Previous Article | Next Article 
Journal of Virology, March 2000, p. 2227-2238, Vol. 74, No. 5
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
A Structured RNA Motif Is Involved in Correct
Placement of the tRNA3Lys Primer onto the Human
Immunodeficiency Virus Genome
Nancy
Beerens,
Bep
Klaver, and
Ben
Berkhout*
Department of Human Retrovirology, Academic
Medical Center, University of Amsterdam, Amsterdam, The Netherlands
Received 3 September 1999/Accepted 22 November 1999
 |
ABSTRACT |
Human immunodeficiency virus type 1 (HIV-1) reverse transcription
is primed by the cellular tRNA3Lys molecule that binds
with its 3'-terminal 18 nucleotides to the fully complementary
primer-binding site (PBS) on the viral RNA genome. Besides this
complementarity, annealing of the primer may be stimulated by
additional base-pairing interactions between other parts of the tRNA
molecule and viral sequences flanking the PBS. According to the RNA
secondary structure model of the HIV-1 leader region, part of the PBS
sequence is involved in base pairing to form a small stem-loop
structure, termed the U5-PBS hairpin. This hairpin may be involved in
the process of reverse transcription. To study the role of the U5-PBS
hairpin in the viral replication cycle, we introduced mutations in the
U5 region that affect the stability of this structured RNA motif.
Stabilization and destabilization of the hairpin significantly
inhibited virus replication. Upon prolonged culturing of the virus
mutant with the stabilized hairpin, revertant viruses were obtained
with additional mutations that restore the thermodynamic stability of
the U5-PBS hairpin. The thermodynamic stability of the U5-PBS hairpin
apparently has to stay within narrow limits for efficient HIV-1
replication. Transient transfection experiments demonstrated that
transcription of the proviral genomes, translation of the viral mRNAs,
and assembly of the virions with a normal RNA content is not affected
by the mutations within the U5-PBS hairpin. We show that stabilization of the hairpin reduced the amount of tRNA primer that is annealed to
the PBS. Destabilization of the hairpin did not affect tRNA annealing,
but the viral RNA-tRNA complex was less stable. These results suggest
that the U5-PBS hairpin is involved in correct placement of the tRNA
primer on the viral genome. The analysis of virus mutants and
revertants and the RNA structure probing experiments presented in this
study are consistent with the existence of the U5-PBS hairpin as
predicted in the RNA secondary structure model.
| |
INTRODUCTION |
The replication cycle of human
immunodeficiency virus type 1 (HIV-1) and other retroviruses is
characterized by reverse transcription of the viral RNA genome into a
double-stranded DNA, which subsequently becomes integrated into the
host cell genome (42). This process is mediated by the
virion-associated enzyme reverse transcriptase (RT), and the cellular
tRNA3Lys molecule is used as a primer by HIV-1
(35). The tRNA primer binds with its 3'-terminal 18 nucleotides (nt) to a complementary sequence in the viral genome, the
primer-binding site (PBS), which is located in the untranslated leader
region of the viral genome (Fig. 1A).
Besides the complementarity between the PBS and the 3' end of
tRNA3Lys, annealing of the primer has been proposed to
be stimulated by additional base-pairing interactions between other
parts of the tRNA molecule and viral sequences flanking the PBS
(31).
View larger version (20K):
[in this window]
[in a new window]
|
FIG. 1.
Annealing of the tRNA3Lys primer to the
PBS of the HIV-1 RNA genome. (A) The tRNA3Lys primer
binds with its 3' terminus to the complementary sequence of the PBS to
form an 18-bp duplex that is shown in detail (PBS sequence is marked in
grey). The remainder of the tRNA cloverleaf structure is shown (AC,
anticodon loop; D, D loop). Besides the base-pairing interaction with
the PBS, sequences in the U5 region may interact with different parts
of tRNA3Lys to stimulate primer annealing. Directly
upstream of the PBS is a small hairpin structure, the U5-PBS hairpin,
which is the topic of this study. (B) Shown is the wild-type U5-PBS
hairpin, which was mutated to change the thermodynamic stability. In
mutant Ts, the hairpin was stabilized by the introduction of an
additional C nucleotide at position 165 and one nucleotide change at
position 162 (G to C). In mutant Td, the hairpin is destabilized by
three nucleotide substitutions at positions 158 to 160. The introduced
mutations are marked by open boxes, and the PBS sequence is marked by a
grey box. The thermodynamic stability of the hairpins, indicated at the
bottom ( G in kilocalories per mole), was calculated using
the Zuker algorithm (53).
|
|
Extensive secondary structure in the 5' untranslated leader region of
the HIV-1 genome has been suggested by electron microscopy, replication
studies with mutant viruses, and biochemical RNase probing studies
(3, 11, 17, 21, 22, 37). These results, combined with
phylogenetic analyses and computer-assisted structure prediction, led
to a model of the secondary RNA structure of the complete leader region
of the HIV-1 genome (4). According to this model, the PBS is
flanked by an upstream small stem-loop structure, the U5-PBS hairpin
(Fig. 1A). This HIV-1 hairpin structure was modeled primarily based on
the fact that phylogenetic analysis of different HIV and simian
immunodeficiency viruses (SIV) demonstrated a conservation of the
hairpin structure, despite considerable divergence in sequence (5,
7). A striking feature of the U5-PBS hairpin of different HIV and
SIV isolates is that part of the PBS sequence is involved in base
pairing (Fig. 1B). Several RNA secondary structures in the leader RNA
have been reported to regulate important viral replication steps of
HIV-1; examples are transcriptional transactivation by Tat (8, 20,
30), mRNA polyadenylation (16, 28), and dimerization
of the viral RNA genome (9, 12, 38). A stem-loop structure
at a similar position as the U5-PBS hairpin of HIV-1 was predicted for
Rous sarcoma virus. This structure is required for efficient initiation of reverse transcription in Rous sarcoma virus (2, 13). In addition, an interaction between U5 RNA and sequences of the primer tRNA has been proposed (1) and was confirmed recently by RNA structure probing studies (37a). A detailed structure has
also been proposed for the HIV-1 RNA-tRNA3Lys complex
based on biochemical experiments (24, 25a). Several sequences in the U5 region upstream of the PBS were suggested to
interact with different parts of the tRNA3Lys primer.
According to this model, base pairing occurs between the U-rich
anticodon loop of tRNA3Lys and the A-rich loop of the
U5-PBS hairpin. These combined observations suggest a specific role for
the U5-PBS hairpin structure in the process of reverse transcription.
To study the role of the U5-PBS hairpin in the viral replication cycle,
we introduced mutations in this structured RNA motif of the HIV-1
genome. Stabilization or destabilization of the U5-PBS hairpin
significantly reduced virus replication. Analysis of revertant viruses,
obtained through prolonged culturing of the mutant viruses, revealed
that the thermodynamic stability of the hairpin has to stay within
narrow limits for efficient HIV-1 replication. Biochemical assays
demonstrated the involvement of the U5-PBS hairpin in the correct
placement of the tRNA3Lys primer onto the viral genome.
| |
MATERIALS AND METHODS |
DNA constructs.
A derivative of the full-length proviral
HIV-1 clone pLAI was used to produce wild-type and U5-mutated viruses.
This construct, pLAI-R37, was described previously (17). The
3' long terminal repeat (3'LTR) was truncated at the SacI
site within the R region, and the chloramphenicol acetyltransferase
(cat) gene and simian virus 40 polyadenylation site were
inserted at this position. Nucleotide numbers refer to positions on the
genomic RNA transcript, with +1 being the capped G residue. For
mutation of the U5-PBS hairpin, we used the construct pBlue-5'LTR
(29), which contains an XbaI-ClaI
fragment of HIV-1 encompassing the 5'LTR, PBS, and 5' end of the
gag gene (positions 
454 to +376) cloned into pBluescript (Stratagene). The U5-PBS hairpin sequence was mutated by
oligonucleotide-directed in vitro mutagenesis with a Muta-Gene phagemid
in vitro mutagenesis kit (Bio-Rad). Oligonucleotides used are Ts
(5'-AGACCCTTTTAGTCACTGCTGGAAAATCTCTAGC-3') and Td (5'-CCTCAGACCCTTTTACAAAGTGTGGAAAATCTC-3'
(mutagenic positions underlined). The mutations introduced were
verified by sequence analysis. Sequencing was performed with the primer
AD-SD (positions +269 to +290), using a Thermo Sequenase dye terminator
cycle sequencing kit (Amersham) and an Applied Biosystems 373 DNA
sequencer. Subsequently, the mutated XbaI-ClaI
fragments were introduced into the proviral clone pLAI-R37, which again
was verified by sequence analysis. For transcription studies, the
pBlue-3'LTR-luciferase reporter construct was generated by the exchange
of the HindIII-BamHI fragment of
pBlue-3'LTR-CAT (29), encompassing the cat gene,
by the HindIII-BamHI fragment of pGL3
(Promega), encoding the luciferase gene. For construction of the
pBlue-5'LTR-luciferase reporter construct, the 5'LTR-leader region of
HIV-1 was PCR amplified to introduce an NcoI restriction
site overlapping the gag translation start codon. The
primers used are AD-R1 (positions +6 to +30) and SP6-ATG (5'-ATTTAGGTGACACTATAG
CCATGGCTCTCCTTCTAGCC-3' (start codon underlined, mutagenic positions in bold). The PCR fragment was digested
with HindIII/NcoI and inserted into
HindIII/NcoI-digested pBlue-3'LTR-luciferase.
