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Clinical and Diagnostic Laboratory Immunology, July 1998, p. 463-466, Vol. 5, No. 4
1071-412X/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Divisions of Clinical Virology (F 68),1 Clinical and Oral Bacteriology (F 88),3 and Infectious Diseases,4 Karolinska Institutet, Huddinge University Hospital, S-141 86 Huddinge, Sweden, and Department of Infectious and Tropical Diseases, University of Rome "La Sapienza," Rome, Italy2
Received 24 November 1997/Returned for modification 15 January 1998/Accepted 19 March 1998
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ABSTRACT |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The correlation among the presence of a 32-bp deletion in the
CC-chemokine receptor 5 (CCR5) gene, disease progression,
and human immunodeficiency virus type 1 (HIV-1)-specific immune
responses was analyzed for a cohort of 79 Caucasian HIV-1-infected
patients. The CCR5 genotype (CCR5/CCR5 = wild type/wild type or 
32CCR5/CCR5 = 32-bp
deletion/wild type) in peripheral blood mononuclear cells was
determined by PCR, followed by sequencing of both wild-type and
32CCR5 gene fragments. HIV-1-specific humoral responses
to gp41 and V3MN peptides were determined by enzyme
immunoassays. The prevalence of the 32CCR5 allele was
lower among 37 patients with rapid progression (progression to AIDS or
to a CD4 cell count of <200 × 106/liter in less than
9 years; P < 0.01) compared to that for 42 patients
with slow progression (no AIDS and CD4 cell count of >200 × 106/liter after at least 9 years from infection) or to that
for 25 non-HIV-1-infected Swedish blood donors (P < 0.05). No differences were observed in the wild-type CCR5
sequences between the different groups of patients. For three analyzed
patients, the 32-bp 32CCR5 gene deletions were
identical. The antibody titers against gp41 and a V3MN
peptide in patients with the 32CCR5/CCR5 genotype were
not significantly different from those in pair-matched
CCR5/CCR5 controls. However, in 13 analyzed patients, a
stronger serum neutralizing activity was associated with the
32CCR5/CCR5 genotype. Thus, a CCR5/CCR5
genotype correlates with a shortened AIDS-free HIV-1 infection period
and possibly with a worse neutralizing activity, without an evident
influence on the antibody response to two major antigenic regions of
HIV-1 envelope.
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INTRODUCTION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Two major coreceptors, essential for
the entry of human immunodeficiency virus type 1 (HIV-1) into
CD4-positive cells, were recently described. The fusin, or CXC
receptor 4 (CXCR-4), is required for the infectivity of
T-cell-tropic syncytium-inducing HIV-1 strains (3).
The CC-chemokine receptor 5 (CCR5) gene (20) is
essential for the infectivity of macrophage-tropic (M-tropic) non-syncytium-inducing HIV-1 strains (1, 9, 10) by
binding the viral gp120 V3 loop (6). It was recently
shown that a homozygous 32-bp deletion in the CCR5
(32CCR5/32CCR5) gene causes
truncation and loss of CCR5 receptor expression on
lymphoid cells, reducing the permissiveness of cells for HIV-1
infection. This mostly results in protection of the host against
infection with HIV-1 (17, 23, 26). A heterozygous deletion
in the same gene pair (32CCR5/CCR5), although not
protective against HIV-1 infection, may change the rate of
HIV-1-related disease progression (8, 15, 21, 22). In
fact, a higher prevalence of this genotype has been reported for
HIV-1-infected long-term nonprogressors (LTNPs) (11,
12). Additional, lesser known factors, such as switching between
different receptor usages (7), are likely to be important
during HIV-1 infection and disease progression.
The prevalence of the 32CCR5 allele in the Caucasian
population varies from 4 to 12% in Europe with a 15% peak in Denmark and Iceland (11, 18). The prevalence in HIV-1-infected and uninfected individuals in Sweden has not yet been reported.
Furthermore, it is not known whether all 32CCR5 deletions
are identical or whether certain sequences or mutations within the
CCR5 gene correlate with disease progression.
The humoral immune response to HIV-1 has been extensively studied. It has been shown elsewhere that HIV-1-infected patients with a long-term nonprogressive course or slow disease progression display significantly different humoral responses than do those with a more rapid disease progression (4, 5, 16, 24, 28). It is not known whether the humoral HIV-1-specific responses are in any way correlated with the CCR5 genotype.
