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.     

Induction and functional characterization of β 2-microglobulin (β2-μ)-free HLA class I heavy chains expressed by β2-μ-deficient human FO-1 melanoma cells

The frequent loss of β2-microglobulin (β₂-μ) in malignant cells has stimulated interest in the functional characteristics of β₂-μ-free HLA class I heavy chains, since this information contributes to assess the impact of β₂-μ abnormalities on the interaction of malignant cells with immune cells. Therefore, the present study has investigated the ability of β₂-μ-free HLA class I heavy chains to modulate NK cell-mediated lysis of melanoma cells and to present melanoma-associated antigen (MAA)-derived peptides to HLA class I-restricted, MAA-specific cytotoxic T lymphocytes (CTL). β₂-μ-free HLA class I heavy chains were induced on B₂m null FO-1 cells by sequential incubation with IFN-α for 48 h at 37 °C and for 24 h at 26 °C. Transfection of cells with a wild-type H-2L^d gene (FO-1L^d) enhanced the induction of β₂-μ-free HLA class I heavy chains under such experimental conditions. β₂-μ-free HLA class I heavy chains expressed on the cell membrane did not protect the B₂m null FO-1 cells from NK cell-mediated lysis. Furthermore, FO-1 cells which express β₂-μ-free HLA-A2 heavy chains following transfection with a wild-type HLA-A2 gene were not lysed by HLA-A2-restricted, MAA-specific CTL lines and clones. These results indicate that association with β₂-μ is required for interaction of HLA class I molecules with NK inhibitory receptors and for peptide presentation to CTL.     

Expression of β2m-Free HLA Class I Heavy Chains in Neuroblastoma Cell Lines

Flow cytometry with the specific monoclonal antibody (MoAb) L31 was used to analyse the expression of HLA class I heavy chains not bound with β₂-microglobulin (β₂m) by neuroblastoma (NB) cell lines IMR-32 and LA-N-1. The cells, which express barely detectable amounts of β₂m-free (L31-positive molecules) and β₂m-complexed HLA class I antigens (W6.32- and BBM. I-reactive molecules), expressed MHC class I molecules not bound to light chains upon differentiation with either retinoic acid or serum starvation. The expression was not accompanied by an increase of surface heterodimers. Conversely, recombinant interferon-γ (rIFN-γ) treatment led IMR-32 and LA-N-1 cells to almost exclusively express β₂m-complexed HLA class I heavy chains. Surface β₂m-free MHC class I molecules displayed a molecular mass of ~45 kDa and did not bind exogenously added β₂m. No changes in the synthesis of either HLA class I and β₂m mRNAs or of L31 proteins were observed in differentiated NB cells, thus suggesting that the surface exposure of unusual HLA class I antigens is regulated post-translationally. These findings indicate that, in addition to activated lymphocytes, the surface expression of β₂m-free class I heavy chains is a feature of other cell types, such as NB cells.     

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.     

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.     

Inhibition of natural killer cell-mediated bone marrow graft rejection by allogeneic major histocompatibility complex class I,but not class II molecules

The role of major histocompatibility complex (MHC) class I and class II molecules in natural killer (NK) cell-mediated rejection of allogeneic, semi-syngeneic and MHC-matched bone marrow grafts was investigated. The use of β₂-microglobulin (β₂m) -/- and β₂m +/- mice as bone marrow donors to MHC-mismatched recipients allowed an analysis of whether the presence of semi-syngeneic and allogeneic MHC class I gene products would be triggering, protective or neutral, in relation to NK cell-mediated rejection. Loss of β₂m did not allow H-2^b bone marrow cells to escape from NK cell-mediated rejection in allogeneic (BALB/c) or semi-allogeneic (H-2D^d transgenic C57BL/6) mice. On the contrary, it led to stronger rejection, as reflected by the inability of a larger bone marrow cell inoculum to overcome rejection by the H-2-mismatched recipients. In H-2-matched recipients, loss of β₂m in the graft led to a switch from engraftment to rejection. At the recipient level, loss of β₂m led to loss of the capability to reject H-2-matched β₂m-deficient as well as allogeneic grafts. When MHC class II-deficient mice were used as donors, the response was the same as that against donors of normal MHC phenotype: allogeneic and semi-syngeneic grafts were rejected by NK cells, while syngeneic grafts were accepted. These data suggest a model in which allogeneic class I molecules on the target cell offer partial protection, while certain syngeneic class I molecules give full protection from NK cell-mediated rejection of bone marrow cells. There was no evidence for a role of MHC class II molecules in this system.     

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.     

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.     

