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Journal of Virology, January 2001, p. 234-241, Vol. 75, No. 1
Laboratoire d'Immunologie Cellulaire,
CNRS-UMR 7527,1 Service des Maladies
Infectieuses,2 and Laboratoire de
Virologie,3 Hôpital
Pitié-Salpétriêre, Paris, France
Received 7 July 2000/Accepted 29 September 2000
Immune control of human immunodeficiency virus (HIV) is not
restored by highly active antiretroviral therapies (HAART) during chronic infection. We examined the capacity of repeated structured therapeutic interruptions (STI) to restore HIV-specific CD4 and CD8
T-cell responses that controlled virus production. Eleven STI (median
duration, 7 days; ranges, 4 to 24 days) were performed in three
chronically HIV-infected patients with CD4 counts above 400/mm3 and less than 200 HIV RNA copies/ml after 18 to 21 months of HAART; treatment resumed after 1 week or when virus became
detectable. HIV-specific T-cell responses were analyzed by
proliferation, gamma interferon (IFN- Combined antiretroviral
therapy can substantially reconstruct the damaged immune system in
human immunodeficiency virus (HIV)-infected patients (1, 10,
17). This major success is, however, limited by the inability of
highly active antiretroviral therapy (HAART) to eradicate HIV and
restore HIV-specific T-cell immunity. The main immune effector involved
in viral control, the HIV-specific CD8 cell response, decreases to
resting-memory low levels when plasma viremia becomes undetectable
after a successful antiretroviral treatment (2, 5, 13,
14). The loss of HIV-specific stimulation that necessarily
follows therapeutic control of HIV might be responsible for such a
decline. The CD8 T-cell responses also depend on generating or
maintaining high levels of HIV-specific CD4 Th1 T cells, which are
detectable only in long-term nonprogressors concurrently with strong
immune control of the virus (22; B. Autran, O. Bonduelle, A. Goubar, D. Candotti, H. Agut, P. Debré, et al., submitted for
publication). These Th1 cells are, however, partially eliminated early
in infection (22) but can be preserved when HAART is
initiated at primary infection (16, 22). In chronic
disease, however, such responses are usually weak (18) or
undetectable and are not restored by HAART (1, 19-21)
except in poorly compliant patients (7). These
observations led to the proposal of transient structured therapeutic
interruptions (STI) to boost the declining T-cell responses to HIV by
reexposing the immune system to virus rebounds. Indeed, several
consecutive drug "holidays" might enhance the immunological set
point and help at controlling virus production when treatment is
introduced during primary infection (11, 15). No rebound
in HIV-specific CD4 T-helper cells has yet been reported, however,
during STI, especially in chronically infected patients. A single
scheduled HAART interruption in chronic infection does not affect the
efficacy of renewed therapy (12, 23). We also showed that
the complete arrest of a triple-drug regimen 1 month after initiation
was followed in all cases by a 1-week delay before virus rebound
(12). Based on these observations, we performed a
prospective pilot study of short-course repeated STI in chronically HIV-infected patients to evaluate whether small bursts of HIV during
STI might restimulate in vivo virus-specific CD4 and CD8 T-cell
responses and to determine the kinetics of these immune responses and
their capacity at delaying subsequent virus rebounds.
Study design and patients.
HIV-1 chronically infected
patients who had been seropositive for 7 to 11 years, were receiving a
HAART regimen with 2 nucleoside analogs plus one protease inhibitor or
one nonnucleoside reverse transcriptase (RT) inhibitor, and had a CD4
lymphocyte count >400/mm3 and a plasma HIV RNA count of
<200 copies/ml for at least 6 months were recruited for the study. All
signed an informed-consent form. Based on our previous observation
(12), we initially designed a fixed duration of 7 days for
STI, which should have led to virus detectability. This schedule was
maintained for the first three STI in patient 1, who was the first to
be included, and for the first STI in patients 2 and 3. Since virus
rebound occurred only once during these five STI, the subsequent
discontinuations of therapy were maintained until the virus reached a
level above 1,000 copies/ml. Three or four STI were performed for each
patient, with an interval of 2 to 3 months between the first and second STI and then an interval of 1 to 2 months between subsequent STI.
