Regulation of EGF receptor expression and function

From the results of these studies of the activities of the various EGF receptor mutants we were able to disassociate the ability of EGF to increase intracellular calcium from its ability to induce genes and to cause morphological transformation and growth. These results lead us to the following concept. The kinase domain has a C-terminal border at about residue 957. The remainder of the C-terminus is regulatory. The 164 amino acids from residue 1022 to 1186 constitute an inhibitory region for the kinase. It contributes to ligand-induced internalization because this is reduced in a mutant receptor truncated to residue 1052. Proximally within the C-terminus kinase inhibitory domain is a domain that is required for endocytosis and for raising intracellular calcium that we call the calcium internalization (CAIN) domain. In summary, we have found that the kinase activity of the EGF receptor is required for its function even when all of the self-phosphorylation sites have been removed. The EGF receptor has several distinct cytoplasmic domains that are important for its activity to regulate gene expression, DNA synthesis, and the intracellular calcium level. Biological signaling occurs from the cell surface via essential protein tyrosine kinase activity with ligand-induced internalization serving to abbrogate the biological signal.     

The transmembrane domain of receptor-activity-modifying protein 1 is essential for the functional expression of a calcitonin gene-related peptide receptor

Three receptor-activity-modifying proteins (RAMP) define specific interactions between calcitonin (CT) gene-related peptide (CGRP), adrenomedullin (AM) and amylin, and a CT receptor or a CT receptor-like receptor (CRLR). Both form heterodimeric RAMP/receptor complexes at the cell surface. This association represents a novel principle of G protein-coupled receptor function. RAMP1 is transported to the cell surface together with the CRLR or the CT receptor. Here, we have investigated the functional relevance of the short C-terminal intracellular tail QSKRTEGIV and of the single transmembrane domain of human (h) RAMP1 for their interactions with the hCRLR to constitute a CGRP receptor. To this end, hRAMP1 has been sequentially truncated from the C-terminus, and [(125)I]h alpha CGRP/hRAMP1/hCRLR association at the cell surface and cAMP accumulation in response to h alpha CGRP have been examined. With the C-terminal truncation of hRAMP1 by four amino acids wild-type hRAMP1 function was maintained, and the hCRLR was required for the transport of hRAMP1 to the cell surface. Further truncation of hRAMP1 through removal of the remaining five intracellular amino acids revealed CRLR-independent cell surface delivery but otherwise normal hRAMP1 activity. Sequential shortening of the hRAMP1 transmembrane domain resulted in progressively impaired association with the hCRLR and, as a consequence, abolished CGRP receptor function. In conclusion, the intracellular QSKRT sequence adjacent to the transmembrane domain of hRAMP1 provides a signal for intracellular retention. The sequence is unrelated to consensus endoplasmic reticulum retention/retrieval motives and overridden by the presence of the hCRLR. The entire single transmembrane domain of hRAMP1 together with one hydrophilic amino acid residue at its C-terminus is required for the formation of a fully functional CGRP/hRAMP1/hCRLR receptor complex.     

Transport of the IgE receptor alpha-chain is controlled by a multicomponent intracellular retention signal

The human high affinity IgE receptor (FcepsilonRI) is a central component of the allergic response and is expressed as either a trimeric alphagamma2 or tetrameric alphabetagamma2 complex. It has been previously described that the cytoplasmic domain (CD) of the alpha-chain carries a dilysine motif at positions -3/-7 from the C terminus that functions in intracellular retention prior to assembly with other FcepsilonRI subunits. In this report we have further explored the role of the -3/-7 dilysine signal in controlling steady-state alpha-chain transport by mutational analysis and found little surface expression of a -3/-7 dialanine alpha-chain mutant but significant Golgi localization. We compared the transport properties of a series of alpha-chain cytoplasmic domain truncation mutants and observed that truncation mutants lacking 23 or more C-terminal residues showed a dramatic increase in steady-state transport suggesting a role for the membrane-proximal CD sequence in alpha-chain retention. By performing alanine-scanning mutagenesis we identified a dilysine sequence (Lys(212)-Lys(216)) proximal to the transmembrane domain (TMD) that is important for both alpha-chain cell-surface expression and intracellular stability. Furthermore, co-mutation of the Lys(212)-Lys(216) residues with the -3/-7 dilysine signal produced a dramatic increase in alpha-chain surface expression that was further increased by co-mutation of the lone charged residue (Asp(192)) in the TMD thereby defining three regions that function to regulate alpha-chain transport and in a highly synergistic manner.     