A dual function of NKG2D ligands in NK-cell activation

NK-cell killing requires both the expression of activating receptor ligands and low MHC class I expression by target cells. Here we demonstrate that the expression of any of the murine ligands for the NK-cell activating receptor NKG2D results in a concomitant reduction in MHC class I expression. We show this both in tumor cell lines and in vivo. NK-cell lysis is enhanced by the decrease in MHC class I expression, suggesting the change is biologically relevant. These results demonstrate that NKG2D ligand expression on target cells not only allows for activating receptor recognition, but also actively reduces expression of the inhibitory ligand, MHC class I, leading to enhanced recognition and killing by NK cells.     

Lateral organization of the ICAM-1 molecule at the surface of human lymphoblasts: A possible model for its co-distribution with the IL-2 receptor,class I and class II HLA molecules

Lateral distribution of the ICAM-1 molecule and its topological relationship (mutual proximity) to the heavy and light chains of class I HLA molecules, HLA-DR and interleukin-2 receptor α-chain (IL-2Rα) were studied in the plasma membrane of HUT-102B2 T and JY B lymphoblastoid cell lines by the technique of flow cytometric energy transfer (FCET). Effects of adherency and treatments with recombinant interferon-γ or tumor necrosis factor-α on the relative expression level of ICAM-1 to the above cell surface proteins were also investigated. While the cytokines did not significantly affect the ICAM-1 level of either cell line, an increased ICAM-1 expression was found on adherent JY cells. The ICAM-1 expression varied significantly with the cell cycle and culture conditions, as well. The statistical analysis of the differences observed in the energy transfer efficiency histograms resulted in a possible model of lateral co-distribution of these proteins in the plasma membrane. These two-dimensional patterns proved to be different for T and B lymphoma lines. ICAM-1 molecules showed a high degree of self-ssociation on HUT-102B2 (T) cells, while they were mainly expressed as monomers on the surface of JY (B) cells. Both cells showed a significant (ca. 30 %) difference between densities of the heavy and light chains of class I HLA antigen, suggesting a substantial amount of β2-microglobulin free heavy chains on these cell lines. The class I HLA molecules also showed partial self-association, but on both cell lines. The β₂-microglobulin and the heavy chain of the class I HLA showed strongly different proximities to the IL-2Rα, HLA-DR and ICAM-1 molecules, indicating that their orientations relative to the other proteins are dissimilar. IL-2Rα molecules of the HUT-102B2 (T) cells are located mostly in the vicinity of the β₂-microglobulin. In contrast, the local density of HLA-DR antigens is higher in the proximity of the heavy chain than in the vicinity of the β₂-microglobulin. The possible functional significance of these protein patterns is also discussed herein.     

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.     

Exogenous peptide ligand influences the expression and half-life of free HLA class I heavy chains ubiquitously detected at the cell surface

A pool of free HLA class I chains has been detected at the plasma membrane of all cells concomitantly expressing folded and assembled class I molecules. To determine the origin of these free HLA heavy chains, we have examined the biosynthesis of a single HLA class I molecule, HLA-B27, expressed by a murine cell line (L-B27). In L-B27 cells, as previously shown in Epstein-Barr virus-transformed lymphoblastoid cell lines, a precursor/product relationship exists, early in biosynthesis, between free (HC10-reactive) and beta-2-microglobulin (β₂m)-associated (W6/32-reactive) class I heavy chains as demonstrated by pulse/chase experiments. At later stages in class I biosynthesis, both HC10- and W6/32-reactive heavy chains display complex oligosaccharides and accumulate at the cell surface. HC10- and W6/32-reactive molecules are both very stable at the cell surface, with half-lifes (t_1/2) of > 7 h and ～ 4 h, respectively. Interestingly, cell surface expression and turnover of HC10- and W6/32-reactive molecules were affected by the addition of peptide ligands to the culture media. Culturing cells in the presence of HLA-B27 ligands resulted in the increased expression of W6/32-reactive molecules and the decreased expression of HC10-reactive molecules. Moreover, addition of exogenous peptide extended the t_1/2 of W6/32-reactive molecules to > 7 h and reduced that of HC10-reactive molecules to 4 h. These results indicate that surface HC10-reactive molecules result largely from W6/32-reactive molecules following peptide and β₂m dissociation. Therefore, HC10-reactive species are not only the precursors but also the end products in class I biosynthesis.     

