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Journal of Virology, September 1998, p. 7501-7509, Vol. 72, No. 9
0022-538X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Temporal Analyses of Virus Replication, Immune Responses, and
Efficacy in Rhesus Macaques Immunized with a Live, Attenuated
Simian Immunodeficiency Virus Vaccine
Ruth I.
Connor,1,*
David C.
Montefiori,2
James M.
Binley,1
John P.
Moore,1
Sebastian
Bonhoeffer,1
Agegnehu
Gettie,1
Elizabeth A.
Fenamore,1
Kristine E.
Sheridan,1
David D.
Ho,1
Peter J.
Dailey,3 and
Preston A.
Marx1,4
The Aaron Diamond AIDS Research Center, The
Rockefeller University,1 and
New
York University School of Medicine,4 New
York, New York 10016;
Duke University Medical Center,
Durham, North Carolina 277102; and
Chiron Corporation, Emeryville, California
946083
Received 26 January 1998/Accepted 28 May 1998
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ABSTRACT |
Despite evidence that live, attenuated simian immunodeficiency
virus (SIV) vaccines can elicit potent protection against
pathogenic SIV infection, detailed information on the replication
kinetics of attenuated SIV in vivo is lacking. In this study, we
measured SIV RNA in the plasma of 16 adult rhesus macaques immunized
with a live, attenuated strain of SIV (SIVmac239
nef). To evaluate the relationship between replication of the vaccine virus and the onset of protection, four animals per group were challenged with
pathogenic SIVmac251 at either 5, 10, 15, or 25 weeks after immunization. SIVmac239nef replicated efficiently in the
immunized macaques in the first few weeks after inoculation. SIV
RNA was detected in the plasma of all animals by day 7 after
inoculation, and peak levels of viremia (105 to
107 RNA copies/ml) occurred by 7 to 12 days. Following
challenge, SIVmac251 was detected in all of the four animals challenged
at 5 weeks, in two of four challenged at 10 weeks, in none of four challenged at 15 weeks, and one of four challenged at 25 weeks. One
animal immunized with SIVmac239nef and challenged at 10 weeks had evidence of disease progression in the absence of detectable SIVmac251. Although complete protection was not achieved at 5 weeks, a
transient reduction in viremia (approximately 100-fold) occurred in the
immunized macaques early after challenge compared to the nonimmunized
controls. Two weeks after challenge, SIV RNA was also reduced in the
lymph nodes of all immunized macaques compared with
control animals. Taken together, these results indicate that host
responses capable of reducing the viral load in plasma and lymph nodes
were induced as early as 5 weeks after immunization with
SIVmac239nef, while more potent protection developed between 10 and
15 weeks. In further experiments, we found that resistance to SIVmac251
infection did not correlate with the presence of antibodies to SIV
gp130 and p27 antigens and was achieved in the absence of significant
neutralizing activity against the primary SIVmac251 challenge stock.
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INTRODUCTION |
Immunization with live, attenuated
strains of simian immunodeficiency virus (SIV) can induce protection
against infection with virulent virus (2, 8, 10, 21, 22, 26, 31, 33). Despite these encouraging results, safety concerns persist over the possible use of live, attenuated HIV vaccines in humans (3). As a result, research efforts by several groups have
focused on elucidating the underlying mechanisms associated with
protective immunity in this model. Although several studies have
evaluated the humoral (1, 6, 12, 22, 24, 26, 33) and
cellular (13, 16) immune responses in monkeys immunized with
live, attenuated SIV, the correlates of protective immunity remain
unclear.
Initial studies suggested that maturation of the protective response
took a prolonged period of time to develop, raising questions as to the
nature of the induced immunity (8, 33). While immune responses to SIV develop within a few weeks following infection with
pathogenic strains (28, 34), protection was achieved only
after 35 weeks following immunization of macaques with an attenuated macrophagetropic virus (SIV17E-Cl) (8)
and 79 weeks after immunization with a triple-deletion mutant (SIV3)
(33). In several studies, inoculation of macaques with
highly attenuated strains of SIV, which were unable to establish
persistent infection in the host, failed to confer significant
protection against challenges by pathogenic viruses (11,
21). Taken together, these results suggest that the degree of
attenuation of the vaccine strain and its ability to replicate in vivo
are critical determinants of the protective effect.
