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Journal of Virology, December 1999, p. 10264-10271, Vol. 73, No. 12
Aaron Diamond AIDS Research Center,
Received 19 July 1999/Accepted 7 September 1999
There are natural mutations in the coding and noncoding regions of
the human immunodeficiency virus type 1 (HIV-1) CC-chemokine coreceptor
5 (CCR5) and in the related CCR2 protein (the CCR2-64I mutation).
Individuals homozygous for the CCR5- The CC-chemokine receptor 5 (CCR5)
is the major coreceptor for the most commonly transmitted (R5) strains
of human immunodeficiency virus type 1 (HIV-1) (1, 5, 8, 10,
11). Over the past few years, several mutations in CCR5 have been
identified as natural genetic polymorphisms able to influence the
probability of acquiring HIV-1 infection or to affect the rate of
disease progression, in infected adults (7, 12, 17, 22, 31, 42) or infants (3, 24, 32). A 32-nucleotide deletion in CCR5, the CCR5- No studies on the CCR5 5'-UTR have yet been conducted in the setting of
mother-infant HIV-1 transmission, which accounts for a significant
fraction of new HIV-1 infections worldwide. Thus, we have now assessed
whether genetic variation in the CCR5 5'-UTR, and whether possession of
the CCR5- Clinical samples.
Pediatric clinical samples were obtained
from four cohorts: the Women and Infants Transmission Study (WITS)
cohort, the New York City-Western New England (NY-WNE) cohort, the
Newark Perinatal Cohort (NPC), and the ARIEL Project cohort. All
pediatric clinical samples were derived from patients in the United
States. For this study, only infants followed from birth were included.
Infants first observed later in life were excluded to avoid introducing a strong selection bias resulting in an apparently higher fraction of
infected infants; infected infants are far more likely than uninfected
ones to be brought to the attention of pediatricians in early life.
HIV-1 infection was defined as two positive viral cultures and/or HIV-1
DNA PCR assays on two separate occasions. The race of the infant was
taken to be the self-described race of the mother.
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
A Polymorphism in the Regulatory Region of the CC-Chemokine
Receptor 5 Gene Influences Perinatal Transmission of Human
Immunodeficiency Virus Type 1 to African-American Infants
ABSTRACT
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
32 allele, which prevents CCR5
expression, strongly resist HIV-1 infection. Several genetic
polymorphisms have been identified within the CCR5 5' regulatory
region, some of which influence the rate of disease progression in
adult AIDS study cohorts. We genotyped 1,442 infants (1,235 uninfected
and 207 HIV-1 infected) for five CCR5 and CCR2 polymorphisms:
CCR5-59353-T/C, CCR5-59356-C/T CCR5-59402-A/G, CCR5-32, and
CCR2-64I. The clinical significance of each genotype was assessed by
measuring whether it influenced the rate of perinatal HIV-1
transmission among 667 AZT-untreated mother-infant pairs (554 uninfected and 113 HIV-1 infected). We found that the mutant CCR5-59356-T allele is relatively common in African-Americans (20.6%
allele frequency among 552 infants) and rare in Caucasians and
Hispanics (3.4 and 5.6% of 174 and 458 infants, respectively; P < 0.001). There were 38 infants homozygous for
CCR5-59356-T, of whom 35 were African-Americans. Among the
African-American infants in the AZT-untreated group, there was a highly
significant increase in HIV-1 transmission to infants with two mutant
CCR5-59356-T alleles (47.6% of 21), compared to those with no or one
mutant allele (13.4 to 14.1% of 187 and 71, respectively;
P < 0.001). The increased relative risk was 5.9 (95%
confidence interval, 2.3 to 15.3; P < 0.001). The
frequency of the CCR5-59356-T mutation varies between population groups
in the United States, a low frequency occurring in Caucasians and a
higher frequency occurring in African-Americans. Homozygosity for
CCR5-59356-T is strongly associated with an increased rate of perinatal
HIV-1 transmission.
