Association with FcRgamma Is Essential for Activation Signal through NKR-P1 (CD161) in Natural Killer (NK) Cells and NK1.1+ T Cells

By Noriko Arase,* Hisashi Arase,* Seung Yong Park,* Hiroshi Ohno,* Chisei Ra,Dagger and Takashi Saito*

From the * Division of Molecular Genetics, Center for Biological Science, Chiba University School of Medicine, Chiba 260, Japan; and the Dagger  Department of Immunology, Juntendo University School of Medicine, Tokyo 113, Japan

SUMMARY
Materials and Methods
Results
Discussion
FOOTNOTES
ACKNOWLEDGEMENTS
References


Summary

Natural killer (NK) cells exhibit cytotoxicity against variety of tumor cells and virus-infected cells without prior sensitization and represent unique lymphocytes involved in primary host defense. NKR-P1 is thought to be one of NK receptors mediating activation signals because cross-linking of NKR-P1 activates NK cells to exhibit cytotoxicity and IFN-gamma production. However, molecular mechanism of NK cell activation via NKR-P1 is not well elucidated. In this study, we analyzed the cell surface complex associated with NKR-P1 on NK cells and found that NKR-P1 associates with the FcRgamma chain which is an essential component of Fc receptors for IgG and IgE. The association between FcRgamma and NKR-P1 is independent of Fc receptor complexes. Furthermore, NK cells from FcRgamma -deficient mice did not show cytotoxicity or IFN-gamma production upon NKR-P1 cross-linking. Similarly, NK1.1+ T cells from FcRgamma -deficient mice did not produce IFN-gamma upon NKR-P1 crosslinking. These findings demonstrate that the FcRgamma chain plays an important role in activation of NK cells via the NKR-P1 molecule.


NK cells play a pivotal role in protective immunity. Especially, NK cells are involved in the earliest stage of immune response because they can exhibit cytotoxicity or cytokine production without prior sensitization (1). Therefore, it is important to elucidate the mechanism of antigen recognition by NK cells to understand innate immunity. Recent analyses have revealed that various types of receptors are involved in the regulation of NK cell activation (2, 3). Among these, the NKR-P1 molecule is thought to be one of NK receptors which mediates NK cell activation because cross-linking of NKR-P1 induces various activation signals such as, Ca2+ flux, PI turnover and lymphokine production (4, 5). The NKR-P1 was originally cloned from rat NK cells (4, 5), and subsequently cloned from mouse and human (6, 7). In mouse NK cells, NK1.1, a specific marker of mouse NK cells, is one of NKR-P1 family molecules, NKR-P1C (8).

NK cells exhibit cytotoxicity and IFN-gamma production upon cross-linking of NKR-P1 molecule with specific mAb (4, 5, 9, 10). Indeed, introduction of NKR-P1 into a NKR-P1-deficient NK cell line restored cytotoxicity against certain tumor cell targets (11). Furthermore, anti-NKR-P1 mAb blocked the cytotoxicity by the NKR-P1-transfected NK cells (11). Therefore, NKR-P1 seems to be involved in the antigen recognition by NK cells. Although the exact ligand for NKR-P1 remains to be determined, NKR-P1 belongs to the C-type lectin superfamily and certain carbohydrates expressed on target cells are postulated to be recognized by the NKR-P1 molecule (12).

In respect to the signaling pathway for NKR-P1, it has been shown that NKR-P1 crosslinking stimulates PI turnover and raises intracellular Ca2+ concentration (13). In addition, NKR-P1 possesses a p56lck-binding motif which is represented by YxxL sequence and indeed the association of p56lck to NKR-P1 was recently reported (14). However, essential components for NK cell activation via the NKR-P1 molecule have not been elucidated. In the present study, we analyzed the cell surface complex associated with the NKR-P1 molecule and found that the FcRgamma chain is associated with NKR-P1. Furthermore, the analysis of NK cells from FcRgamma -deficient mice revealed that the FcRgamma chain is essential for mediating activation signals via NKR-P1.


Materials and Methods

Mice. FcRgamma -deficient (gamma -/-)1 mice with C57BL/6 background were established by gene targeting using a C57BL/6 origin ES cell line BL6/III (15) in our laboratory (Park, S.Y. et al., manuscript submitted, 16, 17) and maintained in our animal facility in SPF condition.

