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Journal of Virology, July 2000, p. 6242-6250, Vol. 74, No. 14
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
An Enzymatic Footprinting Analysis of the
Interaction of 40S Ribosomal Subunits with the Internal Ribosomal Entry
Site of Hepatitis C Virus
Victoria G.
Kolupaeva,1
Tatyana V.
Pestova,1,2 and
Christopher U. T.
Hellen1,*
Department of Microbiology and Immunology,
State University of New York Health Science Center at Brooklyn,
Brooklyn, New York 11203,1 and A.
N. Belozersky Institute of Physico-Chemical Biology, Moscow State
University, 119899 Moscow, Russia2
Received 14 December 1999/Accepted 20 April 2000
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ABSTRACT |
Hepatitis C virus translation is initiated on a ~330-nucleotide
(nt)-long internal ribosomal entry site (IRES) at the 5' end of the
genome. In this process, a 43S preinitiation complex (comprising a 40S
ribosomal subunit, eukaryotic initiation factor 3 (eIF3), and a ternary
[eIF2-GTP-initiator tRNA] complex) binds the IRES in a precise manner
so that the initiation codon is placed at the ribosomal P site. This
binding step involves specific interactions between the IRES and
different components of the 43S complex. The 40S subunit and eIF3 can
bind to the IRES independently; previous analyses revealed that eIF3
binds specifically to an apical half of IRES domain III. Nucleotides in
the IRES that are involved in the interaction with the 40S subunit were
identified by RNase footprinting and mapped to the basal half of domain
III and in domain IV. Interaction sites were identified in locations
that have been found to be essential for IRES function, including (i) the apical loop residues GGG266-268 in subdomain IIId and
(ii) the pseudoknot. Extensive protection from RNase cleavage also occurred downstream of the pseudoknot in domain IV, flanking both sides
of the initiation codon and corresponding in length to that of the
mRNA-binding cleft of the 40S subunit. These results indicate that the
40S subunit makes multiple interactions with the IRES and suggest that
only nucleotides in domain IV are inserted into the mRNA-binding cleft
of the 40S subunit.
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INTRODUCTION |
Hepatitis C virus (HCV), the main
causative agent of non-A, non-B viral hepatitis in human populations,
is classified as one of the genera of the family
Flaviviridae (31). The HCV genome consist of a
positive-stranded RNA molecule of ~9,600 bases that contains a large
open reading frame preceded by a ~342-nucleotide (nt) 5'
nontranslated region (5' NTR) (5). Clinical HCV isolates exhibit considerable genetic diversity, and there is extensive quasispecies sequence variation among isolates from individual infected
patients (37). Sequence heterogeneity is limited to the
coding region, whereas the sequence of the 5' NTR is strongly conserved
among different genotypes (39). The conservation of primary
structure reflects requirements for higher-order structures that
control replication and translation of the genome.
HCV translation initiation occurs on an internal ribosomal entry site
(IRES) rather than by the 5' cap-mediated mechanism that is used by
most eukaryotic mRNAs (40, 42). IRESs also occur in members
of the Pestivirus genus of the Flaviviridae such as bovine viral diarrhea virus (BVDV) and classical swine fever virus
(CSFV) (30, 36). BVDV and CSFV IRESs are structurally similar to the HCV IRES (2, 11, 12, 19, 21, 41). The
proposed secondary structure of the HCV 5' NTR is highly conserved between genotypes and is characterized by four major domains
(designated I to IV). Domain I is dispensable; otherwise nearly the
entire HCV 5' NTR (nt 40 to 372) and ~30 nt of the adjacent coding
region are required for full IRES activity (8, 11, 33, 35). Some reports indicate that deletion of domain II causes near-total loss
of IRES function (8, 35, 42), whereas others indicate only
partial consequent reduction in activity (13, 32, 40). Several structural elements, such as a pseudoknot upstream of the
initiation codon (41, 43), are required for IRES function. Domain IV negatively regulates internal initiation by sequestering the
initiation codon (12).
Mutational analyses have shown that ribosomes bind HCV and pestivirus
IRESs directly at the initiation codon without scanning from an
upstream position (32, 34, 36). We have begun to investigate
the mechanism of this process by reconstituting it in vitro using
purified translation components (27, 28). HCV-like IRESs use
an initiation mechanism that differs fundamentally from the
cap-mediated scanning ribosome mode of initiation used by most mRNAs.
First, a ribosomal 43S complex comprising Met-tRNA; Met, GTP,
eukaryotic initiation factor 2 (eIF2), eIF3, and a 40S ribosomal
subunit is assembled. On capped mRNAs, eIF1, eIF1A, eIF4A, eIF4B, and
eIF4F are required for its attachment to a cap-proximal region of the
mRNA and for it to scan downstream to the initiation codon
(26). On HCV-like IRESs, 43S complexes bind directly to the
initiation codon independently of these five factors
(26-28). Attachment of 43S complexes to these IRESs is very
precise, such that the initiation codon is positioned in the immediate
vicinity of the ribosomal P site. Ribosomal attachment results from
specific interactions between elements in the IRES and components of
the 43S complex (27, 28). Two such interactions have been
identified in addition to codon-anticodon base pairing. HCV-like IRESs
all contain determinants in the apical half of domain III that interact with eIF3 (4, 27, 28, 38). In addition, these IRESs contain as yet undefined determinants that mediate direct and precise factor-independent binding of 40S subunits (27, 28). This ability is a unique property of HCV-like IRESs that differentiates initiation on them from initiation by the cap-mediated scanning ribosome mode that is used by most eukaryotic mRNAs and from internal initiation on picornaviral mRNAs (26, 29).
Toeprinting and deletion analyses indicate that binary
IRES-40S subunit complexes are stabilized by multiple
interactions. Primer extension on the HCV IRES is arrested by bound
ribosomes in the pseudoknot and downstream of the initiation codon.
This observation suggests that the initiation codon and flanking
residues are fixed in the mRNA-binding cleft of the 40S subunit, and
that the 40S subunit binds the IRES at one or more additional
positions. The ability of binary ribosomal complexes to assemble on an
IRES fragment lacking domain IV is consistent with this hypothesis. The
only contact on the 40S subunit that has been identified to date
involves ribosomal protein S9, which can be specifically UV
cross-linked to HCV and CSFV IRESs (28). We report here that we have used enzymatic footprinting to identify nucleotides that are
involved in the interaction with 40S subunits. Interaction sites were
identified in domain IIId, in the pseudoknot, and flanking the
initiation codon. These observations are consistent with a model for
IRES function in which ribosomal binding involves multiple interactions
between the 40S subunit and the IRES.
