In the absence of aminopeptidase ERAAP, MHC class I molecules present many unstable and highly immunogenic peptides

Immunosurveillance by cytotoxic T cells requires that cells generate a diverse spectrum of peptides for presentation by major histocompatibility complex (MHC) class I molecules. Those peptides are generated by proteolysis, which begins in the cytoplasm and continues in the endoplasmic reticulum by the unique aminopeptidase ERAAP. The overall extent to which trimming by ERAAP modifies the peptide pool and the immunological consequences of ERAAP deficiency are unknown. Here we show that the peptide-MHC repertoire of ERAAP-deficient mice was missing many peptides. Furthermore, ERAAP-deficient cells presented many unstable and structurally unique peptide-MHC complexes, which elicited potent CD8+ T cell and B cell responses. Thus, ERAAP is a 'quintessential editor' of the peptide-MHC repertoire and, paradoxically, its absence enhances immunogenicity.     

Positive selection of a Qa-1-restricted T cell receptor with specificity for insulin

The phenotype and development of T cells from transgenic mice expressing a T cell receptor with specificity for insulin presented by the MHC class Ib molecule Qa-1(b) was investigated. Peripheral T cells from the transgenic mice express CD8 and, after activation, kill Qa-1(b)-positive lymphoid target cells in the presence of soluble insulin. Thymic selection requires expression of Qa-1(b) but not the dominant Qa-1-associated peptide, Qdm. In contrast to conventional T cells, selection is at least as efficient when the selecting ligand is expressed only on hematopoietic lineage cells as compared to expression on epithelial cells in the thymus. Our findings suggest that there is a dedicated population of Qa-1-restricted T cells that are selected by interaction with Qa-1 and that the cellular requirements for selection may differ from conventional T cells.     

Role of Qa-1(b)-binding receptors in the specificity of developing NK cells

NK cells acquire the ability to recognize MHC class I molecules during development. Studies with Qa-1(b) tetramers (Qa-1 tetramers) showed that nearly all NK1.1(+) cells from newborn C57BL/6 mice express Qa-1-binding receptors. Cytotoxic activity of these cells is fully inhibited by Qa-1 ligands on target cells. In contrast, neither receptors for H-2K(b) nor H-2D(b) were observed on NK1.1(+) cells from newborn mice. After birth, frequencies of Qa-1 tetramer(+)/ NK1.1(+) cells gradually decrease as the number of Ly49(+) /NK1.1(+) cells increases. Cell transfer studies showed that Qa-1 tetramer(+) cells from newborn mice do not lose expression of Qa-1 receptors, but that they further acquire expression of Ly49 molecules. Acquisition of Qa-1-binding receptors appears largely independent of host MHC class I molecules, as observed in studies using beta2-microglobulin-deficient (beta2m(-/-)) mice as well as K(b)/ D(b-/-) and K(b)/D(b)/beta2m(-/-) mice. The present results suggest that Qa-1-binding receptors play an important role in the specificity of developing NK cells, and suggest that these cells rely mainly on inhibitory receptors specific for non-classical MHC class I molecules to maintain self tolerance during the first weeks of life.     

Cytotoxic T lymphocyte precursor cells specific for the major histocompatibility complex class I-like antigen, Qa-2, require CD4+ T cells to become primed in vivo and to differentiate into effector cells in vitro.

