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Previous Article | Next Article 
Journal of Virology, June 2000, p. 5639-5646, Vol. 74, No. 12
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
The Human Immunodeficiency Virus Type 1 TAR RNA
Upper Stem-Loop Plays Distinct Roles in Reverse Transcription and
RNA Packaging
David
Harrich,*
C.
William
Hooker, and
Emma
Parry
HIV Research Unit, National Centre for HIV
Virology Research, Sir Albert Sakzewski Virus Research Centre,
Royal Children's Hospital, Herston, Queensland, Australia 4029
Received 27 January 2000/Accepted 7 March 2000
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ABSTRACT |
The human immunodeficiency virus type 1 (HIV-1) RNA genome is
flanked by a repeated sequence (R) that is required for HIV-1 replication. The first 57 nucleotides of R form a stable stem-loop structure called the transactivation response element (TAR) that can
interact with the virally encoded transcription activator protein, Tat,
to promote high levels of gene expression. Recently, we demonstrated
that TAR is also important for efficient HIV-1 reverse transcription,
since HIV-1 mutated in the upper stem-loop of TAR showed a reduced
ability both to initiate and to complete reverse transcription. We have
analyzed a series of HIV-1 mutant viruses to better defined the
structural or sequence elements required for natural endogenous reverse
transcription and packaging of virion RNA. Our results indicate that
the requirement for TAR in reverse transcription is conformation
dependent, since mutants with mutations that alter the upper stem-loop
orientation are defective for reverse transcription initiation and have
minor defects in RNA packaging. In contrast, TAR mutations that allowed the formation of alternative upper stem-loop structure greatly reduced
RNA packaging but did not affect reverse transcription efficiency.
These results are consistent with direct involvement of the upper
stem-loop structure in packaging of genomic RNA and suggest that the
TAR RNA stem-loop from nucleotide +18 to +42 interacts with other
components of the reverse transcription initiation complex to promote
efficient reverse transcription.
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INTRODUCTION |
The human immunodeficiency virus
type 1 (HIV-1) RNA genome can form numerous RNA structures, many of
which regulate virus replication. Viral RNA structures are required for
many processes, including transcription by RNA polymerase II,
polyadenylation of viral mRNA, transport of singly spliced and
unspliced viral mRNA, viral genomic RNA dimerization and packaging, and
reverse transcription. For example, the TAR element, which comprises
the first 57 nucleotides (nt) of the viral transcript, can form a stable stem-loop structure. The Tat protein and cellular kinases, which
are recruited by Tat, can bind to the TAR stem-loop to enable efficient
transcription by RNA polymerase II (for reviews, see references
12a and 24a). Another example is
the HIV-1 RNA packaging signal, which includes a series of RNA
stem-loop structures (designated SL1, SL3, and SL4) which flank the 5'
major splice donor site (3, 9, 19, 27) and bind to the
nucleocapsid domain of the pr55 Gag protein to promote packaging of
unspliced HIV-1 transcripts into virions (2, 5, 12, 29).
Another regulatory viral RNA structure is formed by sequences flanking
the primer binding site in conjunction with cellular
tRNA3Lys. Interactions between an A-rich loop upstream
of the virus primer binding site and the anticodon loop of
tRNA3Lys are reported to be required for the formation
of an efficient reverse transcription initiation complex (21, 23,
24).
It has long been appreciated that a single viral RNA structure can have
effects on multiple steps in the replication cycle. The TAR element,
for example, has also been shown to reduce translation of viral mRNA
both in Xenopus oocyte microinjection assays and in
cell-free translation systems (6, 31). Genetic analysis of
TAR showed that maintenance of the TAR stem-loop structure and the
primary sequence of the loop were required for inhibition of HIV-1
translation. Mutations that disrupted the TAR lower stem increased
translation efficiency, while compensatory mutations that restored stem
base pairing also restored TAR-mediated inhibition of translation. More
recently, TAR has been implicated in the encapsidation of virus genomic
RNA (8, 11, 20, 28). Viruses lacking the TAR element or
carrying mutations that disrupted the lower portion of the TAR stem
structure reduced RNA encapsidation, and some, but not all, of these
mutations reduced reverse transcription efficiency. As with
translation, compensatory mutations that restored TAR base pairing also
restored RNA encapsidation, indicating that TAR structure, but not
primary sequence, is required for efficient RNA encapsidation. How TAR
acts in packaging is not known, but evidence that distinct pools of
genomic RNA are packaged into virions makes it plausible that
TAR-mediated inhibition of translation may contribute to the selection
of nontranslated genomic RNA by Gag in the packaging process
(26). In a previous study, we showed that mutations within
the upper TAR stem-loop structure greatly reduced reverse transcription
efficiency, but no defect in RNA encapsidation was observed
(18). In the present study, we constructed further HIV-1 TAR
mutations and determined their effects on viral reverse transcription
and RNA packaging. Our results suggest that TAR's role in reverse
transcription is dependent on the conformation of the upper stem-loop
structure, from nucleotides +18 to +42, and that this region of TAR
also supports RNA encapsidation.
