Isoforms of the nonclassical class I MHC antigen H2-Q5 are enriched in brain and encode Qdm peptide

Although the human nonclassical class Ib major histocompatibility complex (Mhc) locus, HLA-G, is known to act as an immune suppressor in immune-privileged sites, little is currently known regarding participation of the rodent class Ib Mhc in similar pathways. Here, we investigated the expression properties of the mouse nonclassical Mhc H2-Q5(k) gene, previously detected in tumors and tissues associated with pregnancy. We find that H2-Q5(k) is alternatively spliced into multiple novel isoforms in a wide panel of C3H tissues. Unlike other known class I MHC, it is most highly transcribed in the brain, where the classical class Ia Mhc products are scarce. The truncated isoforms are selectively enriched in sites of immune privilege and are translated into cell surface proteins in neural crest-derived transfected cells. Furthermore, we present data supporting a model whereby Q5(k) isoforms serve an immune-protective role by donating their Qdm leader peptide to Qa-1, in a pathway homologous to the HLA-G leader fragment binding HLA-E and inhibiting CD94/NKG2A-positive cytotoxic cells. In addition, we report a previously unknown homolog of H2-Q5(k) in the C57BL/6 mouse, which encodes Qdm, but is transcribed solely into noncanonical isoforms. Collectively, these studies demonstrate that H2-Q5(k), and its homologous class I-like H2(b) gene may play tissue-specific roles in regulating immune surveillance.

An MHC class Ib-restricted CD8 T cell response confers antiviral immunity

Although immunity against intracellular pathogens is primarily provided by CD8 T lymphocytes that recognize pathogen-derived peptides presented by major histocompatibility complex (MHC) class Ia molecules, MHC class Ib–restricted CD8 T cells have been implicated in antiviral immunity. Using mouse polyoma virus (PyV), we found that MHC class Ia–deficient (K^b−/−D^b−/−) mice efficiently control this persistently infecting mouse pathogen. CD8 T cell depletion mitigates clearance of PyV in K^b−/−D^b−/− mice. We identified the ligand for PyV-specific CD8 T cells in K^b−/−D^b−/− mice as a nonamer peptide from the VP2 capsid protein presented by Q9, a member of the β₂ microglobulin–associated Qa-2 family. Using Q9-VP2 tetramers, we monitored delayed but progressive expansion of these antigen-specific CD8αβ T cells in K^b−/−D^b−/− mice. Importantly, we demonstrate that Q9-VP2–specific CD8 T cells more effectively clear wild-type PyV than a VP2 epitope^null mutant PyV. Finally, we show that wild-type mice also generate Q9-restricted VP2 epitope–specific CD8 T cells to PyV infection. To our knowledge, this is the first evidence for a defined MHC class Ib–restricted antiviral CD8 T cell response that contributes to host defense. This study motivates efforts to uncover MHC class Ib–restricted CD8 T cell responses in other viral infections, and given the limited polymorphism of MHC class Ib molecules, it raises the possibility of developing peptide-based viral vaccines having broad coverage across MHC haplotypes.

The role of structurally conserved class I MHC in tumor rejection: contribution of the Q8 locus

The mouse multimember family of Qa-2 oligomorphic class I MHC genes is continuously undergoing duplications and deletions that alter the number of the two "prototype" Qa-2 sequences, Q8 and Q9. The frequent recombination events within the Q region lead to strain-specific modulation of the cumulative Qa-2 expression levels. Q9 protects C57BL/6 hosts from multiple disparate tumors and functions as a major CTL restriction element for shared tumor-associated Ags. We have now analyzed functional and structural properties of Q8, a class I MHC that differs significantly from Q9 in the peptide-binding, CTL-interacting alpha(1) and alpha(2) regions. Unexpectedly, we find that the extracellular domains of Q8 and Q9 act similarly during primary and secondary rejection of tumors, are recognized by cross-reactive antitumor CTL, have overlapping peptide-binding motifs, and are both assembled via the transporter associated with the Ag processing pathway. These findings suggest that shared Ag-presenting functions of the "odd" and "even" Qa-2 loci may contribute to the selective pressures shaping the haplotype-dependent quantitative variation of Qa-2 protein expression.

The murine family of gut-restricted class Ib MHC includes alternatively spliced isoforms of the proposed HLA-G homolog, "blastocyst MHC"

The gastrointestinal tract is populated by a multitude of specialized immune cells endowed with receptors for classical (class Ia) and nonclassical (class Ib) MHC proteins. To identify class I products that engage these receptors and impact immunity/tolerance, we studied gut-transcribed class Ib loci and their polymorphism in inbred, outbred, and wild-derived mice. Intestinal tissues enriched in epithelial cells contained abundant transcripts of ubiquitously expressed and preferentially gut-restricted Q and T class I loci. The latter category included the "blastocyst Mhc" gene, H2-Bl, and its putative paralog, Tw5. Expression of H2-Bl was previously detected only at the maternal/fetal interface, where it was proposed to induce immune tolerance via interactions with CD94/NKG2A receptors. Analysis of coding region polymorphism performed here revealed two major alleles of H2-Bl with conserved residues at positions critical for class I protein folding and peptide binding. Both divergent alleles are maintained in outbred and wild mice under selection for fecundity and pathogen resistance. Surprisingly, we found that alternative splicing of H2-Bl mRNA in gut tissues is prevalent and allele-specific. It leads to strain-dependent expression of diverse repertoires of canonical and noncanonical transcripts that may give rise to distinct ligands for intestinal NK cell, T cell, and/or intraepithelial lymphocyte receptors.

Hepatocytes express abundant surface class I MHC and efficiently use transporter associated with antigen processing, tapasin, and low molecular weight polypeptide proteasome subunit components of antigen processing and presentation pathway

Hepatic expression levels of class I MHC Ags are generally regarded as very low. Because the status of these Ags and their ability to present peptides are important for the understanding of pathogen clearance and tolerogenic properties of the liver, we set out to identify the factors contributing to the reported phenotype. Unexpectedly, we found that the surface densities of K(b) and D(b) on C57BL/6 mouse hepatocytes are nearly as high as on splenocytes, as are the lysate concentrations of mRNA encoding H chain and beta(2)-microglobulin (beta(2)m). In contrast, the components of the peptide-loading pathway are reduced in hepatocytes. Despite the difference in the stoichiometric ratios of H chain/beta(2)m/peptide-loading machineries, both cell types express predominantly thermostable class I and are critically dependent on TAP and tapasin for display of surface Ags. Minor differences in the expression patterns in tapasin(-/-) background suggest cell specificity in class I assembly. Under immunostimulatory conditions, such as exposure to IFN-gamma or Listeria monocytogenes, hepatocytes respond with a vigorous mRNA synthesis of the components of the Ag presentation pathway (up to 10-fold enhancement) but up-regulate H chain and beta(2)m to a lesser degree (<2-fold). This type of response should promote rapid influx of newly generated peptides into the endoplasmic reticulum and preferential presentation of foreign/induced Ag by hepatic class I.

