Modulation of natural killer cell cytotoxicity and cytokine release by the drug glatiramer acetate.

Glatiramer acetate (GA or Copaxone) is a drug used to treat experimental autoimmune encephalomyelitis in mice and multiple sclerosis in human. Here, we describe a new mechanism of action for this drug. GA enhanced the cytolysis of human NK cells against autologous and allogeneic immature and mature monocyte-derived dendritic cells (DCs). This drug reduced the percentages of mature DCs expressing CD80, CD83, HLA-DR or HLA-I. In contrast, it did not modulate the percentages of NK cells expressing NKG2D, NKp30, or NKp44. Nonetheless, anti-NKp30 or anti-CD86 inhibited GA-enhanced human NK cell lysis of immature DCs. Hence, CD86, and NKp30 are important for NK cell lysis of immature DCs, whereas CD80, CD83, HLA-DR and HLA-I are important for the lysis of mature DCs when GA is used as a stimulus. Further, GA inhibited the release of IFN-gamma 24 h but increased the release of TNF-alpha 48 h after incubation with NK cells.

Expression and regulation of chemokine receptors in human natural killer cells.

Using flow cytometric and RNase protection assays, this study examined the expression of chemokine receptors in nonactivated natural killer (NK) cells and compared this expression with NK cells activated with interleukin (IL)-2, which either adhered to plastic flasks (AD) or did not adhere (NA). None of the NK cell subsets expressed CXCR2, CXCR5, or CCR5. The major differences between these cells include increased expression of CXCR1, CCR1, CCR2, CCR4, CCR8, and CX(3)CR1 in AD when compared to NA or nonactivated NK cells. The chemotactic response to the CXC and CC chemokines correlated with the receptor expression except that all 3 populations responded to GRO-alpha, despite their lack of CXCR2 expression. Pretreatment of these cells with anti-CXCR2 did not inhibit the chemotactic response to GRO-alpha. In addition, nonactivated and NA cells responded to fractalkine, although they lack the expression of CX(3)CR1. This activity was not inhibited by anti-CX(3)CR1. Viral macrophage inflammatory protein (vMIP)-I, I-309, and TARC competed with the binding of (125)I-309 to AD cells with varying affinities. Transforming growth factor (TGF)-beta1 but not any other cytokine or chemokine examined including interferon (IFN)-gamma, MIP-3beta, macrophage-derived chemokine (MDC), thymus and activation-regulated chemokine (TARC) or I-309, up-regulated the expression of CXCR3 and CXCR4 on NK cell surface. This is correlated with increased chemotaxis of NK cells treated with TGF-beta1 toward stromal cell-derived factor (SDF)-1alpha and interferon-inducible protein-10 (IP-10). Messenger RNA for lymphotactin, RANTES, MIP-1alpha, and MIP-1beta, but not IP-10, monocyte chemotactic protein (MCP)-1, IL-8, or I-309 was expressed in all 3 NK cell subsets. Our results may have implications for the dissemination of NK cells at the sites of tumor growth or viral replication. (Blood. 2001;97:367-375)

Intracellular signaling events at the leading edge of migrating cells.

Cell migration is an important facet of the life cycle of immune and other cell types. A complex set of events must take place at the leading edge of motile cells before these cells can migrate. Chemokines induce the motility of various cell types by activating multiple intracellular signaling pathways. These include the activation of chemokine receptors, which are coupled to the heterotrimeric G proteins. The release of G beta gamma subunits from chemokine receptors results in the recruitment to the plasma membrane, with subsequent activation of various down-stream signaling molecules. Among these molecules are the pleckstrin homology domain-containing proteins and the phosphoinositide 3-kinase gamma which phosphorylates phospholipids and activates members of the GTP exchange factors (GEFs). These GEFs facilitate the exchange of GTP for GDP in members of GTPases. The latter are important for reorganizing the cell cytoskeleton, and in inducing chemotaxis. Chemokines also induce the mobilization of intracellular calcium from intracellular stores. Second messengers such as inositol 1,4,5 trisphosphate, and cyclic adenosine diphosphate ribose are among those induced by chemokines. In addition, the G beta gamma subunits recruit members of the G protein-coupled receptor kinases, which phosphorylate chemokine receptors, resulting in desensitization and termination of the motility signals. This review will discuss the intracellular signaling pathways induced by chemokines, particularly those activated at the leading edge of migrating cells which lead to cell polarization, cytoskeleton reorganization and motility.