INTRODUCTION
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
32 allele which encodes a defective CCR5 protein, has been identified as a natural genetic polymorphism reducing the risk
of acquiring HIV-1 infection and the rate of disease progression in
infected adults. The complete absence of CCR5 expression in CCR5-32
homozygotes is strongly protective against infection by R5 HIV-1
variants (7, 12, 17, 31), although a few such individuals
have been infected with CXCR4-using (X4) strains (2, 23, 28,
36). Adults and children heterozygous for the CCR5-32 allele
are not protected against HIV-1 infection but progress more slowly to
AIDS and death, compared to CCR5 wild-type individuals (3, 7, 12,
13, 22, 24, 32, 42). However, the magnitude of CCR5 expression on
blood CD4+ T cells varies substantially among individuals
with one or two wild-type CCR5-coding alleles (25, 30, 37),
leading to suggestions that polymorphisms in the CCR5 untranslated
(regulatory) region (5'-UTR) might influence HIV-1 transmission and
disease progression (25, 27, 30, 39). Several genetic
variations have been identified within the CCR5 5'-UTR (14, 19,
21, 26, 27), some of which have been reported recently to affect
the rate of disease progression in adults (19, 21, 26). One
such polymorphism (CCR5-59653-T) is genetically associated with a
coding region mutation in CCR2 (an isoleucine instead of valine at
amino acid 64; CCR2-64I). Adults who possess the CCR2-64I allele are
not protected against HIV-1 infection but progress less rapidly
to disease once infected (13, 14, 34), although the mutation does not affect CCR2 protein function (16).
32 and CCR2-64I alleles, influences perinatal HIV-1
transmission. To do this, we have used four well-characterized cohorts
of HIV-1-infected and uninfected infants from the United States. Since
CCR5-32 and CCR5 5'-UTR polymorphisms exist at different frequencies
among different ethnic groups (13, 18-20, 26, 27, 35), we
also subdivided the cohorts into Caucasian, Hispanic, and
African-American groupings. In addition, because of the significant
reduction in perinatal HIV-1 transmission that is associated with
zidovudine (AZT) prophylaxis (6, 37), we examined the
relationship between the CCR5 and CCR2 polymorphisms and HIV-1
perinatal transmission separately for AZT-treated and AZT-untreated
mother-infant pairs.
MATERIALS AND METHODS
Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
Identification of CCR5-59356-C/T polymorphic site. Genomic DNA was extracted from peripheral blood mononuclear cells (QIAamp Blood kit; Qiagen) from 132 uninfected Caucasian, Hispanic, Asian, or African-American adult volunteers resident in the United States. A 688-nucleotide sequence spanning the CCR5 5'-UTR and the two noncoding exons (26, 27) was amplified from each sample by PCR (Fig. 1). The primers were LK84 (5'-AAGTCCAGGATCCCCCTCTA-3'; positions 59043 to 59064) and LK87 (5'-CATTCCAAACTGTGACCCTTTCC-3'; positions 59709 to 59732; GenBank accession no. U95626). Forty cycles of amplification were performed in a 96-well thermocycler (model 9600; Perkin-Elmer) under conditions previously described (14). Each PCR product was purified and sequenced, using LK84, LK85 (5'-GTGTAGTGGGATGAGCAGAGA-3'; positions 59290 to 59310), and LK86 (5'-CAGAAGAGCTGAGACATCCGT-3'; positions 59530 to 59550) as overlapping sequencing primers. The CCR5-59356-C/T, CCR5-59353-T/C, and CCR5-59402-A/G polymorphisms were identified by analysis of the aligned DNA sequences, using standard procedures (data not shown).
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Spectral genotyping.
To genotype the five polymorphisms
(CCR5-32, CCR2-64I, CCR5-59353-T/C, CCR5-59356-C/T, and
CCR5-59402-A/G) in each infant from all four cohorts, we used both DNA
sequencing and spectral genotyping (4, 15, 33). The
spectral genotyping assays for CCR5-32 and CCR2-64I have been
previously described (14, 15). To genotype the
CCR5-59402-A/G polymorphism, we designed a new assay based on the
general operational principle described previously (14,
15). One molecular beacon, labeled with 6-carboxyfluorescein (FAM), recognizes the wild-type CCR5-59402-A allele (A at position 59653); the other, labeled with hexachlorofluorescein (HEX), is for the
mutant CCR5-59402-G allele (G at position 59402). The nucleotide
sequences were FAM-5'-CGGCGTTCTTCTTTTTAAGTTGAGGCCG-3'-DABCYL and
HEX-5'-CGCGGTCAGTGAA CAGTTCTTCCTTTTAAGTCCGCG-3'- DABCYL,
respectively. The primers were LK85 and LK112
(5'-GCTGTGCAAATCAATCATATAGAG-3'; positions 59497 to 59520).
