CD300b regulates the phagocytosis of apoptotic cells via phosphatidylserine recognition.

The CD300 receptor family members are a group of molecules that modulate a variety of immune cell processes. We show that mouse CD300b (CLM7/LMIR5), expressed on myeloid cells, recognizes outer membrane-exposed phosphatidylserine (PS) and does not, as previously reported, directly recognize TIM1 or TIM4. CD300b accumulates in phagocytic cups along with F-actin at apoptotic cell contacts, thereby facilitating their engulfment. The CD300b-mediated activation signal is conveyed through CD300b association with the adaptor molecule DAP12, and requires a functional DAP12 ITAM motif. Binding of apoptotic cells promotes the activation of the PI3K-Akt kinase pathway in macrophages, while silencing of CD300b expression diminishes PI3K-Akt kinase activation and impairs efferocytosis. Collectively, our data show that CD300b recognizes PS as a ligand, and regulates the phagocytosis of apoptotic cells via the DAP12 signaling pathway.

Activating CTL precursors to reveal CTL function without skewing the repertoire by in vitro expansion.

Detection of the functional CD8(+) CTL response usually requires in vitro restimulation. The differences between the CD8(+) CTL repertoire in freshly isolated precursor cells and CD8(+) CTL after short-term in vitro expansion have been generally assumed to be minimal, but have never been defined experimentally. Using staining with P18-I10/H-2D(d) tetramers and monoclonal antibodies (mAb) against Vbeta, we show the surprising result that there was significant skewing of the CD8(+) CTL repertoire after just 7 days of stimulation. In contrast, we found that overnight incubation of precursor cells with peptide allows the functional assessment of CD8(+) CTL (which cannot be detected ex vivo from freshly isolated cells) without changing the absolute number of antigen-specific CTL as measured by tetramer staining or the repertoire of TCR analyzed with mAb. This study affords a better understanding of the differences between the ex vivo and in vitro stimulated CTL repertoire, and provides an approach to reveal a more faithful representation of the functional in vivo CTL response without skewing of the repertoire of T cells detected.

Ly49A allelic variation and MHC class I specificity.

The Ly49 family of natural killer (NK) cell receptors is encoded by a polygenic genetic locus. Allelic forms have been described and their expression appears to be regulated. The best-characterized Ly49 molecule, the C57BL/6 form of Ly49A, is an NK cell inhibitory receptor that binds H2Dd. To determine whether differences between Ly49a alleles may have functional consequences, allelic variants of Ly49a were cloned from several inbred mouse strains. Stable transfectants expressing each Ly49a allelic variant were generated and tested for reactivity with a panel of monoclonal antibodies (mAbs A1, JR9.318, YE1/32, and YE1/48) that recognize the C57BL/6 form of Ly49A. Binding to H2Dd was also assessed using fluorescently labeled H2Dd tetramers. Furthermore, cytotoxicity assays were performed using anti-Ly49A mAb-separated interleukin-2-activated NK cells. We show that despite binding to fluorescently labeled H2Dd tetramers, the Ly49A+ NK cells from representative mouse strains displayed significantly different degrees of inhibition with H2Dd targets. These results can be interpreted in the light of recent structural data on the Ly49A-H2Dd complex. Thus, the Ly49 family displays functionally significant allelic polymorphism which adds to the repertoire of NK cell receptors.

Structural basis of MHC class I recognition by natural killer cell receptors.

Natural killer (NK)-cell function is regulated by NK receptors that recognize MHC class I (MHC-I) molecules on target cells. Two structurally distinct families of NK receptors have been identified, the immunoglobulin-like family (killer cell immunoglobulin-like receptors (KIRs), leukocyte immunoglobulin-like receptors (LIRs)) and the C-type lectin-like family (Ly49, CD94/NKG2A, NKG2D, CD69). Recently, the three-dimensional structures of several NK receptors were determined, in free form or bound to MHC-I. These include those of unbound KIRs, NKG2D, CD69, LIR-1 and the CD94 subunit of the CD94/NKG2A heterodimer. Together, these structures define the basic molecular architecture of both the immunoglobulin-like and C-type lectin-like families of NK receptors. In addition, crystal structures have been reported for the complex between Ly49A and H-2Dd, and for KIR2DL2 bound to HLA-Cw3. The complex structures provide a framework for understanding MHC-I recognition by NK receptors from both families and reveal striking differences in the nature of this recognition, despite the receptors' functional similarity.

Competitive inhibition in vivo and skewing of the T cell repertoire of antigen-specific CTL priming by an anti-peptide-MHC monoclonal antibody.