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MATERIALS AND METHODS |
Plasmids.
pHCV(40-372).NS' contains HCV nt 40 to 372 linked
to a truncated influenza virus nonstructural protein (NS') reporter
(33). p
F-CAT contains the complete HCV 5' NTR (except for
nt 229 to 238) linked to a chloramphenicol acetyltransferase reporter
(35). PCR was used to generate pHCV(118-372).NS' and
pHCV(118-228/239-372).NS'. Dicistronic vector pXL.CSFV(1-442).NS'
contains CSFV nt 1 to 442 flanked upstream by a cyclin B2 reporter and
downstream by the influenza virus NS' reporter (28). The
complete coding sequence of eukaryotic ribosomal protein S9
(7) was cloned by PCR from a human cDNA library (Clontech,
Palo Alto, Calif.) and cloned between the BamHI and
SacI sites in pET28b (Novagen, Madison, Wis.) to yield
pET28-S9.
Purification of 40S ribosomal subunits and recombinant
proteins.
40S ribosomal subunits were purified from rabbit
reticulocyte lysate (RRL; Green Hectares, Oregon, Wis.) as described
previously (28). Recombinant eIF4A and eIF4A(R362Q) mutant
proteins were expressed in Escherichia coli BL21(DE3) and
purified as described previously (25). Recombinant S9
protein was expressed in E. coli BL21(DE3) and was purified
by chromatography using a Ni2+-nitrilotriacetic acid matrix
(QIAGEN, Valencia, Calif.).
Transcription and translation.
HCV and dicistronic CSFV
mRNAs were transcribed in vitro with T7 polymerase with or without
[32P]UTP (~3,000 Ci/mmol; ICN Radiochemicals) from
plasmids that had been linearized at appropriate sites (28).
Radiolabeled RNAs were purified using Nuc-Trap columns (Stratagene, La
Jolla, Calif.) as described previously (29) and had specific
activities of ~300,000 to 500,000 cpm/µg. Monocistronic HCV mRNA
(0.5 µg) and dicistronic CSFV mRNA (0.2 µg) were translated in RRL
(Roche Molecular Biochemicals, Indianapolis, Ind.) in the presence of [35S]methionine, with or without recombinant eIF4A(R362Q)
or ribosomal protein S9 as indicated, in 15-µl total reaction
volumes. Translation products were resolved by electrophoresis using
12% polyacrylamide gels. Gels were dried and exposed to X-ray film.
Assembly and analysis of ribosomal complexes.
Ribosomal
complexes were assembled on 1 µg (~2.1 pmol) of HCV mRNA in 40-µl
reaction volumes in binding buffer (20 mM Tris-HCl [pH 7.5], 2.5 mM
magnesium acetate, 100 mM KCl, 2 mM dithiothreitol) with a threefold
molar excess of ribosomal 40S subunits. These ribosomal complexes were
analyzed by primer extension (29) using the primer
5'-CTCGTTTGCGGACATGCC-3' (complementary to part of the NS'
coding sequence). cDNA products were ethanol precipitated, resuspended,
and compared with appropriate dideoxynucleotide sequence ladders by
electrophoresis through 6% polyacrylamide-7 M urea gels. For analysis
by enzymatic footprinting (Fig. 1),
IRES-40S subunit complexes were assembled in 20-µl reaction volumes
essentially as described above. Free or ribosome-bound IRES-specific
RNAs in binding buffer were digested by incubation for 10 min at 37°C with either RNase V1 or RNase T1 (Amersham
Pharmacia Biotech) at a final RNase V1 concentration of
0.0007 U/µl (in the absence of 40S subunits) or 0.00105 U/µl (in
their presence) and a final RNase T1 concentration of 0.015 U/µl (in the absence of 40S subunits) or 0.025 U/µl (in their
presence). RNAs were extracted with phenol-chloroform and precipitated
with 3 volumes of ethanol. The end-labeled primer 5'-CTCGTTTGCGGACATGCC-3' (complementary to the NS' coding
sequence) or 5'-CGCAAGCACCCTATC-3' (complementary to HCV nt
295 to 309) was annealed to RNA and extended (15, 16). cDNA
products were analyzed by electrophoresis on 6% polyacrylamide-7 M
urea gels.
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FIG. 1.
Schematic representation of the secondary structure of
the HCV IRES (based on references 11 and
41), showing sites in nt 40-372.NS' mRNA that are
protected from cleavage by RNases T1 and V1 or
at which cleavage is enhanced following binding of a 40S ribosomal
subunit. These sites and the position of toeprints caused by bound 40S
subunits are indicated by symbols shown at the upper right. Smaller
symbols indicate weaker protection from cleavage. Domain IV (nt 331 to
354) is shown as an unstructured linear sequence for greater clarity.
The initiation codon (AUG342-344) is underlined. The
nomenclature used to describe subdomains of the IRES is from reference
12; the helices that constitute the pseudoknot are
labeled 1 and 2.
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UV cross-linking.
UV cross-linking of binary IRES-40S
subunit complexes was done essentially as described previously
(28). Ribosomal proteins were resolved by Tricine-sodium
dodecyl sulfate-polyacrylamide gel electrophoresis. Gels were dried and
exposed to X-ray film.
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RESULTS |
HCV IRES domain II enhances ribosomal binding at the initiation
codon.
Binding of ribosomal 40S subunits to the HCV IRES is
stabilized by multiple IRES-40S subunit contacts. For example, when
primer extension inhibition (toeprinting) is used to assay the
interaction of 40S subunits with HCV nt 40-372.NS' mRNA, toeprints are
detected at CU355-356 downstream of the initiation codon
AUG340-342 and at G318, G320,
U324, and U329 in the pseudoknot (Fig.
2A, lanes 1 and 2), consistent with
previous reports (28). In this mRNA, domain I is absent, and
the influenza virus NS' reporter gene is fused to 30 nt of the HCV
coding region, which are important for IRES function (22,
33). To determine the influence of domain II on these
interactions, we next used nt 118-372.NS' mRNA from which domains I and
II had been deleted completely. The intensity of toeprints downstream
of the initiation codon caused by the bound 40S subunit was
significantly lower on this mRNA, whereas the intensities of toeprints
in the pseudoknot of this RNA were similar (Fig. 2A, lanes 3 and 4).