Experiments were performed to determine whether CD4+ T cells are required for the generation of cytotoxic T lymphocytes (CTL) specific for the nonpolymorphic major histocompatibility complex (MHC) class I-like antigen, Qa-2. Splenic T cells from BALB/cBy (Qa-2b) mice that had been immunized with irradiated BALB/cJ (Qa-2a) splenocytes generated CTL following in vitro stimulation with BALB/cJ splenocytes. These CTL lysed all Qa-2+, but not Qa-2- targets, regardless of the H-2 haplotypes of target cells or their non-MHC backgrounds. This apparent MHC class I-unrestricted recognition of Qa-2 antigen was confirmed using Qa-2-specific CTL clones. The Qa-2-primed CTL precursor cells (CTLp) and CTL were found to be CD8+ T cells. Primed splenocytes depleted of CD4+ T cells prior to culture failed to generate CTL, but addition of lymphokines to the culture restored the CTL generation. Stimulation of primed splenic T cells with irradiated Qa-2+ T blast cells, instead of splenocytes or B blast cells, led to little to no CTL generation, suggesting that MHC class II molecules are involved in the presentation of Qa-2 antigen to CD4+ T cells. This was also supported by the results of experiments using Qa-2+, class II- thymoma cells of BALB/c origin. Stimulation of the thymoma-primed splenic T cells with the mitomycin C-treated thymoma cells resulted in no generation of anti-Qa-2 CTL, despite the fact that high levels of CTL specific for minor histocompatibility (H) antigens and H-2d were generated by immunizing the corresponding allogeneic hosts with the thymoma. However, the addition of lymphokines rendered thymoma-primed T cells capable of generating anti-Qa-2 CTL. Both CD4+ and CD8+ T cell populations, isolated from the BALB/cJ splenocyte-primed responder cells, proliferated in vitro in response to the Qa-2+ splenocytes, suggesting that Qa-2-reactive CD4+ T cells were present in the immunized mice. Depletion of CD4+ T cells from thymectomized BALB/cBy mice with anti-L3T4 monoclonal antibodies markedly reduced, but did not eliminate anti-Qa-2 CTL generation. In contrast, depletion of CD8+ T cells led to a complete abrogation of the CTL response. Addition of lymphokines to the culture of responder cells depleted of either T cell subset did not restore their reactivity. It is concluded that anti-Qa-2 CTLp need "help" from CD4+ T cells to become primed in vivo. Furthermore, primed CTLp also need "help" or lymphokines provided by CD4+ T cells to differentiate into effector CTL in vitro.(ABSTRACT TRUNCATED AT 400 WORDS)     

The aminopeptidase ERAAP shapes the peptide repertoire displayed by major histocompatibility complex class I molecules

Major histocompatibility complex (MHC) class I molecules present thousands of peptides to allow CD8(+) T cells to detect abnormal intracellular proteins. The antigen-processing pathway for generating peptides begins in the cytoplasm, and the MHC molecules are loaded in the endoplasmic reticulum. However, the nature of peptide pool in the endoplasmic reticulum and the proteolytic events that occur in this compartment are unclear. We addressed these issues by generating mice lacking the endoplasmic reticulum aminopeptidase associated with antigen processing (ERAAP). We found that loss of ERAAP disrupted the generation of naturally processed peptides in the endoplasmic reticulum, decreased the stability of peptide-MHC class I complexes and diminished CD8(+) T cell responses. Thus, trimming of antigenic peptides by ERAAP in the endoplasmic reticulum is essential for the generation of the normal repertoire of processed peptides.     

ERAAP synergizes with MHC class I molecules to make the final cut in the antigenic peptide precursors in the endoplasmic reticulum

The major histocompatibility complex class I molecules display peptides (pMHC I) on the cell surface for immune surveillance by CD8(+) T cells. These peptides are generated by proteolysis of intracellular polypeptides by the proteasome in the cytoplasm and then in the endoplasmic reticulum (ER) by the ER aminopeptidase associated with antigen processing (ERAAP). To define the unknown mechanism of ERAAP function in vivo, we analyzed naturally processed peptides in cells with or without appropriate MHC I and ERAAP. In the absence of MHC I, ERAAP degraded the antigenic precursors in the ER. However, MHC I molecules could bind proteolytic intermediates and were essential for generation of the final peptide by ERAAP. Thus, ERAAP synergizes with MHC I to generate the final pMHC I repertoire.     

Immunodominant, protective response to the parasite Toxoplasma gondii requires antigen processing in the endoplasmic reticulum

The parasite Toxoplasma gondii replicates in a specialized intracellular vacuole and causes disease in many species. Protection from toxoplasmosis is mediated by CD8(+) T cells, but the T. gondii antigens and host genes required for eliciting protective immunity are poorly defined. Here we identified GRA6, a polymorphic protein secreted in the parasitophorous vacuole, as the source of the immunodominant and protective decapeptide HF10 presented by the H-2L(d) major histocompatibility complex class I molecule. Presentation of the HF10-H-2L(d) ligand required proteolysis by ERAAP, the endoplasmic reticulum aminopeptidase associated with antigen processing. Consequently, expansion of protective CD8(+) T cell populations was impaired in T. gondii-infected ERAAP-deficient mice, which were more susceptible to toxoplasmosis. Thus, endoplasmic reticulum proteolysis is critical for eliciting protective immunity to a vacuolar parasite.     

