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Journal of Virology, April 2001, p. 3207-3219, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3207-3219.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Brome Mosaic Virus Protein 1a Recruits Viral RNA2
to RNA Replication through a 5' Proximal RNA2 Signal
Jianbo
Chen,1
Amine
Noueiry,1 and
Paul
Ahlquist1,2,*
Institute for Molecular
Virology1 and Howard Hughes Medical
Institute,2 University of
Wisconsin
Madison, Madison, Wisconsin 53706
Received 10 October 2000/Accepted 27 December 2000
 |
ABSTRACT |
Brome mosaic virus (BMV), a positive-strand RNA virus in the
alphavirus-like superfamily, encodes two RNA replication factors. Membrane-associated 1a protein contains a helicase-like domain and RNA
capping functions. 2a, which is targeted to membranes by 1a, contains a
central polymerase-like domain. In the absence of 2a and RNA
replication, 1a acts through an intergenic replication signal in BMV
genomic RNA3 to stabilize RNA3 and induce RNA3 to associate with
cellular membrane. Multiple results imply that 1a-induced RNA3
stabilization reflects interactions involved in recruiting RNA3
templates into replication. To determine if 1a had similar effects on
another BMV RNA replication template, we constructed a plasmid
expressing BMV genomic RNA2 in vivo. In vivo-expressed RNA2 templates
were replicated upon expression of 1a and 2a. In the absence of 2a, 1a
stabilized RNA2 and induced RNA2 to associate with membrane. Deletion
analysis demonstrated that 1a-induced membrane association of RNA2 was
mediated by sequences in the 5'-proximal third of RNA2. The RNA2 5'
untranslated region was sufficient to confer 1a-induced membrane
association on a nonviral RNA. However, sequences in the N-terminal
region of the 2a open reading frame enhanced 1a responsiveness of RNA2
and a chimeric RNA. A 5'-terminal RNA2 stem-loop important for RNA2 replication was essential for 1a-induced membrane association of RNA2
and, like the 1a-responsive RNA3 intergenic region, contained a
required box B motif corresponding to the T
C stem-loop of host tRNAs. The level of 1a-induced membrane association of various RNA2
mutants correlated well with their abilities to serve as replication
templates. These results support and expand the conclusion that
1a-induced BMV RNA stabilization and membrane association reflect
early, 1a-mediated steps in viral RNA replication.
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INTRODUCTION |
During infection, the genomic RNAs
of positive-strand RNA viruses first must be translated to generate RNA
replication factor(s) and other proteins and then must serve as
templates for negative-strand RNA synthesis. One complication of these
dual template functions is the ability of 5'-to-3' processive ribosomes
to block negative-strand RNA synthesis by 3'-to-5' processive
polymerase (11, 20). Therefore, positive-strand RNA
viruses must have evolved mechanisms to regulate the alternate template
functions of genomic RNA, including mechanisms to clear ribosomes from
the RNA and allow transfer of the RNA template from translation to RNA
replication (20, 25).
Brome mosaic virus (BMV), a member of the alphavirus-like superfamily
of positive-strand RNA viruses, has three genomic RNAs with 5' caps and
tRNA-like 3' ends (1, 51). RNA1 and RNA2 encode
nonstructural proteins 1a and 2a, respectively, which direct RNA
replication and contain domains conserved with other superfamily members (4, 19, 25). 1a contains an N-terminal domain with m7G methyltransferase and covalent GTP binding activities
implicated in viral RNA capping (3, 30) and a C-terminal
domain with all motifs of DEAD box RNA helicases (22). The
central portion of 2a is similar to that of RNA-dependent RNA
polymerases (9). 1a localizes to endoplasmic reticulum
(ER) membranes in the absence of other viral factors (47).
2a is distributed throughout the cytoplasm when expressed alone but
localizes to ER membranes by interacting with 1a (14). The
ER sites where 1a and 2a colocalize are the sites of BMV RNA synthesis
(46, 47).
RNA3 encodes the 3a cell-to-cell movement protein and the coat protein.
Both are required for systemic infection of BMV's natural plant hosts
but are dispensable for RNA replication (5, 36, 48). The
3' proximal coat gene is translated from a subgenomic mRNA, RNA4,
produced from the negative-strand RNA3 replication intermediate. RNA3
replication and subgenomic RNA synthesis depend on
cis-acting signals in the RNA3 5', 3', and intergenic
untranslated regions (UTRs) (17, 18, 32, 35). The
intergenic region contains two overlapping cis signals: the
subgenomic mRNA promoter (17) and an approximately
150-nucleotide (nt) replication enhancer, whose deletion reduces RNA3
negative-strand synthesis and replication in vivo approximately
100-fold (18, 44).
In Saccharomyces cerevisiae expressing BMV 1a and 2a, RNA3
is replicated and synthesizes subgenomic RNA4, reproducing all known
features of RNA3 replication in plant cells (24, 25, 44, 47,
50). In yeast expressing RNA3 and 1a but not 2a, RNA3 is not
replicated but its stability and accumulation increase dramatically
(25, 50). Multiple observations imply that 1a-induced RNA3
stabilization reflects interactions involved in recruiting RNA3 from
translation to RNA replication. Although 1a increases RNA3 stability
and accumulation, the additional RNA3 is translated poorly if at all
(25). Indeed, increased RNA3 stability may be a
consequence of the 1a-induced inhibition of RNA3 translation, since
many mRNAs are stabilized by inhibiting translation (40). 1a-induced RNA3 stabilization depends on the intergenic replication enhancer required for negative-strand synthesis in plant and yeast cells (50). Partial deletions in the enhancer cause
parallel decreases or increases in 1a-induced RNA3 stabilization and
1a- and 2a-dependent negative- and positive-strand RNA3 production (50). Moreover, genetic exchanges show that 1a and the
intergenic replication enhancer are the major trans and
cis determinants of template specificity in BMV RNA3
replication (39, 53). The RNA3 replication enhancer
contains a box B motif that is conserved with the TC loop of tRNAs
and is essential for both 1a-induced RNA3 stabilization and RNA3
replication (33, 50). Highly conserved box B motifs are
also found in the 5' UTRs of BMV RNA1 and RNA2 (33, 34).
If, as these findings imply, 1a-induced RNA3 stabilization is related
to selecting RNA3 templates for replication rather than translation,
similar interactions might occur with the other BMV RNA replication
templates, genomic RNA1 and RNA2. To further test this model and the
roles of 1a in RNA replication, we have explored the interaction of 1a
and RNA2. Here we show that BMV RNA2 is also replicated in yeast upon
expression of 1a and 2a and that 1a stabilizes RNA2 in vivo
independently of 2a and RNA replication. We also have identified RNA2
cis-acting sequences required for 1a responsiveness, shown
that these 5' proximal sequences are sufficient to make a nonviral RNA
1a responsive and found that these sequences also are required for RNA2
replication. As for RNA3, 1a responsiveness of RNA2 depends on a
conserved box B motif and flanking sequences.
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MATERIALS AND METHODS |
Yeast strain and cell growth.
