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Journal of Virology, September 2001, p. 8045-8053, Vol. 75, No. 17
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.17.8045-8053.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Conversion in the Requirement of Coat Protein in Cell-to-Cell
Movement Mediated by the Cucumber Mosaic Virus Movement
Protein
Hideaki
Nagano,
Kazuyuki
Mise,
Iwao
Furusawa, and
Tetsuro
Okuno*
Laboratory of Plant Pathology, Graduate
School of Agriculture, Kyoto University, Kyoto 606-8502, Japan
Received 5 March 2001/Accepted 29 May 2001
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ABSTRACT |
Plant viruses have movement protein (MP) gene(s) essential for
cell-to-cell movement in hosts. Cucumber mosaic
virus (CMV) requires its own coat protein (CP) in addition to the
MP for intercellular movement. Our present results using
variants of both CMV and a chimeric Brome mosaic virus with
the CMV MP gene revealed that CMV MP truncated in its C-terminal 33 amino acids has the ability to mediate viral movement independently of
CP. Coexpression of the intact and truncated CMV MPs extremely reduced
movement of the chimeric viruses, suggesting that these
heterogeneous CMV MPs function antagonistically. Sequential deletion
analyses of the CMV MP revealed that the dispensability of CP
occurred when the C-terminal deletion ranged between 31 and
36 amino acids and that shorter deletion impaired the ability of the MP
to promote viral movement. This is the first report that a region
of MP determines the requirement of CP in cell-to-cell movement
of a plant virus.
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INTRODUCTION |
Plant viruses encode proteins
that control their movement from cell to cell. These proteins are
called movement proteins (MPs) and interact with the normal symplastic
connections between plant cells, the plasmodesmata, by modifying the
plasmodesmal structure and function. Consequently, the highly regulated
passage of small molecules through plasmodesmata is altered to allow
the passage of large nucleoprotein complexes containing the viral
genome (8, 28).
Some viruses, including Tobacco mosaic virus (TMV) and
Red clover necrotic mosaic virus, do not require the viral
coat protein (CP) for cell-to-cell movement. The MPs of these viruses
have a nucleic acid binding activity (10, 37), and an
MP-RNA nucleoprotein complex is thought to pass through the modified
plasmodesmata to adjacent uninfected cells (8, 26). Other
viruses do not move from cell to cell in the absence of viral CP.
Cauliflower mosaic virus and Cowpea mosaic virus
are known to move as virus-like particles through tubules that pass
through plasmodesmata into neighboring cells. These tubules are
composed of MP (40, 49). Nepo-, Tospo-, and
Fabaviruses are also thought to move similarly with the
tubule-mediated mechanism. There are viruses that are considered to
move as a nucleoprotein complex different from virus particles despite
their requirement of viral CP for cell-to-cell movement. Cucumber
mosaic virus (CMV) is competent to induce tubules protruding from
infected protoplasts like the viruses that move as virus-like particles
(6). Nevertheless, no such tubules have been found in
planta by electron microscopy (3), and mutants incapable
of virion formation move successfully from cell to cell (22, 44,
46).
CMV is the type member of the genus Cucumovirus and
is one of the most common plant viruses of substantial agricultural
significance. CMV infects more than 1,000 species of plants, shrubs,
and trees and both monocots and dicots (41). The genomic
RNAs of CMV are designated as RNAs 1, 2, and 3, by diminishing size
(39). All the RNAs have a cap structure at the 5'
terminus. The 3' portion of all the RNAs is also highly conserved in
virus-specific manner and can form a tRNA-like structure that can be
aminoacylated with tyrosine. RNAs 1 and 2, encoding the 1a and 2a
proteins, respectively, are involved in viral replication (18,
36). CMV RNA 2 encodes a second protein, 2b, which is translated
from a subgenomic RNA, RNA 4A, and plays a role in systemic spread of
the virus and virulence determination, possibly by suppressing a host
RNA silencing mechanism (4, 14). RNA 3 encodes two
proteins dispensable for viral replication in protoplasts. The
5'-proximal open reading frame (ORF) on RNA 3 is for the 3a protein,
the MP of CMV (15). The 3'-proximal ORF is for the CP that
is translated from a subgenomic RNA 4 (5).
