated failures to produce evidence that the causal agent was an unculturable bacterium too small to be retained on the employed Chamberland filters and to be detected in the light microscope In 1898 Martinus Beijerinck independently replicated Ivanovsky s filtration experiments and then showed that the infectious agent was able to reproduce and multiply in the host cells of the tobacco plant 3 6 Beijerinck adopted the term of virus to indicate that the causal agent of tobacco mosaic disease was of non bacterial nature Tobacco mosaic virus was the first virus to be crystallized It was achieved by Wendell Meredith Stanley in 1935 who also showed that TMV remains active even after crystallization 3 For his work he was awarded 1 4 of the Nobel Prize in Chemistry in 1946 7 8 even though it was later shown some of his conclusions in particular that the crystals were pure protein and assembled by autocatalysis were incorrect 9 The first electron microscopical images of TMV were made in 1939 by Gustav Kausche Edgar Pfankuch and Helmut Ruska the brother of Nobel Prize winner Ernst Ruska 10 In 1955 Heinz Fraenkel Conrat and Robley Williams showed that purified TMV RNA and its capsid coat protein assemble by themselves to functional viruses indicating that this is the most stable structure the one with the lowest free energy The crystallographer Rosalind Franklin worked for Stanley for about a month at Berkeley and later designed and built a model of TMV for the 1958 World s Fair at Brussels In 1958 she speculated that the virus was hollow not solid and hypothesized that the RNA of TMV is single stranded 11 This conjecture was proven to be correct after her death and is now known to be the strand 12 The investigations of tobacco mosaic disease and subsequent discovery of its viral nature were instrumental in the establishment of the general concepts of virology 3 Structure edit nbsp Schematic model of TMV 1 nucleic acid RNA 2 capsomer protein protomer 3 capsidTobacco mosaic virus has a rod like appearance Its capsid is made from 2130 molecules of coat protein and one molecule of genomic single strand RNA 6400 bases long The coat protein self assembles into the rod like helical structure 16 3 proteins per helix turn around the RNA which forms a hairpin loop structure see the electron micrograph above The structural organization of the virus gives stability 13 The protein monomer consists of 158 amino acids which are assembled into four main alpha helices which are joined by a prominent loop proximal to the axis of the virion Virions are 300 nm in length and 18 nm in diameter 14 Negatively stained electron microphotographs show a distinct inner channel of radius 2 nm The RNA is located at a radius of 4 nm and is protected from the action of cellular enzymes by the coat protein 15 X ray fiber diffraction structure of the intact virus was studied based on an electron density map at 3 6 A resolution 16 Inside the capsid helix near the core is the coiled RNA molecule which is made up of 6 395 10 nucleotides 17 18 The structure of the virus plays an important role in the recognition of the viral DNA This happens due to the formation of an obligatory intermediate produced from a protein allows the virus to recognize a specific RNA hairpin structure 19 The intermediate induces the nucleation of TMV self assembly by binding with the hairpin structure 20 Genome edit nbsp Genome of tobacco mosaic virusThe TMV genome consists of a 6 3 6 5 kbp single stranded ss RNA The 3 terminus has a tRNA like structure and the 5 terminus has a methylated nucleotide cap m7G5 pppG 21 The genome encodes 4 open reading frames ORFs two of which produce a single protein due to ribosomal readthrough of a leaky UAG stop codon The 4 genes encode a replicase with methyltransferase MT and RNA helicase Hel domains an RNA dependent RNA polymerase a so called movement protein MP and a capsid protein CP 22 The coding sequence starts with the first reading frame which is 69 nucleotides away from the 5 end of the RNA 23 The noncoding region at the 5 end can be varied in different individual virions but there hasn t been any variation found between virions in the noncoding region at the 3 end 23 Physicochemical properties editTMV is a thermostable virus On a dried leaf it can withstand up to 50 C 120 degree Fahrenheit for 30 minutes 24 TMV has an index of refraction of about 1 57 25 Disease cycle editTMV does not have a distinct overwintering structure Rather it will over winter in infected tobacco stalks and leaves in the soil on the surface of contaminated seed TMV can even survive in contaminated tobacco