Faculty Bibliography

Two promoters for the CCR5 gene, termed Pu and Pd, corresponding to the upstream and downstream initiation sites, respectively, have been described. We show here that the proximal promoter, Pd, is used two- to fivefold more frequently than Pu in primary activated T cells and in the transformed T cell line PM1. Because of its importance in CCR5 transcription we characterized the transcriptional activity of this promoter. Pd contains a pair of consensus TATA elements (nt -19 and -31) and several potential regulatory elements and transcription factor-binding sites, including those for STAT, NF-kappaB, AP-1, NF-AT, and CD28RE. Using a transfected reporter vector, we found the promoter to be highly active and cell type specific. By 5' deletion analysis, the minimal CCR5 promoter was localized to a 225-nucleotide region (nt -189 to +36). This region contained the two TATA elements, a CD28RE consensus sequence, an AP-1-binding site, and two STAT-binding sites. The 1.9-kb intron appeared to have a negative influence on reporter gene activity, suggesting the presence of a negative element in this region. In addition, an upstream negative element was detected in the region nt -988 to -588. Mutagenesis of the TATA elements, of the NF-kappaB-, and AP-1-, and STAT-binding sites, and of the CD28RE indicated the importance of each of these in transcription. Finally, the NF-kappaB/Rel family member, p65(RelA), was a potent activator of the CCR5 promoter

We examined the human immunodeficiency virus type 1 infectability of CD4+ lymphocytes isolated from CCR5 wild-type individuals, individuals heterozygous for the delta32 allele of CCR5, and HIV-1-exposed but uninfected (EU) individuals who had CD4+ lymphocytes refractory to M-tropic viral replication. None of the EU individuals were found to be heterozygous for the delta32 allele. The CD4+ lymphocytes isolated from CCR5/delta32 and EU individuals were less infectable with an M-tropic viral isolate of HIV-1 than CCR5/CCR5 control individuals but were equally as infectable with a T-tropic viral isolate. The restriction to M-tropic viral isolate replication did not associate with any profound genotypic change in the CCR5 gene. CD4+ lymphocytes from CCR5/delta32 and CCR5/CCR5 EU individuals were more sensitive to the HIV-inhibitory effects of the recombinant beta-chemokines RANTES, MIP-1alpha, and MIP-1beta than were CD4+ lymphocytes from CCR5/CCR5 control individuals. CD4+ lymphocytes from EU individuals also showed increased sensitivity to recombinant beta-chemokines and low surface expression of CCR5. A phenotype of low CCR5 expression and high secretion of beta-chemokines is associated with reduced infectability of cells by M-tropic HIV-1. This phenotype may also be associated with protection against sexual transmission of HIV-1

Monocyte-macrophages can be productively infected by CCR5-specific, but not CXCR4-specific, HIV-1. This could be due either to the absence of this chemokine receptor in this cell lineage or to other, yet undefined cellular cofactors that modulate the coreceptor activity of the CXCR4 in these cells. To investigate the basis of macrophage tropism, we studied the expression of CCR5 and CXCR4, as well as several of the other CC chemokine receptors, on monocyte-macrophages at different stages of differentiation. We found that on fresh monocytes, CXCR4 was relatively abundant, but it fell to barely detectable levels in culture over 24 hr and maintained this low level of expression during differentiation in vitro. Some donor macrophages appeared to express CXCR4 at levels comparable to CCR5. In contrast, CCR5 expression was low on fresh monocytes but increased on in vitro differentiation. Taken together, the results show that monocyte-macrophage differentiation is associated with a differential expression of chemokine receptors that may contribute to, but does not fully account for, the selectivity of these cells to HIV entry. GM-CSF, a cytokine that induces macrophage differentiation, caused a rapid decrease in CXCR4 and CCR5 mRNA and was correlated with decreased ability to support HIV entry

Members of the chemokine family of chemotactic peptides interact with their target cells through heptahelical cell surface receptors. An understanding of the biochemistry and expression patterns of these receptors is therefore central to our overall understanding of the roles played by chemokines in both physiological and pathological processes. To date, eight receptors for the beta-chemokine subfamily have been described. We have recently cloned a novel murine beta-chemokine receptor and report here the identification and characterization of a highly homologous human gene termed human D6 (hD6). This is a promiscuous beta-chemokine receptor and appears to be able to bind the majority of members of the beta-chemokine family. It is, however, specific for this family and shows no detectable affinity for members of the alpha-chemokine or the C or CXXXC chemokines. Unlike the majority of other chemokine receptors, human D6 does not appear to be able to flux calcium following ligand binding, thus it is currently not clear if this novel receptor is indeed a signaling receptor. Human D6 is expressed in a range of tissues including hemopoietic cells although it appears not to be ubiquitously expressed in hemopoietic cells. Human D6, unlike some other beta-chemokine receptors, appears not to be able to function as an entry co-factor for human immunodeficiency virus type 1 (HIV-)1 on CD4-expressing cells

