Recognition of autologous dendritic cells by human NK cells

NK cells can recognize and kill tumor as well as certain normal cells. The outcome of the NK-target interaction is determined by a balance of positive and negative signals initiated by different target cell ligands. We have previously shown that human NK cells kill CD40-transfected tumor targets efficiently, but the physiological significance of this is unclear. We now demonstrate that human NK cells can kill dendritic cells (DC), known to express CD40 and other co-stimulatory molecules. The killing was observed with polyclonal NK cells cultured short term in IL-2 as well as with NK cell clones as effectors, and with allogeneic as well as autologous DC as targets. NK cell recognition could be inhibited, but only partially, by preincubation of target cells with monoclonal antibodies against CD40, suggesting that this molecule may be one of several ligands involved. Addition of TNF-alpha of the cultures stimulated the development of a more mature DC phenotype, while addition of IL-10 resulted in a less mature phenotype, with lower expression of CD40 and other co-stimulatory molecules. Nevertheless, such DC were more NK susceptible than the differentiated DC. This may be partly explained by a reduced MHC class I expression observed on such cells, since blocking of MHC class I molecules on differentiated DC or CD94 receptors of NK cells led to increased NK susceptibility. The results show that NK cells may interact with DC, and suggest that the outcome of such interactions depend on the cytokine milieu.

Peptide dependency and selectivity of the NK cell inhibitory receptor Ly-49C

MHC class I molecules can prevent NK cell-mediated cytotoxicity by interacting with inhibitory receptors on the effector cells. Different conclusions have been reached regarding possible peptide selectivity of these receptors. To address whether peptide selectivity is an exclusive feature of human or immunoglobulin-superfamily receptors, we have studied a system based on the murine NK receptor Ly-49C in the lectin-superfamily. Loading of TAP-deficient RMA-S cells with the H-2Kb-restricted, ovalbumin-derived peptide OVA(257 - 264) (pOVA) induced their ability to bind Ly-49C-transfected reporter cells, and also protected them from killing by Ly-49C+ NK cells. Other peptides that bound and stabilized H-2Kb equally well differed in their NK protective capacity. Comparison of the MHC class I peptide complexes (crystal structures and molecular models) revealed a conformational motif encompassing the C-terminal parts of the alpha1 helix (73 - 77) and the bound peptide that was common for the protective complexes. Substitution analysis of pOVA suggested that position 7 in the peptide may be critical for optimal protection as well as for the conformational motif at position 73 - 77. In conclusion, protection mediated by the murine C-type lectin receptor Ly-49C is peptide dependent and selective.

Immunization with dendritic cells breaks immunodominance in CTL responses against minor histocompatibility and synthetic peptide antigens

We have examined the mechanisms involved in immunodominance in two different experimental models: the cytotoxic T lymphocyte (CTL) response in B6 mice against minor histocompatibility antigens of BALB.B mice, and the response of B6 mice against a mixture of five synthetic peptides corresponding to well-defined immunogenic epitopes. The CTL responses in these models focus on a few dominant epitopes, whereas no or only weak responses can be detected against other subdominant epitopes. Neither of these immunodominance phenomena can be explained by insufficient presentation of subdominant epitopes in the presence of the dominant ones. Immunodominance could also be demonstrated in an in vitro system, in which B6 splenocytes primed with BALB.B could interfere with the CTL response against subdominant antigens. This interference was dependent on CD8+ T cells and on the simultaneous presentation of dominant and subdominant antigens on the same antigen-presenting cell, suggesting T cell competition around the antigen-presenting cell as a potential explanation. The immunodominance in both systems could be broken by immunization with dendritic cells (from BALB.B or from B6 loaded with peptides). This procedure allowed detection of CTL responses against both dominant and previously subdominant antigens.