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.1.234-241.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Transient Mobilization of Human Immunodeficiency
Virus (HIV)-Specific CD4 T-Helper Cells Fails To Control Virus Rebounds
during Intermittent Antiretroviral Therapy in Chronic HIV Type 1 Infection
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
) production, and enzyme-linked
immunospot assays. Seven virus rebounds were observed (median, 4,712 HIV-1 RNA copies/ml) with a median of 7 days during which CD4 and CD8 counts did not significantly change. After treatment resumed, the viral
load returned below 200 copies/ml within 3 weeks. Significant CD4
T-cell proliferation and IFN- production against HIV p24 appeared
simultaneously with or even before the virus rebounds in all patients.
These CD4 responses lasted for less than 3 weeks and disappeared before
therapeutic control of the virus had occurred. Increases in the numbers
of HIV-specific CD8 T cells were delayed compared to changes in
HIV-specific CD4 T-cell responses. No delay or increase in virus
doubling time was observed after repeated STI. Iterative reexposure to
HIV during short STI in chronically infected patients only transiently
mobilized HIV-specific CD4 T1-helper cells, which might be rapidly
altered by virus replication. Such kinetics might explain the failure
at delaying subsequent virus rebounds and raises concerns about
strategies based on STI to restore durable HIV-specific T-cell
responses in chronic HIV infection.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
HIV-1 RNA plasma quantification. Quantification of HIV-1 RNA levels in plasma was performed using the Amplicor Monitor assay (Roche Diagnostics, Basel, Switzerland) with a detection limit of 200 copies in real time. All frozen plasma samples were reanalyzed in batch experiments using the detection limit of 20 copies.
Sequence analysis. Plasma RNA at viral rebounds was used for sequence analysis of the RT and protease genes. After purification and reverse transcription, a nested PCR with AmpliTaq Gold (Applied Biosystems, Foster City, Calif.) was performed. For the RT gene, primers 5'MJ3 and 3'MJ4 were used for the one-step RT-PCR and primers 5'A35 and 3'NE1-35 were used for the nested PCR (8). For the protease gene, primers 5'eprB and 3'eprB were used for the one-step RT-PCR and primers 5'prB and 3'prB were used for the nested PCR (3). The purified DNA fragments obtained were directly sequenced with the ABI PRISM Dye Terminator cycle-sequencing kit (Applied Biosystems). Sequence products were analyzed with the ABI PRISM 377 automatic sequencing system. Codon changes considered to be mutations were those showing any difference from the HIV-1 consensus B sequence (24).
Statistical analysis. Rates of viral rebound were calculated using linear regression on log-transformed HIV-1 RNA concentrations in plasma. Doubling times were calculated as ln 2/rate.
Flow cytometry. Absolute CD4 and CD8 cell counts were obtained in fresh blood samples as previously described (10).
Lymphocyte subpopulations were analysed in whole blood with the following monoclonal antibodies (MAbs): HLA-DR-PE and CD38-PE (Becton-Dickinson, Pont de Claix, France) and CD3-PE, CD4-PECY5, CD8-PECY5, CD45RA-PE, CD62L-FITC, CD45-FITC/CD14-PE, and Ki67-FITC (Immunotech, Marseille-Luminy, France). A total of 5,000 lymphocytes were analyzed by three-color flow cytometry as described previously (10). Intracellular Ki67 expression in CD4+ and CD8+ T cells was analyzed after permeabilization by standard procedures on 20,000 to 100,000 CD4 or CD8 events in a large lymphocyte gate on a forward-scatter and side-scatter plot including blasts; monocytes were excluded by their low-level CD4 expression.Lymphocyte proliferation assay. Gradient density separation was used to isolate peripheral-blood mononuclear cells (PBMC). Incubating PBMC with magnetic beads coated with anti-CD8 MAb (Dynabeads; Dynal, Oslo, Norway) negatively selected CD4 T cells, with less than 5% residual CD8+ cells. Total and CD8-depleted PBMC were simultaneously cultured as previously described (10) with p24 (0.25 µg/ml); (Intracell, London, United Kingdom), tuberculin (Statens Serum Institut, Copenhagen, Denmark) or cytomegalovirus (CMV) (Behring, Marburg, Germany) and then labeled with tritiated thymidine (CEA, Saclay, France) on day 6. The stimulation index (SI) was calculated as the ratio of (cells plus stimuli) cpm to (cells plus medium) cpm. Positive antigen-specific responses were defined as those with greater than 3,000 cpm and an SI greater than 3.
