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Previous Article | Next Article 
Clinical and Diagnostic Laboratory Immunology, May 2000, p. 377-383, Vol. 7, No. 3
1071-412X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Variability and Immunogenicity of Human
Immunodeficiency Virus Type 1 p24 Gene Quasispecies
Johanna
Iroegbu,1
Markus
Birk,1,2
Una
Lazdina,1,3
Anders
Sönnerborg,1,2 and
Matti
Sällberg1,3,*
Divisions of Clinical Virology,
F68,1 Infectious
Diseases,2 and Basic Oral Sciences,
F58,3 Karolinska Institute, Huddinge
University Hospital, S-141 86 Huddinge, Sweden
Received 16 July 1999/Returned for modification 25 August
1999/Accepted 27 January 2000
 |
ABSTRACT |
Despite the conserved nature of the human immunodeficiency virus
type 1 (HIV-1) gag gene, multiple quasispecies of
the p24 gene coexist in HIV-1-infected patients. We cloned and
sequenced 31 p24 genes from four HIV-1-infected patients. The
intrapatient homology between the p24 genes ranged from 97.1 to 99.1%,
whereas the interpatient homology ranged from 91.5 to 93.8%,
suggesting a host-specific evolution. Synonymous and nonsynonymous
nucleotide changes were evenly distributed in the p24 gene, with 27 and
28%, respectively, located within host human leukocyte antigen class I
recognition sites. This would suggest only a minor influence from
the host cytotoxic T-cell response on the evolution of the p24 gene.
The importance of minor variations within p24 was analyzed by
designing DNA-based immunogens from two distinct p24 quasispecies genes
simultaneously derived from one patient. In plasmid-immunized H-2b, H-2d, and
H-2k haplotype mice, a clear influence from the
host major histocompatibility complex was noted on the immune
responses, fully consistent with those noted when a recombinant p24
protein is used as the immunogen. The two p24 DNA immunogens did not
differ in their immunogenicity, indicating that the limited genetic
variability (<1%) had little influence on the immune responses.
| |
INTRODUCTION |
The human immunodeficiency virus
type 1 (HIV-1) p24 capsid protein is released from the central portion
of the Gag polyprotein by two cleavages mediated by the viral
protease. The mature form of p24 contains approximately 240 amino acids
and constitutes the major subunit of the nucleocapsid. It has become
clear that HIV-1 rapidly adapts to a new host by continuously changing
the sequence of the viral proteins which are recognized by the host immune system. The cellular immune responses are generally believed to
be of critical importance in controlling the HIV infection (4, 8,
10, 11, 20). However, little is known about how the immune system
recognizes the virus present in the host.
Most previous studies on HIV-1 immunogens have been performed by using
immunogens based on laboratory prototype strains of HIV-1
(6). We know today that the difference between the sequence of a laboratory-based immunogen and that of the virus existing in
patients greatly exceeds the variability already present within each
patient (3). Consequently, even if an immunogen-specific immune response is elicited within an infected host, there is a high
probability that it will not recognize the multiple viral variants or
quasispecies present in the host. This might be one of the reasons why
all HIV-1 vaccines tested to date have failed to show any clinical
benefit (6).
We recently noted that the evolution of the well-conserved p17 gene
within an infected host is in part influenced by the contact regions
between the virus and the host class I-restricted immune response
(3). Recombinant protein immunogens based on two
members of the p17 quasispecies from the same patient and with a 92.4% homology were found to have distinct antigenic and immunogenic properties (2). Thus, despite sequence homologies between
p17 quasispecies of >90%, these quasispecies have distinct
properties. We were now interested to study whether minute sequence
variations might influence the immune responses to patient-based
genetic immunogens.
| |
MATERIALS AND METHODS |
Human serum samples.
Plasma samples were selected from four
HIV-1-seropositive patients (A, B, C, and D) described in detail
previously (3). All patients were monitored at the Division
of Infectious Diseases, Karolinska Institute, Huddinge University
Hospital, Huddinge, Sweden. All patients were men (age range, 27 to 38 years) who were infected by sexual transmission of HIV-1 subtype B. None had received any antiviral therapy prior to sampling.
HLA class I typing of each patient had been performed previously using
sequence-specific primers and PCR (3). The HIV-1 subtype of
each patient had earlier been determined by sequencing the variable
third domain of gp120. This analysis showed that all studied patients
were infected by HIV-1 subtype B (3).
