From the Pathogénie des Infections à Lentivirus, INSERM U372, 163 Avenue de Luminy, BP 178, 13276 Marseille-Cedex 9, France
Received for publication, February 19, 2003
, and in revised form, March 28, 2003.
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ABSTRACT |
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INTRODUCTION |
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Mutational analysis of IN identified distinct functional domains within the protein. The N-terminal domain (residues 1 to 50) contains a highly conserved HHCC motif that binds zinc (2, 3, 4). The catalytic core domain spans residues 51212 and contains the invariant residues Asp-64, Asp-116, and Glu-152 (5, 6, 7, 8, 9). The C-terminal domain (residues 213288) binds to the viral DNA and also possesses nonspecific DNA binding properties (10, 11, 12, 13, 14). Genetic studies have indicated that mutations in IN affect multiple and distinct steps in the replication cycle, including protein maturation, virion morphology, uncoating, reverse transcription, and integration per se, revealing multiple consequences of altered IN in the viral life cycle (15).
Although in vitro studies have demonstrated that IN alone is sufficient to promote the integration process (1), lines of evidence indicate that other viral and cellular proteins can regulate this process. For example, it has been reported that NCp7 might influence the coupled joining by promoting DNA distortion (16) and that reverse transcriptase might play a role in blocking the auto-integration process (17). Host proteins, upon association with IN, have also been reported to improve in vitro viral DNA integration. The barrier-to-autointegration factor (BAF) acts as an inhibitor to the undesirable autointegration process (18), and the HMGI(Y) protein stimulates concerted viral DNA integration (19). DNA-dependent protein kinase has been reported to be involved in the completion of the integration process (20). In some cases host proteins, such as the integrase inhibitor 1 (Ini1) factor or the uracil DNA glycosylase (UNG2) enzyme, interact with IN and are specifically incorporated into viral particles (21, 22).
In a previous study, we demonstrated that leucine residue 172 of IN was
important for the packaging of the host UNG2 enzyme
(23). We have shown that
virion-associated UNG2 plays a role similar to its cellular counterpart and
participates in the correction of G:U mispairs to G:C pairs. The present study
was designed to investigate whether the presence of UNG2 inside viral
particles was required for efficient viral replication. We used a series of
viruses mutated for each of the residues encompassing the region 170181
of the 5 helix of IN, which is located outside of the catalytic triad
of aspartic acid and glutamic acid residues, the D, D(35)E sequence motif.
This series of mutations enabled us to classify viruses as deficient or
proficient for UNG2 packaging
(23). Our results show the
following. i) Viruses with IN mutated at residues 172/173, 174, 178, and
180/181 are impaired for replication. ii) The failure to replicate of viruses
with mutations at residues 174, 178, and 180/181, but not of those with
mutations at residues 172/173, correlates with a loss of the in vitro
catalytic activity of IN. iii) Although IN with mutation at residues 172/173
still retains its enzymatic activity, the integration process of L172A/K173A
viruses is abrogated in the context of infection. iv) Finally, overexpression
in trans of VPR·L172A/K173A IN fusion protein rescues, in a
dose-dependent manner, the replication of L172A/K173A viruses, indicating that
the defect of cis IN mutated viruses was compensated by increasing
amounts of mutated IN. Altogether, our data point out the importance of
leucine residue 172 in the viral integration process and UNG2 packaging.
