Nuclear localization of the tyrosine kinase Itk and interaction of its SH3 domain with karyopherin alpha (Rch1alpha).

We report a physical and functional association between the Tec-family tyrosine kinase Itk (Emt/Tsk) and the nuclear import chaperone karyopherin alpha (Rch1alpha) in human T cells. The Itk-SH3 domain and the Rch1alpha proline-rich (PR) motif were crucial for the Itk/Rch1alpha constitutive interaction as demonstrated by directed mutagenesis of the Rch1alpha PR motif (proline 242 to alanine, P242A). TCR-CD3 stimulation of Jurkat T cells resulted in increased Itk/Rch1alpha complex formation, recruitment of karyopherin beta to the protein complex and Rch1alpha tyrosine phosphorylation. Analysis of in vitro kinase reactions with a panel of recombinant glutathione-S-transferase (GST) fusion tyrosine kinases (Itk, Lck, ZAP-70 and Jak3) revealed that only GST-Itk efficiently phosphorylated a recombinant GST-Rch1alpha fusion. We observed constitutive nuclear localization of Itk that was up-regulated following either TCR-CD3 stimulation or over-expression of wild-type Rch1alpha in T cells. Further, nuclear localization of Itk and TCR-CD3-mediated IL-2 production were significantly down-regulated following expression of the Rch1alpha-P242A mutant, implicating a role for Rch1alpha in the nuclear translocation of Itk.

Engagement of the T lymphocyte antigen receptor regulates association of son-of-sevenless homologues with the SH3 domain of phospholipase Cgamma1.

One mechanism for transducing signals downstream of lymphocyte receptor activation involves the stable association between signaling proteins. To identify protein ligands of the signal activator phospholipase Cgamma1 (PLCgamma1), we screened T cell cDNA libraries with the PLCgamma1-SH3 domain by the yeast two-hybrid assay. We observed association between the PLCgamma1-SH3 domain and the human Ras guanine nucleotide exchange factor son-of-sevenless-2 (hSos2) through a proline-rich domain interaction. Stable and abundant hSos2 / PLCgamma1 and hSos1 / PLCgamma1 complexes were observed in unstimulated T cells. The interaction between these enzymes was augmented following engagement of the T cell antigen receptor (TCR / CD3). The kinetics of protein complex enhancement correlated with TCR / CD3-induced tyrosine phosphorylation of PLCgamma1; however, those PLCgamma1 molecules in complex with hSos2 were non-phosphorylated after TCR / CD3 stimulation, in contrast to the phosphorylated PLCgamma1 associated with the linker for activation of T cells, LAT. The Grb2 adapter protein was detected in complex with hSos / PLCgamma1, suggesting a regulatory role for Grb2. SH3 domains from both Grb2 and PLCgamma1, but not RasGAP, bound directly to hSos homologues. The SH2 domain from Grb2 formed an association with the hSos / PLCgamma1 complex, which was enhanced following TCR / CD3 ligation. Together, the data suggest a mechanism for the son-of-sevenless and PLCgamma1 signal transducing enzymes in recruitment to protein complexes with potentially differential signaling consequences in T lymphocytes.

Regulated association between the tyrosine kinase Emt/Itk/Tsk and phospholipase-C gamma 1 in human T lymphocytes.

The Emt/Itk/Tsk tyrosine kinase is involved in intracellular signaling events induced by several lymphocyte surface receptors. Modulation of TCR/CD3-induced phospholipase-C gamma 1 (PLC gamma 1) activity by the tyrosine kinase Emt/Itk/Tsk has been demonstrated based on studies of Itk-deficient murine T lymphocytes. Here we report a TCR/CD3-regulated association between Emt and PLC gamma 1 in both normal and leukemic T cells. In addition, this association was enhanced following independent ligation of the CD2, CD4, or CD28 costimulatory molecules, but not of CD5 or CD6 surface receptors, correlating to the induced tyrosine phosphorylation of Emt. Before Ab-induced T cell activation, we found that the Emt-SH3 domain was crucial for the constitutive Emt/PLC gamma 1 association; however, upon TCR/CD3 engagement, the Emt-SH2 domain was more efficient in mediating the enhanced Emt/PLC gamma 1 interaction. Furthermore, the PLC gamma 1-SH3 domain, but not the two PLC gamma 1-SH2 domains, contributed to formation of the protein complex. Thus, we describe a regulated interaction between Emt and PLC gamma 1, and based on our studies with individual Emt and PLC gamma 1 SH2/SH3 domains, we propose a mechanism for this association.