Mice.
C57BL/6 (H-2b), BALB/c and
B10.D2 (H-2d), B10.M
(H-2f), CBA and B10.BR
(H-2k), and B10.S (H-2s)
mice were purchased from BK Universal, Sollentuna, or Harlan, Oxon,
United Kingdom. All mice were used at 4 to 6 weeks of age.
Isolation, amplification, cloning, and sequencing of p24
genes.
Virions in plasma were disrupted by treatment with a buffer
(pH 7.5) containing 50 mM Tris-HCl, 10 mM EDTA, 50 mM NaCl, 0.5% sodium dodecyl sulfate, and 10 mg of proteinase K per ml for 60 min.
Thereafter, total viral mRNA was isolated by oligo(dT)-coated magnetic
beads (Dynabeads; Dynal A.S., Oslo, Norway). Reverse transcription was
done at 42°C for 60 min (Moloney murine leukemia virus; Boehringer
Mannheim GmbH, Mannheim, Germany) using the downstream primer p24out3:
5'-CTTTGCCACAATTGAAACACTT-3'. To minimize the number of
PCR-induced errors, a Taq polymerase with proofreading capacity was used (Expand high fidelity PCR system; Boehringer Mannheim). The first-round PCR was performed using the upstream primer
p24out5 (5'-GACACCAAGGAAGCTTTAGA-3') and the p24out3'
primer. Amplification was carried out according to the following
protocol: preheating for 4 min at 95°C, followed by 30 cycles at
95°C for 1 min, 57°C for 1 min, and 72°C for 1 min. Finally,
there was an elongation step of 4 min at 72°C. For the second round
of PCR, we used the p24start primer containing an EcoRI
restriction site: 5'-CCTCGTGGAATTCTGCCTATAGTGCAGAACATCCAGGG-3'
and the p24stop primer containing an XbaI restriction
site and a stop codon:
5'-CGGTCTAGATCAC/AGCCAAAACTC/TTTGCTTTA/GTG-3'. The
second round of PCR was performed under identical conditions as the
first PCR except for a lower annealing temperature (50°C). The PCR
fragment corresponding to the expected size of p24 was extracted from
the agarose gel (2%) and purified (QIAquick gel extraction kit; Qiagen
GmbH, Hilden, Germany).
Amplified p24 genes were cloned in the eucaryotic expression vector
pcDNA3.1C/His (Invitrogen, San Diego, Calif.) containing a
cytomegalovirus promoter and a ColE1 origin of replication followed by
a multiple cloning site and an ampicillin resistance gene. The purified
gene products and the vector were digested with EcoRI and
XbaI (Boehringer Mannheim) for 2 h at 37°C. Ligation
of the amplicons with the vector was done at a molar proportion of 3:1 using T4 DNA ligase (GIBCO-Life Technologies, Gaithersburg, Md.) for 30 min at room temperature. For transformation, 2 µl of the ligation
mixture was added to 25 µl of DH5
-competent E. coli. Cells were spread on Luria-Bertani agar containing ampicillin (50 µg/ml). Growing clones were selected and checked for the p24-encoding gene by PCR using the p24start and p24stop primers. The plasmid DNA of
the p24-positive clones was further purified with the QIAprep plasmid
kit (Qiagen).
The DNA was thereafter prepared for sequencing according to the dideoxy
chain termination method. Sequences were read using the Cy5 AutoRead
sequencing kit (Pharmacia Biotech, Uppsala, Sweden) in conjunction with
an ALFexpress sequencer (Pharmacia Biotech). Sequencing was performed
using the T7 upstream primer (5'-Cy5-TAATACGACTCACTATAGGG-3') and the Sp6 downstream primer
(5'-Cy5-GCATTTAGGTGACACTATAG-3').
Locations of known p24 HLA class I recognition sites epitopes and
sequence analysis.
Locations of defined human p24
cytotoxic-T-lymphocyte (CTL) epitopes which correspond to the HLA
restriction elements of the four patients were derived from the HIV
Molecular Immunology Database (http://hiv-web.lanl.gov/immunology/index.html), as previously described (3). Alignment and phylogenetic analysis of the
p24 sequence homology were carried out by using the GeneWorks 2.3 (IntelliGenetics, Mountain View, Calif.) software package. Dendrograms were constructed using the unweighted pair group method with arithmetic mean (UPGMA) (GeneWorks 2.3).