We have investigated viral cell-to-cell movement mediated by the CMV MP
using chimeric viruses derived from Brome mosaic virus (BMV), the type member of the genus Bromovirus. CMV and BMV
are distantly related (42) and show many similarities,
including the size and form of virus particles (24, 50),
genome organizations (1, 41), and the requirement of the
CP for cell-to-cell movement (7, 43). Our previous results
indicate that the wild-type (wt) CMV MP requires its cognate CP to
mediate cell-to-cell movement of the chimeric BMV genome
(34), while the CMV MP with a deletion of its C-terminal
33 amino acids is able to mediate the movement of the chimeric BMV
genome in the absence of the CMV CP (35). These suggest
that the truncated CMV MP is different from the wt one in the
requirement of viral CP. In this study, the difference in the CP
requirement is characterized and the antagonism between the wt and
truncated CMV MPs is tested. Based on the results, the role of CP in
the CMV MP-mediated viral cell-to-cell movement is discussed.
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MATERIALS AND METHODS |
cDNA clones.
Plasmids pBTF1, pBTF2, and pBTF3W contain the
full-length cDNAs of RNAs 1, 2, and 3, respectively, of the wt BMV (the
KU2 strain) (30, 31, 32). The plasmids pT7B3CKY3 and
pB3C3a247T contain the full-length cDNA of chimeric BMV RNA 3 with the
genes of wt and the C-terminal 33 amino acid-truncated CMV MP,
respectively (35). Plasmids pCY1-T7 and pCY2-T7 (generous
gifts from S. Kuwata, Meiji University, and M. Suzuki, Yokohama
National University) and plasmid pT7CKY3 contain the full-length cDNAs
of CMV-Y RNAs 1, 2, and 3, respectively (35, 46).
There is a SalI site in the 5'-proximal end of the CP ORF in
either BMV or CMV. Four bases (TCGA) within the SalI site
were duplicated by T4 DNA polymerase treatment after digestion with the
enzyme in order to make CP-defective variants of CMV RNA 3 and chimeric
BMV RNA 3.
The RNA 3 variants of chimeric BMV and CMV with various lengths of
C-terminal deletions of CMV MP were created by PCR-based
in vitro
mutagenesis (
20). A translational stop codon, TGA,
was
introduced at the appropriate positions in the subcloned 124-bp
region
between the two
HpaI sites in the CMV MP gene by using
synthetic oligonucleotides. After we confirmed that each nucleotide
substitution was successfully introduced without any undesired
mutations, we used the 124-bp
HpaI fragment to replace the
corresponding
region in pT7B3CKY3 or pT7CKY3. Variants with the
3-amino-acid
deletion from the CMV MP C terminus were created by the
mutagenesis
against the 566-bp region between the
NheI and
SalI sites in pT7B3CKY3
and pT7CKY3, since the codon
encoding the amino acid 277 is overlapped
with the 3'-proximal
HpaI site. The
SalI site exists at the
5'-proximal
end of the CP gene of either BMV or CMV as mentioned above.
After
we confirmed that the mutagenesis was successfully done, we used
the
HpaI-
SalI fragments with the stop codon (385 bp from the chimeric
BMV RNA 3 cDNA and 472 bp from the CMV RNA 3 cDNA)
to replace
the corresponding regions in pT7B3CKY3 and
pT7CKY3.
The chimeric BMV RNA 3 derivatives in which the CMV MP genes are in
tandem were created as follows. First, the BMV CP gene
in the
NsiI/
BlnI-introduced pBTF3W (
34) was
replaced with the
CMV MP gene from pCMP-NX (
35) as
described previously (
33)
to create pB3(CPtoCMP). The
BglII/
EcoRI fragments of pT7B3CKY3
and pB3C3a247T
were replaced with the corresponding fragment containing
the CMV MP
gene from pB3(CPtoCMP). The resulting plasmids were
designated
pB3(Cmp/Cmp) and pB3(CmpDC33/Cmp), respectively. On
the other
hand, the 124-bp
HpaI fragment in pB3(CPtoCMP) was
replaced
with that from pB3C3a247T to create pB3(CPtoCMPDC33). The
BglII/
EcoRI
fragments of pT7B3CKY3 and pB3C3a247T
were replaced with the corresponding
fragment containing the CMV MP
gene with mutation from pB3(CPtoCMPDC33).