The control luciferase construct was generated by deletion of the
XhoI/NcoI fragment, encompassing all HIV-1 sequences, filling of the recessed termini by the Klenow fragment of
DNA polymerase I, and self-ligation of the vector. The expression vector pcDNA3-Tat was described previously (44).
Synthesis of RNA templates.
Plasmid pBlue-5'LTR was used as
a template for PCR amplification and subsequent in vitro transcription.
The 5'LTR region of HIV-1 was PCR amplified with the sense primer T7-2
(positions +1 to +20) containing the T7 RNA polymerase promoter
sequence and the antisense primer AUG (positions +348 to +368). The PCR fragments were phenol extracted, precipitated, and dissolved in water.
The in vitro transcription reaction was performed in 10 µl of
transcription buffer (40 mM Tris [pH 7.5], 2 mM spermidine, 10 mM
dithiothreitol [DTT], 12 mM MgCl2) containing 0.5 µg of DNA template, 0.06 µmol of ATP, GTP, CTP, and UTP, 10 U of T7 RNA
polymerase (Boehringer), and 20 U of RNase inhibitor (Boehringer) and
incubated for 4 h at 37°C. Upon DNase treatment and phenol extraction, the unincorporated free nucleotides were removed by passage
through a Sephadex G-50 column. Subsequently, the RNA was ethanol
precipitated and dissolved in renaturation buffer (10 mM Tris-HCl [pH
7.5], 100 mM NaCl). The RNA was renatured by incubation at 85°C for
2 min, followed by slow cooling to room temperature.
RNA structure probing.
The renatured RNA (25 ng) was treated
with 0.5% diethyl pyrocarbonate (DEPC) or 0.1% dimethyl sulfate (DMS)
in 25 µl of 10 mM Tris (pH 7.5)-10 mM MgCl2-50 mM NaCl
buffer. After incubation for 10 min at 37°C, the RNA sample was
recovered by ethanol precipitation and dissolved in 5 µl of
renaturation buffer. The antisense primer BB-3 (positions +216 to +245)
was used to map the modified RNA positions in a primer extension
reaction. This primer was end labeled with [
-32P]ATP
and T4 polynucleotide kinase (Boehringer). The labeled oligonucleotide (2 ng) was mixed with the RNA sample in a total volume of 10 µl of
annealing buffer (83 mM Tris-HCl [pH 7.5], 125 mM KCl), incubated for
2 min at 85°C and for 10 min 65°C, and slowly cooled to 25°C. The
primer was extended by addition of 5 µl of RT buffer (9 mM MgCl2, 30 mM DTT, 150 µg of actinomycin D per ml, 30 µM
dATP, dGTP, dTTP, and dCTP) and 12.5 U of avian myeloblastosis virus (AMV) RT (Boehringer) in an incubation at 42°C for 15 min. The samples (2.5 µl) were mixed with formamide loading buffer (2.5 µl),
denatured at 90°C, and analyzed on a 6% polyacrylamide-7 M urea gel.
Cells, viruses, and transfection.
SupT1 T cells were grown
in RPMI 1640 medium supplemented with 10% fetal calf serum at 37°C
and 5% CO2. SupT1 cells (5 × 106) were
transfected with 1 and 2 µg of the HIV-1 proviral constructs by
electroporation (250 V, 960 µF). After transfection, 0.5 × 106 fresh SupT1 cells were added to support viral
replication. Cells were split 1 to 10 twice a week. For the selection
of revertant viruses, the transfected cells were passaged up to 124 days. At the peak of virus production, 100 to 0.1 µl of the culture
supernatant was used to infect fresh SupT1 cells. At each passage,
cells and supernatant samples were stored at 70°C. For
transcription studies, 5 × 106 SupT1 cells were
transfected with 5 µg of the 5'LTR-luciferase constructs by
electroporation. We added 100, 500, and 1,000 ng of pcDNA-Tat, which is
within the linear range of LTR transcriptional activation. To have an
equal amount of 6 µg DNA in each transfection, we added the empty
pcDNA3 vector.
C33A and HeLa cells were grown in Dulbecco's modified Eagle's medium
containing 10% fetal calf serum at 37°C and 5% CO
2. For
the transient production of virions, C33A cells were transfected
by the
calcium phosphate method. Cells were grown in 20 ml of
culture medium
in a 75-cm
2 flask to 60% confluency. Thirty micrograms of
the proviral construct
in 880 µl of water was mixed with 1 ml of 50 mM HEPES (pH 7.1)-250
mM NaCl-1.5 mM Na
2HPO
4
and 120 µl of 2 M CaCl
2, incubated at room
temperature
for 20 min, and added to the culture medium. The culture
medium was
changed after 16 h. For transcription studies, HeLa
cells were
transfected by the DEAE-dextran method. Cells were
grown in a 60- by
15-mm tissue culture dish to 60% confluency.
Cells were washed two
times with Tris-buffered saline (TBS) and
incubated for 30 min at room
temperature with the DEAE-dextran-DNA
mixture, containing 1 µg of
5'LTR-luciferase construct with or
without 1, 10, and 100 ng of the
pcDNA3-Tat expression vector,
which is within the linear range of LTR
transcriptional activation,
in 475 µl of TBS and 25 µl of
DEAE-dextran (10 mg/ml in TBS).
Finally, the cells were washed two
times with TBS to remove the
DEAE-dextran-DNA mixture, and culture
medium was
added.
Analysis of phenotypic revertants.
SupT1 cells transfected
with the Ts proviral construct were pelleted by centrifugation at 4,000 rpm for 4 min and washed with phosphate-buffered saline (PBS). The
cells were resuspended in 10 mM Tris-HCl (pH 8.0)-1 mM EDTA-0.5%
Tween 20 and incubated with 200 µg of proteinase K per ml at 56°C
for 1 h and at 95°C for 10 min to isolate total cellular DNA.
The 5'LTR-leader region was PCR amplified from the total cellular DNA
with the 5' U3 region primer 5'X (positions 454 to 434) and the 3'
gag primer AD-gag (positions +442 to +463). To provide this
fragment with a T7 tail for sequencing with the universal T7 dye
primer, a second PCR was performed with the 5' R region primer T7-1
(positions 54 to 34) and the 3' primer AUG (positions +123 to +151,
with six additional nucleotides at its 5' end). These PCR products were sequenced directly with a DYEnamic Direct cycle sequencing kit (Amersham) and an Applied Biosystems 373 DNA sequencer. In addition, the 5'X/AD-gag PCR product was cloned into pBlue-5'LTR as a
HindIII/NarI fragment. For analysis of
individual clones, a PCR was performed with the primers T7-1 and AD-SD
(positions +269 to +290), and this PCR fragment was subsequently
sequenced. Finally, for insertion of the revertant sequences into the
proviral plasmid pLAI-R37, XbaI/ClaI fragments of
the specific clones were used to replace the corresponding wild-type
sequences. Introduction of the revertant sequences into the proviral
plasmid pLAI-R37 was verified by sequence analysis. Therefore, a PCR
was performed with the T7-1 and AD-SD primers and the PCR fragment was sequenced.
CA-p24 and RT assay.
CA (capsid protein)-p24 levels in the
culture medium were determined by enzyme-linked immunosorbent assay. RT
assays were performed as described previously (49). The
virus sample (10 µl) was added to 50 µl of RT buffer (60 mM
Tris-HCl [pH 8.0], 1 mM EDTA, 75 mM KCl, 5 mM MgCl2,
0.1% Nonidet P-40, 4 mM DTT) supplemented with 0.25 µg of poly(A)
and 8 ng of oligo(dT)18 primer and 2.5 µCi (3,000 Ci/mmol) of [
32P]dTTP. Samples (10 µl) were taken
after 1, 2, and 3 h of incubation at 37°C and spotted onto DE-81
paper. The samples were dried for 5 min; the paper was subsequently
washed three times in 5% Na2HPO4, washed two
times in ethanol, and air dried. RT activity was quantified on a
Molecular Dynamics PhosphorImager.
Luciferase assay.
Luciferase assays were performed according
to Promega's luciferase assay system protocol. Two days
posttransfection, HeLa cells were washed with PBS and lysed in 200 µl
of reporter lysis buffer (Promega). SupT1 cells were collected by
centrifugation 3 days after transfection, washed with PBS, and lysed in
200 µl of reporter lysis buffer. Luciferase activity in the samples
(50 µl) was determined by addition of luciferase assay reagent
(Promega) in a Berthold model LB 9501 luminometer.
Isolation of viral RNA.
