Analysis of graft-versus-host disease (GVHD) and graft rejection using MHC class I-deficient mice

GVHD is a major complication in allogeneic bone marrow transplantation (BMT). MHC class I mismatching increases GVHD, but in MHC-matched BMT minor histocompatibility antigens (mH) presented by MHC class I result in significant GVHD. To examine the modification of GVHD in the absence of cell surface MHC class I molecules, β₂-microglobulin-deficient mice (β₂m-/-) were used as allogeneic BMT recipients in MHC- and mH-mismatched transplants. β₂m-/- mice accepted MHC class I-expressing BM grafts and developed significant GVHD. MHC (H-2)-mismatched recipients developed acute lethal GVHD. In contrast, animals transplanted across mH barriers developed indolent chronic disease that was eventually fatal. Engrafted splenic T cells in all β₂m-/- recipients were predominantly CD3⁺ αβ TCR⁺ CD4⁺ cells (15–20% of all splenocytes). In contrast, CD8⁺ cells engrafted in very small numbers (1–5%) irrespective of the degree of MHC mismatching. T cells proliferated against recipient strain antigens and recognized recipient strain targets in cytolytic assays. Cytolysis was blocked by anti-MHC class II but not anti-CD8 or anti-MHC class I monoclonal antibodies (MoAbs). Cytolytic CD4⁺ T cells induced and maintained GVHD in mH-mismatched β₂m-/- mice, supporting endogenous mH presentation solely by MHC class II. Conversely, haematopoietic β₂m-/- cells were unable to engraft in normal MHC-matched recipients, presumably due to natural killer (NK)-mediated rejection of class I-negative cells. Donor-derived lymphokine-activated killer cells (LAK) were unable to overcome graft rejection (GR) and support engraftment.     

Functional cell surface expression by a recombinant single-chain class I major histocompatibility complex molecule with a cis-active β2-microglobulin domain

As a preliminary step towards the use of cell surface single-chain class I major histocompatibility complex (MHC) molecules as T cell immunogens, we have engineered a recombinant gene encoding a full-length cell surface single-chain version of the H-2D^d class I MHC molecule (SCβD^dm) which has β₂-microglobulin (β₂m) covalently linked to the amino terminus of a full-length H-2D^d heavy chain via a peptide spacer. The single-chain protein is correctly folded and stably expressed on the surface of transfected L cells. It can present an antigenic peptide to an H-2D^d-restricted antigen-specific T cell hybridoma. When expressed in peptide-transport-deficient cells, SCβD^dm can be stabilized and pulsed for antigen presentation by incubation with extracellular peptide at 27° or 37 °C, allowing the preparation of cells with single-chain molecules that are loaded with a single chosen antigenic peptide. SCβD^dm can be stably expressed in β₂m-negative cells, showing that the single-chain molecule uses its own β₂m domain to achieve correct folding and surface expression. Furthermore, the β₂m domain of SCβD^dm, unlike transfected free β₂m, does not rescue surface expression of endogenous class I MHC in the β₂m-negative cells. This strict cis activity of the β₂m domain of SCβD^dm makes possible the investigation of class I MHC function in cells, and potentially in animals, that express but a single type of class I MHC molecule.     

Influence of glycosylphosphatidylinositol-linked H-2Dd molecules on target cell protection and natural killer cell specificity in transgenic mice

The expression of certain major histocompatibility complex (MHC) class I ligands on target cells is one important determinate of their susceptibility to lysis by natural killer (NK) cells. NK cells express receptor molecules that bind to MHC class I. Upon binding to their MHC class I ligand, the NK cell is presumed to receive a signal through its receptor that inhibits lysis. It is unclear what role the MHC class I molecules of the effector and target cells play in signaling to the NK cell. We have investigated the role of the cytoplasmic and transmembrane domains of MHC class I molecules by producing a glycosylphosphatidylinositol (GPI)-linked H-2D^d molecule. The GPI-linked H-2D^d molecule is recognized by H-2D^d-specific antibodies and cytotoxic T lymphocytes. Expression of the GPI-linked H-2D^d molecule on H-2^b tumor cells resulted in protection of the tumor cells after transplantation into D8 mice (H-2^b, H-2D^d) from rejection by NK cells. In addition, NK cells from mice expressing the GPI-linked H-2D^d molecule as a transgene were able to kill nontransgenic H-2^b lymphoblast target cells. The GPI-linked MHC class I molecule was able to alter NK cell specificity at the target and effector cell levels. Thus, the expression of the cytoplasmic and transmembrane domains of MHC class I molecules are not necessary for protection and alteration of NK cell specificity.     

