The Duffy antigen/receptor for chemokines (DARC) is expressed in endothelial cells of Duffy negative individuals who lack the erythrocyte receptor

Molecular cloning of a novel T cell-directed CC chemokine expressed in thymus by signal sequence trap using Epstein-Barr virus vector

Precursors of most secreted and cell surface molecules carry signal sequences at their amino termini. Here we describe an efficient signal sequence trap method and isolation of a novel CC chemokine. An expression library was constructed by inserting 5' portion-enriched cDNAs from phytohemagglutinin-stimulated peripheral blood mononuclear cells into upstream of signal sequence-deleted CD4 cDNA in an Epstein-Barr virus shuttle vector. After electroporation into Raji cells, CD4 antigen-positive cells were enriched by repeated cell sorting and plasmids were recovered in Escherichia coli. Out of 100 plasmid clones examined, 42 clones directed expression of CD4 antigen on the cell surface. Among them were signal sequences of CD6, beta2-microglobulin, MGC-24, and T cell receptor epsilon-chain, and at least four novel potential signal sequences. A cDNA clone encoding a novel CC chemokine was isolated by using one of the trapped fragments. The gene designated as TARC from Thymus and Activation-Regulated Chemokine was expressed transiently in phytohemagglutinin-stimulated peripheral blood mononuclear cells and constitutively in thymus. Radiolabeled recombinant TARC specifically bound to T cell lines and peripheral T cells but not to monocytes or granulocytes. The binding of radiolabeled TARC to the high-affinity receptor (Kd, 2.1 nM) on Jurkat was displaced by TARC but not by interleukin-8, MIP-1alpha, RANTES, or MCP-1. TARC also bound to the promiscuous chemokine receptor on erythrocytes (Kd, 17 nM). TARC induced chemotaxis in T cell lines Hut78 and Hut102. Pretreatment of Hut78 with pertussis toxin abolished the TARC-induced cell migration. Collectively, T cells express a highly selective receptor for TARC that is coupled to pertussis toxin-sensitive G-protein. TARC may a factor playing important roles in T cell development in thymus as well as in trafficking and activation of mature T cells.

Identification of the Fy6 epitope recognized by two monoclonal antibodies in the N-terminal extracellular portion of the Duffy antigen receptor for chemokines

The epitope Fy6 recognized by two monoclonal antibodies (i3A and BG6), which inhibit binding of chemokines to the Duffy antigen, was characterized by means of peptides synthesized on pins (Epitope Scanning Kit) and deletion mutagenesis. Both antibodies showed very similar specificities. They recognized a linear epitope, the essential portion of which was the heptapeptide Gln-Leu-Asp-Phe-Glu-Asp-Val comprising amino acid residues 21-27, located between two glycosylation sites of the Duffy protein. All the amino acid residues of the epitope, except Glu, were essential for antibody binding, since they could not be replaced by any other amino acid residues or by only one or two. The Glu residue could be replaced by most other amino acid residues, and its replacement by 10 amino acid residues gave a distinct increase in the antibody binding. The results were in full agreement with the finding that the mutant of the Duffy antigen, lacking amino acid residues 23-25 (-Asp-Phe-Glu-), did not bind the i3A antibody, but bound the anti-Fy3 monoclonal antibody similarly to the wild type of the Duffy antigen. The apparent affinity constants of both anti-Fy6 antibodies were determined by surface plasmon resonance, using immunopurified Duffy protein as a ligand.

A dual-tropic primary HIV-1 isolate that uses fusin and the beta-chemokine receptors CKR-5, CKR-3, and CKR-2b as fusion cofactors

Here, we show that the beta-chemokine receptor CKR-5 serves as a cofactor for M-tropic HIV viruses. Expression of CKR-5 with CD4 enables nonpermissive cells to form syncytia with cells expressing M-tropic, but not T-tropic, HIV-1 env proteins. Expression of CKR-5 and CD4 enables entry of a M-tropic, but not a T-tropic, virus strain. A dual-tropic primary HIV-1 isolate (89.6) utilizes both Fusin and CKR-5 as entry cofactors. Cells expressing the 89.6 env protein form syncytia with QT6 cells expressing CD4 and either Fusin or CKR-5. The beta-chemokine receptors CKR-3 and CKR-2b support HIV-1 89.6 env-mediated syncytia formation but do not support fusion by any of the T-tropic or M-tropic strains tested. Our results suggest that the T-tropic viruses characteristic of disease progression may evolve from purely M-tropic viruses prevalent early in virus infection through changes in the env protein that enable the virus to use multiple entry cofactors.