Yeast strain YPH500
(MAT
ura3-52 lys2-801 ade2-101 trp1-
63 his3-200
leu2-1) was used throughout. Yeast cultures were grown at
30°C in defined synthetic medium containing either 2% glucose or 2%
galactose as indicated and lacking relevant amino acids to maintain
selection for any DNA plasmids presents (10).
Plasmids and plasmid constructions.
Standard procedures were
used for all DNA manipulations (49). DNA fragments
generated by PCR were confirmed by DNA sequencing, and the overall
structures of all plasmids were confirmed by restriction analysis.
Laboratory designations for plasmids are given in parentheses if
different from plasmid names used in this report.
BMV 1a was expressed from pB1CT19 (26), a 2µm plasmid
containing the HIS3 selectable marker gene and 1a open
reading frame (ORF) flanked by the yeast ADH1 promoter and
ADH1 polyadenylation site. In some experiments, BMV 2a was
supplied in trans from pB2YT1 (generously provided by M. Ishikawa), a derivative of centromeric plasmid Ycplac22
(21) containing the TRP1 selectable marker and
2a ORF flanked by the yeast GAL1 promoter and
ADH1 polyadenylation site. BMV RNA3 was expressed from
pB3RQ39 (24), a centromeric plasmid containing the
TRP1 selectable marker and an RNA3 cDNA flanked by the
GAL1 promoter and a self-cleaving hepatitis delta virus ribozyme.
RNA2 was expressed from pB2 (pB2NR3), a centromeric plasmid containing
the
LEU2 selectable marker and a full-length RNA2 cDNA
flanked by the yeast
GAL1 promoter and a self-cleaving
hepatitis
delta virus ribozyme. To construct pB2, RNA2 nt 1 to 884 were
amplified by PCR from pB2TP5 (
27), using a 5' primer that
fused
TAAAGTAC to the 5' end of RNA2 cDNA (GTA ...),
creating a
SnaBI
site (TACGTA). The
SnaBI-
PflMI fragment from the PCR product and
the
PflMI-
BsmI fragment from pB2TP5 were used
collectively to
replace the
SnaBI-
BsmI RNA3
region in pB3RQ39, thus fusing the
GAL1 promoter, RNA2 cDNA,
and ribozyme. In the resulting plasmid,
pB2NR2, a portion of the
200-nt, tRNA-like 3' end conserved on
all BMV genomic RNAs was derived
from RNA3. This region contained
a single nucleotide substitution from
RNA2, but this substitution
has no effect on RNA2 replication
(
45). To obtain the promoter-cDNA-ribozyme
cassette in a
plasmid with the
LEU2 selectable marker, the
EcoRI-
PstI
fragment of pB2NR2 then was
transferred to Ycplac111 (
21), yielding
pB2.
pB2
GDD (pB2NR3
GDD) is a pB2 derivative with RNA2 nt 1772 to 1780 deleted by two-step PCR (57). pB2fs1 (pB2NR3-M1) and
pB2fs2
(pB2NR3-M2) are pB2 derivatives with 2- and 4-nt insertions,
respectively,
at nt 113 and 886. To make pB2fs1, pB2NR2 was digested
with
BstBI,
blunt ended with T4 DNA polymerase, and
religated to yield pB2NR2-M1.
The
EcoRI-
NcoI
fragment in pB2 was replaced with the corresponding
fragment from
pB2NR2-M1 to generate pB2fs1. pB2fs2 was made by
digesting pB2 with
NcoI, blunt ending with T4 DNA polymerase,
and
religating.
pB2
5' (pB2NR3-D1), pB2
M (pB2NR3-D3), and pB2
3' (pB2NR3-D4) are
the
SnaBI-
NcoI,
NcoI-
MluI,
and
MluI-
BsmI, respectively,
deletion derivatives
of
pB2.
pB2
5'-3 (pB2NR3-D20) and pB2
5'-4 (pB2NR3-D21) were made by PCR
amplification of RNA2 fragments corresponding to nt 175 to
890 and 334 to 890, respectively. The 5' PCR primers fused
GATC
TTCGAA,
containing a
BstBI site
(underlined), to nt 175 or 334 at the
5' end. The PCR products were
digested with
BstBI and
NcoI and
used to replace
the equivalent
BstBI-
NcoI fragment in pB2.
pB2
5'-5
(pB2NR3-D14) was made by PCR amplification of RNA2 fragments
corresponding
to nt 407 to 890 with the
BstBI
site-containing sequence GATC
TTCGAAA
added to
the 5' end. The PCR products were digested with
BstBI
and
NcoI and used to replace the equivalent
BstBI-
NcoI fragment
in pB2. Similarly, pB2
5'-6
(pB2NR3-D23), pB2
5'-7 (pB2NR3-D24),
and pB2
5'-8 (pB2NR3-D25) were
constructed by PCR amplification
of RNA2 fragments corresponding to nt
104 to 761, 104 to 641,
and 104 to 521, respectively, with the
NcoI site-containing sequence
CCATGGCTAG
fused to nt 761, 641, and 521, respectively, at the
3' end. The
PCR products were digested with
BstBI and
NcoI
and
used to replace the equivalent
BstBI-
NcoI
fragment in
pB2.
pB2
5'-9 (pB2NR3-D7) contains the deletion previously characterized
in pB2PT70 (
54). The
PflMI-
MluI
fragment from pB2PT70,
encompassing this deletion, was subcloned and
used to replace
the corresponding fragment in pB2NR2 to yield
pB2NR2-D5. The
EcoRI-
PstI
fragment of pB2NR2-D5
was then transferred to Ycplac111 to generate
pB2
5'-9. To make
pB2
5'-10 (pB2NR3-D6), pB2NR2 was digested with
PflMI and
NcoI, blunt ended with T4 DNA polymerase, and religated
to
generate pB2NR2-D4. The
EcoRI-
PstI fragment in
pB2NR2-D4 was
then transferred to Ycplac111 to generate pB2
5'-10.
Deletion and base substitution mutants pB2
5'-1 (pB2NR3
SL1),
pB2
5'-2 (pAON43), pB2SL1 (pAON50), pB2SL2 (pAON39), pB2SL3
(pAON51),
pB2SL4 (pAON38), pB2SL5 (pAON36), and pB2SL6 (pAON37)
were made by PCR
using 5' primers extending from the first nucleotide
of RNA2 through
and beyond the desired mutations and a common
3' primer complementary
to RNA2 sequences 871 to 890. PCR products
containing the desired
mutations then were digested with
NcoI
and used to replace
the
SnaBI-
NcoI fragment in
pB2.
pB2glo1 (pB2JC1) was made by replacing the
NcoI (blunt ended
with T4 DNA polymerase)-
BamHI fragment in pB2 with a
PstI (blunt
ended with T4 DNA polymerase)-
BamHI
fragment from pMS99 (
50)
containing a human
-globin ORF
and
ADH1 polyadenylation site.
To make pB2glo2 (pB2JC1-3),
pMS99 was digested with
BamHI and
HindIII,
blunt ended with T4 DNA polymerase, and religated to
remove a small
fragment containing a
PstI site downstream of the
ADH1 polyadenylation site to generate pMS99J. PCR then was
performed
using pB2 as the template to amplify a fragment corresponding
to the
GAL1 promoter and RNA2 5' UTR sequences.