Chemokines, G proteins and natural killer cells.

Natural killer (NK) cells are anti-tumor and anti-viral effector cells. Members of C, CC, CXC and CX3C chemokines induce the chemotaxis and enhance the cytotoxicity of NK cells, suggesting that these cells express receptors for chemokines. The ability of members of chemokines to inhibit the replication of HIV-1 strains, combined with the ability of the same chemokines to activate the anti-viral NK cells, provide compelling evidence for the role of NK cells in eradicating HIV-1 infection. In addition, chemokines induce various intracellular signaling pathways in NK cells, which include activation of the heterotrimeric, and perhaps the small guanine nucleotide binding (G) proteins, as well as the mobilization of intracellular calcium, among other activities. Further, chemokines induce the phosphorylation of chemokine receptors through the recruitment of G protein-coupled receptor kinases (GRKs) resulting in the desensitization and turning off the signals. In this review, I will update the knowledge of the effect of chemokines on NK cell motility and the signal transduction pathways induced by chemokines in these cells.

Human NK cells express CC chemokine receptors 4 and 8 and respond to thymus and activation-regulated chemokine, macrophage-derived chemokine, and I-309.

NK cells respond to various chemokines, suggesting that they express receptors for these chemokines. In this paper, we show that IL-2-activated NK (IANK) cells express CC chemokine receptor 4 (CCR4) and CCR8, as determined by flow cytometric, immunoblot, and RNase protection assays. Macrophage-derived chemokine (MDC), the ligand for CCR4, induces the phosphorylation of CCR4 within 0.5 min of activating IANK cells with this ligand. This is corroborated with the recruitment of G protein-coupled receptor kinases 2 and 3 and their association with CCR4 in IANK cell membranes. Also, CCR4 is internalized between 5 and 45 min but reappears in the membranes after 60 min of stimulation with MDC. MDC, thymus and activation-regulated chemokine (TARC), and I-309 induce the chemotaxis of IANK cells, an activity that is inhibited upon pretreatment of these cells with pertussis toxin, suggesting that receptors for these chemokines are coupled to pertussis toxin-sensitive G proteins. In the calcium release assay, cross-desensitization experiments showed that TARC completely desensitizes the calcium flux response induced by MDC or I-309, whereas both MDC and I-309 partially desensitize the calcium flux response induced by TARC. These results suggest that TARC utilizes CCR4 and CCR8. Our results are the first to show that IL-2-activated NK cells express CCR4 and CCR8, suggesting that these receptors are not exclusive for Th2 cells.

Differential utilization of cyclic ADP-ribose pathway by chemokines to induce the mobilization of intracellular calcium in NK cells.

We show here that cyclic adenosine diphosphate-ribose (cADPR) may be a second messenger for chemokines. Extracts collected from NK cells stimulated with IL-8 for 2 min were incubated with beta-NAD for an additional 2 min (designated as IL-8 extracts). This mixture elevated the mobilization of (Ca(2+))(i) in alpha-toxin permeabilized NK cells. This activity was inhibited upon prior incubation of these cells with ruthenium red but not with heparin. Purified cADPR and not Ins 1,4,5 P(3) desensitized NK cells to the calcium mobilization effect of IL-8 extracts. Further analysis showed that ruthenium red and heparin differentially inhibit RANTES-, SDF-1alpha-, or MDC-induced calcium mobilization in IL-2-activated NK cells. Also, introduction of anti-ryanodine receptor antibody inside streptolysin O-permeabilized NK cells resulted in complete inhibition of MDC, and only partial inhibition of RANTES and SDF-1alpha-induced calcium fluxes in NK cells. Collectively, these results suggest that chemokines may utilize the cADPR/ryanodine receptor pathway as well as the Ins 1,4,5 P(3)/Ins 1,4,5 P(3) receptor signaling pathway to induce the accumulation of calcium in NK cells.