CD5 negatively regulates the T-cell antigen receptor signal transduction pathway: involvement of SH2-containing phosphotyrosine phosphatase SHP-1.

The negative regulation of T- or B-cell antigen receptor signaling by CD5 was proposed based on studies of thymocytes and peritoneal B-1a cells from CD5-deficient mice. Here, we show that CD5 is constitutively associated with phosphotyrosine phosphatase activity in Jurkat T cells. CD5 was found associated with the Src homology 2 (SH2) domain containing hematopoietic phosphotyrosine phosphatase SHP-1 in both Jurkat cells and normal phytohemagglutinin-expanded T lymphoblasts. This interaction was increased upon T-cell receptor (TCR)-CD3 cell stimulation. CD5 co-cross-linking with the TCR-CD3 complex down-regulated the TCR-CD3-increased Ca2+ mobilization in Jurkat cells. In addition, stimulation of Jurkat cells or normal phytohemagglutinin-expanded T lymphoblasts through TCR-CD3 induced rapid tyrosine phosphorylation of several protein substrates, which was substantially diminished after CD5 cross-linking. The CD5-regulated substrates included CD3zeta, ZAP-70, Syk, and phospholipase Cgammal but not the Src family tyrosine kinase p56(lck). By mutation of all four CD5 intracellular tyrosine residues to phenylalanine, we found the membrane-proximal tyrosine at position 378, which is located in an immunoreceptor tyrosine-based inhibitory (ITIM)-like motif, crucial for SHP-1 association. The F378 point mutation ablated both SHP-1 binding and the down-regulating activity of CD5 during TCR-CD3 stimulation. These results suggest a critical role of the CD5 ITIM-like motif, which by binding to SHP-1 mediates the down-regulatory activity of this receptor.

Roles of chemokines and receptor polarization in NK-target cell interactions.

We report that the ability of NK cells to produce chemokines is increased in NK-target cell conjugates. The chemokines produced play a critical role in the polarization and recruitment of NK cells as well as in the NK effector-target cell conjugate formation. Chemokines induce the formation of two specialized regions in the NK cell: the advancing front or leading edge, where chemokine receptors CCR2 and CCR5 cluster, which might guide the cells toward the chemotactic source, and the uropod, where adhesion molecules ICAM-1 and -3 are redistributed. NK cell polarity was intrinsically involved in conjugate formation. The redistribution of both adhesion receptors and CCR was preserved during the formation of NK-target cell conjugates. Time-lapse videomicroscopy studies of the formation of effector-target conjugates showed that morphologic poles are also functionally distinct; while the binding to target cells was preferentially mediated through the leading edge, the uropod was found at the rear of migrating NK cells and recruited additional NK cells to the vicinity of K562 target cells. Inhibition of cell polarization and adhesion receptor redistribution blocked the formation of NK-K562 cell conjugates and the cytotoxic activity of NK cells. We discuss the implication of NK-cell polarization in the development of cytotoxic responses.

The CD94/NKG2-A inhibitory receptor complex is involved in natural killer cell-mediated recognition of cells expressing HLA-G1.

Human NK cells bear surface receptors that inhibit their cytolytic activity upon specific recognition of MHC class Ia Ags; little is known about the capacity of class Ib molecules to regulate NK cell function. We have studied the roles of different NK inhibitory receptors in recognition of the class Ib HLA-G. To this end, we analyzed the ability of an HLA-defective tumor cell line (721.221) transfected with the membrane form of HLA-G1, which contains the three external domains, to inhibit the cytolytic activity mediated by a panel of NK clones from several donors. A substantial proportion of peripheral blood NK clones appeared to be significantly inhibited by the HLA-G1-transfected cell line (referred to as .221-G1); nevertheless, no relation was observed between the expression and the function of serologically identifiable Ig-SF receptors (p58/p70) and specific recognition of .221-G1 cells. Moreover, p58 killer cell inhibitory receptor-IgG soluble fusion proteins specifically bound to 721.221 transfectants bearing their corresponding HLA-C ligands, but only a weak reactivity with .221-G1 cells was detectable. By contrast, most NK clones blocked by HLA-G1 expressed the CD94/NKG2-A inhibitory receptor, and moreover, CD94-specific mAbs reconstituted their cytolytic activity comparably to anti-HLA class I mAbs. These data support the idea that the CD94/NKG2 receptor complex is involved in the recognition of cells expressing HLA-G1.