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MATERIALS AND METHODS |
Plasmids and sequences.
All HIV-1 sequence notations take
the transcription start site (GGG of TAR) as +1. The HIV-1
infectious molecular construct pBRDH2-neo and procedures used to
introduce TAR mutations into this construct have been previously
described (15). Briefly, a plasmid containing HIV-1
sequences from position 
160 to +988 was mutagenized using the
QuickChange mutagenesis system and oligonucleotides that included the
desired mutations in both DNA strands. The mutations were confirmed by
DNA sequence determination using the Sequenase system (Amersham
Pharmacia Biotec) and ligated into pBRDH2-neo. The runoff RNA used as
an internal control in quantitative reverse transcriptase PCR (RT-PCR)
analysis was synthesized from a pGEM3z (Promega Australia Pty. Ltd.)
construct containing HIV-1 sequences from position 22 to +553 with an
internal deletion from +80 to +151. The construct was linearized with
EcoRI and used as the template for in vitro transcription by
SP6 RNA polymerase. The runoff RNA used for quantitative RNA protection
assays was synthesized from a pGem4z (Promega Australia Pty. Ltd.)
construct containing HIV-1 sequences from position +113 to +553. This
construct was linearized with EcoRI and used as the template
for in vitro synthesis of radiolabeled RNA riboprobe using
[32P]CTP (400 Ci/mmol) (ICN Pharmaceuticals) and T7 RNA
polymerase (Promega Australia Pty. Ltd.). All in vitro transcripts were
purified from 5% polyacrylamide gels before use.
Cell lines, viruses, and infections.
All cells were
incubated at 37°C in a humidified 5% CO2 atmosphere. The
method by which stable cell lines were generated is described in detail
elsewhere (15). Briefly, 293 cells were transfected with the
mutated pBRDH2-neo construct, allowed to recover for 48 h, and
then serially diluted in Iscove's modified Dulbecco minimal essential
medium (IMDM) supplemented with 1% penicillin-streptomycin, 1 mM
Glutamax, 5% newborn calf serum, and 2% fetal bovine serum (complete
IMDM) plus 800 µg of G418 sulfate (Life Technologies) per ml.
Individual cell foci were isolated and expanded, and supernatant from
each culture was assayed for HIV-1 p24 antigen (Ag). Cell lines that
produced p24 Ag were further characterized.
Virus stocks were produced and assayed as previously described
(32). Briefly, 293 cell lines stably transfected with either wild-type or TAR mutant virus were grown in 100-mm-diameter tissue culture dishes in complete IMDM supplemented with 500 µg of G418 sulfate per ml. When the cells reached 50% confluency, the supernatant was replaced with complete IMDM lacking G418 sulfate, and the plates
were incubated for a further 18 to 24 h. The medium was collected,
filtered through a 0.45-mm-pore-size PES membrane, and stored in
aliquots at 80°C. The virus stocks were assayed for HIV-1 p24 Ag
using a commercial enzyme-linked immunosorbent assay (NEN Life Science
Products) and for RT activity using the RT Detect Assay (Roche
Diagnostics Australia Pty. Ltd.).
To infect Jurkat cells, filtered culture supernatant containing 90 mU
of RT activity was adjusted to 10 ml with cell-conditioned culture
medium and incubated with 2 × 106 cells for 2 h
with gentle rotation. Mock infections were carried out with wild-type
virus inactivated by incubation at 60°C for 20 min. The infected
Jurkat cells were washed three times with culture medium to remove
residual virus and incubated in RPMI 1640 medium supplemented with 1%
penicillin-streptomycin, 1 mM Glutamax, and 10% fetal bovine serum.