Because sensitive, quantitative methods to measure SIV in plasma have
only recently been developed, detailed information on the replication
kinetics of live, attenuated SIV in macaques is limited
(12). To address this issue, we examined the replication of
an attenuated strain of SIV (SIVmac239nef) in rhesus
macaques by measuring plasma viremia via a quantitative branched DNA
(bDNA) assay (9). Plasma viral load was measured frequently
following inoculation with SIVmac239nef and again after
challenge with uncloned SIVmac251. To determine the temporal
relationship between replication of the vaccine virus and the onset of
protection, animals infected with SIVmac239nef were
challenged with SIVmac251 at either 5, 10, 15, or 25 weeks after
immunization. Data on viral load in the plasma and lymph nodes, as well
as on the induction of anti-SIV antibody responses, were then compared
with outcome following challenge.
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MATERIALS AND METHODS |
Macaques.
Twenty adult, female rhesus macaques (Macaca
mulatta, 6 to 8 kg) were used in this study. None of the animals
had prior exposure to SIV or type D retrovirus, and all were negative
for SIV and type D retrovirus antibodies before the start of the
experiments. Animal 1490 was also negative for type D retrovirus by
PCR. All protocols used in this study were reviewed and approved by an institutional animal care and use committee.
Vaccine and challenge viruses.
Viral stocks of
SIVmac239nef and SIVmac251 were kindly provided by
Ronald Desrosiers (New England Regional Primate Research Center,
Harvard Medical School, Southborough, Mass.). Both stocks were grown in
rhesus peripheral blood mononuclear cells (PBMC) and titered on
CEM×174 cells (19). The SIVmac239nef stock had a
titer of 4 × 103 50% tissue culture infective doses
(TCID50)/ml; the SIVmac251 challenge stock had a titer of
5 × 103 TCID50/ml. The SIVmac251
challenge stock was also titered in macaques and contained
104.5 animal infective doses per ml. Both stocks were
negative for foamy virus and type D retrovirus.
Inoculation of vaccine and challenge viruses.
Sixteen rhesus
macaques were infected with SIVmac239nef by intravenous
inoculation of the virus stock (2 × 104
TCID50) on day 0. Four additional macaques served as
nonimmunized controls. The immunized and control animals were
subsequently challenged by intravenous inoculation of 10 animal
infective doses of SIVmac251 in groups of five (four immunized and one
control) at either 5, 10, 15, or 25 weeks after immunization with
SIVmac239nef.
SIV RNA in plasma and lymph nodes.
Blood samples collected
in EDTA anticoagulant were used to determine SIV RNA levels in the
plasma, using a bDNA signal amplification assay as previously described
(9). Briefly, viral particles in 1 ml of plasma were
pelleted by centrifugation (23,500 × g for 60 min at
4°C) and detected by using probes that hybridize within the
pol region of SIVmac. SIV RNA was quantified by comparison to a standard curve produced by serial dilutions of cell-free SIV-infected cell culture supernatants. The lower quantification limit
of this assay is 10,000 SIV RNA copies per ml. To quantify SIV RNA in
lymph nodes, quadruplicate samples of peripheral lymph node biopsies
were taken. Each sample was frozen at 
80°C until processing.
Samples were weighed, and the DNA and RNA were extracted in guanidine
HCl as previously described (14). SIV RNA extracted from
lymphoid tissue specimens was quantified by using the bDNA assay, and
the data were expressed as RNA copies per 10 mg of tissue. Individual
values for each sample, as well as the geometric mean of the
quadruplicate samples, are presented. DNA from lymphoid tissues was
further purified (United States Biochemical, Cleveland, Ohio) and used
in PCR assays to discriminate between the vaccine and challenge strains
as described below.
PBMC isolation and DNA PCR.
PBMC were isolated from whole
blood by layering over lymphocyte separation medium (Organon Teknika,
Durham, N.C.) followed by standard density gradient centrifugation.