T cell competition for the antigen-presenting cell as a model for immunodominance in the cytotoxic T lymphocyte response against minor histocompatibility antigens

We recently demonstrated that spleen cells primed against dominant BALB.B antigens can inhibit the cytotoxic T lymphocyte (CTL) response against subdominant antigens in vitro. In this study, we show that this interference is dependent on CD8+, but not CD4+, T cells directed against dominant antigens. Similar to immunodominance in vivo, T cell interference in vitro required presentation of dominant and subdominant antigens by the same antigen-presenting cell. In vivo priming with cells expressing dominant and subdominant antigens did not induce long-lasting unresponsiveness against the latter. These results support a model in which immunodominance is mediated by T cell competition. In line with this, we found that the immunodominance effects in the CTL response against these minor histocompatibility antigens could be broken by immunization with live bone marrow-derived dendritic cells.

The MHC class I molecule H-2Dp inhibits murine NK cells via the inhibitory receptor Ly49A

MHC class I molecules strongly influence the phenotype and function of mouse NK cells. NK cell-mediated lysis is prevented through the interaction of Ly49 receptors on the effector cell with appropriate MHC class I ligands on the target cell. In addition, host MHC class I molecules have been shown to modulate the in vivo expression of Ly49 receptors. We have previously reported that H-2Dd and H-2Dp MHC class I molecules are able to protect (at the target cell level) from NK cell-mediated lysis and alter the NK cell specificity (at the host level) in a similar manner, although the mechanism behind this was not clear. In this study, we demonstrate that the expression of both H-2Dd and H-2Dp class I molecules in target cells leads to inhibition of B6 (H-2b)-derived Ly49A+ NK cells. This inhibition could in both cases be reversed by anti-Ly49A Abs. Cellular conjugate assays showed that Ly49A-expressing cells indeed bind to cells expressing H-2Dp. The expression of Ly49A and Ly49G2 receptors on NK cells was down-regulated in H-2Dp-transgenic (B6DP) mice compared with nontransgenic B6 mice. However, B6DP mice expressed significantly higher levels of Ly49A compared with H-2Dd-transgenic (D8) mice. We propose that both H-2Dd and H-2Dp MHC class I molecules can act as ligands for Ly49A.

Triggering of murine NK cells by CD40 and CD86 (B7-2)

NK cell-mediated cytotoxicity is regulated by both triggering and inhibitory signals. The interaction between MHC class I molecules expressed on target cells and specific MHC class I-binding receptors expressed by NK cells generally leads to inhibition of lysis. We have shown recently that CD80 (B7-1) in mice and CD40 in humans trigger NK cell-mediated cytotoxicity in vitro. In the present study, we show that murine CD40 and CD86 (B7-2) trigger murine NK cell-mediated cytotoxicity in vitro when expressed on tumor cells. Preincubation of the transfected cell lines with anti-CD40 F(ab')2 fragments or cytolytic T lymphocyte-associated Ag-4-Ig (CTLA-4-Ig) before the cytotoxic assay abolished the triggering effect. Furthermore, radiolabeled CD40- and B7-2-expressing cells were rapidly eliminated in vivo in an NK cell-dependent manner. NK cells from CD40 ligand (CD40L)-/- or CD28-/- mice were triggered by tumor cells transfected with CD40 and B7-2, respectively, and these transfectants were rapidly eliminated in vivo when inoculated into CD40L-/- and CD28-/- mice. This suggests that the CD40 and B7-2 molecules can interact with receptors on NK cells other than CD40L and CD28, respectively, and that these may account for some of the reactivities observed in the present study. Collectively, these data demonstrate that 1) costimulatory molecules, other than B7-1, can modulate NK cell responses in vitro, 2) they can also affect NK cell-dependent responses in vivo, and 3) parts of these reactions are independent of CD28 and CD40L.