Three days after transfection of
C33A cells, the culture medium (20 ml) was centrifuged at 1,600 rpm for
15 min to remove cells. Subsequently the supernatant was filtered
through a 0.45-µm-pore-size filter (Schleicher & Schuell), and the
virions were pelleted by centrifugation at 25,000 rpm for 30 min in a
Beckman SW28 rotor. Virions were resuspended in 500 µl of 10 mM
Tris-HCl (pH 8.0)-100 mM NaCl-1 mM EDTA. To isolate viral RNA, the
viruses were incubated for 30 min at 37°C in the presence of 100 µg
of proteinase K per ml and 0.5% sodium dodecyl sulfate, followed by
extraction with phenol-chloroform-isoamyl alcohol (25:24:1) and
precipitation in 0.3 M sodium acetate (pH 5.2) and ethanol at 20°C.
The viral RNA was pelleted by centrifugation (18,000 rpm, 20 min),
washed with 70% ethanol, and dried. The pellet was dissolved in 20 µl of 10 mM Tris-HCl (pH 8.0)-1 mM EDTA and stored at 70°C.
Oligonucleotide and tRNA primer extension assays.
In the
oligonucleotide and tRNA primer extension assays, viral RNA
corresponding to 30 ng CA-p24 was incubated with 20 ng of
oligonucleotide primer in 12 µl of 83 mM Tris-HCl (pH 7.5)-125 mM
KCl at 85°C for 2 min and 65°C for 10 min, followed by cooling to
room temperature in 1 h to allow annealing of the primer. The primer was extended by addition of 6 µl of RT buffer (9 mM
MgCl2, 30 mM DTT, 150 µg of actinomycin D per ml, 30 µM
dATP, dGTP, and dTTP, 1.5 µM dCTP), 0.5 µl of
[32P]dCTP, and either 0.5 U of HIV-1 RT (U.S.
Biochemical) or 12.5 U of AMV RT (Boehringer) and incubation at 42°C
for 3 min; then 10 mM (each) deoxynucleoside triphosphate (dNTP) was
added, and incubation was continued for 30 min. The cDNA product was
precipitated in 25 mM EDTA-0.3 M sodium acetate (pH 5.2)-70% ethanol
at 20°C. For degradation of the tRNA part of the extended product
in the tRNA primer extension assay, the samples were incubated with 0.5 N NaOH for 20 min at 55°C, neutralized with 0.5 M HCl, and
precipitated as described above. The products were analyzed on a
denaturing 6% polyacrylamide-urea sequencing gel. The antisense
primers used are CN1 (positions +123 to +151) and AUG (positions +348
to +368, with six additional nucleotides at its 5' end).
| |
RESULTS |
Design of the U5-PBS hairpin mutants.
To study the role in
HIV-1 replication of the U5-PBS hairpin that is located directly
upstream of the PBS, we introduced mutations in this stem-loop
structure. The U5 region is encoded by the LTR that is present at both
the 5' and 3' ends of the HIV-1 proviral genome. Mutations introduced
into the U5 region of the 5'LTR will be inherited in both LTRs of the
progeny. However, the presence of a wild-type 3'LTR may result in
reversion of the mutant virus to the wild-type sequence by
recombination with the wild-type 3'LTR sequences. For production of the
mutant viruses, we therefore used a derivative of the proviral clone
pLAI in which part of the 3'LTR, including the polyadenylation signal
and the complete U5 region, is deleted. An SV40 polyadenylation site
was placed downstream of the HIV-1 sequences to allow efficient
polyadenylation of the viral transcript. Transfection of the SupT1
T-cell line with this vector results in the production of viruses with
a mutant U5 region in the untranslated leader RNA. Subsequent infection of SupT1 cells by these viruses, followed by reverse transcription of
the viral RNA genome, will produce proviral genomes with a complete
5'LTR and 3'LTR that both have the mutated U5 sequence.
Mutations that affect the stability of the U5-PBS hairpin were
introduced in the U5 region (Fig.
1B). The mutants were carefully
designed not to affect important sequence motifs, such as the
attachment site for integration (positions 170 to 181) (
18,
36) and the PBS sequence. All mutations were therefore introduced
on the left side of the hairpin. We stabilized the hairpin in
mutant Ts
by generating two extra C-G base pairs. This was done
by replacement of
the unpaired G162 by C and by insertion of an
additional C at position
165 (Fig.
1B). This results in an increase
in the thermodynamic
stability of the hairpin (
G) from
5.4 kcal/mol
for the
wild type to
18.2 kcal/mol for mutant Ts. In mutant Td,
the hairpin
was destabilized by substitution of three nucleotides
at position 158 to 160. As a result, base pairing in the lower
part of the stem is
lost, and a relative short and instable hairpin
structure is left
(
G =
1.6 kcal/mol).
Structure probing of the wild-type and mutant U5-PBS hairpins.
To demonstrate that the introduced mutations have no effect on folding
in other parts of the leader RNA, we performed structure probing
experiments. In vitro-synthesized HIV-1 leader RNA was treated with
structure-specific probes, followed by primer extension analysis to
localize the sites of modification. Nucleotides sensitive to DMS or
DEPC are assumed not to be involved in base-pairing or base-stacking
interactions. The sites of modification were identified by primer
extension analysis using the DNA primer BB-3 (positions +216 to +245).
No striking differences in reactivity toward the chemicals was observed
between the wild-type and mutant U5-PBS hairpins (Fig.
2). The A-rich loop of the wild-type
U5-PBS hairpin as well as that of the two mutants is modified by both DMS and DEPC, whereas the flanking sequences are not. The A-rich loop
is even visible in the Td mutant, in which the U5-PBS hairpin was
destabilized but apparently not destroyed. No major differences were
observed in the upstream leader region (Fig. 2) and the region downstream of the PBS, which was also probed and analyzed with the DNA
primers DIS (positions +246 to +269) and AUG (positions +348 to +368)
(results not shown). Furthermore, computer modeling of a larger region
of the 5'LTR leader RNA (positions +111 to +244) suggests that the
introduced mutations do not affect the RNA secondary structure in this
part of the genome. These combined results indicate that the mutations
do not lead to an overall structural rearrangement of the HIV-1 leader.
View larger version (107K):
[in this window]
[in a new window]
|
FIG. 2.
RNA structure probing of the U5-PBS region under native
conditions. In vitro-transcribed HIV-1 leader RNA of the wild-type and
U5-PBS mutants was treated with a limiting amount of the
single-strand-specific reagents DEPC (A specific) and DMS (A/C
specific) as indicated. Modification sites were detected using primer
extension analysis with the BB-3 primer. The products were analyzed on
a 6% polyacrylamide-7M urea gel. For reference, the BB-3 primer was
used in a DNA sequencing reaction (lanes 4 to 7 and 11 to 14).
Positions of the hairpin structures in this part of the HIV-1 leader
RNA and the PBS sequence are shown schematically on the left.
|
|
Replication capacity of viruses with a mutated U5-PBS hairpin.
To study the replication potential of the mutant viruses, we
transfected wild-type and mutant proviral genomes into SupT1 cells.
These cells express the CD4-CXCR4 receptors and are fully susceptible
for replication of the LAI strain. Virus production was followed by
measuring CA-p24 levels in the culture medium at several days after
transfection. Transfection with 2 µg of the proviral constructs
showed that the replication capacity of both mutants was reduced
compared with the wild-type virus (Fig. 3A). This defect is even more pronounced
in transfections with 1 µg of proviral construct (Fig. 3B). No
replication of mutant Ts was observed in transfections with less than 1 µg of the proviral construct. Thus, stabilization of the U5-PBS
hairpin affected the replication potential of the virus more severely
than destabilization of this RNA structure. These results demonstrate
the importance of the U5-PBS hairpin in viral replication.
View larger version (17K):
[in this window]
[in a new window]
|
FIG. 3.
Replication of wild-type (wt) and U5-PBS hairpin mutants
Ts and Td. SupT1 cells were transfected with 2 (A) or 1 (B) µg of the
proviral constructs. Several days after transfection, CA-p24 production
was measured in the culture medium.
|
|
Reversion of the stabilized U5-PBS hairpin mutant.
During
prolonged culturing of replication-defective viruses, phenotypic
revertants with an increased replication capacity can arise. The
genomes of such revertant viruses should be altered in order to
replicate more efficiently, and analysis of such revertant genomes may
allow the identification of important RNA sequences and/or structures.
This forced evolution approach can be used for most retroviruses due to
their high mutation rate and has proven to be valuable in the analysis
of regulatory RNA motifs (6, 15, 30). Mutant Td replicated
too efficiently to allow the selection of faster-replicating revertants
within a reasonable time span. We therefore focused on the evolution of
the severely defective mutant Ts.
SupT1 cells transfected with the Ts proviral construct were split into
several independent cultures that were maintained for
7 weeks. The
replication kinetics of the viruses present in several
cultures
increased after a variable time. To determine the sequence
of the
U5-PBS hairpin of these phenotypic revertants, total cellular
DNA was
isolated from infected cells. The 5'LTR-leader region
was PCR
amplified, and we performed population-based sequencing
of the DNA
fragment. The predicted RNA structures for the revertant
sequences are
shown in Fig.