DNA-based immunogens and in vitro translation.
Protein
expression of the p24 encoding vectors was analyzed using the TNT
coupled reticulocyte lysate system (Promega Corp., Madison, Wis.). In
vitro translation of plasmids was performed at 30°C and the
translation products were labeled using [35S]methionine
(Amersham International plc, Little Chalfont, Buckinghamshire, United
Kingdom). Separation of labeled proteins was done using sodium dodecyl
sulfate-15% polyacrylamide gels. The translation products were
visualized by autoradiography on X-ray film (Hyperfilm MP; Amersham)
for 18 h.
Recombinant protein and plasmid immunizations.
A p24/p17
fusion protein (12) was kindly provided by Darrel L. Peterson, Virginia Commonwealth University, Richmond, Va. Groups of
three or four mice were immunized intraperitoneally with 100 µg of
p24/p17 protein emulsified in Freund's complete adjuvant and received
boosters of the same dose in incomplete adjuvant 4 weeks later. The
mice were bled at 4 and 6 weeks after the first immunization. Titers of
antibody to the immunogen were determined using microplates coated with
p24/p17 fusion protein at 0.5 µg/ml and assay protocols previously
described (22).
Genetic immunizations were performed with groups of four or five mice;
mice received inoculations in tibialis anterior muscles 5 days
following injections of 50 µl of 10 mM cardiotoxin in
phosphate-buffered saline (7). Purified plasmids were
resuspended in phosphate-buffered saline and were injected at 100 µg
of DNA per mouse. The mice were given boosters at weeks 7 and 12.
EIAs.
HIV-1 p24 antibody titers in the serum of the
DNA-immunized mice were measured by Abbott HIV-1/HIV-2 3rd Generation
Plus enzyme immunoassay (EIA) (Abbott Diagnostics Division, Chicago,
Ill.). Serum samples from each group of mice were pooled and were
tested at a final dilution of 1:50. To detect murine antibodies,
alkaline phosphatase-labeled goat anti-mouse immunoglobulin G was used (Sigma). The incubation times for the murine and goat antibodies were
45 min. The substrate dinitrophenyldiamine was used to indicate bound
substrate, and absorbancies were read at 405 nm. All murine samples
giving twice the optical density at 405 nm of the samples derived prior
to immunization were considered positive.
In vitro recall assays.
T-cell recall assays were performed
as previously described (18, 22). In brief, 3 × 105 spleen cells suspended in 100 µl of Click's medium
were added to sterile 96-well microtiter plates. The cells were
incubated with and without fivefold dilutions of recombinant p24
antigen (human T-cell lymphotropic virus IIIB [HTLV-IIIB]) (Intracell Corporation, Cambridge, Mass.) starting at 7.5 µg/ml. After 72 h, 1 mCi of [3H]thymidine (Amersham) was added to each
well and the cells were incubated for another 16 to 20 h. The
cells were harvested onto cellulose filters and quenched, and the level
of incorporated radiolabeled nucleotide was determined by liquid
scintillation in a beta counter.
| |
RESULTS |
p24 sequence analysis.
Thirty-one clones from four HIV-1
positive patients were sequenced and analyzed, and for 28 clones, full-length p24 sequences could be obtained (Fig.
1). The first 23 and the last 18 nucleotides of each clone corresponded to regions covered by the PCR
primers. Thus, the p24 sequence which was used for analysis contained
647 bp coding for 215 amino acids.
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FIG. 1.
Phylogenetic analysis of the 31 full-length p24
sequences derived from four patients infected with HIV-1 subtype B. Dendrograms were generated using the UPGMA algorithm supplied with the
GeneWorks 2.3 software package. The two boxed sequences of patient A
indicate clones C and E, which were used for the design of DNA
immunogens. Also given is the HLA class I type of each patient. Each
clone that contains an amino acid change within the HLA restriction
elements of the host is underlined, and the respective restriction
element is indicated.
|
|
Sequence alignment revealed a 97.1 to 99.1% intrapatient
sequence homology (Table 1). The
interpatient homology ranged from 91.5 to 93.8%. A total of 60 base
substitutions were found when the individual p24 sequences were
compared with the respective intrapatient consensus sequences.
Approximately 0.34% (range, 0.21 to 0.46%) of the total number of
analyzed nucleotides showed changes.
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TABLE 1.