We have recently described a mAb, KP15, directed against the MHC-I/peptide molecular complex consisting of H-2D(d) and a decamer peptide corresponding to residues 311-320 of the HIV IIIB envelope glycoprotein gp160. When administered at the time of primary immunization with a vaccinia virus vector encoding gp160, the mAb blocks the subsequent appearance of CD8(+) CTL with specificity for the immunodominant Ag, P18-I10, presented by H-2D(d). This inhibition is specific for this particular peptide Ag; another H-2D(d)-restricted gp160 encoded epitope from a different HIV strain is not affected, and an H-2L(d)-restricted epitope encoded by the viral vector is also not affected. Using functional assays and specific immunofluorescent staining with multivalent, labeled H-2D(d)/P18-I10 complexes (tetramers), we have enumerated the effects of blocking of priming on the subsequent appearance, avidity, and TCR Vbeta usage of Ag-specific CTL. Ab blocking skews the proportion of high avidity cells emerging from immunization. Surprisingly, Vbeta7-bearing Ag-specific TCR are predominantly inhibited, while TCR of several other families studied are not affected. The ability of a specific MHC/peptide mAb to inhibit and divert the CD8(+) T cell response holds implications for vaccine design and approaches to modulate the immune response in autoimmunity.

A T cell receptor transgenic model of severe, spontaneous organ-specific autoimmunity.

The development of mouse models of human organ-specific autoimmune diseases has been hampered by the need to immunize mice with autoantigens in potent adjuvants. Even autoantigen-specific T cell receptor transgenic models of autoimmunity have proven to be complex as the transgenic mice frequently fail to develop disease spontaneously. We have isolated a CD4(+) T cell clone (TxA23)that recognizes the gastric parietal cell antigen, H/K ATPase alpha-chain(630-641), from a mouse with autoimmune gastritis that developed after thymectomy on day 3 of life. The T cell receptor alpha and beta genes from this clone were used to generate A23 transgenic mice. All A23 transgenic animals spontaneously developed severe autoimmune gastritis, and evidence of disease was detected as early as day 10 of life. Gastritis could be transferred to immunocompromised mice with a limited number of transgenic thymocytes (10(3)), but as many as 10(7) induced only mild disease in wild-type animals. Due to the complete penetrance of spontaneous disease, identity of the auto-antigen, susceptibility to immunoregulation, and close relation to autoimmune gastritis in man, A23 transgenic mice represent a unique CD4(+) T cell-mediated disease model for understanding the multiple factors regulating organ-specific autoimmunity.

A "chimeric" C57l-derived Ly49 inhibitory receptor resembling the Ly49D activation receptor.

Ly49D is a natural killer (NK) cell activation receptor that is responsible for differential mouse inbred strain-determined lysis of Chinese hamster ovary (CHO) cells. Whereas C57BL/6 NK cells kill CHO, BALB/c-derived NK cells cannot kill because they lack expression of Ly49D. Furthermore, the expression of Ly49D, as detected by monoclonal antibody 4E4, correlates well with CHO lysis by NK cells from different inbred strains. However, one discordant mouse strain was identified; C57L NK cells express the mAb 4E4 epitope but fail to lyse CHO cells. Herein we describe a Ly49 molecule isolated from C57L mice that is recognized by mAb 4E4 (anti-Ly49D). Interestingly, this molecule shares extensive similarity to Ly49D(B6) in its extracellular domain, but its cytoplasmic and transmembrane domains are identical to the inhibitory receptor Ly49A(B6), including a cytoplasmic ITIM. This molecule bears substantial overall homology to the previously cloned Ly49O molecule from 129 mice the serologic reactivity and function of which were undefined. Cytotoxicity experiments revealed that 4E4(+) LAK cells from C57L mice failed to lyse CHO cells and inhibited NK cell function in redirected inhibition assays. MHC class I tetramer staining revealed that the Ly49O(C57L)-bound H-2D(d) and lysis by 4E4(+) C57L LAK cells is inhibited by target H-2D(d). The structural basis for ligand binding was also examined in the context of the recent crystallization of a Ly49A-H-2D(d) complex. Therefore, this apparently "chimeric" Ly49 molecule serologically resembles an NK cell activation receptor but functions as an inhibitory receptor.

Two intermediate-avidity cytotoxic T lymphocyte clones with a disparity between functional avidity and MHC tetramer staining.