Regulation of activated CD4+ T cells by NK cells via the Qa-1-NKG2A inhibitory pathway

The ability of natural-killer cells to regulate adaptive immunity is not well understood. Here we define an interaction between the class Ib major histocompatibility complex (MHC) molecule Qa-1-Qdm on activated T cells responsible for adaptive immunity and CD94-NKG2A inhibitory receptors expressed by natural-killer cells by using Qa-1-deficient and Qa-1 knockin mice containing a point mutation that selectively abolishes Qa-1-Qdm binding to CD94-NKG2A receptors. The Qa-1-NKG2A interaction protected activated CD4+ T cells from lysis by a subset of NKG2A+ NK cells and was essential for T cell expansion and development of immunologic memory. Antibody-dependent blockade of this Qa-1-NKG2A interaction resulted in potent NK-dependent elimination of activated autoreactive T cells and amelioration of experimental autoimmune encephalomyelitis. These findings extend the functional reach of the NK system to include regulation of adaptive T cell responses and suggest a new clinical strategy for elimination of antigen-activated T cells in the context of autoimmune disease and transplantation.     

Lack of expansion of major histocompatibility complex class Ib-restricted effector cells following recovery from secondary infection with the intracellular pathogen Listeria monocytogenes

Sublethal infection of BALB/c mice with the intracellular bacterial pathogen Listeria monocytogenes leads to the development of antilisterial immunity with concurrent stimulation of major histocompatibility complex (MHC) class Ia- and Ib-restricted CD8+ effector T cells. Secondary L. monocytogenes infection is followed by an accelerated increase in the number of Listeria-specific CD8+ cells and rapid clearance of the bacterium from the murine host. Recovery from secondary infection is associated with increased levels of effector cell function, as measured by gamma interferon secretion following coculture of immune cells with L. monocytogenes infected APCs in vitro, as well as antilisterial cytotoxicity, as measured by effector cell recognition of L. monocytogenes-infected target cells. We assessed the frequency of L. monocytogenes-specific MHC class I-restricted cells following secondary infection by ELISPOT assays utilizing coculture of immune cells with L. monocytogenes-infected antigen-presenting cells that express MHC class Ia and/or Ib molecules. We found that the antilisterial Qa-1b (MHC class Ib)-restricted effector subset is not detected as an expanded population following secondary infection compared to the frequency of this effector population as measured following recovery from primary infection. This is in contrast to the frequency of antilisterial H2-Kd (MHC class Ia)-restricted effector cells, which following recovery from secondary infection are detected as an expanded population, and appears to undergo a substantial expansion event 3 to 4 days post-secondary infection. These results are consistent with the conclusion that although Listeria-specific MHC class Ib-restricted effector cells are present following recovery from secondary infection, this subset does not appear to undergo the expansion phase that is detected for the MHC class Ia-restricted effector cell response.     

H2-M3 major histocompatibility complex class Ib-restricted CD8 T cells induced by Salmonella enterica serovar Typhimurium infection recognize proteins released by Salmonella serovar Typhimurium

Salmonella enterica serovar Typhimurium causes a typhoid-like disease in mice which has been studied extensively as a model for typhoid fever in humans. CD8 T cells contribute to protection against S. enterica serovar Typhimurium in mice, but little is known about the specificity and major histocompatibility complex (MHC) restriction of the response. We report here that CD8 T-cell lines derived from S. enterica serovar Typhimurium-infected BALB/c mice lysed bone marrow macrophages infected with S. enterica serovar Typhimurium or pulsed with proteins from S. enterica serovar Typhimurium culture supernatants. Cytoxicity was beta-2-microglobulin dependent and largely TAP dependent, although not MHC class Ia restricted, as target cells of several different MHC haplotypes were lysed. The data suggested the participation of class Ib MHC molecules although no evidence for the presence of Qa1-restricted T cells could be found, unlike in previous reports. Instead, the T-cell lines lysed H2-M3-transfected fibroblasts infected with S. enterica serovar Typhimurium SL3261 or treated with Salmonella culture supernatants. Thus, this report increases the number of MHC class Ib antigen-presenting molecules known for Salmonella antigens to three: Qa-1, HLA-E, and now H2-M3. It also expands the range of pathogens that induce H2-M3-restricted CD8 T cells to include an example of gram-negative bacteria.     

