Cell surface expression of class II histocompatibility antigens occurs in the absence of the invariant chain

Subsets of HLA-DR1 molecules defined by SEB and TSST-1 binding

Superantigens bind to major histocompatibility complex class II molecules on antigen-presenting cells and stimulate T cells. Staphylococcus aureus enterotoxin B (SEB) and toxic shock syndrome toxin-1 (TSST-1) bind to the same region of human lymphocyte antigen (HLA)-DR1 but do not compete with each other, which indicates that they bind to different subsets of DR1 molecules. Here, a mutation in the peptide-binding groove disrupted the SEB and TSST-1 binding sites, which suggests that peptides can influence the interaction with bacterial toxins. In support of this, the expression of the DR1 molecule in various cell types differentially affected the binding of these toxins.

The bio-logical role of invariant chain (Ii) in MHC class II antigen presentation

Foreign antigens are internalized by antigen presenting cells by endocytosis and processed to peptides. To enable presentation of antigenic peptides by MHC class II molecules, these molecules have to be sorted to endosomal compartments where they can meet and bind the peptides. Invariant chain is complexed with MHC class II molecules and contains sorting signals responsible for MHC class II accumulation in endosomes. Invariant chain also has several other features contributing to the immune system's specific combat against invaders.

Cathepsin B cleavage and release of invariant chain from MHC class II molecules follow a staged pattern

A staged pattern of cathepsin B cleavage of MHC class II alpha, beta-bound invariant (Ii) chain and release of fragments was defined. Charge-loss mutations in the Ii chain were created in three clusters of cathepsin B putative cleavage sites R78K80K83K86, K137K143, and R151K154. Products of HLA-DR1 alpha, beta and wild type (WT) or mutant Ii genes, co-transfected into COS1 cells, were cleaved by cathepsin B and immunoprecipitated by antibodies either to MHC class II chains or to different Ii epitopes. In WT Ii, cathepsin B digestion generated two forms of p21 Ii fragments: a p21 recognized by anti-C-terminus antibodies and a p21 recognized by an antibody to a determinant near the N-terminus. C-terminal p21 was released from MHC class II alpha, beta chains upon its formation while N-terminal p21 remained associated with MHC class II alpha, beta chains. Mutations at K137K143 inhibited the generation of N-terminal p21 by cathepsin B. Mutation at R78K80K83K86 led to an accumulation of MHC class II-bound N-terminal p21 without the appearance of MHC class II-bound p14, p10, and p6 fragments after cathepsin B digestion. These results indicate that cathepsin B cleaves wild type Ii first about K137K143 to produce a MHC class II-associated N-terminal p21, which is then cleaved about R78K80K83K86 to generate p14, p10 and finally p6 which still associates with MHC class II alpha, beta chains. This pattern of staged cleavage and release of Ii might be related to a concerted mechanism regulating the binding of antigenic peptides to MHC class II molecules.

Cytomegalovirus inhibits major histocompatibility class II expression on infected endothelial cells

Persistent human cytomegalovirus (HCMV) infections are responsible for significant morbidity and mortality in immunocompromised individuals. One mechanism by which HCMV may develop persistence after primary infection is through inhibition of host cell human leukocyte antigen (HLA) class II expression with resultant escape from normal antiviral immune surveillance. Immunofluorescence flow cytometry of human endothelial cell (EC) cultures infected with HCMV AD169 and an EC propagated strain, VHL/E, showed a marked reduction in interferon-gamma (IFN-gamma)-induced surface expression of HLA-DR. This inhibition did not occur when EC were treated with ultraviolet-inactivated virus and IFN-gamma. HCMV, as determined by dual-labeling immunohistochemistry, inhibited induction of surface and cytoplasmic class II antigens specifically in infected cells. HCMV infection also inhibited IFN-gamma and tumor necrosis factor-alpha up-regulation of HLA class I expression. Northern blot analysis of infected, IFN-gamma-treated human umbilical vein endothelial cells revealed an absence of class II mRNA. Persistence of HCMV may result in part from its ability to inhibit HLA class II induction in infected cells.