Protective immunity against disparate tumors is mediated by a nonpolymorphic MHC class I molecule

Current peptide-based immunotherapies for treatment of model cancers target tumor Ags bound by the classical MHC class I (class Ia) molecules. The extensive polymorphism of class Ia loci greatly limits the effectiveness of these approaches. We demonstrate in this study that the murine nonpolymorphic, nonclassical MHC class I (class Ib) molecule Q9 (Qa-2) promotes potent immune responses against multiple syngeneic tumors. We have previously shown that ectopic expression of Q9 on the surface of class Ia-negative B78H1 melanoma led to efficient CTL-mediated rejection of this tumor. In this study, we report that surface-expressed Q9 on 3LLA9F1 Lewis lung carcinoma and RMA T cell lymphoma also induces potent antitumor CTL responses. Importantly, CTL harvested from animals surviving the initial challenge with Q9-positive 3LLA9F1, RMA, or B78H1 tumors recognized and killed their cognate tumors as well as the other cancer lines. Furthermore, immunization with Q9-expressing 3LLA9F1 or RMA tumor cells established immunological memory that enhanced protection against subsequent challenge with a weakly immunogenic, Q9-bearing melanoma variant. Collectively, the generation of cross-reactive CTL capable of eliminating multiple disparate Q9-expressing tumors suggests that this nonpolymorphic MHC class I molecule serves as a restriction element for a shared tumor Ag(s) common to lung carcinoma, T cell lymphoma, and melanoma.

A Nonclassical MHC Class I Molecule Restricts CTL-Mediated Rejection of a Syngeneic Melanoma Tumor

Although CTL and polymorphic, classical MHC class I molecules have well defined roles in the immune response against tumors, little is currently known regarding the participation of nonpolymorphic, nonclassical MHC class I in antitumor immunity. Using an MHC class I-deficient melanoma as a model tumor, we demonstrate that Q9, a murine MHC class Ib molecule from the Qa-2 family, expressed on the surface of tumor cells, protects syngeneic hosts from melanoma outgrowth. Q9-mediated protective immunity is lost or greatly diminished in mice deficient in CTL, including beta(2)-microglobulin knockout (KO), CD8 KO, and SCID mice. In contrast, the Q9 antitumor effects are not detectably suppressed in CD4 KO mice with decreased Th cell activity. Killing by antitumor CTL in vitro is Q9 specific and can be blocked by anti-Q9 and anti-CD8 Abs. The adaptive Q9-restricted CTL response leads to immunological memory, because mice that resist the initial tumor challenge reject subsequent challenges with less immunogenic tumor variants and show expansion of CD8(+) T cell populations with an activated/memory CD44(high) phenotype. Collectively, these studies demonstrate that a MHC class Ib molecule can serve as a restriction element for antitumor CTL and mediate protective immune responses in a syngeneic setting.

Two-signal requirement for activation and effector function of natural killer cell response to allogeneic tumor cells

Optimal activation of T cells requires delivery of both antigenic and costimulatory signals. It is unclear, however, if the function of the natural killer (NK) cells is also modulated by these 2 signals. Here we report that efficient control of solid allogeneic tumors by NK cells depends on codelivery of both B7-1 and major histocompatibility complex (MHC) class I on the tumor cells. The codelivery is required for optimal expansion and effector function of NK cells in response to both melanoma and plasmocytoma that expressed allogeneic MHC class I. Our results demonstrate that the 2 signals required for T-cell function also can regulate NK immunity and reveal an important similarity between the innate NK response and the adaptive T-cell response.

Correction of defects responsible for impaired Qa-2 class Ib MHC expression on melanoma cells protects mice from tumor growth

One of the principal mechanisms of tumor immune evasion is alteration of class I MHC expression. We have identified defects contributing to down-regulation of class I MHC expression in the widely studied murine B16 melanoma and its variants B16F1, B16F10, BL6-2, BL6-8 and B78H1. Transcription of the nonclassical class I MHC genes Q8 and Q9 (Qa-2 Ags) has been switched off in the entire panel of melanoma lines, suggesting that this event occurred early during tumor progression. B78H1, unlike B16F1 and B16F10 sublines, is also selectively devoid of TAP2 and low molecular weight protein 7 as well as classical class I MHC K(b) and D(b) transcripts. Cotransfection of B78H1 with TAP2 and class I H chain genes is sufficient to reconstitute surface expression of exogenously delivered class I MHC without concomitant re-expression of endogenous beta(2)-microglobulin-associated class I. The serological absence of endogenous class Ia and Ib at the surface of TAP2-negative as well as TAP2-transfected B78H1 makes this system a suitable model for studying the properties of isolated class I proteins in tumors. We used this system to demonstrate that B78H1 cells genetically manipulated to re-express Q9 Ag have reduced tumor potential in syngeneic B6 mice compared with TAP2-transfected parental melanoma. Both NK cells and CTLs appear to collaborate in restraining growth of Q9-positive tumors. The results implicate Qa-2 in antitumor responses and illustrate the utility of the B78H1 system for identifying in vivo interactions between class I MHC molecules of interest and immune cells of innate and/or adaptive immunity.

The nonclassical major histocompatibility complex molecule Qa-2 protects tumor cells from NK cell- and lymphokine-activated killer cell-mediated cytolysis

The cytotoxic activity of NK cells is regulated by class I MHC proteins. Although much has been learned about NK recognition of class I autologous targets, the mechanisms of NK self-tolerance are poorly understood. To examine the role of a nonpolymorphic, ubiquitously expressed class Ib Ag, Q9, we expressed it on class I-deficient and NK-sensitive B78H1 melanoma. Presence of this Qa-2 family member on tumor cells partially protected targets from lysis by bulk lymphokine-activated killer (LAK) cells. H-2K(b)-expressing B78H1 targets also reduced LAK cell activity, while H-2D(b) offered no protection. Importantly, blocking with F(ab')(2) specific for Q9 or removal of this GPI-attached molecule by phospholipase C cleavage restored killing to the level of vector-transfected cells. Experiments with LAK cells derived from H2(b) SCID and B6 mice established that NK1.1(+)TCR(-) NK and NK1.1(+)TCR(+) LAK cells were the prevalent cytolytic populations inhibitable by Q9. Treatment of mice with poly(I:C) also resulted in generation of Q9-regulated splenic cytotoxicity. LAK cells from different mouse strains responded to Q9, suggesting that the protective effect of this molecule is not detectably influenced by Ly49 polymorphisms or the presence/absence of Q9 in NK-harboring hosts. We propose that Q9 expressed on melanoma cells serves as a ligand for yet unidentified NK inhibitory receptor(s) expressed on NK1.1(+) NK/T cells.

Promiscuous antigen presentation by the nonclassical MHC Ib Qa-2 is enabled by a shallow, hydrophobic groove and self-stabilized peptide conformation

BACKGROUND

Qa-2 is a nonclassical MHC Ib antigen, which has been implicated in both innate and adaptive immune responses, as well as embryonic development. Qa-2 has an unusual peptide binding specificity in that it requires two dominant C-terminal anchor residues and is capable of associating with a substantially more diverse array of peptide sequences than other nonclassical MHC.

RESULTS

We have determined the crystal structure, to 2.3 A, of the Q9 gene of murine Qa-2 complexed with a self-peptide derived from the L19 ribosomal protein, which is abundant in the pool of peptides eluted from the Q9 groove. The 9 amino acid peptide is bound high in a shallow, hydrophobic binding groove of Q9, which is missing a C pocket. The peptide makes few specific contacts and exhibits extremely poor shape complementarity to the MHC groove, which facilitates the presentation of a degenerate array of sequences. The L19 peptide is in a centrally bulged conformation that is stabilized by intramolecular interactions from the invariant P7 histidine anchor residue and by a hydrophobic core of preferred secondary anchor residues that have minimal interaction with the MHC.