The cells were passaged twice weekly and assayed for p24 Ag by
enzyme-linked immunosorbent assay as described above.
PCR and RT-PCR assays.
Chromosomal DNA was isolated from 293 cell lines using DNAzol (Life Technologies). The long terminal repeats
(LTRs) of TAR mutant viruses were amplified by 30 cycles of PCR (95, 55, and 72°C for 1 min each) using purified chromosomal DNA (500 ng)
as a template, 1.25 U of Platinum Taq DNA polymerase (Life
Technologies), and 50 ng of each of the following oligonucleotide
pairs: 5' LTR, 436/415 (5'-CCC AAA CAA GAC AAG AGA TTG A, sense)
and +242/+219 (5'-CCT GCG TCG AGA GAG CTC CTC TGG, antisense); 3' LTR,
+8605/+8625 (5'-GCA GCT TTA GAT ATT AGC CAC, sense) and +9282/+9258
(5'-CTG CTA GAG ATT TTT CCA CAC TGA C, antisense). The 678- and 677-bp PCR products amplified from the 5' and 3' LTRs, respectively, were
ligated into pGemTeasy (Promega) and analyzed by DNA sequencing.
Quantitative RT-PCR was carried out on virion-associated RNA isolated
from pelleted virus particles. DNase I-treated stocks of wild-type or
TAR mutant virus were subjected to centrifugation through a 20%
sucrose cushion at 120,000 × g for 90 min at 4°C and
resuspended in serum-free IMDM. The viral suspensions were assayed for
p24 Ag and RT activity as described above. Equal amounts of p24 Ag (100 ng) were solubilized with Trizol (Life Technologies) according to the
manufacturer's recommendations, and 5 ng of internally deleted HIV-1
internal control RNA was added to monitor RNA recovery and in vitro
reverse transcription efficiency. Nucleic acids were precipitated
overnight and recovered by centrifugation at 15,000 × g at 28°C for 1 h. The visible pellets were rinsed with
70% ethanol and dissolved in 30 µl of water. Virion RNA was reverse transcribed using C-Therm DNA polymerase (Roche Diagnostics Australia Pty. Ltd.) according to the manufacturer's instructions in duplicate reaction mixtures containing 10 µl of viral RNA and 50 ng of either first-strand primer B (+412/+387; 5'-GAC TGC GAA TCG TTC TAG CTC CCT
GC, antisense) or first-strand primer A (+288/+267; 5'-CAG TCG CCG CCC
CTC GCC TCT TG, antisense). The RT reaction mixtures were serially
diluted and assayed for the internal control RNA by 27 cycles of PCR as
described above with oligonucleotide primers complementary to the
polylinker region of pGem3z (5'-GGG AGA CAA GCT TGC ATG CCT G, sense)
and to HIV-1 sequences from position +65 to +46 (5'-AAG CAG TGG GTT CCC
TAG TTA G, antisense). The HIV-1-specific primer was radiolabeled using
T4 polynucleotide kinase and [
-32P]ATP. The reaction
mixtures were normalized according to internal control cDNA
concentrations and assayed for HIV-1 cDNA by 30 cycles of PCR as
described above with a radiolabeled HIV-1-specific oligonucleotide, primer +96/+118 (5'-CAA GTA GTG TGT GCC CGT CTG TT, sense), and an
unlabeled primer, +182/+158 (5'-CTG CTA GAG ATT TTT CCA CAC TGA C,
antisense). The PCR products were then separated on 5% polyacrylamide
(19:1 acrylamide/bisacrylamide ratio) gels and quantified by
PhosphorImager (Molecular Dynamics) analysis using PCR standard curves
generated from plasmids containing the target sequences. All PCRs were
performed in the linear range of the assay.
RNA protection assay.
RNA protection assays were performed
using an RPAII kit (Ambion) according to the manufacturer's
instructions. Briefly, DNase I-treated sucrose cushion-purified virus
containing 100 ng of p24 Ag was solubilized along with 10 µg of
purified yeast RNA and a radiolabeled RNA riboprobe (Promega Australia
Pty. Ltd.) using Trizol reagent (Life Technologies). The RNA mixtures
were incubated in the hybridization solution provided with the kit at
46°C for 16 h and digested with a combination of RNase
T1 and RNase A. The digested RNAs were precipitated with
ethanol and centrifuged at 12,000 × g at 4°C, and
the pellets were resuspended in the RNA loading dye provided. The
digested RNAs were separated on denaturing (7.3 M urea) 5%
polyacrylamide gels and visualized and quantitated by PhosphorImager
(Molecular Dynamics) analysis.