The invariant chain is required for intracellular transport and function of major histocompatibility complex class II molecules

The major histocompatibility complex (MHC) class II-associated invariant chain (Ii) is thought to act as a chaperone that assists class II during folding, assembly, and transport. To define more precisely the role of Ii chain in regulating class II function, we have investigated in detail the biosynthesis, transport, and intracellular distribution of class II molecules in splenocytes from mice bearing a deletion of the Ii gene. As observed previously, the absence of Ii chain caused significant reduction in both class II-restricted antigen presentation and expression of class II molecules at the cell surface because of the intracellular accumulation of alpha and beta chains. Whereas much of the newly synthesized MHC molecules enter a high molecular weight aggregate characteristic of misfolded proteins, most of the alpha and beta chains form dimers and acquire epitopes characteristic of properly folded complexes. Although the complexes do not bind endogenously processed peptides, class II molecules that reach the surface are competent to bind peptides added to the medium, further demonstrating that at least some of the complexes fold properly. Similar to misfolded proteins, however, the alpha and beta chains are poorly terminally glycosylated, suggesting that they fail to reach the Golgi complex. As demonstrated by double label confocal and electron microscope immunocytochemistry, class II molecules were found in a subcompartment of the endoplasmic reticulum and in a population of small nonlysosomal vesicles possibly corresponding to the intermediate compartment or cis-Golgi network. Thus, although alpha and beta chains can fold and form dimers on their own, the absence of Ii chain causes them to be recognized as "misfolded" and retained in the same compartments as bona fide misfolded proteins.

A possible role of the MHC-associated invariant chain in rheumatoid arthritis

Antigen presentation to T-helper (Th) cells by MHC class II proteins is an important event in the initiation and/or maintenance of autoimmune disease. The class II proteins have a wide, degenerate specificity and are capable of binding several different peptides, including self-peptides. However, recent data suggest that a protein called invariant chain, Ii, binds to the class II molecule in the endoplasmic reticulum in such a way that precludes the binding of peptides derived from intracellular self- or non-self-proteins. The class II-Ii complex is transported through the endoplasmic reticulum to the endosomes, which contain peptides derived from extracellular proteins. The acidic pH and proteolysis in the endosomes cause dissociation of the class II-Ii complex, making the class II protein available for binding to the peptides. Thus, the Ii chain appears to play an important role in suppressing autoimmune responses. A hypothesis that a defect in the Ii chain could lead to autoimmune disorders is proposed. These defects would include alterations in the Ii chain such that it is no longer able to compete with the self-peptides for binding to the class II protein.

The chondroitin sulfate form of invariant chain can enhance stimulation of T cell responses through interaction with CD44

Invariant chain (Ii) is a nonpolymorphic glycoprotein that associates with major histocompatibility complex class II molecules and has been shown to mediate several functions in class II-restricted antigen presentation. A small proportion of Ii is modified by the addition of chondroitin sulfate (Ii-CS), and this form of Ii is associated with class II on the surface of antigen-presenting cells. In this report we show that expression of Ii-CS dramatically enhanced the ability of class II-positive EL4 transfectants to stimulate class II-dependent allogeneic and mitogenic T cell responses. Antibody blocking studies and the ability of CD44 to bind directly to Ii-CS suggest that Ii-CS can function as an accessory molecule during T cell responses through interactions with CD44.

Defective major histocompatibility complex class II assembly, transport, peptide acquisition, and CD4+ T cell selection in mice lacking invariant chain expression

We used gene targeting techniques to produce mice lacking the invariant chain associated with major histocompatibility complex (MHC) class II molecules. Cells from these mice show a dramatic reduction in surface class II, resulting from both defective association of class II alpha and beta chains and markedly decreased post-Golgi transport. The few class II alpha/beta heterodimers reaching the cell surface behave as if empty or occupied by an easily displaced peptide, and display a distinct structure. Mutant spleen cells are defective in their ability to present intact protein antigens, but stimulate enhanced responses in the presence of peptides. These mutant mice have greatly reduced numbers of thymic and peripheral CD4+ T cells. Overall, this striking phenotype establishes that the invariant chain plays a critical role in regulating MHC class II expression and function in the intact animal.