Comparison between nt 40-372.NS' and nt 118-372.NS' mRNAs
showed that deletion of domain II reduced the translation
activity of the IRES to 67% (Fig. 2B, lanes 1 to 4). To verify that
the significant level of residual activity detected on translation of
this mutant RNA was not in fact due to end-dependent translation of
fragmented RNA, eIF4A(R362Q) was included in parallel translation
reactions. This protein is a trans-dominant inhibitor of
end-dependent initiation of translation, but it has no effect on
HCV-like IRESs because initiation on them does not involve eIF4A
(25, 27, 28). Inclusion of eIF4A(R362Q) had no effect on
residual translation activity. In parallel control experiments,
inclusion of wild-type eIF4A in translation reactions also had no
effect on translation of these HCV mRNAs (data not shown). Domain II is
thus not essential for but contributes to IRES function, consistent
with previous reports (13, 32, 40).
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FIG. 2.
Influence of domain II on IRES function. (A) Toeprint
analysis of binary ribosomal complex formation on the HCV IRES.
Ribosomal 40S subunits were incubated with HCV nt 40-372.NS' or nt
118-372.NS' mRNA under standard reaction conditions and then analyzed
by primer extension. Full-length nt 118-372.NS' cDNA is marked E';
other cDNA products terminated at the sites indicated on the right.
Reference lanes C, T, A, and G depict HCV sequences; IRES subdomains
IIIa, IIIb, IIIc, IIId, IIIe, and PS (pseudoknot) are indicated on the
left; HCV nucleotides are indicated by black squares at 50-nt intervals
from nt 150 to 350 on the right. (B) Translation in RRL of HCV nt
40-372.NS' mRNA (lanes 1 and 2) or nt 118-372.NS' mRNA (lane 3 and 4)
in the presence (lanes 2 and 4) or absence (lanes 1 and 3) of a 10-fold
molar excess of mutant eIF4A(R362Q). Translation products were analyzed
by autoradiography after electrophoresis on a 12% polyacrylamide gel.
The position of the NS' translation product is indicated.
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Localization of 40S subunit binding sites on the IRES by enzymatic
footprinting.
Toeprinting assays such as that described above and
sucrose density gradient centrifugation analysis (28)
indicated that the HCV IRES is able to bind a 40S subunit in the
absence of initiation factors to form a stable binary complex. We used
enzymatic footprinting to determine the sites at which 40S subunits
bind the IRES, using a ~3-fold molar excess of 40S subunits and
buffer conditions appropriate for HCV translation. Footprinting was
done using RNase V1 (which cleaves base-paired or stacked
RNA) and RNase T1 (which cleaves RNA specifically after
unpaired G residues) (6). Enzymatic cleavage of RNA is
detected by arrest of primer extension at the nucleotide at the 3' side
of the cleaved bond, and numbering of residues therefore refers to this
nucleotide. Some sites at which cleavage appears to be altered coincide
with strong stops formed during primer extension on this highly
structured RNA. Protection of such residues is therefore equivocal and
is not discussed. Results of this analysis are summarized in Fig. 1.
Ribosomal 40S subunits protected the HCV IRES (nt 40 to 372) from RNase
V
1 cleavage at CGU
334-336, A
348,
G
350, and CUA
355-357 downstream of the
pseudoknot (Fig.
3B, lanes 1 to 3),
weakly at
U
262 in subdomain IIId, at GC
249-250
and C
242 between subdomains
IIIc and IIId, and at
U
220 and weakly at AG
179-180 in IIIb (Fig.
3A,
lanes 1 to 3). Residues CUA
355-357 are downstream of the
initiation
codon AUG
342-344 and overlap the toeprints at
CU
355-356 caused
by 40S subunits bound to the IRES. Binding
of 40S subunits to
the IRES enhanced cleavage at A
206 and
A
214 at the apex of IIIb
(Fig.
3A, lanes 1 and 2). No
additional sites were detected at
which RNase V
1
cleavage was consistently altered as a result of
ribosomal
binding.
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FIG. 3.
RNase V1 footprinting of the binary 40S
subunit-HCV IRES complex. The gels show polyacrylamide-urea gel
fractionation of cDNA products obtained after primer extension. (A)
Sensitivity of HCV nt 40-372 RNA upstream of nt 272 to cleavage (lanes
1 and 2) either alone (lane 2) or bound by a 40S subunit (lane 1); (B)
sensitivity of HCV nt 40-372 RNA (lanes 1 to 3) or nt 118-372 RNA
(lanes 4 to 6) upstream of nt 360 to cleavage (lanes 2, 3, 5, and 6)
either alone (lanes 3 and 6) or bound by a 40S subunit (lanes 2 and 5);
(C) sensitivity of HCV nt 118-372 RNA upstream of nt 265 to cleavage
(lanes 2 and 3) either alone (lane 3) or bound by a 40S subunit (lane
2). cDNA products obtained after primer extension of untreated HCV RNA
are shown in lane 3 of panel A, lanes 1 and 4 of panel B, and lane 1 of
panel C. A dideoxynucleotide sequence generated with the same primer
(shown in lanes C, T, A, and G in panels A and B) was run in parallel
on each gel. IRES subdomains II, IIIa, IIIb, IIIc, IIId, IIIe, and PS
(pseudoknot), as appropriate, are indicated on the left of each panel;
HCV nucleotides are indicated by black squares at 50-nt intervals, and
the positions of protected residues are indicated on the sides of each
panel.
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40S subunits bound to the IRES protected it from RNase T
1
cleavage at GGU
267-269 in the apical loop of subdomain
IIId, at
C
308 and weakly at A
310 in the
pseudoknot, and at A
332, A
345,
and weakly at
C
347 downstream of the pseudoknot (Fig.
3A, lanes
1 to 3).
No additional sites of altered RNase T
1 cleavage were
identified anywhere in domain II or in the 5' half of domain III
(Fig.
4B, lanes 1 to 3). The positions of these sites of altered
RNase
T
1 cleavage correlate well with the sites of altered RNase
V
1 cleavage. The residues downstream of the pseudoknot that
are
protected by 40S subunits from cleavage by RNases T
1
and V
1 flank
the initiation codon AUG
342-344.
The 40S subunit likely covers
about 25 nt flanking the initiation codon
of a eukaryotic mRNA
(
3,
17,
18,
20), and the leading edge
of a 40S subunit
bound to the HCV IRES has been mapped to
CU
355-356 by toeprinting
(
28). Taken together,
these observations suggest that protection
by a 40S subunit of residues
A
332-U
356 downstream of the HCV pseudoknot
from
RNase cleavage (Fig.
1) is consistent with these residues
having been
inserted into the mRNA-binding cleft of the 40S subunit.