RT assays.
Wild-type and TAR mutant virus stocks were
assayed for total RT activity on a synthetic homopolymer template in
the presence of detergent using the RT Detect Assay (Roche Diagnostics)
according to the manufacturer's instructions. Aliquots of virus
(typically 1.0 mU of RT activity) were supplemented with 10 mM
MgCl2 and incubated for 30 min at 37°C with 100 U of
DNase I in a final volume of 200 µl of IMDM. Reverse transcription
was terminated in half of the DNase I-treated virus stock by the
addition of 150 µl of stop solution (10 mM Tris-HCl [pH 7.4], 10 mM
EDTA, 20 mg of sheared salmon sperm DNA per ml, and 50 mg of proteinase K per ml) followed by incubation at 37°C for 10 min and then boiling for 10 min. The remaining 100 µl was supplemented with 200 µM deoxynucleoside triphosphates and incubated at 37°C for 90 min, and
then the reaction was terminated as described above. The stopped reaction mixtures were centrifuged briefly at 14,000 × g, and 10 µl of each was assayed for negative-strand strong-stop
DNA by 34 cycles of PCR (65°C for 2 min and 93°C for 1 min) using the HIV-1-specific oligonucleotide primers +96/+118 (radiolabeled) and
+158/+182 in the presence of 3.5 mM MgCl2 to compensate for EDTA present in the stop mix. PCR standard curves were generated by
amplifying serial dilutions of an HIV-1 proviral plasmid, and all PCRs
were performed in the linear range of the assay.
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RESULTS |
Isolation and characterization of cell lines making wild-type and
TAR mutant HIV-1.
In a previous study we identified HIV-1 viruses
with mutated TAR RNA sequences which supported transactivation by Tat
and high levels of gene expression but did not support efficient virus replication (18). Our original analysis showed that these
viruses were defective for reverse transcription. However, two recent reports have shown that mutations of the HIV-1 lower stem-loop resulted
in decreased packaging of virus genomic RNA and supported packaging of
HIV-1 spliced RNA transcripts (8, 11). Our original study
found either minor or no packaging defects but did not exclude the
possibility that packaging of spliced RNA transcripts was responsible
for the observed reverse transcription defects.
The following mutations were introduced into the TAR RNA upper
stem-loop structure in the HIV-1 proviral construct pBRDH2-neo: a
six-base deletion of nt +19 to +24 (TAR2), a three-base deletion of nt
+22 to +24 in combination with a compensatory UCU insertion (TAR3), and
a three-base substitution at nt +15, +16, and +18 (TAR4) (Fig.
1). Each mutated proviral DNA was
transfected into 293 cells, and stable cell lines producing each TAR
mutant virus were selected and characterized as previously described
(15). In addition, three stable cell lines which have been
described elsewhere (15) were used to produce viruses
carrying the following TAR RNA mutations: a three-base deletion from nt
+22 to +24 (TAR1); a four-base substitution at nt +18, +19, +21 and +39
(TAR5); and a six-base substitution mutation, nt +18, +19, +21/+39,
+41, and +42, that maintained TAR RNA structure (TAR6) (Fig. 1).
Supernatant from each cell line was subjected to ultracentrifugation
through a 20% sucrose cushion. The virus pellets were resuspended in
serum-free RPMI 1640 medium, and their p24 Ag contents and total RT
activities were measured. More than 90% of the p24 Ag present in
culture supernatants was recovered from the pellets, and RT activity
was detected only in the virus pellets (data not shown). The ratio of
p24 Ag concentration to total RT activity was calculated for each virus
stock, and the p24/total RT ratios observed in TAR mutant and wild-type
virus stocks fell within the same range (Table 1).
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FIG. 1.
RNA stem-loop structures and stem energies of wild-type
and mutated TAR RNA sequences. TAR mutations are shown as follows: 1, 3-nt deletion from position +22 to +24 (TAR1); 2, 6-nt deletion from
position +19 to +24 (TAR2); 3, combined 3-nt deletion from position +22
to +24 and compensatory 3-nt insertion of UCU at position +39 (TAR3);
4, three nucleotide substitutions at positions +15, +16, and +18
(TAR4); 5, four nucleotide substitutions at positions +18, +19, +21,
and +39 (TAR5); and 6, six nucleotide substitutions, at nt +18, +19,
+21, +39, +41, and +42, that maintained the stem-loop structure (TAR6).