Cellular and molecular aspects of antigen processing and the function of class II MHC molecules

Antigen processing is the conversion of native antigen molecules into short peptides that can then bind to major histocompatibility complex (MHC) molecules. Class II MHC (MHC-II) molecules target to endocytic compartments, where they bind peptides that are produced by internalization of extracellular antigens and subsequent antigen catabolism. The resulting peptide-MHC complexes are displayed on the surface of antigen-presenting cells for recognition by T cells. Thus, MHC-II molecules first serve as peptide receptors that rescue peptides from total lysosomal degradation and transport them to the plasma membrane; the MHC-II molecules then form a composite peptide-MHC-II determinant that is recognized by the T cell receptor. Recent work has begun to clarify the molecular events and transport mechanisms that govern antigen processing.

Mice lacking the MHC class II-associated invariant chain

The invariant chain (li) has aroused much interest because of its close association with major histocompatibility complex (MHC) class II molecules. Various functions have been proposed for it; several of these have received experimental support, but most have not been definitively proven, owing largely to uncertainties inherent in the experimental systems employed. We have now generated a line of mice devoid of the invariant chain by introducing a drastic mutation into the li gene. Cells from mutant animals show aberrant transport of MHC class II molecules, resulting in reduced levels of class II complexes at the surface, and these do not have the typical compact conformation indicative of tight peptide binding. Consequently, mutant cells present protein antigens very poorly and mutant mice are deficient in producing and at negatively selecting CD4+ T cells.

Cell biology of antigen presentation

MHC class I molecules present degradation products derived from intracellular proteins, whereas MHC class II molecules generally present peptides derived from extracellular or surface proteins. Recent insights into the cell biology of MHC class I and II molecules explain this difference.

Dendritic cells in glomerulonephritis

Renal biopsies (n = 45) from patients with various forms of glomerulonephritis (GN), comprising mesangial IgA-GN (n = 25), focal glomerular sclerosis (n = 13) and acute GN (n = 7), were examined by double staining immunocytochemistry (APAAP, streptavidin-peroxidase) using unconjugated monoclonal antibodies (Ab) against--(i) the CD1b antigen expressed on dendritic cells (DCs), (ii) the invariant chain (Ii), and (iii) biotin-conjugated Ab against HLA-DR. In normal control kidneys (n = 7) without interstitial inflammation, CD1b-positive DCs were not detected. Glomerular endothelial cells and a few cells in mesangial areas showed double staining with the Ab against HLA-DR in Ii. In GN without active interstitial inflammation (n = 9), CD1b-positive DCs were not found. In biopsies with interstitial inflammation (n = 36) CD1b-positive DCs were found interspersed among other inflammatory cells. In seven of the biopsies showing IgA-GN DCs were seen in the vicinity of those glomeruli that exhibited either crescents or glomerular sclerosis with splitting of Bowman's capsule. In proximal tubular epithelial cells de novo expression of HLA-DR/Ii-chain was only seen when DCs were present. We conclude that in different forms of GN: (i) CD1b-positive DCs play an important role in the development of interstitial inflammation, and (ii) their presence may be related to the de novo coexpression of HLA-DR/Ii in tubular epithelial cells, possibly mediated through the production of interferon gamma and other cytokines.

