Editing Plant virus (section)

== History ==

[[File:TobaccoMosaicVirus.jpg|right|thumb|[[Electron microscope|Electron micrograph]] of the rod-shaped particles of [[tobacco mosaic virus]]|upright]]

The discovery of plant viruses causing [[disease]] is often accredited to A. Mayer (1886) working in the Netherlands demonstrated that the sap of mosaic obtained from tobacco leaves developed mosaic symptom when injected in healthy plants. However the infection of the sap was destroyed when it was boiled. He thought that the causal agent was bacteria. However, after larger inoculation with a large number of bacteria, he failed to develop a mosaic symptom.

In 1898, Martinus Beijerinck, who was a professor of microbiology at the Technical University the Netherlands, put forth his concepts that viruses were small and determined that the "mosaic disease" remained infectious when passed through a [[Chamberland filter|Chamberland filter-candle]]. This was in contrast to bacteria [[microorganisms]], which were retained by the filter. [[Beijerinck]] referred to the infectious filtrate as a "[[contagium vivum fluidum]]", thus the coinage of the modern term "virus".

After the initial discovery of the 'viral concept' there was need to classify any other known [[virus|viral]] diseases based on the mode of transmission even though [[microscopic]] observation proved fruitless. In 1939 Holmes published a classification list of 129 plant viruses. This was expanded and in 1999 there were 977 officially recognized, and some provisional, plant virus species.

The purification (crystallization) of TMV was first performed by [[Wendell Stanley]], who published his findings in 1935, although he did not determine that the RNA was the infectious material. However, he received the [[Nobel Prize]] in Chemistry in 1946. In the 1950s a discovery by two labs simultaneously proved that the purified [[RNA]] of the TMV was infectious which reinforced the argument. The RNA carries [[Genetics|genetic]] information to code for the production of new infectious particles.

More recently virus research has been focused on understanding the genetics and molecular biology of plant virus [[genomes]], with a particular interest in determining how the virus can replicate, move and infect plants. Understanding the virus genetics and protein functions has been used to explore the potential for commercial use by [[biotechnology]] companies. In particular, viral-derived sequences have been used to provide an understanding of novel forms of [[Plant disease resistance|resistance]]. The recent boom in technology allowing humans to manipulate plant viruses may provide new strategies for production of value-added proteins in plants.