In vitro cytokine production assay.
Cell culture
supernatants were harvested on day 2 from CD8-depleted PBMC cultured at
106/ml with p24 (0.25 µg/ml) (Intracell) or medium alone
and measured by an enzyme immunoassay for IFN- (Diaclone,
Besançon, France). IFN- levels in the control supernatants
without antigen were subtracted from the results of specific
production. A response above 30 pg/ml was considered positive.
ELISPOT assay for single-cell IFN- release using recombinant
vaccinia virus constructs or synthetic peptides.
Capture
anti-human IFN- MAb (Diaclone) was coated on 96-well polyvinylidene
difluoride-bottom plates (Millipore, Molsheim, France). The vaccinia
virus assay was adapted from Larsson et al. (9). Various
recombinant vaccinia viruses encoding either Gag, Pol, Env, or Nef were
a kind gift from Transgène (Strasbourg, France). Wild-type
vaccinia virus served as negative control. Recombinant vaccinia viruses
were added to PBMC at a multiplicity of infection of 5 PFU/cell as
previously described (6), after which infected cells were
used directly in the ELISPOT assay. Infected or uninfected PBMC were
added to triplicate wells at 105 cells per well, and the
plates were incubated for 16 to 18 h at 37°C in 5% CO2.
The peptide assay was adapted from Dalod et al. (2). PBMC
were added to triplicate wells at 1 × 105, 5 ×104, and 1 ×104 cells/well with 10 µg of
peptide per ml, phytohemagglutinin (Murex, Paris, France), or medium
alone and incubated for 40 h at 37°C in 5% CO2.
Twelve published HIV-1 cytotoxic T-lymphooyte epitopes were selected
from the Los Alamos HIV molecular immunology database by their HLA
class I restriction: HLA-A2: Gag 77-85 (G3), Pol 476-484 (P1);
HLA-B44: Gag 306-316 (G4); HLA-B14: Gag 183-191 (G5), Env 586-593
(E4); HLA-A24: Env 584-592 (E1); HLA-B51: Pol 295-302 (P5), Env
557-565 (E3); HLA-A11: Pol 313-321 (P3), Nef 73-82 (N1); and
HLA-B35: Gag 254-262 (G7), Pol 311-319 (P4). The synthetic peptides
were purchased from Syntem (Nimes, France) or kindly provided by Agence
Nationale de la Recherche sur le SIDA.
MAb
(Diaclone) was added, followed by streptavidin-alkaline phosphatase
conjugate (Amersham, Les Ulis, France) and chromogen substrates
(5-bromo-4-chloro-3-indolylphosphate toluidine and nitroblue
tetrazolium) (Sigma-Aldrich, St. Quentin, France). Spots were counted
under a magnifying glass. The number of peptide-specific T cells,
expressed as spot-forming cells (SFC)/106 PBMC, was
calculated after subtracting negative control values.
Real-Time PCR detection of IFN-.
RNA was extracted from
fresh PBMC using RNeasy 96 (Qiagen, Chatsworth, Calif.). A constant
amount of target RNA was reverse transcribed with 100 IU of Moloney
murine leukemia virus RT (Gibco BRL, Glasgow, Scotland) in the presence
of 5 µM per random primer. Real-time quantitative PCR with 1 µl of
c-DNA was performed in triplicate using human cytokine IFN-
pre-developed TaqMan assay reagents (Perkin-Elmer, Applied Biosystems,
Foster City, Calif.) as specified by the manufacturer, including
controls, on an ABI Prism 7700 sequence detector, which contains a
Gene-Amp PCR system 9600 instrument (Perkin-Elmer, Applied Biosystems).