The real-time PCR conditions and data analyses were as previously
described (14, 15) except that the annealing and data
collection temperature was 55°C instead of 60°C.
Statistical analysis. The Pearson chi-square test for 3 × 2 contingency tables was used to determine the statistical significance of differences in genotype distributions among different populations (e.g., infected and uninfected, different ethnic groups). Fisher's exact test was applied to 2 × 2 contingency tables and used to determine the statistical significance (two sided) of differences in perinatal transmission rates between different subgroups (e.g., between different genotypes). Logistic regression analysis was used to evaluate the relative odds of perinatal transmission, the 95% confidence interval, and the statistical significance for each variable in the regression equation (e.g., between different genotypes). The Hardy-Weinberg equilibrium for each genetic polymorphism was assessed by the Pearson chi-square test with a 3 × 2 contingency table (1 df) of the observed genotype distribution in comparison with the expected distribution based on the observed allele frequency. Mantel-Haenzel analyses were used to verify that the results presented were not influenced by the year of enrollment or study cohorts. Multivariate logistic regression was performed to determine if unions and intersections of polymorphism genotypes were associated with the risk of transmission. Logistic regressions for these analyses were done by a step-down procedure that started with the entire collection of variables (intersections done separately from unions). The univariate genotypes were included in the analysis set of independent variables. The step-down procedure used an alpha level of 0.01 for a variable to stay in the regression. Logistic regression was also used to determine if a univariate association of a polymorphism genotype with HIV-1 perinatal transmission remained, after adjusting for other known predictors of transmission, for the subset of infants in the WITS and ARIEL cohorts (n = 656). The adjustment variables included in this analysis were as follows: African-American race, mother and infant AZT use, mother and infant CD4 counts, premature birth, birth after February 1994, and CCR5-59356T homozygosity.
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RESULTS |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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A total of 1,442 infants born to HIV-1-infected mothers in four
pediatric cohorts met the inclusion criteria for this study. Of these
infants, 1,235 were uninfected and 207 were infected, producing an
overall transmission rate of 14.4% (Table
1). The racial distributions for the
combined cohorts were 47.9% (n = 691)
African-Americans, 13.5% (n = 194) Caucasians, 34.1%
(n = 492) Hispanics, and 4.5% (n = 65)
other racial groups. In total, 667 infants were in the AZT-untreated
group and 473 were in the AZT-treated group. For 302 mother-infant
pairs, treatment data were missing or prophylaxis was only partial;
these 302 cases were excluded from analyses. The racial frequencies
among the 302 excluded infants, the AZT-treated group, and the
AZT-untreated group were not significantly different. In the
AZT-treated category, the HIV-1 transmission rate was significantly
lower (8.5%) than in the untreated category (17.1%; P < 0.001), confirming that AZT prophylaxis is associated with a lower
risk of transmission (0.45; 95% confidence interval, 0.31 to 0.66)
(P < 0.001). A lower transmission rate for
mother-infant pairs receiving AZT was observed in all four individual
cohorts, for all ethnic groups and all coreceptor genotypes. There was
no evidence in this data set for a time-associated decrease in
transmission among mother-infant pairs that did not receive AZT.
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We analyzed the effect of each of five coreceptor genetic
polymorphisms (CCR5-32, CCR2-64I, CCR5-59353-T/C,
CCR5-59356-C/T, and CCR5-59402-A/G), and of composite genotypes,
on perinatal HIV-1 transmission. Separate analyses were performed on
both the AZT-treated and untreated groups, because the
substantial effect of AZT might in principle obscure subtle genetic
influences on transmission. The treated group comprises a complex
set of therapeutic regimens and treatment histories, and so we
considered the untreated mother-infant pairs to be the optimal subset
for discerning genetic associations with HIV-1 transmission. Figure 1
shows the positions on chromosome 3 of all of the studied mutations,
including the CCR5-59356-C/T polymorphism that we identified in this
study. Each mutation was evaluated by (i) comparing the genotype and mutant allele frequencies between HIV-1-infected and uninfected groups;
(ii) comparing the fraction of HIV-1-infected children among the
different genotypes; and (iii) evaluating the relative risks by
regression analyses. The full set of results for the AZT-untreated
group is shown in Table 2; the
significant observations are further analyzed and presented in Fig.