Intracellular signalling pathways induced by chemokines in natural killer cells.

Chemokines are small peptides involved in the recruitment of various cell types into inflammatory sites. They are divided into four sub-families depending on the presence of amino acids separating the cysteine residues in their N-terminal region. These are the alpha (CXC), beta (CC), gamma (C) and delta (CX)C) chemokines. In addition, five CXC chemokine (CXCR1-5), nine CC chemokine (CCR1-9), one C chemokine (XCR1) and one C-X3C chemokine (CX3CR1) receptors have been identified. These receptors belong to the seven transmembrane spanning domain family, and are coupled to the heterotrimeric guanine nucleotide binding (G) proteins. Chemokines activate various immune cells, and in particular the anti-viral/anti-tumour effectors, the natural killer (NK) cells by activating members of the heterotrimeric G proteins. The importance of the family of chemokines is highlighted by the ability of its members to inhibit the replication of HIV-1 strains in CD4+ cells, where chemokine receptors act as HIV-1 co-receptors. This review discusses the intracellular signalling pathways induced by chemokines in NK and other cell types, and the relationships to HIV-1 signalling in these cells.

Recruitment of pleckstrin and phosphoinositide 3-kinase gamma into the cell membranes, and their association with G beta gamma after activation of NK cells with chemokines.

The role of phosphoinositide 3 kinases (PI 3-K) in chemokine-induced NK cell chemotaxis was investigated. Pretreatment of NK cells with wortmannin inhibits the in vitro chemotaxis of NK cells induced by lymphotactin, monocyte-chemoattractant protein-1, RANTES, IFN-inducible protein-10, or stromal-derived factor-1 alpha. Introduction of inhibitory Abs to PI 3-K gamma but not to PI 3-K alpha into streptolysin O-permeabilized NK cells also inhibits chemokine-induced NK cell chemotaxis. Biochemical analysis showed that within 2-3 min of activating NK cells, pleckstrin is recruited into NK cell membranes, whereas PI 3-K gamma associates with these membranes 5 min after stimulation with RANTES. Recruited PI 3-K gamma generates phosphatidylinositol 3,4,5 trisphosphate, an activity that is inhibited upon pretreatment of NK cells with wortmannin. Further analysis showed that a ternary complex containing the beta gamma dimer of G protein, pleckstrin, and PI 3-K gamma is formed in NK cell membranes after activation with RANTES. The recruitment of pleckstrin and PI 3-K gamma into NK cell membranes is only partially inhibited by pertussis toxin, suggesting that the majority of these molecules form a complex with pertussis toxin-insensitive G proteins. Our results may have application for the migration of NK cells toward the sites of inflammation.

Chemokines activate natural killer cells through heterotrimeric G-proteins: implications for the treatment of AIDS and cancer.

Natural killer (NK) cells are anti-tumor and anti-viral effector cells. These cells show increased cytolytic activity upon stimulation with interleukin 2 or chemokines. In addition, members of the C, CC, CXC, or CX3C chemokines induce the in vitro chemotaxis of NK cells and contribute to their in vivo tissue accumulation. Chemokines induce various intracellular signaling pathways in NK cells by activating members of the heterotrimeric G-proteins. Understanding these pathways should provide an insight into NK cell activation, in vivo distribution, and tissue localization. Based on evidence showing the high lytic activity of these effector cells against transformed or virally infected cells, it is suggested that NK cells can be used to maximize the immunotherapeutic protocols for AIDS and cancer patients.