products for many years so smokers can accidentally transmit it by touch although not in the smoke itself 26 27 With the direct contact with host plants through its vectors normally insects such as aphids and leafhoppers TMV will go through the infection process and then the replication process Infection and transmission edit After its multiplication it enters the neighboring cells through plasmodesmata The infection does not spread through contact with insects 28 but instead spreads by direct contact to the neighboring cells For its smooth entry TMV produces a 30 kDa movement protein called P30 which enlarges the plasmodesmata TMV most likely moves from cell to cell as a complex of the RNA P30 and replicate proteins It can also spread through phloem for longer distance movement within the plant Moreover TMV can be transmitted from one plant to another by direct contact Although TMV does not have defined transmission vectors the virus can be easily transmitted from the infected hosts to the healthy plants by human handling Replication edit Following entry into its host via mechanical inoculation TMV uncoats itself to release its viral RNA strand As uncoating occurs the MetHel Pol gene is translated to make the capping enzyme MetHel and the RNA Polymerase Then the viral genome will further replicate to produce multiple mRNAs via a RNA intermediate primed by the tRNAHIS at the RNA 3 end The resulting mRNAs encode several proteins including the coat protein and an RNA dependent RNA polymerase RdRp as well as the movement protein Thus TMV can replicate its own genome After the coat protein and RNA genome of TMV have been synthesized they spontaneously assemble into complete TMV virions in a highly organized process The protomers come together to form disks or lockwashers composed of two layers of protomers arranged in a helix The helical capsid grows by the addition of protomers to the end of the rod As the rod lengthens the RNA passes through a channel in its center and forms a loop at the growing end In this way the RNA can easily fit as a spiral into the interior of the helical capsid 29 Host and symptoms edit nbsp Tobacco mosaic virus symptoms on tobacco nbsp Tobacco mosaic virus symptoms on orchidLike other plant pathogenic viruses TMV has a very wide host range and has different effects depending on the host being infected Tobacco mosaic virus has been known to cause a production loss for flue cured tobacco of up to two percent in North Carolina 30 It is known to infect members of nine plant families and at least 125 individual species including tobacco tomato pepper all members of the Solanaceae cucumbers a number of ornamental flowers 31 and beans including Phaseolus vulgaris and Vigna unguiculata 32 There are many different strains The first symptom of this virus disease is a light green coloration between the veins of young leaves This is followed quickly by the development of a mosaic or mottled pattern of light and dark green areas in the leaves Rugosity may also be seen where the infected plant leaves display small localized random wrinkles These symptoms develop quickly and are more pronounced on younger leaves Its infection does not result in plant death but if infection occurs early in the season plants are stunted Lower leaves are subjected to mosaic burn especially during periods of hot and dry weather In these cases large dead areas develop in the leaves This constitutes one of the most destructive phases of Tobacco mosaic virus infection Infected leaves may be crinkled puckered or elongated However if TMV infects crops like grape and apple it is almost symptomless TMV is able to infect and complete its replication cycle in a plant pathogenic fungus TMV is able to enter and replicate in cells of C acutatum C clavatum and C theobromicola which may not be an exception although it has neither been found nor probably searched for in nature 33 Environment editTMV is one of the most stable viruses and has a wide survival range As long as the surrounding temperature remains below approximately 40 degrees Celsius TMV can sustain its stable form All it needs is a host to infect If necessary greenhouses and botanical gardens would provide the most favorable condition for TMV to spread out due to the high population density of possible hosts and the constant temperature throughout the year It also could be useful to culture TMV in vitro in sap because it can survive up to 3000 days 34 Treatment and management editOne of the common control methods for TMV is sanitation which includes removing infected plants and washing hands in between each