Recognition of the major histocompatibility complex restriction element modulates CD8(+) T cell specificity and compensates for loss of T cell receptor contacts with the specific peptide

Triggering of a T cell requires interaction between its specific receptor (TCR) and a peptide antigen presented by a self-major histocompatibility complex (MHC) molecule. TCR recognition of self-MHC by itself falls below the threshold of detection in most systems due to low affinity. To study this interaction, we have used a read-out system in which antigen-specific effector T cells are confronted with targets expressing high levels of MHC compared with the selecting and priming environment. More specifically, the system is based on CD8(+) T cells selected in an environment with subnormal levels of MHC class I in the absence of beta2-microglobulin. We observe that the MHC restriction element can trigger viral peptide-specific T cells independently of the peptide ligand, provided there is an increase in self-MHC density. Peptide-independent triggering required at least four times the natural in vivo level of MHC expression. Furthermore, recognition of the restriction element at expression levels below this threshold was still enough to compensate for lack of affinity to peptides carrying alanine substitutions in major TCR contact residues. Thus, the specificity in TCR recognition and T cell activation is fine tuned by the avidity for self-MHC, and TCR avidities for peptide and MHC may substitute for each other. These results demonstrate a functional role for TCR avidity for self-MHC in tuning of T cell specificity, and support a role for cross-reactivity on "self" during T cell selection and activation.

Murine class I major histocompatibility complex H-2Dd: expression, refolding and crystallization

A truncated soluble form of the murine class I major histocompatibility antigen complex H-2Dd was cloned using an Escherichia coli based system. It was expressed, refolded in vitro and crystallized in a complex with murine beta2 microglobulin and the peptide RGPGRAFVTI from the V3-loop of the gp160 HIV-1 protein. Crystals belonging to the space group P212121 with cell dimensions a = 51.3, b = 92.5, c = 108.8 A were obtained using two different crystallization conditions. The crystals contain one complex per asymmetric unit and diffract to at least 2.4 A resolution.

External and internal calibration of the MHC class I-specific receptor Ly49A on murine natural killer cells

Expression of the H-2Dd-specific inhibitory receptor Ly49A on murine NK cells is subject to MHC class I-dependent modulation in vivo. As a result, NK cells in H-2Dd-transgenic mice express low cell surface levels of Ly49A, whereas NK cells from nontransgenic C57BL/6 (B6) mice express high levels. The purpose of this study was to assess the role of MHC class I molecules on the NK cell itself vs those on surrounding cells in this calibration and to test whether the Ly49A levels are subject to regulation in mature NK cells also. Analysis of transgenic mice with mosaic expression of an H-2Dd/Ld transgene showed that MHC class I molecules on surrounding cells (external ligands) and on the NK cell itself (internal ligands) played distinct roles in the determination of Ly49A levels. External ligands were involved in down-regulation of Ly49A levels in vivo, whereas internal ligands kept the down-regulated levels of Ly49A low upon NK cell activation in vitro. Furthermore, in an experimental system based on adoptive transfer of spleen cells, receptor down-regulation of Ly49A occurred as a rapid adaptation process in mature NK cells after interaction with the H-2Dd ligand in vivo. This suggests that Ly49 levels are not fixed but can be changed in mature NK cells when they are exposed to a changed MHC class I environment.

Immunodominance in the CTL response against minor histocompatibility antigens: interference between responding T cells, rather than with presentation of epitopes

We have investigated mechanisms involved in immunodominance of the CTL response of C57BL/6 (B6) mice against cells of BALB.B origin. This transplantation barrier consists of at least 40 minor histocompatibility (H) Ags. Insufficient presentation of nondominant epitopes in the presence of dominant epitopes was investigated as a possible mechanism for immunodominance. Ag presentation was assessed by recognition of dendritic cells of BALB.B origin, MLC restimulatory capacity, and quantification of cell surface presentation by peptide elution from intact cells. Cells from BALB.B mice, which fail to elicit CTL against nondominant epitopes, presented nondominant epitopes to a similar extent as cells from minor H congenic mice; the latter do elicit CTL against nondominant minor H Ags. Nevertheless, presentation of nondominant and dominant epitopes by the same APC appeared to be an important factor for immunodominance to occur, since simultaneous immunization with the epitopes on separate cells elicited CTL against both types of epitopes. This suggested that immunodominance is determined in the interaction between different responding T cells and the APC. Support for this was obtained in an in vitro model in which the CTL response against a nondominant epitope was inhibited by the concomitant response against a dominant epitope. This study suggests that immunodominance in the CTL response against certain minor H Ags results from interference between T cell responses and not from insufficient presentation of peptide epitopes. The study also provides an in vitro model for further investigations of the immunodominance phenomenon.