4, with the thermodynamic
stability
indicated below the hairpins. Remarkably, the nucleotide
changes
introduced in mutant Ts were frequently found to be altered in
the revertant genomes, although no true wild-type reversions were
observed. All acquired mutations are located on the left side
of the
hairpin, which is consistent with the presence of important
sequence
motifs on the right side. Analysis of the revertants
demonstrated a
variation in repair strategies, but all mutations
reduced the stability
of the hairpin. This is most striking in
revertant w6, with two
reversion-based mutations that result in
a hairpin with a stability
very similar to that of the wild-type
U5-PBS structure. It is likely
that the other revertants, all
with only one nucleotide substitution
within the hairpin, had
not yet attained the optimal configuration and
will evolve toward
hairpin structures with wild-type stability over
time.
View larger version (21K):
[in this window]
[in a new window]
|
FIG. 4.
Phenotypic revertants of the stabilized U5-PBS hairpin
mutant Ts. Through prolonged culturing of the mutant virus Ts, several
revertant viruses with nucleotide changes in the hairpin were obtained.
The predicted RNA structures of these revertants and G
values (in kilocalories per mole) are shown. The mutations present in
mutant Ts are marked by an open box, the acquired additional mutations
are marked by black boxes, and the PBS is marked by a grey box. All
reversion-based mutations reduce the stability of the mutant U5-PBS
hairpin.
|
|
To study the evolution of the stabilized Ts hairpin in more detail, we
performed an independent SupT1 transfection and monitored
this culture
for up to 124 days. Total cellular DNA was isolated
from infected cells
at several days posttransfection. Figure
5A
shows the results of direct sequence
analysis of the PCR-amplified
U5-PBS region of the revertants.
Substitutions were initially
observed at the two mutated residues in
mutant Ts, but two additional
mutations were acquired over time. This
so-called population sequencing
provides information on the acquired
mutations and their relative
frequency in the virus quasispecies
population. However, this
method does not determine genetic linkages if
mixed sequences
are present at multiple positions (e.g., the day 27 sample). We
therefore also performed clonal sequencing. To do so, the
PCR
fragment was cloned into pBlue-5'LTR, and multiple individual
clones were sequenced for the samples obtained at day 27, 86,
and 124 (Fig.
5B). In the initial phase of the evolution experiment,
two
revertants appeared to be present simultaneously. Both evolution
routes
target one of the nucleotides introduced in mutant Ts.
The evolutionary
pathways of Ts reversion are depicted in Fig.
6, which shows the predicted RNA
structure and thermodynamic stability
of the observed revertants.
Alteration of C165 to A produces an
A/G mismatch and destabilizes the
hairpin from
18.2 to
11.1
kcal/mol. The other revertant changes
C162 to U, thereby creating
a weak U-G base pair that has a moderate
effect on stability (
G = 15.6 kcal/mol). Although
both genotypes are present at an approximately
equimolar concentration
at day 27 (Fig.
5A), the former seems
to outcompete the latter, as is
evident from the population sequence
at days 36 and 41. However, the
latter genotype reappears at day
65 due to the acquisition of another
destabilizing mutation (G168
to A) that triggers a rearrangement of the
upper part of the stem
region and increases the loop size. This hairpin
(
G =
11.1 kcal/mol)
acquires one more substitution
at day 124 that further reduces
the hairpin stability
(
G =
7.3 kcal/mol) to a value that is
similar to
that of the wild-type structure (
G =
5.4
kcal/mol).
View larger version (25K):
[in this window]
[in a new window]
|
FIG. 5.
Sequence analysis of Ts revertant genomes. (A) The
sequence of the U5-PBS hairpin was determined by population sequencing
several days after transfection of SupT1 cells with the Ts proviral
construct. Positions of the hairpin motif and the PBS are indicated at
the top. Dashes indicate nucleotides that are identical to that of the
input Ts mutant. Acquired mutations are indicated in capitals if the
majority of genomes carried the mutation; minor changes are in small
characters. (B) The genetic linkage of the various acquired mutations
was determined by sequencing of multiple individual clones for the
samples taken at days 27, 86, and 124 posttransfection. The frequency
of each sequence is given in parentheses. The clones tested in the
replication studies are marked by asterisks.
|
|
View larger version (22K):
[in this window]
[in a new window]
|
FIG. 6.
Evolutionary pathway of the stabilized U5-PBS hairpin
mutant Ts. The predicted structure for the sequences observed at
several days posttransfection (Fig. 5) is shown. The period in which
the intermediates were observed is indicated at the top, and the
calculated thermodynamic stability (in kilocalories per mole) is
indicated below the hairpins. The introduced mutations in mutant Ts are
marked by an open box, the acquired mutations are marked by black
boxes, and the PBS is marked by a grey box. The hairpin of mutant Ts
acquires several mutations that reduce the thermodynamic stability and
finally attains a stability similar to that of the wild-type U5-PBS
hairpin.
|
|
The role of the acquired U5 mutations in the phenotypic reversion of
mutant Ts was demonstrated by introduction of revertant
sequences
observed at days 27, 86, and 124 in the wild-type proviral
genome for
replication studies. Consecutive intermediates in the
evolutionary
pathway showed gradually improved replication (Fig.
7). This finding demonstrates that
replication of the mutant Ts
is repaired by restoration of the hairpin
stability. The combined
results of the evolution studies indicate that
a U5-PBS hairpin
of approximately wild-type stability is optimal for
virus replication.
View larger version (19K):
[in this window]
[in a new window]
|
FIG. 7.
Replication of different intermediates in the reversion
of mutant Ts. Revertant genomes observed at days 27, 86, and 124 (marked by an asterisk in Fig. 5B) were introduced in the wild-type
(wt) proviral genome. SupT1 cells were transfected with 2 µg of the
proviral constructs. Several days after transfection, CA-p24 production
was measured in the culture medium.
|
|
The U5-PBS hairpin is not involved in gene expression and virus
production.
Binding sites for AP-1 and NF-AT/AP3 transcription
factors were recently reported to be positioned on the proviral DNA
genome directly upstream of the PBS (43). These
transcription factor binding sites have been suggested to be involved
in HIV-1 transcription and replication. The upstream AP-1 site is
changed in mutant Td, and both binding sites are affected in mutant Ts
(Fig. 8A), raising the
possibility that viral transcription is affected in these mutants.
Furthermore, the revertants obtained by prolonged culturing of mutant
Ts possibly restore the binding of these transcription factors and
thereby virus replication. To test whether the U5 mutations affect
viral transcription, we transfected C33A cells (human cervix carcinoma
cells not expressing CD4) with the wild-type and mutant Ts and Td
proviral vectors and analyzed the level of viral gene expression and
virion production. Virus production was monitored by measuring the
amount of CA-p24 and virion-associated RT activity in the culture
medium. Table 1 summarizes the results of
two independent transfections. No significant differences were measured, as the observed differences reflect experimental variation in
the electroporation protocol. The expression levels of viral proteins
were also found to be similar for all constructs by Western blot
analysis of total cell extracts (results not shown).
View larger version (25K):
[in this window]
[in a new window]
|
FIG. 8.
Transcriptional activity of wild-type and mutant LTR
promoters. (A) The Ts and Td mutations affect transcription factor
binding sites in the U5 DNA. Marked are the AP-1 and NF-AT/AP-3
transcription factor binding sites located in the U5 region immediately
upstream of the PBS (43). The nucleotide changes in mutant
Td, mutant Ts, and two Ts revertants (rev), w3 and w3.1 (clones
obtained from revertant w3), are shown. (B) Relative basal
transcriptional activity of wild-type (wt) and mutant LTRs in HeLa and
SupT1 cells after transfection with 1 and 5 µg, respectively, of the
different LTR-luciferase constructs. The basal transcriptional activity of the wild-type LTR was
set at 1. (C and D) Relative Tat-activated transcriptional activities
of wild-type and mutant LTRs in HeLa (C) and SupT1 (D) cells. HeLa
cells were transfected with 1 µg of the LTR-luciferase constructs
with or without 1, 10, and 100 ng of Tat expression vector. SupT1 cells
were transfected with 5 µg of the LTR-luciferase constructs with or
without 100, 500, and 1,000 ng of Tat expression vector. The amounts of
added Tat expression vector are within the linear range of LTR
transcriptional activation. The basal transcriptional activity of each
individual LTR promoter was set at 1. Transfection with the control
luciferase construct, containing the luciferase gene but not the LTR,
and cotransfection of this construct with pcDNA3-Tat as well as
transfection with the empty Tat vector (pcDNA3) revealed no luciferase
activity. Cotransfection of the LTR-luciferase constructs with pcDNA3
resulted in a low basal level of LTR transcription.
|
|
To study the transcriptional activity of the mutants Td and Ts as well
as two Ts revertants in more detail, we constructed
LTR-reporter
vectors with the complete LTR-leader region of HIV-1
fused to the
luciferase open reading frame. Transient LTR-luciferase
transfection
assays and cotransfections with a Tat expression
vector were performed
in HeLa and SupT1 cells. Transfection of
episomal plasmids may not
accurately reflect proviral transcription
from an integrated position,
but the results shown in Fig.