HLA-DR associates with specific stress proteins and is retained in the endoplasmic reticulum in invariant chain negative cells

The major histocompatibility complex class II molecules are composed of two polymorphic chains which, in cells normally expressing them, transiently associate with a third, nonpolymorphic molecule, the invariant chain (Ii). To determine differences in the biology of class II molecules synthesized in the presence or absence of Ii, a comparative study was performed of BALB/c 3T3 cells that had been transfected with human class II HLA-DR molecules with or without cotransfection with human Ii. It was observed that in the absence of Ii, at least three high molecular weight proteins coimmunoprecipitate with HLA-DR molecules. These proteins did not coimmunoprecipitate with HLA-DR from cells cotransfected with Ii, nor did they coimmunoprecipitate with class I molecules from any of the transfectants. NH2-terminal sequence and/or Western blot analysis revealed the identity of two of the proteins as the endoplasmic reticulum (ER) resident stress proteins GRP94 and ERp72. Neither of these proteins was found to have an increased level of synthesis in the Ii- versus the Ii+ transfectants, indicating that their synthesis was not induced over constitutive levels. Fluorescence microscopy revealed that in the Ii- transfectants, the majority of the HLA-DR molecules were present in the ER, whereas in the Ii+ transfectants, the HLA-DR molecules were found in vesicular structures. We hypothesize that in the absence of Ii, ER resident stress proteins bind to class II molecules and retain them in the ER. This process, in turn, could prevent class II molecules from exiting the ER with endogenous peptides bound in their peptide binding cleft, and therefore could minimize autoimmune responses to endogenously processed self-peptides.

Phenotypic characterization of KU812, a cell line identified as an immature human basophilic leukocyte

The knowledge about the differentiation of basophilic leukocytes is fragmentary. This report discusses a detailed phenotypic characterization of molecular markers for hematopoietic differentiation in a basophilic leukemia cell line, KU812. The expression of markers for lymphoid, erythroid, neutrophil, eosinophil, monocytic, megakaryocytic, mast cell and basophil differentiation was analyzed at the mRNA level by Northern blots in the KU812 cells, and for reference, in a panel of human cell lines representative of the different hematopoietic differentiation lineages. KU812 was found to express a number of mast cell and basophil-related proteins, i.e. mast cell tryptase, mast cell carboxypeptidase A, high-affinity immunoglobulin (IgE) receptor alpha and gamma chains and the core protein for heparin and chondroitin sulphate synthesis. We found no expression of a number of monocyte/-macrophage or neutrophil leukocyte markers except for lysozyme. From earlier studies, it has been shown that lysozyme is not expressed in murine mucosal mast cell lines. This finding, together with the expression of the mast cell carboxypeptidase in KU812 might distinguish the phenotype of this cell line from that typical of mucosal mast cell lines in rodents. We found a low level of expression of the eosinophil and basophil marker, major basic protein, which might indicate a relationship between basophils and eosinophils. No expression is, however, detected with the eosinophil-specific markers eosinophil cationic protein, eosinophil-derived neurotoxin or eosinophil peroxidase. We also report an extensive screening for inducers of basophilic differentiation of the KU812 cells. The most efficient protocol of induction included serum starvation which led to a dramatic increase in a number of markers specific for mast cells and basophils such as tryptase, carboxypeptidase A and the heparin core protein. Finally, diisopropylfluorophosphate analysis of total protein extracts from KU812 show four labeled protein bands with sodium dodecyl sulfate-polyacrylamide gel electrophoresis, indicating that this cell line expresses at least three previously undescribed serine proteases of which one or more could be a potential basophil-specific marker(s).

Induction of intercellular adhesion molecule-1 but not of lymphocyte function-associated antigen-3 in thyroid follicular cells

We investigated the expression of intercellular adhesion molecule-1 (ICAM-1) and lymphocyte function-associated antigen-3 (LFA-3) by thyrocytes and their regulation by cytokines. Immunofluorescence studies on cryostat sections and on freshly dispersed cell preparations showed that ICAM-1 and LFA-3 are barely detectable in non-autoimmune thyrocytes. However, thyrocytes acquired ICAM-1 expression in culture. IFN-gamma, IL-1 beta and TNF-alpha produced a clear enhancement of ICAM-1 expression. When tested in combination, IL-1 beta and TNF-alpha were additive to the IFN-gamma effect. LFA-3 expression was not modulated by these cytokines. In the HT93 thyroid cell line generated by transfection with SV40, ICAM-1 and LFA-3 were both constitutively expressed at high levels. Cytokines modulated ICAM-1 expression similarly, but to a greater extent than in normal thyrocytes. LFA-3 remained unmodified. These results support the notion that normal thyrocytes are immunologically silent cells. The capability of cytokines to induce ICAM-1 together with HLA class I and class II-expression on thyrocytes suggests that under their influence, these cells may express all the surface molecules required for antigen presentation and/or for being recognized as target cells in the context of thyroid autoimmune disease.

