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.     

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.     

Stimulation of murine natural killer (NK) cells by a monoclonal antibody specific for the NK1.1 antigen. IL-2-activated NK cells possess additional specific stimulation pathways

NK cells lyse certain tumor cell targets but the effector cell surface molecules responsible for this reactivity remain uncertain. The allotypic NK1.1 Ag is the most specific serologic marker on murine cells that display non-MHC-restricted cytolysis of tumor cell targets, but no function has been previously ascribed to this Ag. In this report, we demonstrate that, in the presence of a mAb specific for the NK1.1 Ag (mAb PK136), freshly isolated and IL-2-activated NK cells from C57BL/6 mice can be induced to lyse an otherwise resistant target cell, Daudi. This phenomenon is effector and mAb specific because NK cells derived from BALB/c mice do not express the NK1.1 Ag and cannot be triggered by mAb PK136. We demonstrate that IL-2 activated but not freshly isolated NK cells express the Ly-6 and VEA Ag, originally described as T cell activation Ag. Moreover, mAb specific for Ly-6 and VEA induce target cell lysis by IL-2 activated but not freshly isolated NK cells. These mAb effects are specific, concentration dependent, and display kinetics that are similar to spontaneous cytolysis of NK-sensitive targets. The Fc portion of the activating antibodies and only FcR bearing target cells participate in mAb-induced activation, consistent with the mechanism of redirected lysis. Finally, analysis of Daudi cells transfected with beta 2-microglobulin gene demonstrate that the expression of MHC class I Ag by the target cell does not affect its sensitivity to mAb-induced lysis by NK cells. These data demonstrate that the NK1.1 Ag is functionally active on both freshly isolated and IL-2-activated NK cells and that IL-2-activated NK cells possess additional pathways of specific stimulation.     

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.     

Analysis of a 1-Mb BAC contig overlapping the mouse Nkrp1 cluster of genes: cloning of three new Nkrp1 members, Nkrp1d, Nkrp1e, and Nkrp1f

The murine Nkrp1 gene family encodes three previously identified activation and inhibitory receptors expressed on natural killer (NK) cells. This family includes the gene for NKR-P1C (NK1.1), the most specific serologic marker on C57BL/6-derived NK cells and is localized in a gene cluster in the NK gene complex (NKC). To further analyze the Nkrp1 family, we constructed and analyzed a bacterial artificial chromosome contig. A genomic organization of the Nkrp1 family was obtained and three new Nkrp1 genes were isolated from interleukin-2-activated NK cells. Thus, the Nkrp1 family adds to the repertoire of receptors expressed by NK cells.     

Heterogeneity of natural killer cell subsets in NK-1.1+ and NK-1.1- inbred mouse strains and their progeny.

The 4LO3311 monoclonal antibody, a new NK-specific reagent recently produced in our laboratory, reacts with spleen cells of 11 mouse strains, most of which do not express the NK-1.1 alloantigen recognized by the PK136 mAb. Among positive strains, the susceptibility of spleen cells to the complement-dependent NK-inhibiting activity of the 4LO3311 mAb was variable but independent of the initial NK cell activity level of cells tested. This property was furthermore not modified after poly(I:C) stimulation. The susceptibility of spleen cells to the in vitro 4LO3311 mAb plus complement treatment is however influenced by the absolute number of 4LO3311+ cells as well as by the density of the corresponding alloantigen at the cell surface. Moreover, it was established that the strain-related variations observed also depended upon the relative size of the 4LO3311 cell subset within the lytic NK cell population. Indeed, when C3H (NK-1.1-4LO3311+) mice were inoculated with the 4LO3311 mAb, the lytic activity of their spleen cells was almost unaltered but 4LO3311-reactive cells were no longer detected in the spleen of treated animals and remaining NK cells were totally resistant to the in vitro 4LO3311 mAb plus complement treatment. These findings indicate that the 4LO3311 mAb identifies a subset rather than all NK cells, even in a NK-1.1- strain. Since a NK-1.1-unreactive cell subset was identified in NZB (NK-1.1+4LO3311-) mice inoculated with the PK136 mAb, the NK-1.1+ cell population is not necessarily responsible for all the splenic NK cell activity in all NK-1.1+ strains. In B6C3F1 hybrid mice, a relatively large subset of NK-1.1-4LO3311- cells was found in addition to those expressing the NK-1.1, the 4LO3311 alloantigen, or both. According to these results, NK cell heterogeneity should thus be taken as an evolving concept whose resolution appears more and more complex with the identification of new NK-specific reagents.     