EcoRI sequences
were engineered at the 5' end directly
upstream of the
GAL1 promoter,
and
PstI sequences
were engineered at the 3' end immediately downstream
of RNA2 5' UTR
sequences. This PCR-generated fragment was digested
with
EcoRI and
PstI and used to replace the
EcoRI-PstI fragment
in pMS99J to yield pB2glo2. pB2glo3
(pB2JC1-9) was made by replacing
the
EcoRI-
PstI
fragment in pB2glo2 with a corresponding PCR fragment
generated from a
pB2SL1
template.
RNA and protein analysis.
RNA decay assays, total yeast RNA
isolation, Northern blot analysis, two-cycle RNase protection assays,
primer extension, total protein extraction, and Western blot analysis
were performed as described elsewhere (14, 24, 38, 50).
For cell fractionation, yeast cells were grown in synthetic galactose
medium to mid-log phase and converted to spheroplasts as described
elsewhere (14). Spheroplasts were osmotically lysed by
pipetting up and down in extraction buffer (50 mM Tris [pH 7.4], 10 mM ribonucleoside vanadyl complex). The resulting lysate was
centrifuged for 5 min at 10,000 × g. The supernatant
was removed and retained, and the pellet was washed once with
extraction buffer and resuspended to original lysate volume in
extraction buffer. Nucleic acids were isolated from these fractions by
phenol-chloroform extraction and analyzed by Northern blotting.
| |
RESULTS |
1a- and 2a-dependent RNA2 replication in yeast.
To test
whether yeast would support BMV RNA2 replication, we constructed pB2
(Fig. 1), a yeast centromeric plasmid
containing a full-length RNA2 cDNA. The 5' end of RNA2 cDNA was linked
to the galactose-inducible, glucose-repressible yeast GAL1
promoter, and the 3' end was linked to a self-cleaving hepatitis delta
virus ribozyme to generate RNA2 transcripts with the authentic RNA2 3'
end (24).
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FIG. 1.
Pathway for initiating BMV RNA2 replication from DNA
plasmid pB2. The bracket at the top indicates the RNA2 cDNA copy within
pB2, with the 2a ORF boxed. The yeast GAL1 promoter fused to
5' end of RNA2 cDNA allows galactose-inducible, glucose-repressible
transcription of RNA2, and the hepatitis delta virus ribozyme cleaves
the transcripts at the natural 3' end of RNA2 as indicated. RNA2
transcripts serve as templates for translation of 2a protein and for
synthesis of the negative-strand RNA2 replication intermediate.
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pB2 was introduced into yeast alone or with a plasmid expressing BMV
RNA replication factor 1a. To assay for possible negative-strand
RNA2
synthesis, total RNA extracted from yeast cells was hybridized
with a
32P-labeled RNA probe complementary to 245 nt in the center
of negative-strand
RNA2 and treated with single-strand-specific RNases
A and T
1.
This RNase protection assay produced a strong
negative-strand
signal in yeast coexpressing wt RNA2 and 1a (Fig.
2A, lane 3).
Negative-strand RNA2
accumulation was suppressed by omitting 1a
or mutating 2a. In yeast
containing pB2 but lacking 1a, the background
signal in this assay was
only 1 to 2% of that in the presence
of 1a (Fig.
2A, lane 2). This
background signal was not reduced
by mutating RNA2 to delete the 2a
protein GDD residues (lane 4)
that constitute the most conserved
functional motif in RNA-dependent
RNA polymerases (
9,
29).
Thus, the background signal resulted
from 1a-, 2a-independent
mechanisms such as cryptic promoter-initiated
transcription of the pB2
RNA2 cDNA in the direction opposite to
GAL1-promoted
transcription. In 1a-expressing yeast, deleting
the conserved 2a GDD
motif reduced negative-strand RNA levels
15-fold (Fig.
2A, lane 5),
showing that high-level RNA2 negative-strand
production was 1a and 2a
dependent. Nevertheless, even for yeast
expressing RNA2 with the
GDD
mutation, 1a produced a small increase
in negative-strand RNA2 levels
(Fig.
2A, lanes 4 and 5). This
might reflect low-level residual
activity in the 2a
GDD mutant,
low-level nonspecific effects of 1a
on all RNAs (
50), or both.
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FIG. 2.
RNA2 replication in yeast. (A) Negative-strand RNA2
accumulation was assayed by a two-cycle RNase protection assay
(38) using equal amounts of total RNA extracted from yeast
expressing no BMV components (lane 1) or yeast expressing wt RNA2 (B2)
or an RNA2 mutant with a deletion of the conserved GDD polymerase motif
(B2GDD), in the presence (+1a) or absence ( 1a) of 1a as indicated.
After initial hybridization and RNase treatment to remove excess
positive-strand RNA2, the remaining double-stranded RNA was denatured,
hybridized with a 32P-labeled RNA probe corresponding to nt
1441 to 1685 of positive-strand RNA2, and treated with RNases A and
T1. The reaction products were electrophoresed and
autoradiographed. Parallel strand-specific Northern blot analysis
produced similar negative-strand RNA2 accumulation results, but with
higher background signals apparently due to cross-hybridization. Neg.
ctrl., negative control. (B) Positive-strand RNA2 accumulation in yeast
expressing RNA2 alone, with 1a, with RNA3, or with both, as indicated.
Total RNA was isolated from yeast and analyzed by Northern blotting
with a probe specific for positive-strand RNA2. (C) Primer extension
analysis of 5' ends of RNA2 species in yeast expressing wt RNA2 with or
without 1a. A 5' 32P-labeled primer complementary to nt 47 to 73 of RNA2 was annealed with BMV virion RNA (vRNA) or total RNA from
the indicated yeast. The primer was extended with reverse
transcriptase, and the resulting cDNA products were analyzed in a 6%
polyacrylamide sequencing gel. A sequencing ladder prepared by
extending the same labeled primer on pB2 plasmid DNA was
coelectrophoresed, and sequence corresponding to the sense of the RNA
product is shown at right. As previously demonstrated, the major primer
extension bands from BMV positive-strand RNA replication products
migrate one nucleotide above the end of the viral sequence due to
cap-dependent incorporation of an additional nucleotide (2,
6).
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Next, we compared positive-strand RNA2 accumulation in yeast expressing
RNA2 by itself, with 1a, with BMV RNA3, or with both.
Coexpressing RNA3
alone did not affect the accumulation of positive-stand
RNA2
transcripts (Fig.
2B, lane 3 and 4). However, coexpressing
1a increased
positive-stand RNA2 accumulation twofold over that
produced by DNA
transcription from the strong
GAL1 promoter in
pB2 (Fig.
2B,
lane 2 versus lane 4). Coexpressing 1a and RNA3
increased
positive-strand RNA2 accumulation 18-fold (Fig.
2B,
lane 1). This is
consistent with prior findings that BMV coat
protein, which is produced
by subgenomic mRNA synthesis in yeast
expressing 1a, 2a, and RNA3,
encapsidates and stabilizes RNA2
in yeast (
31).