Comparison of the inter- and intrapatient variability
of the p17 and p24 genes in four patients infected with HIV-1
of subtype B
|
|
Eighteen (30%; range, 23 to 40%) nucleotide mutations were
nonsynonymous, whereas 42 (70%; range, 60 to 77%) were synonymous. The frequency of transitions (80%) was higher than that of
transversions (20%) and was dominated by the nucleotide change from A
to G (50%), followed by C to T (27%) and T to C (17%).
The inter- and intrapatient homologies of the p24 genes were compared
to the previously reported p17 gene variabilities of the same patients
(Table 1) (3). As expected, the analysis showed that
the inter- and intrapatient homology was higher for the p24 gene
than for the p17 gene in all patients analyzed. Thus, despite the fact
that these are conserved neighboring genes encoding proteins which are
not present on the viral surface, they show different degrees of variability.
Analysis of p24 sequence variability in relation to locations of
host p24 HLA class I recognition sites.
Previously identified CTL
epitopes within p24 were matched with the HLA class I restriction
element of each patient, as described previously (3).
p24 CTL epitopes have been more precisely mapped for the restriction
elements HLA-A2, -B7, -B8, -B12, and -B27, which are present among the
four patients. An average of 14% (range, 7 to 20%) of the
patient-derived p24 sequences corresponded to known host p24 HLA class
I recognition sites (Fig. 2). Out of the
18 amino acid changes, 3 (17%) were located inside while 15 (83%)
were located outside p24 epitopes recognized by the HLA class I
recognition sites of the host. Thus, the distribution of mutations
showed no preference for HLA class I recognition sites. One minor
observation is that two out of the three mutations detected in the p24
genes of patient C resided within an HLA-A2-restricted recognition site
(Fig. 2).
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FIG. 2.
Alignment of all 28 sequenced full-length p24 clones
from the four HIV-1-infected patients. The consensus sequence derived
from the 28 clones is given at the top of the alignment. Homologies
with the consensus are indicated by a dot. Also shown are the locations
of known CTL epitopes within p24 and the responsible restriction
element. For each patient, the sequence corresponding to an epitope
recognized by the host restriction element is boxed. The sequences of
clones C and E of patient A, which were used for the design of DNA
immunogens, are indicated by arrows.
|
|
Construction of p24 gene-based plasmid immunogens.
Two
members of the p24 quasispecies derived from patient A were
represented by the clones C and E, which were used for the construction of p24-expressing plasmids (p24DNA-C and p24DNA-E). The
clones were selected according to their few but distinct differences in
amino acid sequences, residue 47-Pro instead of Ala (p24DNA-C) and
residue 79-Glu instead of Gly (p24DNA-E) (Fig. 2). Also, the two clones
differed from the HIV-1IIIB p24 sequence by two amino acids
within an H-2b-restricted T-cell site (21),
but all sequences were identical within an H-2d-restricted
T-cell site (14) (Fig. 3). The
p24-C and p24-E p24 genes were reamplified with primers containing
EcoRI and XbaI restriction sites and were
inserted into the pcDNA3.1C/His vector for protein expression, as
shown in Fig. 2.
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FIG. 3.
(a) Sequences of the two members of the C and E p24
quasispecies used for cloning into the pcDNA3 eucaryotic expression
vector aligned with the HIV-1IIIB p24 sequence. (b) The
integrity of the cloned p24 genes C and E and the size of the
translation product were evaluated using in vitro translation in a
rabbit reticulocyte lysate assay. Lanes 1 and 2 show the HIV-1 p24
protein translated from clone C (p24DNA-C), and lanes 3 and 4 show the
HIV-1 p24 protein translated from clone E (p24DNA-E). Lane 5 shows the
70-kDa hepatitis C virus nonstructural 3/4A protein, and lane 6 shows
the 60-kDa kit control.
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|
The expression of p24 protein was analyzed by in vitro translation
using a rabbit reticulocyte lysate assay. Both plasmids express
proteins of 24 kDa, confirming the integrity of the cloned genes (Fig.
3). Also shown is the positive 60-kDa control plasmid included in
the kit and a plasmid expressing a 70-kDa hepatitis C virus
nonstructural 3/4A fusion protein (Fig. 3).
Immune responses to recombinant and genetic p24 immunizations.
