Abstract
Recently,
it has become evident that nucleolar passage of movement proteins
occurs commonly in a number of plant RNA viruses that replicate in the
cytoplasm. Systemic movement of Potato mop-top virus (PMTV) involves two
viral transport forms represented by a complex of viral RNA and TRIPLE
GENE BLOCK1 (TGB1) movement protein and by polar virions that contain
the minor coat protein and TGB1 attached to one extremity. The integrity
of polar virions ensures the efficient movement of RNA-CP, which
encodes the virus coat protein. Here, we report the involvement of
nuclear transport receptors belonging to the importin-α family in
nucleolar accumulation of the PMTV TGB1 protein and, subsequently, in
the systemic movement of the virus. Virus-induced gene silencing of two
importin-α paralogs in Nicotiana benthamiana resulted in significant
reduction of TGB1 accumulation in the nucleus, decreasing the
accumulation of the virus progeny in upper leaves and the loss of
systemic movement of RNA-CP. PMTV TGB1 interacted with importin-α in N.
benthamiana, which was detected by bimolecular fluorescence
complementation in the nucleoplasm and nucleolus. The interaction was
mediated by two nucleolar localization signals identified by
bioinformatics and mutagenesis in the TGB1 amino-terminal domain. Our
results showed that while TGB1 self-interaction is needed for
cell-to-cell movement, importin-α-mediated nucleolar targeting of TGB1
is an essential step in establishing the efficient systemic infection of
the entire plant. These results enabled the identification of two
separate domains in TGB1: an internal domain required for TGB1
self-interaction and cell-to-cell movement and the amino-terminal domain
required for importin-α interaction in plants, nucleolar targeting, and
long-distance movement.Recently, it has become evident that nucleolar passage of movement
proteins occurs commonly in a number of plant RNA viruses that replicate
in the cytoplasm. Systemic movement of Potato mop-top virus (PMTV)
involves two viral transport forms represented by a complex of viral
RNA and TRIPLE GENE BLOCK1 (TGB1) movement protein and by polar virions
that contain the minor coat protein and TGB1 attached to one extremity.
The integrity of polar virions ensures the efficient movement of RNA-CP,
which encodes the virus coat protein. Here, we report the involvement
of nuclear transport receptors belonging to the importin-α family in
nucleolar accumulation of the PMTV
TGB1 protein and, subsequently, in the systemic movement of the virus.
Virus-induced gene silencing of two importin-α paralogs in Nicotiana benthamiana
resulted in significant reduction of TGB1 accumulation in the nucleus,
decreasing the accumulation of the virus progeny in upper leaves and the
loss of systemic movement of RNA-CP. PMTV TGB1 interacted with importin-α in N. benthamiana,
which was detected by bimolecular fluorescence complementation in the
nucleoplasm and nucleolus. The interaction was mediated by two nucleolar
localization signals identified by bioinformatics and mutagenesis in
the TGB1 amino-terminal domain. Our results showed that while TGB1
self-interaction is needed for cell-to-cell movement,
importin-α-mediated nucleolar targeting of TGB1 is an essential step in
establishing the efficient systemic infection of the entire plant. These
results enabled the identification of two separate domains in TGB1: an
internal domain required for TGB1 self-interaction and cell-to-cell
movement and the amino-terminal domain required for importin-α
interaction in plants, nucleolar targeting, and long-distance movement.
Original language | English |
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Pages (from-to) | 738-752 |
Number of pages | 15 |
Journal | Plant Physiology |
Volume | 167 |
Issue number | 3 |
Early online date | 27 Feb 2015 |
DOIs | |
Publication status | Published - Mar 2015 |
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Dive into the research topics of 'Importin-α-mediated nucleolar localization of potato mop-top virus TRIPLE GENE BLOCK1 (TGB1) protein facilitates virus systemic movement, whereas TGB1 self-interaction is required for cell-to-cell movement in Nicotiana benthamiana'. Together they form a unique fingerprint.Profiles
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Jens Tilsner
Person: Academic
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Lesley Torrance
- School of Biology - Emeritus Professor
- Biomedical Sciences Research Complex
Person: Emeritus Professor