The resulting
plasmids were designated pB3(Cmp/CmpDC33) and
pB3(CmpDC33/CmpDC33),
respectively.
Inoculation of plants and protoplasts.
Chenopodium
quinoa plants and protoplasts were inoculated with in vitro
transcripts synthesized from the plasmids by T7 RNA polymerase after
linearization with appropriate restriction endonuclease as previously
described (34). In all cases, each inoculum contained an
RNA 3 variant of CMV or chimeric BMV, together with its cognate RNAs 1 and 2. Inoculation onto Nicotiana benthamiana plants was done as described elsewhere (16).
Analysis of RNA and protein.
Northern, tissue-printing, and
press blot hybridizations were done as described previously
(35). Probes used to detect BMV RNAs (21) and
CMV RNAs (35) were as described previously. The
32P radioactive signals on the membrane were quantified
with a digital radioactive imaging analyzer (Fujix BAS 2000; Fuji Photo Film).
Electrophoresis and immunodetection of proteins extracted from
protoplasts and plant tissues were done as described previously
(
34,
35). Polyclonal rabbit antiserum raised against BMV,
CMV (
35), or the CMV MP (a generous gift from P. Palukaitis
and I. B. Kaplan) was used as the first antibody. The
second antibody
used was alkaline phosphatase-conjugated goat
anti-rabbit immunoglobulin
G.
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RESULTS |
The CMV MP with a deletion of the C-terminal 33 amino acids do not
require CP to mediate viral cell-to-cell movement.
Our previous
results demonstrated that the wt CMV MP requires its cognate CP to
mediate viral cell-to-cell movement (34). However, a
chimeric BMV containing the gene of CMV MP from which the C-terminal 33 amino acids are deleted (
C33-CMV MP) can move from cell to cell,
although this chimeric virus expresses the BMV CP instead of the CMV CP
(35). Also, a CMV variant with the C33-CMV MP gene can
move from cell to cell. Therefore, it was considered that viral
cell-to-cell movement was mediated by the C33-CMV MP independently
of or cooperatively with either BMV CP or CMV CP. We first tested
whether the BMV CP was required for the movement mediated by the
truncated CMV MP. The CP-defective variant of chimeric BMV with the
C33-CMV MP gene induced chlorotic lesions in inoculated C. quinoa leaves. The lesions were indistinguishable from lesions
induced by the CP-intact chimeric BMV with the C33-CMV MP gene (Fig.
1A). Distribution of viral RNA in these
leaves was analyzed by the press blot method. Although the size and
number of visible lesions were comparable between the two chimeric
viruses with the C33-CMV MP gene (Fig. 1A and data not shown), the
CP-defective virus accumulated viral RNA to lower level than the
CP-intact virus (Fig. 1B). This is probably due to the absence of RNA
protection by the BMV CP since the absence of CP resulted in
approximately 10-fold decrease of viral RNA accumulation in protoplasts
(Fig. 2). Immunoblot analysis with
anti-BMV antiserum confirmed that the intact BMV CP did not accumulate
either in the protoplasts or in the leaves inoculated with the
CP-defective virus (Fig. 3; data not
shown). The above results indicate that the C33-CMV MP functions in
cell-to-cell movement of the chimeric virus independently of the BMV
CP. On the other hand, a CP-defective variant, as well as a CP-intact
variant, of the chimeric BMV with the wt-CMV MP gene did not induce
lesions in the inoculated C. quinoa leaves (data not shown).
No viral RNA accumulation was detected in these leaves (Fig. 1B).
However, viral RNA accumulated in protoplasts infected by either
CP-intact or -defective variant to the level comparable to the
corresponding variants of the chimeric BMV with the C33-CMV MP gene
(Fig. 2). Thus, it was confirmed that the wt-CMV MP alone does not
function in cell-to-cell movement of the chimeric BMV genome.
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FIG. 1.