NK Cell Preparation. NK cells were purified as previously described (18). In brief, NK cells were purified from spleen of 6-8-wk-old C57BL/6 mice. Splenocytes were mixed with anti-CD4 mAb (GK1.5) and anti-CD8 mAb (53.6.7), and incubated with magnetic beads (Advanced Magnetics, Inc., Cambridge, MA) coupled with goat anti-mouse IgG Ab and goat anti-rat IgG Ab (Cappel, Organon Teknika Co., West Chester, PA) to remove surface Ig (sIg)+ B cells and CD4+ and CD8+ T cells. The residual cells were then stained with PE-anti-NK1.1 (PK136) mAb and FITC-anti-CD3epsilon (145-2C11) mAb (Pharmingen, San Diego, CA) and NK1.1+ CD3- cells were sorted by FACStarplus® (Becton Dickinson, Mountain View, CA). The purified NK cells were cultured in RPMI-1640 supplemented with 10% FCS, kanamycin (100 µg/ml) and 5 × 10-5 M 2-ME in the presence of 1,000 U/ml human recombinant IL-2 (kindly provided by Dr. Junji Hamuro, Ajinomoto Co. Inc., Kawasaki, Japan) for 5 d.

Flow Cytometric Analysis of NK Cells. CD4-CD8-sIg- splenocytes prepared as described above were cultured for 4 d in the presence of 1,000 U/ml IL-2. The cultured cells were first stained with FITC-anti-Fcgamma RIII (2.4G2) mAb. Then, the cells were mixed with Biotin-anti-CD3epsilon and PE-anti-NK1.1 mAbs followed by Quantum-red streptavidin (Sigma Chem. Co., St. Louis, MO).

NK1.1+ T Cell Preparation. Basically, NK1.1+ T cells were prepared as previously described (10). Thymocytes were treated with anti-HSA mAb (J11d) followed by complement treatment. The resultant cells were incubated with anti-CD8 and anti-MEL-14 mAb. Thereafter, CD8+ MEL-14+ cells were removed by use of magnetic beads coupled with goat anti-rat IgG Ab. The residual cells were cultured for 3 d in the presence of 1,000 U/ml IL-2. Thereafter, cells were stained with PE-anti-NK1.1 mAb and FITC-anti-CD3epsilon mAb. The stained cells were sorted into NK1.1+CD3+ cells. The sorted cells were further cultured for 2 d in the presence of 1,000 U/ml IL-2 and used for functional analysis.

Surface Biotinylation, Immunoprecipitation and Western Blotting. Cells were surface biotinylated as previously described (19). Biotinylated cells were lysed with a lysis buffer containing 1% digitonin, 50 mM Tris-HCl (pH 7.6), 150 mM NaCl, 10 µg/ml aprotinin, 10 µg/ml leupeptin, 1 mM PMSF, 10 mM iodoacetamide, at a concentration of 1 × 107 cell/ml. Immunoprecipitation was performed with anti-CD3epsilon or anti-NK1.1 mAbs. Immunoprecipitates were separated on two-dimensional nonreducing and reducing SDS-PAGE and transferred onto a polyvinylidene difluoride (PVDF) membrane (Immobilon-P; Millipore Corporation, Bedford, MA). The biotinylated proteins were detected using streptavidin-peroxidase (VECSTAIN Elite ABC kit; Vector Laboratories Incorporated, Burlingame, CA), the ECL system (Amersham International, Buckinghamshire, England), and autoradiography. After termination of chemiluminescence, the membrane was blotted with anti-FcRgamma Ab followed by peroxidase-labeled anti-rabbit Ab (Amersham) and detected by the ECL system.

NKR-P1 and TCR Stimulation. (Fab)'2 fragment of anti-NK1.1 mAb was immobilized on a 96-well flat-bottomed culture plate (Coaster, Cambridge, MA) by incubating for 2 h at 37°C at a concentration of 50 µg/ml in PBS. Similarly, anti-TCR-beta mAb (H57-597) was immobilized at a concentration of 100 µg/ml. 1 × 105 NK cells cultured for four days in the presence of IL-2 were stimulated with the immobilized anti-NK1.1 mAb, or with recombinant mouse IL-12 (4.9 × 106 U/mg, generously supplied from Genetics Institute, Inc., Cambridge, MA) for 2 d.