Fine tuning of natural killer cell specificity and maintenance of self tolerance in MHC class I-deficient mice

TAP1 −/−, β2-microglobulin (β2m) −/− and TAP1/β2m −/− mice all express low but quantitatively different levels of MHC class I molecules. Using these mice, we have addressed questions relating to the fine tuning of natural killer (NK) cell specificity and maintenance of self tolerance in the NK cell system. NK cells from B6 wild-type mice killed target cells from TAP1 −/−, β2m −/− and TAP1/β2m −/− mice in vivo and rejected bone marrow grafts from the same mice in vivo at equivalent levels. NK cells from TAP1 −/−, β2m −/− mice did not kill target cells or reject bone marrow grafts from TAP1/β2m −/− mice. NK cells in all MHC class I-deficient mice were tolerant to autologous MHC class I-deficient cells, as revealed by in vitro cytotoxicity assays using NK cell effectors activated with the interferon-inducing agent Tilorone, or by in vivo bone marrow graft experiments. However, the self-tolerant state of MHC class I-deficient NK cells was broken by in vitro stimulation with IL-2 for 4 days. Under these conditions, NK cells from the MHC class I-deficient mice killed autologous MHC class I-deficient cells while MHC class I-positive targets were spared. The C-type lectin inhibitory receptor Ly49C has a specificity for H-2K^b and is expressed on a subset of NK1.1⁺ cells in B6 mice. Wild-type and all MHC class I-deficient mice had similar numbers of Ly49C-positive NK1.1⁺ cells. However, Ly49C expression was markedly down-regulated on NK1.1⁺ cells from B6 mice, as compared to TAP1 −/−, β2m −/− and TAP1/β2m −/− mice. In vitro stimulation of NK cells with IL-2 for 4 days did not significantly change this pattern. The present results are discussed in relation to the role of MHC class I molecules and Ly49 receptors in shaping the NK cell repertoire and raise new questions about maintenance of self tolerance in the NK cell system.     

Major histocompatibility complex class I presentation of exogenously acquired minor alloantigens initiates skin allograft rejection

Major histocompatibility complex (MHC) class I molecules present peptides from endogenous proteins. However, in some cases class I-restricted peptides can also derive from exogenous antigens. This MHC class I exogenous presentation could be involved in minor histocompatibility antigen (mHAg)-disparate allograft rejection when donor alloantigens are not expressed in graft antigen-presenting cells (APC) that initiate the rejection mechanism. Here we addressed this question by using a skin graft experimental model where donors (H-2^b or H-2^d Tgβ-gal mice) expressed the mHAg like β-galactosidase (β-gal) in keratinocytes but not in Langerhans' cells (LC) which have an APC function. Rejection of Tgβ-gal skin by a β-gal-specific CD8 cytotoxic T lymphocyte (CTL) effector mechanism should require presentation by donor and/or recipient LC of MHC class I-restricted peptides of exogenous β-gal shed by keratinocytes. Indeed, our results showed that 1) H-2^b Tgβ-gal skin was rejected by H-2^bxs and H-2^bxd recipients; 2) rejection was mediated by β-gal-specific CD8⁺ CTL effectors; and 3) H-2^bxd mice having rejected H-2^b Tgβ-gal skin generated β-gal-specific CTL restricted by H-2^b and H-2^d class I molecules and rejected subsequently grafted H-2^d Tgβ-gal skin in an accelerated fashion, demonstrating that recipient LC have presented exogenous β-gal-derived MHC class I epitopes. These results lead to the conclusion that MHC class I exogenous presentation of donor mHAg can initiate allograft rejection.     