Intracellular transport of MHC class II molecules

MHC class II molecules associate, during biosynthesis, with peptides derived from endocytosed antigen. Here, Jacques Neefjes and Hidde Ploegh describe the intracellular transport of MHC class II molecules and its relationship to the binding of peptides in endosomal compartments. They discuss alternative routes for the delivery of antigen to sites at which peptides associate with MHC class II molecules and raise the possibility of cell type-specific differences in the handling of MHC class II molecules, and hence in antigen presentation.

Chemistry and functional role of the invariant chain

The invariant chain has two critical properties that regulate the function of the class II glycoproteins with which it associates. It prevents class II molecules from binding antigenic peptides during the early stages of their assembly and transport, and it contains a signal that drives the assembled class II-invariant chain complex to an endocytic compartment. Dissociation of the invariant chain in this compartment is believed to generate class II molecules capable of binding antigenic peptides.

A novel method for generating stable high-level transfectants involving direct immunomagnetic selection for cell-surface epitopes: expression of HLA class-II genes in HeLa cells

A versatile method that allows efficient detection and selection of both transient and stable transfectants expressing exogenous cell-surface molecules is described and used to generate stable HeLa transfectants expressing each of the human HLA class-II isotypes, specifically the DR1, DQw8 and DPw2 heterodimers. The method combines use of the strong mammalian expression vector, CDM8, and a highly efficient transfection protocol with the powerful technique of immunomagnetic selection. It offers significant advantages in comparison to standard procedures involving co-selection with drug-resistance markers. The transfection efficiency can be assessed 60 h after transfection rather than after three weeks of drug selection. Repeated rounds of immunomagnetic selection applied over the subsequent ten days result in homogeneous populations which express the surface marker of interest stably at high levels, making further subcloning or fluorescence-activated cell sorting unnecessary. Any number of surface products can be transfected into the same cell, the only limitation being the availability of specific monoclonal antibodies (a DP/DR double transfectant is described expressing four exogenous gene products simultaneously). The high sensitivity of immunomagnetic selection and its applicability to large samples allows rescue of transfectants present at very low frequencies. Finally, the technique can be used as a coselection procedure, by analogy with drug coselection, to achieve expression even of non-cell surface products.

Class II MHC antigen expression by cultured human cerebral vascular endothelial cells

Cerebral vascular endothelial cells (EC) isolated from human brain do not constitutively express class II MHC antigens. However, incubation in the presence of human interferon-gamma (IFN gamma) resulted in the expression of both HLA-DR and -DP antigens. FACS analysis revealed that approximately 40% of the EC population expressed HLA-DR antigen. Quantitation by ELISA demonstrated that maximum expression was observed with 100 U/ml IFN gamma for 4 days. Treatment with IFN gamma also increased class II mRNA levels in all EC cultures tested.

Defective intracellular transport as a common mechanism limiting expression of inappropriately paired class II major histocompatibility complex alpha/beta chains