Qa-1 interaction and T cell recognition of the Qa-1 determinant modifier peptide

The peptide-binding properties of the nonclassical major histocompatibility complex (MHC) class 1b molecule Qa-1 were investigated using a transfected hybrid molecule composed of the α1 and α2 domains of Qa-1^b and the α3 domain of H-2D^b. This allowed the use of a monoclonal antibody directed against H-2D^b whilst retaining the peptide-binding groove of Qa-1^b. By comparison with classical MHC class I molecules, intracellular maturation of the chimeric molecule was inefficient with weak intracellular association with β2-microglobulin. However, at the cell surface the hybrid molecules were stably associated with β2-microglobulin and were recognized by cytotoxic T lymphocyte (CTL) clones specific for the Qa-1^b -presented peptide Qdm (AMAPRTLLL). A whole-cell binding assay was used to determine which residues of Qdm were important for binding to Qa-1^b and CTL clones served to identify residues important for T cell recognition. Substitutions at position 1 and 5 did not reduce the efficiency of binding and had little effect on CTL recognition. In contrast, substitutions at position 9 resulted in loss of MHC class I binding. Mass spectrometric analysis of peptides eluted from immunopurified Qa-1^b/D^b molecules indicated that Qdm was the dominant peptide. The closely related peptide, AMVPRTLLL, which is derived from the signal sequence of H-2D^k, was also present, although it was considerably less abundant. The mass profile suggested the presence of additional peptides the majority of which consisted of eight to ten amino acid residues. Finally, the finding that a peptide derived from Klebsiella pneumoniae can bind raises the possibility that this non-classical MHC class I molecule may play a role in the presentation of peptides of microorganisms.     

Qa-1/Tla region alloantigen-specific CTL with alpha beta receptor

Recent studies involving T cells that express gamma delta T-cell receptor (gamma delta TcR) have raised the possibility that Qa-1/Tla region class I major histocompatibility complex (MHC)-like molecules are antigen-presenting molecules for gamma delta TcR. In this report, cytotoxic T lymphocyte (CTL) clones specific for a Qa-1/Tla region gene product were isolated from a bulk B10. QBR (Kb, Ib, Dq Qa-1/Tlab) anti-B10.MBR (Kb, Ik, Dq, Qa/Tlaa) CTL line. These CTL lysed blasts from all Qa-1a strains regardless of the H-2 haplotype, indicating that the recognition of the Qa-1 antigen by these CTL is not restricted by other class I molecules. In bulk populations, CTL activity of this specificity was found only in the CD8+CD4- subpopulation. Accordingly, all established CTL clones were phenotyped as Thy-1+, CD8+CD4-. Furthermore, these clones were shown to express alpha beta TcR rather than gamma delta TcR. Thus, the results indicate that Qa-1 antigen can be recognized by alpha beta TcR T cells in a manner similar to recognition of classical class I molecules.     

Qa-1, a nonclassical class I histocompatibility molecule with roles in innate and adaptive immunity

Qa-1, a nonclassical class I histocompatibility molecule expressed in mice, predominantly assembles with a single nonameric peptide, Qdm, derived from the signal sequence of certain class Ia molecules. The Qa-1/Qdm complex is the primary ligand for CD94/NKG2A inhibitory receptors expressed on a major fraction of natural killer (NK) cells. Cells become susceptible to killing by NK cells under conditions where surface expression of the Qa-1/Qdm inhibitory ligand is reduced. The CD94/NKG2 "missing-self" recognition system serves as mechanism for removing cells that have abnormalities in the intracellular machinery required for assembly and expression of class I-peptides complexes, as a consequence of viral infection, for example. Despite its highly focused peptide-binding specificity, Qa-1 also has a capacity to act as an antigen-presentation molecule for CD8+ T cells. It appears that a small subpopulation of these T cells undergoes positive selection by interaction with Qa-1 in the thymus, and they maintain their specificity for Qa-1 after maturation. The role of these unusual T cells in adaptive immune responses remains to be defined.     