Impaired MHC class I (H-2Dd)-mediated protection against Ly-49A+ NK cells after amino acid substitutions in the antigen binding cleft

The MHC class I molecule H-2Dd (Dd) acts as a ligand for the inhibitory NK cell receptor Ly-49A. We have constructed altered Dd molecules by site-directed mutagenesis, replacing residues with the corresponding amino acids from the Db molecule, which fails to inhibit via Ly-49A. Mutations at positions 73 and 156 (DdS73WD156Y) impaired the protective effect of the Dd molecule, as evaluated by testing lymphoma cells transfected with the mutant gene for sensitivity to killing by Ly-49A+ NK cells in vitro and rejection by NK cells in vivo. The altered residues form a hydrophobic ridge across the floor of the antigen binding cleft. A mutation in the alpha helix of the alpha2 domain, facing the solvent and without direct contact with the peptide (DdA150S) had no effect. Dd recognition by Ly-49A+ NK cells is considered to be peptide dependent, but not peptide specific. Our results indicate that alterations of residues buried in the antigen binding cleft can induce changes in peptide binding patterns and/or conformational changes in the Dd molecule that make the trimolecular complex less permissive for inhibition of Ly-49A+ NK cells.

The crystal structure of H-2Dd MHC class I complexed with the HIV-1-derived peptide P18-I10 at 2.4 A resolution: implications for T cell and NK cell recognition

The structure of H-2Dd complexed with the HIV-derived peptide P18-I10 (RGPGRAFVTI) has been determined by X-ray crystallography at 2.4 A resolution. This MHC class I molecule has an unusual binding motif with four anchor residues in the peptide (G2, P3, R/K/H5, and I/L/F9 or 10). The cleft architecture of H-2Dd includes a deep narrow passage accomodating the N-terminal part of the peptide, explaining the obligatory G2P3 anchor motif. Toward the C-terminal half of the peptide, p5R to p8V form a type I' reverse turn; residues p6A to p9T, and in particular p7F, are readily exposed. The structure is discussed in relation to functional data available for T cell and natural killer cell recognition of the H-2Dd molecule.

The alpha2 domain of H-2Dd restricts the allelic specificity of the murine NK cell inhibitory receptor Ly-49A

Mouse NK lymphocytes express Ly-49 receptors, which inhibit cytotoxicity upon ligation by specific MHC I molecules on targets. Different members of the lectin-like mouse Ly-49 receptor family recognize distinct subsets of murine H-2 molecules, but the molecular basis for the allelic specificity of Ly-49 has not been defined. We analyzed inhibition of natural killing by chimeric MHC I molecules in which the alpha1, alpha2, or alpha3 domains of the Ly-49A-binding allele H-2Dd were exchanged for the corresponding domains of the nonbinding allele H-2Db. Using the Ly-49A-transfected rat NK cell line, RNK-mLy-49A.9, we demonstrated that the H-2Dd alpha2 domain alone accounts for allelic specificity in protection of rat YB2/0 targets in vitro. We also showed that the H-2Dd alpha2 domain is sufficient to account for the allele-specific in vivo protection of H-2b mouse RBL-5 tumors from NK cell-mediated rejection in D8 mice. Thus, in striking contrast to the alpha1 specificity of Ig-like killer inhibitory receptors for human HLA, the lectin-like mouse Ly-49A receptor is predominantly restricted by the H-2Dd alpha2 domain in vitro and in vivo.