2 and 3.
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The CCR5-32 deletion is significantly more prevalent in Caucasians
(allele frequency, 5.9% in 194 individuals) than in African-Americans (2.0% in 691; P = 0.001) and Hispanic individuals
(2.4% in 492; P = 0.02) (Fig. 2A), consistent with
previous report (5, 10, 20). Because of the smaller number
of Caucasians in this study, no CCR5-32/32 homozygotes were
present, and so the effect of this genotype on perinatal transmission
could not be determined. Untreated CCR5-32 heterozygotes have lower
HIV-1 transmission rates than CCR5 wild-type homozygous infants (Table
2), but this was not statistically significant (P > 0.3).
The distribution of the CCR2-64I genotypes is similar (allele frequency, 13.4 to 16.5%; P = 0.05) among the three racial groups (Fig. 2A), consistent with previous reports (14, 34). In the untreated group, there is no effect of CCR2-64I on HIV-1 transmission (Fig. 2B and Table 2), but in the AZT-treated group there is a trend (P = 0.06) for reduced transmission to CCR2-64I heterozygotes compared to CCR2 wild-type homozygotes (Table 2, footnote c).
The CCR5-59356-T mutant allele is significantly (P < 0.001) more prevalent among African-Americans (20.6% of 552 individuals) than in the Hispanic (5.6% of 458) or Caucasian (3.4% of 174) group (Fig. 2A). In fact, CCR5-59356-T mutant homozygotes are most often found among African-Americans: 35 of the 38 mutant homozygotes in this study are in African-Americans. Therefore, we analyzed the CCR5-59356 alleles in the African-American group.
Among the 552 African-Americans, 6.3% were homozygotes for the mutant CCR5-59356-T allele. In the untreated group, the genotype and allele distributions of the CCR5-59356-T mutation are significantly (P < 0.001) different between HIV-1-infected and uninfected infants (Table 2 shows data for the AZT-untreated group, all races combined). Among the 45 HIV-1-infected African-American infants, there is a significantly (P < 0.002) higher CCR5-59356-T allele frequency (33.3%) (Fig. 2B), and a CCR5-59356-T mutant homozygote genotype frequency (22.2%), than among the 234 uninfected infants (17.7 and 4.7%, respectively). By comparing the fractions of untreated, HIV-1-infected infants in the three CCR5-59356 genotypes (Fig. 3A), we found a significantly higher rate of transmission among CCR5-59356-T mutant homozygotes (47.6% of 21 CCR5-59356-T mutant homozygote infants) compared with both CCR5-59356-A wild-type homozygotes (13.4% of 187; P < 0.001) and CCR5-59356 heterozygotes (14.1% of 71; P = 0.001). In other words, about half of the untreated infants in the four combined cohorts who are homozygotes for the CCR5-59356-T mutation are infected with HIV-1, an unexpectedly large fraction. Infants who are CCR5-59356-T mutant homozygotes are associated with an increased relative risk for HIV-1 infection of 5.9 (95% confidence interval, 2.3 to 15.3) (P < 0.001). The enhancing effect of the CCR5-59356-T mutation on HIV-1 transmission was not observed in the AZT-treated group (Fig. 3B).
A logistic regression was performed on data from the WITS and ARIEL
cohorts (only these two cohorts were included, as the other studies did
not have detailed information on all of the covariables to determine if
the HIV-1 transmission resistance demonstrated by infants homozygous
for CCR5-59356T remained after adjusting for other known predictors of
HIV transmission). The variables used are included in Table
3, with the exception of the log of the
mothers' HIV-1 RNA count at the time of delivery. There was only a
small number of WITS mothers for whom the RNA count was available
(n = 146, HIV-1 infected = 33), and so the full
results including this variable are not presented here; results of the
analysis including this variable were similar to those presented for
homozygous CCR5-59356T (odds ratio = 12, P < 0.04). The results in Table 3 indicate that the presence of the
CCR5-59356T homozygous genotype was a significant independent predictor
of transmission. The AZT variable and the time indicator of birth are
highly correlated. The time indicator function of a baby's delivery
date indicates whether the birth was before or after February 1994, when it first became clear that AZT could dramatically reduce
mother-infant HIV-1 transmission and AZT became widely used. AZT use by
the mother is not significant in this regression analysis due to the
inclusion of the time variable. The statistical finding in favor of the
time variable probably reflects other changes in treatment combinations
after 1994 that may be more successful than AZT alone.