CONCLUSIONS

Unexpectedly, the preferred secondary peptide residues that exhibit tenuous contact with Q9 contribute significantly to the overall stability of the peptide-MHC complex. The structure of this complex implies a "conformational" selection by Q9 for peptide residues that optimally stabilize the large bulge rather than making intimate contact with the MHC pockets.

Widespread expression of the nonclassical class I Qa-2 antigens in hemopoietic and nonhemopoietic cells

We reexamined expression patterns of one of the best characterized mouse class Ib MHC molecules, Qa-2. Transcripts encoding glycosylphosphatidylinositol-linked and soluble forms of Qa-2 are expressed in all organs except brain. The membrane-bound Qa-2 proteins are detectable, to varying degrees, in many cell types of immunological interest: on professional antigen-presenting cells capable of inducing anti-Qa-2 allogeneic responses, on thymic epithelial cells essential for T-cell positive selection, on mature as well as immature thymocytes, in immunologically privileged sites (testis/spermatazoa), and on cells implicated in mucosal immunity (lymphoid-derived and epithelial gut cells and hepatocytes). Although Qa-2 has a nearly ubiquitous tissue distribution similar to H2-Kb and Db molecules, the relative levels of Qa-2 and class Ia displayed on cell surfaces vary in a cell-specific fashion. Analyses of primary cell lines derived from normal mouse tissues also support the conclusion that Qa-2 is present in all cells that can express class Ia antigens. In contrast, tumor lines from Qa-2-positive mice are frequently Qa-2 deficient, suggesting that the Qa-2-negative phenotype of malignant cells is selected in vivo.

Qa-2-dependent selection of CD8alpha/alpha T cell receptor alpha/beta(+) cells in murine intestinal intraepithelial lymphocytes

Murine intestinal intraepithelial lymphocytes (iIELs) are made up of a heterogeneous mix of T cells with unique phenotypes. Whereas CD8(+) T cells in peripheral lymphoid organs use CD8alpha/beta and are selected on MHC class Ia molecules, a majority of iIELs use CD8alpha/alpha. Here, we report that the presence of CD8alpha/alpha TCR-alpha/beta cells in iIELs is independent of classical MHC class I molecules K(b) and D(b), as illustrated by their presence in K(b)/D(b) double-knockout mice and in mice lacking a nonclassical MHC class I molecule, CD1d. Most strikingly, their presence is decreased by approximately 70% in mice lacking transporter associated with antigen processing (TAP). The TAP-dependent nonclassical MHC class I molecule Qa-2 is strongly implicated in the presence of these cells, as inferred from the low numbers of CD8alpha/alpha TCR-alpha/beta T cells in mice deficient in Qa-2 genes. Second, a Qa-2-transgenic mouse made in a Qa-2(-) strain showed an increase in the numbers of CD8alpha/alpha cells among its iIELs. Thus, the presence of CD8alpha/alpha TCR-alpha/beta cells in iIELs is mainly dependent on the nonclassical MHC class I molecule Qa-2.

The murine liver-specific nonclassical MHC class I molecule Q10 binds a classical peptide repertoire

The biological properties of the nonclassical class I MHC molecules secreted into blood and tissue fluids are not currently understood. To address this issue, we studied the murine Q10 molecule, one of the most abundant, soluble class Ib molecules. Mass spectrometry analyses of hybrid Q10 polypeptides revealed that alpha1alpha2 domains of Q10 associate with 8-9 long peptides similar to the classical class I MHC ligands. Several of the sequenced peptides matched intracellularly synthesized murine proteins. This finding and the observation that the Q10 hybrid assembly is TAP2-dependent supports the notion that Q10 groove is loaded by the classical class I Ag presentation pathway. Peptides eluted from Q10 displayed a binding motif typical of H-2K, D, and L ligands. They carried conserved residues at P2 (Gly), P6 (Leu), and Pomega (Phe/Leu). The role of these residues as anchors/auxiliary anchors was confirmed by Ala substitution experiments. The Q10 peptide repertoire was heterogeneous, with 75% of the groove occupied by a multitude of diverse peptides; however, 25% of the molecules bound a single peptide identical to a region of a TCR V beta-chain. Since this peptide did not display enhanced binding affinity for Q10 nor does its origin and sequence suggest that it is functionally significant, we propose that the nonclassical class I groove of Q10 resembles H-2K, D, and L grooves more than the highly specialized clefts of nonclassical class I Ags such as Qa-1, HLA-E, and M3.

Expression of a nonclassical MHC class Ib molecule in the eye

BACKGROUND

MHC class Ia molecules are absent, or expressed at low levels, on cells lining the anterior chamber of the eye, an immune-privileged site. Although the scarcity of class Ia MHC antigens may protect cells from T cell-mediated tissue injury, it may also render them vulnerable to natural killer cell-mediated cytolysis. There is growing evidence that MHC class Ib molecules share similar functions to class Ia. In this study, we examine the expression and distribution of Qa-2, one of the best-characterized murine MHC class Ib molecules in the eye.

METHODS

The transcription of Qa-2 mRNA in whole eye and eye-derived cells was analyzed by sensitive and specific RNase protection and reverse transcription-polymerase chain reaction assays. Immunohistochemistry, flow cytometry, and ELISA were used to determine whether Qa-2 was expressed as cell surface proteins. Expression levels of Qa-2 were monitored in resting cells and cells stimulated with interferon-gamma.

RESULTS

Expression of membrane-bound and soluble Qa-2 isoforms was detected in various tissues of the eye, including cell subsets lining the anterior chamber. Immunohistological staining revealed Qa-2 expression on corneal epithelium as well as endothelium, iris ciliary bodies, and retina. These observations were confirmed by analysis of cultured, eye-derived cells. Qa-2 expression was inducible by interferon-gamma. Qa-2 was not detected in lens cells.

CONCLUSIONS

The results demonstrate that membrane-bound and soluble MHC class Ib molecules are expressed by eye cells. Expression of Qa-2 in the corneal endothelium and other substructures lining the anterior chamber suggests that this class Ib protein may contribute to the immune-privileged status of the anterior chamber.

Alternative peptide binding motifs of Qa-2 class Ib molecules define rules for binding of self and nonself peptides

Studies of naturally processed peptides eluted from membrane-bound and soluble isoforms of murine class Ib Qa-2 molecules determined several features of these ligands, such as the conserved nonameric length and the preferred usage of specific residues at four to six of nine peptide positions. The structural information derived from these studies proved insufficient to distinguish between two interpretations: 1) that Qa-2 are peptide receptors of higher stringency than ordinary class I molecules, and 2) that Qa-2 molecules, like classical class I Ags, bind diverse arrays of peptides. We have addressed this issue by a systematic analysis of peptide residues involved in the binding of membrane-bound Qa-2 molecule, MQ9b. The optimal binding of synthetic peptides in vitro occurs at neutral pH. Two dominant anchors are required for peptide binding to MQ9b: His at position 7 and a hydrophobic residue, Leu, Ile, or Phe, at position 9. In addition, one or two auxiliary anchors participate in binding. The identity and the position of the auxiliary anchors differ from peptide to peptide, suggesting that the binding motifs defined from pool sequencing are composed of many superimposed alternative motifs present in individual peptides. The number of anchors used by Qa-2 peptides is similar to that found in ligands of classical class I Ags. Consequently, the Qa-2 are predicted to bind large repertoires of self and nonself peptides. In support of this interpretation we demonstrate that MQ9b binds strongly 5 of 17 motif-positive, pathogen-derived synthetic peptides.