The ability of wt- and C33-CMV MPs to mediate
cell-to-cell movement of chimeric BMV with or without expression of BMV
CP in C. quinoa leaves. (A) Symptom induced by the chimeric
BMV variants with the gene of C33-CMV MP in the presence (+) or the
absence ( ) of BMV CP expression at 7 days p.i. (B) Press blotting
analysis of C. quinoa leaves inoculated with chimeric BMV
variants at 7 days p.i. Viral RNA was detected by using a probe
specific for the conserved 3' sequence of BMV RNAs. wt and C33
denote the chimeric BMV variants harboring the corresponding MP gene. + and denote the variants that expressed and did not express BMV CP,
respectively.
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FIG. 2.
Northern hybridization analysis of C. quinoa
protoplasts inoculated with the chimeric BMV variants using a probe
specific for the conserved 3' sequence of BMV RNAs. Total RNA was
extracted at 24 hours p.i. and analyzed. The positions of the chimeric
BMV genomic and subgenomic RNAs are indicated on the right. M, mock.
For other symbols, refer to the legend of Fig. 1.
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FIG. 3.
Immunodetection of the CP of BMV and of CMV in infected
C. quinoa protoplasts at 24 hours p.i. BMV and CMV denote
the genomic background of RNA3 from which CMV MP was expressed. The
positions of the CPs of CMV and BMV are indicated on the right. For
other symbols, refer to the legend of Fig. 1.
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Next, to investigate whether the
C33-CMV MP requires CMV CP in CMV
movement, a frameshift mutation was introduced into the
CP gene of a
CMV variant harboring the
C33-CMV MP gene that is
able to move from
cell to cell (
35). The CP-defective CMV variant
with the
C33-CMV MP gene induced necrotic lesions on the inoculated
leaves
(Fig.
4A). The size of lesions induced by
the CP-defective
variant was slightly larger than that by the CP-intact
variant;
the former was approximately 0.5 to 1.3 mm and the latter was
0.3 to 0.7 mm in diameter at 7 days postinoculation (p.i.). Viral
RNA
in these leaves was detected by press-blot analysis (Fig.
4B). On the
other hand, when the same frameshift mutation was
introduced into the
CP gene of wt-CMV, the CP-defective CMV did
not move from cell to cell
(Fig.
4B) as reported previously (
7,
46). Immunoblot
analysis with anti-CMV antiserum confirmed that
no intact CMV CP
accumulated in the protoplasts inoculated with
these CP-defective
variants (Fig.
3). The results demonstrated
that CMV CP was dispensable
for cell-to-cell movement of the CMV
variant with
C33-CMV MP gene.
The CP-defective variant accumulated
viral RNA in infected
C. quinoa protoplasts, although the accumulation
level was lower than
from the variant with the intact CP gene
(Fig.
5). Further, the CP-intact or the
CP-defective variant of
CMV with the
C33-CMV MP gene was tested for
the ability to systemically
infect a host by analyzing viral RNA
distribution in
N. benthamiana plants with the
tissue-printing hybridization technique. The CP-intact
variant
systemically infected the plants while the infection by
the
CP-defective variant was limited to the inoculated leaves
(data not
shown), indicating that the
C33-CMV MP is able to mediate
viral
systemic movement, while the CP is necessary for the systemic
but not
for the cell-to-cell movement.
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FIG. 4.
The ability of wt- and C33-CMV MPs to mediate
cell-to-cell movement of CMV with or without expression of CP in
C. quinoa leaves. (A) Symptom induced by the CMV variants
with the C33-MP gene in the presence (+) or the absence () of CP
expression at 7 days p.i. (B) Press blotting analysis of C. quinoa leaves inoculated with CMV variants at 7 days p.i. Viral
RNA was detected by using a probe specific for the conserved 3'
sequence of CMV RNAs. For other symbols, refer to the legend of Fig.
1.
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FIG. 5.
Northern hybridization analysis of C. quinoa
protoplasts inoculated with the CMV variants using a probe specific for
the conserved 3' sequence of CMV RNAs. Total RNA was extracted at 24 hours p.i. and analyzed. Positions of CMV genomic and subgenomic
RNAs are indicated on the right. The bands with no indication
are likely RNA 4A. M, mock. For other symbols,
refer to the legend of Fig. 1.
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Antagonism between the C33- and wt-CMV MPs.