Superdominance among immunodominant H-2Kb-restricted epitopes and reversal by dendritic cell-mediated antigen delivery

To examine possible interference patterns between immunodominant CTL Ags, we analyzed the response to mixtures of five well-characterized H-2Kb-restricted epitopes, each of which had earlier been described as immunodominant within its antigenic system. Clear patterns of dominance were observed between peptides in the mixture, with the CTL response focusing on the Sendai virus nucleoprotein 324-332 and vesicular stomatitis virus nucleoprotein 52-59 epitopes. The dominance of these epitopes correlated with high CTL availability. Subdominance of the OVA(257-264) and the MCF1233 murine leukemia virus envelope 574-581 peptides could not be explained by inferior ability to bind and stabilize MHC class I molecules. Interestingly, immunodominance was broken if the peptide mixture was pulsed on bone marrow-derived dendritic cells, a mode of immunization allowing efficient recognition of a broader set of specificities. Our results show that immunodominance is neither an absolute feature of a given epitope nor does it apply only in relation to other epitopes within the same protein, micro-organism, or cell. Novel "superdominant" hierarchies emerge in the response against multiple "dominant" epitopes. A T cell competition model to explain the data in terms of a balance influenced by CTL frequencies and available APC capacity is discussed.

Beta2-microglobulin-deficient NK cells show increased sensitivity to MHC class I-mediated inhibition, but self tolerance does not depend upon target cell expression of H-2Kb and Db heavy chains

Mice lacking beta2-microglobulin (beta2m- mice) express greatly reduced levels of MHC class I molecules, and cells from beta2m- mice are therefore highly sensitive to NK cells. However, NK cells from beta2m- mice fail to kill beta2m- normal cells, showing that they are self tolerant. In a first attempt to understand better the basis of this tolerance, we have analyzed more extensively the target cell specificity of beta2m- NK cells. In a comparison between several MHC class I-deficient and positive target cell pairs for sensitivity to beta2m- NK cells, we made the following observations: First, beta2m- NK cells displayed a close to normal ability to kill a panel of MHC class I-deficient tumor cells, despite their nonresponsiveness to beta2m- concanavalin A (Con A)-activated T cell blasts. Secondly, beta2m- NK cells were highly sensitive to MHC class I-mediated inhibition, in fact more so than beta2m+ NK cells. Thirdly beta2m- NK cells were not only tolerant to beta2m- Con A blasts but also to Con A blasts from H-2Kb-/Db- double deficient mice in vitro. We conclude that NK cell tolerance against MHC class I-deficient targets is restricted to nontransformed cells and independent of target cell expression of MHC class I free heavy chains. The enhanced ability of beta2m- NK cells to distinguish between MHC class I-negative and -positive target cells may be explained by increased expression of Ly49 receptors, as described previously. However, the mechanisms for enhanced inhibition by MHC class I molecules appear to be unrelated to self tolerance in beta2m- mice, which may instead operate through mechanisms involving triggering pathways.

Generation of CD8+ T cells specific for transporter associated with antigen processing deficient cells

Cells with impaired transporter associated with antigen processing (TAP) function express low levels of cell surface major histocompatibility complex (MHC) class I molecules, and are generally resistant to lysis by MHC class I restricted cytotoxic T lymphocytes (CTLs). Here we report the generation of MHC class I restricted CD8(+) CTLs that surprisingly require target cell TAP deficiency for efficient recognition. C57BL/6 (B6) mice immunized with syngenic B7-1 (CD80) expressing TAP-deficient cells generated a potent CTL response against both TAP-deficient RMA-S tumor cells and TAP-deficient Con A blasts, whereas the corresponding TAP-expressing target cells were considerably less susceptible or resistant to lysis. The CTL epitopes recognized were expressed also by the human TAP-deficient cell line T2, transfected with appropriate MHC class I molecules. B6 mice immunized with B7-1-transfected TAP-deficient RMA-S cells were protected from outgrowth of a subsequent RMA-S tumor challenge. These findings are discussed in relation to the biochemical nature of MHC class I dependent CTL epitopes associated with impaired TAP function, as well as implications for immunotherapy and autoimmunity.