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MATERIALS AND METHODS |
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Cell Lines, Transfection, and InfectionHuman 293T cells were cultured in Dulbecco's modified Eagle's medium (Invitrogen) supplemented with antibiotics and 10% fetal calf serum. The SupT1, H9, and C8166 cell lines were cultured in RPMI 1640 medium (Invitrogen) supplemented with antibiotics and 10% fetal calf serum. Viral stocks were produced by transfection of each of the proviral DNAs into subconfluent 293T cells with the FuGENE 6 transfectant reagent (Roche Applied Science) according to the manufacturer's protocol. For viral replication studies, SupT1 cells were infected with viral stocks obtained from the cell-free supernatant of transfected 293T cells and calibrated for equivalent amounts of CA p24 antigen by HIV-1 p24 antigen capture assay kit (Coulter). Propagation of viral infection was followed by measuring the reverse transcriptase activity in cell-free supernatants twice a week. For trans-complementation studies, provirus expression plasmids were cotransfected in 293T cells at a ratio of 2:1 with pLR2P-Vpr-IN expression vectors. Viral supernatants were then calibrated for similar amounts of CA p24 antigen by an HIV-1 p24 antigen capture assay kit. Serial 5-fold dilutions were used to infect the C8166 indicator cell line. The infectivity of trans-complemented viruses was calculated by the Reed-Muench method (25) to determine the 50% tissue culture infective dose (TCID50). Expression of Vpr·IN fusion proteins in trans-complemented viruses was analyzed by Western blot with rabbit polyclonal anti-IN antibody (a gift from D. Trono). Similar amounts of trans-complemented viruses were used as judged by the level of CA p24 antigen in the viral lysate revealed by Western blot with sheep polyclonal anti-p24 antibody (Aalto Bio Reagents, Rathfarnham-Dublin, Ireland). The presence of UNG2 was revealed by Western blot using anti-UNG2 antibody kindly provided by G. Slupphaug.
Purification of VirusesViral particles released in the cell-free supernatant of transfected cells were collected by ultracentrifugation and highly purified through 818% Optiprep density gradient as described (26). Gradient fractions coinciding with the peak of the reverse transcriptase activity were pooled and normalized for equivalent amounts of the CA p24 antigen. Viral lysate was obtained by lysis of purified virions in TNE buffer (10 mM Tris-HCl, pH 7.5, 100 mM NaCl, and 1 mM EDTA) in the presence of 0.2% of Triton X-100.
In Vitro Catalytic Activity of INGST·IN fusion
proteins were expressed in Epicurian Coli BL21-codonPlus RIL (Stratagene) and
purified on glutathione-agarose beads as reported previously
(23). GST derivatives were
eluted from agarose beads in the presence of 20 mM glutathione, and
the purity of proteins was estimated by Coomassie Blue staining. The amounts
of GST derivatives were quantified by comparison with the bovine serum albumin
(BSA) standard. The oligonucleotide pair used for processing activity
measurement was 71 (5'-GTGTGGAAAATCTCTAGCAGT-3') and 72
(5'-ACTGCTAGAGATTTTGCACAC-3'). The oligonucleotide pair used for
strand transfer activity measurement was 70
(5'-GTGTGGAAAATCTCTAGCA-3') and 72. Oligonucleotides 70 and 71
were 5'-end labeled with T4 polynucleotide kinase in the presence of
[-32P]ATP and purified through Microspin G25 columns
(Amersham Biosciences) before annealing to oligonucleotide 72. IN catalytic
activity was assayed essentially as described
(27). Briefly, 200
nM of each GST derivative were incubated with 10 nM of
the appropriate set of oligonucleotides in a final volume of 20 µl of a
buffer containing 20 mM Hepes, pH 7.2, 1 mM
dithiothreitol, and 10 mM MnCl2. After an incubation of
1 h at 37 °C, the reactions were stopped by the addition of 20
mM EDTA, and DNA products were recovered by ethanol precipitation
in the presence of 10 µg of tRNA carrier. DNA products of the
3'-processing and DNA strand transfer reactions were dried and dissolved
in 10 µl of 95% formamide loading dye. The samples were separated on 8
M urea, 15% polyacrylamide denaturating gels in 1x TBE. Gels
were fixed in 10% acetic acid, and radiolabeled products were visualized by
autoradiography. Where indicated, increasing amounts (5, 25, and 100
nM)ofGST·wild-type IN and GST·L172A/K173A IN were
used in the assay.
Determination of Viral DNA IntegrationViral stocks from transfected 293T cells were filtered through 0.45-µm pore size filters and treated with DNase I (20 µg/ml) for 30 min at 37 °C in the presence of 10 mM MgCl2. H9 cells (106) were infected for 2 h by spinoculation (28) with equal amounts of IN mutant viruses; then cells were washed extensively with phosphate-buffered saline and cultured for 18 additional hours. The total DNA was isolated from the infected cells by the QIAamp DNA Mini Kit protocol (Qiagen) and eluted with 200 µl of elution buffer. Viral DNA products corresponding to the different steps of retrotranscription were assessed by quantitative real-time PCR as described in literature (29). Real-time PCR was performed with an ABI PRISM 7000 apparatus (Applied Biosystems) using PCR primers and TaqMan probes described previously (29). The integrated forms of proviral DNA were assessed using a two-step PCR amplification with 5' Alu primer (5'-TCCCAGCTACTGGGGAGGCTGAGG-3') and L1 primer (5'-AGGCAAGCTTTATTGAGGCTTAGGC-3') followed by nested PCR with L2 primer (5'-CTGTGGATCTACCACACACAAGGCTAC-3') and L3 primer (5'-GCTGCTTATATGTAGCATCTGAGGGC-3') as described (30).