To test whether
the C33-CMV MP is antagonistic to the wt-CMV MP, chimeric BMV RNA3
variants with two MP genes, each in the position of the MP and CP ORFs,
were constructed so that the variants could express both wt and
C33-CMV MPs from either the MP or the CP ORF of the viral genome
(Fig. 6B and C). Similar variants having two copies of the wt or the C33-CMV MP gene were also constructed as
controls (Fig. 6A and D). The resulting four variants were tested for
their ability to move from cell to cell in C. quinoa leaves.
If the antagonism occurred between the two MPs, the movement of the
chimeric viruses with the heterogeneous CMV MP genes should be
suppressed. We repeated these experiments three times with four
inoculated leaves in every experiment, and highly reproducible results
were obtained. One of the chimeric BMV variants in which the C33-CMV
MP and wt- CMV MP genes lay at the position of MP and CP genes,
respectively, induced two to six lesions in every inoculated leaf (Fig.
6C). The other chimeric BMV variant in which the two CMV MP genes lay
at the reverse position induced no symptoms (Fig. 6B). On the other
hand, a chimeric BMV variant with two C33-CMV MP genes induced more
than 50 lesions in every inoculated leaf, while another chimeric BMV
variant with two wt-CMV MP genes induced no symptoms (Fig. 6A and D).
Since a visible local lesion requires infection of many cells by
invading virus (43), the symptomatic results are most
likely to reflect the ability of the variants to move from cell to
cell, although we failed to detect viral RNA accumulation in these
infected leaves by press blot hybridization (data not shown). Thus,
these results suggest that viral movement is strongly suppressed by
coexpression of wt- and C33-CMV MPs. Similar level of replication of
the variants and the translation of MPs from the replaced ORFs were
confirmed by protoplast infection (Fig.
7). Therefore, we concluded that the
antagonism occurred between the wt- and C33-CMV MPs.
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FIG. 6.
Symptoms on C. quinoa leaves inoculated with
the chimeric BMV variants with two CMV MP genes in RNA 3. Photographs
were taken at 7 days p.i. The combinations of the CMV MPs in the
inoculated chimeric RNA 3's are wt-wt (A), wt-C33 (B), C33-wt
(C), and C33-C33 (D), respectively. Schematic diagrams of the
inocula are shown above the photographs. Lines, noncoding regions
derived from BMV RNA 3. Open boxes, wt-CMV MP gene; boxes with closed
area, C33-CMV MP gene.
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FIG. 7.
Protoplast infection of the chimeric BMV variants with
two CMV MP genes in RNA 3. (A) Northern hybridization analysis at 24 hours p.i. using a probe specific for the conserved 3' sequence of BMV
RNAs. Positions of the chimeric BMV genomic and subgenomic RNAs are
indicated on the right. Since these variants have no CP gene, strong
signals near the bottom in each lane are considered as degraded viral
RNA. (B) Immunodetection of the wt- and C33-CMV MP at 24 h p.i.
Positions of those proteins are indicated on the right. The
combinations of CMV MP genes in the chimeric RNA 3s are wt-wt (lane 1),
wt-C33 (lane 2), C33-wt (lane 3), and C33-C33 (lane 4). For
easy visualization of these inocula, see the schematic diagrams in Fig.
6. M, mock. For symbols, refer to the legend of Fig. 1.
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The translation products from RNA 4 accumulated to a higher level than
those from RNA 3 in protoplasts infected with the variants
having the
heterogeneous set of CMV MP genes (Fig.
7B, lanes 2
and 3). The
difference in the ability to induce lesions between
the variants having
the heterogeneous set of CMV MP genes might
be due to the timing lag of
protein expression. To test this possibility,
the accumulation kinetics
of the MPs was examined in infected
protoplasts every hour. MPs
translated from RNA 3 or RNA 4 were
detectable at 8 h p.i. and
later (data not shown). We, thus, failed
to detect difference in the
timing of translation due to the genetic
position of the two MP
genes.
Mapping of the domain involved in the CP requirement for viral
cell-to-cell movement.
The C-terminal 33-amino-acid region of CMV
MP was predicted to be divided into three parts based on the analysis
by the method of Chou and Fasman (9) (data not shown).