A normalization 18S RNA experiment was performed simultaneously for
each sample with 18SRNA primer and carboxyfluorescein-labeled 18SRNA
probe. CT (threshold) values were calculated for target (IFN- CT)
and standard (18S RNA CT) genes by determining the point at which the
fluorescence exceeded a threshold limit (10 times the standard deviation of the baseline). The results are expressed as 
CT; expressed as mean (IFN- CT) 
mean (18SRNA CT).
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RESULTS |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Virus and CD4 kinetics during STI.
Table
1 summarizes the patients'
characteristics. The three HIV-1 chronically infected patients had been
seropositive for 7 to 12 years with nadir CD4 levels of 236, 211, and
456/mm3 and maximal viral loads before HAART of 59,000, 48,500, and 73,000 copies/ml. All had been treated with the same line
of therapy for 18 to 21 months, which had led to virus control under
the threshold of 200 copies/ml for at least the last 6 months and CD4
counts above 400/mm3. Patient 1 (Fig.
1A) did not experience any plasma viral
rebound during three STI of 1 week each. The fourth STI thus was
continued until the plasma virus level became detectable: on day 21, the viral load reached 15,207 copies/ml, and on day 24 it reached 113,333 copies/ml. For patient 2 (Fig.
2A), the first 7-day STI similarly did
not cause his plasma viral load to rebound. The following STI continued
until the plasma virus level became detectable. Rebounds occured within
15 and 19 days of the second and third STI, respectively. Viral loads
had reached 6,640 and 4,712 copies/ml when treatment resumed. For
patient 3 (Fig. 3A), plasma virus levels
rebounded slightly, to 399 copies/ml, on day 4 of the first 7-day STI.
A second STI continued until the viral load became detectable on day 10 and reached 6,737 copies/ml on day 18. During the next two STI,
however, the viral load rapidly increased on day 3, reaching 3,795 and
2,719 copies/ml, and treatment was therefore resumed immediately.
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1
picograms per milliliter; T cell proliferative responses against HIV-1
(p24) were measured on CD8-depleted PBMC, and the results are expressed
as a stimulation index. (D) Effect of intermittent interruptions of
antiretroviral therapy on CD8+ cell responses to HIV-1
protein. The frequency of HIV-specific CD8+ T cells was
tested by a recombinant vaccinia virus ELISPOT assay. PBMC were
infected with wild-type vaccinia virus or recombinant vaccinia virus
Gag, Pol, Env, or Nef, and IFN-
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163/mm3 (range, +14 to 297). Both CD4 and CD8 counts
returned to baseline values at end of the study. For all three
patients, viral replication decreased below or close to baseline levels
within 3 weeks after therapy resumed, except after two STI. This
persistence of detectable virus replication did not lead to changes of
virus doubling time in either case during the next STI.
No resistance-conferring mutations (24) were observed in
the HIV-1 RT and protease genes during the rebounds (data not shown).
Virus replication-induced bursts of T-cell activation. The consequences of virus rebounds for T-cell activation and differentiation status were evaluated. All patients had normal baseline proportions of both CD4+ and CD8+ cells expressing Ki67+ a cell cycle marker (Fig. 1B, 2B, and 3B). Minimal, if any, increases in the proportion of CD4+ Ki67+ cells were observed except in patient 3. The proportion of CD8+ Ki67+ cells, however, most often increased simultaneously with or a few days after peaks in viral load, to reach 9% of CD8 cells. These levels persisted for 1 week after viral control was reestablished.
Analyzing late CD8+ T-cell activation markers, such as HLA-DR and CD38, yielded similar results, involving slight increases (data not shown) with return to baseline in all cases after each interruption and at the end of the study. Neither the proportions nor the absolute counts of either naive (CD45RA+ 62L+) or memory (CD45RO+) CD4+ T cells varied significantly (data not shown).Rapid but transient increase in numbers of HIV-specific
CD4+ T cells during virus rebounds.
At baseline, a
conventional lymphocyte proliferation assay detected no HIV
p24-specific response even when performed with CD8-depleted PBMC,
except for patient 2. Similarly cytokine production against HIV-1 p24
was undetectable. In patient 1 (Fig. 1C), the Th1 response to p24 did
not increase during the three STI that did not led to virus rebound.
