Successful infection of a plant by a plant virus depends on its ability to move from the cell initially infected to neighbouring cells in order to spread infection. Unlike animal cells, plant cells have robust cell walls, which viruses cannot easily penetrate. A movement protein is a non-structural protein which is encoded by some plant viruses to enable their movement from one infected cell to neighbouring cells. Many, if not all, plant viruses encode a movement protein, and some express more than one. The movement protein of tobacco mosaic virus (TMV) has been most extensively studied. Plant viruses can also be transported over longer distances through the host plant in the vascular system via the phloem.
Most plant viruses move between plant cells via plasmodesmata, pores between plant cell walls that allow the plant cells to communicate with each other. Plasmodesmata usually only allow the passage of small diffusible molecules, such as various metabolites. Neither virus particles nor viral genomic nucleic acid can pass through plasmodesmata unaided.
Movement proteins modify the plasmodesmata by one of two well-understood molecular mechanisms. The movement proteins of many plant viruses form a transport tubule within the pore of the plasmodesmata that allows the transport of mature virus particles. Examples of viruses that use this mechanism are cowpea mosaic virus (CPMV) and tomato spotted wilt virus (TSWV). The second mechanism by which movement proteins work is by associating with and coating the genome of the virus, causing the ribonucleoprotein complexes to be transported through plasmodesmata into neighbouring cells. TMV's 30 KDa movement protein acts via this mechanism, although it may also have other roles in infection.