Alloreactive natural killer cells in the rat: complex genetics of major histocompabitility complex control

A major role for the nonclassical major histocompatibility complex (MHC) class I region, i.e. RTI.C, in controlling rat natural killer (NK) cell alloreactivity has recently been established, and several findings suggested the existence of NK-triggering alloantigens coded for by this region. Here, we have extended our studies on the MHC control of NK cell cytotoxicity against concanavalin A-activated T cell blasts by comparing semi-syngeneic and fully allogeneic combinations, and we show the following: (a) The self MHC exerted a strong influence on the NK allorecognition repertoire. (b) When anti-F₁ hybrid cytolytic activities of parental strain NK cells were measured, both recessively and non-recessively inherited susceptibility patterns emerged. (c) In most combinations parental strain cells were lysed by F₁ hybrid NK cells, thus resembling the hybrid resistance phenomenon described in mice. The cytotoxicity was lower in strain combinations where NK susceptibility was inherited non-recessively, i.e. when parent anti-F₁ reactivity was detected, than in recessive combinations. (d) LEW.1LM1 (RT1^1m1) target cells, with a deletion in the RTI.C region that includes expressed class I genes, were more sensitive to lysis by MHC matched NK cells (PVG.IL(LEW), RT1¹) than were parental LEW (RT1¹) cells. The effect of the deletion was the opposite when MHC allogeneic (RT1^c, RT1^u) as well as semi-syngeneic (RT1^1/c) NK cells were employed, i.e. sensitivity was decreased. We conclude that certain MHC-encoded antigens, depending on the haplotype combination of effector and target cells, may either trigger or inhibit rat NK cell cytotoxicity. Furthermore, the potential role of peptides bound to MHC class I molecules recognized by NK cells is discussed.     

Impact of donor MHC class I or class II antigen deficiency on first- and second-set rejection of mouse heart or liver allografts

The influence of donor major histocompatibility complex (MHC) class I- or class II-deficiency on the initiation of first- and second-set rejection of mouse heart and liver allografts was examined. C3H (H-2^k) mice received heterotopic cardiac or orthotopic liver grafts from unmodified B10 (H-2^b), B6 (H-2^b), b2m (H-2^b; class I deficient) or AB⁰ (H-2^b; class II deficient) donors. Organ survival was also investigated in C3H recipients that had been presensitized by a normal B10 skin graft 2–3 weeks before heart or liver transplantation. The absence of cell surface MHC class I or class II resulted in significant prolongation of primary cardiac allograft survival. Three of seven (43%) MHC class I-deficient, and two of five (40%) class II-deficient heart grafts were accepted indefinitely (survival time >100 days). Thus both MHC class I and class II molecules appear to be important for the elicitation of first-set rejection in the heart allograft model. All liver allografts survived >100 days in normal recipients. In C3H recipients that had been presensitized by a B10 skin graft, however, both heart and liver grafts from AB⁰ (class II deficient) donors underwent accelerated rejection (median survival time [MST] 3 and 4 days, respectively). In contrast, liver grafts from class I-deficient mice (b2m) were still accepted indefinitely by B10 skin-presensitized C3H recipients, whereas class I-deficient hearts survived significantly longer than those from class II-deficient or normal donors. These data demonstrate that the expression of donor MHC class I, and not class II is crucial in initiating second-set organ allograft rejection. In vitro monitoring revealed that at the time of organ transplant, both splenocytes and serum of the skin-presensitized animals displayed high cytotoxicity against AB⁰ (class II-deficient) but not against b2m (class I-deficient) targets.     

Location-specific regulation of transgenic Ly49A receptors by major histocompatibility complex class I molecules

Inhibitory receptors expressed on natural killer (NK) cells and T cells specific for major histocompatibility complex (MHC) class I are believed to prevent these cells from responding to normal self tissues. To understand the regulation and function of Ly49 receptor molecules in vivo, we used the CD2 promoter to target Ly49A expression to all thymocytes, T cells, and NK cells. In animals expressing its MHC class I ligand, H-2D^d or H-2D^k, there was a large decrease in the expression of Ly49A on thymocytes, peripheral T cells, and NK1.1⁺ cells. The extent of the down-regulation of Ly49A was dependent on the expression of the MHC ligand for Ly49A and on the site where the cells were located. The level of expression of endogenous Ly49A was similarly found to be dependent upon the organ where the cells resided. Data from bone marrow chimeras indicated that most cell types may regulate Ly49A expression, but the efficacy to regulate receptor expression may vary depending on the cell type.     