Measurement of IFN-gamma and IL-4. IFN-gamma and IL-4 in the culture supernatant was measured by ELISA with standard protocol. Anti-IFN-gamma (R4-6A2) and anti-IL-4 (BVD4-1D11) mAb was coated to capture IFN-gamma and IL-4 and the captured IFN-gamma and IL-4 were detected with biotinylated anti-IFN-gamma (XMG1.2) and anti-IL-4 (BVD6-24G2) mAbs. These antibodies were purchased from Pharmingen. Concentrations of IFN-gamma and IL-4 were determined with recombinant IFN-gamma and IL-4 as a standard.

Redirected Cytotoxicity of NK Cells. Cytotoxic assay was done basically as previously described (20). Briefly, freshly isolated CD4- CD8- HSA- sIg- population was used as NK cell enriched population. About 50% of this population expressed the NK1.1 molecule. These NK cells were incubated at 4°C for 30 min in the presence or absence of anti-NK1.1 mAb. Thereafter, 51Cr-labeled FcR-expressing P815 cells were added and cultured at 37°C for 4 h and analyzed the amount of Cr51 released in the culture supernatant. Specific cytotoxicity was calculated as previously described (20).


Results

To elucidate signaling pathways for NK cell activation through NKR-P1, we analyzed the NKR-P1-associated complex on the cell surface using an NK1.1-expressing T cell line CTLL-2. CTLL-2 cells were surface-biotinylated and the cell lysate was immunoprecipitated with anti-NK1.1 or anti-CD3epsilon mAbs, followed by analysis on two dimensional nonreducing and reducing SDS-PAGE.

As shown in Fig. 1 A, immunoprecipitation with anti-NK1.1 mAb revealed that a 9-kD homodimer was coprecipitated with NK1.1 molecule. In contrast, when the TCR complex was precipitated with anti-CD3epsilon mAb, CD3zeta homodimers, CD3zeta -FcRgamma heterodimers and a small amount of FcRgamma homodimers were observed as previously reported (21). Interestingly, the 9-kD homodimers coprecipitated with NK1.1 appeared to be identical to FcRgamma within the TCR complex. Indeed, the homodimers coprecipitated with NK1.1 were blotted with anti-FcRgamma Ab similarly to FcRgamma observed in the CD3epsilon -immunoprecipitates (Fig. 1 B). The association of the FcRgamma chain with the NKR-P1 molecule was also observed in a rat NK cell line, RNK-16 (data not shown). We next analyzed normal NK cells to generalize the physical association between FcRgamma and NKR-P1 in normal NK cell population. Similar to CTLL-2, when NK1.1 was immunoprecipitated from IL-2 activated NK cells, the FcRgamma homodimer was coprecipitated with NK1.1 (Fig. 2). Collectively, these data indicate that the association of FcRgamma with NKR-P1 is generally observed for NK cells in vivo.


Fig. 1. Association of the FcRgamma chain with the NKR-P1 molecule on the cell surface of CTLL-2 cell line. (A) CTLL-2 cells were surface-biotinylated and the cell lysate was immunoprecipitated with anti-NK1.1 mAb or anti-CD3epsilon mAb and analyzed on two-dimensional nonreducing (NR) and reducing (R) SDS-PAGE. Biotinylated proteins were detected by an ECL. (B) FcRgamma chain was detected by blotting the membrane with anti-FcRgamma Ab after immunoprecipitation with anti-NK1.1 or anti-CD3epsilon mAbs. FcRgamma homodimer (gamma -gamma ) and CD3zeta -FcRgamma heterodimers (zeta -gamma ) were indicated.
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Fig. 2. Association of the FcRgamma chain with the NKR-P1 molecule in IL-2-expanded NK cells. NK cells from normal mice expanded for 1 wk in the presence of IL-2 and were surface-biotinylated. The cell lysate of them was immunoprecipitated with anti-NK1.1 mAb ((Fab)'2 fragment) and analyzed on two-dimensional nonreducing (NR) and reducing (R) SDS-PAGE. Biotinylated proteins were detected as Fig. 1 A. FcRgamma homodimer (gamma -gamma ) was indicated.
[View Larger Version of this Image (44K GIF file)]