MIP-3alpha, MIP-3beta and fractalkine induce the locomotion and the mobilization of intracellular calcium, and activate the heterotrimeric G proteins in human natural killer cells.

We demonstrate here that the CC chemokines macrophage inflammatory protein-3alpha (MIP-3alpha), macrophage inflammatory protein-3beta (MIP-3beta) and the CX3C chemokine fractalkine induce the chemotaxis of interleukin-2 (IL-2)-activated natural killer (IANK) cells. In addition, these chemokines enhance the binding of [gamma-35S]guanine triphosphate ([gamma-35S]GTP) to IANK cell membranes, suggesting that receptors for these chemokines are G protein-coupled. Our results show that MIP-3alpha receptors are coupled to Go, Gq and Gz, MIP-3beta receptors are coupled to Gi, Gq and Gs, whereas fractalkine receptors are coupled to Gi, and Gz. All three chemokines induced a robust calcium response flux in IANK cells. Cross-desensitization experiments show that MIP-3alpha, MIP-3beta or fractalkine use receptors not shared by each other or by the CC chemokine regulated on activation, normal, T-cell expressed, and secreted (RANTES), the CXC chemokines stromal-derived factor-1alpha (SDF-1alpha) and interferon-inducible protein-10 (IP-10), or the C chemokine lymphotactin.

Interferon-inducible protein-10 and lymphotactin induce the chemotaxis and mobilization of intracellular calcium in natural killer cells through pertussis toxin-sensitive and -insensitive heterotrimeric G-proteins.

We show here that interferon-inducible protein-10 (IP-10), an ELR lacking CXC chemokine, and the C chemokine lymphotactin (Ltn) induce the chemotaxis and calcium mobilization in IL2-activated NK (IANK) and CC chemokine-activated NK (CHAK) cells. Cross-desensitization experiments show that IP-10 or Ltn use receptors not shared by other C, CC, or CXC chemokines. The chemotaxis induced by either IP-10 or Ltn for both cell types is inhibited upon pretreatment of these cells with pertussis toxin (PT). Also, Ltn-induced [Ca2+]i in IANK but not in CHAK cells is inhibited upon pretreatment with PT, whereas IP-10-induced [Ca2+]i in IANK and CHAK cells is inhibited upon pretreatment with this toxin. These results suggest important roles for PT-sensitive and -insensitive G-proteins in IP-10-induced and Ltn-induced chemotaxis and calcium fluxes in activated NK cells. This was further implicated after streptolysin O permeabilization of CHAK and IANK cells and after introduction of inhibitory antibodies to the PT-sensitive Gi and Go or the PT-insensitive Gq. Our results suggest that IP-10 and Ltn receptors are coupled to Gi, Go, and Gq in IANK cells and to Gi and Gq in CHAK cells, with a possible low coupling of IP-10, but not of Ltn, receptors to Go in these cells. Together, these results show that IP-10 and Ltn-dependent chemotaxis and calcium mobilization may differentiate at the level of receptor coupling to the heterotrimeric G-proteins.

Role of the heterotrimeric G proteins in stromal-derived factor-1alpha-induced natural killer cell chemotaxis and calcium mobilization.

The CXC chemokine stromal derived factor-1alpha (SDF-1alpha) induces both the chemotaxis and calcium mobilization in IL-2-activated NK (IANK) cells. The ability of SDF-1alpha to induce IANK cell chemotaxis is inhibited upon incorporating antibodies to the alpha subunit of Go and Gq but not Gi, Gs, or Gz, whereas (Ca++)i mobilization is inhibited with anti-Go, [corrected] anti-Gq and anti-Gs, but not with any other anti-G proteins examined. Further analysis showed that antibody to phospholipase C (PLC)beta but not PLCgamma inhibited SDF-1alpha-induced (Ca++)i mobilization, suggesting that this signal is mediated by G protein coupled receptor and not by tyrosine kinase receptors. Our results are the first to show that SDF-1alpha is chemoattractant for NK cells, and that this effect is coupled to G proteins.