8B
to D indicate that the wild-type,
mutant, and revertant LTR constructs
do not differ significantly in
basal or Tat-activated transcriptional
activity. These combined results
suggest that the mutations in
the U5 region do not affect viral gene
expression (e.g., transcription
and translation) and virion
assembly.
The U5-PBS hairpin is not involved in packaging of the viral
RNA.
The untranslated leader RNA contains important signals for
packaging of the viral RNA into virion particles. To determine the RNA
content of the wild-type and mutant viruses, we isolated RNA from
purified virions that were produced in C33A cells. The viral RNA was
measured by primer extension analysis with the CN1 oligonucleotide
primer, which is complementary to the +123 to +151 region. The CA-p24
values were used to control for the amount of virions used per sample.
The mutant virions contained a normal level of RT enzyme (Table 1). As
summarized in Table 2, no significant differences were observed between the mutant and wild-type viruses in
regard to the amount of viral RNA per virion. These results show that
the U5-PBS hairpin does not contribute to the process of packaging of
genomic HIV-1 RNA.
The U5-PBS hairpin is involved in reverse transcription.
The
U5-PBS structure of HIV-1 may be involved in regulation of reverse
transcription, in particular because the hairpin includes part of the
PBS sequence. In addition, a similar hairpin structure in avian
sarcoma-leukosis virus has been found to be involved in the process of
reverse transcription, and an interaction between the anticodon of the
tRNA primer and the A-rich hairpin loop was proposed for HIV-1 to play
a role in the process of reverse transcription. We therefore analyzed
the amount of tRNA3Lys primer annealed to the PBS of
the wild-type and mutant virion particles. During the isolation of
viral RNA, the tRNA primer remains bound to the PBS and can be
visualized by extension upon addition of HIV-1 RT enzyme and dNTPs.
Extension of the tRNA primer produces a 257-nt-long tRNA-cDNA product
(Fig. 1A shows a schematic; Fig. 9A,
lanes 4 to 6). The identity of this product was confirmed by
NaOH-mediated degradation of the tRNA part, leaving a 181-nt cDNA
product (Fig. 9A, lanes 7 to 9). The extended tRNA-cDNA products were
quantified and corrected for the amount of input viral RNA template as
determined by CN1 primer extension (Fig. 9A, lanes 1 to 3). As
summarized in Table 3, the tRNA extension efficiency of mutant Ts was
reduced to 27% of the value measured for the wild-type template. The
mutant Td was not affected in tRNA extension; we consistently measured
a small improvement compared with the wild-type (125%).
View larger version (47K):
[in this window]
[in a new window]
|
FIG. 9.
DNA-primed and tRNA-primed reverse transcription assays
with the virion-extracted RNA genome. (A) C33A cells were transfected
with the wild-type (wt), Ts and Td proviral constructs. Three days
posttransfection, viruses were purified and viral RNA was isolated. The
amount of viral RNA was quantified by DNA primer extension with the
oligonucleotide CN1 (lanes 1 to 3). Relative positions of the different
primers are shown in panel B. The tRNA3Lys primer
remains bound to the genomic RNA during viral RNA isolation and was
extended by addition of the HIV RT enzyme and dNTPs. Extension of the
tRNA primer results in a 257-nt cDNA product (lanes 4 to 6). The tRNA
extension product was incubated with NaOH, resulting in the degradation
of the tRNA part (76 nt), leaving a cDNA of 181 nt (lanes 7 to 9). The
occupancy of the PBS with tRNA primer was determined by a primer
extension assay with a primer that is positioned downstream of the PBS.
The AUG primer was extended by the HIV (lanes 10 to 12) or AMV (lanes
13 to 15) RT enzyme. When the PBS is occupied by the tRNA primer, a
175-nt premature stop product is generated; in the absence of the tRNA
primer, a 374-nt full-length cDNA is produced (B).
|
|
The reduced tRNA extension efficiency of mutant Ts may be the result of
less tRNA primer that is annealed to the PBS. Alternatively,
normal
levels of tRNA are bound, but these primers cannot be extended
efficiently on the template with the stabilized U5-PBS hairpin.
To
discriminate between these two possibilities, the tRNA occupancy
of the
PBS was determined by a different assay. Viral RNA-tRNA
complexes were
used as a template for the extension of a primer
that is positioned
downstream of the PBS. The oligonucleotide
primer AUG, complementary to
the +348 to +368 region with six
additional nucleotides at its 5' end,
was used in this experiment.
Viral RNA without a tRNA primer will
produce a full-length cDNA
product of 374 nt (Fig.
9B). When a tRNA
primer is present on
the PBS, this primer will also be extended by the
RT enzyme, and
RNase H will subsequently degrade the RNA template
strand. The
AUG primer can be extended to the 3' end of the PBS, where
it
encounters the annealed tRNA, which will result in a 175-nt cDNA
product. Alternatively, when the tRNA is displaced by the RT enzyme,
the AUG primer can be extended to the 5' end of the PBS, producing
a
193-nt cDNA product. As shown in Fig.
9A (lanes 10 to 12), extension
of
the downstream AUG primer produced predominantly the 175-nt
stop
product, indicating that the tRNA primer is not displaced
by the
elongating RT enzyme. A different result was reported for
the avian
leukosis virus, where the tRNA primer was efficiently
displaced
(
48). Extension of the AUG primer on the wild-type
template
(Fig.
9, lane 10) produced predominantly the 175-nt stop
product and
almost no 374-nt full-length product. Quantitation
of the stop and
full-length cDNA products indicated that approximately
90% of the
wild-type template has bound a tRNA primer (Table
3),
suggesting that nearly all PBS sites
of the wild-type HIV-1 RNA
are occupied. In contrast, extension of the
AUG primer on the
mutant Ts template produced relatively less premature
stop product
(23%) and more full-length product (77%). This result
demonstrates
that the PBS of mutant Ts is only partially occupied by a
tRNA.
In fact, the 23% PBS occupancy measured with this assay
correlates
well with the 27% tRNA extension efficiency (Table
3).
Surprisingly, the PBS occupancy of mutant Td was strongly reduced
(38%), even though this mutant showed no defect in the assay
(125%)
(Fig.
9A; Table
3). Apparently, the tRNA primer is present
on the PBS
and can be extended efficiently, but the tRNA is lost
during the PBS
occupancy assay with the downstream AUG primer.
The tRNA primer is
probably released during the heat denaturation
step that is used to
anneal the AUG primer. The results suggest
that the PBS-associated tRNA
primer does not optimally interact
with the Td template. In fact, this
means that the PBS occupancy
assay is not a reliable method when RNA
templates that differentially
bind the tRNA primer are compared.
Similar results were obtained
in PBS occupancy assays performed with
the RT enzyme of AMV (Fig.
9A, lanes 13 to 15). However, upon extension
of the tRNA primer,
we observed several additional stop products,
specific for the
wild-type template, at positions both upstream and
downstream
of the PBS. This implies a conformational difference between
the
viral RNA-tRNA duplex formed with the wild-type and mutant
templates.
Annealing of the tRNA primer onto the wild-type genome is
evidently
more complex and more stable than interaction with the genome
of mutant Td. These results indicate that the U5-PBS hairpin is
involved in the correct placement of the tRNA primer onto the
viral
RNA.
| |
DISCUSSION |
In this study, we demonstrate the importance of the U5-PBS hairpin
structure for efficient HIV-1 replication. Both stabilization and
destabilization of this RNA structure decreased the viral replication
capacity. Upon prolonged culturing of the stabilized mutant Ts, several
revertant viruses were obtained with an increased replication
potential. All of the phenotypic revertants acquired additional
mutations in the hairpin that reduce its thermodynamic stability. Thus,
the mutant viruses revert by emulating the stability of the wild-type
hairpin. This indicates that RNA structural effects rather than RNA or
DNA sequence effects are responsible for the replication defect of
these HIV-1 mutants. Apparently, the thermodynamic stability of the
U5-PBS hairpin must stay within narrow limits for efficient HIV-1 replication.
Analysis of revertant viruses of the mutant Ts also revealed that the
reversion-based mutations are almost exclusively present on the left
side of the U5-PBS hairpin, and in particular at the nucleotide
positions that were altered in the mutant Ts (first sites). This result
contrasts with reversion analyses of other structured RNA motifs in
which second-site reversions were observed frequently (6,
30). The nonrandom nature of U5-PBS hairpin reversion suggests
that important sequence motifs are encoded by this region of the HIV-1
genome. The observation that the reversion-based mutations are
predominantly present on the left side of the hairpin suggests that
such motifs are encoded by the right side of the hairpin. In fact,
these U5 sequences from the extreme 3' end of the LTR, and this region
is well known to contribute to proviral integration through
sequence-specific interaction with the viral integrase protein
(10). Recently, the importance of the 3'-terminal 12 nt
(positions 170 to 181) of the U5 region has been demonstrated (18,
36, 45). Thus, the U5 motif that is critical for integration also
includes part of the A-rich loop sequence, which may explain in part
the importance of this sequence element for HIV-1 replication (34). In addition, the right side of the hairpin contains
part of the PBS sequence (positions 182 to 185), which does not allow mutation (15, 32, 47). These two sequence motifs together constitute the right side of the U5-PBS hairpin. Thus, this part of the
HIV-1 genome encodes at least three signals, of which one is recognized
as part of the double-stranded DNA genome (integration motif), one as
RNA sequence (PBS), and one as structured RNA motif (U5-PBS hairpin).