The CD94 and NKG2-A C-type lectins covalently assemble to form a natural killer cell inhibitory receptor for HLA class I molecules.

CD94, a type II membrane protein containing a C-type lectin domain, has been shown to be involved in natural killer (NK) cell-mediated recognition of different HLA allotypes. The inhibitory form of the CD94 receptor has recently been identified by the specific monoclonal antibody (mAb) Z199. Herein, we demonstrate that the inhibitory receptor is in fact a complex formed by the covalent association of CD94 with the NKG2-A molecule (Mr approximately 43 kDa), another member of the C-type lectin superfamily, and that Z199 mAb specifically recognize NKG2-A molecules. Although the NKG2-A-encoding cDNA has been known for several years, the corresponding protein and its possible function remained undefined. Moreover, we show that the NKG2-B protein, an alternatively spliced product of the NKG2-A gene, can also assemble with CD94. Remarkably, both NKG2-A and NKG2-B proteins contain cytoplasmic immunoreceptor tyrosine-based inhibitory motifs (ITIM). This may provide the molecular basis of the inhibitory function mediated by the CD94/NKG2-A receptor complexes.

Implications for immunosurveillance of altered HLA class I phenotypes in human tumours.

HLA class I downregulation is a frequent event associated with tumour invasion and development. Altered HLA class I tumour phenotypes can have profound effects on T-cell and natural killer (NK)-cell antitumour responses. Here, Federico Garrido and colleagues analyse these altered tumour phenotypes in detail, indicating their potential relevance for implementation of immunotherapeutic protocols and strategies to overcome tumour escape mechanisms.

Structure and function of the CD94 C-type lectin receptor complex involved in recognition of HLA class I molecules.

A multigene family of immunoglobulin superfamily (Ig-SF) killer cell inhibitory receptors (KIRs) specifically recognize HLA class I molecules, while the interaction with H-2 products is mediated by members of the murine Ly49 C-type lectin family. A common structural feature of these receptors with inhibitory function is the presence of cytoplasmic immunoreceptor tyrosine-based inhibitory motifs (ITIMs) that couple them to SHP phosphatases. Strong support for the involvement of the CD94 C-type lectin receptor complex in NK cell-mediated recognition of Bw6+ HLA-B, HLA-A and HLA-C alleles has been obtained. The cloned CD94 molecule covalently assembles with at least two different glycoproteins (43 kDa and 39 kDa) to form functional receptors. NK cells inhibited upon HLA recognition express the CD94/p43 dimer, whose specificity for HLA molecules partially overlaps the Ig-SF receptor system. By contrast, NK clones bearing the homologous CD94/p39 receptor are triggered upon its ligation by CD94-specific mAbs. Remarkably, a set of Ig-SF receptors (p50) homologous to p58 KIRs also display an activating function. CD94-associated molecules belong to the NKG2 family of C-type lectins; the NKG2-A gene encodes for the p43 subunit, which contains cytoplasmic ITIMS. Expression of the different CD94 heterodimeric receptors will enable precise analysis of their putative interaction with HLA class I molecules.

Biochemical and serologic evidence for the existence of functionally distinct forms of the CD94 NK cell receptor.