planting Crop rotation should also be employed to avoid infected soil seed beds for at least two years As for any plant disease looking for resistant strains against TMV may also be advised Furthermore the cross protection method can be administered where the stronger strain of TMV infection is inhibited by infecting the host plant with a mild strain of TMV similar to the effect of a vaccine In the past ten years the application of genetic engineering on a host plant genome has been developed to allow the host plant to produce the TMV coat protein within their cells It was hypothesized that the TMV genome will be re coated rapidly upon entering the host cell thus it prevents the initiation of TMV replication Later it was found that the mechanism that protects the host from viral genome insertion is through gene silencing 35 TMV is inhibited by a product of the myxomycete slime mold Physarum polycephalum Both tobacco and the beans P vulgaris and V sinensis suffered almost no lesioning in vitro from TMV when treated with a P polycephalum extract 32 Research has shown that Bacillus spp can be used to reduce the severity of symptoms from TMV in tobacco plants In the study treated tobacco plants had more growth and less build up of TMV virions than tobacco plants that hadn t been treated 36 A research has been conducted by H Fraenkel Conrat to show the influence of acetic acid on the Tobacco Mosaic Virus According to the research 67 acetic acid resulted as degradation of the virus 37 Another possible source of prevention for TMV is the use of salicylic acid A study completed by a research team at the University of Cambridge found that treating plants with salicylic acid reduced the amount of TMV viral RNAs and viral coat protein present in the tobacco plants Their research showed that salicylic acid most likely was disrupting replication and transcription and more specifically the RdRp complex 38 A research was conducted and revealed that humans have antibodies against Tobacco Mosaic Virus 39 Scientific and environmental impact edit nbsp TMV virus super resolution light microscopyThe large amount of literature about TMV and its choice for many pioneering investigations in structural biology including X ray diffraction virus assembly and disassembly and so on are fundamentally due to the large quantities that can be obtained plus the fact that it does not infect animals After growing several hundred infected tobacco plants in a greenhouse followed by a few simple laboratory procedures a scientist can produce several grams of the virus 40 In fact tobacco mosaic virus is so proliferate that the inclusion bodies can be seen with only a light microscope 28 James D Watson in his memoir The Double Helix cites his x ray investigation of TMV s helical structure as an important step in deducing the nature of the DNA molecule 41 Applications editPlant viruses can be used to engineer viral vectors tools commonly used by molecular biologists to deliver genetic material into plant cells they are also sources of biomaterials and nanotechnology devices 42 43 Viral vectors based on TMV include those of the magnICON and TRBO plant expression technologies 43 44 Due to its cylindrical shape high aspect ratio self assembling nature and ability to incorporate metal coatings nickel and cobalt into its shell TMV is an ideal candidate to be incorporated into battery electrodes 45 Addition of TMV to a battery electrode increases the reactive surface area by an order of magnitude resulting in an increase in the battery s capacity by up to six times compared to a planar electrode geometry 45 46 The TMV based vector also enabled C acutatum to transiently express exogenous GFP up to six subcultures and for at least 2 mo after infection without the need to develop transformation technology RNAi can be expressed in the phytopathogenic fungus Colletotrichum acutatum by VIGS using a recombinant vector based on TMV in which the ORF of the gene encoding the green fluorescent protein GFP was transcribed in fungal cells from a duplicate of the TMV coat protein CP subgenomic mRNA promoter and demonstrated that the approach could be used to obtain foreign protein expression in fungi 33 References edit The Largest Molecule Ever Made Could Be Used to Deliver Drugs Popular Science 2019 03 18 Retrieved 2021 05 09 Mayer A 1886 Uber die Mosaikkrankheit des Tabaks Die Landwirtschaftliche Versuchs stationen in German 32 451 467 Translated into English in Johnson J ed 1942 Concerning the mosaic disease of tobacco PDF Phytopathological Classics St Paul Minnesota American Phytopathological Society 7 11 24 a b