RNA stem-loop structure energies ( G), shown in
kilocalories per mole, were predicted using M-fold version 3.0 (copyright 1996 by M. Zuker; http://mfold.burnet.edu.au).
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Jurkat cells were infected with equivalent amounts of each virus for
2 h, after which the virus was removed. Infected and mock-infected
cells were cultured for 3 weeks, and the culture supernatant was
sampled twice weekly. The peak amount of p24 Ag produced by each
infection was used as a measure of the replication potential of each
virus and was expressed relative to the wild-type level (Table 1). TAR6
virus, which had an intact TAR-like RNA stem-loop structure, replicated
at wild-type levels as previously observed. In contrast, the TAR1,
TAR2, and TAR3 mutants failed to replicate at all, while TAR4 and TAR5
replicated at very low levels. These results are consistent with
previous reports on the effect of TAR mutations on virus replication
kinetics (15, 25). The previously observed capacity of these
TAR structures to support activation of HIV-1 gene expression by Tat
correlated with both the replication kinetics observed in Jurkat cells
and the levels of virus made by stably transfected 293 cells (4, 13, 14, 16).
An intact upper TAR structure is required for natural endogenous
reverse transcription.
We used PCR to measure the amounts of
negative strong-stop DNA synthesized by each of these viruses in
natural endogenous reverse transcription (NERT) assays (32,
35), and we expressed the NERT capacity of each virus relative to
that of the wild type. Consistent with previous results in a cell
infection assay system, the TAR1 and TAR6 mutants produced 63 and 71%,
respectively, of wild-type amounts of negative strong-stop DNA in NERT
assays (Fig. 2). In contrast, the TAR2,
TAR3, TAR4, and TAR5 mutants displayed only 10 to 17% of wild-type
NERT capacity (Fig. 2). It is therefore apparent that deletion of
sequences from position +22 to +24 had only minor effects on reverse
transcription, while transposition of the bulge (TAR3, nt +37 to +38)
resulted in defective reverse transcription. These NERT results
confirmed that the stem structure, but not the primary sequence, of TAR
from position +18 to +21 and +39 to +42 is required for optimal HIV-1
reverse transcription initiation. TAR5, which has a symmetrical
internal loop at +19/+41, was also defective for negative strong-stop
DNA synthesis in NERT assays. Finally, the TAR4 mutation, which,
according to stem energy calculations (36), favors an
alternate structure over a less stable TAR-like RNA conformation, also
reduced negative strong-stop DNA synthesis relative to that of the wild
type.
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FIG. 2.
Representative NERT assay of wild-type and TAR mutant
viruses. (A) negative strong-stop DNA detected by PCR in NERT reactions
with TAR1, TAR2, TAR3, TAR4, TAR5, TAR5, TAR6, or wild-type virus
(lanes 1 to 7, respectively) or mock supernatant (lane 8). (B)
PhosphorImager analysis of the PCR shown in panel A; DNA copy number is
indicated. (C) PCR standard curve generated using an HIV-1 proviral
plasmid. (D) PhosphorImager analysis of the gel shown in panel C;
r2 = 0.996.
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An intact upper TAR structure is required for efficient packaging
of HIV-1 genomic RNA.
A previous analysis of HIV-1 TAR mutants
(18) failed to detect significant defects in RNA packaging,
but that study did not eliminate the possibility that defects in RNA
packaging resulted in the encapsidation of spliced HIV-1 RNA species.
Therefore, we performed both RT-PCR and RNA protection assays to
quantitate and characterize virion RNA content in viruses with mutated
TAR sequences. The RT-PCR strategy was similar to a previously
described strategy (Fig. 3). Briefly, an
in vitro-transcribed HIV-1 RNA with an internal 71-nt deletion was used
as an internal control in the RT-PCR assay. Partially purified virus
containing 100 ng of p24 Ag was lysed in Trizol solution, and 5 ng of
synthetic internal control RNA was added. First-strand cDNA synthesis
was performed in separate reactions using primer A, which hybridized to
both spliced and unspliced RNA, and primer B, which hybridized only to
unspliced RNA. The cDNA products were analyzed by PCR using primers
specific for HIV-1 or internal control sequences. The PCR products were
separated by polyacrylamide gel electrophoresis and then visualized and
quantitated with a Molecular Dynamics PhosphorImager. As shown in Fig.