The CD94 NK cell receptor is assembled as a disulfide-linked dimer and appears to be encoded by a single-copy gene of the C-type lectin superfamily. In reverse Ab-dependent cellular cytotoxicity assays, CD94-specific mAbs may either trigger or inhibit cytotoxicity in distinct subsets of NK clones, termed groups A and B, respectively. The molecular basis for this functional ambivalence of CD94 has been addressed. CD94 molecules immunoprecipitated with the HP-3B1 mAb from the two different subsets of NK clones were comparatively analyzed by SDS-PAGE. Under reducing conditions, the stimulating form of CD94 from group A clones displayed a significantly lower Mr (39 kDa) than the inhibitory form of group B clones (Mr = 43 kDa). Analyses of N-glycanase and V8 protease-digested samples indicated that the two CD94 forms are homologous. A CD94-specific mAb (Z199) that did not recognize cells transfected with a CD94 cDNA (LL288) was characterized. Z199 did not bind to group A clones, whereas its reactivity with group B NK cells was indistinguishable from that of other CD94-specific mAbs. Different from the HP-3B1 mAb, the Z199 mAb displayed only inhibitory effects in reverse Ab-dependent cellular cytotoxicity assays. Immunoprecipitation studies confirmed that Z199 selectively identified the 43-kDa CD94. Our study proves the existence of at least two biochemically and serologically distinct CD94 molecules, whose selective/predominant expression at the clonal level correlates with the pattern of response (i.e., inhibition vs activation) of NK cells to ligation by CD94-specific mAbs.

Clonotypic differences in signaling from CD94 (kp43) on NK cells lead to divergent cellular responses.

Ligation of MHC class I-recognizing receptors on NK cells dramatically modulates their secretory and cytotoxic function. This study focuses on characterizing key signaling events regulating these activities after ligation of the C-type lectin superfamily member, CD94. We isolated separate clonal populations of human NK cells in which ligation of CD94 (kp43) either triggered cell-mediated cytotoxicity (group A clones) or potently inhibited NK cell activation (group B clones). We then evaluated the proximal signaling events that regulate these alternative responses. CD94 stimulation of group A clones induced the rapid activation of intracellular protein tyrosine kinases (i.e., lck and ZAP-70), phospholipase C, and phosphatidylinositol 3-kinase. In contrast, CD94 ligation on group B clones had none of the above noted effects and instead inhibited the FcR-induced tyrosine phosphorylations of ZAP-70 and phospholipase C-gamma 2, the formation of phospho-zeta/ZAP-70 complexes, and the release of inositol phosphates. These results define distinct proximal signaling events initiated after CD94 ligation and suggest that clonotypic differences in signaling generate fundamentally different NK cell-mediated responses.

Functional analysis of alpha 1 beta 1 integrin in human natural killer cells.

Upon activation with interleukin (IL)-2 human natural killer (NK) cells acquire on their surface the alpha 1 beta 1 and alpha 2 beta 1 integrins and down-regulate the expression of alpha 6 beta 1. By employing alpha 1 beta 1-specific monoclonal antibody (mAb) HP-2B6, characterized in our laboratory, we examined the functional role of the alpha 1 beta 1 integrin in NK cells. Treatment with HP-2B6 mAb partially interfered with attachment of cultured NK cells to type I collagen, and combined with an anti-alpha 2 beta 1 (TEA 1/41) mAb, it completely abrogated cell adhesion to this extracelular matrix protein. In contrast, NK cell attachment to laminin was completely blocked by the anti-beta 1 LIA 1/2 mAb, but was unaffected by alpha 1 and alpha 2-specific mAb; as alpha 3 beta 1 and alpha 6 beta 1 were undetectable, the data indicate that the alpha 1 beta 1 integrin binding sites for type I collagen and laminin are different. Incubation with anti-alpha 1 HP-2B6 or its F(ab')2 fragments specifically induced a rapid homotypic aggregation of NK cells that was dependent on active metabolism, an intact cytoskeleton and the presence of divalent cations (Ca2+ and Mg2+); homotypic cell adhesion was selectively blocked by anti-CD18, CD11a or CD54 mAb. In addition, stimulation of cultured NK cells with the anti-alpha 1 HP-2B6 enhanced TNF-alpha production and induced tyrosine phosphorylation of a 110-kDa protein. Pretreatment with specific inhibitors of protein tyrosine kinase (PTK) activity (tyrphostin 25 and herbimycin A) completely abrogated the functional effects induced by the anti-alpha 1 HP-2B6 mAb. Our data show that ligation of the alpha 1 beta 1 integrin positively modulates IL-2-activated NK cell function via a PTK-dependent pathway.