Genomic DNA was extracted from 106 cells, and sequences
spanning the deleted region of nef were amplified by nested
PCR. DNA (1 µg) was added to a PCR mixture containing 50 mM KCl, 10 mM Tris HCl, 0.1% Triton X-100, 2 mM deoxynucleoside triphosphate, 25 mM MgCl2, 2.5 U of Taq DNA polymerase (Promega,
Madison, Wis.), and 100 ng each of the outer primers A
(5'-CCTACCTACAATATGGGTGGAGC; SIVmac239, nucleotides [nt]
9065 to 9087) (10, 27) and B
(5'-CCTCTGACAGGCCTGACTTGCTTCC; nt 9776 to 9800) (10,
27) in a final volume of 50 µl. Amplification was performed for
35 cycles (94°C, 1 min; 60°C, 30 s; 72°C, 45 s), after
which 5 µl of the first-round product was transferred to a new
reaction mixture containing the inner primers C
(5'-CCGTCTGGAGATCTGCGACAGAGACT; nt 9110 to 9135)
(27) and D (5'-GGTATCTAACATATGCCTCATAAG; nt 9741 to 9764) (27). Amplification was carried out for an
additional 35 cycles under the cycling conditions specified above. PCR
products were separated on 1% agarose gels and visualized by ethidium
bromide staining. Under these conditions, amplification of
SIVmac239nef yields an expected product of 472 bp, and
amplification of SIVmac251 yields a product of 654 bp. To confirm
detection of SIVmac251, PCR was carried with primers A and B, after
which 5 µl of the amplified product was transferred to a new reaction
mixture containing primer E (5'-GAAACCCAGCTGAAGAGAGAG; nt
9288 to 9310) (27) paired with primer D. Primer E hybridizes
within the 182-bp deleted region of SIVmac239nef and
therefore recognizes only wild-type nef alleles. Protection
was defined as the failure to detect the challenge virus by nested PCR
under these conditions.
Flow cytometry.
Whole blood collected in EDTA was analyzed
for CD4 and CD8 T-cell subsets, using antibodies to CD3 (Biosource
International, Camarillo, Calif.) and to CD4 and CD8 (anti-Leu-3a and
anti-Leu2a, respectively; Becton Dickinson, San Jose, Calif.).
Antibodies (10 µl of each) were added to 50 µl of whole blood and
allowed to sit for 15 min at room temperature, after which erythrocytes were lysed by the addition of 450 µl of lysing buffer. Samples were
analyzed on a FACS Calibur flow cytometer (Becton Dickinson), and the
CD4 and CD8 cell counts per microliter were enumerated relative to a
standard count of beads used for calibration.
Detection of antibodies to SIV Env and Gag proteins by
enzyme-linked immunosorbent-assay (ELISA).
To detect antibodies to
the SIV envelope glycoproteins, a sheep polyclonal antibody
to the C terminus of SIV gp130 (D7369; Aalto BioReagents, Dublin,
Ireland) was coated onto Immulon II plates (Dynatech, Ltd.) at 5 µg/ml in 0.1 NaHCO3 (pH 8.6). To detect SIV p27, a
p27-glutathione S-transferase fusion protein (a gift from
Ian Jones, Medical Research Council, London, England) was coated at
approximately 5 µg/ml. The plates were then washed with Tris-buffered
saline (TBS) and blocked with 2% nonfat milk in TBS for 30 min, after
which recombinant gp130 (a gift from James Arthos, National Institutes
of Health) was added at 100 ng/ml to the D7369-coated wells. Simian
plasma, precleared for platelets, was titrated threefold (starting at
1:100) in TBS-2% milk-20% sheep serum and added to plates
precoated with either gp130 or p27 for 1 h at room temperature.
After two further TBS washes, goat anti-human immunoglobulin G-alkaline
phosphatase conjugate (Accurate Chemicals, Westbury, N.Y.) was added to
wells at 1:10,000 in TBS-2% milk-20% sheep serum. After 30 min at
room temperature, the plates were washed and developed by using the AMPAK amplification system (Dako, Carpenteria, Calif.), and the A490 was determined. Midpoint titers were
calculated and are presented.
Neutralization assays.
Neutralizing antibodies were assessed
in a CEMx174 cell-killing assay as described previously
(24). Briefly, cell-free virus (50 µl containing 0.5 to 1 ng of p27) was added to multiple dilutions of test plasmas in 100 µl
of growth medium in triplicate wells of 96-well microtiter plates and
incubated at 37°C for 1 h. Twenty-five microliters was then
transferred to a separate plate that contained 100,000 CEMx174 cells in
100 µl of growth medium/well and incubated until syncytium formation
and nearly complete cell killing first became apparent by light
microscopic examination (usually 6 days). Cell densities were reduced
and medium was replaced after 3 days of incubation. Viable cells were
quantified by staining with Finter's neutral red in
poly(L-lysine)-coated plates. Percent protection from
virus-induced cell killing was calculated by taking the difference in
A540 values between test wells (cells, plasma
sample, and virus) and virus control wells (cells and virus) and
dividing this result by the difference in absorption between cell
control wells (cells only) and virus control wells. Neutralization
titers are given as the reciprocal of the plasma dilution required to
protect 50% of cells from virus-induced killing. T-cell line-adapted
(TCLA) SIVmac251 had been passaged repeatedly in H9 cells and was
expanded in H9 cells for use in neutralization assays. Assay stocks of primary SIVmac251 and molecularly cloned SIVmac239/nef-open
were derived by a single expansion in rhesus PBMC of virus taken
directly from vials of animal challenge stocks (24). The
animal challenge stocks were of a low passage number in rhesus PBMC
exclusively (19). All viruses were provided by Ronald
Desrosiers.