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RESULTS |
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Catalytic Activity of IN MutantsWe therefore investigated whether disrupting some residues of the region 170181 of IN affects its catalytic function. We measured processing and integration steps by using in vitro assays with similar amounts of purified GST·IN proteins. For these assays, IN mutant proteins fused in N terminus to GST were purified from bacterial lysate and incubated with appropriate oligonucleotides. The presence of faster migrating DNA species is the hallmark of the processing process (Fig. 3, top panel), and the presence of slower-migrating DNA species is the hallmark of the integration process (Fig. 3, bottom panel). As a negative control, we used the GST·IN protein with a missense mutation (D116A) in the catalytic core domain of IN, impairing the integration process (6). Results showed that IN proteins with mutations at residues 170/171, 172/173, and 176/177 behaved as wild-type (Fig. 3). In contrast, IN with mutations at residues 174, 178, or 180/181 was enzymatically inactive, explaining why viruses carrying these mutations failed to replicate. Intriguingly, the L172A/K173A IN protein exhibited wild-type catalytic activity, although this mutation in the context of HIV-1 virus infection was shown to impair replication. A provirus bearing the single point mutation L172A was constructed, and results of the infectivity study showed that residue L172A alone was responsible for both UNG2 packaging (23) and the defect of replication (not shown).
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Impaired Integration Process of L172A/K173A VirusesWe next examined which step(s) of the viral life cycle, including reverse transcription, nuclear import, and integration processes, was altered in cells infected with L172A/K173A viruses. H9 cells were infected with similar amounts of viruses from the DNase I-treated cell-free supernatant of transfected cells, and, 18 h post-infection, viral DNA from wild-type or IN mutated viruses produced during the unique cycle of infection was extracted and amplified with appropriate primer pairs. Using real-time PCR to quantify the amounts of reverse transcription intermediate DNA products (R-U5, R-Gag, and 2-LTR circles), we detected similar amounts of completed products of reverse transcription in cells infected with either wild-type, D116A, or L172A/K173A viruses (data not shown), indicating that viral DNA synthesis and nuclear entry were unaffected.
We then measured the integration process by evaluating proviral integration events using an Alu LTR PCR assay with primers corresponding to the viral LTR and the repetitive Alu sequences present in the cellular DNA. Results in Fig. 4 show the complete absence of integrated DNA products for D116A and L172A/K173A viruses in contrast to wild-type viruses, indicating that the L172A/K173A virus was defective at the integration step, although its integrase was demonstrated to be functional in the LTR mimic assays in vitro.
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Rescue of the Replication of L172A/K173A VirusesTo
address whether replication of L172A/K173A viruses could be restored, we used
a previously reported experimental system
(24,
31,
32,
33,
34) in which IN protein was
incorporated in trans into viral particles via a fusion with HIV-1
Vpr (Fig. 5A). It has
been reported that proviruses mutated in one domain of IN can be rescued by
trans-expressed IN containing mutations in another domain
(14). This successful
trans-complementation was indeed due to the ability of INs to oligomerize each
subunit, providing distinct functions to obtain a wild-type IN phenotype.
Viral stocks were generated by cotransfection of D116A, IN minus (IN),
or L172A/K173A proviral DNA together with expression vectors encoding
VPR·wild-type IN, VPR·L172A/K173A IN, or VPR·D116A IN
fusion proteins. The C8166 indicator cell line was infected with serial 5-fold
dilutions of viral stocks. The infectivity of trans-complemented viruses was
measured by the number of cell-forming syncytia and expressed as the
TCID50. Expression of Vpr·IN fusion proteins in
trans-complemented viral particles was demonstrated by Western blotting
(Fig. 5B). The
apparently higher levels of IN in trans-complemented viruses, compared with
non-trans-complemented viruses, is likely due to proteolytic cleavage of the
Vpr·IN protein by the viral protease.