4, similar levels of HIV-1 genomic RNA
were measured by RT-PCR in the TAR1, TAR5, TAR6, and wild-type viruses.
RNA packaging in the TAR2 and TAR4 viruses was reduced to approximately
55% and approximately 10%, respectively, of the wild-type level. The
overall reduction in copy numbers detected in first-strand reactions
containing primer B, compared to primer A, was due to the lower
efficiency of primer B in first-strand synthesis and was consistent
between HIV-1-specific and internal control primers.
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FIG. 3.
RT-PCR strategy. HIV-1 genomic RNA (A) was isolated from
virus containing 100 ng of p24 Ag along with added synthetic internal
control RNA (B) containing plasmid sequence (dotted line) and HIV-1
sequences from position 22 to +517, except for an internal deletion
from +80 to +151. The isolated RNA was reverse transcribed in separate
reactions using the first-strand primers shown (solid arrows). Primer A
can anneal to either spliced or unspliced HIV-1 RNA, while primer B can
anneal to unspliced but not to spliced HIV-1 RNA; both primers can
anneal to internal control RNA. HIV-1 and internal control cDNAs were
detected by PCR using the primers shown (dotted arrows). PBS, primer
binding site.
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FIG. 4.
RT-PCR analysis of virion RNA levels. Virion RNA was
isolated from partially purified TAR1, TAR2, TAR3, TAR4, TAR5, TAR6,
and wild-type virus (lanes 1 to 7 respectively), to which internal
control RNA had been added. The isolated RNAs were reverse transcribed
in either the presence or absence (not shown) of C-Therm DNA polymerase
and first-strand primer A (A and C) or first-strand primer B (B and D).
PCR to detect HIV-1 cDNA (A and B) or internal control cDNA (C and D)
was performed using the primers shown in Fig. 3. The PCR products were
separated by polyacrylamide gel electrophoresis and analyzed with a
Molecular Dynamics PhosphorImager. The copy numbers shown for HIV-1
cDNA (A and B) are normalized to internal control cDNA copy numbers (C
and D). The correlation coefficients (r2) of
standard curves generated with plasmid DNA were 0.992 for
HIV-1-specific primers and 0.997 for internal control-specific primers
(data not shown). The data shown are representative of those from three
similar replicate experiments using different virus stocks.
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RNase protection assays were performed on virion RNA and cellular RNA
from the corresponding 293 stable cell lines, using a 550-bp antisense
RNA probe that spanned the 5' major splice donor site. Full-length
HIV-1 genomic RNA overlaps with 363 nt of the probe, while spliced
HIV-1 RNA overlaps with only 189 bp. Virion RNA isolated from partially
purified virus containing 100 ng of p24 Ag, or 10 µg of total
cellular RNA isolated from stable 293 cell lines, was incubated with
the radiolabeled antisense RNA probe. As shown in Fig.
5, both genomic and spliced HIV-1 RNA
species were detected in cell lines producing TAR5, TAR4, and wild-type
viruses. The ratios of full-length to spliced RNA were 0.82, 0.51, and
0.83 in TAR5, TAR4, and wild-type virus, respectively. These ratios are
similar to the RNA ratios in wild-type and TAR mutant viruses reported
by Clever et al. (8). Virion RNA from TAR5, TAR4, and
wild-type virus protected an RNA fragment indicative of full-length
genomic RNA, but little if any spliced RNA was detected. In this and
other similar RNase protection assays, the RNA packaging efficiency of
the TAR5 mutant ranged from 50 to 60% of the wild-type level, compared
to the value of 80% obtained from the RT-PCR assay. The RNA packaging
efficiency of TAR4 ranged from 8 to 11% of the wild-type level,
consistent with the RT-PCR assay results.
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FIG. 5.
RNA protection assay of cellular and virion RNAs. Total
cellular RNA was isolated from stable 293 cell lines producing TAR4
(lane 2), TAR5 (lane 1), and wild-type (lane 3) HIV-1. Ten micrograms
of total cellular RNA or virion RNA isolated from TAR4 (lane 5), TAR5
(lane 4), and wild-type (lane 6) virus containing 100 ng of p24 Ag was
annealed to excess radiolabeled RNA probe. The same RNA probe was also
incubated with 10 µg of yeast RNA (lanes 7 and 8). The annealed RNA
mixtures were digested with RNase T1 and RNase A. Intact
probe is shown (lane 8 and dotted arrow). Protected fragments
corresponding to unspliced (top arrow, 363 nt) or spliced (bottom
arrow, 189 nt) HIV-1 RNA are indicated.