Negative-strand RNA2 levels were unaffected by
the presence or absence
of RNA3, implying that RNA3 did not stimulate
RNA2
replication.
In the absence of RNA3 and coat protein, the increased RNA2
accumulation in yeast coexpressing 1a could result from 1a-induced
stabilization of DNA-derived RNA2 transcripts (see also below),
from
RNA-dependent RNA2 replication, or from both. To explore
these
possibilities, we used primer extension to examine the 5'
ends of RNA2
species in yeast expressing wild-type (wt) RNA2 alone
or with 1a (Fig.
2C). Primer extension was used based on prior
findings that
GAL1-driven transcription starts at multiple sites,
that 1a
equally stabilizes RNA3 transcripts from all start sites,
but that 1a-
and 2a-driven, RNA-dependent RNA3 replication specifically
amplifies
RNA3 species with natural viral 5' ends (
24,
25).
As expected,
GAL1-promoted RNA2 transcripts in yeast lacking
1a exhibited multiple 5' ends (Fig.
2C, lane 2) (
24,
28).
Upon coexpression of 1a, we observed the same RNA2 species but
overlaid
with the intense, selective amplification of a single
band
corresponding to the 5' end of natural BMV RNA2 replication
products
(Fig.
2C, lanes 1 and 3). Thus, RNA replication contributed
substantially to increased RNA2 accumulation in the presence of
1a.
Results presented below show that RNA2 replicated to even
higher levels
when higher levels of 2a were supplied in
trans from a 2a
mRNA unable to serve as a replication
template.
1a stabilizes RNA2 and induces RNA2 association with membrane.
In the absence of 2a and RNA replication, 1a increases the stability
and accumulation of DNA-derived RNA3 transcripts (25, 50).
To determine if 1a similarly stabilized RNA2, we measured RNA2 decay
with and without 1a by repressing the GAL1 promoter with
glucose and monitoring surviving RNA2 levels by Northern blotting.
In the absence of 1a, RNA2 decayed rapidly, with an initial half-life
of approximately 7 min (Fig.
3A). Decay
slowed after
70% or more of the initial RNA2 had decayed. Similar
biphasic
decay patterns have been seen for BMV RNA3 and other RNAs
containing
the BMV tRNA-like 3' end (
50). In the presence
of 1a, the level
of surviving RNA2 was much higher for all time points
after glucose
repression. Sixty minutes after glucose repression, e.g.,
approximately
50% of the initial RNA2 survived in the presence of 1a,
compared
to less than 10% in the absence of 1a.
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FIG. 3.
1a-induced stabilization and membrane association of wt
RNA2 and RNA2 frameshift mutants. (A) On the left are diagrams of
expression cassettes for wt RNA2, B2fs1, and B2fs2. In B2fs1, a 2-nt
insertion after nt 110 results in translation of 3 wt 2a codons
followed by 18 out-of-frame codons. In B2fs2, a 4-nt insertion after nt
882 results in translation of 261 wt 2a codons followed by 3 out-of-frame codons. The stabilities of these RNAs in the absence
(1a) and presence (+1a) of 1a were analyzed by transferring
galactose-induced yeast to glucose to repress GALI-promoted
RNA2 transcription. Equal amounts of total RNA prepared from yeast
harvested at the indicated times following glucose repression were
analyzed by Northern blotting to detect positive-strand RNA2 (middle).
The results of three or more independent stability analyses of each RNA
were averaged and plotted on a logarithmic scale (right). Standard
error bars are included on all points but in some cases are obscured by
the symbols used to plot the average values. (B) Effects of 1a on
distribution of wt RNA2, B2fs1, and B2fs2 in cell fractionation. Yeast
cells expressing these RNAs with or without 1a were spheroplasted and
lysed osmotically to yield a total RNA fraction (Tot.). A portion of
the lysate was then centrifuged at 10,000 × g to yield
pellet (Pell.) and supernatant (Sup.) fractions. RNA was isolated from
each fraction by phenol-chloroform extraction, and equal percentages of
each fraction were analyzed by Northern blotting to detect
positive-strand RNA2. For each RNA, the accumulation in each fraction
was normalized to that in the total fraction for that RNA in the
absence of 1a. Averages and standard errors from three or more
independent experiments were plotted.
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Since wt RNA2 expressing 2a can replicate in yeast coexpressing 1a
(Fig.
2), the higher RNA2 levels in the presence of 1a
could be due to
RNA2 replication, to increased RNA2 stability,
or to both. To
distinguish among these possibilities, we created
two pB2 derivatives
with frameshift mutations in the 2a gene (Fig.
3A). pB2fs1 bore a 2-nt
insertion at RNA2 position 110, resulting
in translation of 3 wt 2a
codons followed by 18 out-of-frame codons.
pB2fs2 bore a 4-nt insertion
at RNA2 position 882, resulting in
translation of 261 wt 2a codons
followed by 3 out-of-frame codons.
Western blotting with anti-2a
antibodies showed that, as expected,
yeast expressing B2fs1 RNA
contained no detectable 2a-related
peptide, while yeast expressing
B2fs2 RNA contained a truncated
2a peptide of the predicted size (data
not
shown).
RNA2 decay assays showed that in the absence of 1a, B2fs1 and B2fs2 RNA
decayed rapidly, with kinetics indistinguishable from
those of wt RNA2
in the absence of 1a (Fig.
3A). In the presence
of 1a, the levels of
B2fs1 and B2fs2 RNA surviving after glucose
repression were
dramatically increased. Nevertheless, consistent
with the ability of wt
RNA2 to replicate in a 2a-dependent manner
(Fig.
2), the levels of
B2fs1 and B2fs2 RNA after glucose repression
were lower than that of wt
RNA2 (Fig.
3A). The results imply that
in the absence of functional 2a
protein and RNA2 replication,
1a increased the stability of DNA-derived
transcripts of the B2fs1
and B2fs2 RNA2 derivatives, but that for wt
RNA2, RNA replication
also contributed to the 1a-dependent increase in
RNA2 levels after
glucose
repression.
In plant and yeast cells, cell fractionation and confocal microscopy
show that BMV RNA replication factors 1a and 2a and BMV
RNA-dependent
RNA synthesis colocalize on ER membranes (
14,
46,
47). In
the presence or absence of other viral factors,
1a localizes to ER
membranes and remains membrane-associated upon
cell fractionation
(
14,
47). In keeping with these findings,
recent results
show that 1a-dependent stabilization of RNA3 results
in membrane
association of RNA3 (M. Janda, M. Sullivan, and P.
Ahlquist,
unpublished results). To determine if 1a also induces
RNA2 to associate
with membranes, yeast expressing wt RNA2 in
the presence or absence of
1a were spheroplasted, lysed, and centrifuged
at 10,000 ×
g to produce soluble supernatant and membrane-associated
pellet
fractions, and the level of RNA2 in each fraction was determined
by
Northern
blotting.
As shown in Fig.
3B, in the absence of 1a, nearly all wt RNA2 was found
in the supernatant. When 1a was coexpressed, the level
of RNA2
increased, and half of all RNA2 was found in the membrane-associated
pellet. RNA2 mutants B2fs1 and B2fs2 showed similar behavior (Fig.