NK cell receptor calibration: effects of MHC class I induction on killing by Ly49Ahigh and Ly49Alow NK cells

NK cells from C57BL/6 (B6) mice and H-2Dd transgenic B6 (D8) mice express different levels of the inhibitory receptor Ly49A, and they also differ in their target cell specificity. Here, we examined this differential specificity with respect to the role of the Ly49A receptor expression on effector cells and levels of H-2Dd inhibitory ligands on target cells. NK cells from D8 mice express low levels of Ly49A receptor (Ly49Alow), and are able to kill SP2/0 tumor cells in spite of their expression of H-2Dd. H-2Dd is expressed at reduced levels on SP2/0 cells; when these were increased three- to fivefold after IFN-gamma treatment, the killing by Ly49Alow NK cells from D8 mice was markedly reduced. Efficient killing was restored when the effectors were preincubated with anti-Ly49A F(ab')2 Abs. A separate experimental system was based on D8 TAP1-deficient Con A blasts exogenously loaded with H-2Dd-specific peptides. In this system, higher levels of cell surface H-2Dd had to be induced by peptide to inhibit D8 Ly49Alow NK cells to an extent similar to that of B6 Ly49Ahigh NK cells. Ly49A receptors on NK cells from H-2Dd transgenic mice are thus functional, although they require high levels of ligand to inhibit progression of the NK-target cell interaction. The data are in favor of the "receptor-calibration" model, which suggests that down-regulation of inhibitory receptors on NK cells may be useful in order for NK cells to discriminate between normal and reduced levels of MHC class I molecules.

NK cell receptor calibration: effects of MHC class I induction on killing by Ly49Ahigh and Ly49Alow NK cells

NK cells from C57BL/6 (B6) mice and H-2Dd transgenic B6 (D8) mice express different levels of the inhibitory receptor Ly49A, and they also differ in their target cell specificity. Here, we examined this differential specificity with respect to the role of the Ly49A receptor expression on effector cells and levels of H-2Dd inhibitory ligands on target cells. NK cells from D8 mice express low levels of Ly49A receptor (Ly49Alow), and are able to kill SP2/0 tumor cells in spite of their expression of H-2Dd. H-2Dd is expressed at reduced levels on SP2/0 cells; when these were increased three- to fivefold after IFN-gamma treatment, the killing by Ly49Alow NK cells from D8 mice was markedly reduced. Efficient killing was restored when the effectors were preincubated with anti-Ly49A F(ab')2 Abs. A separate experimental system was based on D8 TAP1-deficient Con A blasts exogenously loaded with H-2Dd-specific peptides. In this system, higher levels of cell surface H-2Dd had to be induced by peptide to inhibit D8 Ly49Alow NK cells to an extent similar to that of B6 Ly49Ahigh NK cells. Ly49A receptors on NK cells from H-2Dd transgenic mice are thus functional, although they require high levels of ligand to inhibit progression of the NK-target cell interaction. The data are in favor of the "receptor-calibration" model, which suggests that down-regulation of inhibitory receptors on NK cells may be useful in order for NK cells to discriminate between normal and reduced levels of MHC class I molecules.

Synthetic peptides derived from the melanocyte-stimulating hormone receptor MC1R can stimulate HLA-A2-restricted cytotoxic T lymphocytes that recognize naturally processed peptides on human melanoma cells

Human melanoma-specific HLA-A2 restricted CTLs have recently been shown to recognize antigens expressed by melanoma lines and normal melanocytes, including Melan-A/Mart-1, gp100, gp75, and tyrosinase. Herein, we define HLA-A2-restricted CTL epitopes from a recently cloned melanocortin 1 receptor (MC1R), which belongs to a new subfamily of the G-protein-coupled receptors expressed on melanomas and melanocytes. Thirty-one MC1R-derived peptides were selected on the basis of HLA-A2-specific motifs and tested for their HLA-A2 binding capacity. Of a group of 12 high or intermediate HLA-A2 binding peptides, three nonamers, MC1R244 (TILLGIFFL), MC1R283 (FLALIICNA), and MC1R291 (AIIDPLIYA), were found to induce peptide-specific CTLs from peripheral blood mononuclear cells of healthy HLA-A2+ donors after repeated in vitro stimulation with peptide-pulsed antigen-presenting cells. The CTLs raised against these three HLA-A2+-restricted peptides could recognize naturally processed peptides from HLA-A2+ melanomas and from Cos7 cells cotransfected with MC1R and HLA-A2. CTLs induced by the MC1R291 peptide (but not induced or induced only to a very low extent by the other two MCR1 peptide epitopes) showed cross-reactions with two other members of the melanocortin receptor family, which are more broadly expressed on other tissues. Taken together, our findings have implications in relation both to autoimmunity and immunotherapy of malignant melanomas.