The cleavage
of residues in helix 2 of the pseudoknot in naked
RNA by RNase
T
1 is consistent with a previous report (
41) and
strongly suggests that helix 2 is not static but may instead be
in
equilibrium with alternate higher-order structures. RNase
V
1 cleavage in helix 2 was not enhanced by binding of a 40S
subunit
to the IRES; therefore, we suggest that the 40S subunit
protects
helix 2 from cleavage directly, rather than simply stabilizing
the pseudoknot so that helix 2 is base paired and thus cannot
be
cleaved by RNase T
1 (which cleaves only unpaired RNA). The
protected residues at the apex of subdomain IIId are absolutely
conserved in all HCV genotypes and isolates (
39) and in
related
pestivirus IRESs (
10,
21) and are essential for the
function
of HCV and CSFV IRESs (
14; V. G. Kolupaeva, C. U. T. Hellen,
and T. V. Pestova,
unpublished
data).
Enzymatic footprinting analysis of the interaction of 40S subunits
with mutant HSV IRESs.
Domain II was not protected from RNase
cleavage by a 40S subunit bound to the IRES (Fig. 3 and
4). We therefore investigated whether
domain II is necessary for a 40S subunit to interact with all of the
binding sites that we identified in domains III and IV of the IRES.
Binary ribosomal complexes were assembled on HCV nt 118-272.NS' mRNA
and probed enzymatically. There were no major differences in the
patterns of cleavage in domains III and IV by RNase T1 of
transcripts lacking either nt 1 to 40 or nt 1 to 117 (Fig. 4A, lanes 3 and 6; Fig. 4B, lanes 3 and 6). Similarly, there was no significant
difference in the pattern of RNase V1 cleavage in domain
III of these two RNAs, except that sequences at the base of IIId and
downstream of the pseudoknot were more susceptible to RNase
V1 cleavage in the RNA lacking domain II (compare Fig. 3A,
lane 2, and Fig. 3C, lane 3; Fig. 3B, lanes 3 and 6). These results
indicate that deletion of domains I and II did not cause major
structural alterations in domain III or in the pseudoknot.
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FIG. 4.
RNase T1 footprinting of the binary 40S
subunit-HCV IRES complex. Polyacrylamide-urea gel fractionation of cDNA
products obtained after primer extension shows the sensitivity of HCV
nt 40-372 RNA (lanes 1 to 3) or nt 118-372 RNA (lanes 4 to 6) upstream
of nt 360 (A) or of nt 250 (B) to cleavage (lanes 1, 2, 5, and 6)
either alone (lanes 3 and 6) or bound by a 40S subunit (lanes 2 and 5).
cDNA products obtained after primer extension of untreated HCV RNA are
shown in lanes 1 and 4 of both panels. A dideoxynucleotide sequence
generated with the same primer and run in parallel is shown to the left
of both panels. IRES subdomains II, IIIa, IIIb, IIIc, IIId, IIIe, and
PS (pseudoknot) are indicated on the left of each panel; HCV
nucleotides are indicated by black squares at 50-nt intervals, and the
positions of protected residues are marked on the right of each panel.
The position of the initiation codon AUG is indicated to the left of
panel A.
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Ribosomal 40S subunits protected nt 118-272.NS' mRNA from RNase
V
1 cleavage in IIIb (U
220 and weakly at
AG
179-180), in and
adjacent to IIId
(C
242, GC
249-250, A
252, and
U
262), and downstream
of the pseudoknot
(CGU
334-336, A
348, G
350, and
CUA
355-357) in
a similar manner to the protection of the nt
40-372.NS' RNA that
contained domain II (Fig.
3A and C). Protection of
nucleotides
in and adjacent to IIId was slightly greater in the RNA
that lacked
domain II. The only other difference in the pattern of
RNase V
1 cleavage of these two RNAs bound to 40S subunits
is that no enhancement
of cleavage was noted at A
206 or
A
214 on the RNA lacking domain
II (compare Fig.
3A, lane 1, with Fig.
3C, lane 2). IRES transcripts
with or without domain II were
otherwise protected in an equivalent
manner by bound 40S subunits from
cleavage by RNase T
1 in IIId
(GGU
267-269), in
the pseudoknot (C
308 and weakly at A
310), and
flanking the initiation codon (A
332, A
345, and
weakly at C
347)
(Fig.
4). We conclude that a 40S subunit
binds to essentially
the same sites on the HCV IRES whether or not
domain II is present.
Deletion of domain II caused minor changes in the
sensitivity
to nuclease cleavage of domains III and IV and in their
interactions
with 40S subunits (Fig.
3 and
4). Domain II may therefore
interact
weakly with one or both of these domains, as has been
suggested
previously on the basis of the unanticipated resistance to
RNase
T
1 cleavage of some residues in these regions of the
IRES (
14).
An interdomain interaction of this type could
indirectly influence
the precise interaction between a 40S ribosomal
subunit and the
essential domain III/domain IV core of the IRES. A
change in the
interaction of 40S subunits with the IRES in the absence
of the
additional stabilization due to codon-anticodon base pairing was
detected by toeprinting (Fig.
2A, lanes 2 and
4).
Subdomain IIIc is essential for binding of eIF3 to the IRES but is not
required for a 40S subunit to bind to form a stable
binary complex
(
28,
38). It is also not protected from RNase
cleavage by a
40S subunit bound to the IRES. Deletion of IIIc
(
35) caused
only few alterations in the pattern of RNase V
1 cleavage.
We used RNase V
1 footprinting to examine the effect
of this
deletion on ribosomal protection of residues in and upstream
of IIId
(Fig.
5, lanes 1 and 2). Sites at
AG
179-180, U
220, GC
241-242,
GC
249-250, and A
252 were protected by bound 40S
subunits from
cleavage in a similar manner to ribosomal protection of
the intact
IRES. Overall, the pattern of ribosomal protection of this
mutant
RNA closely resembled the pattern of protection of nt 118-372
and nt 40-372 RNAs. This result indicates that the sites on the
IRES
that are protected by a bound 40S subunit are therefore not
significantly altered by deletion of IIIc and/or domain II. However,
some differences in the changes induced by ribosomal binding to
these
three RNAs was noted. Ribosomal binding to the mutant lacking
IIIc
resulted in strong enhancement of cleavage at GA
133-134 and
C
139 at the base of domain III, adjacent to the pseudoknot;
this
effect was not observed for the other two RNAs. Deletion of IIIc
therefore increases conformational changes at sites close to the
pseudoknot caused by ribosomal binding. Enhancement of cleavage
in the
presence of ribosomes was noted at A
205 or A
214
only on
nt 40-372 RNA and not on RNAs that lacked either IIIc or
domains
I and II (compare Fig.
