The Coat and Cylindrical Inclusion Proteins of a Potyvirus Are Associated with Connections between Plant Cells (original) (raw)
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Virology, 1998
A systematic ultrastructural study across the edge of an advancing infection in pea seed-borne mosaic potyvirus-infected pea cotyledons showed the cylindrical inclusion (CI) protein to exist in transient functional states. Initially, the characteristic CI pinwheel inclusion bodies were positioned centrally over the plasmodesmal apertures (including those of plasmodesmata connected to the previously infected cell), in agreement with a proposed role in virus movement (Carrington et al., 1998, Plant J., 13, in press). The viral coat protein was associated with these structures and was seen within the modified plasmodesma, most notably in a continuous channel that passed along the axis of the pinwheel and through the plasmodesma. The CI protein was not detected within the plasmodesmal cavities. Later in the infection (i.e., behind the zone of active virus replication) the CI was no longer associated with cell walls, or with coat protein, and showed signs of structural degeneration. In contrast, the coat protein remained within plasmodesmal cavities. The role of the CI in assisting virus movement is not known but the presence of the CI was linked with an apparent transient reduction in callose in the vicinity of the plasmodesmata.
Journal of General Virology, 2008
Potato virus A (PVA) particles were purified by centrifugation through a 30 % sucrose cushion and the pellet (P1) was resuspended and sedimented through a 5-40 % sucrose gradient. The gradient separation resulted in two different virus particle populations: a virus fraction (F) that formed a band in the gradient and one that formed a pellet (P2) at the bottom of the gradient. All three preparations contained infectious particles that retained their integrity when visualized by electron microscopy (EM). Western blotting of the P1 particles revealed that the viral RNA helicase, cylindrical inclusion protein (CI), co-purified with virus particles. This result was confirmed with co-immunoprecipitation experiments. CI was detected in P2 particle preparations, whereas F particles were devoid of detectable amounts of CI. ATPase activity was detected in all three preparations with the greatest amount in P2. Results from immunogold-labelling EM experiments suggested that a fraction of the CI present in the preparations was localized to one end of the virion. Atomic force microscopy (AFM) studies showed that P1 and P2 contained intact particles, some of which had a protruding tip structure at one end, whilst F virions were less stable and mostly appeared as beaded structures under the conditions of AFM. The RNA of the particles in F was translated five to ten times more efficiently than RNA from P2 particles when these preparations were subjected to translation in wheat-germ extracts. The results are discussed in the context of a model for CI-mediated functions.
Acta Physiologiae Plantarum, 2012
The studies focus on an ultrastructural analysis of the phenomenon of intercellular and systemic (vascular) transport of tobacco rattle virus (TRV) in tissues of the infected plants. TRV is a dangerous pathogen of cultivated and ornamental plants due to its wide range of plant hosts and continuous transmission by vectors-ectoparasitic nematodes. Two weeks after infection with the PSG strain of TRV, tobacco plants of the Samsun variety and potato plants of the Glada variety responded with spot surface necroses on inoculated leaf blades. Four weeks after the infection a typical systemic response was observed on tobacco and potato leaves, necroses on stems and lesions referred to as corky ringspot. Ultrastructural analysis revealed the presence of two types of TRV virions: capsidated and non-capsidated forms in tobacco and potato tissues. In the protoplast area, viral particles either occurred in a dispersed form or they formed organised inclusions of virions. We demonstrated for the first time the presence of non-capsidated-type TRV in the vicinity of and inside plasmodesmata. Capsidated particles of TRV were observed in intercellular spaces of the tissues of aboveground and underground organs. Expanded apoplast area was noted at the cell wall, with numerous dispersed non-capsidated-type TRV particles. These phenomena suggest active intercellular transport. Our ultrastructure studies showed for the first time that xylem can be a possible route of TRV systemic transport. We demonstrated that both capsidated and non-capsidated virions, of varied length, participate in long-distance transport. TRV virions were more often documented in xylem (tracheary elements and parenchyma) than in phloem. Non-capsidated TRV particles were observed inside tracheary elements in a dispersed form and in regular arrangements in potato and tobacco xylem. The presence of TRV virions inside the bordered pits was demonstrated in aboveground organs and in the root of the tested plants. We documented that both forms of TRV virions can be transported systemically via tracheary elements of xylem.
The Journal of general virology, 1998
The N-terminal P1 proteinase of potato virus Y (ordinary strain group isolate PVY-O) was expressed in E. coli. Antiserum was raised against the expressed protein and used to detect the viral proteins in infected tobacco leaf tissue by Western blotting and by electron microscopy with immunogold labelling. In the immunogold localization studies P1 protein was detected in association with the cytoplasmic inclusion bodies characteristic of PVY infections and in the cytoplasm of the infected plant cells. No significant P1 antibody binding with other plant cell organelles, or with the cell wall and plasmodesmata, was detected by immunogold labelling.