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MATERIALS AND METHODS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Patients. Peripheral blood mononuclear cells (PBMC) were obtained from a cohort of 79 HIV-1-infected Swedish or Italian patients attending the Division of Infectious Diseases at Huddinge Hospital, Huddinge, Sweden (n = 64), or the Department of Infectious and Tropical Diseases at the University of Rome "La Sapienza," Rome, Italy (n = 15), respectively. The cohort is composed of patients with a defined HIV-1 seroconversion time (n = 13) or a first positive HIV-1 test documented before 1988. Patients were divided into rapid and very rapid progressors versus slow progressors and LTNPs on the basis of their individual AIDS-free intervals (time from seroconversion or from first HIV-positive test to reach Centers for Disease Control and Prevention [CDC] stage C or 3) and their CD4+ cell counts in February 1997. The median time for progression in the whole cohort was 9.2 years. The patients considered rapid progressors were those with an AIDS-free period of less than 9 years (n = 37), including 12 very rapid progressors (AIDS-free interval shorter than 5 years). Slow progressors were all the remaining individuals (n = 42; 29 Swedish and 13 Italian patients) including 23 LTNPs, these being defined by the contemporary presence of 9 or more years of documented HIV-1 infection, a CD4+ cell count always above 500 per µl of blood, no antiretroviral therapy, and no HIV-related symptoms. Twenty-five HIV-1-seronegative Swedish blood donors were used as controls. Serum samples from 36 non-AIDS patients of the cohort (26 Swedish and 10 Italian patients; 47% in CDC stage A1, 39% in A2, and 14% in B1-B2), collected from October 1995 to February 1997, were also used for antibody measurement and neutralization testing.
Enzyme immunoassays and neutralization activity test. The levels of antibodies to a peptide corresponding to the V3 loop of HIV-1MN (U.S.-European consensus; RKSIHIGPGRAFYTT) and to a peptide corresponding to an antigenic region of the HIV-1 gp41 (GIWGCSKLICTTAVPWNAS) were determined exactly as described previously (5). The 90% inhibitory activity (neutralizing activity) of patient sera toward clinical primary Swedish and Italian macrophage-tropic HIV-1 isolates was measured as previously described (24).
PCR.
A 183-bp fragment of the CCR5 gene was
amplified by a previously described PCR (17) from PBMC
genomic DNA. Wild-type 183-bp CCR5 gene fragments were
distinguished from the CCR5 genes with an internal
32-bp deletion (32CCR5) (17) by
electrophoresis separation. For sequencing, a 340-bp fragment from
the CCR5 gene was amplified by a separate PCR, with the
primers 5'-CTCCTGACAATCGATAGGTAC-3' and biotinylated
5'-CACAGCCCTGTGCCTC-TTCTT-3'. The amplification was
performed in a volume of 50 µl with 10 µl of sample (lysed PBMC or
extracted DNA from PBMC), 20 pmol of each primer, 0.5 mM
MgCl2, 125mmoles of each deoxynucleoside triphosphate per
liter, and 1 U of Taq polymerase in 1× PCR buffer. In
the PCR program, a 5-min 94°C denaturation was followed by 5 cycles
of 94°C for 30 s, 55°C for 45 s, and 72°C for 90 s
and 30 cycles of 94°C for 30 s, 62°C for 45 s, and 72°C
for 90 s. Amplimers were separated on a 2.5% agarose gel and
visualized by ethidium bromide staining. The PCR products with the
32CCR5/CCR5 genotype were excised, purified with the
QIAEX II kit (Qiagen, Heiden, Germany), and separately reamplified for
sequencing.
Sequencing. The amplified products were directly sequenced with the Cy5-labeled primer 5'-ACTTGGGTGGTGGCTGTGTTT-3' and T7 polymerase as previously described (23). Sequence alignment and analysis were performed with the DNASIS sequence analysis software (Hitachi Software Engineering Co., San Bruno, Calif.).
Pair matching and statistical analysis.
The prevalence of
the 32CCR5 allele in the different groups was compared by
the Fisher's exact test. The Kaplan-Meier log rank test was used to
compare cumulative AIDS-free fractions. HIV-1 antibody titers were
compared in 32CCR5/CCR5 subjects and in
CCR5/CCR5 patients by the Mann-Whitney U test. Patient pair matching was obtained for sex, age (±5 years), and CDC stage to control the effects of these confounding variables on antibody titers
in 12 32CCR5/CCR5 subjects and in 12 CCR5/CCR5
controls. The remaining 12 controls could not be matched with the cases (unmatched).
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RESULTS |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Analysis of CCR5 genotypes.
The CCR5
genotype was determined for the cohort of 79 HIV-1-infected
patients and for 25 uninfected blood donors. The prevalence of the
32CCR5 allele in rapid progressors was lower than that in
slow progressors (P < 0.01) and than that in blood
donors (P < 0.05) (Table
1). A different classification of the
patients was also tested for statistical significance, including LTNP
(n = 23) and very rapid progressor (n = 12) subgroups (Table 1). However, a difference in the prevalence of the
mutated allele did not further increase. The prevalence rates of the
32CCR5 allele in Swedish and Italian LTNPs were similar
(14.3 and 16.6%, respectively; P = 0.99). A
significant delayed progression rate was found in subjects with the
32CCR5/CCR5 genotype compared to those with
CCR5/CCR5 (Fig. 1).