5, lane 1, with Fig.
3C, lane 2).
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FIG. 5.
RNase V1 footprinting of the binary
ribosomal complex formed on HCV nt 40-372 RNA lacking subdomain IIIc
(nt 229 to 238). Polyacrylamide-urea gel fractionation of cDNA products
obtained after primer extension shows the sensitivity of the HCV RNA
upstream of nt 255 to cleavage (lanes 1 and 2) either alone (lane 2) or
bound by a 40S subunit (lane 1). cDNA products obtained after primer
extension of untreated HCV RNA are shown in lane 3. A dideoxynucleotide
sequence generated with the same primer and run in parallel is shown to
the left; HCV nucleotides are indicated by black squares at 50-nt
intervals from nt 100 to 250. IRES subdomains II, IIIa, and IIIb are
indicated on the left, and the positions of protected residues are
indicated to the right. The position of the nt 229-238 deletion is
indicated by an asterisk.
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Interaction of the HCV IRES with ribosomal protein S9.
UV
cross-linking of binary 40S subunit-HCV IRES complexes assembled on HCV
nt 40 to 372 or a corresponding fragment of the CSFV IRES results in
specific radiolabeling of ribosomal protein S9 (Fig.
6A, lane 2), as reported previously
(28). This ribosomal protein also became radiolabeled after
UV cross-linking of binary complexes assembled on HCV nt 118-372.NS'
mRNA, albeit somewhat more weakly than on the transcript containing nt
40 to 373 (Fig. 6A, lane 3). Domain II is therefore not necessary for
this interaction to occur and does not contain the site on the IRES to
which S9 binds. However, an additional deletion of nt 229 to 238 (i.e., of IIIc) made within nt 118-372.NS' mRNA resulted in an almost total
loss of the ability of this IRES fragment to be UV cross-linked to S9
(Fig. 6A, lane 4). We have previously suggested that S9 binds to the
IRES downstream of the initiation codon (28), and we note
that these two deletions both weaken the interaction of the ribosome
with this region (Fig. 2; reference 28).
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FIG. 6.
Ribosomal protein S9 requires the context of the
ribosomal 40S subunit to bind to the HCV IRES. (A and B) UV
cross-linking of native S9 as a constituent of 40S subunits (A, lanes 2 and 3; B, lane 2) and (B) UV cross-linking of recombinant S9 (B, lane
3) to [32P]UTP-labeled HCV nt 40-372 RNA (A, lanes 1 and
2; B, lanes 1 to 3), nt 118 to 372 RNA (A, lane 3) or nt
118-372(229-238) RNA (panel A, lane 4). Samples were treated with
RNases after irradiation, and proteins were resolved by gel
electrophoresis. The position of S9 is indicated to the right of both
panels. (C) Effect of recombinant S9 added with dicistronic cyclin-CSFV
IRES-NS' mRNA at the indicated molar ratios to translation reaction
mixtures on CSFV IRES-mediated NS' translation.
|
|
Ribosomal protein S9 either may be a primary determinant of the HCV
IRES's interaction with the 40S subunit or could bind
to the IRES as a
secondary consequence of another interaction.
To investigate whether S9
alone is able to bind to the HCV IRES
specifically, we expressed and
purified it as a recombinant protein
and then assayed its binding to
the HCV IRES by UV cross-linking.
Cross-linking of the IRES to S9 was
not detected (Fig.
6B, lane
3). This observation suggests that S9 is
unable to bind to the
HCV IRES except in the context of a 40S ribosomal
subunit. If
S9 were to bind directly to the HCV or CSFV IRES, we
reasoned
that it would inhibit translation directed by the IRES because
it would act as a competitive inhibitor of ribosomal binding.
However,
no inhibition of CSFV IRES-mediated translation of an
NS' reporter was
observed when purified recombinant S9 protein
was added in up to
10-fold molar excess over mRNA to translation
reactions programmed with
dicistronic mRNA containing the CSFV
IRES (Fig.
6C). In this
experiment, translation of the upstream
cistron of the dicistronic mRNA
served as a control that the S9
protein did not have general inhibitory
effects on translation.
Taken together, these results suggest that S9
does not act as
a primary determinant of the IRES-40S subunit
interaction by itself,
but they do not exclude the possibility that it
does so in the
context of the 40S ribosomal
subunit.
| |
DISCUSSION |
The ability of the HCV IRES to bind specifically and precisely to
a ribosomal 40S subunit in the absence of initiation factors is an
important characteristic of the mechanism of HCV translation initiation
(10). It is also a step that differentiates initiation on
HCV-like IRESs from initiation by the cap-mediated ribosome-scanning mode that is used by the majority of eukaryotic mRNAs (24).
Toeprinting and deletion analyses indicated that a 40S subunit makes
multiple contacts with the HCV IRES. By using enzymatic footprinting,
we have now identified the principal sites in the IRES that are
protected by a bound 40S subunit. These sites include the helix between
IIIc and IIId, the apex of IIId, the pseudoknot, and nucleotides
flanking both sides of the initiation codon (Fig. 1). These results
confirm that the 40S subunit makes multiple interactions with the IRES
and indicate that these interactions sites are centered in the basal
half of the essential core (nt 120 to 360) of the IRES. The binding
site for eIF3 is located in the apical part of this structure
(38), and these two components of the 43S preinitiation
complex therefore bind to distinct recognition domains in the IRES.
These ribosomal interaction sites are located in regions of very high
sequence conservation in the HCV IRES (39). More generally,
analogous structural regions in pestivirus IRESs also have highly
conserved sequences (1, 9) that are closely related to that
of HCV.