Cloning, functional activities and in vivo tissue distribution of rat NKR-P1+ TCR alpha beta + cells.

We have successfully cloned nine NKR-P1+ TCR alpha beta + cells from PVG rat spleens, utilizing murine macrophage inflammatory protein-1 alpha (MIP-1 alpha) and IL-2. These clones are either double negative (DN, CD4-CD8-), which included clones 3.31, 3.71, 4.19, 4.59 and 4.65, or single positive (SP, CD4+CD8-), which included clones 1.64, 3.8, 3.76 and 3.78. No CD8+ clone was recovered. All nine clones are restricted in terms of their expression of the V beta antigens, since they express V beta 8.2 but not V beta 8.5, V beta 10 or V beta 16. These clones are agranular and they fall to generate NK or LAK activity upon incubation with IL-2, IL-12 or their combination. On the basis of their production of intracellular cytokines they can be divided into three categories: (I) SP clones (1.64, 3.8, 3.76 and 3.78) do not produce IL-2 or IL-4, but produce IFN-gamma and IL-12, and they vary in their production of IL-1, RANTES or tumor necrosis factor (TNF)-alpha; (II) DN clones 4.59 and 4.65 produce IL-1 alpha and IFN-gamma only, and fall to produce other cytokines; and (III) DN clones 3.31, 3.71 and 4.19 produce IL-1 alpha, IL-1 beta, IL-2, IL-12, IFN-gamma, RANTES and TNF-alpha. From all the clones examined only DN clones 3.31 and to a lesser degree 4.19 produce IL-4. In vivo tissue localization of clones 3.8, 3.31 and 4.59 shows that these cells distribute into the liver and bone marrow 24 h post i.v. administration. Their accumulation in the liver and bone marrow along with their ability to secrete various cytokines suggest that these cells may influence the generation, differentiation or apoptosis of immune or hematopoietic cells.

Elevated expression of endothelin-1 and endothelin-converting enzyme-1 in idiopathic pulmonary fibrosis: possible involvement of proinflammatory cytokines.

Endothelin-1 (ET-1) is a vasoconstrictor, bronchoconstrictor, and mitogenic peptide which is enzymatically converted from a biologically inactive big ET to mature ET (21 amino acid) by the ET-converting enzyme (ECE). Here, we investigate the expression of ECE-1, big ET-1, and ET-1 in the lungs of patients with idiopathic pulmonary fibrosis (IPF) and compare it to those of normal subjects using immunohistochemistry and in situ hybridization. In normal lungs, focal moderate expression of all three molecules is localized to airway epithelium, pulmonary endothelium, and airway and vascular smooth muscle cells. Serous bronchial glands also expressed ET-1 and ECE-1. In IPF, strong diffuse expression of ECE-1 was seen in airway epithelium, proliferating type II pneumocytes, and in endothelial and inflammatory cells. ECE-1 immunostaining was colocalized to big ET-1 and ET-1 immunostaining, and correlated with disease activity (P < 0.05). To study regulatory mechanisms of ET-1 and ECE-1 expression, human normal bronchial epithelial (NBE) cells were treated with cytokines and analyzed by radioimmunoassay and Northern blot. Incubation of human NBE cells with IL-1alpha and -beta or tumor necrosis factor alpha (TNFalpha) resulted in a significant increase in ET-1 release and mRNA expression. TNFalpha resulted in a significant increase in ECE-1 mRNA expression. These findings demonstrated the colocalization of the precursor and active ET-1, and ECE-1 in the same cell, and that ECE-1 expression is elevated in IPF. In addition, increased expression of ET-1 and ECE-1 in IPF may be mediated by proinflammatory cytokines.