From the prediction, a stop codon was introduced into the CMV MP gene
in both CMV RNA 3 and the chimeric BMV RNA 3 with the CMV MP gene to
create RNA 3 derivatives that express truncated CMV MP with deletions
of 10, 19, and 25 amino acids from its C terminus. Northern
hybridization analysis of infected protoplasts revealed that these
variants accumulated progeny RNAs in C. quinoa protoplasts
(data not shown). However, when inoculated onto C. quinoa plants, neither CMV nor the chimeric BMV variants induced
local lesions (Table 1). No accumulation
of viral RNA was detected in these leaves by press blotting
hybridization analyses (Table 1). The results did not change even when
the concentration of these inocula increased up to threefold (data not
shown). The failure of the CMV variants, as well as of the chimeric BMV
variants, to move from cell to cell suggests that the C-terminal
deletions of 10, 19, and 25 amino acids abolish the ability of the CMV
MP to mediate viral cell-to-cell movement, although the C33-CMV MP
promotes the movement.
To delimit the CMV MP regions involved in virus movement, more CMV
variants with various sizes of the C-terminal deletion
in the CMV MP
were created (Table
1). These variants all replicated
similarly in
C. quinoa protoplasts (data not shown). The ability
of the
variants to move from cell to cell and to induce local
lesions is
summarized in Table
1. In short, CMV variants moved
from cell to cell
if the C-terminal deletion in CMV MP was from
33 to 36 amino acids,
although the degrees of movement were distinctive.
When 31 or 32 amino
acids were deleted, a few local lesions were
occasionally induced in
the inoculated leaves, although viral
RNA was not detected by press
blotting analysis. Longer and shorter
C-terminal deletions abolished
viral movement. It is noteworthy
that the function of CMV MP to mediate
viral cell-to-cell movement
was abolished when only three amino acids
were deleted from its
C terminus. A movement-incapable CMV variant with
the C-terminal
deletion of 43 amino acids corresponds to a CMV mutant
that infects
tobacco plants systemically (
23). To test
this, a CMV variant
was created by the manner identical to that for
Kaplan's mutant.
This variant, however, did not move from cell to cell
and did
not induce any symptom in
C. quinoa plants (data not
shown).
The ability of the CMV MP with the various sizes of C-terminal deletion
to mediate cell-to-cell movement was also tested in
chimeric BMV. As
with CMV variants, the chimeric BMV variants
with the gene of truncated
CMV MP moved from cell to cell and
induced local lesions in the
inoculated leaves when the C-terminal
deletion was from 33 to 36 amino
acids, although the degrees of
movement were distinctive (Table
1). In
contrast to the case
of CMV, however, the chimeric BMV with a deletion
of either 31
or 32 amino acids in the CMV MP C terminus induced no
symptom,
but press blotting analyses of the inoculated leaves showed
accumulation
and unusual distribution of viral RNA. The shape of RNA
signals
reproducibly looked like a trail of a comet (data not shown).
The difference in the shape of signals should reflect the difference
in
the localization of virus RNA. Further studies are required
to
determine the distribution of these variants. The chimeric
BMV variants
competent for cell-to-cell movement had the CP gene
of BMV but not of
CMV, suggesting that the CMV MP with C-terminal
deletion ranging from
31 to 36 amino acids can promote viral cell-to-cell
movement
independently of viral CP. The independence from CP of
viral movement
mediated by the CMV MP with those C-terminal deletions
was further
confirmed by the ability of the CP-defective CMV variants
to move from
cell to cell and to induce lesions in the inoculated
leaves (Table
2). Although viral RNA was not detected
in the
leaves inoculated with the CP-defective CMV variants having a
deletion of 31 or 32 amino acids in the C terminus of the MP,
local
lesions with pinpoint size were induced on the inoculated
leaves (data
not shown).
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DISCUSSION |
This study demonstrates that the CMV MP truncated in its C
terminus can promote viral cell-to-cell movement independently of CP.
The CP-independent viral movement occurs when the deletion length was
within 31 to 36 amino acids. To our knowledge, this is the first report
to show a region of MP that determines the requirement of CP in
cell-to-cell movement of a plant virus.