Alternative peptide binding motifs of Qa-2 class Ib molecules define rules for binding of self and nonself peptides

Studies of naturally processed peptides eluted from membrane-bound and soluble isoforms of murine class Ib Qa-2 molecules determined several features of these ligands, such as the conserved nonameric length and the preferred usage of specific residues at four to six of nine peptide positions. The structural information derived from these studies proved insufficient to distinguish between two interpretations: 1) that Qa-2 are peptide receptors of higher stringency than ordinary class I molecules, and 2) that Qa-2 molecules, like classical class I Ags, bind diverse arrays of peptides. We have addressed this issue by a systematic analysis of peptide residues involved in the binding of membrane-bound Qa-2 molecule, MQ9b. The optimal binding of synthetic peptides in vitro occurs at neutral pH. Two dominant anchors are required for peptide binding to MQ9b: His at position 7 and a hydrophobic residue, Leu, Ile, or Phe, at position 9. In addition, one or two auxiliary anchors participate in binding. The identity and the position of the auxiliary anchors differ from peptide to peptide, suggesting that the binding motifs defined from pool sequencing are composed of many superimposed alternative motifs present in individual peptides. The number of anchors used by Qa-2 peptides is similar to that found in ligands of classical class I Ags. Consequently, the Qa-2 are predicted to bind large repertoires of self and nonself peptides. In support of this interpretation we demonstrate that MQ9b binds strongly 5 of 17 motif-positive, pathogen-derived synthetic peptides.

TAP associates with a unique class I conformation, whereas calnexin associates with multiple class I forms in mouse and man

To define the rules governing de novo assembly of the trimeric class I complex, we have identified the class I folding/assembly intermediates associated with calnexin or TAP, using both human and mouse cell lines. To better characterize the class I H chain structure associated with TAP, mouse mAb that distinguish open (64-3-7+) vs folded (30-5-7+) Ld heavy (H) chains were used. We report here that open forms of Ld are uniquely and specifically associated with TAP and that the conformational change in the class I H chain coincident with peptide binding induces TAP release. Chimeric Ld/Q10 displayed TAP association, demonstrating that soluble class I molecules can bind TAP. As previously reported, beta 2m was found to be required for H chain association with TAP. Interestingly, beta 2m was associated with TAP in the human class I-negative cell line LCL 721.221, suggesting that beta 2m can bind to TAP before class I H chain. In contrast to TAP, which binds a specific class I conformation, calnexin was detected in association with multiple forms of both mouse and human class I. Most significantly, we show for the first time that beta 2m-assembled forms of human as well as mouse class I molecules interact with calnexin. Based on these findings, we propose a model for the sequential assembly of class I heterotrimers and their respective interactions with TAP and calnexin.

TAP associates with a unique class I conformation, whereas calnexin associates with multiple class I forms in mouse and man

To define the rules governing de novo assembly of the trimeric class I complex, we have identified the class I folding/assembly intermediates associated with calnexin or TAP, using both human and mouse cell lines. To better characterize the class I H chain structure associated with TAP, mouse mAb that distinguish open (64-3-7+) vs folded (30-5-7+) Ld heavy (H) chains were used. We report here that open forms of Ld are uniquely and specifically associated with TAP and that the conformational change in the class I H chain coincident with peptide binding induces TAP release. Chimeric Ld/Q10 displayed TAP association, demonstrating that soluble class I molecules can bind TAP. As previously reported, beta 2m was found to be required for H chain association with TAP. Interestingly, beta 2m was associated with TAP in the human class I-negative cell line LCL 721.221, suggesting that beta 2m can bind to TAP before class I H chain. In contrast to TAP, which binds a specific class I conformation, calnexin was detected in association with multiple forms of both mouse and human class I. Most significantly, we show for the first time that beta 2m-assembled forms of human as well as mouse class I molecules interact with calnexin. Based on these findings, we propose a model for the sequential assembly of class I heterotrimers and their respective interactions with TAP and calnexin.

Aglycosylated and phosphatidylinositol-anchored MHC class I molecules are associated with calnexin. Evidence implicating the class I-connecting peptide segment in calnexin association

The endoplasmic reticulum resident protein calnexin interacts with several glycoproteins including class I MHC molecules. Calnexin is thought to retain free class I heavy chains and/or promote their folding and assembly with beta 2-microglobulin and peptide ligand. Whereas with other glycoproteins, Asn-linked glycans seem to be involved in calnexin association, with class I molecules the transmembrane region has been implicated. To critically define the structures on class I molecules that determine their interaction with calnexin, we have studied carbohydrate-deficient and transmembrane-variant class I molecules. Carbohydrate-deficient class I molecules were found to accumulate intracellularly in an open, non-beta 2-microglobulin-associated conformation. However, open as well as conformed class I molecules showed significant calnexin association whether they were aglycosylated or fully glycosylated. Thus, carbohydrate moieties may be necessary for efficient class I folding, but are not required for calnexin association. Calnexin was also found associated with a soluble class I molecule that has a truncated transmembrane segment, demonstrating that membrane attachment of class I is not required for interaction with calnexin. Finally, two isoforms of the class Ib molecule Q7b were compared. Unexpectedly, the glycosylphosphatidylinositol-anchored Q7b isoform was found associated with calnexin, whereas the soluble Q7b isoform was not calnexin associated. These comparisons of Q7b isoforms implicate the class I-connecting peptide segment and not the transmembrane region as a site of interaction with calnexin.

Aglycosylated and phosphatidylinositol-anchored MHC class I molecules are associated with calnexin. Evidence implicating the class I-connecting peptide segment in calnexin association

The endoplasmic reticulum resident protein calnexin interacts with several glycoproteins including class I MHC molecules. Calnexin is thought to retain free class I heavy chains and/or promote their folding and assembly with beta 2-microglobulin and peptide ligand. Whereas with other glycoproteins, Asn-linked glycans seem to be involved in calnexin association, with class I molecules the transmembrane region has been implicated. To critically define the structures on class I molecules that determine their interaction with calnexin, we have studied carbohydrate-deficient and transmembrane-variant class I molecules. Carbohydrate-deficient class I molecules were found to accumulate intracellularly in an open, non-beta 2-microglobulin-associated conformation. However, open as well as conformed class I molecules showed significant calnexin association whether they were aglycosylated or fully glycosylated. Thus, carbohydrate moieties may be necessary for efficient class I folding, but are not required for calnexin association. Calnexin was also found associated with a soluble class I molecule that has a truncated transmembrane segment, demonstrating that membrane attachment of class I is not required for interaction with calnexin. Finally, two isoforms of the class Ib molecule Q7b were compared. Unexpectedly, the glycosylphosphatidylinositol-anchored Q7b isoform was found associated with calnexin, whereas the soluble Q7b isoform was not calnexin associated. These comparisons of Q7b isoforms implicate the class I-connecting peptide segment and not the transmembrane region as a site of interaction with calnexin.

Novel molecules related to MHC antigens

Several types of molecules related to classical class I and II antigens of the MHC have been recently discovered. At the same time we have learnt more about the functions of non-classical (class Ib) antigens. This has shed light on the possible evolutionary origins and the likely roles that these molecules may play in the immune response.