The fact that mainly first-site mutations were found in the revertants
suggests that an important sequence motif surrounds the introduced
mutations. Nevertheless, no true wild-type reversions were observed.
AP-1 and NF-AT/AP3 transcription factor binding sites have been found
in the U5 region (43). The mutations introduced in mutant Ts
and Td affect these sites, and we therefore analyzed the
transcriptional activity of these mutants in transient LTR-luciferase transfection assays. In addition, we tested whether two revertants of
mutant Ts increased the LTR activity of mutant Ts. Both basal and
Tat-activated transcriptional activities of the wild-type, mutant, and
revertant LTRs were tested, but we measured no difference among the
different promoters. Furthermore, similar levels of virus production
were measured in cells transiently transfected with the proviral
constructs. Thus, these transcription factor binding sites in the U5
region are either not affected by the Ts and Td mutations or not
important for viral replication. Nevertheless, the nonrandom pattern of
reversion suggests the presence of a sequence-specific motif in this
part of the U5 region.
Biochemical assays with virion-derived RNA-tRNA complexes showed that
the reduced replication potential of mutant Ts correlates with reduced
tRNA priming efficiency, which is the result of decreased tRNA
occupancy of the PBS. We measured nearly complete occupancy of the PBS
for the wild-type template, suggesting that both copies of the dimeric
HIV-1 RNA genome have an associated tRNA primer. This result differs
somewhat with studies on murine leukemia virus and avian leukosis
virus, for which PBS occupancies of 50 and 70% have been reported
(19, 48). We found the PBS occupancy of the mutant Ts
template to be reduced to 23%. Thus, inclusion of part of the PBS in
an excessively stable hairpin structure inhibits the annealing of the
tRNA primer. This effect apparently restricts the U5-PBS hairpin from
becoming excessively stable in natural HIV and SIV isolates
(5). In other words, the HIV-1 genome contains a structured
RNA motif in the U5-PBS region that is at the threshold of becoming
inhibitory to the process of initiation of reverse transcription. In
fact, the tRNA extension efficiency could be increased to 125% of the
wild-type value by opening of the U5-PBS hairpin as in mutant Td.
Although speculative, this hairpin may restrict premature tRNA
annealing to the viral RNA in the infected cell, but this restriction
is apparently overcome in the context of the virion particle, perhaps
due to viral cofactors (see below). More extended hairpin structures
with greater thermodynamic stability were predicted for the HIV-2
genome and several SIV variants, but we previously stressed that these
structures are characterized by having either a limited number of PBS
nucleotides that are involved in base pairing or a large percentage of
relatively weak G-U base pairs (7). There is recent evidence
for ribozymes that terminal G-U base pairs are involved in structural
rearrangements (50), which may explain the efficient tRNA
annealing in HIV-2, despite the relatively stable U5-PBS structure.
Obviously, there may be cofactors that facilitate tRNA annealing onto
the PBS in the context of the viral particle. One such a factor is the
viral nucleocapsid (NC) protein, which has been reported to facilitate the annealing of the tRNA primer to the PBS (23, 39).
Apparently, the excessively stable Ts hairpin interferes with this
process, and it will be of interest to study this annealing reaction in more detail in in vitro assays in the absence and presence of NC
protein. Such studies are currently being performed.
A more complex defect was apparent for the Td mutant with the
destabilized U5-PBS hairpin. This mutant template was at least as
efficient in tRNA extension as the wild-type template, demonstrating that the PBS is occupied by tRNA. Despite efficient tRNA extension, we
measured a strongly reduced PBS occupancy in tests in which reverse
transcription is primed by an oligonucleotide from a position downstream of the PBS. Apparently, the tRNA primer was released during
the primer-annealing step. This result indicates that the interaction
between the tRNA primer and the mutant Td genome is less stable than
the complex with the wild-type template, even though the two templates
have identical PBSs. Moreover, several additional stop products
upstream and downstream of the PBS were observed for the wild-type
template during extension of the downstream primer with the AMV RT
enzyme. These stops are due to tRNA annealing because the signals are
not observed with the mutant Ts template. Most importantly, these stops
were not observed either for the mutant Td template. These combined
results indicate that a different conformation of the viral RNA-tRNA
complex is reached on the wild-type template compared with mutant Td,
suggesting that the U5-PBS hairpin is directly or indirectly involved
in correct tRNA annealing onto the viral RNA genome. Several studies
suggest that the A-rich loop of the U5-PBS hairpin interacts directly
with the anticodon of tRNA3Lys (24-27, 33, 34,
40, 41, 46, 51, 52), but the interpretation of these experiments
is complicated because this U5 sequence encodes multiple, overlapping
replication signals. For instance, mutations in the U5-PBS region may
affect the secondary structure of this part of the leader RNA
(5), and the presence of overlapping integration signals
(18, 36) makes it difficult to analyze the proposed
interactions between the viral RNA and the tRNA primer. The phenotype
of the carefully designed RNA structure mutant Td in this study does
support the idea that structured RNA motifs in the U5 region contribute
to functional tRNA annealing. The induction of multiple stop signals
upon tRNA binding to the wild-type template suggests that a structural
rearrangement occurs in the region surrounding the PBS, but the
molecular nature of the additional viral RNA-tRNA interactions remains
to be determined.
The mutant and revertant analysis presented in this study is consistent
with the existence of the U5-PBS hairpin as depicted in Fig. 1. We
previously proposed this hairpin conformation as part of a secondary
RNA structure model of the complete leader region of the HIV-1 genome
(4). In fact, this HIV-1 hairpin structure is not very
stable but was modeled based primarily on similar structures in the
HIV-2 RNA (7) and the genomes of several SIV viruses
(5). Although a different conformation was recently proposed
for this part of the HIV-1 genome based on RNA structure probing
experiments (14), our structure probing results and in
particular the functional data strongly support the existence of the
U5-PBS hairpin. Furthermore, this stem-loop structure is supported by
phylogenetic evidence based on the sequence of different HIV-1 subtypes
(not shown). It may nevertheless be too simplistic to suggest that this
part of the RNA genome has one static conformation. Several factors
will bind to this region of the viral genome during discrete steps of
virus replication, e.g., the tRNA primer, the NC protein, and the RNA
itself during dimerization, and it is likely that the RNA conformation
will change during consecutive steps of the viral replication cycle. It
cannot even be excluded that this region acts as a molecular switch
during replication by changing between alternative RNA conformations.
We recently obtained evidence for such a conformational polymorphism of
the HIV-1 leader RNA (9a).
| |
ACKNOWLEDGMENTS |
We thank Atze Das for helpful discussions, Bianca Schuijt for
performing the LTR-luciferase transcription assays, and Wim van Est for
photography work.
This work was supported in part by the Dutch AIDS Fund and by the
Netherlands Foundation for Chemical Research with financial aid from
the Netherlands Organization for Scientific Research.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Human Retrovirology, Academical Medical Center, University of
Amsterdam, P.O. Box 22700, 1100 DE Amsterdam, The Netherlands. Phone:
31-20-5664822. Fax: 31-20-6916531. E-mail:
B.Berkhout{at}AMC.UVA.NL.
| |
REFERENCES |
| 1.
|
Aiyar, A.,
D. Cobrinik,
Z. Ge,
H. J. Kung, and J. Leis.
1992.
Interaction between retroviral U5 RNA and the TYC loop of the tRNATrp primer is required for efficient initiation of reverse transcription.
J. Virol.
66:2464-2472[Abstract/Free Full Text].
|
| 2.
|
Aiyar, A.,
Z. Ge, and J. Leis.
1994.
A specific orientation of RNA secondary structures is required for initiation of reverse transcription.
J. Virol.
68:611-618[Abstract/Free Full Text].
|
| 3.
|
Baudin, F.,
R. Marquet,
C. Isel,
J. L. Darlix,
B. Ehresmann, and C. Ehresmann.
1993.
Functional sites in the 5' region of human immunodeficiency virus type 1 RNA from defined structural domains.
J. Mol. Biol.
229:382-397[CrossRef][Medline].
|
| 4.
|
Berkhout, B.
1996.
Structure and function of the human immunodeficiency virus leader RNA.
Prog. Nucleic Acid Res. Mol. Biol.
54:1-34[Medline].
|
| 5.
|
Berkhout, B.
1997.
The primer-binding site on the RNA genome of human and simian immunodeficiency viruses is flanked by an upstream hairpin structure.
Nucleic Acids Res.
25:4013-4017[Abstract/Free Full Text].
|
| 6.
|
Berkhout, B.,
B. Klaver, and A. T. Das.
1997.
Forced evolution of a regulatory RNA helix in the HIV-1 genome.
Nucleic Acids Res.
25:940-947[Abstract/Free Full Text].
|
| 7.
|
Berkhout, B., and I. Schoneveld.
1993.
Secondary structure of the HIV-2 leader RNA comprising the tRNA-primer binding site.