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The relative reverse transcription efficiency of each TAR RNA mutant
was calculated as the percentage of wild-type NERT activity divided by
the percentage of wild-type RNA packaging level (Fig. 6). This analysis revealed that the NERT
defect observed in the TAR4 virus could be attributed almost entirely
to decreased RNA packaging, while the TAR1 and TAR6 viruses both had
relative reverse transcription efficiencies which were reduced by less
than onefold, which was consistent with previous results (18,
20). The TAR2, TAR3, and TAR5 viruses were all defective for
reverse transcription; the TAR3 mutant had a sevenfold defect compared
to wild-type virus. The reverse transcription defects associated with
TAR5 were lower in NERT assays than previously reported for cell
infection assays (13) and were partly due to reduced
packaging efficiency.
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FIG. 6.
Relative reverse transcription efficiencies of wild-type
and TAR mutant viruses. The reverse transcription efficiency of each
virus was calculated as the percentage of wild-type negative
strong-stop DNA synthesis measured by NERT assay divided by the
percentage of wild-type virion RNA detected by RT-PCR (values were
averaged over two different first-strand primers). Relative reverse
transcription efficiencies of TAR1, TAR2, TAR3, TAR4, TAR5, TAR6, and
wild-type viruses (lanes 1 to 7, respectively) are shown.
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DISCUSSION |
In this study we confirmed that TAR is required for efficient
HIV-1 reverse transcription. The upper stem-loop from position +18 to
+42 is required for this function of TAR, but reverse transcription is
not strictly dependent on the bulge sequences from position +22 to +24,
since deletion of these sequences had no effect. However, reverse
transcription was down regulated when the bulge was either transposed
to the opposite side of the stem or shifted by an internal deletion,
indicating that the role of TAR in reverse transcription is dependent
on its secondary structure. The mechanism by which TAR exerts its
effect remains unknown, but it may involve the binding of viral or
cellular proteins that facilitate reverse transcription. Alternatively,
TAR may form alternative RNA structures that stabilize the reverse
transcription complex. The TAR RNA upper stem-loop structure is the
binding site for the HIV-1 Tat protein and cellular protein complexes
that contain the RNA polymerase II large subunit, Trp-185, and
Tat-cyclin-T1 (33, 34). The binding events involving these
proteins share a common dependence upon single-stranded regions of the
loop and.or bulge regions of TAR. The binding of protein to RNA is
commonly accompanied by a conformational change in RNA structure. For
example, crystal structure analysis of the anticodon loops of tRNAs
complexed with the appropriate aminoacyl-tRNA synthetases showed that
protein interactions facilitate unstacking of anticodon sequences,
allowing them to bind in separate recognition pockets in the RNA
structure (10). In TAR RNA, the three-nucleotide bulge
causes a distortion in the RNA duplex which makes the major groove
accessible, and binding of ligands to this region results in the
formation of a triple base pair between U23 and A27-U38 that restores
TAR RNA to an A-form-like duplex (1, 7, 30). It is
intriguing that the TAR bulge deletion mutation, an A-form RNA duplex
structure, was the only bulge mutation that supported high levels of
reverse transcription. It is possible that Tat or another TAR binding protein may induce a similar conformational change in TAR structure and
that this conformational change favors efficient reverse transcription. In a separate study, Tat was shown to be required for efficient early
reverse transcription in the absence of obvious biochemical defects in
the virions (17, 32), but numerous attempts to detect Tat in
purified HIV-1 have been unsuccessful. Studies are under way in our
laboratory to determine whether other viral proteins such as RT and
Ncp7 specifically bind to the TAR element.
The multiple functions associated with TAR include transcription,
translation, genomic RNA packaging, and reverse transcription. Some of
these functions are at least partially controlled by complex RNA
structures. For example, packaging depends on the so-called psi
sequences, which include the stem-loop structures SL1, SL2, and SL4
(Fig. 7A) (3, 9, 19, 27), and
reverse transcription requires RNA interactions
between the primer binding site and flanking sequences that bind the
anticodon loop of tRNA3Lys (22, 36, 37).