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Sequence analysis of the amplified CCR5 gene
fragments.
The sequence of the amplified CCR5 gene
fragments was determined for 44 patients with a CCR5/CCR5
genotype and for 3 patients with a 32CCR5/CCR5 genotype.
In the latter three cases, the wild-type and 32CCR5 gene
fragments were excised from the gels and were separately sequenced. The
32-bp deletion was identical for all three patients. Moreover, no
differences were observed in the wild-type CCR5 genes of
patients with different rates of disease progression compared to
the CCR5 consensus sequence (GenBank accession no.
U54994) (data not shown). Thus, in the present material no
specific sequence motif within the amplified wild-type CCR5 gene fragments correlates with the rate of disease progression.
Correlation between CCR5 genotype and
HIV-1-specific humoral responses.
To analyze the correlation
between the CCR5 genotypes and HIV-1-specific humoral
responses, titers of antibodies to HIV-1 V3 and gp41 peptides were
determined by enzyme immunoassays for 12 patients with a
32CCR5/CCR5 genotype and for 24 CCR5/CCR5 controls (12 of them pair matched with the patients). No significant differences in V3 and gp41 antibody titers were observed with respect
to the CCR5 genotype (Table
2).
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32CCR5/CCR5 subjects was significantly higher than that
for the 11 subjects with the CCR5/CCR5 genotype (1:22
versus 1:14; P = 0.025). In this group, the correlation
between neutralizing activity and anti-V3 or -gp41 titer was not
significant.
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DISCUSSION |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The recent discovery that cellular chemokine receptors are
required for HIV-1 entry into CD4-positive cells has improved the understanding of HIV-1 pathogenesis (6, 9, 10, 17, 23). It has been shown elsewhere that both the natural receptor ligands and
their antagonists may interfere with HIV-1 infection of permissive cells in vitro (25). It has been proposed elsewhere that the presence of a heterozygous 32-bp deletion in the CCR5 gene
may partially protect against progression to AIDS (8, 11, 12, 15,
19, 21, 22). We could confirm this finding in the present patient
samples since the 32CCR5 allele was more frequent among
patients with slow or no disease progression. Interestingly, we
observed similar high frequencies of the 32CCR5 allele in LTNPs, slow progressors, and uninfected blood donors, which indicates that in our samples the wild-type CCR5/CCR5 genotype
correlates with a faster disease progression and not vice versa. This
result can probably be explained by both the high prevalence of LTNPs in our slow progressor group and the high prevalence of the
32CCR5 allele in our Swedish blood donor sample. Patients
with the CCR5/CCR5 genotype may better support a rapid
HIV-1 life cycle (14, 27) than do the ones expressing
the mutant 32CCR5 allele (29). The mutant
allele may prevent efficient HIV-1 replication by a reduction in
the number of available receptors, and this effect could be amplified
by secondary increases in the level of antiviral chemokine secretion
(21). Therefore, patients with a CCR5/CCR5 genotype might be more prone to an early onset of immune deficiency and
clinical symptoms during the first years of infection, when M-tropic
HIV-1 strains are predominant. Still unclear is the influence of
the CCR5 genotype in the advanced stages of HIV-1
infection. However, in a recent report, the 32CCR5/CCR5
genotype was found to correlate with a reduced survival time after AIDS
development (13). Other rare allelic variants of the
CCR5 gene apart from the wild type and the 32
deletion have been described elsewhere (2). By sequence
analysis of the 207 bases of the amplified CCR5 gene
fragment outside the primer regions, we could not correlate a
particular CCR5 sequence motif with the rate of disease
progression. However, our analysis is limited to the amplified fragment
and should be extended to full-length CCR5 genes.
We have for the first time correlated the CCR5 genotype with
the humoral HIV-1-specific immune responses. However, in patients with the 32CCR5/CCR5 genotype no differences were
observed in levels of antibody to HIV-1 V3 and gp41 peptides,
especially when the influence of the clinical stage was excluded by
pair matching the CCR5/CCR5 controls. A higher mean
neutralization titer was associated with the 32CCR5/CCR5
genotype in our results (P = 0.025), and this finding
merits further investigation. However, only two
32CCR5/CCR5 patients could be tested, a number too small to control the confounding effect of clinical stage on neutralizing activity (24). Thus, this result has to be interpreted with caution.
In conclusion, we could confirm that the 32CCR5 allele is
more frequent among HIV-1-infected patients with a long-term
AIDS-free infection period compared to those who rapidly progress to
AIDS. No differences were seen in comparing LTNPs with the remaining slow progressors. A high prevalence of the 32CCR5 allele
was found in our group of Swedish blood donors. Moreover, in the
present study possible correlations between HIV-1-specific immune
responses and the 32CCR5/CCR5 genotype were not clearly
observed.
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FOOTNOTES |
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* Corresponding author. Mailing address: Division of Clinical Virology, F 68, 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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