Functional requirements for signaling through the stimulatory and inhibitory mouse NKR-P1 (CD161) NK cell receptors

The NK cell receptor protein 1 (NKR-P1) (CD161) molecules represent a family of type II transmembrane C-type lectin-like receptors expressed predominantly by NK cells. Despite sharing a common NK1.1 epitope, the mouse NKR-P1B and NKR-P1C receptors possess opposing functions in NK cell signaling. Engagement of NKR-P1C stimulates cytotoxicity of target cells, Ca2+ flux, phosphatidylinositol turnover, kinase activity, and cytokine production. In contrast, NKR-P1B engagement inhibits NK cell cytotoxicity. Nonetheless, it remains unclear how different signaling outcomes are mediated at the molecular level. Here, we demonstrate that both NKR-P1B and NKR-P1C associate with the tyrosine kinase, p56(lck). The interaction is mediated through the di-cysteine CxCP motif in the cytoplasmic domains of NKR-P1B/C. Disrupting this motif leads to abrogation of both stimulatory and inhibitory NKR-P1 signals. In addition, mutation of the consensus ITIM (LxYxxL) in NKR-P1B abolishes both its Src homology 2-containing protein tyrosine phosphatase-1 recruitment and inhibitory function. Strikingly, engagement of NKR-P1C on NK cells obtained from Lck-deficient mice failed to induce NK cytotoxicity. These results reveal a role for Lck in the initiation of NKR-P1 signals, and demonstrate a requirement for the ITIM in NKR-P1-mediated inhibition.     

The NKR-P1B gene product is an inhibitory receptor on SJL/J NK cells

The mouse NKR-P1 family includes at least three genes: NKR-P1A, -B, -C. Neither surface expression nor function of the NKR-P1B gene product has previously been shown. Here, we demonstrate that the SJL/J allele of the NKR-P1B gene product is expressed on SJL/J NK cells, and is recognized by PK136 mAb. Interestingly, the same mAb does not recognize the NKR-P1B gene product of C57BL/6. We have also generated a novel mAb, 1C10, that recognizes an activation receptor on SJL/J NK cells. Activation of the NKR-P1B receptor-inhibited 1C10 mAb induced redirected lysis and recruited SHP-1, indicating that NKR-P1B is an inhibitory receptor. Therefore, the mouse NKR-P1 gene family, like the Ly49 family, includes both activation and inhibitory receptors.     

CD161 (human NKR-P1A) signaling in NK cells involves the activation of acid sphingomyelinase

NK and NKT cells play a major role in both innate immunity and in influencing the development of adaptive immune responses. CD161 (human NKR-P1A), a protein encoded in the NK gene complex, is a major phenotypic marker of both these cell types and is thought to be involved in the regulation of NK and NKT cell function. However, the mechanisms of action and signaling pathways of CD161 are poorly understood. To identify molecules able to interact with the cytoplasmic tail of human CD161 (NKR-P1A), we have conducted a yeast two-hybrid screen and identified acid sphingomyelinase as a novel intracellular signaling pathway linked to CD161. mAb-mediated cross-linking of CD161, in both transfectants and primary human NK cells, triggers the activation of acid, but not neutral sphingomyelinase. The sphingomyelinases represent the catabolic pathway for N-acyl-sphingosine (ceramide) generation, an emerging second messenger with key roles in the induction of apoptosis, proliferation, and differentiation. These data therefore define a novel signal transduction pathway for the CD161 (NKR-P1A) receptor and provide fresh insights into NK and NKT cell biology.     

A novel NKR-P1B(bright) NK cell subset expresses an activated CD25(+)CX(3)CR1(+)CD62L(-)CD11b(-)CD27(-) phenotype and is prevalent in blood, liver, and gut-associated lymphoid organs of rats

The inhibitory NKR-P1B receptor identifies a subset of rat splenic NK cells that is low in Ly49 receptors but enriched for CD94/NKG2 receptors. We report in this study a novel NKR-P1B(bright) NK subpopulation that is prevalent in peripheral blood, liver, and gut-associated lymphoid organs and scarce in the spleen, peripheral lymph nodes, bone marrow, and lungs. This NKR-P1B(bright) NK subset displays an activated phenotype, expressing CD25, CD93, CX(3)CR1 and near absence of CD62-L, CD11b, and CD27. Functionally, NKR-P1B(bright) NK cells are highly responsive in terms of IFN-γ production and exert potent cytolytic activity. They show little spontaneous proliferation, are reduced in numbers upon in vivo activation with polyinosinic:polycytidylic acid, and have poor survival in ex vivo cytokine cultures. Our findings suggest that NKR-P1B(bright) NK cells are fully differentiated effector cells that rapidly die upon further activation. The identification of this novel rat NK cell subset may facilitate future translational research of the role of distinct NK cell subsets under normal physiological conditions and during ongoing immune responses.     