Coping with loss of perfection in the MHC class I peptide repertoire

The MHC class I molecules present thousands of peptides (pMHC I) on the cell surface for immune surveillance by CD8 T cells. The pMHC I repertoire normally contains peptides of perfect length and sequences suitable for binding each MHC I. The peptides are made by first fragmenting cytoplasmic proteins. The fragments are then transported into the endoplasmic reticulum (ER), where they are trimmed to appropriate length by the ER aminopeptidase associated with antigen processing (ERAAP) to generate the final pMHC I. Here, we review studies on the role of ERAAP in generating pMHC I from endogenous or viral proteins and their ability to elicit CD8 T cell responses. The absence of ERAAP profoundly disrupts the pMHC I repertoire which can have major consequences on the immune responses to endogenous and viral antigens.     

The human major histocompatibility complex class Ib molecule HLA-E binds signal sequence-derived peptides with primary anchor residues at positions 2 and 9

Human histocompatibility leukocyte antigen E (HLA-E) and mouse major histocompatibility complex (MHC) class Ib antigen, Qa-1, share the same substitutions at two normally conserved positions 143 and 147, which are likely to affect binding of the C terminus of peptides. Qa-1 is able to bind a peptide derived from the leader sequence of H-2 D and H-2 L molecules. We developed a peptide binding assay in vitro to compare the binding specificity of HLA-E with the mouse MHC class Ib molecule Qa-1. We demonstrate that HLA-E binds, although poorly, the peptide which binds to Qa-1 and that it also binds nonamer signal sequence-derived peptides from human MHC class I molecules. Using alanine and glycine substitutions, we could define primary anchor residues at positions 2 and 9 and secondary anchor residues at position 7 and possibly 3.     

Major histocompatibility complex (MHC) control of CD4 T cell subset activation. II. A single peptide induces either humoral or cell-mediated responses in mice of distinct MHC genotype.

CD4 T cells activated in vivo in response to human collagen type IV (hCol IV) resemble either T helper type 1 (Th1) or Th2 cells depending on the major histocompatibility complex (MHC) class II genotype of the responding mice. H-2s mice were shown to selectively activate Th1-like cells, releasing interleukin (IL 2 and interferon-gamma in response to hCol IV, whereas H-2b.d mice were shown to selectively activate Th2-like cells, releasing IL 4 and IL 5 in response to hCol IV. These results suggested that MHC class II regulated the type of effector function observed during an immune response. It was of interest to determine if the functional difference observed between the CD4 T cells of the two strains was due to the presentation of different peptides of the hCol IV molecule by the two MHC class II molecules. The present results demonstrate that a single peptide of the collagen IV molecule will elicit a Th1-like response in H-2s strains and Th2-like responses in H-2b.d strains, as was observed when using the intact hCol IV molecule. Furthermore, the failure to generate Th1-like responses in H-2b.d could be overcome by increasing the dose of this peptide in vitro. Compared to H-2s, the Th1-like response in H-2b required 100 times the amount of peptide to reelicit an equivalent response. These data suggest that a single peptide of hCol IV can control the type of effector response observed.     

Definition of a novel binding site on CD8 cells for a conserved region of the MHC class Ib molecule Qa-1 that regulates IFN-gamma expression

Natural killer (NK) cells and activated CD8 cells both express cytotoxic activity and produce substantial levels of IFN-gamma in response to viral and bacterial infections. In the case of NK cells, cellular activation and IFN-gamma expression are regulated by an interaction between NK receptors and MHC class Ib molecules, including HLA-E/Qa-1. We have used soluble tetrameric complexes of the murine class Ib molecule Qa-1 to define the significance of this interaction for CD8 cells. We find that all CD8 cells express a receptor for Qa-1 and that ligation of this receptor by Qa-1 results in up-regulation of IFN-gamma production.