To elucidate the physiological role of the association between FcRgamma and NKR-P1 particularly on signal transduction in NK cells, NK cells were prepared from gamma -/- mice and analyzed for NKR-P1 expression and NKR-P1-mediated NK cell activation. When CD4-CD8-sIg- splenocytes from gamma -/- mice were stained with anti-NK1.1 and anti-CD3epsilon mAbs, normal development of NK cells (NK1.1+CD3-) was observed (data not shown). When expression of Fcgamma RIII on IL-2-expanded NK cells was analyzed, NK cells from gamma -/- mice did not express Fcgamma RIII (Fig. 3). In addition, the expression level of NK1.1 on the cell surface of IL-2-expanded NK cells from gamma -/- mice was significantly lower than that of NK cells from gamma +/+ and gamma +/- mice. However, the difference of NK1.1 expression between gamma -/- and gamma +/- mice was marginal when freshly isolated NK cells were analyzed (data not shown). This suggested that FcRgamma is not absolutely required for but affects the surface expression of the NKR-P1 molecule.


Fig. 3. Loss of the cell surface expression of Fcgamma RIII on NK cells from gamma -/- mice. CD4-CD8-HSA-sIg- splenocytes from gamma +/+, gamma +/- and gamma -/- mice were cultured for 4 d in the presence of 1,000 U/ml IL-2. The cultured cells were stained with FITC-anti-Fcgamma RIII, PE-anti-NK1.1 and Quantum red-anti-CD3epsilon mAbs and the expression of Fcgamma RIII and NK1.1 on the CD3- population was illustrated. Representative data from five independent experiments are shown.
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Recently, we have shown that cross-linking of NKR-P1 on NK cells with anti-NK1.1 mAb induced not only cytotoxicity but also IFN-gamma production (10). Thus, we stimulated purified NK cells from gamma -/- mice with immobilized F(ab)'2 fragment of anti-NK1.1 mAb in order to avoid the binding of the Ab to Fc receptors, and measured the amount of IFN-gamma produced in the culture supernatant. Surprisingly, NK cells from gamma -/- mice did not produce IFN-gamma at all upon NKR-P1 cross-linking, whereas NK cells from gamma +/+ mice produced a large amount (Fig. 4). In contrast, NK cells from both gamma -/- and gamma +/+ mice produced almost equal amount of IFN-gamma upon IL-12 stimulation. This suggests that the defect of IFN-gamma production upon NKR-P1 cross-linking by NK cells from gamma -/- mice is not due to the inability of IFN-gamma production but the signaling defect via NKR-P1.


Fig. 4. Defect of IFN-gamma production by NK cells from gamma -/- mice upon stimulation with NK1.1 cross-linking. NK cells from gamma +/+ (closed bar) and gamma -/- (open bar) mice were stimulated with immobilized (Fab)'2 fragment of anti-NK1.1 mAb or 1 ng/ml IL-12 and IFN-gamma produced in the culture supernatant was measured. Data are presented as mean ± SD of triplicate culture.
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Because NK1.1+ T cells also produce IFN-gamma but not IL-4 upon NKR-P1 cross-linking (10), we also analyzed the function of NK1.1+ T cells in gamma -/- mice. As we have previously reported (22), NK1.1+ T cells develop normally in gamma -/- mice. NK1.1+ T cells were prepared from gamma +/+ and gamma -/- mice and stimulated with immobilized anti-NK1.1 mAb (Fig. 5). Similar to NK cells, NK1.1+ T cells from gamma -/- mice did not produce IFN-gamma upon NKR-P1 cross-linking whereas these cells from gamma +/+ mice produced a significant amount of IFN-gamma . In contrast to the stimulation through NKR-P1, NK1.1+ T cells from both gamma +/+ and gamma -/- mice produced IFN-gamma and IL-4 upon TCR crosslinking. These observations demonstrate that the FcRgamma chain is required for IFN-gamma production via NKR-P1 cross-linking both in NK cells and NK1.1+ T cells.


Fig. 5. Defect of IFN-gamma production by NK1.1+ T cells from gamma -/- mice upon stimulation with NK1.1 cross-linking. NK1.1+ T cells from gamma +/+ (closed bar) and gamma -/- (open bar) mice were stimulated with immobilized anti-NK1.1 mAb or anti-TCRbeta mAb and IFN-gamma and IL-4 produced in the culture supernatant was measured. Data are presented as mean ± SD of triplicate culture.
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We also investigated the involvement of FcRgamma in the NKR-P1-mediated cytotoxicity of NK cells. Since NKR-P1 is known to induce redirected cytotoxicity against FcR-expressing cells, we analyzed cytotoxicity of NK cells against FcR-expressing P815 cells in the presence of anti-NK1.1 mAb (Fig. 6). NK cells from gamma +/+ and gamma +/- mice showed increased cytotoxicity against P815 cells in the presence of anti-NK1.1 mAb, whereas NK cells from gamma -/- mice failed to enhance cytotoxicity. These results demonstrate that FcRgamma is involved in both IFN-gamma production and cytotoxicity upon stimulation through the NKR-P1 molecule.