Phylogenetic and functional conservation of the NKR-P1F and NKR-P1G receptors in rat and mouse

Two clusters of rat Nkrp1 genes can be distinguished based on phylogenetic relationships and functional characteristics. The proximal (centromeric) cluster encodes the well-studied NKR-P1A and NKR-P1B receptors and the distal cluster, the largely uncharacterized, NKR-P1F and NKR-P1G receptors. The inhibitory NKR-P1G receptor is expressed only by the Ly49s3⁺ NK cell subset as detected by RT-PCR, while the activating NKR-P1F receptor is detected in both Ly49s3⁺ and NKR-P1B⁺ NK cells. The mouse NKR-P1G ortholog is expressed by both NKR-P1D⁻ and NKR-P1D⁺ NK cells in C57BL/6 mice. The rat and mouse NKR-P1F and NKR-P1G receptors demonstrate a striking, cross-species conservation of specificity for Clr ligands. NKR-P1F and NKR-P1G reporter cells reacted with overlapping panels of tumour cell lines and with cells transiently transfected with rat Clr2, Clr3, Clr4, Clr6 and Clr7 and mouse Clrc, Clrf, Clrg and Clrd/x, but not with Clr11 or Clrb, which serve as ligands for NKR-P1 from the proximal cluster. These data suggest that the conserved NKR-P1F and NKR-P1G receptors function as promiscuous receptors for a rapidly evolving family of Clr ligands in rodent NK cells.     

cDNA cloning of mouse NKR-P1 and genetic linkage with LY-49. Identification of a natural killer cell gene complex on mouse chromosome 6.

NK cells lyse tumor cells and virally infected cells, but the molecular basis for this phenomenon has not been defined. A mAb specific for the rat cell surface molecule, NKR-P1, stimulates rat NK cell lytic activity and is reactive with all rat NK cells, suggesting that this molecule may play a significant role in NK cell function. We have previously described another NK cell-specific Ag, Ly-49, that belongs to a family of cross-hybridizing genes on distal mouse chromosome 6. The rat NKR-P1 Ag shares several features with the mouse Ly-49 Ag, including selective cell surface expression on NK cells, homology to the C-type lectins, expression as a type II integral membrane protein, and disulfide-linked homodimeric structure. To further examine the relationship of NKR-P1 to Ly-49, we have cloned the cDNA encoding a mouse homologue of NKR-P1 (mNKR-P1). The mouse and rat NKR-P1-deduced polypeptide sequences are highly conserved, suggesting a similar tertiary structure. By examination of DNA from informative recombinant inbred mice with Southern blot analysis, we have determined that mNKR-P1 is encoded by a distinct gene that is genetically linked to the Ly-49 locus, lying within 0.5 centi-Morgan (cM) of Ly-49. Although the deduced amino acid sequences of mNKR-P1 and Ly-49 reveal that these proteins are structurally similar, they are only 24% identical at the amino acid level and the cDNA sequences do not demonstrate significant nucleotide homology. Our studies suggest that we have identified a region on mouse chromosome 6 that includes distinct NK-specific genes that encode structurally related proteins (type II integral membrane proteins, C-type lectin super-gene family) but which demonstrate considerable heterogeneity. We have termed this genetic region the NK complex.     

The ischemia-responsive protein 94 (Irp94) activates dendritic cells through NK cell receptor protein-2/NK group 2 member D (NKR-P2/NKG2D) leading to their maturation