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RESULTS |
Replication of SIVmac239nef following inoculation.
To assess virus replication following inoculation of rhesus macaques
with SIVmac239nef, plasma samples were obtained at frequent intervals and the levels of SIV RNA were determined by using a quantitative bDNA assay (9). SIV RNA was detected in the
plasma of all immunized animals on day 7 after inoculation (Fig.
1), and peak viremia (105 to
107 RNA copies/ml) occurred within 7 to 12 days. SIV RNA
was rapidly cleared to undetectable levels by 5 to 7 weeks in all
animals, with the exception of one (animal 1490) that maintained
detectable plasma viremia throughout the entire study. DNA PCR
performed on PBMC samples from the immunized animals confirmed that the replicating virus was SIVmac239nef, with no evidence that
repair or reversion of the original nef deletion had
occurred (Table 1).
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FIG. 1.
SIV RNA in plasma following immunization with
SIVmac239nef and challenge with SIVmac251. Viremia was
determined by measuring total SIV RNA in plasma in a bDNA assay
(sensitivity of 104 RNA copies/ml). Immunization with
SIVmac239nef
( )
was performed on day 0. The animals were then challenged with SIVmac251
( )
at either 5 (A), 10 (B), 15 (C), or 25 (D) weeks. Levels of SIV RNA for
the nonimmunized control animal in each challenge group are designated
by open symbols.
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To evaluate the temporal onset of protection, the immunized
animals were challenged in groups of five (four immunized and one
nonimmunized control) with uncloned SIVmac251 at either 5, 10, 15, or 25 weeks after inoculation of SIVmac239nef. DNA
PCR was performed on PBMC samples, using two sets of primers to
discriminate between the vaccine and challenge viruses. Shortly after
challenge, all of the four immunized animals in group A experienced a
transient increase in plasma viremia (Fig. 1A), which coincided with
detection of SIVmac251 DNA in PBMC (Table 1). Despite evidence that
these animals were not protected from challenge, the level of viremia was approximately 100-fold lower than in the nonimmunized control animal (animal 1480), suggesting that virus-suppressive mechanisms may
act as early as 5 weeks after immunization. Suppression of virus
replication was transient, however, and the levels of plasma SIV RNA
subsequently increased in three of four macaques in this group,
reaching levels comparable to that of the nonimmunized control by 45 weeks after challenge (Fig. 1A).
SIVmac251 DNA was detected in two of four immunized animals (1482 and
1484) challenged at 10 weeks (Table
1), coincident
with a marked
increase in plasma viremia in animal 1482 (Fig.
1B). Increasing plasma
viremia was also detected in another animal
(1490) from this challenge
group. However, nested DNA PCR performed
on PBMC and lymph node
samples from this animal failed to detect
the challenge virus,
suggesting that plasma viremia was due to
replication of the
vaccine strain (see below). In the 5- and 10-week
challenge groups,
SIVmac251 was detected by DNA PCR at only a
single time point for 2 animals (1474 and 1484), and the level
of plasma viremia has remained
below the limit of detection for
more than a year after challenge in
both animals, suggesting they
were able to control replication of the
challenge virus. Taken
together, these results indicate that protective
responses induced
by 5 to 10 weeks act to initially control virus
replication but
provide long-term suppression in only some animals. In
contrast,
plasma viremia remained undetectable in all of the four
immunized
animals challenged at 15 weeks (Fig.
1C) and in three of four
challenged at 25 weeks (Fig.
1D), suggesting that more potent
protection develops between 10 and 15 weeks after immunization.
DNA PCR
performed on PBMC samples from the immunized animals in
these latter
groups detected only SIVmac239
nef (Table
1), with
the
exception of the one unprotected animal (1510) in the 25-week
challenge
group, in which SIVmac251 was first detected on day
70 after challenge.
Viral load in lymph nodes.