Reduced expression of major histocompatibility complex class I free heavy chains and enhanced sensitivity to natural killer cells after incubation of human lymphoid lines with β2-microglobulin

Enhancement of major histocompatibility complex (MHC) class I expression leads to protection from recognition by natural killer (NK) cells in several systems. MHC class I gene products can be expressed in different forms at the cell surface - for example as “empty” β₂-microglobulin (β₂m)-associated heterodimers or free heavy chains. To study the role of different class I heavy chain forms in NK target interactions, we have used lymphoblastoid target cell lines preincubated with β₂m. This was found to shift the equilibrium between β₂m-associated and nonassociated - heavy chains in favor of the former. In parallel, there was a significant increase in NK sensitivity. The recognition of MHC class I-deficient cell lines was not affected by β₂m, arguing against a general nonspecific effect of fern on NK sensitivity. Our data indicate that protection against NK recognition correlates with target cell expression of free heavy chains (i.e. devoid of β₂m) rather than with expression of complexes.     

Differential reactivity of residual CD8+ T lymphocytes in TAP1 and β2-microglobulin mutant mice

TAP1 -/- and β2-microglobulin (β2m) -/- mice (H-2^b background) express very low levels of major histocompatibility complex (MHC) class I molecules on the cell surface. Consequently these mice have low numbers of mature CD8⁺ T lymphocytes. However, TAP1 -/- mice have significantly higher numbers of CD8⁺ T cells than β2m -/- mice. Alloreactive CD8⁺ cytotoxic T lymphocyte (CTL) responses were also stronger in TAP1 -/- mice than in β2m -/- mice. Alloreactive CTL generated in TAP1 -/- and β2m -/- mice cross-react with H-2^b-expressing cells. Surprisingly, such cross-reactivity was stronger with alloreactive CTL from β2m -/- mice than with similar cells from TAP1 -/- mice. The β2m -/- mice also responded more strongly when primed with and tested against cells expressing normal levels of H-2^b MHC class I molecules. Such H-2^b-reactive CD8⁺ CTL from β2m -/- mice but not from TAP1 -/- mice also reacted with TAP1 -/- and TAP2-deficient RMA-S cells. In contrast, H-2^b-reactive CD8⁺ CTL from neither β2m -/- mice nor TAP1 -/- mice killed β2m -/- cells. In line with these results, β2m -/- mice also responded when primed and tested against TAP1 -/- cells. We conclude that the reactivity of residual CD8⁺ T cells differs between TAP1 -/- and β2m -/- mice. The MHC class I-deficient phenotype of TAP1 -/- and β2m -/- mice is not equivalent: class I expression differs between the two mouse lines with regard to quality as well as quantity. We propose that the differences observed in numbers of CD8⁺ T cells, their ability to react with alloantigens and their cross-reactivity with normal H-2^b class I are caused by differences in the expression of MHC class I ligands on selecting cells in the thymus.     

Comparative immunocytochemical study of MHC class II expression in human donor pancreas and isolated islets

Expression of major histocompatibility complex (MHC) molecules by pancreatic islets may influence the survival of pancreas or islet grafts in allogeneic recipients. This study compares the presence of MHC class II (HLA-DP, DQ, DX and DR)-positive cells in 27 pancreases and in 10 isolated islet preparations from human donors. Cells expressing MHC class II were present in all tissues examined as histiocytes located in interstitial areas in both the endocrine and nonendocrine components and as endothelial cells in the nonendocrine part. Endocrine, acinar and duct cells were MHC class II negative. In pancreases from donors under the age of 7 years the frequency of MHC class II-positive histiocytes was only one third of that in adults, and they rarely contained MHC class II-positive endothelial cells. The MHC class II-positive hisiocytes were further phenotyped as macrophages positive for LCA and acid phosphatase, or dendritic cells negative for the latter markers. Dendritic cells were frequent in adult organs but rare in organs from donors under 7 years of age. In freshly isolated islet preparations from adult donors, less than 1% of the cells were MHC class II positive. These were identified as resident macrophages and dendritic cells. No MHC class II positive cells were encountered in the islet capillaries. The putative role of MHC class II-positive donor cells in allograft rejection suggests that these differences in MHC class II expression influence the immunogenicity of pancreatic and islet grafts in an age-dependent manner.     