Tumor recognition and killing, the uptake of released immunogenic substrate, and the generation of immunity are crucial aspects of dendritic cell (DC)-mediated antitumor immune response. In the context of direct tumoricidal activity, we have recently shown NK cell receptor protein-2 (NKR-P2)/NK group 2 member D (NKG2D) as a potent activation receptor on rat DCs. The activation of DCs with agonistic anti-NKR-P2 mAb, the binding of soluble NKR-P2 to the AK-5 tumor, and DC maturation with fixed AK-5 cells led us to identify a putative NKR-P2 ligand on the AK-5 cell surface. In this study we have shown that the AK-5 tumor-derived ischemia-responsive protein-94 (Irp94, a 110 kDa Hsp family member) acts as a functional ligand for NKR-P2 on DCs and enhances Irp94-NKR-P2 interaction-dependent tumor cell apoptosis via NO. Surface expression of Irp94 was also found on tumors of diverse origin in addition to AK-5. Furthermore, the Th1-polarizing cytokine IL-12, produced from Irp94-ligated BMDCs, augments NK cell cytotoxicity. Irp94-NKR-P2 interaction drives the maturation of BMDCs by up-regulating MHC class II, CD86, and CD1a and also induces autologous T cell proliferation, which displays a crucial state of DCs for adaptive antitumor immune response. These functional properties of Irp94 reside in the COOH terminus subdomain but not in the NH2 terminus ATPase domain of Irp94. We also show the involvement of PI3K, ERK, protein kinase C, phosphatases, and NF-kappaB translocation as downstream mediators of DCs activation upon NKR-P2 ligation with Irp94. Our studies demonstrate for the first time a novel role of a 110-kDa heat shock protein (Irp94) as a ligand for NKR-P2 on DCs, which in turn executes both innate and adaptive immunity.     

High-level expression of soluble form of mouse natural killer cell receptor NKR-P1C(B6) in Escherichia coli

Mouse NKR-P1C(B6) receptor corresponding to NK1.1 alloantigen is one of the most widespread surface markers of mouse NK and NKT cells in C57BL/6 mice detected by monoclonal antibody PK136. Although functional studies revealed the ability of this receptor to activate both natural killing and production of cytokines upon antibody crosslinking, the ligand for NKR-P1C(B6) remains unknown. In order to initiate ligand identification, structural studies, and epitope mapping experiments, we developed a simple and efficient expression and purification protocol allowing to produce large amounts of pure soluble monomeric mouse NKR-P1C(B6). Our protein encompassed approximately half of the stalk region and the entire C-terminal globular ligand binding domain. The identity of protein that was devoid of N-terminal initiation methionine and had all three expected disulfides closed was confirmed using high resolution ion cyclotron resonance mass spectrometry. Protein produced into inclusion bodies in Escherichia coli was efficiently refolded into a unique three dimensional structure as confirmed by NMR using (1)H-(15)N-HSQC spectra of uniformly labeled protein. The exceptional purity of the protein should allow its crystallization and detailed structural investigations, and is a prerequisite for its use as a probe in ligand identification and antibody epitope mapping experiments.     

Genomic structure and strain-specific expression of the natural killer cell receptor NKR-P1.

NK cells are able to lyse a variety of virally infected and neoplastic cells in an MHC-unrestricted manner. The cell-surface protein NKR-P1 is thought to play a key role in this process. NKR-P1, initially identified in rat IL-2 activated NK cells, is encoded in the mouse by at least three similar, but not identical, genes. We previously reported the isolation and characterization of three different NKR-P1 cDNA, termed cDNA 2, 34, and 40, from IL-2 activated mouse NK cells. This report describes the structure of the gene encoding NKR-P1 cDNA 2, the smallest of these three cDNA. Gene 2 is composed of six exons spanning approximately 14 kb of genomic DNA. The first exon encodes the N-terminal intracellular domain, and exons 4, 5, and 6 contain the sequences coding for the CRD. This organization is similar to that of other genes that encode C-type animal lectins. The expression of the NKR-P1 genes in A-LAK cells from 13 mouse strains was examined by Northern blot analysis. NKR-P1 expression appears to coincide with that of the NK1.1 Ag. This observation further supports the hypothesis that the NK1.1 Ag is encoded by one of the NKR-P1 genes. Nucleotide sequence analysis of the promoter region of the three NKR-P1 genes in BALB/c and C57BL/6 mice suggests that differences in the level of expression probably do not result from alterations in the upstream regions of these genes, but may be caused by the expression of strain-specific transacting factors.     

Chromosomal location of the Ly-49 (A1, YE1/48) multigene family. Genetic association with the NK 1.1 antigen