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As expected, the trans-expression of wild-type IN rescued the replication
of the IN, L172A/K173A, and D116A viruses
(Fig. 5C). The
trans-expression of D116A IN, which is catalytically incompetent, restored the
replication of L172A/K173A viruses but not that of
IN and D116A
viruses. Conversely, trans-expression of L172A/K173A IN has the capacity to
rescue the replication of D116A and
IN viruses up to
50% of that
shown with trans wild-type IN. Unexpectedly, trans-complementation
experiments showed that trans L172A/K173A IN can rescue the
propagation of L172A/K173A viruses, although both cis- and trans-expressed IN
proteins carried the same mutation. This restoration is approximately twice
less efficient than that observed with trans wild-type IN, whatever the
cis-expressed viruses. Altogether, these results suggest that mutations of
residues 172 and 173 of IN fused to Vpr did not alter the catalytic property
of IN.
The Rescue of Replication Is Independent of UNG2
PackagingPrevious studies have reported that Vpr associates with
UNG2 (35) and that Vpr can
promote the packaging of overexpressed HA-tagged UNG2 into viral particles
(36). To investigate whether
the rescue of L172A/K173A viruses might be due to the packaging of host UNG2
via the Vpr portion within the Vpr·IN fusion protein, we analyzed the
presence of packaged UNG2 into highly purified IN viruses
trans-complemented with either Vpr·IN or VPR·L172A/K173A IN.
Results presented in Fig. 6
show that
IN virus was devoid of detectable endogenous UNG2 and that
neither Vpr fusions with wild-type IN nor those with mutated IN were able to
direct a substantial packaging of UNG2. As a control, similar amounts of the
HIV-1 wild-type virus were analyzed and showed the presence of packaged UNG2.
These data indicate that IN promoted UNG2 packaging in the context of the
Gag-Pol polyprotein but not in the context of a Vpr·IN fusion. To
ascertain that no UNG2 packaging was responsible for the rescue, we performed
trans-complementation assays with a Vpr·IN fusion protein, containing
Vpr mutated at tryptophan 54, fused to L172A/K173A IN. The W54R and W54G
mutations have been shown to abolish the interaction with UNG2
(36).2
Our results indicate that the W54G·VPR·L172A/K173A IN fusion
protein rescued the viral propagation of L172A/K173A viruses to the same
extent as the wild-type VPR·L172A/K173A IN fusion protein,
demonstrating that the Vpr-UNG2 association was not involved in the successful
rescue of L172A/K173A viruses (data not shown).
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Trans-complementation of cis L172A/K173A Viruses by trans L172A/K173A IN Is Dose-dependentTo understand how the overexpression of L172A/K173A IN can rescue the propagation of L172A/K173A viruses, we carried out trans-complementation experiments with increasing amounts of wild-type and L172A/K173A IN fusion proteins. The expression level of fused proteins in both cell lysate and viral particles was analyzed by Western blot (Fig. 7A). Trans-complementation of L172A/K173A viruses with increased doses of trans wild-type or L172A/K173A IN proteins led to a dose-dependent rescue of viral propagation (Fig. 7B). These data indicate that the failure to replicate of L172A/K173A viruses could be compensated by increasing amounts of trans L172A/K173A IN protein delivered into viral particles.
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To demonstrate that IN alone, and not IN-associated proteins, was involved
in the rescue of L172A/K173A viruses, we performed in vitro
experiments wherein the catalytic activity of increasing amounts of
recombinant L172A/K173A IN was compared with that of wild-type IN. As shown in
Fig. 8, both the processing and
DNA strand transfer of L172A/K173A IN fusion protein, although this latter was
catalytically active, were nevertheless 4 times less efficient than those
of wild-type IN. These in vitro results are consistent with in
vivo results showing that trans L172A/K173A IN in infected cells
rescues the replication of cis L172A/K173A viruses in a dosedependent
manner.