The interaction of beta 2-microglobulin (β2m) with mouse class I major histocompatibility antigens and its ability to support peptide binding. A comparison of human and mouse β2m

The function of major histocompatibility complex (MHC) class I molecules is to sample peptides derived from intracellular proteins and to present these peptides to CD8⁺ cytotoxic T lymphocytes. In this paper, biochemical assays addressing MHC class I binding of both peptide and β₂-microglobulin (β₂m) have been used to examine the assembly of the trimolecular MHC class I/β₂m/peptide complex. Recombinant human β₂m and mouse β₂m² have been generated to compare the binding of the two β₂m to mouse class I. It is frequently assumed that human β₂m binds to mouse class I heavy chain with a much higher affinity than mouse β₂m itself. We find that human β₂m only binds to mouse class I heavy chain with slightly (about 3-fold) higher affinity than mouse β₂m. In addition, we compared the effect of the two β₂m upon peptide binding to mouse class I. The ability of human β₂m to support peptide binding correlated well with its ability to saturate mouse class I heavy chains. Surprisingly, mouse β₂m only facilitated peptide binding when mouse β₂m was used in excess (about 20-fold) of what was needed to saturate the class I heavy chains. The inefficiency of mouse β₂m to support peptide binding could not be attributed to a reduced affinity of mouse β₂m/MHC class I complexes for peptides or to a reduction in the fraction of mouse β₂m/MHC class I molecules participating in peptide binding. We have previously shown that only a minor fraction of class I molecules are involved in peptide binding, whereas most of class I molecules are involved in β₂m binding. We propose that mouse β₂m interacts with the minor peptide binding (i.e. the “empty”) fraction with a lower affinity than human β₂m does, whereas mouse and human β₂m interact with the major peptide-occupied fraction with almost similar affinities. This would explain why mouse β₂m is less efficient than human β₂m in generating the peptide binding moiety, and identifies the empty MHC class I heavy chain as the molecule that binds human β₂m preferentially.     

The ability of H-2Dd molecule to affect natural resistance to hemopoietic allografts is an intrinsic property shared by Ddm1 but not Ld

F₁ hybrid resistance (HR) to parental bone marrow grafts is mediated by natural killer (NK) cells, and thought to be controlled by the non-class I hemopoietic histocompatibility (Hh) genes linked to the major histocompatibility complex (MHC). However, as in the in vitro NK cytotoxicity against hemopoietic targets, expression of certain class I MHC molecules does affect HR, although mechanisms underlying such an effect are not understood. In this study, we examine the relevance of the “self/non-self” property of class I molecules and the molecular domains responsible for this function. H-2^b/Hh-1^b lymphoma cells were transfected with class 1 H-2D^d or L^d gene, and its effect on the Hh-1 phenotype was examined by testing the transfectant's ability to competitively inhibit the in vivo rejection of parental H-2^b/Hh-1^b bone marrow grafts by irradiated F₁ hybrid hosts. Multiple independent clones of transfectants show that the genomic or cDNA of the D^d gene, but not of L^d, renders the Hh-1^b-positive cells incapable of inhibiting HR in F₁ mice, although both genes belong to the same region of the same haplotype. The same effect could be observed not only in H-2^b/d F₁ mice for which D^d and L^d are self, but also in H-2^b/k F₁ mice for which both D^d and L^d are non-self. Thus, this function of the D^d molecule is an intrinsic property, not necessarily related to its self/non-self characteristic relative to the effector cells. Furthermore, given the nature of the assay used in this study, the results favor a “target interference” model as the underlying mechanism of the D^d effect. To locate the relevant domain(s) of the D^d molecule, mutant D^dm1 gene was tested and found to have the same effect as the non-mutant D^d. D^dm1 is a hybrid molecule between D^d and L^d, sharing with D^d only the α1 domain and a portion of the α2 domain. The two N-terminal domains of D^dm1 differ from those of D^d by three amino acid substitutions, two of which affect the molecules' peptide-binding properties.     