Amino acids in the cytoplasmic C terminus of the parathyroid Ca2+-sensing receptor mediate efficient cell-surface expression and phospholipase C activation

The C-terminal tail of the calcium receptor (CaR) regulates the affinity of the receptor for ligand, desensitization, and membrane localization. To determine the role of specific amino acids in the bovine parathyroid CaR in mediating signal transduction and cell-surface expression, we transfected truncated and mutated CaR cDNAs into HEK-293 cells. The ability of high extracellular [Ca(2+)] ([Ca(2+)](o)) to increase total inositol phosphate (InsP) production, an index of phospholipase C (PLC) activation, was determined. Receptor expression was assessed by immunoblotting and immunocytochemistry. In cells transiently or stably expressing receptors with the C-terminal tail truncated after residue 895 (CaR-(1-895)) or 929 (CaR-(1-929)), raising [Ca(2+)](o) increased InsPs to levels comparable with those of cells expressing wild-type CaRs. There were no PLC responses to high [Ca(2+)](o) (up to 30 mm) in cells expressing CaRs with C-terminal tails of only 3 residues (CaR-(1-866)), even though these receptors were expressed in the membrane. We scanned the residues between Ser(866) and Val(895) using tandem-Ala and single-site mutagenesis. Two point mutants (His(880) --> Ala and Phe(882) --> Ala CaR) showed 50-70% reductions in high [Ca(2+)](o)-induced InsP production. The levels of expression and glycosylation of these mutants were comparable with wild-type CaRs, but both receptors were profoundly retained in intracellular organelles and co-localized with the endoplasmic reticulum marker BiP. This suggested that the signaling defects of these receptors were likely because of defective trafficking of receptors to the cell surface. Modeling of the C-terminal domain of the CaR indicated that His(880) and Phe(882) are situated in a putative alpha-helical structure of 15 amino acids between residues 877 and 891 in the C-terminal tail. Our studies support the idea that specific amino acids, and possibly a unique secondary structure in the C-terminal tail, are required for the efficient targeting of the CaR to the cell surface required for PLC activation.     

A missense mutation in the seventh transmembrane domain constitutively activates the human Ca2+ receptor

A missense mutation, A843E, in the seventh transmembrane domain of the human Ca2+ receptor, identified in a subject with autosomal dominant hypocalcemia, was found to cause a constitutive activation while at the same time lowering the maximal response of the receptor to Ca2+. A truncated human Ca2+ receptor lacking the majority of the N-terminal extracellular domain failed to respond to Ca2+ despite an excellent cell surface expression. The A843E mutant version of this truncated receptor showed constitutive activation. These results identify A843 as a critical residue for maintaining the inactive conformation of the human Ca2+ receptor. Substitution of glutamate, but not lysine or valine, for alanine 843 leads to activation of the human Ca2+ receptor in a manner that no longer depends upon Ca2+ binding to the extracellular domain.     