Expression of secreted and glycosylphosphatidylinositol-bound Qa-2 molecules is dependent on functional TAP-2 peptide transporter

The assembly of class Ia MHC Ags is thought to occur in the endoplasmic reticulum (ER) where H chains, beta 2m, and peptides come together to form trimers. Several types of proteins are implicated in the regulation of class Ia MHC assembly, including: 1) TAP1/TAP2 transporters, which translocate peptides derived from naturally processed endogenous proteins from the cytosol into the ER and which are necessary for expression of "peptide-filled" class Ia Ags, and 2) calnexin, a chaperone protein, which was proposed to retain unassembled class Ia chains in the ER. In our study, we examined if the expression of class Ib Qa-2 molecules depends on the TAP1/TAP2 peptide delivery system. The glycosylphosphatidylinositol-linked GPIQa-2 and soluble SQa-2 molecules lack transmembrane regions and consensus calnexin binding sites. Because of these structural features, they were thought to differ from class Ia Ags in cellular trafficking pathways and peptide-binding mechanisms. We find that in TAP2 negative RMA-S cells, the great majority of GPIQa-2 and SQa-2 behave as "empty" heterodimers: They cannot maintain stable conformations at 37 degrees C, but their half-lives can be significantly extended by reducing the temperature to 26 degrees C. These results suggest that the Qa-2 binding peptides are delivered to Qa-2 molecules in a manner similar to the class Ia MHC Ag system and, therefore, that both GPIQa-2 and SQa-2 may be assembled in the ER. Detection of a small population of heat-resistant Qa-2 molecules in RMA-S is indicative of an alternative, but minor, peptide delivery pathway, or "leakiness" of the RMA-S mutation.

Expression of secreted and glycosylphosphatidylinositol-bound Qa-2 molecules is dependent on functional TAP-2 peptide transporter

The assembly of class Ia MHC Ags is thought to occur in the endoplasmic reticulum (ER) where H chains, beta 2m, and peptides come together to form trimers. Several types of proteins are implicated in the regulation of class Ia MHC assembly, including: 1) TAP1/TAP2 transporters, which translocate peptides derived from naturally processed endogenous proteins from the cytosol into the ER and which are necessary for expression of "peptide-filled" class Ia Ags, and 2) calnexin, a chaperone protein, which was proposed to retain unassembled class Ia chains in the ER. In our study, we examined if the expression of class Ib Qa-2 molecules depends on the TAP1/TAP2 peptide delivery system. The glycosylphosphatidylinositol-linked GPIQa-2 and soluble SQa-2 molecules lack transmembrane regions and consensus calnexin binding sites. Because of these structural features, they were thought to differ from class Ia Ags in cellular trafficking pathways and peptide-binding mechanisms. We find that in TAP2 negative RMA-S cells, the great majority of GPIQa-2 and SQa-2 behave as "empty" heterodimers: They cannot maintain stable conformations at 37 degrees C, but their half-lives can be significantly extended by reducing the temperature to 26 degrees C. These results suggest that the Qa-2 binding peptides are delivered to Qa-2 molecules in a manner similar to the class Ia MHC Ag system and, therefore, that both GPIQa-2 and SQa-2 may be assembled in the ER. Detection of a small population of heat-resistant Qa-2 molecules in RMA-S is indicative of an alternative, but minor, peptide delivery pathway, or "leakiness" of the RMA-S mutation.

Alternative splicing of class Ib major histocompatibility complex transcripts in vivo leads to the expression of soluble Qa-2 molecules in murine blood

Class Ib Qa-2 molecules are expressed in tissue culture cells as approximately 40-kDa membrane-bound, glycophosphatidylinositol-linked antigens and as approximately 39-kDa soluble polypeptides. Recently, alternative splicing events which delete exon 5 from a portion of Qa-2 transcripts were demonstrated to give rise to truncated secreted Qa-2 molecules in transfected cell lines. To determine whether this mechanism operates in vivo and to find out whether Qa-2 can be detected in soluble form in circulation, murine blood samples were analyzed. Critical to these experiments was preparation of an anti-peptide antiserum against an epitope encoded by a junction of exon 4 and exon 6. We find that supernatants of splenocytes cultured in vitro as well as serum or plasma contain two forms of soluble Qa-2 molecules. One form corresponds to a secreted molecule translated from transcripts from which exon 5 has been deleted; the other is derived from membrane-bound antigens or their precursors. The levels of both soluble forms of Qa-2 are inducible upon stimulation of the immune system, suggesting an immunoregulatory role for these molecules or for the mechanism leading to the reduction of cell-associated Qa-2 antigens in vivo.

A nonpolymorphic major histocompatibility complex class Ib molecule binds a large array of diverse self-peptides

Unlike the highly polymorphic major histocompatibility complex (MHC) class Ia molecules, which present a wide variety of peptides to T cells, it is generally assumed that the nonpolymorphic MHC class Ib molecules may have evolved to function as highly specialized receptors for the presentation of structurally unique peptides. However, a thorough biochemical analysis of one class Ib molecule, the soluble isoform of Qa-2 antigen (H-2SQ7b), has revealed that it binds a diverse array of structurally similar peptides derived from intracellular proteins in much the same manner as the classical antigen-presenting molecules. Specifically, we find that SQ7b molecules are heterodimers of heavy and light chains complexed with nonameric peptides in a 1:1:1 ratio. These peptides contain a conserved hydrophobic residue at the COOH terminus and a combination of one or more conserved residue(s) at P7 (histidine), P2 (glutamine/leucine), and/or P3 (leucine/asparagine) as anchors for binding SQ7b. 2 of 18 sequenced peptides matched cytosolic proteins (cofilin and L19 ribosomal protein), suggesting an intracellular source of the SQ7b ligands. Minimal estimates of the peptide repertoire revealed that at least 200 different naturally processed self-peptides can bind SQ7b molecules. Since Qa-2 molecules associate with a diverse array of peptides, we suggest that they function as effective presenting molecules of endogenously synthesized proteins like the class Ia molecules.

Antigen presentation by non-classical class I molecules

Non-classical class I genes are no longer clearly distinguished from classical ones in mammals, and they are found also in fishes, frogs and chickens. They contribute to immune responses against pathogens. Given the number and diversity of class Ib products, their various tissue distribution patterns, and the wide range of peptides they bind, new functions are to be expected.

The alpha 3 domain of the Qa-2 molecule is defective for CD8 binding and cytotoxic T lymphocyte activation

Qa-2 is a nonclassical class I molecule encoded by the Q7 gene within the mouse major histocompatibility complex (MHC). Results from previous experiments on Qa-2, and on a chimeric Ld molecule (LQ3) in which the alpha 3 domain is encoded by Q7b, suggested that the alpha 3 domain of Qa-2 does not carry out the functions typical of the alpha 3 domains in other classical and nonclassical class I antigens. Class I molecules that contain the Qa-2 alpha 3 domain are poorly recognized by primary cytotoxic T lymphocytes (CTLs), and do not function normally in either positive or negative selection in vivo. By employing a cell-cell adhesion assay we demonstrate directly that the Qa-2 alpha 3 domain in the context of the LQ3 hybrid molecule cannot bind to human CD8, although other mouse class I alpha 3 domains bind efficiently. In addition, CD8-dependent CTL-mediated lysis of target cells, in a system which requires mouse CD8-class I alpha 3 domain interactions, is deficient in cells that express the Qa-2 alpha 3 domain. When combined with our earlier work on LQ3 transgenic mice, these results provide additional molecular support for the hypothesis that interaction with CD8 is required for both positive and negative selection of class I restricted T cells in the thymus. As the Qa-2 alpha 3 domain sequence does not differ from the previously defined minimal CD8 binding sequence of other class I molecules, these results also suggest that additional amino acids in the alpha 3 domain must be critical for CD8 binding and CTL activation.