Fig. 6. Defect of NK1.1 mediated cytotoxicity by NK cells from gamma -/- mice. Cytotoxicity of NK cells from gamma +/+, gamma +/-, and gamma -/- mice against P815 cell line was analyzed in the presence (open circles) or absence (closed circles) of anti-NK1.1 mAb. Data are presented as mean ± SD of triplicate assay.
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The failure of NK cell activation through NKR-P1 in gamma -/- mice is likely due to a defect in signaling pathway of the NKR-P1 molecule. However, since the NK1.1 expression on the cell surface of NK cells from gamma -/- mice is slightly lower than that of gamma +/- and gamma +/+ mice, it might be attributed to the low expression of the cell surface NKR-P1. To clarify these possibilities, we prepared two populations of NK cells from normal mice expressing low or high level of NKR-P1 (NKR-P1lo and NKR-P1hi, respectively) by cell sorting. The expression level of NKR-P1 on the NKR-P1lo population was almost identical to that of NK cells from gamma -/- mice. (Fig. 7, A and B). Then, we stimulated these NK cell populations with immobilized anti-NK1.1 mAb. NKR-P1lo NK cells from gamma +/+ mice produced significant amount of IFN-gamma upon NKR-P1 cross-linking, although the amount of IFN-gamma was lower than that by NKR-P1hi NK cells (Fig. 7 C). In contrast, NK cells from gamma -/- mice did not produce any detectable level of IFN-gamma upon NKR-P1 cross-linking. These observations confirm the crucial role of FcRgamma in signaling pathway through NKR-P1 for NK activation and also demonstrate that FcRgamma is partly involved in the expression of the cell surface NKR-P1.


Fig. 7. Activation defect of NK cells from FcRgamma -deficient mice upon NKR-P1 crosslinking is not due to the low level of NKR-P1 expression. (A) NK1.1 expression on NK cells from gamma +/+ and gamma -/- mice. NK cells from gamma +/+ or gamma -/- mice were stained with anti-NK1.1 mAb (solid line) or control Ab (dotted line). (B) Preparation of NK cell population expressing high (hi) and low (lo) level of NKR-P1 from wild-type mice. (C) Production of IFN-gamma by NK cell population expressing low NKR-P1 upon stimulation with immobilized anti-NK1.1 mAb. Two NK cell populations expressing high (NK1.1hi) and low (NK1.1lo) level of NK1.1 as shown in B from gamma +/+ mice and NK cells from gamma -/- mice were stimulated with immobilized (Fab)'2 fragment anti-NK1.1 mAb and IFN-gamma production was measured.
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Discussion

FcRgamma was originally identified in the Fcepsilon RI complex and found to play an essential role in the expression and signaling of Fcepsilon RI (23). FcRgamma was also found to be required for the expression and function of Fcgamma RI, Fcgamma RIII and Fcalpha R (24, 25). On the other hand, we found that FcRgamma also associates with the TCR complexes in two types of T cells. One is T cells in epithelia such as CD8alpha alpha + TCR-gamma /delta + intestinal intraepitherial lymphocytes and TCR gamma /delta + dendritic epidermal cells and the association with FcRgamma in these cells was shown in vivo from the analysis of CD3zeta -deficient mice (26). The second population is NK1.1+ TCR-alpha /beta + T cells. (22). However, these T cells obtained from gamma -/- mice showed no clear defect in function upon TCR activation, although the expression level of the TCR complex was slightly decreased (27). Accordingly, it is striking that NK cells and NK1.1+ T cells from gamma -/- mice show no response upon NKR-P1 cross-linking in spite of normal development. This finding suggests that CD3zeta expressed in NK cells and NK1.1+ T cells can not be replaced for FcRgamma in signaling through NKR-P1, because NKR-P1 bind only to FcRgamma dimers but not to CD3zeta homodimers or CD3zeta -FcRgamma heterodimers. In contrast, T cells show no functional defect in gamma -/- mice probably because the TCR complexes can utilize both CD3zeta and FcRgamma and CD3zeta can replace for FcRgamma in the TCR complexes of gamma -/- mice.