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We investigated whether the higher frequency of the CCR5-59356-T mutation among African-Americans would significantly increase the relative risk of HIV-1 perinatal transmission in this group by several methods, including a Mantel-Haenzel analysis and a comparison of transmission frequencies in African-Americans versus non-African-Americans. We could, however, find no evidence for an association between race and HIV-1 transmission (Table 1). Although homozygosity for CCR5-59356-T significantly increases the risk of transmission, and this genotype is most commonly found in African-Americans, its frequency is too low to profoundly affect the overall transmission rate among African-Americans. How CCR5 5'-UTR polymorphisms affect perinatal transmission in pediatric cohorts from Africa is currently being investigated.
The frequency of the CCR5-59353-C allele is high (44.8%) in the combined population (Fig. 2A) but is significantly lower among African-Americans (40.3% of 656 individuals) than in Hispanic individuals (48.2% of 477; P = 0.02) and Caucasians (53.8% of 185; P = 0.001). In the AZT-untreated group, the CCR5-59353-C allele had no observable effect on transmission (Fig. 2B), but in the treated group, the CCR5-59353 genotype distribution was different (P = 0.006) between HIV-1-infected and uninfected infants (Table 2, footnote d).
The frequency of the CCR5-59402-G mutant allele is significantly lower (P < 0.001) among African-Americans (13.7% of 681 individuals) than in the Caucasian (29.1% of 189) and Hispanic groups (33.2% of 486) (Fig. 2A). In the untreated group, there is a trend (P = 0.05) for a reduced HIV-1 transmission rate to infants who are CCR5-59402-G mutant homozygotes compared to CCR5-59402-A wild-type homozygous infants (Table 2). The relative risk of 0.35 (95% confidence interval, 0.12 to 1.0) is also reduced (P = 0.05). There was no significant effect of the CCR5-59402 genotype on HIV-1 transmission rates in the AZT-treated group.
In a systematic study of linkage disequilibrium between the different
loci to search for any effects of combinations of alleles on HIV-1
transmission, we observed indications of an additive protective effect
against HIV-1 transmission of the CCR5-32, CCR5-59353-C, and
CCR5-59402-G alleles in combination. The P values obtained
in this analysis should be interpreted cautiously, as we performed
multiple tests to look for combinations of alleles of particular
interest. Given this caveat, there was a significant difference
(P = 0.01) in the linked distribution of the CCR5-59353 and CCR5-59402 genotype distributions between HIV-1-infected and uninfected infants who are CCR5-32 heterozygotes, an effect not seen
in infants who are CCR5 wild-type homozygotes. In the untreated group,
infants who are CCR5-32 heterozygotes, and who also have two or more
CCR5-59353-C, CCR5-59402-G, and CCR5-59356-T mutant alleles
(n = 25), have a significantly lower transmission rate (0% of 25 infants) than the 642 other infants who do not have this
genotype combination (17.6% transmission rate; 113 of 642 infants).
Moreover, in the full cohort (AZT treated or untreated), none of the 46 infants in the combined groups who are CCR5-32 heterozygotes, and
who also have two or more CCR5 5'-UTR mutations, was HIV-1 infected.
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DISCUSSION |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Our studies on coreceptor gene polymorphisms in infants exposed to HIV-1 in vitro or during delivery have revealed that possession of the CCR5-59356-T/T genotype can significantly increase the rate of perinatal HIV-1 transmission. It is conceivable that the CCR5 genotype of the mother will also affect her capacity to transmit HIV-1 to her infant, but we have not yet completed studies of this. There are no previous reports of the influence of CCR5 regulatory region polymorphisms on perinatal HIV-1 transmission, although it has been shown that some such polymorphisms affect the rate of disease progression in HIV-1-infected adults (19, 21). Among these reports is one by Martin et al., who found no association between the possession of any of the CCR5 regulatory region alleles (CCR5P1 to CCR5P4 based on their nomenclature) and protection from sexual HIV-1 transmission (19). However, HIV-1-infected adults who were CCR5P1/P1 homozygotes (CCR5-59353-C/C and CCR5-59356-C/C homozygotes based on our nomenclature) progressed to AIDS more rapidly than those with other CCR5 promoter haplotypes. It is important to note that the infants who were CCR5-59356-T/T homozygotes (n = 38) in our study also had the CCR5-59353-T/T-, CCR5-59402-A/A-, and CCR5-coding wild-type genotypes. In a different study, McDermott et al. found that another mutation within the CCR5 regulatory region, a G-to-T variant at position 59029 (CCR5-59029-G/T polymorphism), is associated with relatively slow progression to AIDS in adults (21). We have not investigated whether this polymorphism affects perinatal transmission. We also do not yet know whether any of the CCR5 5'-UTR polymorphisms that we have studied influence disease progression in infected infants; these studies are complicated by the relative lack of long-term clinical follow-up in pediatric cohorts before use of antiretroviral agents became common, compared to the longer-established adult sexual transmission cohorts that have been studied by others (19, 21).