The mechanism of specific prolongation of class I-mismatched skin grafts induced by retroviral gene therapy

In the present study, we examine the mechanism of specific hyporesponsiveness to major histocompatibility complex (MHC) class I-mismatched skin allografts induced by retrovirus-mediated gene transfer of an allogeneic class I gene into syngeneic bone marrow (BM). Using appropriate congenic recombinant mouse strains, we have mapped MHC determinants that are capable of restoring rapid rejection of K^b-bearing skin grafts. Our results indicate that either a single class I or a single class II alloantigen expressed on skin in association with K^b is able to restore the rapid rejection of K^b -mismatched skin grafts. These data suggest that third-party alloantigens expressed on skin in association with K^b abrogate hyporesponsiveness by providing T cell help. Consistent with this interpretation, spleen cells from mice reconstituted with K^b-transduced BM were unable to elicit a significant anti-K^b cytotoxic T lymphocyte response in vitro unless interleukin-2 was added to the culture medium. Skin graft survival was also analyzed on B10.AKM mice thymectomized 3–4 weeks post-reconstitution with K^b-transduced BM. Thymectomy did not result in significantly prolonged survival of B10.MBR skin grafts compared to euthymic controls, suggesting that even early after reconstitution, intrathymic deletion of K^b-reactive T cells must have been incomplete. Taken together, these data suggest that prolongation of skin allograft survival in this model is controlled at the level of T cell help.     

A quantitative assay to measure the interaction between immunogenic peptides and purified class I major histocompatibility complex molecules

A direct and sensitive biochemical assay to measure the interaction in solution between peptides and affinity-purified major histocompatibility complex (MHC) class I molecules has been generated. Specific binding reflecting the known class I restriction of cytotoxic T cell responses was obtained. Adding an excess of β₂-microglobulin (β₂m) significantly increased the rate of peptide association, but it did not affect the rate of dissociation. Binding was complicated by a rapid and apparently irreversible loss of functional MHC class I at 37°C which might limit the life span of empty MHC class I thereby preventing the inadvertent exchange of peptides at the target cell surface. All class I molecules tested bound peptides of the canonical octa- to nona-meric length. However, one class I molecule, K^k, also bound peptides, which were much longer suggesting that the preference of class I molecules for short epitopes is not absolute and may be caused by factors other than the peptide-MHC class I binding event itself.     

β2 -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 β2 -microglobulin (β₂ m− mice) express greatly reduced levels of MHC class I molecules, and cells from β₂ m− mice are therefore highly sensitive NK cells. However, NK cells from β₂ m− mice fail to kill β₂ m− 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 β₂ m− NK cells. In a comparison between several MHC class I-deficient and positive target cell pairs for sensitivity to β₂ m− NK cells, we made the following observations: First, β₂ m− NK cells displayed a close to normal ability to kill a panel of MHC class I-deficient tumor cells, despite their nonresponsiveness to β₂ m− concanavalin A (Con A)-activated T cell blasts. Secondly, β₂ m− NK cells were highly sensitive to MHC class I-mediated inhibition, in fact more so than β₂ m+ NK cells. Third β₂ m− NK cells were not only tolerant to β₂ m− 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 β₂ m− 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 β₂ m− mice, which may instead operate through mechanisms involving triggering pathways.     

Lack of F1 anti-parental resistance in H-2b/d F1 hybrids devoid of β2-microglobulin

F₁ hybrid mice often reject parental hematopoietic grafts, a phenomenon known as hybrid resistance. Hybrid resistance is mediated by natural killer (NK) cells and although the molecular interactions responsible for this phenomenon are largely unknown, one hypothesis suggests that parental cells are rejected because they fail to express a complete set of host major histocompatibility complex (MHC) class I molecules. Inherent in this theory is that NK cells in the F₁ hybrid are instructed by self MHC class I molecules to form an NK cell repertoire capable of reacting against cells lacking these self MHC class I molecules. Here, we show that C57BL/6 x DBA/2 mice (H-2^b/d) devoid of β₂-microglobulin (β₂m) are incapable of rejecting β₂m?/? parental C57BL/6 cells (H-2^b) both in vivo and in vitro. From this, we conclude that the development of an NK cell repertoire, at least in F₁ mice of the H-2^b/d haplotype, requires expression of MHC class I molecules complexed with β₂m.     