3B):
without 1a, nearly all of the RNA was in the supernatant
fraction,
while 1a coexpression induced approximately half of
the total RNA2 to
associate with the membrane fraction. Thus,
independently of 2a and RNA
replication, the ER membrane-associated
1a protein stabilized RNA2 and
induced RNA2 to associate with
the pelletable membrane fraction.
Because membrane association
provided a more direct and easily
quantified measure of 1a effects
on RNA2 than the RNA decay assay, it
was used in subsequent
experiments.
The 5' third of RNA2 is required for 1a-induced membrane
association.
To identify the RNA2 cis signals required
for 1a-induced membrane association, we created nonoverlapping deletion
derivatives B25', B2M, and B23', collectively spanning almost
the complete RNA2 sequence, and tested their abilities to associate
with membrane in the presence of 1a. In the absence of 1a, all three
deletion derivatives were primarily found in the supernatant fraction, similar to wt RNA2 (Fig. 4). B23',
which lacked RNA2 nt 1685 to 2817 but retained the 3' 48 nt, showed
this same distribution pattern despite accumulating to lower levels
than wt RNA2 or the other two derivatives, B25' and B2M. As found
previously (44), this lower accumulation was presumably
due to disruption of the 3'-terminal tRNA-like sequence of BMV RNAs,
which confers a degree of 1a-independent stability on these
nonpolyadenylated RNAs (50). B23' retained the last 48 nt of RNA2 because deletions lacking this extreme 3'-terminal region
accumulated to virtually undetectable levels.
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FIG. 4.
RNA2 nt 1 to 882 contain sequences required for
1a-induced membrane association. (A) Expression cassettes for wt RNA2
and RNA2 deletion derivatives are diagrammed at the left. Membrane
association of these RNAs with or without 1a was assessed by cell
fractionation as described in the legend to Fig. 3, and representative
Northern blots are shown at the right. Sup., supernatant. (B) As a
quantitative measure of 1a responsiveness, the ratio of RNA
accumulation in the membrane-associated pellet fraction in the presence
and absence of 1a was calculated for each RNA. Averages and standard
errors from three or more independent experiments are shown.
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|
In the presence of 1a, the B2
3' and B2
M RNAs showed 1a
responsiveness equal to that of wt RNA2: 1a induced a seven- to
eightfold
increase in the accumulation of wt RNA2, B2
3' RNA, and
B2
M RNA
in the membrane-containing pellet fraction (Fig.
4). By
contrast,
B2
5' RNA, lacking RNA2 nt 1 to 882, completely lost 1a
responsiveness,
showing equally low accumulation in the membrane pellet
in the
presence and absence of 1a. Thus, the first 882 bases of RNA2
contain signals required for 1a-induced membrane association,
while
sequences 3' to this region are dispensable. The independence
of 1a
responsiveness from the last 48 nt of RNA2 (the only region
common to
pB2
5', pB2
M, and pB2
3') is addressed below using
a chimeric,
3'-polyadenylated
RNA.
5' noncoding and coding sequences influence 1a responsiveness.
To further map RNA2 sequences required for 1a-induced membrane
association, smaller deletions within the first 882 nt were made and
tested (Fig. 5). In the absence of 1a,
all of these deletion derivatives behaved like wt RNA2, with the
majority of the RNA recovered in the supernatant fraction of cell
lysates (Fig. 5A, 1a lanes). However, the ability of 1a to stimulate
accumulation of these RNAs in the pelletable membrane fraction varied
considerably with the deletion boundaries (Fig. 5).
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FIG. 5.
Deletion analysis of 5' proximal RNA2 sequences required
for 1a responsiveness. (A) Expression cassettes for wt RNA2 and the
indicated RNA2 deletion derivatives are diagrammed at the left.
Membrane association abilities of these RNAs in the absence () or
presence (+) of 1a were assessed by cell fractionation as described in
the legend to Fig. 3, and representative Northern blots are shown at
the right. Sup., supernatant. (B) As a measure of 1a responsiveness,
the ratio of RNA accumulation in the membrane-associated pellet
fraction in the presence and absence of 1a was calculated for each RNA.
Averages and standard errors from three or more independent experiments
are shown.
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|
The first deletion derivative tested, B2
5'-1, lacked nt 1 to 46 of
RNA2. This region was selected because these 5'-terminal
nucleotides
share sequence similarity and secondary structure
potential with the 5'
ends of BMV RNA1 and RNA1 and RNA2 from
other bromoviruses and
cucumoviruses (see below). This deletion
nearly abolished 1a
responsiveness: 1a increased accumulation
in the membrane-containing
pellet fraction 8-fold for wt RNA2
but only 1.6-fold for B2
5'-1.
Deleting 5' UTR sequences 3' of
the first 46 bases (B2
5'-2) resulted
in an intermediate (threefold)
1a stimulation of RNA2 accumulation in
the pellet
fraction.
Additional deletions were created throughout the 2a ORF up to nt 882. Nested deletions extending 3' from the 2a start codon
up to nt 406 all
produced intermediate decreases in 1a responsiveness:
for deletions
extending to nt 174 (B2
5'-3), 333 (B2
5'-4), and
406 (B2
5'-5),
1a stimulated RNA accumulation in the membrane-containing
pellet four-,
six-, and threefold, respectively (Fig.
5). Nested
deletions extending
5' from nt 882 caused a progressive decline
in 1a responsiveness.
Deletion up to nt 762 (B2
5'-6) or 642 (B2
5'-7)
showed wt or near
wt RNA2 levels of 1a responsiveness, while extending
the deletion
endpoint to nt 522, 446, and 353 (B2
5'-8 to -10)
again reduced 1a
stimulation of pelletable RNA2 from eight- to
threefold (Fig.
5B).
Thus, the conserved 5'-terminal 46 nt of
RNA2 appear to be the most
important sequences for 1a-induced
membrane association of RNA2, while
flanking 5' UTR sequences
and a region in the 2a ORF (within RNA2 nt
333 to 642) also are
required for full 1a
responsiveness.
5'-terminal conserved sequences are essential for 1a
responsiveness.
RNA2 nt 1 to 46 have the potential to form a
structure consisting of a terminal loop (loop I) followed by a stem
(stem I), a bulge loop region (loop II region), and a second stem (stem II) extending to the 5'-terminal nucleotide (Fig. 6A and
B). Mutational analysis shows that this
region and the predicted positive-strand RNA base pairing are important
for RNA2 replication in plant cells (41, 42). A similar
stem-loop structure is conserved at the 5' ends of the RNA1 and RNA2 of
other bromoviruses and cucumoviruses (Fig. 6A; see also references
33 and 34). For all of these RNAs, the apex of this
structure including loop I and the adjoining nucleotide of stem I
comprises an 11-base box B motif corresponding to the invariant
residues of the TC stem-loop of host tRNAs (Fig. 6A and B). On
either side of the box B motif, despite significant sequence
divergence, the flanking sequences conserve the ability to form
base-paired stems. The box B motif is also an essential part of the
intergenic replication enhancer (RE) element required for 1a-induced
stabilization and membrane association of RNA3 (reference
50 and unpublished results), where it is also presented at
the apex of an extended stem-loop (T. Baumstark and P. Ahlquist, unpublished results).