The central finding of the present study is that homozygosity for a
genetic mutation in the CCR5 5'-UTR (CCR5-59356-T) is associated with
an increased rate of HIV-1 perinatal transmission. This mutation is
found at a higher frequency among African-Americans than in Hispanic or
Caucasian populations. Conversely, mutations associated with a reduced
rate of perinatal transmission (CCR5-32 and CCR5-59402-G) are less
common among African-Americans. However, the frequency of the
CCR5-59356-T genotype among African-Americans was not sufficient to
cause an overall increase in the rate of perinatal transmission in this
group. It remains possible that these various genetic factors
contribute to the relatively high rate of perinatal HIV-1 transmission
reported to occur in Africa, although many other influences on
transmission efficiency are also likely to be relevant (38).
As yet, we have only limited information on the origin of the CCR5
5'-UTR mutations we have studied and on their global distribution. What
we have observed among present-day African-Americans probably reflects
founder effects; certain CCR5 alleles may be enriched among
African-Americans because they were prevalent in their African ancestors who arrived in United States during the 16th to 19th centuries. Over time, the distribution of these alleles will change because of population mixing; the CCR5-32 allele has been introduced into present-day African-American and Hispanic populations by contact
with the northern Europeans in whom it originated (18, 20).
It will therefore be valuable to determine the frequencies of the CCR5
5'-UTR alleles among modern African populations. This may well not be
uniform; an analogy is the distribution of the CCR5-32 allele in
Caucasian populations, which is high in northern Europe and less common
in central and southern Europe, probably reflecting population
migration patterns over the past few thousand years (18,
20).
We do not know how the effects of the CCR5 5'-UTR polymorphism are manifested biologically. It is a reasonable assumption, however, that they influence the expression of CCR5 in relevant immune system cells. This could be achieved by modifying the extent of CCR5 expression or the cells in which CCR5 is expressed. The levels of CCR5 on CD4+ T cells vary significantly among different individuals with wild-type CCR5-coding alleles (19, 25, 30, 39). We are presently exploring whether such variation is directly linked to polymorphisms in the CCR5 5'-UTR. However, it is also possible that CCR5 promoter usage varies, absolutely or quantitatively, between tissues and that the 5'-UTR polymorphisms affect this difference. The CCR5 5'-UTR has twin promoters, a feature often associated with tissue-dependent protein expression patterns (27). Of note is that CCR5 expression has been detected in multiple cell types in the female genital tract (40). Furthermore, the extents of CCR5 expression in the ectocervix and in CD4+ T cells of the peripheral blood are not correlated (29). This is potentially relevant to the efficiency of HIV-1 perinatal transmission, since CCR5-using viruses are the most commonly transmitted strains, both perinatally and sexually (7, 12, 22, 41, 42).
In principle, mutations affecting CCR5 expression or function might have different influences on perinatal transmission, depending on the time at which transmission occurs. For instance, HIV-1 transmission in utero may take place by a process that is less dependent on CCR5, compared to transmission mechanisms that operate at or soon after birth. There is some evidence that HIV-1 infections which occur despite AZT therapy result primarily from ante partum transmission, based on positive HIV-1 culture and DNA or RNA PCR results from blood samples obtained within 48 h of birth (10). In the WITS cohort, a significantly higher proportion of HIV-1 perinatal infections were antepartum (P < 0.05) after March 1994, when the ACTG 076 results became publicly known, versus before March 1994. We have observed that among the AZT-treated, HIV-1-infected group in the combined cohorts, the deleterious effect of the CCR5-59356-T/T mutant genotype is not evident. However, future meta-analyses may fruitfully address the issue of whether CCR5 polymorphisms have an effect on perinatal transmission rates that is conditional on the timing or route of transmission. Likewise, meta-analysis will be able to confirm whether certain CCR5-genotype combinations provide partial protection from HIV-1 perinatal transmission, as indicated by our study.