Distinct combinations of class II major histocompatibility complex (MHC) alpha and beta chains show widely varying efficiencies of cell surface expression in transfected cells. Previous studies have analyzed the regions of the class II chains that are critically involved in this phenomenon of variable expression and have shown a predominant effect of the NH2-terminal domains comprising the peptide-binding site. The present experiments attempt to identify the post-translational defects responsible for this variation in surface class II molecule expression for both interisotypic alpha/beta combinations failing to give rise to any detectable cell membrane molecules (e.g., E alpha A beta k) and intraisotypic pairs with inefficient surface expression (e.g., A alpha d A beta k). The results of metabolic labeling and immunoprecipitation experiments using L cell transfectants demonstrate that in both of these cases, the alpha and beta chains form substantial amounts of stable intracellular dimers. However, the isotype- and allele-mismatched combinations do not show the typical post-translational increases in molecular weight that accompany maturation of the N-linked glycans of class II MHC molecules. Studies with endoglycosidase H reveal that no or little progression to endoglycosidase H resistance occurs for these mismatched dimers. These data are consistent with active or passive retention of relatively stable and long-lived mismatched dimers in a pre-medial-Golgi compartment, possibly in the endoplasmic reticulum itself. This retention accounts for the absent or poor surface expression of these alpha/beta combinations, and suggests that conformational effects of the mismatching in the NH2-terminal domain results in a failure of class II molecules to undergo efficient intracellular transport.

Class II antigen-associated invariant chain mRNA in mouse small intestine

MHC class II antigen-associated invariant (Ii) chain mRNA appears in mouse small intestine during postnatal development. Ii chain cDNA hybridizes to RNA from epithelial sheets dissociated from the lamina propria with EDTA. Of several mouse organs tested, only bone marrow and spleen contain higher levels of Ii chain mRNA than small bowel. Ii chain mRNA is not detected in stomach, colon, duodenum, testis, liver, submandibular gland, or L-cell RNA; brain contains a cross-reactive but uncharacterized sequence. cDNA amplification using primers specific for both Ii31 and Ii41 chain mRNAs showed that both forms occur in small intestine. These results support the conclusion that regulation of the class II Ii chain gene is associated with the ontogeny of intestinal immunity.

Efficient cDNA expression vectors for stable and transient expression of HLA-DR in transfected fibroblast and lymphoid cells

cDNA expression vectors with several useful features were constructed. First, the long terminal repeat of Rous sarcoma virus was used as a promoter to obtain high levels of expression in various cells of human and mouse origin. Second, cis-linked expression units that confer resistance either to mycophenolic acid or the neomycin analog G418 were inserted to facitate the isolation of transfected cells expressing the cDNA of interest. Third, by replicating in simian COS cells, these vectors can be used for efficient transient expression. cDNA fragments encoding the DR alpha or DR beta chains of human class II major histocompatibility complex antigens were inserted into these vectors and high levels of cell surface HLA-DR antigen were obtained after cotransfection into mouse and human fibroblasts. These vectors were also successfully used to correct the inability of a class II-negative B cell line, derived from a patient with a congenital immunodeficiency, to present peptide antigen to DR-restricted T cells.

Invariant chain targets HLA class II molecules to acidic endosomes containing internalized influenza virus

The role of the HLA class II-associated invariant chain in the intracellular trafficking of HLA-DR molecules was examined in a transient expression system using HeLa cells. In the absence of alpha and beta polypeptides, invariant chain was retained in the endoplasmic reticulum (ER). In the absence of invariant chain, intracellular alpha beta heterodimers could be detected only in the ER and the Golgi apparatus. However, when alpha and beta subunits were coexpressed with invariant chain, HLA-DR molecules were detectable in peripheral cytoplasmic vesicles, which also contained invariant chain. In addition, an antibody directed to an acid-induced conformational determinant on the influenza hemagglutinin molecule detected internalized influenza virus in the HLA-DR-containing vesicles. These findings provide direct evidence that the invariant chain targets class II molecules to an acidic endosomal compartment and that this compartment, long suspected to be the site of antigen processing, is the site where class II molecules interact with natural antigen.