Significantly, the importance of these interaction sites for HCV IRES
function is supported by mutational analyses. Substitution of the
apical GGG266-268 nucleotides in IIId abrogated HCV IRES function (14). Corresponding nucleotides in the CSFV IRES
are also essential for its function, and are also protected from RNase T1 cleavage by a bound 40S subunit (Kolupaeva et al.,
unpublished data). Taken together, the available data lead us to
conclude that they are therefore likely to be one of the primary
determinants of ribosomal binding that are recognized in a
base-specific manner by a component of the 40S subunit. Substitutions
that disrupted base pairing in helix 2 of the HCV pseudoknot reduced
IRES-mediated translation 50- to 100-fold, but significantly,
translation was restored by compensatory "pseudo-revertant"
substitutions in the opposite strand of the helix that restored the
potential for base pairing (41). Precisely analogous
observations have also been made regarding the pseudoknot in the CSFV
IRES (36). The third principal area of the IRES that is
protected by a bound 40S subunit comprises nucleotides flanking the
initiation codon, extending over 26 nt from A332 at the 3'
border of the pseudoknot to A357, 12 nt downstream of the
initiation codon and overlapping the positions of toeprints at the
leading edge of the 40S subunit. The sequence of the coding region is
important for HCV IRES function (22, 33); it is strongly
conserved (33, 37, 39), and toeprinting has shown that
substitutions within it alter the interaction of this region with the
40S subunit (28). Mutations that enhance the propensity of
this region to form base-paired structures also reduce the efficiency
of translation (12); on the basis of results presented here,
we suggest that these mutations impair the ability of the initiation
codon and flanking residues to enter the mRNA-binding cleft of the 40S subunit.
The 26-nt sequence protected by a 40S subunit bound to the HCV
initiation codon corresponds closely to the length of sequences protected by ribosomes on other eukaryotic cellular and viral mRNAs,
which have led to estimates that the eukaryotic ribosomal mRNA-binding
cleft covers 10 to 11 nt upstream and 11 to 14 nt downstream of the
initiation codon (3, 18, 20). This region of the IRES is
therefore likely to be in a nearly fully extended conformation and in
fact undergoes only a minor structural rearrangement when base pairing
between the initiation codon and the anticodon of initiator tRNA is
established (28). This observation suggests that additional
contacts between the 40S subunit and elements of the IRES such as IIId
and the pseudoknot involve regions of the 40S subunit outside the
mRNA-binding cleft. One of these contacts involves ribosomal protein
S9, which is located on the 40S subunit at the other end of the
mRNA-binding cleft from the eIF3-binding site (23). Domain
II of the IRES is not required for this interaction (Fig. 6A) and
therefore does not contain the site on the IRES to which S9 binds. We
have previously suggested that this interaction involves nucleotides
immediately downstream of the pseudoknot (28). The
experiments reported here indicate that S9 does not by itself act as a
determinant of ribosomal attachment to the IRES, although we cannot
rule out that it may do so in the context of the 40S subunit. How
ribosomal binding occurs has not yet been established, but is clear
from the experiments reported here that this process is more
complicated than simple docking of the 40S subunit onto a wholly
preformed IRES structure. Instead, ribosomal binding to the IRES
requires recognition of specific structural elements, and in addition
induces conformational changes in several regions of the IRES,
including IIIb, the pseudoknot, and domain IV.
| |
ACKNOWLEDGMENTS |
This work was supported by grant AI44108-01 from the NIH to
T.V.P. and C.U.T.H.
We thank R. Romain for technical assistance.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: State University
of New York Health Science Center at Brooklyn, 450 Clarkson Ave., Brooklyn, NY 11203. Phone: (718) 270-1034. Fax: (718) 270-2656. E-mail:
chellen{at}netmail.hscbklyn.edu.
| |
REFERENCES |
| 1.
|
Becher, P.,
M. Orlich,
A. D. Shannon,
G. Horner,
M. König, and J.-J. Thiel.
1997.
Phylogenetic analysis of pestiviruses from domestic and wild ruminants.
J. Gen. Virol.
78:1357-1366[Abstract].
|
| 2.
|
Brown, E. A.,
H. Zhang,
L.-H. Ping, and S. M. Lemon.
1992.
Secondary structure of the 5' nontranslated regions of hepatitis C virus and pestivirus genomic RNAs.
Nucleic Acids Res.
20:5041-5045[Abstract/Free Full Text].
|
| 3.
|
Browning, K. S.,
D. W. Leung, and J. M. Clark.
1980.
Protection of satellite tobacco necrosis virus ribonucleic acid by wheat germ 40S and 80S ribosomes.
Biochemistry
19:2276-2283[CrossRef][Medline].
|
| 4.
|
Buratti, E.,
S. Tisminetzky,
M. Zotti, and F. E. Baralle.
1998.
Functional analysis of the interaction between HCV 5' UTR and putative subunits of eukaryotic translation initiation factor eIF3.
Nucleic Acids Res.
26:3179-3187[Abstract/Free Full Text].
|
| 5.
|
Clarke, B.
1997.
Molecular virology of hepatitis C virus.
J. Gen. Virol.
78:2397-2410[Medline].
|
| 6.
|
Ehresmann, C.,
F. Baudin,
M. Mougel,
P. Romby,
J.-P. Ebel, and B. Ehresmann.
1987.
Probing the structure of RNAs in solution.
Nucleic Acids Res.
15:9109-9128[Abstract/Free Full Text].
|
| 7.
|
Frigerio, J.-M.,
J.-C. Dagorn, and J. L. Iovanna.
1995.
Complete sequencing and expression of the L5, L21, L27A, L28, S5, S9, S10 and S29 human ribosomal protein RNAs.
Biochim. Biophys. Acta
1262:64-68[Medline].
|
| 8.
|
Fukushi, S.,
K. Katayama,
C. Kurihara,
N. Ishiyama,
F. B. Hoshino,
T. Ando, and A. Oya.
1994.
Complete 5' noncoding region is necessary for the efficient internal initiation of hepatitis C virus RNA.
Biochem. Biophys. Res. Commun.
199:425-432[CrossRef][Medline].
|
| 9.
|
Harasawa, R.
1996.
Phylogenetic analysis of pestivirus based on the 5'-untranslated region.
Acta Virol.
40:49-54[Medline].
|
| 10.
|
Hellen, C. U. T., and T. V. Pestova.
1999.
Translation of hepatitis C virus RNA.
J. Viral Hepatitis
6:79-88[CrossRef][Medline].
|
| 11.
|
Honda, M.,
M. R. Beard,
L.-H. Ping, and S. M. Lemon.
1999.
A phylogenetically conserved stem-loop structure a the 5' border of the internal ribosome entry site of hepatitis C virus is required for cap-independent viral translation.
J. Virol.
73:1165-1174[Abstract/Free Full Text].
|
| 12.
|
Honda, M.,
E. A. Brown, and S. M. Lemon.
1996.
Stability of a stem-loop involving the initiator AUG controls the efficiency of internal initiation of translation on hepatitis C virus RNA.
RNA
2:955-968[Abstract].
|
| 13.
|
Kamoshita, N.,
K. Tsukiyama-Kohara,
M. Kohara, and A. Nomoto.
1997.
Genetic analysis of internal ribosome entry site on hepatitis C virus RNA: implication for involvement of the highly ordered structure and cell type-specific trans-acting factors.