Fcgamma RIII which is associated with FcRgamma is known to activate NK cells upon cross-linking. Therefore, there is a possibility that NKR-P1 associates with Fcgamma RIII on the cell surface and delivers activating signal through FcRgamma which is coupled with Fcgamma RIII. However, this is unlikely because of two reasons. One is that Fcgamma RIII was not expressed on the cell surface of CTLL-2 (data not shown), whereas the association between FcRgamma and NKR-P1 was readily detected in the CTLL-2 (Fig. 1). Second, we used the (Fab)'2 fragment of anti-NK1.1 mAb for cross-linking of NKR-P1 and thus it is unlikely that immobilized anti-NK1.1 mAb activated Fcgamma RIII. Taken together, the association of FcRgamma with NKR-P1 is essentially independent of Fcgamma RIII.

Recent analysis revealed that activation of NK cells is negatively regulated by several killer inhibitory receptors (KIR) possessing immunoreceptor tyrosine-based inhibition motif (ITIM) (28, 29). These receptors such as p58, NKG2, and Ly49 recognize specific MHC class I molecule and deliver inhibitory signal for the cytotoxicity by NK cells (30). Furthermore, association of SHP-1 phosphatase with ITIM is important for the inhibition of NK cell activation (28, 29). Although the coprecipitation of CD3zeta or FcRgamma with p58 was suggested, functional significance remained unclear (33). On the other hand, only a few receptors which deliver positive signal for NK cell activation have been identified such as NKR-P1 and CD94/NKG2-C (34) and the molecular mechanism of NK cell activation through these receptors remains unclear. Under these circumstances, it is noteworthy that FcRgamma , a signal transducing chain possessing immunoreceptor tyrosine-based activation motif (ITAM), is involved in signal transduction through NKR-P1. Because Syk tyrosine kinase interacts with the phosphorylated ITAM of FcRgamma and is involved in NK cell activation through FcR (35, 36), it is likely that Syk also mediates the activating signal through NKR-P1 in NK cells. Furthermore, it has been shown that Lck directly associates with NKR-P1 (14). Taken together, both Syk and Lck seem to play an important role in mediating activation signals through NKR-P1 in NK cells.

Although the NKR-P1 molecule belongs to the C-type lectin superfamily and has been shown to have affinity to specific carbohydrates (12), the exact function of NKR-P1 has remained unclear. This is partly because antibodies against mouse or rat NKR-P1 do not block cytotoxicity of NK cells against YAC-1, a NK-sensitive target cell line. In addition, NK cells from gamma -/-- mice showed normal cytotoxicity against representative NK targets (data not shown). However, the failure of blocking with anti-NKR-P1 mAb can be explained by the possible redundancy of NKR-P1 family molecules on NK cells. Indeed, recent observation that introduction of NKR-P1 into a NKR-P1-deficient NK cell line restored cytotoxicity against specific tumor cell targets and the restored cytotoxicity was blocked by anti- NKR-P1 mAb (11) strongly suggested that NKR-P1 is involved in the recognition of specific target molecules on NK cells. A couple of reports demonstrating that anti-NK1.1 mAb blocked cytotoxicity of NK cells against specific targets also support this idea (37, 38). Further analysis of NK cells in gamma -/- mice may elucidate novel function of NKR-P1 molecule in the host defence.


Footnotes

Address correspondence to Takashi Saito, Division of Molecular Genetics, Center for Biological Science, Chiba University School of Medicine, 1-8-1 Inohana, Chuou-ku, Chiba 260, Japan. Phone: 81 43 226-2197; FAX: 81 43 222-1791; E-mail: saito{at}med.m.chiba-u.ac.jp

Received for publication 28 July 1997 and in revised form 3 October 1997.

   The first two authors contributed equally to this work.
1   Abbreviations used in this paper: gamma -/-, FcRgamma -deficient; ITAM, immunoreceptor tyrosine-based activation motif; ITIM, immunoreceptor tyrosine-based inhibition motif; KIR, killer inhibitory receptors.

We would like to thank Dr. J. Hamuro for providing IL-2, Ms. C. Sakuma and Ms. R. Siina for technical assistance, and Ms. H. Yamaguchi for secretarial assistance.

This work was supported by Grants-in-Aid for Scientific Research from the Ministry of Education to H. Arase and T. Saito.


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