Synthesis and biophysical characterization of a multidomain peptide from a Saccharomyces cerevisiae G protein-coupled receptor

We attached peptides corresponding to the seventh transmembrane domain (TMD7) of the alpha-mating factor receptor (Ste2p) of Saccharomyces cerevisiae to a hydrophilic, 40-residue fragment of the carboxyl terminus of this G protein-coupled receptor. Peptides corresponding to (a) the 40-residue portion of the carboxyl tail (T-40), (b) the tail plus a part of TMD7 (M7-12-T40), and (c) to the tail plus the full TMD7 (M7-24-T40) were chemically synthesized and purified. The molecular mass and primary sequence of these peptides were confirmed by mass spectrometry and tandem mass spectrometry procedures. Circular dichroism (CD) revealed that T-40 was disordered in phosphate buffer and in the presence of 1,2-dimyristoyl-sn-glycero-3-phosphocholine/1,2-dimyristoyl-sn-glycero-3-[phospho-racemic-(1-glycerol)] bilayers. In contrast, M7-12-T40 and M7-24-T40 peptides were partially helical in the presence of vesicles, and difference CD spectroscopy showed that the transmembrane regions of these peptides were 42 and 94% helical, respectively. CD analysis also demonstrated that M7-24-T40 retained its secondary structure in the presence of 1-palmitoyl-2-hydroxy-sn-glycero-3-[phospho-racemic-(1-glycerol)] micelles at 0.5 mm concentration. Thus, the tail and the transmembrane domain of the multidomain 64-amino acid residue peptide manifest individual conformational preferences. Measurement of tryptophan fluorescence indicated that the transmembrane domain integrated into bilayers in a manner similar to that expected for this region in the native state of the receptor. This study demonstrated that the tail of Ste2p can be used as a hydrophilic template to study transmembrane domain structure using techniques such as CD and NMR spectroscopy.     

A membrane-proximal basic domain and cysteine cluster in the C-terminal tail of CCR5 constitute a bipartite motif critical for cell surface expression

We examined the structural requirements for cell surface expression, signaling, and human immunodeficiency virus co-receptor activity for the chemokine receptor, CCR5. Serial C-terminal truncation of CCR5 resulted in progressive loss of cell surface expression; mutants truncated at the 317th position and shorter were not detected at the cell surface. Alanine substitution of basic residues in the membrane-proximal domain (residues 314-322) in the context of a full-length C-tail resulted in severe reduction in surface expression. C-terminal truncation that excised the three cysteines in this domain reduced surface expression, but further truncation of upstream basic residue(s) abolished surface expression. Substituting the carboxyl-terminal domain of CXCR4 for that of CCR5 failed to rectify the trafficking defect of the tailless CCR5. In contrast, tailless CXCR4 or a CXCR4 chimera that exchanged the native cytoplasmic domain for that of wild type CCR5 was expressed at the cell surface. Deletion mutants that expressed at the cell surface responded to chemokine stimulation and mediated human immunodeficiency virus entry. Substitution of all serine and threonine residues in the C-terminal tail of CCR5 abolished chemokine-mediated receptor phosphorylation but preserved downstream signaling (Ca(2+) flux), while substitutions of tyrosine residues in the C-tail affected neither phenotype. CCR5 mutants that failed to traffic to the plasma membrane did not exhibit obvious changes in metabolic turnover and were retained in the Golgi or pre-Golgi compartments(s). Thus, the basic domain (-KHIAKRF-) and the cysteine cluster (-CKCC-) in the C-terminal tail of CCR5 function cooperatively for optimal surface expression.     

The Golgi localization of GOLPH2 (GP73/GOLM1) is determined by the transmembrane and cytoplamic sequences

Golgi phosphoprotein 2 (GOLPH2) is a resident Golgi type-II membrane protein upregulated in liver disease. Given that GOLPH2 traffics through endosomes and can be secreted into the circulation, it is a promising serum marker for liver diseases. The structure of GOLPH2 and the functions of its different protein domains are not known. In the current study, we investigated the structural determinants for Golgi localization using a panel of GOLPH2 truncation mutants. The Golgi localization of GOLPH2 was not affected by the deletion of the C-terminal part of the protein. A truncated mutant containing the N-terminal portion (the cytoplasmic tail and transmembrane domain (TMD)) localized to the Golgi. Sequential deletion analysis of the N-terminal indicated that the TMD with a positively charged residue in the cytoplasmic N-terminal tail were sufficient to support Golgi localization. We also showed that both endogenous and secreted GOLPH2 exist as a disulfide-bonded dimer, and the coiled-coil domain was sufficient for dimerization. This structural knowledge is important for the understanding the pathogenic role of GOLPH2 in liver diseases, and the development of GOLPH2-based hepatocellular cancer diagnostic methods.     