Functional coupling of NKR-P1 receptors to various heterotrimeric G proteins in rat interleukin-2-activated natural killer cells.

NKR-P1 molecules constitute a family of type II membrane receptors in natural killer (NK) cells that preferentially activate NK cell killing and release of interferon-gamma from these cells. Here, we demonstrate that anti-NKR-P1 enhances GTP binding in rat interleukin-2-activated NK cell membranes; GTP binding to Gi3alpha, Gsalpha, Gq,11alpha, and Gzalpha increased noticeably in these cell membranes after treatment with anti-NKR-P1. Western blot analysis of membrane proteins prepared from interleukin-2-activated NK cells reveals the presence of Gi1,2alpha, Gi3alpha, Goalpha, Gsalpha, Gq, 11alpha, Gzalpha, and G12alpha, but not G13alpha. However, only alphai3, alphas, alphaq,11, and alphaz, but not alphai1,2, alphao, alpha12, or alpha13 subunits when immunoprecipitated with the appropriate anti-G protein antibodies, are associated with NKR-P1 when immunoblotted with anti-NKR-P1. Reciprocally, NKR-P1 immunoprecipitated with anti-NKR-P1 is associated with alphai3, alphas, alphaq,11, and alphaz immunoblotted with anti-G proteins. These results are the first to demonstrate the physical and functional coupling of NKR-P1 to the heterotrimeric G proteins in NK cells.

Preferential involvement of Go and Gz proteins in mediating rat natural killer cell lysis of allogeneic and tumor target cells.

IL-2-activated NK cells from PVG rats potently lyse target cells expressing allo-MHC class I determinants. Here, we investigated the role that G proteins play in mediating this activity. Pretreatment of NK cells with pertussis toxin (PT) or cholera toxin (CT) inhibited NK cell killing of tumor (YAC-1 or P815), and allogeneic target cells. ADP ribosylation assay revealed that PT ADP ribosylates a 39-kDa G protein, whereas CT ADP ribosylates a 45 to 47-kDa G protein in PVG NK cell membranes. Membranes prepared from intoxicated NK cells with either PT or CT lost their ability to incorporate [32P]NAD. These membranes possess Gi, Go, Gs, and Gz as demonstrated by immunoblot analysis. However, Gq was not clearly detected by this method. IL-2-activated NK cells were permeabilized with streptolysin O. Permeabilized cells incorporated Abs to Gi, Go, Gz, Gs, and Gq as determined by flow cytometric analysis. When Abs to Go or Gz, but not to Gi, Gs, or Gq, were incorporated inside permeabilized NK cells, a significant reduction in the lysis of tumor or allo-MHC target cells was observed, suggesting that Go and Gz play important roles in transducing the signals necessary to lyse target cells. Our results show for the first time a role for G proteins in mediating NK cell killing of allo-MHC-encoded target cells, and provide evidence for Gz protein involvement in NK cell recognition of target cells. The effect of Gz is novel and has not been previously described in any other system or cell type.

Differential coupling of CC chemokine receptors to multiple heterotrimeric G proteins in human interleukin-2-activated natural killer cells.