As a reference for the murine responder hierarchy and the
immunogenicity of recombinant p24, groups of
H-2d and H-2k mice were
immunized with the recombinant p24/p17 fusion protein in
adjuvant. The antibody titers were around 1:1,000 in the primary response (after 4 weeks) and from 1:16,667 to 1:129,167 in the secondary response (after 6 weeks) (Fig.
4).
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FIG. 4.
Immunogenicity of recombinant p24/17 fusion protein in
two murine haplotypes (H-2d and
H-2k). Groups of three or four mice were
immunized and given boosters with p24/17 protein as described in
Materials and Methods. The mice were bled at weeks 4 and 6, and the
sera were tested for specific total immunoglobulin G in serial
dilutions by the p24/17 EIA as described in the text. Values are given
as the mean endpoint titers (a). Also shown is the immunogenicity of
the p24DNA-C and p24DNA-E plasmids in H-2b,
H-2d, and H-2k mice as
determined by p24-specific antibodies (b) and in vitro recall T-cell
proliferation (c). For panel b, the sera from each group of mice were
pooled and tested. For panel c, the results were calculated as the mean
sample counts per minute minus the mean counts per minute of the medium
control. OD, optical density; TdR, thymidine.
|
|
Groups of four or five mice of haplotypes H-2b,
H-2d, and H-2k were
primed and given boosters with 100 µg of either p24DNA-C or p24DNA-E
at weeks 0, 7, and 12. Serum samples were collected at 2- to 4-week
intervals. Serum samples were pooled, and the presence of anti-p24
antibodies was determined by a commercial EIA. At week 16, all animals
were sacrificed, and splenocytes were collected for T-cell
proliferation assays. Antibodies to p24 became detectable within 5 to
10 weeks from first immunization (Fig. 4). The
H-2b and H-2d haplotypes
were the earliest and best responders, while the
H-2k haplotype was consistently a slow and low
responder. This is fully consistent with the rp24 immunizations (Fig.
4), which confirms the influence from the murine major
histocompatibility complex (MHC) genes on the responder status. No
difference between the humoral responses to the p24DNA-C and p24DNA-E
immunogens was noted, showing that the minor sequence variations
between the p24DNA immunogens did not influence the ability to respond
to HIV-1 p24. Overall, the responses primed by the recombinant protein immunizations were quantitatively much stronger than those recorded following the DNA-based immunizations (always <1:500).
The p24-specific proliferative responses in the two best antibody
responder haplotypes confirmed the immunogenicity of the DNA immunogens
on the T-cell level (Fig. 4). p24-specific T-cell proliferation could
be recalled at p24 concentrations as low as about 10 to 100 ng/ml
regardless of the haplotype and regardless of the immunogen. It should
be noted that the primed T cells were recalled by p24 from the IIIB
strain, which differs by two amino acids within an
H-2b-restricted T-cell site (Fig. 3) (21),
whereas all sequences were identical within an
H-2d-restricted T-cell site (14). This
sequence difference may explain the slightly less efficient
recall of p24DNA-C and p24DNA-C-primed H-2b-restricted T
cells than that of the H-2d-restricted T cells (Fig.
4).
| |
DISCUSSION |
Due to the high replication rate and low fidelity of the
reverse transcriptase, HIV-1 has an extremely high mutation rate, resulting in changes in the antigenicity (9, 16). These
factors are likely to be major obstacles in both antiviral therapies
and the development of HIV-1 vaccines. By accumulating mutations, HIV-1
may render itself less sensitive to the host humoral and CD4+ and CD8+ cellular immune responses. This
has now been evidenced by the failure of all human HIV-1 vaccine trials
in humans to prevent or to modulate the infection (6).
Most HIV-1 immunogens so far have been based on viruses, proteins, or
genes from laboratory strains of HIV-1. For example, it was recently
shown that the sequence differences between the gp120 of the HTLV-IIIB
and the SF-2 subtype B strains result in distinct immunogenicities in
mice (1). In particular, A.SW mice were antibody responders
to gp120 of the SF-2 strain and were nonresponders to gp120 of the IIIB
strain (1). This is most likely explained by the fact that
these two gp120 proteins have an amino acid sequence homology of only
around 83%. We recently found that despite a 92% homology between two
members of the HIV-1 p17 quasispecies, the two genes encode proteins
which are antigenically and immunogenically distinct in both humans and
mice (2). It could therefore be questioned whether it
is at all possible to induce immune responses by vaccines based on even
slightly varying proteins of HIV-1 that actually recognize a
wild-type virus that has adapted to the host immune response. To
further address this question we have now performed similar analyses
using the highly conserved p24 gene.