The strong virus rebound during the last interruption induced only
IFN- production but no proliferative response: the p24-specific
IFN- production increased 1 week after drug arrest and 10 days
before virus became detectable. This IFN- production, however,
rapidly disappeared 1 week before the peak viral load was attained.
production against p24 increased significantly during the first 7-day
STI, although no rebound of the viral load in plasma was detectable
(Fig. 2C). The peaks in viral load during the subsequent STI were also
accompanied by an anti-HIV-1 p24 Th1 response that was mobilized as
soon as the virus reached detectability and even 3 days before the
increase in viral load during the second STI. The SI and/or IFN-
production had already decreased by the time of the peak viral load.
The HIV-specific Th1 responses became almost undetectable 10 days
later, after therapy resumed, whether the viral load was controlled
(third STI) or not (second STI). To evaluate whether the CD4 T cells
were producing IFN- in vivo during these rebounds, we quantified the
IFN- messengers ex vivo in freshly harvested, unstimulated CD4 T
cells by a real-time quantitative RT-PCR method. The levels of these
messengers, already detectable when the study started, increased
significantly (fourfold) during the STI (data not shown).
In patient 3, HIV-specific CD4-cell proliferative and cytokine
responses increased with only a slight virus rebound (400 copies/ml) at
the first STI, with an intensity similar to that in patient 2 (Fig.
3C). This HIV-specific Th1 response increased rapidly and persisted for
7 days but disappeared on day 28, after resumption of treatment, when
the virus was still detectable in plasma (388 copies/ml). Despite
substantial virus rebounds during the following three STI, the
proliferative responses remained undetectable while IFN- production
was stimulated only minimally.
Therefore, the CD4 Th1 cells appeared to be rapidly mobilizable in vivo
in all patients with virus rebounds, even though they were undetectable
during continuous therapy. Specific IFN- production was reinduced in
seven STI versus four STI for the CD4 T-cell proliferation. This
cytokine response appeared 7 days (median) after drug arrest and hence
thus was concurrent with the median delay in the increase of the viral
load. The proliferative responses against other recall antigens
(tuberculin, CMV, and candidin) did not vary significantly during these
11 STI (data not shown).
Delayed increases of the levels of HIV-specific CD8+ cells during
viral rebounds.
Two IFN- ELISPOT assays using synthetic
peptides and recombinant vaccinia virus allowed us to quantify the CD8
cells specific for HIV. First, a panel of 12 HIV cytotoxic T-lymphocyte
epitopes was chosen according to the HLA haplotypes of the patients,
with five to seven peptides being tested per patient. No or very small numbers of HIV-specific CD8 cells were detectable at entry for the
three patients (data not shown). A moderate increase in HIV-specific CD8 T-cell frequencies was observed only in patient 3 at the time of
each rebound in the viral load (Fig. 3D). Since no specific responses
to the tested epitopes were detected during STI in patients 1 and 2, we
reanalyzed these responses using a recombinant vaccinia virus ELISPOT
assay, which ensures a more exhaustive evaluation of HIV-specific CD8
T-cell responses. In fact, very high frequencies of CD8 T cells were
detected against Gag and Pol (1,554 and 2,724 SFC/106
cells, respectively) at baseline for patient 1 (Fig. 1D) and during the
three STI that did not lead to rebounds in viral loads. No responses to
Nef and Env were detected over time. The rebound in viral load during
the fourth STI was associated with an increase in the number of
Nef-specific T cells (up to 1,100 SFC/106 cells). For
patient 2, no or weak specific responses were detected at entry. Each
STI induced an increase in the responses to Env, Pol, and Gag, with a
range of frequencies from 177 to 724 SFC/106 cells (Fig.
2D). Overall, the increases in the frequencies of HIV-specific CD8
cells were delayed compared to changes in the numbers of HIV-specific
CD4 T cells and appeared only when the latter had already diminished in
six of seven STI.
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DISCUSSION |
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Abstract
Introduction
Materials and Methods
Results
Discussion
References
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This study clearly demonstrates that HIV-specific T-helper responses are reinducible during short-course STI in chronically infected patients in whom they were undetectable after 18 months or more of effective antiretroviral therapy.
