Chemokine receptor 5 (CKR-5) was recently characterized as a major co-receptor for entry of macrophage (M)-tropic HIV-1 strains. A 32-base pair deletion allele (CKR-5∆32) was also identified and found to encode a non-functional receptor that does not support membrane fusion or infection by M-tropic HIV-1 strains. Combined results from 3 independent studies provide strong evidence to suggest that individuals homozygous for CKR-5∆32 are protected from HIV infection. Out of a total of 1058 high risk for HIV exposure, seronegative individuals, there were 33 (3.1%) deletion homozygotes. In contrast, there was not a single homozygote among 2741 seropositive subjects. There is somewhat less of a consensus about the effect of heterozygosity on HIV infection and disease progression, but it appears that heterozygotes are not resistant to infection; however, they may have some limited protection against disease progression. Although other genetic and environmental cofactors may play a role in HIV infection, these findings have significant implications for the development of new HIV therapies, as drugs can be designed to target the HIV-CKR5 interaction and block viral entry.

Key Words: chemokine receptor 5 (CKR-5), CKR-5∆32, macrophage (M)-tropic, T cell (T)-tropic, HIV resistance

CKR-5∆32

TTT CCA TAC Agt cag tat caa ttc tgg aag aat ttc cag aca TTA AAG ATA GTC

[ 32-bp deletion ________]

This mutant protein was determined to be a nonfunctional ß-chemokine receptor as well as a nonfunctional M-tropic HIV-1 co-receptor, accounting for the uninfected, seronegative status of homozygotes at high risk for HIV exposure; homozygotes for the deletion allele avoid infection because they lack a functional CKR-5 receptor (6; 13; 14; 16). Interestingly enough, there appears to be no negative phenotype associated with the CKR-5 defect, probably because of the redundant nature of the chemokine system.

So far, three studies have been published that collectively examined CKR-5 genotype frequencies in cohorts of HIV infected people, at-risk, HIV seronegative individuals, and normal, uninfected populations. The first study conducted by Samson et al. (1996) genotyped DNA samples from 704 healthy, Northern European Caucasian individuals, 124 Western and Central African individuals, and 248 Japanese people for CKR-5 (16). The allele frequencies were found to be .908 for wild-type CKR-5 and .092 for the mutant in the sample of Caucasian individuals. The CKR-5 genotype frequencies translate to about 83% of the Caucasian population being homozygous for wild-type, 16% being heterozygous, and 1% being homozygous for the deletion allele, which is not significantly different from the expected Hardy-Weinberg distribution. However, there were no CKR-5∆32 alleles found in the cohorts from Africa and Japan, suggesting that the mutant allele is either absent or extremely rare in these regions. Samson et al. then compared the CKR-5 allele and genotype frequencies of 723 HIV seropositive Caucasian individuals from Belgium and France with the seronegative cohort of healthy Caucasian people. This comparison revealed that the frequency of the CKR-5∆32 allele was significantly less in the HIV-infected population (0.054) versus the uninfected population (0.092) [p<0.0005]. There was a smaller percentage of heterozygotes in the infected group (10.8%) versus the uninfected group (16.2%), and there were no homozygotes for the deletion allele among the 723 seropositive individuals compared to 1.1% among the seronegative population. The authors of this study also found that the truncated CKR-5∆32 protein cannot function effectively as an HIV-1 co-receptor. From their results, the Samson group confirmed that CKR-5 is the major co-receptor used by M-tropic HIV-1 strains and concluded that homozygotes will demonstrate strong resistance to HIV-1 infection, and that heterozygotes may also have some degree of protection. They suggested that the partial resistance of heterozygotes may be due to a decrease in the number of functional CKR-5 receptors or a dominant-negative effect of CKR-5∆32.