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FIG. 6.
RNA2 5' stem-loop is required for 1a-induced membrane
association. (A) Alignment of BMV, cowpea chlorotic mottle virus
(CCMV), and cucumber mosaic virus (CMV) RNA1 and RNA2 5'-terminal
sequences, showing conservation of the box B motif and the potential
for base pairing of the surrounding stem regions. (B) Predicted
structure of the 5'-terminal stem-loop of BMV wt RNA2 and deletion or
base substitution mutants within the stem-loop. Base substitutions are
indicated by boxes, and deletions are indicated with dashes. Membrane
association abilities of these RNA2 mutants in the absence () or
presence (+) of 1a were assessed by cell fractionation as described in
the legend to Fig. 3, and representative Northern blots are shown below
each derivative. Sup., supernatant. (C) As a measure of 1a
responsiveness, the ratio of RNA accumulation in the
membrane-associated pellet fraction in the presence and absence of 1a
was calculated for each RNA. Averages and standard errors from three or
more independent experiments are shown.
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Accordingly, we created a series of RNA2 derivatives with deletions and
base substitutions within nt 1 to 46 to test what
sequences or
structures of this region might be required for 1a-induced
membrane
association of RNA2 (Fig.
6B). In the absence of 1a,
all RNA2
derivatives shown in Fig.
6B behaved like wt RNA2, with
the majority of
the RNA recovered in the supernatant fraction.
However, in the presence
of 1a, all of these derivatives were
impaired in 1a responsiveness.
Sequence changes in either terminal
loop I (B2SL1), stem I (B2SL2), or
both (B2SL3) largely abolished
1a responsiveness. The same was true for
deleting the bulge loop
region (B2SL4) or the second stem (B2SL5).
Sequence changes in
stem II designed to conserve base pairing (B2SL6)
had lesser but
still significant inhibitory effects on 1a
responsiveness. Thus,
the whole 5'-terminal stem-loop structure,
including the box B
motif and flanking elements, contributes to
1a-induced membrane
association of
RNA2.
RNA2 5' UTR confers 1a responsiveness on a nonviral RNA.
To
test whether 5' RNA2 sequences were sufficient for 1a-induced membrane
association of RNA2, we constructed chimeric RNAs containing 5' RNA2
sequences followed by a human -globin ORF (37, 50) and
the yeast ADH1 polyadenylation signal (Fig.
7A). As shown previously, a -globin
mRNA with the same 3' UTR but a nonviral 5' UTR lacks 1a responsiveness
(50). In chimeras B2glo1 to -3 (Fig. 7A), the -globin
ORF was linked, respectively, to nt 1 to 882 of RNA2, to only the RNA2
5' UTR (nt 1 to 103), and to the RNA2 5' UTR with base substitutions in
the box B motif. In the absence of 1a, all of these chimeric RNAs
accumulated to similar levels and behaved similarly in cell
fractionation, with most of the RNA recovered in the supernatant
fraction (Fig. 7A). In the presence of 1a, approximately six- and
fourfold accumulation increases in the pelletable membrane fraction
were observed for -globin RNA linked to the 5' 882-nt RNA2 and to
the RNA2 5' UTR, respectively, while base substitutions of the box B
motif in the 5' UTR almost completely abolished 1a responsiveness (Fig.
7). Thus, the RNA2 5' UTR is sufficient to confer 1a-induced membrane association on a nonviral RNA. However, sequences in the N-terminal region of the 2a ORF enhance this response, in agreement with the Fig.
5 results showing that sequences within RNA2 nt 333 to 642 are required
for full 1a responsiveness of wt RNA2.
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FIG. 7.
RNA2 5' UTR and flanking 2a ORF sequences confer 1a
responsiveness on a nonviral RNA. (A) Expression cassettes for chimeric
RNAs containing the indicated RNA2 sequences, -globin ORF, and the
ADH1 3' UTR and polyadenylation site are diagrammed at the
left. Base substitutions within the box B motif are indicated with
boxes. Membrane association abilities of these RNAs in the absence ()
or presence (+) of 1a were assessed by cell fractionation as described
in the legend to Fig. 3, and representative Northern blots are shown at
the right. Sup., supernatant. (B) As a measure of 1a responsiveness,
the ratio of RNA accumulation in the membrane-associated pellet
fraction in the presence and absence of 1a was calculated for each RNA.
Averages and standard errors from three or more independent experiments
are shown.
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|
RNA2 sequences required for 1a-induced membrane association are
also required for RNA2 replication.
To determine whether the
sequences responsible for 1a-induced membrane association were required
for RNA2 replication in yeast, selected RNA2 derivatives from Fig. 2 to
6 were tested as replication templates (Fig.
8). Because 2a protein is required for
RNA replication and many of these RNA2 derivatives had deletions in the
2a ORF, an additional plasmid was used to provide wt 2a in
trans. This 2a expression plasmid produced an mRNA
containing the 2a ORF but with the RNA2 5' and 3' UTRs replaced by
nonviral sequences. Since the viral 5' and 3' UTRs contain signals
required for RNA2 replication (26, 53), this modified 2a
mRNA was unable to serve as a replication template.
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FIG. 8.
RNA2 sequences required for 1a-induced membrane
association are also required in cis for RNA2 replication.
(A) RNA2 derivatives unable to produce functional 2a are efficiently
replicated by 2a provided in trans from pB2YT1, which
expresses 2a from a nonreplicatable 2a mRNA with 5' and 3' UTR
sequences replaced by nonviral sequences. Wt RNA2, B2fs2 (Fig. 3A), and
B2GDD (Fig. 2A) were expressed in yeast also expressing 1a or both
1a and 2a in trans. Total RNA was isolated from these yeast
cells, and negative-strand RNA2 accumulation was assessed by RNase
protection as described in the legend to Fig. 2A. Averages and standard
errors from three or more independent experiments are shown. (B)
Comparison of 2a protein accumulation in yeast expressing wt RNA2 from
pB2 or expressing chimeric 2a mRNA from 2a expression plasmid pB2YT1.
Equal amounts of total protein extract from each cell type were
analyzed by Western blotting with anti-2a antibodies. (C)
Negative-strand RNA2 accumulation in yeast expressing 1a, 2a, and the
indicated RNA2 derivatives, determined by RNase protection as described
in the legend to Fig. 2A. Averages and standard errors from three or
more independent experiments are shown. (D) Positive-strand RNA2
accumulation in the same yeast as panel C, determined by Northern
blotting with a single-stranded, 32P-labeled RNA probe
complementary to the conserved 3' 200 bases of positive-strand BMV
RNAs, which hybridizes to wt RNA2 but not the 2a mRNA from pB2YT1. The
arrowhead indicates the front edge of the yeast 25S rRNA band. The high
concentration of RNA in this band tends to sweep background signals
ahead of the rRNA, creating the observed discontinuity in the
background.