The functions of CMV MP have been compared with those of TMV MP, the
best-characterized virus MP. The two MPs share the abilities to (i)
traffic through plasmodesmata (19, 48), (ii) increase plasmodesmal size exclusion limit (15, 48), (iii) bind
single-stranded nucleic acids in vitro (10, 27), and (iv)
complement their respective movement-deficient mutants (13,
23). In contrast to these similarities, CMV MP cannot promote
viral cell-to-cell movement without its cognate CP, although TMV MP
can. Replacement of both MP and CP genes is required to make a
movement-competent chimeric virus with wt-CMV MP gene
(34). In contrast, movement-competent chimeric viruses can
be made by replacing the MP gene with that of TMV in dianthovirus and
hordeivirus (17, 45). In addition, CMV MP expressed in
transgenic plants cannot promote a movement-defective variant of TMV
(12). These indicate that the wt-CMV MP lacks one or more
functions in the absence of the CMV CP compared with the TMV MP.
As shown in this study, CMV MP comes to promote cell-to-cell movement
of CMV and chimeric BMV independently of viral CP by deletion of the C
terminus. This suggests that the truncated CMV MP is comparable to TMV
MP in the independence of CP in movement function. However, the
C-terminal region of the MP is conserved among all strains of CMV whose
sequences have been published to date in the GeneBank, EMBL, and DDBJ
databases. This suggests that the C-terminal region has a biological
significance necessary for the CMV life cycle. Indeed, a CMV variant
with C33-CMV MP gene does not move as efficiently as wt-CMV
(35).
On the other hand, we have reported that a chimeric BMV with the
C33-CMV MP gene moves efficiently to induce chlorotic lesions comparably to wt BMV in their size and number (34) and
that another chimeric BMV with both the CMV MP and CP genes moves less efficiently than wt BMV (35). In addition, when the BMV MP
and CP genes were replaced with the C33-CMV MP and CMV CP genes, respectively, the resulting chimeric BMV moved more efficiently than
the chimeric BMV with wt-CMV MP and CMV CP (unpublished results). These
results indicate that C33-CMV MP can promote more
cell-to-cell movement of the chimeric BMV genome than CMV movement
equipment composed of wt-CMV MP and CP. Therefore, the two kinds of CMV equipment for cell-to-cell movement different in regard to the involvement of the CP show different specialties with respect to the
genomes of CMV and chimeric BMV.
It is known that a nonfunctional MP expressed in transgenic plants
confers resistance to multiple viruses by inhibiting their cell-to-cell
movement (2, 11, 25, 29). The inhibitory effect on virus
movement has been considered due to antagonism between competent and
incompetent MPs. The chimeric BMV variants containing both wt- and
C33-CMV MP genes were remarkably inferior in cell-to-cell movement
to the variant containing two C33-CMV MP genes. This suggests
antagonism between wt- and C33-CMV MPs. Therefore, it is most likely
that these MPs share common functions, although the wt-CMV MP is
dominant negative in the absence of the CMV CP.
Sequential deletion analysis of the CMV MP C terminus revealed that the
CMV MPs with truncation ranging from 31 to 36 amino acids are able to
promote viral movement independently of viral CP. The wt-CMV MP is also
able to promote viral movement in the presence of the CMV CP. However,
the C-terminal deletion of fewer than 31 amino acids abolishes the
ability of the CMV MP to mediate viral movement even in the presence of
the CMV CP. These results indicate that the CP requirement in
cell-to-cell movement of CMV is conferred by the C terminus of the MP
and, further, that the participation of the CP in cell-to-cell movement
is regulated in a highly complicated manner. A similar complex
relationship between the size of C-terminal deletion and the competence
of the MP to promote viral movement has been observed in the MP of Cowpea chlorotic mottle virus, a member of the genus
Bromovirus (38). The existence of CP affects
the movement, although this virus does not require the CP for
cell-to-cell movement. The complicated results from the sequential
deletion analysis may suggest that the C terminus of MP of these
viruses affects the conformation of the protein.