Cytopathological Potato virus Y structures during Solanaceous plants infection
Micron, 2012
The ultrastructural analysis of tobacco, potato and pepper tissues during infection with necrotic strains and the ordinary Potato virus Y strain of revealed the presence of virus inclusions not only in the epidermis and mesophyll but also in the vascular tissues. For the first time cytoplasmic inclusions were documented in companion cells and phloem parenchyma as well as in xylem tracheary elements. The ultrastructural features studied in this work consisted of mostly laminated inclusions (in the traverse and longitudinal section), which were frequently connected with enlarged cisternae of endoplasmic reticulum (ER) located in the direct vicinity of the cell wall attached to virus particles opposite to plasmodesmata. It was noticed that ER participates in synthesis and condensation of the PVY inclusions. During compatible interaction of tobacco and potato plants with PVY, amorphous and nuclear inclusions were observed. Such forms were not found in pepper tissues and potato revealing the hypersensitivity reaction to the infection with PVY necrotic strains. It was stated that the forms of cytoplasmic inclusions cannot serve as a cytological criterion to distinguish the potato virus Y strains and do not depend on host resistance level. Only in compatible interaction in Solanaceous plants tissues cytoplasmic inclusions were observed from the moment the morphological symptoms appeared. In the reaction of hypersensitivity, the inclusions were found on the 24th day following the infection with the PVY necrotic strains, whereas the symptoms were observed 3 days after the PVY infection.
Systemic Infection of Potyvirus: A Compatible Interaction Between Host and Viral Proteins
Approaches to Plant Stress and their Management, 2013
Viruses profoundly depend on endogenous host transport system and interact with preexisting host cellular factors during movement. Potyviral movement is directed by several movement proteins that are HCpro, CP, VPg, and CI and newly discovered P3N-PIPO. CP and HC-pro facilitate movement of virus by increasing size exclusion limit (SEL) of plasmodesmata (PD). These movement proteins serve many functions: binding the viral genome, transporting the viral genome to plasmodesmata, gating plasmodesmata, trafficking through plasmodesmata, and then transporting through phloem. TuMV P3N-PIPO is a PD-localized protein and mediates the targeting of CI to PD. The P3 protein was not previously associated with potyvirus movement, but it was known to interact with the P1 protein; it is co-localized with 6K2 vesicles (site of potyviral replication). This points out a link between virus replication complexes and intracellular movement. CP has the ability to increase SEL of PD and interact with host RTM factors and suppress RTM resistance of plants. HC-Pro is crucial for long-distance movement of potyvirus by suppressing gene silencing mechanism of host plant. Interaction with host factors and chaperones is also required for efficient spread of potyvirus; presumably interaction of the viral CP with a plant DnaJ-like protein NtCPIP (coat protein interacting protein) provides a strong in vivo confirmation for the essential role of plant chaperones in potyvirus movement. In this chapter, we are concerned on potyvirus intracellular, intercellular, and long-distance movement, focusing on the host cellular factors' interaction with movement proteins involved. Abstract 8 Viruses profoundly depend on endogenous host transport system and 9 interact with preexisting host cellular factors during movement. Potyviral
Plants that express a potyvirus proteinase gene are resistant to virus infection
Proceedings of the National Academy of Sciences, 1993
Transgenic tobacco plants that express the genome-linked protein/proteinase-coding region of the potyvirus tobacco vein mottvlngirus (TVMV) were produced and tested for their reaction to inoculation with TVMV and two other potyviruses. These plants did not develop disease symptoms after being inoculated with large doses ofTVMV but were as susceptible to infection by the other potyviruses as were control plants. Lines of tobacco that express the coat proteinor the nonstructural cylndrical inclusion protein-coding regions were also produced. The coat protein transgenic plants
2012
The potato mop-top virus (PMTV) triple gene block 2 (TGB2) movement proteins fused to monomeric red fluorescent protein (mRFP-TGB2) was expressed under the control of the PMTV subgenomic promoter from a PMTV vector. The subcellular localizations and interactions of mRFP-TGB2 were investigated using confocal imaging [confocal laser-scanning microscope, (CLSM)] and biochemical analysis. The results revealed associations with membranes of the endoplasmic reticulum (ER), mobile granules, small round structures (1-2 μm in diameter), and chloroplasts. Expression of mRFP-TGB2 in epidermal cells enabled cell-to-cell movement of a TGB2 defective PMTV reporter clone, indicating that the mRFP-TGB2 fusion protein was functional and required for cell-to-cell movement. Protein-lipid interaction assays revealed an association between TGB2 and lipids present in chloroplasts, consistent with microscopical observations where the plastid envelope was labeled later in infection. To further investigate the association of PMTV infection with chloroplasts, ultrastructural studies of thin sections of PMTV-infected potato and Nicotiana benthamiana leaves by electron microscopy revealed abnormal chloroplasts with cytoplasmic inclusions and terminal projections. Viral coat protein (CP), genomic RNA and fluorescently-labeled TGB2 were detected in plastid preparations isolated from the infected leaves, and viral RNA was localized to chloroplasts in infected tissues. The results reveal a novel association of TGB2 and vRNA with chloroplasts, and suggest viral replication is associated with chloroplast membranes, and that TGB2 plays a novel role in targeting the virus to chloroplasts.
Plant Physiology, 2012
Tobacco mosaic virus (TMV) forms dense cytoplasmic bodies containing replication-associated proteins (virus replication complexes [VRCs]) upon infection. To identify host proteins that interact with individual viral components of VRCs or VRCs in toto, we isolated viral replicase- and VRC-enriched fractions from TMV-infected Nicotiana tabacum plants. Two host proteins in enriched fractions, ATP-synthase γ-subunit (AtpC) and Rubisco activase (RCA) were identified by matrix-assisted laser-desorption ionization time-of-flight mass spectrometry or liquid chromatography-tandem mass spectrometry. Through pull-down analysis, RCA bound predominantly to the region between the methyltransferase and helicase domains of the TMV replicase. Tobamovirus, but not Cucumber mosaic virus or Potato virus X, infection of N. tabacum plants resulted in 50% reductions in Rca and AtpC messenger RNA levels. To investigate the role of these host proteins in TMV accumulation and plant defense, we used a Tobacco...