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DISCUSSION |
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In trans-complementation assays, proviruses mutated in one domain of IN can be rescued by trans-expressed IN containing a mutation in another domain (14). This trans-complementation was due to the ability of INs to oligomerize, each subunit providing distinct functions to obtain a wild-type IN phenotype. The replication defect of viruses carrying the L172A/K173A IN mutation can be rescued by the coexpression in trans of the catalytically incompetent D116A IN protein, indicating that the two mutated IN proteins retain their ability to oligomerize and that the defect of the L172A/K173A IN viruses was compensated by the presence of the wild-type leucine 172 residue in D116A. Therefore, the replication blockage of L172A/K173A viruses was not due to alteration of the catalytic properties of the mutated IN per se.
Remarkably, these L172A/K173A viruses were also rescued by dose-dependent trans-expression of the same mutated IN. These data correlate well with the integration assays using LTR mimics in vitro, which show that four times more L172A/K173A IN than wild-type IN was required to achieve a similar integration pattern. Because the first step of the integration reaction, namely the processing of the 3'-ends of the LTR mimics, is affected, we propose that mutated IN is less efficient in binding to the LTR ends. This weakness in LTR binding was alleviated by allowing a higher concentration of mutated IN. We propose that the integration process is a rate-limiting process in the natural course of HIV-1 infection. It is possible that the integration activity of viruses with the L172A/K173A IN mutation is just below the threshold. A slight enhancement of the expression of IN in infected cells, even carrying the same mutation, might surpass the threshold and lead to the restoration of the integration process.
In trans-complementation assays, we observed that host UNG2 could not be packaged by the Vpr·IN fusion despite being clearly dependent on the presence of IN in the context of the Gag-Pol precursor. We can speculate on two hypotheses, which are not mutually exclusive. First, the folding of IN processed from the Vpr fusion protein may not accurately reflect the folding of IN processed from the Gag-Pol precursor, leading to differential bindings of UNG2. Such a differential in binding between INs deriving from either the Vpr·IN fusion or the Gag-Pol precursor has been reported in the case of the HA-S6 trans dominant mutant of the integrase interactor 1 (Ini 1) (21). Second, although the IN domain of the Gag-Pol precursor is required for UNG2 packaging, it may not be sufficient. Indeed, we have reported previously that UNG2 can also bind viral reverse transcriptase (23). It may be that a triple interaction between UNG2 and both the reverse transcriptase and IN domains of the Gag-Pol precursor is necessary to allow the efficient packaging of UNG2.
Because the L172A/K173A mutation led to a severe blockage in provirus integration in vivo, we were unable to follow the replication of the sole UNG2-deficient virus over many replicative cycles. The integration defect could be rescued in trans by overexpression of IN, either wild-type or mutated, but it allowed only one replicative cycle. However, we have previously reported (23) that wild-type but not UNG2-deficient viruses have the ability to repair G:U mispairs, suggesting a role of UNG2 in the control of the accuracy of reverse transcription. If the rescued proviral DNA is riddled with G to A mutations due to unprocessed uracils in the absence of packaged UNG2, that would lead to impair replication in subsequent passages of the virus. The role of the virion-associated UNG2 enzyme in the viral life cycle remains an open question and will require studies of viral replication in UNG2-deficient T cells.
In conclusion, we have investigated the replicative properties of UNG2-deficient or -proficient IN mutant viruses in order to study the role of packaged UNG2 in the viral life cycle. We have not been able to draw definite conclusions about the importance of UNG2 for HIV-1 replication, but we have found an interesting mutant of IN that could be rescued by allowing a higher concentration of the very same mutant integrase in the viral particle. Whether the mutation L172A/K173K leads to a reduced affinity of IN for its LTR substrate or to another undefined defect remains to be investigated.
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FOOTNOTES |
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Recipient of a fellowship of the French Ministry of Research.
To whom correspondence should be addressed. Tel.: 33-491-82-75-91; Fax:
33-491-82-60-61; E-mail:
jsire{at}inserm-u372.univ-mrs.fr.
1 The abbreviations used are: HIV-1, human immunodeficiency virus, type 1;
IN, integrase; IN, IN minus; CA, capsid; LTR, long terminal repeat;
UNG2, uracil DNA glycosylase; GST, glutathione S-transferase;
TCID50, 50% tissue culture infective dose.
2 S. Priet, J.-M. Navarro, G. Quérat, and J. Sire, unpublished
data.
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ACKNOWLEDGMENTS |
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REFERENCES |
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