Based on our initial findings,
which indicated that immunization with SIVmac239nef could
reduce the postchallenge viral load in the peripheral blood, we
evaluated the viral burden in lymphoid tissues. Lymph node biopsies
were performed 2 weeks after challenge, and the samples were used to
quantify total SIV RNA by bDNA assay. Because this assay uses
probes that hybridize within the SIV pol gene, it detects
both SIVmac239nef and SIVmac251. Quadruplicate samples
were assayed from each lymph node, and the results were expressed as
RNA copies/10 mg of tissue. The levels of SIV RNA found in the lymph
nodes ranged from 104 to 106 RNA copies/10 mg
in the immunized animals (with the exception of animal 1490, in
which the viral load approached 107 RNA copies/10 mg) (Fig.
2). Comparison with the
nonimmunized controls showed approximately 100-fold-higher levels
of SIV RNA in the lymph nodes of the control animals (106
to 108 RNA copies/10 mg) than in those of animals immunized
with SIVmac239nef. However, it is important to note
that this assay detects total SIV RNA in lymph nodes, and a large
proportion may represent trapped virions. Overall, these results
indicate that immunization with SIVmac239nef can reduce the
postchallenge viral load in lymph nodes and that this reflects similar
changes seen in the blood.
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FIG. 2.
Comparison of SIV RNA in the plasma ( ) and lymph
nodes ( ) 2 weeks after challenge with SIVmac251. Lymph node biopsy
samples were collected, and the tissues were divided into quadruplicate
samples. SIV copy number was determined for each sample by bDNA assay,
and the data were normalized per 10 mg of tissue. Individual data
points, as well as the geometric mean, are presented for the
quadruplicate samples. Paired plasma samples were analyzed for SIV RNA,
and the data are expressed as SIV copies per ml. Data for controls
depict the results obtained for the nonimmunized animals in each
challenge group.
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Calculation of total viral load following immunization.
To
assess whether the level of SIVmac239nef replication is a
determinant of protection, we calculated the area under the curve of
virus load in plasma during the period prior to challenge (Table
2). For those time points when the virus
load was below the limit of detection, the actual value of the
detection limit of the bDNA assay was used (104 RNA
copies/ml). While this leads to a slight overestimate, the contribution
of these data points to the integral is negligible, even for the
25-week challenge group, where the virus load is below the limit
of detection for about 100 days prior to challenge (Fig. 1D).
Following infection with SIVmac239nef, the mean area under
the curve was approximately 1.2 × 107 virions for the
16 immunized macaques (Table 2). Comparison of the different challenge
groups revealed no significant difference between the groups, with mean
values ranging from 9.2 × 106 to 1.5 × 107 virions (Table 2). To estimate the total production of
virions in the blood, the area under the curve was multiplied by the
clearance rate of free virus and the volume of blood. Assuming an
extracellular fluid volume of 0.5 liters (based on a mean body weight
of 7.68 kg) and a free virus half-life of 20 min for
nef-deleted SIV (35), the mean total production
of virus in the blood prior to challenge was approximately 3.0 × 1011 virions, suggesting that SIVmac239nef
replicates quite extensively in vivo. Despite these findings, the level
of virus replication was not significantly different between the
different challenge groups (Table 2), implying that total exposure to
virions cannot be the sole determinant for protection. Rather, our
findings support the idea that the duration of exposure to the vaccine
virus is a critical factor for the development of protection.
Detection of binding antibodies to SIV Env (gp130) and Gag (p27)
proteins.
To address possible immune correlates of protection, we
evaluated the temporal development of anti-SIV antibodies, both before and after challenge with SIVmac251. Antibodies to SIV gp130 and p27
increased rapidly in the first 2 to 3 weeks in response to immunization
with SIVmac239nef and in association with a decline in
plasma viremia (Fig. 3). All of the
animals responded to immunization, although some variation in the
magnitude of the response was observed. In some cases this variation
was associated with the extent of SIVmac239nef replication
in vivo, such that those animals with higher initial viremia (e.g.,
1490) had more rapid development of antibodies to SIV gp130 compared to
those with lower peak viremia (e.g., 1484). A similar association was
recently reported for rhesus macaques infected with highly
attenuated mutants of SIV (12). However, this phenomenon was
not observed for all the animals in our study; several (e.g., 1502 and
1514) had similar levels of plasma viremia following immunization with
SIVmac239nef but different anti-gp130 antibody responses,
suggesting that host factors may also affect the kinetics of anti-SIV
antibody development. As expected, specific antibodies were not
detected prior to challenge in the nonimmunized controls. Following
challenge, there was evidence of an anamnestic response to both Env and
Gag in a subset of the animals (notably 1472 and 1476) which was
associated with detection of the challenge virus in PBMC and an
increase in plasma viremia. However, comparison of the anti-gp130 and
anti-p27 antibody titers on the day of challenge did not reveal any
obvious correlation with outcome (Fig.