Class IMHC molecules: assembly and antigen presentation

Summary: Several years ago, the only factor known to be necessary for the assembly and surface expression of class I MHC was pjm; even for β₂m, it was unclear at what point in class I maturation its role was played. Recent experiments that employed attachment of an endoplasmic reticulum (ER) retention signal to β₂m have shown that the point of time at which β₂m is required is while the class I heavy chain is in the ER. Later association between β₂m and class I is not vital in order for properly folded class I to be expressed at β₂m cell surface. After crystallization of the first class I MHC molecule, it was reahed that not only is antigen presented by class I, but that antigen is presented in the form of a peptide that stabilizes the class I structure and allows its transit to the cell surface. Class I allelic differences influence interactions with both peptide and β₂m, with likely consequences for the ability of the class I heavy chains to present antigen through alternative pathways. Furthermore, it is now also clear that formation of appropriate disulfide bonds in the class I heavy chain is needed before class I can bind peptide antigen securely, a process that may he assisted by an ER chaperone. Many different proteins that are resident in the ER, such as calnexin, transporter associated with antigen processing (TAP), caheticulin, and tapasin, have been found to be integral to class I assembly. TAP, tapasin, and calreticulin hind preferentially to the open form of class I, which can be distinguished with the use of a monoclonal antibody specific for this form. Calreticulin and calnexin contrast in their interactions with class I, despite other similarities between these two chaperones. Overall, class I MHC assembly is now understood to involve the interplay of multiple intra- and intermolecular events in a defined chronological order which ensure continual reporting of cellular contents to cytotoxic T lymphocytes.     

β2-microglobulin with an endoplasmic reticulum retention signal increases the surface expression of folded class I major histocompatibility complex molecules

With β₂-microglobulin^? (β₂m^?) cell lines such as R1E/D^b, the surface expression of class I major histocompatibility complex molecules is greatly impaired, and class I molecules that are on the surface are generally misfolded. To determine whether β₂m must be continually present with the class I heavy chain for the class I molecule to reach the surface in a folded conformation, a sequence encoding an endoplasmic reticulum (ER) retention signal (KDEL) was attached onto the 3′ end of a β₂m cDNA. After this chimeric cDNA was transfected into R1E/D^b cells, β₂m-KDEL protein was detectable by an anti-β₂m serum within the cells but not at the cell surface. Interestingly, R1E/D^b cells transfected with β₂m-KDEL were found to express a high level of conformationally correct D^b molecules at the cell surface. This observation implies that β₂m has a critical and temporal role in the de novo folding of the class I heavy chain. We propose that the critical time for β₂m association is when the class I molecule is docked with the transporter associated with antigen processing (TAP) and first interacts with peptide.     

Surface expression of β2-microglobulin-associated thymus-leukemia antigen is independent of TAP2

Mouse thymus-leukemia antigen (TL), like other major histocompatibility complex (MHC) class I-b antigens, displays signs of a specialized function. It is normally expressed at high levels on immature thymocytes and at moderate levels on gut epithelium and activated mature T cells. A promoter/enhancer region unique among class I genes accounts for this narrow range of tissue distribution. Like most other class I molecules, TL is dependent upon endogenous β2-microglobulin (β2m) for transport to the surface. However, here we show that unlike most other MHC class I molecules, TL is expressed efficiently in the absence of functional transporter associated with antigen processing subunit 2 (TAP2). A putative fourth TL^a gene cloned from A.SL1 cells was expressed in RMA and RMA-S cells. In bulk transformants, TL expression is higher in TAP2^? RMA-S cells than in wild-type RMA cells, and is not elevated by incubation at reduced temperatures or exposure to exogenous β2m. Analysis of immunoprecipitasted molecules by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate indicates that TL is processed normally in RMA-S cells and is associated with β2m both intracellularly and at the cell surface. However, TL heavy chains expressed on the cell surface in the absence of TAP2 are cleaved to a predominant 38 kDa fragment, presumably the result of an altered conformation that renders TL more susceptible to proteolysis. These results suggest that while TL may normally acquire TAP2-dependent peptides, this class I-b molecule does not require them for efficient export to, and stable expression at the cell surface.     

Modified Human Beta 2‐Microglobulin (desLys58) Displays Decreased Affinity for the Heavy Chain of MHC Class I and Induces Nitric Oxide Production and Apoptosis

Beta2‐microglobulin (β2m) is the light chain of major histocompatibility complex class I (MHC‐I) molecules, and is a prerequisite for the binding of peptides to the heavy chain and their presentation to CD8⁺ T cells. β2m can be modified in vivo and in vitro by proteolytic cleavage by complement C1 and subsequent carboxypeptidase B‐like activity – processes that lead to the generation of desLys⁵⁸β2m (dβ2m). This work aims to study the effect of dβ2m on peptide binding to MHC‐I, the influence of dβ2m on the binding of β2m to the MHC‐I heavy chain and the biological activity of dβ2m. Both β2m and dβ2m are able to support the generation of MHC‐I/peptide complexes at 18 °C, but complexes formed in the presence of dβ2m destabilize at 37 °C. Moreover, a 250 times higher concentration of dβ2m than of β2m is needed to displace MHC‐I associated β2m from the cell surface. In addition, only β2m is able to restore MHC‐I/peptide complex formation on acid‐treated cells whereas dβ2m appears to bind preferentially to denatured MHC‐I heavy chains. In cell cultures, exogenously added dβ2m, but not β2m, induces apoptotic cell death in monocytic leukaemic cell lines but spares other kinds of leukaemic cells. Additionally, the presence of dβ2m, and to a lesser extent β2m, enhances IFN‐γ‐induced NO production by monocytic leukaemic cells. In conclusion, these data show that dβ2m is not able to support the formation of a stable tri‐molecular MHC‐I complex at physiological temperature and that dβ2m exerts other biological functions compared to β2m when bound to cells.     