Negative and positive selection of antigen-specific cytotoxic T lymphocytes affected by the alpha 3 domain of MHC I molecules

The alpha 1 and alpha 2 domains of major histocompatibility complex (MHC) class I molecules function in the binding and presentation of foreign peptides to the T-cell antigen receptor and control both negative and positive selection of the T-cell repertoire. Although the alpha 3 domain of class I is not involved in peptide binding, it does interact with the T-cell accessory molecule, CD8. CD8 is important in the selection of T cells as anti-CD8 antibody injected into perinatal mice interferes with this process. We previously used a hybrid class I molecule with the alpha 1/alpha 2 domains from Ld and the alpha 3 domain from Q7b and showed that this molecule binds an Ld-restricted peptide but does not interact with CD8-dependent cytotoxic T lymphocytes. Expression of this molecule in transgenic mice fails to negatively select a subpopulation of anti-Ld cytotoxic T lymphocytes. In addition, positive selection of virus-specific Ld-restricted cytotoxic T lymphocytes does not occur. We conclude that besides the alpha 1/alpha 2 domains of class I, the alpha 3 domain plays an important part in both positive and negative selection of antigen-specific cells.

The Q7 alpha 3 domain alters T cell recognition of class I antigens

In this study we have analyzed the role of the alpha 3 domain of class I molecules in T cell recognition. Using the laboratory engineered molecules LLQQ (alpha 1/alpha 2 from Ld, alpha 3, and phosphatidyl inositol (PI) linked C terminus from Q7) and LLQL (alpha 1/alpha 2 from Ld, alpha 3 from Q7, transmembrane (TM) and cytoplasmic domains from Ld) we show that these molecules are not recognized by primary Ld-specific CTL. The cell membrane expression of both Ld and LLQL are upregulated by co-culture with an exogenously supplied murine cytomegalovirus-derived peptide indicating that the Q7 alpha 3 domain does not interfere with binding of Ag to alpha 1/alpha 2. However, only peptide pulsed Ld but not LLQL target cells are recognized by Ld-restricted-peptide specific CTL. In contrast to the above results, LLQL and LLQQ molecules can be recognized by bulk alloreactive anti-Ld CTL and 2/3 of CTL clones derived from in vivo primed mice. The fact that these secondary CTL recognize LLQQ indicates that a PI linkage is permissive for presentation of class I epitopes to alloreactive CTL. These secondary CTL are resistant to blocking at the effector stage by mAb against CD8 and express relatively low levels of membrane CD8 molecules compared to CTL from unprimed mice. Further, culture of unprimed CTL precursors in the presence of CD8 mAb also allows for the generation of CD8-independent CTL that recognize LLQL. Taken together, these data indicate that the alpha 3 domain of Q7 (Qa-2) prevents CD8-dependent CTL from recognizing Ld, regardless of whether the class I molecule is attached to the cell surface by a PI moiety or as a membrane spanning protein domain. We hypothesize that this defect in recognition is most likely due to an inability of CD8 to interact efficiently with the Q7 alpha 3 domain and could account for why Q7 molecules do not serve as restricting elements for virus and minor H-Ag-specific CTL.

The Q7 alpha 3 domain alters T cell recognition of class I antigens

In this study we have analyzed the role of the alpha 3 domain of class I molecules in T cell recognition. Using the laboratory engineered molecules LLQQ (alpha 1/alpha 2 from Ld, alpha 3, and phosphatidyl inositol (PI) linked C terminus from Q7) and LLQL (alpha 1/alpha 2 from Ld, alpha 3 from Q7, transmembrane (TM) and cytoplasmic domains from Ld) we show that these molecules are not recognized by primary Ld-specific CTL. The cell membrane expression of both Ld and LLQL are upregulated by co-culture with an exogenously supplied murine cytomegalovirus-derived peptide indicating that the Q7 alpha 3 domain does not interfere with binding of Ag to alpha 1/alpha 2. However, only peptide pulsed Ld but not LLQL target cells are recognized by Ld-restricted-peptide specific CTL. In contrast to the above results, LLQL and LLQQ molecules can be recognized by bulk alloreactive anti-Ld CTL and 2/3 of CTL clones derived from in vivo primed mice. The fact that these secondary CTL recognize LLQQ indicates that a PI linkage is permissive for presentation of class I epitopes to alloreactive CTL. These secondary CTL are resistant to blocking at the effector stage by mAb against CD8 and express relatively low levels of membrane CD8 molecules compared to CTL from unprimed mice. Further, culture of unprimed CTL precursors in the presence of CD8 mAb also allows for the generation of CD8-independent CTL that recognize LLQL. Taken together, these data indicate that the alpha 3 domain of Q7 (Qa-2) prevents CD8-dependent CTL from recognizing Ld, regardless of whether the class I molecule is attached to the cell surface by a PI moiety or as a membrane spanning protein domain. We hypothesize that this defect in recognition is most likely due to an inability of CD8 to interact efficiently with the Q7 alpha 3 domain and could account for why Q7 molecules do not serve as restricting elements for virus and minor H-Ag-specific CTL.

Differences between the lateral organization of conventional and inositol phospholipid-anchored membrane proteins. A further definition of micrometer scale membrane domains

Plasma membranes of many cells appear to be divided into domains, areas whose composition and function differ from the average for an entire membrane. We have previously used fluorescence photo-bleaching and recovery to demonstrate one type of membrane domain, with dimensions of micrometers (Yechiel, E., and M. Edidin. 1987, J. Cell Biol. 105: 755-760). The presence of membrane domains is inferred from the dependence of the apparent mobile fraction of labeled molecules on the size of the membrane area probed. We now find that by this definition classical class I MHC molecules, H-2Db, are concentrated in domains in the membranes of K78-2 hepatoma cells, while the nonclassical class I-related molecules, Qa-2, are free to pass the boundaries of these domains. The two proteins are highly homologous but differ in their mode of anchorage to the membrane lipid bilayer. H-2Db is anchored by a transmembrane peptide, while Qa-2 is anchored by a glycosylphosphatidylinositol (GPI) anchor. A mutant class I protein with its external portion derived from Qa-2 but with transmembrane and cytoplasmic sequences from a classical class I molecule shows a dependence of its mobile fraction on the area of membrane probed, while a mutant whose external portions are a mixture of classical and nonclassical class I sequences, GPI-linked to the bilayer, does not show this dependence and hence by our definition is not restricted to membrane domains.