Major histocompatibility complex genes determine natural killer cell tolerance

Murine natural killer (NK) cell subsets, as defined by expression of members of the Ly49 gene family, discriminate target cells expressing different major histocompatibility complex (MHC) class I alleles. For example, Ly49A⁺ NK cells lyse H-2^b but not H-2^d tumor target cells. The specificity arises because D^d on target cells binds to Ly49A, transducing an inhibitory signal into the Ly49A⁺ NK cells. The capacity of NK cells to discriminate allelic class I determinants raises a key issue: are NK cells self-tolerant, and if so what are the mechanisms that lead to self-tolerance? As previously reported, potentially autoaggressive Ly49A⁺ NK cells are not clonally deleted in H-2^b mice. However, IL-2- cultured Ly49A⁺ effector cells from H-2^b mice exhibit reduced lysis of H-2^b (self) concanavalin A blast target cells, compared to Ly49A⁺ effector cells from H-2^d mice. Possible mechanisms accounting for this self-tolerance are addressed in this report. Self-tolerance was not due to anergy of the cells, because the Ly49A⁺ effector cells from both types of mice lysed β2-microglobulin-deficient target cells efficiently and equivalently. These results also suggest that tolerance results from inhibition mediated by β2m-dependent H-2^b class I molecules. Significantly, blockade of Ly49A on Ly49A⁺ effector cells from H-2^b mice did not restore lysis of H-2^b target cells, suggesting that inhibition is not mediated through the Ly49A receptor. Additional experiments suggest that inhibition is also not mediated primarily through the Ly49C receptor. These results suggest that Ly49A⁺ effector cells from H-2^b mice, unlike those from H-2^d mice, express inhibitory receptors specific for H-2^b molecules that are distinct from Ly49A and Ly49C.     

Cross-reactivity among evolutionarily distant major histocompatibility complex class I molecules (HLA-B27 and H-2Kk) revealed by xenoreactive T lymphocytes

A set of mouse HLA-B27-reactive cytotoxic T lymphocyte clones were found to recognize the HLA-B27 molecule in an H-2-unrestricted manner, i.e. independently of any mouse major histocompatibility complex (MHC) molecule. The reactivity patterns of these clones on HLA-B27 variants (positive only on HLA-B*2702 and HLA-B*2701) allowed the identification of residues N77 and A81 of the HLA-B27 molecule as important for their reactivity. The location of these residues in the peptide-binding groove (specificity pocket F) suggested that the reactivity of the clones is dependent on HLA-B27-bound peptide(s). However, several other class I molecules sharing these residues (N77 and A81) were not recognized, indicating that other residues might also be involved. One of the clones was found to display an interesting cross-reactivity with allogeneic H-2K^k molecules, sharing N77 and A81 with HLA-B*2702. Sequence comparison suggested the involvement of residue H9, located in specificity pocket B of the peptide-binding groove, and revealed some similarity of pockets B in HLA-B27 and H-2K^k. The structural basis of such T cell-mediated MHC cross-reactions across species barriers is discussed.     

The effect of anchor residue modifications on the stability of major histocompatibility complex class I-peptide interactions

Anchor residues in peptides determine the specificity of binding to major histocompatibility complex class I molecules through interactions of their side chains with pockets in the peptide-binding groove. We have compared the kinetics of association of a Sendai virus nucleoprotein-derived peptide (FAPGNYPAL, termed SV9) with H-2K^b class I molecules, and the same peptide iodinated on the anchor residue tyrosine (¹²⁵I-SV9). Even though the association rates were too rapid for direct measurements, competition studies indicated that they were similar for SV9 and ¹²⁵I-SV9. To measure the binding of non-radioactive SV9 directly, SV9 was tritiated (³H-SV9). ³H-SV9 remained stably associated with H-2K^b molecules, whereas ¹²⁵I-SV9 dissociated in a temperature-dependent fashion. Thus, modifications on anchor residues do not necessarilly have to affect the specificity and association kinetics of peptide binding to class I molecules but can affect the stability of the resulting class I-peptide interaction. The dissociation of peptides with modified and, more generally, suboptimal anchor residue side chains may explain the presence of empty class I molecules and free class I heavy chains at the cell surface.