The second study of this kind was conducted by Dean et al. (1996) and examined CKR-5 genotype frequencies in high-risk for HIV exposure populations in the United States (6). This study was more extensive than the previous one in that it included 6 different long-term AIDS cohort studies and a total of 1955 subjects. The participants in this study included HIV-1 seronegative individuals at high risk for exposure, HIV-1 infected AIDS patients, and HIV-1 infected patients who have not progressed to AIDS. While the previous study compared allele and genotype frequencies of HIV seropositive people with healthy, uninfected individuals, this study made comparisons within high risk groups for HIV-1 infection (homosexual men, intravenous drug users, and hemophiliacs) who differed in their seronegative and seropositive status. Unlike the Samson study, these authors did not find any significant difference in the allele frequencies of CKR5 between HIV-1 infected and seronegative individuals in any of the cohorts. However, they did find a significant difference when they compared genotype frequencies between seropositive and seronegative subjects. Out of the 612 seronegative individuals, 17 (3%) were homozygous for the CKR-5∆32 deletion allele. As in the Samson study, there was not a single deletion homozygote among the 1343 seropositive individuals. However, unlike the Samson study, the Dean group did not find any evidence showing that heterozygotes are protected against HIV-1 infection; there was approximately the same proportion of heterozygotes in both the seropositive (15%) and seronegative (14%) populations. But, they did find some indications to suggest that heterozygotes may have a delayed progression to AIDS compared to wild-type homozygotes. In the homosexual cohorts, there were more than twice as many heterozygotes among the long-term nonprogressors compared with rapid progressors; however, there was no significant difference in the heterozygote frequencies in long-term nonprogressors versus rapid progressors in the hemophiliac populations studied. Kaplan-Meier survival analyses also demonstrated that heterozygotes have a significantly delayed progression to AIDS compared with wild-type homozygotes. These authors also confirmed the Samson group's observations that the CKR-5∆32 allele is rare in populations of African descent (allele frequency of 0.017) compared to the Caucasian population (allele frequency of 0.115).

The third paper that examined CKR-5 genotype frequencies was published by Huang et. al (1996) and studied a combination of the types of populations looked at in the previous two papers (13). These authors genotyped 637 normal platelet donors to the New York Blood Center, 191 selected Asian populations, 137 African populations, and 1252 homosexual men from the Chicago MACS cohort studies. Once again, these researchers did not find any homozygotes for the CKR-5∆32 allele among 675 HIV infected participants. In addition, they did not find a single deletion allele in the Asian and African groups. The protective effect of the CKR-5∆32 homozygous state was further confirmed by follow-up of Caucasian MACS participants who had anal receptive intercourse with over 6 different partners in the 6 months prior to enrollment. After being followed for 8 years or longer, these subjects were observed to remain seronegative. 33.3% of these individuals were homozygous for CKR-5∆32. However, one should be a bit cautious when analyzing this percentage, since only 12 cases were followed for the 8+ year period. Unlike the Samson study, but like the Dean study, this group did not find any evidence to support that heterozygosity protects against HIV-1 infection. The percentage of heterozygotes in normal platelet donors, at-risk seronegative subjects, and infected people were found to be comparable. In order to examine the role of the heterozygous genotype on disease progression, they compared CD4 decline and viral load in heterozygotes and wild-type homozygotes, and found that heterozygotes had a slower CD4 decline and lower mean plasma viremia. However, the authors of this study were more skeptical than the Dean group about the protective effect of heterozygosity on disease progression as they did not note any significant differences between wild-type homozygotes and heterozygotes in Kaplan Meier survival analyses of time to AIDS or death in seroconverters.