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.     

Molecular cloning of the NK1.1 antigen, a member of the NKR-P1 family of natural killer cell activation molecules.

In mice, the NK1.1 alloantigen is expressed on all NK cells and it initiates transmembrane signals that activate cytotoxicity. NK1.1 has been mapped to a chromosomal region that encodes two families of receptor-like molecules, the NKR-P1 family and the Ly-49 family. Both of these gene families encode type II integral membrane proteins whose extracellular domains are homologous with known C-type lectins. We have isolated and expressed a member of the NKR-P1 gene family (mNKR-P1.9) and have demonstrated both by immunofluorescence and by immunoprecipitation that this cDNA encodes NK1.1. These findings, which demonstrate the receptor-like structure of NK1.1, will facilitate studies regarding the role of NK1.1 in natural killing and regarding the identification of possible NK1.1 ligands.     

LGL-1: a non-polymorphic antigen expressed on a major population of mouse natural killer cells

Rat mAb have been raised to mouse liver-derived large granular lymphocytes (LGL). One of these mAb (4D11) binds specifically to mouse LGL and appears to recognize a non-allelic determinant on NK-active cell populations. The Ag recognized by 4D11 is expressed on LGL of all mouse strains tested, including C57BL/6 (B6), BALB/c, C3H/HeJ, and SJL/J; thus, we have provisionally called this Ag LGL-1. Analysis of various lymphoid and hemopoietic tissues has indicated that only normal tissues known to contain NK activity have 4D11+ cells. With B6 and B6 congenic strains, a positive correlation exists between the number of LGL in a sample and the percentage of 4D11 immunofluorescence-positive cells detected by flow cytometric analysis. Dual color immunofluorescence analyses indicate that some LGL-1+ cells are also stained for Ly-1 and Thy-1. A very small subset exists that is weakly positive for CD3 and LGL-1. However, virtually no cells are seen which co-express LGL-1 and Ly-2. LU activity against YAC-1 targets was increased 7- to 700-fold in LGL-1+ spleen cells obtained by cell sorting from several different strains of mice (B6, BALB/c, C3H/HeJ, SJL/J, and athymic/nude). Sorted, LGL-1- spleen cells contained little or no NK activity. Cells positively selected for LGL-1 also contained between 50 and 60% LGL by morphology. By using facilitated in vitro antibody plus C' treatments, the majority of NK activity can be depleted from both B6 spleen and liver-derived leukocyte populations enriched for NK cells. mAb 4D11 was also shown to precipitate a protein of approximately 87 kDa from the surface of enriched murine NK cells. This mAb should prove valuable for understanding the role of NK cells in the immune response.     

Mouse NKR-P1B, a novel NK1.1 antigen with inhibitory function

The mouse NK1.1 Ag originally defined as NK cell receptor (NKR)-P1C (CD161) mediates NK cell activation. Here, we show that another member of the mouse CD161 family, NKR-P1B, represents a novel NK1.1 Ag. In contrast to NKR-P1C, which functions as an activating receptor, NKR-P1B inhibits NK cell activation. Association of NKR-P1B with Src homology 2-containing protein tyrosine phosphatase-1 provides a molecular mechanism for this inhibition. The existence of these two NK1.1 Ags with opposite functions suggests a potential role for NKR-P1 molecules, such as those of the Ly-49 gene family, in regulating NK cell function.     

Characterization of Effector Cells against B16 Melanoma in Mice Inoculated with Allogeneic Spleen Cells

Inbred C57BL/6 (B6) mice which had received an inoculation of allogeneic spleen cells showed remarkable antitumor activity against syngeneic tumor challenge with B16 melanoma cells 3 days after the allogeneic cell inoculation. This antitumor activity was not specific to the inoculated alloantigen, since the challenging B16 cells are syngeneic to B6 mice and since it was induced by BALB/c spleen cells as well as C3H/He spleen cells. The antitumor activity was sensitive to an in vivo treatment with anti-asialo GM1 (AGM1) antiserum or anti-Thy.1 monoclonal antibody (mAb) just before the tumor challenge and was resistant to an in vivo treatment with anti-CD8 (Ly. 2) mAb. These results suggest that AGM1+Thy.1+CD8– activated natural killer (NK) cells were generated by alloantigen inoculation and took an important part in the antitumor effect of the alloantigen inoculation.     