Although our analysis is limited by the number of clones sequenced and
the incomplete definition of CTL epitopes for all HLA restriction
elements, we found that both synonymous and nonsynonymous mutations
seem to be evenly distributed throughout the HIV-1 p24 gene. In
contrast to the more variable p17 gene (3), no clear clustering of the nonsynonymous mutations was found within host HLA
class I-restricted recognition sites within the p24 gene. These
observations could, apart from the already-mentioned limitations, also
be secondary to the possibility that mutations within p24 may be lethal
for the virus or that changes in p24 CTL epitopes occur immediately
after infection, thereby adapting the virus to the new host. Several
studies have indicated that CTLs to p24 are present within the
infected host, which suggests that these types of responses are induced
(5, 11, 13). Although both p17- and p24-related CTL epitopes
have been proposed to undergo immune escape, for example through
antagonism, no clear correlation has been found between the
p24-specific CTL responses and the rate of disease progression
(15). CTLs have in some cases even been found to be
deleterious for the infected host (13). In contrast, it was
recently shown that the p24-specific CD4+ proliferative
T-cell response correlates with the ability to control HIV-1 viremia
(17).
Using two members of the p24 quasispecies from one infected individual,
we designed DNA-based genetic immunogens. The translation products from
the two plasmids were of identical size and quality, indicating that
the two quasispecies may not differ substantially in their biochemical
properties. More importantly, when used as genetic immunogens, both
quasispecies-based plasmids induced comparable immune responses. The
responder hierarchy, with the H-2d haplotype as
a good responder and the H-2k haplotype as a low
responder, was reiterated using both DNA and recombinant protein
immunizations, implicating the host MHC as the major determinant in the
responder status. This is similar to observations made for other
conserved viral proteins, where clear influences from the host MHC on
the immune responses can be noted (18, 19). However, in
responses to more variable proteins, such as HIV-1 gp120 and p17 or the
hepatitis C virus NS4A, a clear influence is also seen from sequence
variations between the different viral variants (1, 2, 22).
Altogether, the present data suggest that the two quasispecies-based
genetic immunogens have comparable immunogenicities, which implies that the minor differences between these two proteins do not have a major
impact on the immune response. Collectively, p17 quasispecies-based recombinant proteins with a homology of 92% were antigenically and
immunogenically distinct (2), whereas a sequence homology of
>99% between p24 immunogens did not seem to cause obvious differences in immunogenicity in the three murine haplotypes tested. We noted that
the p24-specific humoral responses were of a low magnitude following
DNA-based immunizations as compared to immunizations using recombinant
proteins. This is fully consistent with similar studies using HIV-1 or
other viral antigens (18). Both humoral and cellular immune
responses following genetic immunizations using the hepatitis
B virus core and e antigens were of a 100-fold-lower magnitude than the
corresponding responses following immunizations with recombinant
proteins in adjuvant (18). Thus, the present study further
confirms that genetic immunogens are comparatively ineffective in
priming these responses.
We have herein not found clear evidence that nonsynonymous mutations
cluster within the HLA class I-restricted recognition sites of the
HIV-1 p24 protein. However, to further minimize the risk of inducing
immune responses which are only vaccine-specific, we have herein
described the design and evaluation of two patient-derived p24-based
genetic immunogens. The immunological analysis of these genetic
immunogens suggests that they have comparable immunogenicities and that
the viral variability does not affect the ability to mount an immune
response. Similar patient-derived, "personal" vaccines may be the
most effective way to ensure the priming of immune responses that
actually recognize the virus of the infected host if more variable
viral proteins are to be used as immunogens.
| |
ACKNOWLEDGMENTS |
The present study was supported by the Swedish Medical Research
Council grant no. K98-06X-12617-01A and Swedish Physicians Against AIDS.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Clinical Virology, F68, Karolinska Institute at Huddinge University
Hospital, S-141 86 Huddinge, Sweden. Phone: 46-8-5858 79 39. Fax:
46-8-5858 79 33. E-mail: misg{at}labd01.hs.sll.se.
| |
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Clinical and Diagnostic Laboratory Immunology, May 2000, p. 377-383, Vol. 7, No. 3
1071-412X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