Activated T cells transcribe an alternatively spliced mRNA encoding a soluble form of Qa-2 antigen

Among the best characterized non-classical mouse major histocompatibility antigens are the Qa-2 molecules. These proteins can serve as targets for allogenic cytotoxic T cells and as signal transducing molecules. They are structurally similar to H-2 transplantation antigens in their N-terminal and beta 2-microglobulin binding domains but differ at their C-termini. While the H-2 antigens span the cell membrane, the Qa-2 molecules are attached to the cell surface via phospholipid anchors. The genetic information encoding this attachment is contained in exon 5. In concanavalin A activated splenocytes the expression of membrane bound Qa-2 antigens declines and, simultaneously, soluble forms of Qa-2 molecules are secreted. We demonstrate here that the soluble Qa-2 polypeptides are translated from alternatively spliced mRNAs lacking exon 5, while the membrane forms are encoded by the full-size transcripts. In cultured cells the alternative splicing of the Qa-2 message is induced by T-cell activation splicing of the Qa-2 message is induced by T-cell activation with concanavalin A. The canonical mRNA encoding the membrane form of Qa-2 predominates in unstimulated mouse tissues but the cultured cell lines, like activated T cells, express enhanced levels of the truncated mRNA. In some cell lines almost all Qa-2 transcripts lack exon 5. For example, in L cells, mRNAs encoding soluble Qa-2 molecules are at least 10 times more abundant than Qa-2 transcripts encoding phospholipid anchored antigens. These findings are discussed in terms of potential functions of membrane bound and secreted Qa-2 molecules.

Molecular signals for phosphatidylinositol modification of the Qa-2 antigen

Most cell surface proteins are anchored to the cell bilayer by hydrophobic membrane-spanning domains. Recently it has been shown that a small class of molecules are attached to cell surfaces via a phosphatidylinositol moiety covalently linked to the C-terminus of the mature processed polypeptide. The molecular signals that identify a polypeptide for phosphatidylinositol (PI) attachment have not been well defined in any system, but are thought to reside in the C-terminus of the primary translation product. We report that all the signals responsible for PI anchoring of Qa-2 Ag are confined to the 36 C-terminal residues of the precursor proteins. To investigate further the features that signal cleavage and PI addition, we have studied mutants of two closely related murine class I MHC molecules: the PI-linked Ag, Q9b, from the Qa-2 Ag family, and the integral membrane transplantation antigen, H-2Ld. The addition of 15 amino acids to the three residue long cytoplasmic domain of Q9b or the mutation of Asp295 found in its C-terminal hydrophobic domain to Val converts this molecule into an integral membrane protein. However, the introduction of a short three residue cytoplasmic tail and Asp295 into the transmembrane domain of H-2Ld does not convert this molecule to a PI-linked one. The results of these analyses suggest that the PI-processing signals may depend on overall conformation, hydrophobicity, and length of the C-terminal domain of the precursor protein. In addition these data indicate that PI anchoring of class I Ag requires more than two mutational steps and may have been selected during the evolution.

Molecular signals for phosphatidylinositol modification of the Qa-2 antigen

Most cell surface proteins are anchored to the cell bilayer by hydrophobic membrane-spanning domains. Recently it has been shown that a small class of molecules are attached to cell surfaces via a phosphatidylinositol moiety covalently linked to the C-terminus of the mature processed polypeptide. The molecular signals that identify a polypeptide for phosphatidylinositol (PI) attachment have not been well defined in any system, but are thought to reside in the C-terminus of the primary translation product. We report that all the signals responsible for PI anchoring of Qa-2 Ag are confined to the 36 C-terminal residues of the precursor proteins. To investigate further the features that signal cleavage and PI addition, we have studied mutants of two closely related murine class I MHC molecules: the PI-linked Ag, Q9b, from the Qa-2 Ag family, and the integral membrane transplantation antigen, H-2Ld. The addition of 15 amino acids to the three residue long cytoplasmic domain of Q9b or the mutation of Asp295 found in its C-terminal hydrophobic domain to Val converts this molecule into an integral membrane protein. However, the introduction of a short three residue cytoplasmic tail and Asp295 into the transmembrane domain of H-2Ld does not convert this molecule to a PI-linked one. The results of these analyses suggest that the PI-processing signals may depend on overall conformation, hydrophobicity, and length of the C-terminal domain of the precursor protein. In addition these data indicate that PI anchoring of class I Ag requires more than two mutational steps and may have been selected during the evolution.

Embryonal carcinoma cells express Qa and Tla class I genes of the major histocompatibility complex

The murine major histocompatibility complex encodes H-2K and H-2D transplantation antigens and other class I-like proteins called Qa and Tla molecules; the functions of the Qa/Tla molecules are not known. That they may participate in embryonic cell-cell interactions and/or play a role in immune responses against tumors has been speculated. We have studied two murine embryonal carcinoma tumors, 402AX and PCC4, that are rejected in vivo immunologically, although they do not express H-2K or H-2D antigens. Transplantation studies with these cells suggest that rejection is mediated by class-I-like major histocompatibility complex antigens. As a first step in evaluating Qa/Tla function(s), we have characterized expression of class I-like genes and proteins in 402AX and PCC4 cells. Northern (RNA) blot hybridizations, polymerase chain reaction studies, and cDNA cloning experiments demonstrate that EC lines transcribe genes allelic to the Tla region gene "37", Qa-2 region gene "Q7", and another, previously uncharacterized, class I-like gene. Immunoprecipitation studies show that the embryonal carcinoma tumor cells contain low levels of beta 2-microglobulin expressed in association with non-H-2K, non-H-2D class I-like proteins.

Epitope clusters of Qa-2 antigens defined by a panel of new monoclonal antibodies

A recently derived intra-MHC recombinant mouse strain, the C3H.KBR was found to produce a surprisingly high titer of anti-Qa antibodies when immunized with C3H.SW lymphocytes. By using this immunization combination, a panel of 10 mAb with specificity for determinants encoded by the Q region was produced. These reagents were analyzed for strain distribution by microcytotoxicity, immunofluorescence, and flow cytometry assays. Competitive inhibition analyses, performed by using fluorescein-labeled antibodies and normal spleen cells, defined at least three epitope clusters, or groups of spatially related determinants, detected by this panel. One epitope cluster was unique to this new series of antibodies in that it was not detected with seven previously described anti-Qa mAb. These antibodies also have been analyzed for reactivity with products of isolated Q-region genes by using transfected cell lines. The data indicate that the Q6d, Q7d, and Q10d genes encode determinants reactive with one or more mAb and that two of the three epitope clusters defined with normal cells map to the N and/or C2 domains of these molecules. The third epitope cluster is presumed to map to the C2 domain. These reagents should be useful in determining the number of Q-region genes expressed and in analyses of Q gene expression in subpopulations of normal cells, in transfected cell lines, and during differentiation and ontogeny.

Epitope clusters of Qa-2 antigens defined by a panel of new monoclonal antibodies

A recently derived intra-MHC recombinant mouse strain, the C3H.KBR was found to produce a surprisingly high titer of anti-Qa antibodies when immunized with C3H.SW lymphocytes. By using this immunization combination, a panel of 10 mAb with specificity for determinants encoded by the Q region was produced. These reagents were analyzed for strain distribution by microcytotoxicity, immunofluorescence, and flow cytometry assays. Competitive inhibition analyses, performed by using fluorescein-labeled antibodies and normal spleen cells, defined at least three epitope clusters, or groups of spatially related determinants, detected by this panel. One epitope cluster was unique to this new series of antibodies in that it was not detected with seven previously described anti-Qa mAb. These antibodies also have been analyzed for reactivity with products of isolated Q-region genes by using transfected cell lines. The data indicate that the Q6d, Q7d, and Q10d genes encode determinants reactive with one or more mAb and that two of the three epitope clusters defined with normal cells map to the N and/or C2 domains of these molecules. The third epitope cluster is presumed to map to the C2 domain. These reagents should be useful in determining the number of Q-region genes expressed and in analyses of Q gene expression in subpopulations of normal cells, in transfected cell lines, and during differentiation and ontogeny.