4), and there was no evidence to suggest
that unprotected animals were among those with lower antibody
responses.
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FIG. 3.
Antibody responses to SIV gp130 ( ) and p27 ()
measured by ELISA following immunization with SIVmac239nef
()
and challenge with SIVmac251
()
of animals in 5-week (A), 10-week (B), 15-week (C), and 25-week (D)
challenge groups. Data for nonimmunized control animals (1480, 1492, 1504, and 1516) are shown on the far right.
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FIG. 4.
Antibody titers to SIV gp130 and p27 measured by ELISA
on the day of challenge for each of the 16 macaques immunized with
SIVmac239nef. The results are presented based on the outcome
following challenge, irrespective of the challenge group (unprotected
[n = 7] or protected [n = 9]).
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Neutralizing antibody responses to primary and TCLA SIVmac251.
It is not yet clear whether protection conferred by
SIVmac239nef correlates with the presence of
SIV-neutralizing antibodies. Such a correlation was found in one study
(33) but has not been supported by others (1, 22, 24,
26, 30). In part, these discrepancies may result from the use of
either TCLA-adapted or primary SIV stocks, which have different
sensitivities to antibody neutralization (23). To address
this question, we tested plasma from animals immunized with
SIVmac239nef for neutralization activity against both a TCLA
stock of SIVmac251 and the primary SIVmac251 stock used for challenge.
Our results show that antibodies capable of neutralizing the
TCLA virus arise within the first few weeks following
immunization (Table 3). In general, the
increase in neutralization titer paralleled the replication
kinetics of the vaccine virus, such that plasma from animals with
higher viremia tended to have higher titers of neutralizing activity.
However, neutralizing titers to TCLA SIVmac251 on the day of challenge were not associated with the ability to resist infection by the challenge virus. We next evaluated neutralizing activity against the primary SIVmac251 challenge stock. Little or no neutralizing activity was detected against the primary virus in any of the animals
over the entire course of observation (over 25 weeks). Moreover, at 15 weeks, when neutralizing activity to the challenge virus was low or
absent, all of the four animals resisted SIVmac251 infection, showing
that neutralizing antibodies are not associated with protection in this
model.
Disease progression associated with increased replication of
SIVmac239nef.
For the majority of unprotected animals,
a dramatic increase in the levels of SIV in plasma and a decline in the
number of circulating CD4+ T cells (Fig.
5) was associated with consistent
detection of SIVmac251 by DNA PCR (Table 1). The one notable
exception was animal 1490 (10-week challenge group), in which a
high viral load and declining CD4+ T cells occurred
in the absence of detectable SIVmac251. Following immunization
with SIVmac239nef, the level of plasma viremia in this
animal reached 5 × 106 RNA copies/ml, the highest for
16 immunized macaques (Fig. 1). Viremia subsequently declined by almost
2 logs; however, SIV RNA was readily detectable in plasma at all time
points, in contrast to all other animals, in which viremia consistently
dropped below the limit of detection. Following challenge with
SIVmac251, the level of SIV RNA in plasma continued to
gradually increase, reaching a peak of approximately
106 RNA copies/ml, after which it declined slightly (Fig.
1). DNA PCR performed on multiple, sequential PBMC samples failed to
detect wild-type nef but rather identified several
shorter PCR products (Fig. 6). One
of these products corresponded in size to the expected band for
SIVmac239nef and was the predominant band seen in samples obtained early after immunization (Fig. 6A). However, multiple shorter
products were identified in later PBMC samples obtained several weeks
after immunization, suggesting that additional deletions in
nef had occurred. A similar, shorter PCR product was also
identified in later samples derived from sequential plasma cocultures
from animal 1490 (Fig. 6B). Amplification and sequencing of the
nef gene from later PBMC samples confirmed the presence of
the original 182-bp nef deletion and also identified a
second 112-bp deletion in the upstream U3 region of the 3' long
terminal repeat (data not shown), similar to that described
earlier by Kirchoff et al. (17). In contrast to the results
of Kirchoff et al., which suggested that additional deletions in U3
develop only after a prolonged period of infection, we found evidence
of additional nef deletions early after infection with
SIVmac239nef, and by 12 weeks the multiply deleted form had
become the major variant detected by PCR.
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FIG. 5.