Nucleic Acids Res.
21:1171-1178[Abstract/Free Full Text].
|
| 8.
|
Berkhout, B.,
R. H. Silverman, and K. T. Jeang.
1989.
Tat trans-activates the human immunodeficiency virus through a nascent RNA target.
Cell
59:273-282[CrossRef][Medline].
|
| 9.
|
Berkhout, B., and J. L. B. van Wamel.
1996.
Role of the DIS hairpin in replication of human immunodeficiency virus type 1.
J. Virol.
70:6723-6732[Abstract/Free Full Text].
|
| 9a.
| Berkhout, B., and J. L. B. van Wamel. The leader of
the RNA genome forms a compactly folded tertiary structure. RNA, in
press.
|
| 10.
|
Brown, P. O.
1997.
Integration, p. 161-204.
In
J. M. Coffin, S. H. Hughes, and H. E. Varmus (ed.), Retroviruses. Cold Spring Harbor Laboratory Press, New York, N.Y.
|
| 11.
|
Clever, J.,
C. Sassetti, and T. G. Parslow.
1995.
RNA secondary structure and binding sites for gag gene products in the 5' packaging signal of human immunodeficiency virus type 1.
J. Virol.
69:2101-2109[Abstract].
|
| 12.
|
Clever, J. L., and T. G. Parslow.
1997.
Mutant human immunodeficiency virus type 1 genomes with defects in RNA dimerization or encapsidation.
J. Virol.
71:3407-3414[Abstract].
|
| 13.
|
Cobrinik, D.,
A. Aiyar,
Z. Ge,
M. Katzman,
H. Huang, and J. Leis.
1991.
Overlapping retrovirus U5 sequence elements are required for efficient integration and initiation of reverse transcription.
J. Virol.
65:3864-3872[Abstract/Free Full Text].
|
| 14.
|
Damgaard, C. K.,
H. Dyhr-Mikkelsen, and J. Kjems.
1998.
Mapping the RNA binding sites for human immunodeficiency virus type-1 Gag and NC proteins within the complete HIV-1 and -2 untranslated leader regions.
Nucleic Acids Res.
26:3667-3676[Abstract/Free Full Text].
|
| 15.
|
Das, A. T.,
B. Klaver, and B. Berkhout.
1995.
Reduced replication of human immunodeficiency virus type 1 mutants that use reverse transcription primers other than the natural tRNA3Lys.
J. Virol.
69:3090-3097[Abstract].
|
| 16.
|
Das, A. T.,
B. Klaver, and B. Berkhout.
1999.
A hairpin structure in the R region of the human immunodeficiency virus type 1 RNA genome is instrumental in polyadenylation site selection.
J. Virol.
73:81-91[Abstract/Free Full Text].
|
| 17.
|
Das, A. T.,
B. Klaver,
B. I. F. Klasens,
J. L. B. van Wamel, and B. Berkhout.
1997.
A conserved hairpin motif in the R-U5 region of the human immunodeficiency virus type 1 RNA genome is essential for replication.
J. Virol.
71:2346-2356[Abstract].
|
| 18.
|
Esposito, D., and R. Craigie.
1998.
Sequence specificity of viral end DNA binding by HIV-1 integrase reveals critical regions for protein-DNA interaction.
EMBO J.
17:5832-5843[CrossRef][Medline].
|
| 19.
|
Fu, W.,
B. A. Ortiz-Conde,
R. J. Gorelick,
S. H. Hughes, and A. Rein.
1997.
Placement of tRNA primer on the primer-binding site requires pol gene expression in avian but not murine retroviruses.
J. Virol.
71:6940-6946[Abstract].
|
| 20.
|
Harrich, D.,
G. Mavankal,
A. Mette-Snider, and R. B. Gaynor.
1995.
Human immunodeficiency virus type 1 TAR element revertant viruses define RNA structures required for efficient viral gene expression and replication.
J. Virol.
69:4906-4913[Abstract].
|
| 21.
|
Harrison, G. P., and A. M. L. Lever.
1992.
The human immunodeficiency virus type 1 packaging signal and major splice donor region have a conserved stable secondary structure.
J. Virol.
66:4144-4153[Abstract/Free Full Text].
|
| 22.
|
Hoglund, S.,
A. Ohagen,
J. Goncalves,
A. T. Panganiban, and D. Gabuzda.
1997.
Ultrastructure of HIV-1 genomic RNA.
Virology
233:271-279[CrossRef][Medline].
|
| 23.
|
Huang, Y.,
A. Khorchid,
J. Wang,
M. A. Parniak,
J.-L. Darlix,
M. A. Wainberg, and L. Kleiman.
1997.
Effect of mutations in the nucleocapsid protein (NCp7) upon Pr160gag-pol and tRNALys incorporation into human immunodeficiency virus type 1.
J. Virol.
71:4378-4384[Abstract].
|
| 24.
|
Isel, C.,
C. Ehresmann,
G. Keith,
B. Ehresmann, and R. Marquet.
1995.
Initiation of reverse transcription of HIV-1: secondary structure of the HIV-1 RNA/tRNA(3Lys) (template/primer).
J. Mol. Biol.
247:236-250[CrossRef][Medline].
|
| 25.
|
Isel, C.,
G. Keith,
B. Ehresmann,
C. Ehresmann, and R. Marquet.
1998.
Mutational analysis of the tRNA3Lys/HIV-1 RNA (primer/template) complex.
Nucleic Acids Res.
26:1198-1204[Abstract/Free Full Text].
|
| 25a.
|
Isel, C.,
E. Westhof,
S. F. Le Grice,
B. Ehresmann,
C. Ehresmann, and R. Marquet.
1999.
Structural basis for the specificity of the initiation of HIV-1 reverse transcription.
EMBO J.
18:1038-1048[CrossRef][Medline].
|
| 26.
|
Kang, S.-M.,
J. K. Wakefield, and C. D. Morrow.
1996.
Mutations in both the U5 region and the primer-binding site influence the selection of the tRNA used for the initiation of HIV-1 reverse transcription.
Virology
222:401-414[CrossRef][Medline].
|
| 27.
|
Kang, S.-M.,
Z. Zhang, and C. D. Morrow.
1997.
Identification of a sequence within U5 required for human immunodeficiency virus type 1 to stably maintain a primer binding site complementary to tRNAMet.
J. Virol.
71:207-217[Abstract].
|
| 28.
|
Klasens, B. I. F.,
M. Thiesen,
A. Virtanen, and B. Berkhout.
1999.
The ability of the HIV-1 AAUAAA signal to bind polyadenylation factors is controlled by local RNA structure.
Nucleic Acids Res.
27:446-454[Abstract/Free Full Text].
|
| 29.
|
Klaver, B., and B. Berkhout.
1994.
Comparison of 5' and 3' long terminal repeat promoter function in human immunodeficiency virus.
J. Virol.
68:3830-3840[Abstract/Free Full Text].
|
| 30.
|
Klaver, B., and B. Berkhout.
1994.
Evolution of a disrupted TAR RNA hairpin structure in the HIV-1 virus.
EMBO J.
13:2650-2659[Medline].
|
| 31.
|
Leis, J.,
A. Aiyar, and D. Cobrinik.
1993.
Regulation of initiation of reverse transcription of retroviruses, p. 33-48.
In
A. M. Skalka, and S. P. Goff (ed.), Reverse transcriptase. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 32.
|
Li, X.,
J. Mak,
E. J. Arts,
Z. Gu,
L. Kleiman,
M. A. Wainberg, and M. A. Parniak.
1994.
Effects of alterations of primer-binding site sequences on human immunodeficiency virus type 1 replication.
J. Virol.
68:6198-6206[Abstract/Free Full Text].
|
| 33.
|
Li, Y.,
Z. Zhang,
J. K. Wakefield,
S.-M. Kang, and C. D. Morrow.
1997.
Nucleotide substitutions within U5 are critical for efficient reverse transcription of human immunodeficiency virus type 1 with a primer binding site complementary to tRNAHis.
J. Virol.
71:6315-6322[Abstract].
|
| 34.
|
Liang, C.,
X. Li,
L. Rong,
P. Inouye,
Y. Quan,
L. Kleiman, and M. A. Wainberg.
1997.
The importance of the A-rich loop in human immunodeficiency virus type 1 reverse transcription and infectivity.
J. Virol.
71:5750-5757[Abstract].
|
| 35.
|
Marquet, R.,
C. Isel,
C. Ehresmann, and B. Ehresmann.
1995.
tRNAs as primer of reverse transcriptases.
Biochimie
77:113-124[Medline].
|
| 36.
|
Masuda, T.,
M. J. Kuroda, and S. Harada.
1998.
Specific and independent recognition of U3 and U5 att sites by human immunodeficiency virus type 1 integrase in vivo.
J. Virol.
72:8396-8402[Abstract/Free Full Text].
|
| 37.
|
McBride, M. S., and A. T. Panganiban.
1996.
The human immunodeficiency virus type 1 encapsidation site is a multipartite RNA element composed of functional hairpin structures.
J. Virol.
70:2963-2973[Abstract].
|
| 37a.
|
Morris, S., and J. Leis.