Sequence requirements for induction of cytolysis by the T cell antigen/Fc receptor zeta chain.

The zeta chain of the T cell antigen receptor is a dimeric transmembrane protein with a very short extracellular domain and an extended cytoplasmic tail that triggers T cell effector function when aggregated by extracellular stimuli. We have reduced the active site of zeta to an 18 residue motif that can be appended to the intracellular domain of other transmembrane proteins to endow them with receptor-like activity. The compact size of the motif appears to eliminate zeta mechanisms based on enzymatic activity and suggests that one or at most a few cellular proteins interact with the zeta intracellular domain to initiate signal transduction. Analysis of individual amino acids within the 18 residue element reveals two phylogenetically conserved tyrosines that are absolutely required for activity and other residues that are less essential but contribute to the efficacy of receptor-directed cytolysis.     

Identification of putative sites of interaction between the human formyl peptide receptor and G protein.

Wild-type and 35 mutant formyl peptide receptors (FPRs) were stably expressed in Chinese hamster ovary cells. All cell surface-expressed mutant receptors bound N-formyl peptide with similar affinities as wild-type FPR, suggesting that the mutations did not affect the ligand-binding site. G protein coupling was examined by quantitative analysis of N-formyl-methionyl-leucyl-phenylalanine-induced increase in binding of (35)S-labeled guanosine 5'-3-O-(thio)triphosphate (GTPgammaS) to membranes. The most prominent uncoupled FPR mutants were located in the N-terminal part of the second transmembrane domain (S63W and D71A) and the C-terminal interface of the third transmembrane domain (R123A and C124S/C126S). In addition, less pronounced uncoupling was detected with deletion mutations in the third cytoplasmic loop and in the cytoplasmic tail. Further analysis of some of the mutants that were judged to be uncoupled based on the [(35)S]GTPgammaS membrane-binding assay were found to transduce a signal, as evidenced by intracellular calcium mobilization and activation of p42/44 MAPK. Thus, these single point mutations in FPR did not completely abolish the interaction with G protein, emphasizing that the coupling site is coordinated by several different regions of the receptor. Mutations located in the putative fifth and sixth transmembrane domains near the N- and C-terminal parts of the third cytoplasmic loop did not result in uncoupling. These regions have previously been shown to be critical for G protein coupling to many other G protein-coupled receptors. Thus, FPR appears to have a G protein-interacting site distinct from the adrenergic receptors, the muscarinic receptors, and the angiotensin receptors.     

Dendritic cell immunoactivating receptor,a novel C-type lectin immunoreceptor,acts as an activating receptor through association with Fc receptor gamma chain

An increasing number of C-type lectin receptors are being discovered on dendritic cells, but their signaling abilities and underlying mechanisms require further definition. Among these, dendritic cell immunoreceptor (DCIR) induces negative signals through an inhibitory immunoreceptor tyrosine-based inhibitory motif (ITIM) in its cytoplasmic tail. Here we identify a novel C-type lectin receptor, dendritic cell immunoactivating receptor (DCAR), whose extracellular lectin domain is highly homologous to that of DCIR. DCAR is expressed similarly in tissues to DCIR, but its short cytoplasmic portion lacks signaling motifs like ITIM. However, a positively charged arginine residue is present in the transmembrane region of the DCAR, which may explain its association with Fc receptor gamma chain and its stable expression on the cell surface. Furthermore, cross-linking of DCAR in the presence of gamma chain activates calcium mobilization and tyrosine phosphorylation of cellular proteins. These signals are mediated by the immunoreceptor tyrosine-based activating motif (ITAM) of the gamma chain. Thus, DCAR is closely related to DCIR, but it introduces activating signals into antigen-presenting cells through its physical and functional association with ITAM-bearing gamma chain. The identification of this activating immunoreceptor provides an example of signaling via a dendritic cell-expressed C-type lectin receptor.     