Natural killer cell tolerance in mice with mosaic expression of major histocompatibility complex class I transgene

We have studied natural killer (NK) cell tolerance in a major histocompatibility complex (MHC) class I transgenic line, DL6, in which the transgene product was expressed on only a fraction of blood cells. In contrast with transgenic mice expressing the same transgene in all cells, NK cells from mosaic mice failed to reject transgene-negative bone marrow or lymphoma grafts. However, they retained the capability to reject cells with a total missing-self phenotype, i.e., cells lacking also wild-type MHC class I molecules. Tolerance against transgene-negative cells was demonstrated also in vitro, and could be broken if transgene-positive spleen cells of mosaic mice were separated from negative cells before, or after 4 d of culture in interleukin-2. The results provide support for selective NK cell tolerance to one particular missing-self phenotype but not to another. We suggest that this tolerance is determined by NK cell interactions with multiple cells in the environment, and that it is dominantly controlled by the presence of cells lacking a specific MHC class I ligand. Furthermore, the tolerant NK cells could be reactivated in vitro, which suggests that the tolerance occurs without deletion of the potentially autoreactive NK cell subset(s), and that it may be dependent upon the continuous presence of tolerizing cells.

A new mechanism of NK cell cytotoxicity activation: the CD40-CD40 ligand interaction

NK recognition is regulated by a delicate balance between positive signals initiating their effector functions, and inhibitory signals preventing them from proceeding to cytolysis. Knowledge of the molecules responsible for positive signaling in NK cells is currently limited. We demonstrate that IL-2-activated human NK cells can express CD40 ligand (CD40L) and that recognition of CD40 on target cells can provide an activation pathway for such human NK cells. CD40-transfected P815 cells were killed by NK cell lines expressing CD40L, clones and PBL-derived NK cells cultured for 18 h in the presence of IL-2, but not by CD40L-negative fresh NK cells. Cross-linking of CD40L on IL-2-activated NK cells induced redirected cytolysis of CD40-negative but Fc receptor-expressing P815 cells. The sensitivity of human TAP-deficient T2 cells could be blocked by anti-CD40 antibodies as well as by reconstitution of TAP/MHC class I expression, indicating that the CD40-dependent pathway for NK activation can be downregulated, at least in part, by MHC class I molecules on the target cells. NK cell recognition of CD40 may be important in immunoregulation as well as in immune responses against B cell malignancies.

Altered expression of Ly49 inhibitory receptors on natural killer cells from MHC class I-deficient mice

MHC class I molecules in the host affect the specificity of NK cells. Previous work has suggested that this specificity is conferred by the expression of products encoded by the Ly49 gene family. This gene family encodes receptors that upon specific recognition of MHC class I ligands mediate an inhibitory signal that prevents killing by NK cells. The pattern of expression of the Ly49 MHC class I binding inhibitory receptors on NK cells is thought to be adapted to the host to ensure the generation of a self-tolerant, yet functional, NK cell repertoire. In the present study we have examined the expression of inhibitory receptors (Ly49A, Ly49C, and Ly49G2) on NK1.1+ cells from B6 (H-2b) and D8 (B6 mice transgenic for H-2Dd) mice as well as corresponding TAP1 -/-, beta2m -/-, and TAP1/beta2m -/- mutants of these mice. We demonstrate that receptor expression on NK1.1+ cells can be specifically modulated by host MHC class I molecules in at least two different ways: alteration of numbers of cells expressing a given receptor and modulation of the levels of expression of a given receptor at the cell surface. The degree of this modulation varies significantly among the various receptors studied and may depend upon the nature of their MHC class I ligands. The results are discussed in relation to the influence of MHC class I molecules on the development of an NK cell repertoire.