Orchestrated information transfer underlying leukocyte endothelial interactions

The specificity and efficiency of leukocyte binding to endothelial cells (ECs) depends on coordinated information transfer from the underlying tissue to endothelium and from there to the leukocyte. We address three distinct information-transfer points in this system: 1, How does the leukocyte read information from the EC? This process is best accounted for by the paradigm of a multi-step adhesion cascade optimized for rapid information readout; it consists of primary adhesion (rolling/tethering), triggering, and strong adhesion. Recent studies with T cells, monocytes, and eosinophils confirm the generality of the paradigm. The concept of primary adhesion has been expanded to involve not only the selectins, but also certain integrins; furthermore, it depends on receptor concentration on leukocyte microvilli. 2. What information from the underlying tissue does the EC transform into signals for the leukocytes? And what rules govern that process? We illustrate the principles with chemokines, believed to participate in the triggering step. The endothelium displays chemokines either (a) directly by "posting" them from other cells or (b) by integrating a variety of tissue and environmental signals and "relaying" that information by producing its own chemokines and surface adhesion molecules. The rules for this endothelial transduction include specificity coupled with redundancy, amplification, synergy, and coordinated induction of ensembles of molecules. Finally, 3. How does the relevant information reach the endothelium? Simple diffusion is sufficient to deliver signals from cells close to the vessel. However, longer range soluble mediator transport appears to be facilitated by fiber bundles, particularly those ensheathed by fibroblastic reticular cells in the lymph node.

The promiscuous chemokine binding profile of the Duffy antigen/receptor for chemokines is primarily localized to sequences in the amino-terminal domain

The Duffy antigen (DARC) is a promiscuous chemokine receptor that also binds Plasmodium vivax. DARC belongs to a family of heptahelical chemokine receptors that includes specific (IL-8RA) and shared (IL-8RB) IL-8 receptors. Ligand binding specificity of IL-8 receptors was localized to the amino-terminal extracellular (E1) domain. To determine the basis for promiscuous chemokine binding by DARC, a chimeric receptor composed of the E1 domain of DARC and hydrophobic helices and loops from IL-8RB (DARCe1/IL-8RB) was constructed. Scatchard analysis of stable transfectants demonstrated that the DARCe1/IL-8RB chimeric receptor bound IL-8 and melanoma growth stimulating activity (MGSA) with KD values almost identical to the native receptors. The hybrid receptor also bound RANTES, MCP-1, and MGSA-E6A (which binds DARC, but not IL-8RB), but not MIP-1 alpha, similarly to DARC. Ligand binding to DARC transfectants was unaltered by anti-Fy3, but inhibited by Fy6, which binds an epitope in the E1 domain. The epitope recognized by Fy3 was localized to the third extracellular loop by analysis of insect cells expressing chimeric receptors composed of complementary portions of DARC and IL-8RB. These findings implicate the E1 domain of DARC in multispecific chemokine binding.

Distributions of melanoma growth stimulatory activity of growth-regulated gene and the interleukin-8 receptor B in human wound repair

The alpha-chemokines have been implicated as regulators of proliferation and differentiation of normal keratinocytes and as mediators of keratinocyte maturation and migration in inflammatory processes that involve the skin. Using the cutaneous wound repair model, we examined the sites and temporal sequence of the appearance of melanoma growth stimulatory activity or growth-regulated gene (MGSA/GRO;ligand) and the type B interleukin (IL)-8 receptor (IL-8RB) to which MGSA/GRO binds. Human burn tissues (n = 44) representing days 2 to 12 after injury were obtained during surgical debridement, fixed in 4% paraformaldehyde, and embedded in paraffin. Immunolocalizations were performed with polyclonal antisera for both ligand and receptor, as well as a monoclonal antibody for the IL-8 RB. Western blot analysis confirmed the presence of the IL-8 RB in immunoprecipitates of epidermal keratinocyte lysates. In normal skin, MGSA/GRO protein was restricted to sites populated by differentiated keratinocytes (suprabasal compartments, inner root sheath cells, and dermal sweat ducts). MGSA/GRO protein was barely detectable within epithelial margins and islands of burn wounds where the migrating/proliferating keratinocyte populations reside, but staining intensities increased as cells matured into the outer layers. Weak diffuse staining was detected in areas of neutrophilic infiltration (granulation tissue and overlying exudates). By contrast, in normal skin the IL-8 RB was detected in specific locations within epidermal and dermal compartments of healing wounds. In the dermis, polyvalent antibodies detected receptor immunoreactivity most prominently in dermal sweat ducts and endothelium of capillaries, whereas this immunoreactivity was inconspicuous in sections stained with the monoclonal antibody. Receptor immunostaining was noted in migrating/proliferating keratinocytes in epithelial margins and islands but was in the outer layers or in hypertrophic epidermis adjacent to wounds. This same pattern was observed in epidermal appendages such as hair follicles and eccrine sweat ducts. In granulation tissues, IL-8 RB was noted in numerous fibroblasts and in subpopulations of macrophages and smooth muscle. The presence of both MGSA/GRO and its receptor in human burn wounds implicate this cytokine as an autocrine or paracrine mediator of epidermal regeneration in both the inflammatory and proliferative phases of cutaneous wound repair.