The efficacy of cytotoxic T lymphocytes (CTL) has been shown to be highly dependent upon their functional avidity (the sensitivity of their cellular response to MHC-peptide complexes). To examine this relationship, we employed target cell lysis as a quantitative measure and established a set of four CTL clones that exhibited a range of functional avidities spanning more than three orders of magnitude. Within this set, clones displayed a linear correlation between functional avidity and the TCR down-regulation that occurred in response to increasing antigen density. Staining intensity of MHC-peptide tetramer, however, correlated only with the very highest and very lowest avidity clones; the two intermediate-avidity clones showed an inverse relationship between tetramer staining and functional avidity. Compensation for differences in surface levels of TCR improved the correlation, but failed to fully account for this discrepancy. Comparison of TCR signals generated by stimulation of CTL with substrate-bound soluble MHC-peptide or antigen-presenting cells suggested that internal TCR signaling efficiency accounts for at least a portion of the observed functional avidity and suggests the need for caution in directly relating tetramer staining to avidity.

Crystal structure of human CD69: a C-type lectin-like activation marker of hematopoietic cells.

CD69 is a widely expressed type II transmembrane glycoprotein related to the C-type animal lectins that exhibits regulated expression on a variety of cells of the hematopoietic lineage, including neutrophils, monocytes, T cells, B cells, natural killer (NK) cells, and platelets. Activation of T lymphocytes results in the induced expression of CD69 at the cell surface. In addition, cross-linking of CD69 by specific antibodies leads to the activation of cells bearing this receptor and to the induction of effector functions. However, the physiological ligand of CD69 is unknown. We report here the X-ray crystal structure of the extracellular C-type lectin-like domain (CTLD) of human CD69 at 2.27 A resolution. Recombinant CD69 was expressed in bacterial inclusion bodies and folded in vitro. The protein, which exists as a disulfide-linked homodimer on the cell surface, crystallizes as a symmetrical dimer, similar to those formed by the related NK cell receptors Ly49A and CD94. The structure reveals conservation of the C-type lectin-like fold, including preservation of the two alpha-helical regions found in Ly49A and mannose-binding protein (MBP). However, only one of the nine residues coordinated to Ca(2+) in MBP is conserved in CD69 and no bound Ca(2+) is evident in the crystal structure. Surprisingly, electron density suggestive of a puckered six-membered ring was discovered at a site structurally analogous to the ligand-binding sites of MBP and Ly49A. This sugar-like density may represent, or mimic, part of the natural ligand recognized by CD69.

Mapping the ligand of the NK inhibitory receptor Ly49A on living cells.

We have used a recombinant, biotinylated form of the mouse NK cell inhibitory receptor, Ly49A, to visualize the expression of MHC class I (MHC-I) ligands on living lymphoid cells. A panel of murine strains, including MHC congenic lines, was examined. We detected binding of Ly49A to cells expressing H-2D(d), H-2D(k), and H-2D(p) but not to those expressing other MHC molecules. Cells of the MHC-recombinant strain B10.PL (H-2(u)) not only bound Ly49A but also inhibited cytolysis by Ly49A(+) effector cells, consistent with the correlation of in vitro binding and NK cell function. Binding of Ly49A to H-2D(d)-bearing cells of different lymphoid tissues was proportional to the level of H-2D(d) expression and was not related to the lineage of the cells examined. These binding results, interpreted in the context of amino acid sequence comparisons and the recently determined three-dimensional structure of the Ly49A/H-2D(d) complex, suggest a role for amino acid residues at the amino-terminal end of the alpha1 helix of the MHC-I molecule for Ly49A interaction. This view is supported by a marked decrease in affinity of an H-2D(d) mutant, I52 M, for Ly49A. Thus, allelic variation of MHC-I molecules controls measurable affinity for the NK inhibitory receptor Ly49A and explains differences in functional recognition in different mouse strains.

Enhanced antigen-specific antitumor immunity with altered peptide ligands that stabilize the MHC-peptide-TCR complex.

T cell responsiveness to an epitope is affected both by its affinity for the presenting MHC molecule and the affinity of the MHC-peptide complex for TCR. One limitation of cancer immunotherapy is that natural tumor antigens elicit relatively weak T cell responses, in part because high-affinity T cells are rendered tolerant to these antigens. We report here that amino acid substitutions in a natural MHC class I-restricted tumor antigen that increase the stability of the MHC-peptide-TCR complex are significantly more potent as tumor vaccines. The improved immunity results from enhanced in vivo expansion of T cells specific for the natural tumor epitope. These results indicate peptides that stabilize the MHC-peptide-TCR complex may provide superior antitumor immunity through enhanced stimulation of specific T cells.