At study entry, CD4 Th1-cell responses were almost undetectable; they
appeared concurrently with rebounds in viral load in the three
patients. The HIV-specific IFN- production occurred within a median
of 7 days after drug arrest, concurrently with the rebound in viral
load or even before the virus became detectable. Real-time PCR showed
that ex vivo IFN- production in the CD4 T cells increased as the
viral load rebounded, suggesting that HIV-specific Th1 responses did
occur in vivo. This is the first demonstration that Th1 responses to
HIV can be boosted after reexposure to the virus even after several
years of HIV infection and antiretroviral therapy. However, these
responses were weak and lasted for less than 3 weeks after drug arrest.
Both proliferation and IFN- production vanished in all cases, even
before the virus was controlled. Their intensity eventually diminished
during subsequent STI. This contrasts with the robust responses to
other recall antigens such as CMV or tuberculin, which were unaffected
by rebounds in viral load. These data strongly suggest that HIV acts
rapidly, preferentially, and directly against the CD4 T cells directed
at the virus itself. Finally, subsequent reexposure to virus did not
enhance the set point of the HIV-specific Th1 responses, which returned
to undetectable levels in all cases at the end of the study.
A recombinant vaccinia virus ELISPOT assay allowed us to quantify the HIV-specific CD8 T cells when they were undetectable by using a panel of peptides representative of the four major HIV proteins (Gag, Pol, Env, and Nef). Some boosting effect was observed for HIV-specific CD8 T cells in the two cases where they were undetectable at baseline. Such boosts were delayed compared to changes in HIV-specific CD4 T-cell responses and were not sustained. The failure to stimulate a strong and durable CD4 Th1 response in these patients during rebounds in viral load might have limited the CD8 T-cell expansion, which in turn might have prevented immune control of the HIV relapses. Indeed, repeated STI in this short pilot study were not accompanied by an increasing delay in the rebound of viral load. These results contrast with those of studies of early treatment discontinuation (11, 15). Recent communications (4, 23) have raised a controversy about whether HIV-specific CD4 Th1 cells could be mobilized after STI in patients treated during established HIV infection. A frequent sampling in our analysis, even limited to three patients, allowed us to describe the respective kinetics of rebounds in viral load and HIV-specific T-cell responses: our data strongly suggest that virus replication leads to a rapid destruction of these HIV-specific Th1 cells and therefore help us understand the contradictions mentioned above.
In conclusion, STI did not harm HIV sensitivity to antiretroviral drugs or CD4 counts in these three chronically infected patients. However, our data demonstrate the limitations of such an STI approach for clinical management, raising concerns about such autovaccination strategies among chronically infected patients. This led us to interrupt our study of short-course STI. Nevertheless, the fine kinetics of HIV-specific CD4 T-cell changes described here contribute to our further understanding of results obtained with longer courses of STI, which might miss these changes. Therapeutic immunization with nonpathogenic vaccines seems an alternative strategy of interest for prolonging the delay to rebounds in viral load during STI without damaging the CD4 T-helper cells specific for HIV.
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ACKNOWLEDGMENTS |
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G. Carcelain and R. Tubiana contributed equally to this work.
We thank N. Jouys, C. Desousa, P. Grenot, C. Robert, and I. Viseux for technical assistance; M. Pauchard for logistical assistance; A. Necker and F. Romagné (Immunotech, Marseilles, France) for kindly providing tetramer reagents; and the patients who participated in this study. The English text was edited by Jo-Ann Cahn.
We thank SIDACTION and the Agence Nationale de Recherche sur le SIDA for financial support.
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FOOTNOTES |
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* Corresponding author. Mailing address: Laboratoire d'Immunologie Cellulaire, CNRS-UMR 7527, Hôpital Pitié-Salpétriêre, Paris, France. Phone: 33 (1) 42.17.74.81. Fax: 33 (1) 42.17.74.90. E-mail: brigitte.autran{at}psl.ap-hop-paris.fr.
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Materials and Methods
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Discussion
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Journal of Virology, January 2001, p. 234-241, Vol. 75, No. 1
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.1.234-241.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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