Virology
233:9-18[CrossRef][Medline].
|
| 14.
|
Kieft, J. S.,
K. Zhou,
R. Jubin,
M. G. Murray,
J. Y. N. Lau, and J. A. Doudna.
1999.
The hepatitis C virus internal ribosomal entry site adopts an ion-dependent tertiary fold.
J. Mol. Biol.
292:513-529[CrossRef][Medline].
|
| 15.
|
Kolupaeva, V. G.,
C. U. T. Hellen, and I. N. Shatsky.
1996.
Structural analysis of the interaction of the pyrimidine tract-binding protein with the internal ribosomal entry site of encephalomyocarditis virus and foot-and-mouth disease virus RNAs.
RNA
2:1199-1212[Abstract].
|
| 16.
|
Kolupaeva, V. G.,
T. V. Pestova,
C. U. T. Hellen, and I. N. Shatsky.
1998.
Translation initiation factor eIF4G recognizes a specific structural element within the internal ribosomal entry site of encephalomyocarditis virus RNA.
J. Biol. Chem.
273:18599-18604[Abstract/Free Full Text].
|
| 17.
|
Kozak, M.
1977.
Nucleotide sequences of 5'-terminal ribosome-protected initiation regions from two reovirus messages.
Nature
269:390-394[CrossRef].
|
| 18.
|
Kozak, M., and A. J. Shatkin.
1977.
Sequences and properties of two ribosome binding sites from the small size class of reovirus messenger RNA.
J. Biol. Chem.
252:6895-6908[Free Full Text].
|
| 19.
|
Le, S.-Y.,
W. M. Liu, and J. V. Maizel.
1998.
Phylogenetic evidence for the improved RNA higher-order structure in internal ribosome entry sequences of HCV and pestiviruses.
Virus Genes
17:279-295[CrossRef][Medline].
|
| 20.
|
Legon, S.
1976.
Characterization of the ribosome-protected regions of 125I-labelled rabbit globin messenger RNA.
J. Mol. Biol.
106:37-53[CrossRef][Medline].
|
| 21.
|
Lemon, S. M., and M. Honda.
1997.
Internal ribosome entry sites within the RNA genomes of hepatitis C virus and other flaviviruses.
Semin. Virol.
8:274-288[CrossRef].
|
| 22.
|
Lu, H. H., and E. Wimmer.
1996.
Poliovirus chimeras replicating under the translational control of genetic elements of hepatitis C virus reveal unusual properties of the internal ribosomal entry site of hepatitis C virus.
Proc. Natl. Acad. Sci. USA
93:1412-1417[Abstract/Free Full Text].
|
| 23.
|
Lütsch, G.,
H. Bielka,
G. Enzmann, and F. Noll.
1983.
Electron microscopic investigations on the location of rat liver ribosomal proteins S3a, 5, S6, S7, and S9 by means of antibody labeling.
Biomed. Biochim. Acta
42:705-723[Medline].
|
| 24.
|
Merrick, W. C.
1992.
Mechanism and regulation of eukaryotic protein synthesis.
Microbiol. Rev.
56:291-315[Abstract/Free Full Text].
|
| 25.
|
Pause, A.,
N. Méthot,
Y. Svitkin,
W. C. Merrick, and N. Sonenberg.
1994.
Dominant negative mutants of mammalian translation initiation factor eIF-4A define a critical role for eIF-4F in cap-dependent and cap-independent initiation of translation.
EMBO J.
13:1205-1215[Medline].
|
| 26.
|
Pestova, T. V.,
S. I. Borukhov, and C. U. T. Hellen.
1998.
Eukaryotic ribosomes require eIFs 1 and 1A to locate initiation codons.
Nature
394:854-859[CrossRef][Medline].
|
| 27.
|
Pestova, T. V., and C. U. T. Hellen.
1999.
Internal initiation of translation of bovine viral diarrhea virus RNA.
Virology
258:249-256[CrossRef][Medline].
|
| 28.
|
Pestova, T. V.,
I. N. Shatsky,
S. P. Fletcher,
R. J. Jackson, and C. U. T. Hellen.
1998.
A prokaryotic-like mode of cytoplasmic eukaryotic ribosome binding to the initiation codon during internal initiation of translation of hepatitis C virus and classical swine fever virus RNAs.
Genes Dev.
12:67-83[Abstract/Free Full Text].
|
| 29.
|
Pestova, T. V.,
C. U. T. Hellen, and I. N. Shatsky.
1996.
Canonical eukaryotic initiation factors determine initiation of translation by internal ribosomal entry.
Mol. Cell. Biol.
16:6859-6869[Abstract].
|
| 30.
|
Poole, T. L.,
C. Wang,
R. A. Popp,
L. N. D. Potgieter,
A. Siddiqui, and M. S. Collett.
1995.
Pestivirus translation initiation occurs by internal ribosome entry.
Virology
206:750-754[CrossRef][Medline].
|
| 31.
|
Pringle, C. R.
1999.
The universal system of virus taxonomy, updated to include the new proposals ratified by the International Taxonomy of Viruses during 1998.
Arch. Virol.
144:421-429[CrossRef][Medline].
|
| 32.
|
Reynolds, J. E.,
A. Kaminski,
A. R. Carroll,
B. E. Clarke,
D. J. Rowlands, and R. J. Jackson.
1996.
Internal initiation of translation of hepatitis C virus RNA: the ribosome entry site is at the authentic initiation codon.
RNA
2:867-878[Abstract].
|
| 33.
|
Reynolds, J. E.,
A. Kaminski,
H.-J. Kettinen,
A. R. Carroll,
D. J. Rowlands, and R. J. Jackson.
1995.
Unique features of internal initiation on hepatitis C virus.
EMBO J.
14:6010-6020[Medline].
|
| 34.
|
Rijnbrand, R. C.,
T. E. Abbink,
P. C. Haasnoot,
W. J. Spaan, and P. J. Bredenbeek.
1996.
The influence of AUG codons in the hepatitis C virus 5' nontranslated region on translation and mapping of the translation initiation window.
Virology
226:47-56[CrossRef][Medline].
|
| 35.
|
Rijnbrand, R.,
P. J. Bredenbeek,
T. van der Straaten,
L. Whetter,
G. Inchauspé,
S. Lemon, and W. Spaan.
1995.
Almost the entire 5' non-translated region of hepatitis C virus is required for cap-independent translation.
FEBS Lett.
365:115-119[CrossRef][Medline].
|
| 36.
|
Rijnbrand, R.,
T. Van der Straaten,
P. A. van Rijn,
W. J. Spaan, and P. J. Bredenbeek.
1997.