Antibodies directed against the MHC-I molecule H-2Dd complexed with an antigenic peptide: similarities to a T cell receptor with the same specificity.

alphabeta TCRs, which use an Ab-like structure to form a combining site, recognize molecular complexes consisting of peptides bound to MHC class I (MHC-I) or class II (MHC-II) molecules. To explore the similarities and differences between Ab and T cell recognition of similar structures, we have isolated two mAbs, KP14 and KP15, that specifically bind H-2D(d) complexed with an HIV envelope gp160-derived peptide, P18-I10. These Abs are MHC and peptide specific. Fine specificity of mAb binding was analyzed using a panel of synthetic peptides, revealing similarities between the mAb and a cloned TCR with the same specificity. These two mAbs used the same V(H) and J(H) gene segments, but different D, Vkappa, and Jkappa genes. Administered in vivo, mAb KP15 blocked the induction of CTL specific for recombinant vaccinia virus-encoded gp160, indicating its ability to bind endogenously generated MHC/peptide complexes. Analysis of the fine specificity of these mAbs in the context of their encoded amino acid sequences and the known three-dimensional structure of the H-2D(d)/P18-I10 complex suggests that they bind in an orientation similar to that of the TCR. Thus, the plasticity of the B cell receptor repertoire and the structural similarities among BCR and TCR allow Abs to effectively mimic alphabeta TCRs. Such mAbs may be useful in the therapeutic modulation of immune responses against infectious agents or harmful self Ags as well as in tracing steps in Ag processing.

Interaction of the NK cell inhibitory receptor Ly49A with H-2Dd: identification of a site distinct from the TCR site.

Natural killer cell function is controlled by interaction of NK receptors with MHC I molecules expressed on target cells. We describe the binding of bacterially expressed Ly49A, the prototype murine NK inhibitory receptor, to similarly engineered H-2Dd. Despite its homology to C-type lectins, Ly49A binds independently of carbohydrate and Ca2+ and shows specificity for MHC I but not bound peptide. The affinity of the Ly49A/H-2Dd interaction as determined by surface plasmon resonance is from 6 to 26 microM at 25 degrees C and is greater by ultracentrifugation at 4 degrees C. Biotinylated Ly49A stains H-2Dd-expressing cells. Competition experiments indicate that the Ly49A and T cell receptor (TCR) binding sites on MHC I are distinct, suggesting complex regulation of cells that bear both TCR and NK cell receptors.

Crystal structure of a lectin-like natural killer cell receptor bound to its MHC class I ligand.

Natural killer (NK) cell function is regulated by NK receptors that interact with MHC class I (MHC-I) molecules on target cells. The murine NK receptor Ly49A inhibits NK cell activity by interacting with H-2D(d) through its C-type-lectin-like NK receptor domain. Here we report the crystal structure of the complex between the Ly49A NK receptor domain and unglycosylated H-2D(d). The Ly49A dimer interacts extensively with two H-2D(d) molecules at distinct sites. At one interface, a single Ly49A subunit contacts one side of the MHC-I peptide-binding platform, presenting an open cavity towards the conserved glycosylation site on the H-2D(d) alpha2 domain. At a second, larger interface, the Ly49A dimer binds in a region overlapping the CD8-binding site. The smaller interface probably represents the interaction between Ly49A on the NK cell and MHC-I on the target cell, whereas the larger one suggests an interaction between Ly49A and MHC-I on the NK cell itself. Both Ly49A binding sites on MHC-I are spatially distinct from that of the T-cell receptor.

An allosteric mechanism controls antigen presentation by the H-2K(b) complex.

The mechanism of assembly/dissociation of a recombinant water-soluble class I major histocompatibility complex (MHC) H-2Kb molecule was studied by a real-time fluorescence resonance energy transfer method. Like the H-2Kd ternary complex [Gakamsky et al. (1996) Biochemistry 35, 14841-14848], the interactions among the heavy chain, beta2-microglobulin (beta2m), and antigenic peptides were found to be controlled by an allosteric mechanism. Association of the heavy chain with beta2m increased peptide binding rate constants by more than 2 orders of magnitude and enhanced affinity of the heavy-chain molecule for peptides. Interaction of peptides with the heavy-chain binding site, in turn, increased markedly the affinity of the heavy chain for beta2m. Binding of peptide variants of the ovalbumin sequence (257-264) to the heavy chain/beta2m heterodimer was found to be a biphasic reaction. The fast phase was a second-order process with nearly the same rate constants as those of binding of peptides derived from the influenza virus nucleoprotein 147-155 to the H-2Kd heavy chain/beta2m heterodimer [(3.0 +/- 1.0) x 10(-6) M-1 s-1 at 37 degrees C]. The slow phase was a result of both the ternary complex assembly from the "free" heavy chain, beta2m, and peptide as well as an intramolecular conformational transition within the heavy chain/beta2m heterodimer to a peptide binding conformation. Biexponential kinetics of peptide or beta2m dissociation from the ternary complex were observed. They suggest that it can exist in two conformations. The rate constants of beta2m dissociation from the H-2Kb ternary complex were, in the limits of experimental accuracy, independent of the structure of the bound peptide, though their affinities differed by an order of magnitude. Dissociation of peptides from the Kb heavy chain was always faster than from the ternary complexes, yet the heavy chain/peptide complexes were considerably more stable compared with their Kd/nucleoprotein peptide counterparts.