Expression and function of alpha 4/beta 7 integrin on human natural killer cells.

In this report we have analysed the expression and function of the alpha 4/beta 7 heterodimer in human natural killer (NK) cells. The expression of alpha 4 beta 7 is induced in NK cells upon activation as the anti alpha 4 beta 2 ACT-1 monoclonal antibody (mAb) family stained a minority of peripheral blood NK cells, whereas it strongly reacted with in vitro long-term interleukin-2 (IL-2)-activated NK cells. Incubation with ACT-1 on its F(ab) fragments induced a strong homotypic adhesion of NK cells, comparable to than stimulated by the anti-alpha 4 HPI 7 mAb. Cell cell interaction induced by the ACT-1 mAb was only prevented by another anti-alpha 4 mAb (HP2.1) that recognizes a different epitope. In alpha 4 beta 7-mediated cell aggregation the alpha 4 beta 7 heterodimer was redistributed to intercellular contact sites thus, suggesting a direct involvement of this integrin in the formation of cell clusters. In NK cells attached to Fibronectin (FN38) or vascular cell adhesion molecule-1 (VCAM-1), both alpha 4 beta 7 and alpha 4 beta 7 integrins were redistributed at the ventral cellular membrane forming discrete contact sites. The ACT-1 mAb only partially blocked NK cell binding to FN38, but in combination with the anti-beta 7 mAb LIAI 2, NK cell binding to FN38 was completely inhibited. In contrast. ACT-1 did not modify NK cell adhesion to VCAM-1 thus supporting the theory that the alpha 4 beta 7 binding sites for both ligands appear to be different. Our results indicate that upon IL-2-activation, expression of functional alpha 4 beta-integrin is induced on NK cells potentially participating in their interaction with both extracellular matrix and endothelial cells.

Natural killer clones recognize specific soluble HLA class I molecules.

Enhancement of major histocompatibility complex (MHC) class I expression leads to protection from natural killer (NK) cell recognition in several systems. MHC class I gene products are released from the cell surface and can be found in sera as soluble forms. To investigate the possible immunoregulatory role of soluble HLA (sHLA) in NK cell-target recognition, several sHLA antigens were studied for their ability to induce NK cell cytotoxicity modulation. NK cell-target recognition was inhibited by the addition of sHLA during the cytotoxicity assay. Our results indicate that sHLA molecules can down-regulate NK killing at the effector level. Moreover, different NK clones are able to specifically recognize different sHLA antigens. Kp43 molecules seem to be involved in the NK recognition of sHLA-B7.

Functional ambivalence of the Kp43 (CD94) NK cell-associated surface antigen.

We originally characterized the Kp43 (CD94) surface Ag, whose expression is restricted to human NK cells and a minor T lymphocyte subset. As shown in the present study, anti-Kp43 mAbs but not their F(ab')2 fragments markedly inhibited the cytolytic activity of polyclonal-activated NK cells in a redirected lysis assay against the murine P815 cell line. Furthermore, anti-Kp43 mAbs also down-regulated the CD16-dependent redirected killing and PHA-induced lectin-dependent cellular cytotoxicity. However, the intensity of the inhibitory effect was variable and no significant down-regulation of cytotoxicity was substantiated in NK cell populations from some individuals. A similar variability in the responsiveness to anti-Kp43 mAb was noticed when fresh CD3- lymphocyte populations were tested: in some donors we observed the induction of redirected lysis, whereas in other samples the Kp43-specific mAb inhibited cytotoxicity. The analysis of single cell-derived microcultures provided a clue to interpret the variable responsiveness of polyclonal cell populations; remarkably, the cytolytic activity of some NK clones was inhibited, whereas that of others was either stimulated or unaffected. The pattern of responsiveness in the cytolytic assay correlated with TNF production upon stimulation with solid phase-bound anti-Kp43 mAbs. The different types of clones could be derived from the same individual, although their relative proportions varied from donor to donor. Moreover, Kp43 appeared to be coupled differently to signal transduction pathways, because (Ca2+)i mobilization in the presence of the Kp43-specific mAbs was substantiated only in clones that were activated in the redirected lysis assay.