The Ly-49 (A1, YE1/48) Ag is a disulfide-linked dimer with 44-kDa subunits, and is expressed on the cell surface of rare T cell tumors of C57BL/6 origin. Although this Ag is undetectable by flow microfluorimetry analysis, normal cells have been shown to express the A1 Ag by immunoprecipitation experiments performed on surface radioiodinated spleen and thymus cells. We (J. Immunol. 143:1379, 1989) and others (J. Immunol. 142:1727, 1989) have recently isolated cDNA encoding the Ly-49 Ag. Southern blots with an Ly-49 cDNA probe revealed multiple bands, consistent with cross-hybridization to other members of a multigene family, and significant RFLP between the C57BL/6 and BALB/c strains. When the RFLP patterns displayed by other common laboratory strains as well as informative recombinant inbred strains were examined, the Ly-49 gene family displayed five RFLP patterns and the entire family was found to reside on a contiguous stretch of the distal portion of mouse chromosome 6, the same region to which the NK1.1 Ag has been mapped. Although tissue distribution studies and transfection analysis ruled out the possibility that Ly-49 was identical to NK1.1 Ag, approximately 20% of NK1.1 cells isolated from normal spleen coexpressed Ly-49 and all Ly-49+ cells were CD3-. Although spleen cells cultured in high doses of rIL-2 demonstrated similar coexpression of NK1.1 and Ly-49, approximately 10% of CD3+ cells coexpressed Ly-49. The chromosomal mapping data and the expression of the Ly-49 and NK1.1 Ag suggest that the NK1.1 Ag may be a member of the Ly-49 multigene family.     

The novel inhibitory NKR-P1C receptor and Ly49s3 identify two complementary, functionally distinct NK cell subsets in rats

The proximal region of the NK gene complex encodes the NKR-P1 family of killer cell lectin-like receptors which in mice bind members of the genetically linked C-type lectin-related family, while the distal region encodes Ly49 receptors for polymorphic MHC class I molecules. Although certain members of the NKR-P1 family are expressed by all NK cells, we have identified a novel inhibitory rat NKR-P1 molecule termed NKR-P1C that is selectively expressed by a Ly49-negative NK subset with unique functional characteristics. NKR-P1C(+) NK cells efficiently lyse certain tumor target cells, secrete cytokines upon stimulation, and functionally recognize a nonpolymorphic ligand on Con A-activated lymphoblasts. However, they specifically fail to kill MHC-mismatched lymphoblast target cells. The NKR-P1C(+) NK cell subset also appears earlier during development and shows a tissue distribution distinct from its complementary Ly49s3(+) subset, which expresses a wide range of Ly49 receptors. These data suggest the existence of two major, functionally distinct populations of rat NK cells possessing very different killer cell lectin-like receptor repertoires.     

Protection against diabetes and improved NK/NKT cell performance in NOD.NK1.1 mice congenic at the NK complex

The NK1.1 cell surface receptor, which belongs to the NKR-P1 gene cluster, has been bred onto nonobese diabetic (NOD) mice for two purposes. The first was to tag NK and NKT cells for easier experimental identification of those subsets and better analysis of their implication in type 1 diabetes. The second was to produce a congenic strain carrying Idd6, a susceptibility locus that has been repeatedly mapped in the vicinity of the NKR-P1 gene cluster and the NK complex, to explore the impact of this locus upon autoimmune diabetes. NOD.NK1.1 mice express the NK1.1 marker selectively on the surface of their NK and NKT cell subsets. In addition, the mice manifest reduced disease incidence and improved NK and NKT cell performance, as compared with wild-type NOD mice. The association of those two features in the same congenic strain constitutes a strong argument in favor of Idd6 being associated to the NK complex. This could explain at the same time the multiple alterations of innate immunity reported in NOD mice and the fact that disease onset can be readily modified by boosting the innate immune system of the mouse.     

Association of human NK cell surface receptors NKR-P1 and CD94 with Src-family protein kinases

 Human natural killer (NK) cells express on their surface several members of the C-type lectin family such as NKR-P1, CD94, and NKG2 that are probably involved in recognition of target cells and delivery of signals modulating NK cell cytotoxicity. To elucidate the mechanisms involved in signaling via these receptors, we solubilized in vitro cultured human NK cells by a mild detergent, Brij-58, immunoprecipitated molecular complexes containing the NKR-P1 or CD94 molecules, respectively, by specific monoclonal antibodies, and performed in vitro kinase assays on the immunoprecipitates. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis, autoradiography, and phospho-amino acid analysis revealed the presence of in vitro tyrosine phosphorylated proteins that were subsequently identified by re-precipitation (and/or by western blotting) as the respective C-type lectin molecules and Src family kinases Lck, Lyn, and Fyn. The NKR-P1 and the CD94-containing complexes were independent of each other and both very large, as judged by Sepharose 4B gel chromatography. Crosslinking of NKR-P1 on the cell surface induced transient in vivo tyrosine phosphorylation of cellular protein substrates. These results indicate involvement of the associated Src-family kinases in signaling via the NKR-P1 and CD94 receptors. Received: 4 February 1997 / Revised: 28 February 1997