Expression of polycystin-1 C-terminal fragment enhances the ATP-induced Ca2+ release in human kidney cells

Polycystin-1 (PC1) is a membrane protein expressed in tubular epithelia of developing kidneys and in other ductal structures. Recent studies indicate this protein to be putatively important in regulating intracellular Ca(2+) levels in various cell types, but little evidence exists for kidney epithelial cells. Here we examined the role of the PC1 cytoplasmic tail on the activity of store operated Ca(2+) channels in human kidney epithelial HEK-293 cell line. Cells were transiently transfected with chimeric proteins containing 1-226 or 26-226 aa of the PC1 cytoplasmic tail fused to the transmembrane domain of the human Trk-A receptor: TrkPC1 wild-type and control Trk truncated peptides were expressed at comparable levels and localized at the plasma membrane. Ca(2+) measurements were performed in cells co-transfected with PC1 chimeras and the cytoplasmic Ca(2+)-sensitive photoprotein aequorin, upon activation of the phosphoinositide pathway by ATP, that, via purinoceptors, is coupled to the release of Ca(2+) from intracellular stores. The expression of TrkPC1 peptide, but not of its truncated form, enhanced the ATP-evoked cytosolic Ca(2+) concentrations. When Ca(2+) assays were performed in HeLa cells characterized by Ca(2+) stores greater than those of HEK-293 cells, the histamine-evoked cytosolic Ca(2+) increase was enhanced by TrkPC1 expression, even in absence of external Ca(2+). These observations indicate that the C-terminal tail of PC1 in kidney and other epithelial cells upregulates a Ca(2+) channel activity also involved in the release of intracellular stores.     

The cytoplasmic region of the erythropoietin receptor contains nonoverlapping positive and negative growth-regulatory domains.

The erythropoietin (EPO) receptor (EPO-R), a member of a large cytokine receptor superfamily, has a 236-amino-acid cytoplasmic region which contains no obvious tyrosine kinase or other catalytic domain. In order to delineate the linear functional domains of the cytoplasmic tail, we generated truncated mutant cDNAs which were transfected into a murine interleukin-3-dependent cell line, Ba/F3, and the EPO-dependent growth characteristics of the stable transfectants were assayed. We identified two unique domains of the cytoplasmic tail. A membrane-proximal positive signal transduction domain of less than or equal to 103 amino acids, in a region highly similar to the interleukin-2 receptor beta chain, was sufficient for EPO-mediated signal transduction. A carboxy-terminal negative-control domain, a serine-rich region of approximately 40 amino acids, increased the EPO requirement for the Ba/F3 transfectants without altering EPO-R cell surface expression, affinity for EPO, receptor oligosaccharide processing, or receptor endocytosis. Truncation of this negative-control domain allowed the Ba/F3 transfectants to grow maximally in only 1 pM EPO, 1/10 the concentration required for growth of cells expressing the wild-type EPO-R. All truncated EPO-R mutants which retained the transmembrane region of the EPO-R polypeptide bound to the gp55 envelope protein of Friend spleen focus-forming virus. Only the functional EPO-R mutants were activated by the gp55, however, suggesting that gp55- and EPO-mediated signaling occur via a similar mechanism.     