HLA-class-I and -class-II expression on renal tumor xenografts and the relation to sensitivity for alpha-IFN, gamma-IFN and TNF

In this study we evaluated the usefulness of the histocompatibility leucocyte antigen (HLA) class-I and class-II expression on renal-cell carcinoma (RCC) xenografts as predictive markers for response to cytokine therapy. Eight different RCC xenografts growing in BALBC nu/nu mice were treated with 0.5 or 5.0 ng/g recombinant human alpha- or gamma-interferon (IFN), or 500 ng/g recombinant human tumor necrosis factor (TNF). Modulation of HLA class-I, -II expression was evaluated immunohistochemically using the monoclonal antibodies (MAbs) W6.32 and B8.11.2 and at the mRNA level using the plasmids pDP001 and DR alpha 120. HLA class-I expression in all lines was upregulated by alpha- and gamma-IFN and was highest in the high-IFN-dose-treated tumors. TNF also stimulated HLA-class-I expression and up-regulated class-I expression still further when combined with IFN. Highest up-regulation of HLA-class-I in all tumors was measured in the alpha-IFN-5.0/TNF-500-ng/g-treated mice, although this was not necessarily the treatment regimen resulting in the most pronounced effect on tumor growth. Hence, maximum upregulation of class-I antigens at a given regimen was not always indicative for the highest achievable anti-tumor effect. HLA-class-II expression which was present on only 3 of the untreated tumors was up-regulated by both alpha and gamma-IFN. TNF itself did not up-regulate class-II expression but enhanced the class-II expression on the alpha-IFN-treated tumors but not on the gamma-IFN-treated tumors. Irrespective of the basic expression level, inducibility of both HLA-class-I and -class-II antigens appear to be correlated to the direct effects on growth of renal-tumor xenografts towards alpha-IFN, gamma-IFN and TNF. Modulation of HLA antigens was studied in the nude mouse, hence T-cell-mediated effector mechanisms cannot explain the good correlation between inducibility and response. Nonetheless, our studies indicate that the extent of modulation of HLA-class-I and -II can serve as predictive marker for response to cytokine therapy, which may serve as a valuable criterion for inclusion of patients in cytokine treatment regimens.

Interleukin-1 beta decreases HLA class II expression on a glioblastoma multiforme cell line

Antigens encoded within the major histocompatibility complex (MHC) are not normally expressed in the central nervous system (CNS), but can be induced by treatment with interferon-gamma (IFN-gamma). Other cytokines released during an inflammatory process can potentially influence MHC expression as well. One cytokine of interest is interleukin-1 (IL-1), an immunoregulatory polypeptide that is produced by macrophages and also by cells in the CNS. In this study, the effect of IL-1 beta on MHC expression in a human glioblastoma multiforme cell line, U-105 MG, has been examined. Treatment of U-105 MG with 10 U IL-1 beta/ml for a period of 5 days resulted in a decrease in constitutive cell surface HLA class II expression and limited the induction of class II by IFN-gamma. This effect was also observed on steady-state levels of class II RNA and could be neutralized with antibodies to IL-1 beta. All class II transcripts examined (HLA-DR, -DQ, and -DP alpha and beta) were affected. Class I expression was only marginally changed by IL-1 beta treatment. A minimal concentration of 1 U IL-1 beta/ml was required to reduce class II expression and a kinetics experiment indicated that U-105 MG must be treated for at least 4 days with IL-1 beta for a decrease in class II expression to be observed. This study suggests that IL-1 may play a role in limiting immunoreactivity in the CNS by limiting class II induction.

Allo-cross-reactivity of a human neuraminidase-specific T cell clone dependent on presentation of an endogenous B cell-specific antigen

T cells specific for foreign antigen recognize a complex of peptides and self-major histocompatibility complex (MHC) molecules and can also cross-react with allo-MHC molecules. It remains controversial, however, what alloreactive T cells exactly recognize. It has been proposed that alloreactive T cells recognize endogenous peptides presented by allo-MHC molecules. To test this hypothesis, we examined an influenza virus-specific T cell clone (6H5), specific for neuraminidase N2 and restricted by HLA-DR1. In the absence of influenza virus, this clone cross-reacted with HLA-DR1Dw1+ but not with HLA-DR1Dw20+ Epstein-Barr virus-transformed lymphoblastoid cells (B-LCL). Cold target inhibition experiments and the rearrangement pattern of the T cell receptor beta chain indicated that 6H5 was a monoclonal T cell population most likely using the same T cell receptor for both responses. To determine whether determinants other than HLA-DR1Dw1+ B-LCL or activated B cells, but, surprisingly, not to other cell types expressed HLA-DR1Dw1, including monocytes and transfected L cells. These experiments further support the concept that recognition of allogeneic MHC (in this case HLA-DR1Dw1) may result from a cross-reactivity of T cells specific for a complex of foreign antigen and self-MHC (neuraminidase N2 and HLA-DR1Dw20). Furthermore, allorecognition of T cell clone 6H5 appears to depend upon the recognition of a complex of allogeneic MHC and a cell-type specific endogenous peptide presented by activated B cells.