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.     

Studies on murine natural killer (NK) cells. V. Genetic analysis of NK cell markers

This paper attempts to clarify the number and nomenclature of murine natural killer (NK) cell specific alloantigens by defining the genetic relationships between them, that is, are they coded by loci which are independent, allelic, or linked. Strain typing and F2 analyses using five alloantisera (C3H X BALB/c)F1 anti-CE, CE anti-CBA, NZB anti-BALB/c, C3H anti-ST, and BALB/c anti-DBA/2 revealed that (a) the alloantigens NK-1.1 and NK-3.1 are determined by distinct loci which are linked on the same chromosomes, (b) the alloantigen NK-2.1 is determined by an independently segregating locus to those coding for NK-1.1 and NK-3.1, (c) the alloantisera, CE anti-CBA and NZB anti-BALB/c, which have been designated anti-NK-2.1 alloantisera recognize different alloantigens coded by independent genetic loci. Thus, these five alloantisera detect four NK cell specific alloantigens which, based on the chronology of their discovery, have been designated NK-1.1-(C3H X BALB/c)F1 anti-CE, NK-2.1-CE anti-CBA, NK-3.1-C3H anti-ST, and BALB/c anti-DBA/2 and NK-4.1-NZB anti-BALB/c.     

Murine NK cell heterogeneity: subpopulations of C57BL/6 splenic NK cells detected by NK-1.1 and NK-2.1 antisera

NK-1.1 antiserum - (BALB/c X C3H)F1 anti-CE - and NK-2.1 antiserum - NZB anti-BALB/c - detect genetically distinct alloantigens on C57BL/6 natural killer (NK) cells. We have analyzed whether these two alloantigens are associated with functional subsets of NK cells. For this study, nylon wool nonadherent C57BL/6 spleen cells (SC) were treated with complement (C) and NK-1.1 or NK-2.1 antisera and then tested for NK activity against a panel of tumor targets in 6- and 19-hour 51Cr release assays. The NK activity against the prototype NK target YAC-1 was reduced equally by both antisera. Similar reductions by both antisera were also observed when SC were tested against another murine lymphoma target, L5178c127v, against the C57BL/6 melanoma B16, and against the human liver cell line Chang. In contrast, NK activity to the lymphoma FBL-3 and the human erythroleukemia K562 was significantly reduced in SC treated with NK-2.1 antiserum and C, whereas SC treated with NK-1.1 antiserum and C showed either less reduction or no reduction in activity against these two cell lines. With two other targets, E male G2 and RBL-5, neither serum produced significant depletion of activity, Analysis of SC indirectly labeled with either NK-1.1 or NK-2.1 antiserum and fluorescein-labeled goat anti-mouse Ig, however, did not detect significant differences between NK-1+ and NK-2+ cell populations.     

Suppression of murine NK activity induced by Corynebacterium parvum

Summary Formalin-killed Corynebacterium parvum (CP), given at a dose of 0.4–0.7 mg/mouse IV or IP, induced suppressor cells for NK activity in B6C3F₁ mice. The suppressor cells belong to at least two different populations, plastic adherent and nonadherent, and were not depleted by antibodies specific for Thy-1.2, Ia^k, or NK-1.2 surface markers. Administration of p-I:C, an interferon-inducer, to animals 18 h before the assay did not affect the suppressor activity. Hypotonic shock treatment of splenocytes abrogated the in vitro suppressive activity, and subsequent reconstitution of the shock-treated cells with RBC failed to restore the suppressive activity. SJL/J mice, which have low NK activity, exhibited suppressor activity comparable to B6C3F₁ mice following CP treatment, whereas CP-treated BALB/c athymic and euthymic mice showed a lower ability to generate suppressors for NK as compared to B6C3F₁ mice.     