Expression of a glycosylphosphatidylinositol-anchored ligand,growth hormone,blocks receptor signalling

We have investigated the interaction between GH (growth hormone) and GHR (GH receptor). We previously demonstrated that a truncated GHR that possesses a transmembrane domain but no cytoplasmic domain blocks receptor signalling. Based on this observation we investigated the impact of tethering the receptor''s extracellular domain to the cell surface using a native lipid GPI (glycosylphosphatidylinositol) anchor. We also investigated the effect of tethering GH, the ligand itself, to the cell surface and demonstrated that tethering either the ecGHR (extracellular domain of GHR) or the ligand itself to the cell membrane via a GPI anchor greatly attenuates signalling. To elucidate the mechanism for this antagonist activity, we used confocal microscopy to examine the fluorescently modified ligand and receptor. GH–GPI was expressed on the cell surface and formed inactive receptor complexes that failed to internalize and blocked receptor activation. In conclusion, contrary to expectation, tethering an agonist to the cell surface can generate an inactive hormone receptor complex that fails to internalize.     

The C-terminal tail of the metabotropic glutamate receptor subtype 7 is necessary but not sufficient for cell surface delivery and polarized targeting in neurons and epithelia

Complex neuronal functions rely upon the precise sorting, targeting, and restriction of receptors to specific synaptic microdomains. Little is known, however, of the molecular signals responsible for mediating these selective distributions. Here we report that metabotropic glutamate receptor subtype 7a (mGluR7a) is polarized at the basolateral surface when expressed in Madin-Darby canine kidney (MDCK) epithelial cells but is not polarized when expressed in cultured hippocampal neurons. Truncation of the mGluR7 cytoplasmic tail produces a protein that is restricted to a perinuclear intracellular compartment in both neurons and MDCK cells, where this protein colocalizes with a trans-Golgi network antigen. The mGluR7 cytoplasmic domain appended to the transmembrane portion of the vesicular stomatitis virus G protein and the ectodomain of human placental alkaline phosphatase is distributed over the entire cell surface in cultured neurons. When expressed in MDCK cells, this construct remains in an intracellular compartment distinct from endosomes or lysosomes. Thus, the cytoplasmic tail domain of mGluR7 is necessary but not sufficient for polarized targeting in MDCK monolayers, whereas in neurons the cytoplasmic tail is sufficient for cell surface expression but not polarization. Additional mechanisms are likely required to mediate mGluR7 neuronal polarization and synaptic clustering.     

Truncation of N-terminal extracellular or C-terminal intracellular domains of human ETA receptor abrogated the binding activity to ET-1.

We have investigated the function of N-terminal and C-terminal domains of the human ETA receptor by expressing truncated mutants in COS-7 cells. Three kinds of ETA receptors truncated in the N-terminal extracellular or C-terminal intracellular domains were produced. Deletion of the entire extracellular N-terminal or intracellular C-terminal domain completely inactivated the ET-1 binding activity. However, the deletion of one half of the N-terminal extracellular domain of the ETA receptor, missing one of two N-linked glycosylation sites, maintained complete binding activity. Specific monoclonal antibodies detected all the truncated ETA receptors in the cell membrane fraction of transfected COS-7 cells. The size of the ETA receptor was heterogeneous due to differential glycosylation and distributed in 48K, 45K and 42K dalton bands in Western blot analysis. These results demonstrated that a part of the N-terminal domain in close proximity to the first transmembrane region is required for the ligand binding activity of the ETA receptor, and the C-terminal domain is perhaps necessary as an anchor for maintenance of the binding site.     

Phosphatidylinositol linkage of a truncated form of the platelet-derived growth factor receptor

The platelet-derived growth factor (PDGF) receptor is usually anchored to the plasma membrane through a membrane-spanning hydrophobic amino acid sequence that splits the molecule into two approximately equal pieces, an amino-terminal external domain that contains the binding site for PDGF and a carboxyl-terminal cytoplasmic domain that includes the tyrosine kinase coding sequences. Here we report the expression of a truncated PDGF receptor that consists of the extracellular domain without the transmembrane and cytoplasmic domains. Unexpectedly, this form of the receptor that lacks a hydrophobic membrane-anchoring sequence was bound to the membrane and was not secreted into the culture media. Conventional methods to dissociate noncovalent protein-protein interactions failed to release the protein from the membrane. When the transmembrane and cytoplasmic sequences were artificially deleted from the PDGF receptor, the truncated extracellular domain was anchored to the membrane through phospholipids and could be released by phospholipase C treatment. This truncated form of the receptor bound PDGF with an affinity 5-20-fold lower than the full-length receptor.     