Some earlier studies of TAR mutations used gross clustered mutations
that greatly altered TAR structure. For example, a mutation called
Xho+10 destabilized TAR from position +2 to +16 and reduced packaging
efficiency by more than 90% (11). However, these large
mutations may allow alternative Watson-Crick base pairing with nearby
sequences, and this may interfere with other natural RNA structures.
Computer analysis indicates that Xho+10 sequences have a strong
potential to base pair with nearby sequences within SL1, which could
cause marked changes in the RNA structures of SL1 and SL2 (Fig. 7B and
C). Our results confirm that TAR plays a role in packaging, since
viruses with altered TAR structures have packaging defects. In this
study and others, viruses that formed non-TAR-like structures, or which
destabilized the lower stem structure, were associated with packaging
defects of 90% or greater (8, 11, 20, 28). Mutations in TAR
that destabilized portions of the lower stem without disturbing other structural elements greatly reduced RNA packaging, and second-site mutations that restored the stem base pairing also restored RNA packaging. These observations indicate that structure rather than primary RNA sequence is important for this function of TAR. The seminal
observations that distinct pools of genomic RNA traffic to either
translation or packaging processes (26), that TAR RNA
inhibits translation (6, 31), and that the TAR lower stem
region contributes to an efficient packaging signal (8, 11,
20) all suggest that specific features of the TAR lower stem are
one determinant of RNA packaging and translation pathways that is
codependent upon other RNA structures or RNA binding proteins.
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|
FIG. 7.
Computer model of potential HIV-1 RNA
secondary structures in the presences of stem-destabilizing clustered
mutations. (A) HIV-1 RNA secondary structure predicted from the
wild-type HIV-1 HXB2 sequence from position +1 to +359 using M-fold
version 3.0. Stem-loop structures corresponding to TAR, pA, SL1, SL2,
SL3, and SL4 as well as the primer binding site (PBS) are indicated.
(B) Predicted secondary structure of TAR RNA (positions +1 to +57)
showing the clustered mutation Xho+10 (10) indicated by red
letters. HIV-1 nt +274 to +284 (shown in blue) can base pair to
sequences in Xho+10. A dotted arrow indicates a shift by cytidine +243
(green) to base pair with guanine +272 (green). (C) The new secondary
structure maintains TAR and pA stem-loop structures (not shown), SL3,
and SL4 but eliminates SL1 and SL2. The free energy of this structure
is 40.2 kcal/mol compared to the structure shown in panel B, from
position +243 to +359, with free energy of 33.9 kcal/mol calculated
by M-fold version 3.0 using standardized parameters (36).
|
|
Our results provide evidence that the TAR upper stem structure is also
important for RNA packaging, since the TAR4 mutant, which has an
altered upper stem-loop structure but a conserved lower stem mutation,
was defective for RNA packaging. However, not all of the TAR mutations
fit this model. For example, a TAR deletion from position +34 to +37
would be expected to form an alternative RNA structure, yet genomic RNA
carrying this deletion was efficiently packaged into virions
(20). At least a partial explanation for this may lie in the
different methods which have been used to generate virus in different
studies. Several studies produced virus by transient expression from
proviral plasmids, and in some cases these plasmids carried a simian
virus 40 origin of replication. Transfection of these plasmids into
either COS or 293T cells, both of which make simian virus 40 large T
antigen, results in amplification of the plasmid and synthesis of large quantities of viral transcripts. In contrast, the present study used
isolated cell lines with stably integrated proviral constructs, resulting in levels of virus production more nearly approximating those
in a natural infection. The impact of this technical difference is not
known and requires further analysis.
Further study is also required to identify the specific features of TAR
that support reverse transcription and genomic RNA packaging. Attempts
to identify potential cofactors of reverse transcription are in
progress in our laboratory.
| |
ACKNOWLEDGMENTS |
We thank William B. Lott for critical reading of the manuscript.
This work was supported by grants from the National Centre for HIV-1
Virology Research (to D.H.).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Sir Albert
Sakzewski Virus Research Centre, Royal Children's Hospital, Herston
Rd., Herston, Queensland, Australia 4029. Phone: 617-3636-1679. Fax: 617-3636-1401. E-mail.
d.harrich{at}mailbox.uq.edu.au.
Publication number 106 from Sir Albert Sakzewski Virus Research Centre.
| |
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Abstract
Introduction