The assembly of H2-Kb class I molecules translated in vitro requires oxidized glutathione and peptide

Association of the mouse major histocompatibility complex (MHC) class I heavy chain H2-K^b with mouse β₂-microglobulin (β₂m) was studied in an in vitro translation system. Formation of stable class I complexes was found to be dependent on the presence of presentable peptides and oxidized glutathione, which promotes the formation of disulfide bridges. Translocation of peptides into microsomes was demonstrated by showing that a radioiodinated peptide containing an N-glycosylation acceptor site became glycosylated. Class I complex formation was observed only when heavy chains and β₂m were translated simultaneously, and thus occurs in the microsomes and not after their solubilization. However, peptide binding takes place only after solubilization of the microsomes. The class I complexes translated in vitro show the same specificity and length preference for peptides as their counterparts in RMA-S cells. Assembly of in vitro translated class I complexes was found to occur also in the absence of peptides, resulting in the formation of unstable molecules that are stabilized by incubation with peptides.     

Blocking oncogenic RAS enhances tumour cell surface MHC class I expression but does not alter susceptibility to cytotoxic lymphocytes

Mutations in the RAS family of oncogenes are highly prevalent in human cancer and, amongst its manifold effects, oncogenic RAS impairs the expression of components of the antigen presentation pathway. This allows evasion of cytotoxic T lymphocytes (CTL). CTL and natural killer (NK) cells are reciprocally regulated by MHC class I molecules and any gain in CTL recognition obtained by therapeutic inactivation of oncogenic RAS may be offset by reduced NK cell activation. We have investigated the consequences of targeted inactivation of oncogenic RAS on the recognition by both CTL and NK cells. Inactivation of oncogenic RAS, either by genetic deletion or inactivation with an inducible intracellular domain antibody (iDAb), increased MHC class I expression in human colorectal cell lines. The common RAS mutations, at codons 12, 13 and 61, all inhibited antigen presentation. Although MHC class I modulates the activity of both CTL and NK cells, the enhanced MHC class I expression resulting from inactivation of mutant KRAS did not significantly affect the in vitro recognition of these cell lines by either class of cytotoxic lymphocyte. These results show that oncogenic RAS and its downstream signalling pathways modulate the antigen presentation pathway and that this inhibition is reversible. However, the magnitude of these effects was not sufficient to alter the in vitro recognition of tumour cell lines by either CTL or NK cells.     

Strong association of HLA-B27 heavy chain with β2-microglobulin

Monoclonal antibody TG1 recognizes specifically antigens HLA-B27, B7, B22 and B17 on cell surface in cytotoxicity and cytofluorometry tests. When cell detergent extracts were subjected to SDS PAGE under mild conditions (no heating and no reduction of the sample) followed by Western blotting, TG1 detected exclusively a complex of B27 heavy chains with β₂-microglobulin (as a 50 kDa band) whereas the other B-locus antigens (B7, B22, B17) were detected as free 43 kDa heavy chains under the same conditions. When the samples were boiled prior to SDS PAGE, TG1 detected again the 43 kDa free heavy chains of B7, B22 and B17 but no zone corresponding to B27 could be detected indicating that the epitope in free B27 chains is more sensitive to denaturation by SDS. Thus, our main finding is that the interaction of HLA-B27 heavy chain with β₂-microglobulin appears to be stronger than that of the other HLA-B chains. The resistance of the HLA-B27/β₂-microglobulin complex to the SDS dissociation is strikingly similar to the behavior of MHC class II molecules under similar conditions. Thus, it may be speculated that HLA-B27 complexes can be also more stable than other MHC class I molecules under more physiological dissociative conditions (e.g. in endosomal compartments). This feature might potentially influence antigen presentation by HLA-B27 and contribute to the well known disease linkage of HLA-B27.     

Conformational changes induced in the MHC class I molecule by peptide and β2-microglobulin

Assembly of the class I MHC molecule is inextricably linked to the antigen presentation function of the class I molecule. Association of the class I MHC molecule with β₂-microglobulin (β₂m) is a prerequisite for association with the heterodimeric protein TAP, and once peptide is acquired, the class I molecule folds and begins its sojourn to the cell surface. To maintain its folded conformation, class I MHC requires peptide but not β₂m, and the sequence of the peptide bound exercises a subtle influence on the structure of the class I molecule that is likely to be a factor in T cell receptor discrimination of MHC/peptide complexes.