Using two different approaches, we have investigated the types of G proteins coupled to CC chemokine receptors. First, permeabilization of interleukin-2-activated natural killer (IANK) cells with streptolysin-O and introduction of anti-G protein antibodies inside these cells resulted in the following. (1) Anti-G(s), anti-G(o), and anti-G(z) inhibited the migration of IANK cells in response to macrophage-inflammatory protein-1 alpha (MIP-1 alpha), monocyte chemoattractant protein-1 (MCP-1), or regulated on activation normal T cell expressed and secreted (RANTES). (2) Anti-Gi inhibited their migration in response to MCP-1 or RANTES but not in response to MIP-1 alpha. Second, incubation of IANK cell membranes with anti-G protein antibodies before incubating with (gamma-35S) GTP or (gamma-32P) GTP, resulted in the following. (1) Anti-G(s), anti-G(o), or anti-G(z) inhibited GTP binding and GTPase activity in the presence of MIP-1 alpha, or RANTES. (2) Anti-G(i) inhibited GTP binding and GTPase activity in the presence of MCP-1 or RANTES but not in the presence of MIP-1 alpha. The inhibitory effect of anti-G protein antibodies was reversed upon incubating these antibodies with their respective synthetic peptides before addition to IANK cell membranes. These results suggest that MCP-1 and RANTES receptors are promiscuously coupled to multiple G proteins in IANK cell membranes and that this coupling is different from MIP-1 alpha receptors, which seem to be coupled to G(s), G(o), and G(z) but not to G(i).

CC chemokines induce the generation of killer cells from CD56+ cells.

We describe here that members of the CC chemokines exhibit biological activities other than chemotaxis. Macrophage inflammatory protein (MIP)-1 alpha, MIP-1 beta, monocyte chemoattractant protein-1 and RANTES, but not interleukin (IL)-8, induce the generation of cytolytic cells, designated here as CHAK (CC chemokine-activated killer) cells to distinguish them from IL-2-activated (LAK) cells. Like IL-2, CC chemokines can induce the proliferation and activation of killer cells. While incubating CC chemokines with CD4+ or CD8+ cells did not generate CHAK activity, all CC chemokines were capable of inducing CHAK activity upon incubating with CD56+ cells, suggesting that the primary effectors are NK cells. However, the presence of other cell types, such as CD4+ or CD8+, are necessary to induce the proliferation of CD56+ cells. Confirming the involvement of T cell-derived factors in inducing the proliferation of these cells, anti-IL-2 and anti-interferon-gamma, but not anti-IL-1 beta, anti-tumor necrosis factor-alpha, anti-IL-8, or anti-granulocyte/monocyte-colony-stimulating factor inhibited RANTES-induced proliferation of nylon wool column-nonadherent cells. Our results may have important clinical applications for the utilization of CHAK cells in the treatment of cancer and immunodeficient patients.

C-C chemokines induce the chemotaxis of NK and IL-2-activated NK cells. Role for G proteins.

The C-C chemokines MIP-1 alpha, MCP-1, and RANTES, but not MIP-1 beta, induce the chemotaxis of NK and IL-2-activated NK (IANK) cells, as determined in microchemotaxis assay. Only RANTES and MCP-1, but not MIP-1 alpha were able to induce the chemokinesis of NK cells. In contrast, none of the C-C chemokines tested was able to induce the chemokinesis of IANK cells. IANK cell chemotaxis in response to MCP-1 or RANTES but not MIP-1 alpha, was inhibited by pertussis toxin (PT). In contrast, cholera toxin (CT) inhibited the ability of all three chemokines to induce the chemotaxis of IANK cells. IANK cells intoxicated with PT lost their ability to migrate in response to RANTES and MCP-1 but not MIP-1 alpha, whereas those intoxicated with CT lost their ability to migrate in response to the three C-C chemokines tested. These results suggest that guanine nucleotide binding (G) proteins are coupled to C-C chemokine receptors in IANK cells. Subsequently, we observed that MIP-1 alpha, MCP-1, and RANTES, but not MIP-1 beta, enhance the binding of guanosine 5'-O-(thiotriphosphate), and increase the hydrolysis of [32P]GTP in IANK cell membranes. Further analysis showed that MIP-1 alpha, RANTES, or MCP-1 did not enhance GTP binding in membranes prepared from IANK cells intoxicated with CT, whereas only RANTES and MCP-1 but not MIP-1 alpha lost their ability to enhance GTP binding to IANK cell membranes prepared from PT-intoxicated cells. The differential inhibitory activity of CT and PT suggests that C-C chemokine receptors are coupled to different G proteins in IANK cells.