NK and CTL recognition of a single chain H-2Dd molecule: distinct sites of H-2Dd interact with NK and TCR.

We generated transgenic mice expressing a single-chain beta2-microglobulin (beta2m)-H-2Dd. The cell-surface beta2m-H-2Dd molecule was expressed on a beta2m-deficient background and reacted with appropriate mAbs. It was of the expected m.w. and directed the normal development of CD8+ T cells in the thymus of a broad TCR repertoire. It also presented both exogenously provided and endogenous peptide Ags to effector CD8+ T cells. In tests of NK cell education and function, it failed to reveal any interaction with NK cells, suggesting that the site of the interaction of NK receptors with H-2Dd was disrupted. Thus, the sites of TCR and NK receptor interaction with H-2Dd are distinct, an observation consistent with independent modes of TCR and NK receptor evolution and function.

The X-ray crystal structure of a Valpha2.6Jalpha38 mouse T cell receptor domain at 2.5 A resolution: alternate modes of dimerization and crystal packing.

We describe here the structure of a murine T cell receptor (TCR) Valpha2.6Jalpha38 (TCRAV2S6J38) domain, derived from a T cell hybridoma with specificity for the H-2Ddmajor histocompatibility complex class I molecule bound to a decamer peptide, P18-I10, from the HIV envelope glycoprotein gp120, determined by X-ray crystallography at 2.5 A resolution. Unlike other TCR Valpha domains that have been studied in isolation, this one does not dimerize in solution at concentrations below 1 mM, and the crystal fails to show dimer contacts that are likely to be physiological. In comparison to other Valpha domains, this Valpha2.6 shows great similarity in the packing of its core residues, and exhibits the same immunoglobulin-like fold characteristic of other TCR Valpha domains. There is good electron density in all three complementarity-determining regions (CDRs), where the differences between this Valpha domain and others are most pronounced, in particular in CDR3. Examination of crystal contacts reveals an association of Valpha domains distinct from those previously seen. Comparison with other Valpha domain structures reveals variability in all loop regions, as well as in the first beta strand where placement and configuration of a proline residue at position 6, 7, 8, or 9 affects the backbone structure. The great variation in CDR3 conformations among TCR structures is consistent with an evolving view that CDR3 of TCR plays a plastic role in the interaction of the TCR with the MHC/peptide complex as well as with CDR3 of the paired TCR chain.

Post-thymectomy autoimmune gastritis: fine specificity and pathogenicity of anti-H/K ATPase-reactive T cells.

Thymectomy at day 3 of life (d3Tx) results in the development of organ-specific autoimmunity. We have recently shown that d3Tx BALB/c mice which develop autoimmune gastritis contain CD4+ T cells specific for the gastric parietal cell proton pump, H/K ATPase. Here, we demonstrate that freshly explanted gastric lymph node (LN) cells from d3Tx mice react significantly to the H/K ATPase alpha chain, but only marginally to the beta chain. Two H/K ATPase-reactive T cell lines were derived from the gastric LN of d3Tx mice. Both are CD4+, TCR alpha/beta-, and I-Ad restricted, and recognize distinct peptides from the H/K ATPase alpha chain. One cell line secretes Th1 and the other Th2 cytokines, but both are equally potent in inducing gastritis with distinct profiles of cellular infiltration in nu/nu recipient animals. Neither of the cell lines induced disease in normal BALB/c recipients and transfer of disease to nu/nu recipients was blocked by co-transfer of normal BALB/c spleen cells containing CD4+ CD25+ cells. Although CD4+ CD25+ T cells are thought to emigrate from the thymus after day 3 of life, they could be identified in LN of 2-day-old animals. The capacity of CD4+ CD25+ T cells to abrogate the pathogenic activity in vivo of both activated Th1/Th2 lines strongly suggests that this suppressor T cell population may have a therapeutic role in other models of established autoimmunity. The availability of well-characterized lines of autoantigen-specific T cells should greatly facilitate the analysis of the mechanism of action and target of the CD4+ CD25+ immunoregulatory cells.