Cytoplasmic targeting signals in transmembrane invariant surface glycoproteins of trypanosomes

Protein targeting mechanisms in flagellated protozoan parasites have received considerable interest because of a huge bias in these organisms toward the glycosylphosphatidylinositol anchor as a mechanism for the membrane attachment of cell surface macromolecules. In this study, the trafficking of invariant surface glycoprotein 65 (ISG65), a family of type I transmembrane proteins, was examined. Analysis of the C-terminal domains of ISG65 family members demonstrated a high level of conservation and, in particular, the presence of three lysine residues contained within the cytoplasmic tails of all ISG65s. ISG65 was expressed on the cell surface, in agreement with earlier work, but an intracellular pool of ISG65 was also detected within a Rab5A early endosome. Transplantation of the C-terminal 74 amino acids of ISG65 (encompassing the 23 C-terminal residues of the extracellular domain, the transmembrane peptide, and the cytoplasmic domain) onto the N-terminal domain of BiP (BiPN) was sufficient to target the chimera to the same internal compartments as native ISG65. Further, site-directed mutagenesis indicated that the cytoplasmic tail was required for endoplasmic reticulum exit and that at least two of the cytoplasmic domain lysine residues are needed for endosomal targeting, as removal of all three led to surface expression. Kinetic measurements demonstrate that the BiPN fusion protein (containing the ISG65 C terminus) has a short half-life, indicating rapid turnover. In contrast, BiPN fusion proteins containing a glycosylphosphatidylinositol anchor instead of the ISG65 C-terminal region are stably expressed on the surface, confirming the requirement for the ISG65 sequence for endosomal targeting. We suggest that the lack of surface expression of the BiPN-ISG65 fusion protein is likely due to more efficient internalization compared with ISG65. Taken together, these data demonstrate the presence of a lysine-dependent endocytosis signal in the ISG65 family.     

Recognition of HLA-Cw4 but not HLA-Cw6 by the NK cell receptor killer cell Ig-like receptor two-domain short tail number 4

NK cells are cytotoxic to virus-infected and tumor cells that have lost surface expression of class I MHC proteins. Target cell expression of class I MHC proteins inhibits NK cytotoxicity through binding to inhibitory NK receptors. In contrast, a similar family of activating NK receptors, characterized by the presence of a charged residue in their transmembrane portion and a truncated cytoplasmic tail, augment lysis by NK cells when ligated by an appropriate class I MHC protein. However, the class I MHC specificity of many of these activating NK receptors is still unknown. Here, we show enhanced lysis of HLA-Cw4 but not HLA-Cw6-expressing cells, by a subset of NK clones. This subset may express killer cell Ig-like receptor two-domain short tail number 4 (KIR2DS4), as suggested by staining with various mAb. It is still possible, however, that these clones may express receptors other than KIR2DS4 that might recognize HLA-Cw4. Binding of KIR2DS4-Ig fusion protein to cells expressing HLA-Cw4 but not to those expressing HLA-Cw6 was also observed. The binding of KIR2DS4-Ig to HLA-Cw4 is weaker than that of killer cell Ig-like receptor two-domain long tail number 1 (KIR2DL1)-Ig fusion protein; however, such weak recognition is capable of inhibiting lysis by an NK transfectant expressing a chimeric molecule of KIR2DS4 fused to the transmembrane and cytoplasmic portion of KIR2DL1. Residue alpha14 is shown to be important in the KIR2DS4 binding to HLA-Cw4. Implications of the role of the activating NK receptors in immunosurveillance are discussed.