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To assess whether 2a provided by this plasmid could replicate RNA2 in
trans, we used RNA2 derivatives whose 2a function was
blocked by a frameshift mutation (B2fs2 in Fig.
3) or by deleting
the
conserved GDD motif of RNA-dependent RNA polymerase (B2
GDD
in Fig.
2). In the presence of 1a but absence of functional 2a
provided in
trans, only weak negative-strand RNA2 signals were
detected
for B2fs2 and B2
GDD (Fig.
8A, lanes 2 and 3), equivalent
to the
2a-independent background seen previously (Fig.
2A). Supplying
both 1a
and 2a in
trans produced two notable effects. First, the
level of negative-strand RNA2 detected for wt RNA2 was twofold
above
that when 1a alone was provided in
trans (Fig.
8A, lanes
1 and 4). Similarly, positive-strand RNA2 levels increased 2.5-fold
over
RNA2 replication from 2a provided in
cis, reaching levels
5-fold over those of DNA-derived RNA2 transcripts (Fig.
8D and
results
not shown). These increases in RNA2 replication products
coincided with
and were presumably due to a fivefold increase
in 2a protein expression
relative to yeast containing wt RNA2
(Fig.
8B). Second, when 1a and 2a
were provided in
trans, negative-strand
RNA2 levels for
B2fs2 and B2
GDD were equivalent to those of wt
RNA2 (Fig.
8A, lanes
4 to 6). Thus, when 2a was provided in
trans,
RNA2 templates
unable to produce functional 2a in
cis were replicated
as
efficiently as wt
RNA2.
Next, selected RNA2 derivatives with various levels of 1a
responsiveness were tested for their function as RNA replication
templates when both 1a and 2a were supplied in
trans. The
level
of 1a-induced membrane association of the various RNA2 mutants
(Fig.
4 to
6) correlated well with their abilities to serve as
replication templates to produce negative-strand RNA2 (Fig.
8C),
and
amplification of positive-strand RNA2 (Fig.
8D) paralleled
negative-strand RNA2 production. For example, B2
5' and B2
5'-1,
which had little or no 1a responsiveness for membrane association
(Fig.
4 and
5), produced only background levels of negative-strand
RNA2
signal (Fig.
8C, lanes 2 and 3) and similarly low positive-strand
RNA2
levels (Fig.
8D, lanes 2 and 3). By contrast, B2
5'-6, showing
wt 1a
responsiveness (Fig.
5), produced the highest levels of
negative- and
positive-strand RNA2 among the mutants (70 to 75%
of wt; Fig.
8C and
D, lanes 6). The other RNA2 mutants all showed
intermediate levels of
1a responsiveness (Fig.
5 and
6), and their
degree of 1a responsiveness
correlated with their relative ranking
in negative- and positive-strand
levels. For example, B2
5'-5
and B2
5'-10, which had the
second-highest 1a responsiveness among
the tested mutants (after
B2
5'-6), also had the second-highest
levels of negative- and
positive-strand RNA2 among the mutants
(Fig.
8C and D, lanes 5 and 7).
The results imply that 1a responsiveness,
as measured by RNA2
stabilization and membrane association, is
an important though not the
only requirement for RNA2
replication.
| |
DISCUSSION |
Prior studies of BMV RNA replication in yeast have used templates
derived from genomic RNA3. In this report, we demonstrated that yeast
expressing viral replication factors 1a and 2a also replicate genomic
RNA2, further validating yeast as a model host for studies of BMV RNA
replication. In the absence of 2a protein and RNA replication, the
ER-associated 1a protein stabilized RNA2 and induced it to associate
with the rapidly sedimenting cellular membrane fraction (Fig. 3). As
discussed further below, 1a-induced RNA2 stabilization and membrane
association as well as 1a- and 2a-mediated-RNA2 replication in yeast
required sequences previously identified as cis-acting
signals for RNA2 replication in natural plant hosts (42, 53,
54). The results show close parallels to the 1a- and the 1a- and
2a-responsive behavior of RNA3 templates and imply that 1a-induced RNA
stabilization and membrane association reflect general features of 1a
action on BMV RNA replication templates.
RNA2 replication in yeast.
Simultaneous production of 1a and
2a-expressing wt RNA2 in yeast induced synthesis of negative-strand
RNA2 and amplification of positive-strand RNA2 (Fig. 2 and 8). Out of
the multiple 5' ends generated by DNA transcription, RNA replication
amplified the specific RNA2 5' end of natural infection products (Fig.
2C). As in plant cells (41, 54), 2a functioned in
trans to replicate RNA2 templates unable to produce
functional 2a in cis (Fig. 8). This contrasts with another
tripartite RNA plant virus, alfalfa mosaic virus, whose analogous RNA2
templates can be replicated only by a 2a homologue produced in
cis (55). For BMV in yeast, an engineered 2a
mRNA unable to function as a replication template produced higher
levels of 2a protein than wt RNA2 and supported higher levels of RNA2
replication (Fig. 8). Similar or even greater increases in RNA
replication were seen in plant cells when 2a was expressed from a DNA
plasmid rather than from replicating RNA2 (16).
When 2a was supplied in
cis or in
trans under the
conditions used here, RNA replication amplified positive-strand RNA2
two-
and fivefold, respectively, over the level of DNA-derived RNA2
transcripts from the strong yeast
GAL1 promoter (Fig.
2B and
8D).
In the further presence of RNA3-expressed BMV coat protein, which
encapsidates and stabilizes RNA2 in yeast (
31), RNA
replication
amplified RNA2 18-fold over DNA-derived RNA2 transcripts
(Fig.
2B). Thus, in the absence of coat protein, higher levels of RNA2
replication products were generated but turned over. 1a- and
2a-expressing
yeast amplify wt RNA3 to higher levels than RNA2, viz.,
45-fold
over the levels of
GAL1-promoted RNA3 transcripts
(
24). RNA3
also replicates to significantly higher levels
than RNA2 in natural
BMV infections of plants (
39).
RNA2 sequences required in cis for 1a
responsiveness.
The first 882 nt of RNA2 contained sequences
essential for 1a-induced membrane association (Fig. 4) and conferred
nearly wt RNA2 levels of 1a responsiveness on -globin mRNA (Fig. 7).
By contrast, deleting the middle third or 3' third of RNA2 had little or no effect on 1a responsiveness (Fig. 4). Further mapping showed that
the 103-nt 5' UTR was essential for 1a-induced membrane association (Fig. 5 and 6), and this 5' UTR alone transferred much of the 1a
responsiveness of RNA2 to -globin mRNA (Fig. 7).
The first 46 nt of the RNA2 5' UTR were crucial for 1a responsiveness.
These nucleotides are predicted to form a 5'-terminal
stem-loop
structure whose apical loop and flanking base pairs
duplicate the
arrangement of the conserved residues in the T
C
stem-loops of tRNAs
(Fig.
6A and B). Prior mutational analysis
supports the existence of
this stem-loop (
42). 1a responsiveness
was abolished by
mutations in the box B loop and was highly sensitive
to deletions or
substitutions in other features of the stem-loop,
including the
base-paired stem regions and two bulge loops (Fig.