Expression of murine killer immunoglobulin-like receptor KIRL1 on CD1d-independent NK1.1<Superscript>+</Superscript> T cells

Three mouse killer immunoglobulin-like receptors (KIRs), namely, KIR3DL1, KIRL1, and KIRL2, have recently been identified in C56BL/6 (B6) mice. However, only two Kir genes are found in the B6 mouse genome sequence data base. To clarify this discrepancy, we cloned Kir cDNAs from multiple strains of mice. Sequencing of the cDNA clones showed that the Kir3dl1 gene is found in C3H/HeJ and CBA/J but not in B6 mice. Analysis of the single nucleotide polymorphism data base suggested that Kir3dl1 is the C3H/HeJ and CBA/J allele of Kirl1. We generated mAb to the recombinant KIRL1 protein to investigate its expression pattern. The anti-KIRL1 mAb bound to NK1.1⁺ T cells but only very weakly or at undetectable levels to other lymphocytes including natural killer (NK) cells and conventional T cells. Among NK1.1⁺ T cells, conventional NK T cells stained with CD1d tetramer did not significantly bind anti-KIRL1 mAb, whereas CD1d-tetramer-negative subset was KIRL1-positive. Furthermore, the expression of KIRL1 is readily detected on NK1.1⁺ T cells from β₂-microglobulin-deficient B6 mice. Thus, KIRL1 is predominantly expressed on CD1d-independent NK1.1⁺ T cells.     

Oral administration of high molecular mass poly-gamma-glutamate induces NK cell-mediated antitumor immunity

We analyzed the in vivo tumor regression activity of high molecular mass poly-gamma-glutamate (gamma-PGA) from Bacillus subtilis sups. chungkookjang. C57BL/6 mice were orally administered 10-, 100-, or 2000-kDa gamma-PGA or beta-glucan (positive control), and antitumor immunity was examined. Our results revealed higher levels of NK cell-mediated cytotoxicity and IFN-gamma secretion in mice treated with higher molecular mass gamma-PGA (2000 kDa) vs those treated with lower molecular mass gamma-PGA (10 or 100 kDa) or beta-glucan. We then examined the effect of oral administration of 10- or 2000-kDa gamma-PGA on protection against B16 tumor challenge in C57BL/6 mice. Mice receiving high molecular mass gamma-PGA (2000 kDa) showed significantly smaller tumor sizes following challenge with the MHC class I-down-regulated tumor cell lines, B16 and TC-1 P3 (A15), but not with TC-1 cells, which have normal MHC class I expression. Lastly, we found that gamma-PGA-induced antitumor effect was decreased by in vivo depletion of NK cells using mAb PK136 or anti-asialo GM1 Ab, and that was completely blocked in NK cell-deficient B6 beige mice or IFN-gamma knockout mice. Taken together, we demonstrated that oral administration of high molecular mass gamma-PGA (2000 kDa) generated significant NK cell-mediated antitumor activity in mice bearing MHC class I-deficient tumors.     

NK cells regulate CD4 responses prior to antigen encounter

NK cells not only respond rapidly to infection, shaping subsequent adaptive immunity, but also play a role in regulating autoimmune disease. The ability of NK cells to influence adaptive immunity before Ag exposure was examined in a gender-dependent model of preferential Th1 and Th2 activation. The inability of young adult male SJL mice to activate Th1 cells was reversed via depletion of NK1.1(+) cells, whereas the presence or the absence of NK1.1(+) cells did not alter responses in age-matched females. Consistent with a gender-dependent role in regulating adaptive immunity, significantly more NK1.1(+) cells were present in males compared with females, and this difference was reversed by castration. In contrast to NK1.1(+) cells derived from C57BL/6 mice, no spontaneous cytokine secretion was detected in NK1.1(+) cells derived from either male or female SJL mice, although an increased frequency of IL-10-secreting NK1.1(+) cells was observed in males vs females following in vitro stimulation. Direct evidence that NK1.1(+) cells in males influence CD4(+) T cell activation before Ag exposure was demonstrated via the adoptive transfer of APC from control and NK1.1-depleted males. The absence of a functional NK T cell population in SJL mice suggests that NK cells influence adaptive immunity before Ag exposure via alterations in APC activity.