CD4+ T-cell counts for immunized and control
animals in the 5-week (A), 10-week (B), 15-week (C), and 25-week (D)
challenge groups. The results for nonimmunized control animals are
depicted by open symbols.
,
day of challenge with SIVmac251.
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FIG. 6.
DNA PCR analysis of sequential PBMC and plasma samples
from animal 1490. Sequences in nef were amplified by nested
DNA PCR using primers that span the deleted region in
SIVmac239nef as described in Materials and Methods. (A)
Sequential PBMC samples obtained before and after challenge with
SIVmac251 (70*, day of challenge); (B) plasma samples from sequential
time points following coculture with CEMx174 cells. M, molecular size
markers; (+), amplification of nef sequences from rhesus
PBMC used to propagate the SIVmac239nef immunization stock;
(), no DNA control.
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DISCUSSION |
In this study, we examined in detail the replication of a live,
attenuated strain of SIV (SIVmac239nef) in rhesus macaques and determined the temporal relationship between replication of the attenuated virus and the onset of protection against
challenge with pathogenic SIVmac251. Our results indicate
that protective responses capable of reducing the
postchallenge viral load in both plasma and lymph nodes are induced as
early as 5 weeks after immunization with SIVmac239nef, while
more potent protection develops between 10 and 15 weeks. Antibodies
directed against SIV Env and Gag proteins could be detected within the
first few weeks after immunization; however, there was no apparent
relationship between antibody titer and subsequent protection from
challenge. Moreover, protection was achieved in the absence of
detectable antibodies capable of neutralizing the primary SIVmac251
challenge virus in vitro, raising questions as to the significance of
neutralizing antibody responses in this model. Overall, our results
suggest that protective responses can develop much more rapidly than
was previously observed with more highly attenuated SIV strains
(8, 33) and support the idea that the ability of live,
attenuated vaccines to elicit protection is closely linked to their
replicative capacity in vivo.
Based on earlier reports, increased attenuation of SIV as a result of
successive deletion of virus auxiliary genes (12), or
through recombination of SIV env genes (8, 21),
results in a decrease in replicative capacity in vivo and extends the period required for protective antiviral immunity to develop. We found
that SIVmac239nef, which is attenuated as a result of a
large 182-bp deletion in the nef gene (10),
replicates efficiently in rhesus macaques in the first few weeks
following inoculation. However, we observed considerable variation in
the levels of SIVmac239nef replication among the immunized
animals (notably 1484 and 1490), with almost a 2-log range in peak
values between different animals. Similar differences in viral
replication patterns have been reported for macaques infected with
pathogenic SIV (20), and these differences have been
correlated with in vitro permissiveness of host cells to infection
(20). Since all of the animals in our study were inoculated
with the same virus under similar conditions, our results imply that
inherent host factors can also have a considerable impact on the
ability of live, attenuated SIV vaccines to replicate in vivo. Given
that the replicative ability of the vaccine virus can influence the
development of antiviral immunity (8, 12, 21, 33), it is
possible that host factors which restrict replication of a live,
attenuated vaccine in some individuals may prolong the period required
for protective immunity to develop, while in others, replication of the
same attenuated strain may be enhanced, leading to pathogenicity.
Anecdotally, the one animal in our study with the highest level of
viremia during acute infection (1490) failed to control replication of
the vaccine virus, resulting in an increase in viral load and a
sustained drop in CD4+ T cells.
In all but one animal (1490), SIVmac239nef was rapidly
reduced to undetectable levels within 5 to 7 weeks. In assessing
possible correlates of protection, we found that the decline in viremia was associated with an increase in the titer of antibodies to SIV Env
and Gag proteins. Binding antibody titers increased rapidly in the
first few weeks following immunization and were sustained at high
levels for many months. It was notable that animals immunized with
SIVmac239nef all developed anti-p27 antibody responses with kinetics similar to those against gp130. Previous studies have shown
that sustained antibody responses to HIV-1 Gag proteins correlate with
a favorable clinical outcome, while the failure to generate anti-Gag
antibodies, or the loss of this response, is an early indicator of
disease progression (4, 7, 15, 32, 36). Our results indicate
that anti-p27 antibody titers per se do not correlate with protection
in animals immunized with SIVmac239nef. However, the lack of
strong anti-Gag antibody responses in the nonimmunized control animals
following SIVmac251 challenge suggests early immune dysfunction that
was not evident in animals infected with SIVmac239nef.