An H-2Ld hybrid molecule with a Qa-2 alpha-3 domain and phosphatidyl-inositol anchor is not recognized by H-2Ld-specific cytotoxic T lymphocytes

Ld/Q7d, a hybrid molecule consisting of alpha-1 and alpha-2 domains from H-2Ld and alpha-3 and carboxy-end components from Q7d, was expressed on the surface of CRL-3A rat liver cells. This molecule retained serologic H-2Ld epitopes. The Ag is attached to the cell membrane through a phosphatidyl-inositol linkage, characteristic of Qa-2 molecules. Both bulk cultured and cloned H-2Ld alloreactive CTL as well as H-2Ld restricted vesicular stomatitis virus-specific CTL lyse CRL-3A cells which express H-2Ld but show little or no lytic activity on cells which express the Ld/Q7d hybrid. These cells also fail to act as cold target competitors for alloreactive anti-H-2Ld CTL. However, cells expressing Ld/Q7d are not resistant to CTL mediated lysis because they can be killed in the presence of lectin. These data indicate that recognition of polymorphic class I CTL epitopes in the alpha-1 and alpha-2 domains are influenced by the structure of the carboxy-end of the molecule.

An H-2Ld hybrid molecule with a Qa-2 alpha-3 domain and phosphatidyl-inositol anchor is not recognized by H-2Ld-specific cytotoxic T lymphocytes

Ld/Q7d, a hybrid molecule consisting of alpha-1 and alpha-2 domains from H-2Ld and alpha-3 and carboxy-end components from Q7d, was expressed on the surface of CRL-3A rat liver cells. This molecule retained serologic H-2Ld epitopes. The Ag is attached to the cell membrane through a phosphatidyl-inositol linkage, characteristic of Qa-2 molecules. Both bulk cultured and cloned H-2Ld alloreactive CTL as well as H-2Ld restricted vesicular stomatitis virus-specific CTL lyse CRL-3A cells which express H-2Ld but show little or no lytic activity on cells which express the Ld/Q7d hybrid. These cells also fail to act as cold target competitors for alloreactive anti-H-2Ld CTL. However, cells expressing Ld/Q7d are not resistant to CTL mediated lysis because they can be killed in the presence of lectin. These data indicate that recognition of polymorphic class I CTL epitopes in the alpha-1 and alpha-2 domains are influenced by the structure of the carboxy-end of the molecule.

H-2Kb antigen expression has no effect on natural killer susceptibility and tumorigenicity of a murine hepatoma

Recent reports suggested a correlation between decreased expression of tumor cell MHC class I Ag and increased susceptibility to NK cells. These studies led to the hypothesis that tumor cells displaying reduced levels of MHC class I Ag have reduced tumorigenicity in vivo because they are eliminated from the host by endogenous NK cells. The present studies use the murine hepatoma BW7756 and a spontaneous H-2Kb loss variant, Hepa-1, to test this hypothesis. The parental BW7756 tumor is highly malignant in syngeneic C57L/J hosts while Hepa-1 cells do not give rise to tumors, suggesting that the loss of H-2Kb Ag expression correlates with decreased tumorigenicity and NK susceptibility. Hepa-1 cells were therefore transfected with an H-2Kb gene to generate H-2Kb Ag expressing clones. The resulting clones were tested for tumorigenicity. Syngeneic or NK-deficient C57BL/6-beige/beige mice challenged with Hepa-1 or the H-2Kb transfectants rejected the cells, suggesting that reexpression of H-2Kb Ag does not restore tumorigenicity and that NK cells are not involved in Hepa-1 rejection. In vitro H-2Kb Ag-negative and -positive Hepa-1 cells are equally susceptible to tilorone-boosted NK cells, indicating that MHC class I Ag expression also does not affect in vitro NK susceptibility. Tumor challenged athymic nude and sublethally irradiated syngeneic mice develop tumors demonstrating that T cells are probably responsible for rejection of the Hepa-1 tumor, and that H-2Kb Ag expression has no effect on rejection. Inasmuch as the expression of H-2Kb Ag on Hepa-1 cells does not effect tumorigenicity or in vitro NK susceptibility, the previously reported association between reduced MHC class I Ag levels and increased NK susceptibility is not universally applicable.

H-2Kb antigen expression has no effect on natural killer susceptibility and tumorigenicity of a murine hepatoma

Recent reports suggested a correlation between decreased expression of tumor cell MHC class I Ag and increased susceptibility to NK cells. These studies led to the hypothesis that tumor cells displaying reduced levels of MHC class I Ag have reduced tumorigenicity in vivo because they are eliminated from the host by endogenous NK cells. The present studies use the murine hepatoma BW7756 and a spontaneous H-2Kb loss variant, Hepa-1, to test this hypothesis. The parental BW7756 tumor is highly malignant in syngeneic C57L/J hosts while Hepa-1 cells do not give rise to tumors, suggesting that the loss of H-2Kb Ag expression correlates with decreased tumorigenicity and NK susceptibility. Hepa-1 cells were therefore transfected with an H-2Kb gene to generate H-2Kb Ag expressing clones. The resulting clones were tested for tumorigenicity. Syngeneic or NK-deficient C57BL/6-beige/beige mice challenged with Hepa-1 or the H-2Kb transfectants rejected the cells, suggesting that reexpression of H-2Kb Ag does not restore tumorigenicity and that NK cells are not involved in Hepa-1 rejection. In vitro H-2Kb Ag-negative and -positive Hepa-1 cells are equally susceptible to tilorone-boosted NK cells, indicating that MHC class I Ag expression also does not affect in vitro NK susceptibility. Tumor challenged athymic nude and sublethally irradiated syngeneic mice develop tumors demonstrating that T cells are probably responsible for rejection of the Hepa-1 tumor, and that H-2Kb Ag expression has no effect on rejection. Inasmuch as the expression of H-2Kb Ag on Hepa-1 cells does not effect tumorigenicity or in vitro NK susceptibility, the previously reported association between reduced MHC class I Ag levels and increased NK susceptibility is not universally applicable.

Qa-region class I gene expression: identification of a second class I gene, Q9, encoding a Qa-2 polypeptide

A feature of the expression of the tissue-specific class I antigen Qa-2 is the quantitative variation among mouse strains. Recently, the class I gene Q7 has been shown to encode a protein product that is biochemically indistinguishable from the lymphocyte-bound Qa-2 molecule. Utilizing gene transfection, we have identified a second Qa-2 subregion class I gene (Q9), in H-2b mice, which encodes a polypeptide biochemically similar to the Q7 and the Qa-2 polypeptides. Furthermore, we have observed that cell lines transfected with the allelic forms of the Q7 gene from C57BL/10 (Qa-2hi) or BALB/C (Qa-2low) display quantitative differences in cell-surface expression. Based on these studies, we suggest that gene dosage and allele-specific variation in cell-surface expression contribute to the strain-specific variation in the levels of Qa-2 antigen expression.

Regulation of gene expression by interferons: control of H-2 promoter responses

The magnitude of the response to interferons and the requirement for individual elements in the promoter of the H-2Dd gene were shown to be cell-specific and dependent on the type of interferon used. Three DNA sequences in the promoter were found to bind murine nuclear factors. Two of these sequences are in functionally defined enhancer regions and also bind to the transcription factor AP-1. The third sequence is part of the region involved in interferon regulation and is homologous to the enhancer element of the interferon beta gene. A model for interferon regulation of H-2 promoters is discussed.