Finally, whatever genetic influences contribute to HIV-1 perinatal transmission, a consistent finding of this and other studies (6, 37) is that AZT prophylaxis reduces the probability of transmission. There is, therefore, every reason to support the provision of AZT or relevant drugs to HIV-1-infected, pregnant women worldwide.
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ACKNOWLEDGMENTS |
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We are indebted to the staff members of the hospitals listed below who provided clinical data and samples for this study. The participants and funding sources were as follows: for the WITS, C. Diaz and E. Pacheco-Acosta (University of Puerto Rico, San Juan; U01 AI 34858), R. Tuomala, E. Cooper, and D. Mestehene (Boston/Worcester Site, Boston, Mass.; U01 AI 34856), J. Pitt and A. Higgins (Columbia Presbyterian Hospital, New York, N.Y.; U01 AI 34842), S. Landesman, H. Mendez, and G. Moroso (State University of New York, Brooklyn; HD-8-2913 and RO-1-HD-25714), K. Rich and D. Turpin (University of Illinois at Chicago; U01 AI 34841), W. Shearer, C. Hanson, and N. Cooper (Baylor College of Medicine, Houston, Tex.; U01 AI 34840), R. Nugent (National Institute of Child Health and Human Development, Bethesda, Md.), and V. Smeriglio (National Institute on Drug Abuse, Rockville, Md.); for the NY-WNE, M. McManus (University of Massachusetts, Worcester), B. Stechenberg (Baystate Medical Center, Springfield, Mass.); P. Krause (University of Connecticut Medical School, Farmington), and K. Krasinski, M. Rigaud, A. Kaul, R. Lawrence, W. Hoover, and S. Chandwani (New York University Medical School, New York, N.Y.); for the NPC, T. Denny (University of Medicine and Dentistry of New Jersey, Newark); for the ARIEL, C. Hanson (Texas Children's Hospital/Baylor, Houston), W. T. Shearer (Baylor College of Medicine), R. B. Van Dyke (Tulane University School of Medicine, New Orleans, La.), S. M. Widmayer (Children's Diagnostic and Treatment Center, Fort Lauderdale, Fla.), A. Wiznia (Bronx Lebanon Hospital Center, Bronx, N.Y.), A. Ammann (Center for AIDS Prevention, University of California San Francisco, San Francisco), I. S. Y. Chen (University of California Los Angeles, Los Angeles), R. Koup (University of Texas, Dallas), P. Krogstad (University of California Los Angeles, Los Angeles), J. Mullins (University of Washington, Seattle), and B. D. Walker (Massachusetts General Hospital, Boston). We are indebted to M. G. Fowler, A. J. Amman, C. Wilfert, and T. Divine for assistance with sample access and to M. Small for secretarial help.
Financial support was provided by the National Institutes of Health (grants RO1 AI43868 [to L.G.K.] and RO1 AI41420 [to J.P.M.]). Additional support was provided by the Irene Diamond Fund; the Columbia-Rockefeller Center for AIDS Research; the Committee for the Advancement of Research and the Gonda-Goldschmied Medical Diagnostic Center at Bar-Ilan University (A.U.N. and L.D.); the National Institutes of Health (grant NO1-AI85339); the Centers for Disease Control and Prevention (grant U64/CCU202219-13 [to P.P.]); and the Pediatric AIDS Foundation, of which J.P.M., K.L., and B.T.K. are Elizabeth Glaser Scientists and H.M.L.S. is a Scholar.
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FOOTNOTES |
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* Corresponding author. Mailing address: Aaron Diamond AIDS Research Center, 455 First Ave., New York, NY 10016. Phone: (212) 448-5021. Fax: (212) 725-1126. E-mail: lkostrik{at}adarc.org.
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REFERENCES |
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Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References
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Journal of Virology, December 1999, p. 10264-10271, Vol. 73, No. 12
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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