c d e Zaitlin M 1998 The Discovery of the Causal Agent of the Tobacco Mosaic Disease PDF In Kung SD Yang SF eds Discoveries in Plant Biology Hong Kong World Publishing Co pp 105 110 ISBN 978 981 02 1313 8 Iwanowski D 1892 Uber die Mosaikkrankheit der Tabakspflanze Bulletin Scientifique Publie Par l Academie Imperiale des Sciences de Saint Petersbourg Nouvelle Serie III in German and Russian 35 67 70 Translated into English in Johnson J ed 1942 Concerning the mosaic disease of the tobacco plant Phytopathological Classics St Paul Minnesota American Phytopathological Society 7 27 30 Iwanowski D 1903 Uber die Mosaikkrankheit der Tabakspflanze Zeitschrift fur Pflanzenkrankheiten und Pflanzenschutz in German 13 1 1 41 JSTOR 43221892 Beijerinck MW 1898 Uber ein Contagium vivum fluidum als Ursache der Fleckenkrankheit der Tabaksblatter PDF Verhandelingen der Koninklijke Akademie van Wetenschappen te Amsterdam in German 65 1 22 Translated into English in Johnson J ed 1942 Contagium vivum fluidum as the cause of spot disease in tobacco leaves Phytopathological Classics St Paul Minnesota American Phytopathological Society 7 33 52 Wendell M Stanley Biographical nobelprize org The Nobel Prize in Chemistry 1946 NobelPrize org Retrieved 2019 12 03 Kay LE September 1986 W M Stanley s crystallization of the tobacco mosaic virus 1930 1940 Isis an International Review Devoted to the History of Science and Its Cultural Influences 77 288 450 72 doi 10 1086 354205 JSTOR 231608 PMID 3533840 S2CID 37003363 Kausche GA Pfankuch E Ruska H May 1939 Die Sichtbarmachung von pflanzlichem Virus im Ubermikroskop Naturwissenschaften 27 18 292 9 Bibcode 1939NW 27 292K doi 10 1007 BF01493353 S2CID 206795712 Maddox B 2002 Rosalind Franklin the Dark Lady of DNA Harper Collins ISBN 978 0 06 018407 0 Zaitlin M 1984 Brunt AA Crabtree K Dallwitz MJ Gibbs AJ Watson L Zurcher EJ eds Tobacco mosaic tobamovirus Plant Viruses Online Descriptions and Lists from the VIDE Database Archived from the original on 2009 10 01 Caspar DL January 1964 Anfinsen CB Anson ML Edsall JT eds Assembly and Stability of the Tobacco Mosaic Virus Particle Advances in Protein Chemistry Academic Press 18 37 121 doi 10 1016 S0065 3233 08 60268 5 ISBN 9780120342181 PMID 14151998 Stryer L 1988 Biochemistry San Francisco W H Freeman ISBN 978 0 7167 1843 7 Klug A March 1999 The tobacco mosaic virus particle structure and assembly Philosophical Transactions of the Royal Society of London Series B Biological Sciences 354 1383 531 5 doi 10 1098 rstb 1999 0404 PMC 1692534 PMID 10212932 PDB 1VTM Namba K Stubbs G March 1986 Structure of tobacco mosaic virus at 3 6 A resolution implications for assembly Science 231 4744 1401 6 doi 10 1126 science 3952490 PMID 3952490 Goelet P Lomonossoff GP Butler PJ Akam ME Gait MJ Karn J October 1982 Nucleotide sequence of tobacco mosaic virus RNA Proceedings of the National Academy of Sciences of the United States of America 79 19 5818 22 Bibcode 1982PNAS 79 5818G doi 10 1073 pnas 79 19 5818 PMC 347001 PMID 6964389 Sequence V01408 1 European Nucleotide Archive EMBL EBI Retrieved 28 March 2020 International central site for archiving nucleic acid sequence The reference standard in international science Klug A March 1999 The tobacco mosaic virus particle structure and assembly Philosophical Transactions of the Royal Society of London Series B Biological Sciences 354 1383 531 535 doi 10 1098 rstb 1999 0404 PMC 1692534 PMID 10212932 Butler PJ March 1999 Self assembly of tobacco mosaic virus the role of an intermediate aggregate in generating both specificity and speed Philosophical Transactions of the Royal Society of London Series B Biological Sciences 354 1383 537 550 doi 10 1098 rstb 1999 0405 PMC 1692540 PMID 10212933 Tobamovirus Expasy Viralzone SIB Swiss Institute of Bioinformatics Gergerich RC Dolja VV 2006 Introduction to Plant Viruses the Invisible Foe The Plant Health Instructor doi 10 1094 PHI I 2006 0414 01 a b Goelet P Lomonossoff GP Butler PJ Akam ME Gait MJ Karn J October 1982 Nucleotide sequence of tobacco mosaic virus RNA Proceedings of the National Academy of Sciences of the United States of America 79 19 5818 5822 Bibcode 1982PNAS 79 5818G doi 10 1073 pnas 79 19 5818 PMC 347001 PMID 6964389 Islam W Qasim M Ali N Tayyab M Chen S Wang L Jan 16 2018 Management of Tobacco Mosaic Virus through Natural Metabolites PDF Records of Natural Products 404 Ashkin A Dziedzic JM March 1987 Optical trapping and manipulation of viruses and bacteria Science 235 4795 1517 20 Bibcode 1987Sci 235 1517A doi 10 1126 science 3547653 PMID 3547653 Is smoking harmful to plants OSU Extension Service Ohio State