The magnitude and duration of anti-SIV antibody responses in the
immunized animals is consistent with ongoing replication of
SIVmac239nef or, alternatively, continuous antigenic
stimulation as a result of virions trapped on follicular dendritic
cells in lymphoid tissues (6). While our results cannot
discriminate between these two possibilities, we were able to detect
SIVmac239nef in PBMC many months after immunization, and
abundant SIV RNA was found in the lymph nodes of animals that were
protected from SIVmac251 challenge. DNA PCR performed on lymph node
samples from the immunized animals revealed the presence of
SIVmac239nef (data not shown), indicating persistence of the
vaccine virus in both blood and tissues.
Despite high titers of antibodies against SIV envelope
glycoproteins, plasma from the immunized animals failed to
neutralize the primary SIVmac251 stock used for challenge,
although some neutralizing activity was measured against a TCLA
stock. These results are consistent with earlier studies of human
immunodeficiency virus type 1 (HIV-1) (25) and confirm
observed differences in the neutralization sensitivity of primary and
TCLA SIV strains (23). This may also explain discrepancies
in the literature with regard to the role of neutralizing antibodies in
mediating protection by live, attenuated SIV vaccines (2, 22, 26, 30, 33). Because very few epitopes on primary HIV-1 envelopes are
accessible to antibodies, and the immunogenicity of the mature oligomer
on virions is generally low (reviewed in reference
5), it is perhaps not surprising that antisera from
the immunized macaques failed to neutralize the primary SIVmac251
challenge virus in vitro. In vivo, passive transfer of immune sera from protected macaques to recipient animals has yielded mixed results; protection was conferred in some studies (8) but not others (1). Again variation in the virus strain used for challenge, the relative neutralization sensitivity of the challenge strain, and the source of cells used for virus propagation may all contribute to the observed differences in outcome.
Recent reports have shown that vigorous cytotoxic
T-lymphocyte (CTL) activity is present as early as 14 days
after infection with SIVmac239nef, coincident with a
drop in the viral load (16). Similar observations have
been made in macaques infected with pathogenic SIVmac251
(34) and in humans infected with HIV-1 (18),
providing strong evidence that CTL play a key role in reducing the
viral load during acute infection. It is not yet clear whether CTL also
contribute to the protective responses observed with live, attenuated
SIV vaccines. Assessment of the contribution of CD8+ cells,
either through in vitro measurement of CTL activity (13, 16)
or through severe depletion by CD8-specific monoclonal antibodies in
vivo (29), has not yielded conclusive results. Given
that CTL arise rapidly during primary infection, one
would expect to see protection developing coincident with a decline in
viremia. Although we observed a reduction in postchallenge viremia
as early as 5 weeks following immunization with
SIVmac239nef, more potent protection did not
develop until 10 to 15 weeks later, well after viremia was reduced to
undetectable levels. It is possible that SIV-specific CTL affect the
initial reduction in viremia through the clearance of infected cells,
while resistance to infection with the challenge virus depends on a
broadening or maturation of the cellular response over time.
Our results indicate that suppression of pathogenic SIV infection can
occur rapidly after immunization with SIVmac239nef and that
this is associated with significant replication of the vaccine virus in
vivo. Estimates of the total virus load of SIVmac239nef in
plasma prior to challenge indicate that approximately 3.0 × 1011 virions are produced during the immunization period.
However, comparison of the different challenge groups revealed no
significant difference in total viral load between the groups,
indicating that total exposure to virions (or viral antigens) cannot be
the sole determinant for protection. Rather, our results support the idea that the duration of time between immunization and challenge is
critical for protective immunity to develop and that this may be
dependent on continuous replication of the attenuated strain. It is not
yet known whether replication of the vaccine virus must be sustained in
order to maintain protective immunity, or whether the initial antigenic
stimulation achieved in the first 10 to 15 weeks following immunization
is sufficient to impart long-lasting immunity. This will be an
important question to address in future studies and will provide
information this is directly relevant to the design of alternative
vaccine strategies.
| |
ACKNOWLEDGMENTS |
We thank J. Booth, B. Clas, M. Bilska, C. Wingfield, and J. Keeperman for technical assistance, and we thank W. Chen for
preparation of the figures.
This work was supported by NIH grants (AI42454, AI41373, and AI35166)
and the Aaron Diamond Foundation.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Aaron Diamond
AIDS Research Center, 455 First Ave., 7th Floor, New York, NY 10016. Phone: (212) 448-5040. Fax: (212) 725-1126. E-mail:
rconnor{at}adarc.org.
| |
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Abstract
Introduction