1998.
Changes in Rous sarcoma virus RNA secondary structure near the primer binding site upon tRNATrp primer annealing.
J. Virol.
73:6307-6318[Abstract/Free Full Text].
|
| 38.
|
Paillart, J.-C.,
L. Berthoux,
M. Ottmann,
J.-L. Darlix,
R. Marquet,
B. Ehresmann, and C. Ehresmann.
1996.
A dual role of the putative RNA dimerization initiation site of human immunodeficiency virus type 1 in genomic RNA packaging and proviral DNA synthesis.
J. Virol.
70:8348-8354[Abstract].
|
| 39.
|
Prats, A. C.,
L. Sarih,
C. Gabus,
S. Litvak,
G. Keith, and J. L. Darlix.
1988.
Small finger protein of avian and murine retroviruses has nucleic acid annealing activity and positions the replication primer tRNA onto genomic RNA.
EMBO J.
7:1777-1783[Medline].
|
| 40.
|
Puglisi, E. V., and J. D. Puglisi.
1998.
HIV-1 A-rich RNA loop mimics the tRNA anticodon structure.
Nat. Med.
5:1033-1036.
|
| 41.
|
Skripkin, E.,
C. Isel,
B. Marquet,
B. Ehresmann, and C. Ehresmann.
1996.
Psoralen crosslinking between human immunodeficiency virus type 1 RNA and primer tRNAlys3.
Nucleic Acids Res.
24:509-514[Abstract/Free Full Text].
|
| 42.
|
Telesnitsky, A., and S. P. Goff.
1997.
Reverse transcriptase and the generation of retroviral DNA, p. 121-160.
In
J. M. Coffin, S. H. Hughes, and H. E. Varmus (ed.), Retroviruses. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
|
| 43.
|
Van Lint, C.,
C. A. Amella,
S. Emiliani,
M. John,
T. Jie, and E. Verdin.
1997.
Transcription factor binding sites downstream of the human immunodeficiency virus type 1 transcription start site are important for virus infectivity.
J. Virol.
71:6113-6127[Abstract].
|
| 44.
|
Verhoef, K.,
M. Koper, and B. Berkhout.
1997.
Determination of the minimal amount of Tat activity required for human immunodeficiency virus type 1 replication.
Virology
237:228-236[CrossRef][Medline].
|
| 45.
|
Vicenzi, E.,
D. S. Dimitrov,
A. Engelman,
T.-S. Migone,
D. F. J. Purcell,
J. Leonard,
G. Englund, and M. A. Martin.
1994.
An integration-defective U5 deletion mutant of human immunodeficiency virus type 1 reverts by eliminating additional long terminal repeat sequences.
J. Virol.
68:7879-7890[Abstract/Free Full Text].
|
| 46.
|
Wakefield, J. K.,
S.-M. Kang, and C. D. Morrow.
1996.
Construction of a type 1 human immunodeficiency virus that maintains a primer binding site complementary to tRNAHis.
J. Virol.
70:966-975[Abstract].
|
| 47.
|
Wakefield, J. K.,
H. Rhim, and C. D. Morrow.
1994.
Minimal sequence requirements of a functional human immunodeficiency virus type 1 primer binding site.
J. Virol.
68:1605-1614[Abstract/Free Full Text].
|
| 48.
|
Whitcomb, J. M.,
B. A. Ortiz Conde, and S. H. Hughes.
1995.
Replication of avian leukosis viruses with mutations at the primer binding site: use of alternative tRNAs as primer.
J. Virol.
69:6228-6238[Abstract].
|
| 49.
|
Willey, R. L.,
D. H. Smith,
L. A. Lasky,
T. S. Theodore,
P. L. Earl,
B. Moss,
D. J. Capon, and M. A. Martin.
1988.
In vitro mutagenesis identifies a region within the envelope gene of the human immunodeficiency virus that is critical for infectivity.
J. Virol.
62:139-147[Abstract/Free Full Text].
|
| 50.
|
Wu, M., and I. Tinoco.
1999.
RNA folding causes secondary structure rearrangement.
Proc. Natl. Acad. Sci. USA
95:11555-11560[Abstract/Free Full Text].
|
| 51.
|
Zhang, Z.,
S.-M. Kang,
A. LeBlanc,
S. L. Hajduk, and C. D. Morrow.
1996.
Nucleotide sequences within the U5 region of the viral RNA genome are the major determinants for an human immunodeficiency virus type 1 to maintain a primer binding site complementary to tRNAHis.
Virology
226:306-317[CrossRef][Medline].
|
| 52.
|
Zhang, Z.,
S.-M. Kang,
Y. Li, and C. D. Morrow.
1998.
Genetic analysis of the U5-PBS of a novel HIV-1 reveals multiple interactions between the tRNA and RNA genome required for initiation of reverse transcription.
RNA
4:394-406[Abstract].
|
| 53.
|
Zuker, M.
1989.
On finding all suboptimal foldings of an RNA molecule.
Science
244:48-52[Abstract/Free Full Text].
|
Journal of Virology, March 2000, p. 2227-2238, Vol. 74, No. 5
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Dobard, C. W., Briones, M. S., Chow, S. A.
(2007). Molecular Mechanisms by Which Human Immunodeficiency Virus Type 1 Integrase Stimulates the Early Steps of Reverse Transcription. J. Virol.
81: 10037-10046
[Abstract]
[Full Text]
-
Abbink, T. E. M., Beerens, N., Berkhout, B.
(2004). Forced Selection of a Human Immunodeficiency Virus Type 1 Variant That Uses a Non-Self tRNA Primer for Reverse Transcription: Involvement of Viral RNA Sequences and the Reverse Transcriptase Enzyme. J. Virol.
78: 10706-10714
[Abstract]
[Full Text]
-
Goldschmidt, V., Paillart, J.-C., Rigourd, M., Ehresmann, B., Aubertin, A.-M., Ehresmann, C., Marquet, R.
(2004). Structural Variability of the Initiation Complex of HIV-1 Reverse Transcription. J. Biol. Chem.
279: 35923-35931
[Abstract]
[Full Text]
-
Rigourd, M., Goldschmidt, V., Brule, F., Morrow, C. D., Ehresmann, B., Ehresmann, C., Marquet, R.
(2003). Structure-function relationships of the initiation complex of HIV-1 reverse transcription: the case of mutant viruses using tRNAHis as primer. Nucleic Acids Res
31: 5764-5775
[Abstract]
[Full Text]
-
Dupuy, L. C., Kelly, N. J., Elgavish, T. E., Harvey, S. C., Morrow, C. D.
(2003). Probing the Importance of tRNA Anticodon: Human Immunodeficiency Virus Type 1 (HIV-1) RNA Genome Complementarity with an HIV-1 That Selects tRNAGlu for Replication. J. Virol.
77: 8756-8764
[Abstract]
[Full Text]
-
Gaddis, N. C., Chertova, E., Sheehy, A. M., Henderson, L. E., Malim, M. H.
(2003). Comprehensive Investigation of the Molecular Defect in vif-Deficient Human Immunodeficiency Virus Type 1 Virions. J. Virol.
77: 5810-5820
[Abstract]
[Full Text]
-
Sakuragi, J.-I., Ueda, S., Iwamoto, A., Shioda, T.
(2003). Possible Role of Dimerization in Human Immunodeficiency Virus Type 1 Genome RNA Packaging. J. Virol.
77: 4060-4069
[Abstract]
[Full Text]
-
Goldschmidt, V., Rigourd, M., Ehresmann, C., Le Grice, S. F. J., Ehresmann, B., Marquet, R.
(2002). Direct and Indirect Contributions of RNA Secondary Structure Elements to the Initiation of HIV-1 Reverse Transcription. J. Biol. Chem.
277: 43233-43242
[Abstract]
[Full Text]
-
Morris, S., Johnson, M., Stavnezer, E., Leis, J.
(2002). Replication of Avian Sarcoma Virus In Vivo Requires an Interaction between the Viral RNA and the T{psi}C Loop of the tRNATrp Primer. J. Virol.
76: 7571-7577
[Abstract]
[Full Text]
-
Berkhout, B., Das, A. T., Beerens, N., Araya, A., Litvak, S.
(2001). HIV-1 RNA Editing, Hypermutation, and Error-Prone Reverse Transcription. Science
292: 7a-7
[Full Text]
-
Beerens, N., Groot, F., Berkhout, B.
(2000). Stabilization of the U5-leader stem in the HIV-1 RNA genome affects initiation and elongation of reverse transcription. Nucleic Acids Res
28: 4130-4137
[Abstract]
[Full Text]
-
Beerens, N., Berkhout, B.
(2000). In Vitro Studies on tRNA Annealing and Reverse Transcription with Mutant HIV-1 RNA Templates. J. Biol. Chem.
275: 15474-15481
[Abstract]
[Full Text]
-
Beerens, N., Groot, F., Berkhout, B.
(2001). Initiation of HIV-1 Reverse Transcription Is Regulated by a Primer Activation Signal. J. Biol. Chem.
276: 31247-31256
[Abstract]
[Full Text]
Top
Abstract
Introduction