Internal entry of ribosomes is directed by the 5' noncoding region of classical swine fever virus and is dependent on the presence of an RNA pseudoknot upstream of the initiation codon.
J. Virol.
71:451-457[Abstract].
|
| 37.
|
Simmonds, P.
1995.
Variability of hepatitis C virus.
Hepatology
21:570-583[CrossRef][Medline].
|
| 38.
|
Sizova, D. V.,
V. G. Kolupaeva,
T. V. Pestova,
I. N. Shatsky, and C. U. T. Hellen.
1998.
Specific interaction of eukaryotic translation initiation factor 3 with the 5' nontranslated regions of hepatitis C virus and classical swine fever virus RNAs.
J. Virol.
72:4775-4782[Abstract/Free Full Text].
|
| 39.
|
Smith, D. B.,
J. Mellor,
L. M. Jarvis,
F. Davidson,
J. Kolberg,
M. Urdea,
P.-L. Yap,
P. Simmonds, and The International HCV Collaborative Study Group.
1995.
Variation of the hepatitis C virus 5' non-coding region: implications for secondary structure, virus detection and typing.
J. Gen. Virol.
76:1749-1761[Abstract/Free Full Text].
|
| 40.
|
Tsukiyama-Kohara, K.,
N. Iizuka,
M. Kohara, and A. Nomoto.
1992.
Internal ribosomal entry site within hepatitis C virus RNA.
J. Virol.
66:1476-1483[Abstract/Free Full Text].
|
| 41.
|
Wang, C.,
S. Le,
N. Ali, and A. Siddiqui.
1995.
An RNA pseudoknot is an essential structural element of the internal ribosome entry site located within the hepatitis C virus 5' noncoding region.
RNA
1:526-537[Abstract].
|
| 42.
|
Wang, C.,
P. Sarnow, and A. Siddiqui.
1993.
Translation of human hepatitis C virus RNA in cultured cells is mediated by an internal ribosome-binding mechanism.
J. Virol.
67:3338-3344[Abstract/Free Full Text].
|
| 43.
|
Wang, C.,
P. Sarnow, and A. Siddiqui.
1994.
A conserved helical element is essential for internal initiation of translation of hepatitis C virus RNA.
J. Virol.
68:7301-7307[Abstract/Free Full Text].
|
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[Full Text]
-
Tallet-Lopez, B., Aldaz-Carroll, L., Chabas, S., Dausse, E., Staedel, C., Toulme, J.-J.
(2003). Antisense oligonucleotides targeted to the domain IIId of the hepatitis C virus IRES compete with 40S ribosomal subunit binding and prevent in vitro translation. Nucleic Acids Res
31: 734-742
[Abstract]
[Full Text]
-
Randall, G., Grakoui, A., Rice, C. M.
(2003). Clearance of replicating hepatitis C virus replicon RNAs in cell culture by small interfering RNAs. Proc. Natl. Acad. Sci. USA
100: 235-240
[Abstract]
[Full Text]
-
Lafuente, E., Ramos, R., Martinez-Salas, E.
(2002). Long-range RNA-RNA interactions between distant regions of the hepatitis C virus internal ribosome entry site element. J. Gen. Virol.
83: 1113-1121
[Abstract]
[Full Text]
-
Fletcher, S. P., Jackson, R. J.
(2002). Pestivirus Internal Ribosome Entry Site (IRES) Structure and Function: Elements in the 5' Untranslated Region Important for IRES Function. J. Virol.
76: 5024-5033
[Abstract]
[Full Text]
-
Bag, J.
(2001). Feedback Inhibition of Poly(A)-binding Protein mRNA Translation. A POSSIBLE MECHANISM OF TRANSLATION ARREST BY STALLED 40 S RIBOSOMAL SUBUNITS. J. Biol. Chem.
276: 47352-47360
[Abstract]
[Full Text]
-
Odreman-Macchioli, F., Baralle, F. E., Buratti, E.
(2001). Mutational Analysis of the Different Bulge Regions of Hepatitis C Virus Domain II and Their Influence on Internal Ribosome Entry Site Translational Ability. J. Biol. Chem.
276: 41648-41655
[Abstract]
[Full Text]
-
Lytle, J. R., Wu, L., Robertson, H. D.
(2001). The Ribosome Binding Site of Hepatitis C Virus mRNA. J. Virol.
75: 7629-7636
[Abstract]
[Full Text]
-
Hellen, C. U.T., Sarnow, P.
(2001). Internal ribosome entry sites in eukaryotic mRNA molecules. Genes Dev.
15: 1593-1612
[Full Text]
-
Pestova, T. V., Kolupaeva, V. G., Lomakin, I. B., Pilipenko, E. V., Shatsky, I. N., Agol, V. I., Hellen, C. U. T.
(2001). Molecular mechanisms of translation initiation in eukaryotes. Proc. Natl. Acad. Sci. USA
98: 7029-7036
[Abstract]
[Full Text]
-
Martínez-Salas, E., Ramos, R., Lafuente, E., López de Quinto, S.
(2001). Functional interactions in internal translation initiation directed by viral and cellular IRES elements. J. Gen. Virol.
82: 973-984
[Full Text]
-
Myers, T. M., Kolupaeva, V. G., Mendez, E., Baginski, S. G., Frolov, I., Hellen, C. U. T., Rice, C. M.
(2001). Efficient Translation Initiation Is Required for Replication of Bovine Viral Diarrhea Virus Subgenomic Replicons. J. Virol.
75: 4226-4238
[Abstract]
[Full Text]
-
Spahn, C. M. T., Kieft, J. S., Grassucci, R. A., Penczek, P. A., Zhou, K., Doudna, J. A., Frank, J.
(2001). Hepatitis C Virus IRES RNA-Induced Changes in the Conformation of the 40S Ribosomal Subunit. Science
291: 1959-1962
[Abstract]
[Full Text]
-
KIEFT, J.S., GRECH, A., ADAMS, P., DOUDNA, J.A.
(2001). Mechanisms of Internal Ribosome Entry in Translation Initiation. Cold Spring Harb Symp Quant Biol
66: 277-284
[Abstract]
-
Fukushi, S., Okada, M., Stahl, J., Kageyama, T., Hoshino, F. B., Katayama, K.
(2001). Ribosomal Protein S5 Interacts with the Internal Ribosomal Entry Site of Hepatitis C Virus. J. Biol. Chem.
276: 20824-20826
[Abstract]
[Full Text]
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Abstract
Introduction