University 2018 05 02 Retrieved 2021 03 06 Tobacco Mosaic Virus TMV Penn State Extension Penn State College of Agricultural Sciences Retrieved 2021 03 06 a b Tobacco Mosaic Virus Pioneering Research for a Century academic oup com Retrieved 2022 10 09 Woolverton C Willey J Sherwood L 2008 Prescott s Microbiology 7th ed Boston McGraw Hill Higher Education pp 464 5 ISBN 978 0 07 110231 5 Melton TA 2001 Control of Tobacco Mosaic Virus on Flue Cured Tobacco North Carolina Cooperative Extension Service Archived from the original on 2005 12 01 Retrieved 2009 02 21 Pfleger FL Zeyen RJ Tomato Tobacco Mosaic Virus Disease University of Minnesota Archived from the original on 2012 06 14 a b Mayhew DE Ford RE 1971 An Inhibitor of Tobacco Mosaic Virus Produced by Physarum polycephalum Phytopathology American Phytopathological Society 61 6 636 doi 10 1094 phyto 61 636 ISSN 0031 949X a b Mascia Tiziana Nigro Franco Abdallah Ali Ferrara Massimo De Stradis Angelo Faedda Roberto Palukaitis Peter Gallitelli Donato 18 March 2014 Gene silencing and gene expression in phytopathogenic fungi using a plant virus vector Proceedings of the National Academy of Sciences 111 11 4291 4296 Bibcode 2014PNAS 111 4291M doi 10 1073 pnas 1315668111 PMC 3964105 PMID 24594602 Creager AN Scholthof KB Citovsky V Scholthof HB March 1999 Tobacco mosaic virus Pioneering research for a century The Plant Cell 11 3 301 308 doi 10 1105 tpc 11 3 301 PMC 1464663 PMID 10072391 Agrios G 2005 Plant Pathology 5th ed Burlington MA Elsevier Academic Press p 320 ISBN 978 0 12 044565 3 Wang S 2009 10 28 Molecular Mechanism of Plant Growth Promotion and Induced Systemic Resistance to Tobacco Mosaic Virus by Bacillus spp Journal of Microbiology and Biotechnology 19 10 1250 1258 doi 10 4014 jmb 0901 008 PMID 19884788 Fraenkel Conrat H August 1957 Degradation of tobacco mosaic virus with acetic acid Virology 4 1 1 4 doi 10 1016 0042 6822 57 90038 7 ISSN 0042 6822 PMID 13456355 Chivasa S Murphy AM Naylor M Carr JP April 1997 Salicylic Acid Interferes with Tobacco Mosaic Virus Replication via a Novel Salicylhydroxamic Acid Sensitive Mechanism The Plant Cell 9 4 547 557 doi 10 1105 tpc 9 4 547 PMC 156938 PMID 12237364 Liu R Vaishnav RA Roberts AM Friedland RP 2013 Humans have antibodies against a plant virus evidence from tobacco mosaic virus PLOS ONE 8 4 e60621 Bibcode 2013PLoSO 860621L doi 10 1371 journal pone 0060621 PMC 3615994 PMID 23573274 Rollinson Shirley personal communication Watson JD 2012 11 06 chapters 16 18 The Annotated and Illustrated Double Helix Simon and Schuster ISBN 978 1 4767 1549 0 Pasin F Menzel W Daros JA June 2019 Harnessed viruses in the age of metagenomics and synthetic biology an update on infectious clone assembly and biotechnologies of plant viruses Plant Biotechnology Journal 17 6 1010 1026 doi 10 1111 pbi 13084 PMC 6523588 PMID 30677208 a b Abrahamian P Hammond RW Hammond J June 2020 Plant Virus Derived Vectors Applications in Agricultural and Medical Biotechnology Annual Review of Virology 7 1 513 535 doi 10 1146 annurev virology 010720 054958 PMID 32520661 S2CID 219588089 Lindbo JA December 2007 TRBO a high efficiency tobacco mosaic virus RNA based overexpression vector Plant Physiology 145 4 1232 40 doi 10 1104 pp 107 106377 PMC 2151719 PMID 17720752 a b Gerasopoulos K McCarthy M Royston E Culver JN Ghodssi R January 13 17 2008 Microbatteries with Tobacco Mosaic Virus Templated Electrodes 2008 IEEE 21st International Conference on Micro Electro Mechanical Systems Proceedings IEEE Micro Electro Mechanical Systems Tucson USA pp 960 963 doi 10 1109 MEMSYS 2008 4443817 ISBN 978 1 4244 1792 6 Atanasova P Rothenstein D Schneider JJ Hoffmann RC Dilfer S Eiben S et al November 2011 Virus templated synthesis of ZnO nanostructures and formation of field effect transistors Advanced Materials 23 42 4918 22 Bibcode 2011AdM 23 4918A doi 10 1002 adma 201102900 PMID 21959928 S2CID 205242233 Further reading edit nbsp Viruses portalCreager AN 2002 The life of a virus tobacco mosaic virus as an experimental model 1930 1965 Chicago University of Chicago Press ISBN 978 0 226 12026 3 Flue cured tobacco field manual Winston Salem North Carolina R J Reynolds Tobacco Company 1995 External links edit nbsp Wikimedia Commons has media related to Tobacco mosaic virus Description of plant viruses TMV Archived 2007 09 26 at the Wayback Machine contains information on symptoms hosts species purification etc Further information Electron microscope image of TM Retrieved from https en wikipedia org w index php title Tobacco mosaic virus amp oldid 1184841752, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.