When the data is combined from these 3 studies, there is not a single CKR-5∆32 homozygote among 2741 HIV-1 infected individuals. When data on high risk, seronegative individuals from the Dean and Huang studies are combined, there is a total of 33 (3.1%) CKR-5∆32 homozygotes out of 1058 at-risk, uninfected people. Combining the data from normal, uninfected Caucasian individuals in the Samson and Huang studies results in a total of 17 (1.3%) CKR-5∆32 homozygotes out of 1341 people (Table 1). The absence of any deletion homozygotes among the HIV-1 infected subjects compared to the prevalences of 1.3% in normal, Caucasian individuals and 3.1% in high risk, uninfected subjects is highly significant, with p<0.0001 in both cases (z-test). Furthermore, when compared to normal, Caucasian individuals, there is a significantly greater proportion of homozygotes among the high risk, seronegative subjects (1.3% vs. 3.1%, respectively), with a p-value of 0.0027. Collectively, these results support the hypothesis that individuals homozygous for the CKR-5∆32 allele are strongly protected against HIV-1 infection.

§ Samson et al., 1996; Dean et al., 1996; Huang et. al, 1996

† Dean et al., 1996; Huang et. al, 1996

* Samson et al., 1996; Huang et al., 1996. The majority of these subjects were Caucasian individuals

§ Samson et al., 1996; Dean et al., 1996; Huang et. al, 1996. The total number of subjects is less than that in Table 1 because the Huang study only included numerical data on heterozygotes for Caucasian participants of the MACS study.

† Dean et al., 1996; Huang et. al, 1996

* Samson et al., 1996; Huang et al., 1996. The majority of these subjects were Caucasian individuals

There were several limitations with these studies that should be considered when conducting future research in this area. First, the true HIV-exposure status of the at-risk, seronegative individuals in the Dean and Huang studies was not clear. Although these people were in high risk groups for HIV exposure, some of these individuals may never have been exposed to the virus. Perhaps, more detailed questions could be asked regarding the subjects' knowledge of their partners' HIV status as well as their own sexual behavior (number of partners, use of condoms and other methods of protection) and infection with other STDs. These factors can play a significant role in determining whether or not an individual becomes infected. Secondly, none of these studies control for the effects of anti-viral therapy on disease progression. This is critical particularly when Kaplan-Meier survival analyses are being done, since anti-viral drugs can affect disease and survival outcome.

The knowledge that has been gained through these studies raises several interesting questions for future research: Since CKR-5 is the co-receptor for M-tropic HIV strains, but not T- tropic strains, are deletion homozygotes susceptible to infection by the latter types of virus? Is the resistance of deletion homozygotes to M-tropic HIV absolute or relative? If it is relative, is the level of resistance affected by the viral inoculum size or route of transmission? Only 3.1% of the high-risk, seronegative individuals in the combined studies were homozygous for CKR-5∆32; what other genetic, environmental, or behavioral factors could have contributed to protection from disease in the other 97%, particularly in those who were homozygous for wild-type?

A study by Garred et al. (1997) recognized the influence of another genetic cofactor on HIV susceptibility and disease progression (11). The authors found that homozygotes for variant mannose-binding lectin (MBL) alleles have an increased risk for HIV infection. MBL functions as part of the complement system and therefore is particularly important in the first line of host defense prior to establishment of the adaptive immune response. None of the high risk, HIV negative subjects were homozygous for variant MBL alleles in comparison to 8% of the HIV-infected individuals. Furthermore, both heterozygosity and homozygosity for the variant MBL alleles were correlated with a significantly shorter survival time after AIDS diagnosis. Therefore, the association between CKR-5 genotype and rate of disease progression in subjects in the Dean and Huang studies may have been confounded by the effects of MBL genotype.

The existence of other co-receptors for HIV entry is also a likely possibility. A study by Cheng-Mayer et al. (1997) showed that there was no strict correlation between macrophage tropism and use of the CKR-5 co-receptor as well as T-cell tropism and use of the CXCR4 co-receptor (3). The authors found that several T-tropic and M-tropic viral strains were able to use both CXCR4 and CKR-5 for entry, despite their specific tropism for either T-cells or macrophages. These findings suggest that other co-receptors play a role in determining tissue-specific HIV entry.

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