6B and
C).
In addition to this 5' stem-loop, full 1a responsiveness required
flanking 5' UTR sequences and 5' proximal sequences of the
2a ORF,
particularly sequences within nt 333 to 762 (Fig.
5 and
7). However,
while these sequences enhanced 1a responsiveness,
they were unable to
independently confer significant 1a responsiveness
in the absence of
the RNA2 5' UTR (Fig.
5).
1a-responsive signals are required for RNA2 replication.
As
with RNA3, the RNA2 regions responsible for 1a-induced membrane
association were required in cis for RNA2 replication in yeast and in the natural plant hosts of BMV. In the 5'-terminal stem-loop, substitutions throughout the box B motif inhibit RNA2 replication in plant cells expressing 1a and 2a in
trans, as do substitutions partially disrupting the
predicted base pairing shown in Fig. 6B (41, 42).
Substitutions or deletions in these same stem and loop regions also
severely inhibited RNA2 replication in yeast expressing 1a and 2a in
trans (Fig. 8). Efficient RNA2 replication in plant
protoplasts also requires in cis a subset of 2a ORF
sequences within nt 257 to 887 (54). This corresponds well
to the 2a ORF segment that stimulated 1a responsiveness (Fig. 5) and
RNA2 replication template activity in 1a- and 2a-expressing yeast (Fig.
8C and D). Thus, deletions and substitutions in the RNA2 5' UTR and 2a
ORF all had closely parallel cis effects on 1a
responsiveness and RNA2 replication template activity in yeast and
plant cells.
The parallel between the function of these RNA2 sequences in 1a
responsiveness and RNA2 replication extends to the polarity
of the RNA
strand in which they act. 1a stabilized and induced
membrane
association of positive-strand RNA2 (Fig.
2). Similarly,
1a- and
2a-mediated RNA replication requires the 5' stem-loop
in
positive-strand RNA2, not a complementary structure in negative-strand
RNA2 (
41). Specifically, the activity of RNA2 as a
replication
template in 1a- and 2a-expressing plant cells was inhibited
85
to 95% by mutations that disrupted base pairing in the
positive-strand
5' stem-loop while creating G · U base pairs
to preserve the complementary
negative-strand 3' stem-loop. Conversely,
RNA2 replication was
not inhibited by mutations disrupting the
negative-strand 3' stem-loop
while preserving the positive-strand 5'
stem-loop.
Relation to BMV RNA1, RNA3, and other viruses.
In addition to
BMV RNA2, BMV RNA1, and RNA1 and RNA2 of other bromoviruses and
cucumoviruses conserve the potential for similar 5'-terminal
stem-loops, each equivalently presenting the conserved TC loop
residues (box B motif) at its apex (7, 34, 41, 42) (Fig.
6A). Such conservation implies a conserved role or roles in infection.
For comparison, 1a-induced stabilization and membrane association of
BMV RNA3 is mediated by an ~150-nt intergenic RE segment
that makes a
nonviral mRNA fully responsive to 1a-induced stabilization
(50;
Sullivan et al., unpublished). As in RNA2, this RNA3 RE segment
contains a tRNA-like box B motif that is required, together with
flanking sequences, for 1a responsiveness (
50). Moreover,
RNA
structure probing shows that the RNA3 box B motif is also presented
in the apex of a stem-loop that mirrors the T
C stem-loops of
tRNAs
(Baumstark and Ahlquist, unpublished). Like RNA2 sequences
required for
1a responsiveness, the RE is required for efficient
RNA3 replication in
plant cells and yeast, and RE mutations inhibit
or stimulate 1a
responsiveness and RNA3 replication coordinately
(
18,
50).
Thus, RNA2 replication and RNA3 replication require
similar box
B-containing signals that direct 2a-independent, 1a-induced
RNA
stabilization and related
effects.
As noted in the introduction, 1a-induced stabilization and membrane
association of RNA3 are closely linked to inhibition of
RNA3
translation and stimulation of negative-strand RNA3 synthesis
(
25,
50). Assaying in vivo negative-strand synthesis in
the
absence of positive-strand synthesis shows that the RE enhances
negative-strand RNA3 synthesis 50- to 100-fold (
44). This
duplicates
the RE's stimulatory effect on full RNA3 replication
(
18,
50),
suggesting that the RE may act primarily at or
before negative-strand
RNA synthesis. A possible analog to the action
of 1a on RNA3 is
found in poliovirus protein 3CD, which interacts with
poliovirus
positive-strand RNA to inhibit translation and promote
negative-strand
RNA synthesis. Interestingly, 3CD mediates these
effects by interacting
with a 5' proximal cloverleaf structure in
poliovirus RNA (
20).
The extensive similarities between the roles of box B-containing
elements in 1a responsiveness and replication of RNA2 and
RNA3, as well
as the role of 5' sequences in poliovirus RNA, suggest
that the 1a
responsiveness of the positive-strand RNA2 5' end
also might be
involved in inhibiting translation and stimulating
negative-strand RNA
synthesis. Such a role would not preclude
the possibility that RNA2 5'
sequences or their complements in
negative-strand RNA2 may also play a
role in positive-strand RNA2
synthesis, as previously suggested from
kinetic studies (
43).
Similarly, though involved in
negative-strand RNA synthesis, poliovirus
5' proximal sequences may
also contribute to positive-strand initiation
(
8,
20).
Although the 1a-responsive intergenic RE is over 1 kb from the RNA3 5'
end, 1a action on RNA3 may also involve direct or indirect
interaction
with the 5' end, suggesting possible similarities
with poliovirus RNA
and BMV RNA2. Efficient 1a-induced stabilization
of RE-containing RNAs
requires a 5' UTR functional for translation
initiation
(
50) and either host protein Lsm1p or a
cis-linked
3' poly(A) (
15). Both poly(A) and
Lsm1p mediate interactions
with mRNA 5' ends: poly(A) stabilizes the
interaction of translation
factors with mRNA 5' ends, while Lsm1p
stimulates the action of
decapping factor Dcp1p on 5' ends (
12,
13,
52). Dcp1p recently
was found to interact with
poly(A)-stabilized translation initiation
factor eIF4G
(
56), confirming an inferred linkage between these
processes (
15). For RNA3, as well as poliovirus RNA and
perhaps
BMV RNA2, involvement of the 5' end may facilitate inhibiting
translation preparatory to RNA
replication.
| |
ACKNOWLEDGMENTS |
We thank Yuriko Tomita and Masayuki Ishikawa for generously
providing pB1YT1; Michael Sullivan, Michael Janda, and Tilman Baumstark
for sharing unpublished results; and additional members of our
laboratory for helpful discussions throughout these experiments.
This work was supported by the National Institutes of Health through
grant GM35072. P.A. is an Investigator of the Howard Hughes Medical Institute.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute for
Molecular Virology, University of WisconsinMadison, 1525 Linden Dr., Madison, WI 53706-1596. Phone: (608) 263-5916. Fax: (608) 265-9214. E-mail: ahlquist{at}facstaff.wisc.edu.
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Journal of Virology, April 2001, p. 3207-3219, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3207-3219.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