Entry of human immunodeficiency virus type 1 (HIV-1) requires CD4 and one of a family of related seven-transmembrane-domain coreceptors. Macrophage-tropic HIV-1 isolates are generally specific for CCR5, a receptor for the CC chemokines RANTES, MIP-1alpha, and MIP-1beta, while T-cell line-tropic viruses tend to use CXCR4 (also known as fusin, LESTR, or HUMSTR). Like HIV-1, simian immunodeficiency virus (SIV) requires CD4 on the target cell surface; however, whether it also requires a coreceptor is not known. We report here that several genetically divergent SIV isolates, including SIVmac, SIVsmSL92a, SIVsmLib-1, and SIVcpzGAB, can use human and rhesus CCR5 for entry. CXCR4 did not facilitate entry of any of the simian viruses tested, nor did any of the other known chemokine receptors. Moreover, SIVmac251 that had been extensively passaged in a human transformed T-cell line retained its use of CCR5. Rhesus and human CCR5 differed at only eight amino acid residues, four of which were in regions of the receptor that could be exposed, two in the amino-terminal extracellular region and two in the second extracellular loop. The human coreceptor was as active as the simian for SIV entry. In addition, HIV-1 was able to use the rhesus homologs of the human coreceptors, CCR5 and CXCR4. The SIV strains tested were specific for CCR5 regardless of whether they were able to replicate in transformed T-cell lines or macrophages and whether they were phenotypically syncytium inducing or noninducing in MT-2 cells. However, SIV replication was not restricted to cells expressing CCR5. SIV strains replicated efficiently in the human transformed lymphoid cell line CEMx174, which does not express detectable amounts of transcripts of CCR5. SIV also replicated in human peripheral blood mononuclear cells that were genetically deficient in CCR5. These findings indicated that, in addition to CCR5, SIV can use one or more unknown coreceptors that are expressed on human PBMCs and CEMx174 cells

Recent studies have identified several coreceptors that are required for fusion and entry of Human Immunodeficiency Virus type 1 (HIV-1) into CD4+ cells. One of these receptors, CCR5, serves as a coreceptor for nonsyncytium inducing (NSI), macrophage-tropic strains of HIV-1, while another, fusin or CXCR-4, functions as a coreceptor for T cell line-adapted, syncytium-inducing (SI) strains. Using sequential primary isolates of HIV-1, we examined whether viruses using these coreceptors emerge in vivo and whether changes in coreceptor use are associated with disease progression. We found that isolates of HIV-1 from early in the course of infection predominantly used CCR5 for infection. However, in patients with disease progression, the virus expanded its coreceptor use to include CCR5, CCR3, CCR2b, and CXCR-4. Use of CXCR-4 as a coreceptor was only seen with primary viruses having an SI phenotype and was restricted by the env gene of the virus. The emergence of variants using this coreceptor was associated with a switch from NSI to SI phenotype, loss of sensitivity to chemokines, and decreasing CD4+ T cell counts. These results suggest that HIV-1 evolves during the course of infection to use an expanded range of coreceptors for infection, and that this adaptation is associated with progression to AIDS

The recent identification of the CC-CKR5 beta chemokine receptor as a major cofactor for entry of macrophage-tropic isolates of human immunodeficiency virus type 1 (HIV-1) raises the question of whether macrophage tropism is determined by utilization of this chemokine receptor. We observe that in addition to macrophage-tropic isolates of clades A, B, and E, macrophage-tropic isolates of clade F also utilize the CC-CKR5 molecule for entry. However, using single-round replication-competent reporter viruses carrying the envelope genes of T-cell line-tropic or macrophage-tropic phenotypic recombinant and mutant HIV-1 strains in infection of stable cell lines that coexpress the CD4 and chemokine receptors, we were unable to establish a strict correlation between macrophage tropism and utilization of the CC-CKR5 chemokine receptor. This latter finding suggests that a cofactor other than CC-CKR5 serves to determine entry into primary macrophages