Deletion of the C-terminal three amino acids in CMV MP is sufficient to
impair viral movement. This suggests that the full-length C terminus is
required to mediate viral cell-to-cell movement in a movement mechanism
supported with CMV CP. Similarly, the MP of Alfalfa mosaic
virus (AlMV), a member of the genus Alfamovirus belonging to the family Bromoviridae, is rendered
nonfunctional by a deletion of the C-terminal three amino acids
(47). AlMV is considered to move as virus-like particles
via tubular structure, and a similar C-terminal deletion interfered
with tubule formation by the MP (51). While the CMV MP
also has an ability to induce tubules on the surface of infected
protoplasts, a mutation impairing the ability to assemble tubules does
not affect the systemic spread of CMV in tobacco and N. benthamiana (6). Therefore, although it is uncertain
whether the C-terminal deletion of the CMV MP impairs the ability for
the tubule formation, it is not likely that the impaired ability to
assemble tubules affects the local spread mediated by the CMV MP.
Our results reveal that the C-terminal deletion more than 37 amino
acids impairs the ability of the CMV MP to promote viral movement as
well as local lesion induction. Kaplan et al. (23) have
reported a CMV mutant with the C-terminal deletion of 43 amino acids in
the MP that infects tobacco systemically. The mutation was maintained
in the progeny virus in the systemically infected leaves. To the
contrary, our corresponding variant of CMV constructed identically with
the previous report of Kaplan et al. (23) did not move
from cell to cell. The reason for the different results is not clear,
although the CMV strains used in these studies are not identical. Since
a variant of chimeric BMV with the gene of the CMV MP truncated in its
C-terminal 43 amino acids is also unable to move from cell to cell,
1-amino-acid difference in the sequence of the truncated CMV MP might
cause the different results. Alternatively, there might be a
second-site mutation in the movement-competent CMV mutant.
Coexistence of the CMV CP with the CMV MP can mediate the cell-to-cell
movement of heterogeneous as well as homogeneous viral genomes
(34). As discussed above, the wt-CMV MP alone is
considered nonfunctional. However, it is suggested that the MP itself
and/or the putative MP-viral RNA complex are altered by the existence of the CP, although the mechanism remains unclear. A likely possibility is that the CMV CP interacts with the wt-CMV MP. The interaction might
be mediated by the C terminus of the wt-CMV MP. However, our
preliminary study on the interaction between these proteins in vitro
failed to detect the binding of CP to the C terminus of the CMV MP
(unpublished data). Further experiments are needed to clarify how the
CP is involved in CMV movement.
Since a positive correlation has been seen between viral movement
and the induction of local lesions in C. quinoa leaves, the
lesions appearing on the leaves should reflect viral cell-to-cell movement and amplification (references 34, 35, and 43 and the present study). The local lesions also appear on the leaves inoculated with either CMV or chimeric BMV variants that did not express viral CP (Fig. 1, 4, and 7). This indicates that the CPs of BMV
and CMV are dispensable for local lesion induction in C. quinoa. Similar observations have been reported in necrotic
reaction in C. amalanticolor, in which viral movement from
initially infected epidermal cells, and not the simultaneous expression
of the MP and the CP of CMV in the cells, is required for the induction of cell death (6).
| |
ACKNOWLEDGMENTS |
We are grateful to Sigeru Kuwata (Meiji University) and Masashi
Suzuki (Yokohama National University) for the infectious clones of
CMV-Y and to Peter Palukaitis (Scottish Crop Research Institute) and
Igor Boris Kaplan (Cornell University) for antiserum for CMV MP.
This work was supported in part by a Grant-in-Aid (12052201) for
Scientific Research on Priority Area (A) and a Grant in-Aid (09NP1501)
for Creative Basic Research from the Ministry of Education, Culture,
Sports, Science and Technology, Japan, and a Grant-in-Aid (JSPS-RFTF96L00603) from the Research for the Future program of the
Japan Society for the Promotion of Science. H.N. was supported by
Research Fellowships of the Japan Society for the Promotion of Science
for Young Scientists.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Plant Pathology, Graduate School of Agriculture, Kyoto University,
Sakyo-Ku, Kitashirakawa-Oiwakecho, Kyoto 606-8502, Japan. Phone:
81-75-753-6131. Fax: 81-75-753-6131. E-mail:
okuno{at}kais.kyoto-u.ac.jp.
Present address: Virus Disease Laboratory, Department of Plant
Pathology, National Agricultural Research Center, Tsukuba, Ibaraki
305-8666, Japan.
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Journal of Virology, September 2001, p. 8045-8053, Vol. 75, No. 17
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.17.8045-8053.2001
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Top
Abstract
Introduction