Chemokine class differences in binding to the Duffy antigen-erythrocyte chemokine receptor

The Duffy blood group antigen-erythrocyte chemokine receptor has been shown to bind to chemokines of both the C-X-C and C-C classes and to the malarial parasites Plasmodium vivax and Plasmodium knowlesi. We performed experiments to evaluate the binding properties of this receptor for the newly appreciated "C" and "non-ELR C-X-C" classes of chemokines. Binding to mouse erythrocytes was also evaluated for the first time. Whereas ELR C-X-C and C-C chemokines bound to human erythrocytes with high affinity, differences in the ability of non-ELR chemokines to act as competitive inhibitors were noted. While non-ELR chemokines were unable to displace C-X-C chemokines on human cells, they exhibited a low affinity interaction with the C-C chemokine binding site. The newly discovered C chemokine, lymphotactin, was unable to displace either C-X-C or C-C chemokines. On mouse erythrocytes, non-ELR chemokines exhibited a low affinity for both the C-X-C and C-C chemokines binding sites; again lymphotactin failed to bind. Binding competition studies using an anti-Duffy monoclonal antibody and chemokines suggested a common binding domain. These data show that the chemokine superfamily has at least four functional subdivisions, each interacting differently with the Duffy antigen-erythrocyte chemokine receptor. In addition the chemokine binding function is conserved between mouse and man. Unlike other proteins in the superfamily C and non-ELR C-X-C chemokines do not efficiently bind red blood cells, thus their role may not require clearance from circulation.

Chemokines, a family of chemotactic cytokines

Chemokines are low-molecular-weight proteins that stimulate recruitment of leukocytes. They are secondary pro-inflammatory mediators that are induced by primary pro-inflammatory mediators such as interleukin-1 (IL-1) or tumor necrosis factor (TNF). The physiologic importance of this family of mediators is derived from their specificity. Unlike the classic leukocyte chemo-attractants, which have little specificity, members of the chemokine family induce recruitment of well-defined leukocyte subsets. Thus, chemokine expression can account for the presence of different types of leukocytes observed in various normal or pathologic states. There are two major chemokine sub-families based upon the position of cysteine residues, i.e., CXC and CC. All members of the CXC chemokine sub-family have an intervening amino acid between the first two cysteines; members of the CC chemokine sub-family have two adjacent cysteines. As a general rule (with some notable exceptions), members of the CXC chemokines are chemotactic for neutrophils, and CC chemokines are chemotactic for monocytes and a small sub-set of lymphocytes. This review discusses the potential role of chemokines in inflammation and focuses on the two best-characterized chemokines, monocyte chemoattractant protein-1 (MCP-1), a CC chemokine, and interleukin-8 (IL-8), a member of the CXC chemokine sub-family.

Duffy and receptors for P. vivax and chemotactic peptides

The Duffy blood group system consists of two principal antigens, Fya and Fyb produced by FY*A and FY*B co-dominant alleles. Antisera, anti-Fya and anti-Fyb, define four phenotypes: Fy(a+b-), Fy(a-b+), Fy(a+b+) and Fy(a-b-). Neither antiserum agglutinates Fy(a-b-) cells, the predominant phenotype in Blacks. Outside the Black population, Fy(a-b-) phenotype is very rare. Duffy antigens appear to be multimeric erythrocyte-membrane proteins composed of different subunits. A glycoprotein of 35-45 kDa, gp-Fy, is the major subunit of the complex and has antigenic determinants defined by Duffy antibodies. The protein consists of 337 amino acid residues with a M(r) of 35,733, the same as deglycosylated gp-Fy. The hydropathy map predicts an exocellular N-terminal domain of 64 residues, nine transmembrane alpha-helices, three short protruding hydrophilic loops and an endocellular C-terminal domain of 23 residues. Duffy specific transcript, a approximately 1.3 kb mRNA, is produced by the bone marrow of Duffy-positive individuals, but it is not produced by the bone marrow of Duffy-negative individuals. The same size mRNA is produced in many tissues of Duffy-positive individuals. The same tissues of Duffy-negative individuals also synthesize the same size mRNA and the same gp-Fy as that of Duffy-positive individuals. There is not, therefore, Duffy null phenotype in the Black population. The difference between FY*A and FY*B alleles is a single nucleotide change at position 306; guanine is in FY*A, and adenine is in FY*B.(ABSTRACT TRUNCATED AT 250 WORDS)