Invariant chain promotes egress of poorly expressed, haplotype-mismatched class II major histocompatibility complex A alpha A beta dimers from the endoplasmic reticulum/cis-Golgi compartment

Invariant chain (Ii) is a nonpolymorphic, non-major histocompatibility complex (MHC)-encoded glycoprotein that rapidly associates with newly synthesized class II MHC alpha and beta chains in the rough endoplasmic reticulum. This oligomerization of Ii, alpha, and beta and their cotransport within the cell led to speculation that Ii was an essential alpha beta transport protein. However, direct tests failed to show an absolute requirement for Ii in class II MHC molecule transport. More recently, it has become clear that different class II alpha beta chain combinations vary greatly in their efficiency of cell-surface expression, based largely on the allelic origin of the alpha and beta amino-terminal regions. Because the previous tests of Ii for a role in class II molecule expression utilized efficiently expressed alpha beta combinations, we have reexamined this question with several haplotype-mismatched murine A alpha and A beta chain combinations of various potentials for cell-surface expression. Using a transient expression assay in Ii-negative COS cells, we find that many inefficiently expressed alpha beta combinations show marked augmentation of surface expression upon cosynthesis of Ii. This effect is absent or minimal with evolutionarily coselected, haplotype-matched chains that give efficient expression alone. Biochemical studies show that at least one component of the Ii effect is an increased egress of already formed alpha beta dimers from the rough endoplasmic reticulum/cis-Golgi. We suggest that these results reflect the interaction of Ii with the peptide-binding domain of the poorly expressed class II molecules, either aiding in maintenance of a transportable conformation or competing with endoplasmic reticulum retention proteins, and thus enhancing movement to the cell surface. These results suggest a complex and variable role for trans-associated alpha and beta chains in the immune responses of MHC heterozygotes and provide a method for examining Ii interaction with class II MHC molecules independent of measurement of peptide presentation to T cells.

Molecules that modify antigen recognition

MHC class II molecules assemble in the presence of invariant chains. These probably serve not only to protect the peptide-binding site on MHC class II molecules from endogenous peptides, but also to sort MHC class II molecules from the Golgi complex to endosomes and there to retain the class II polypeptides to allow binding of peptides generated from exogenous antigens.

Lead influences translational or posttranslational regulation of Ia expression and increases invariant chain expression in mouse B cells

The molecular mechanisms governing the increased cell surface expression of major histocompatibility complex (MHC) class II molecules (Ia) on lead-treated mouse B cells was investigated. Lead has been shown to directly cause a selective, two-fold increase in the B cell's surface density of both products of the I region of the mouse MHC, I-A and I-E. In the present study, Western blot analysis showed that Pb increases the total cellular pool of I-A beta-chain by twofold. The increase in cellular I-A was not found to be due to increased messenger RNA (mRNA) for either the alpha- or the beta-chain of I-A. Biosynthetic labeling studies showed that Pb increases the translation or the stability of the Ia-associated invariant chain (Ii or gamma) and possibly the beta-chain of Ia. Collectively these results suggest that Pb increases the B cell's surface Ia by influencing translational or posttranslational regulation of Ia and/or Ia-associated chains.

Intracellular transport of class II MHC molecules directed by invariant chain

Three structural motifs in the invariant chain (li) control the intracellular transport of class II major histocompatibility complex molecules. An endoplasmic reticulum retention signal in the full-length li suggests a role for li in the alpha-beta heterodimer assembly. Another signal motif directs a truncated li, alone or associated with individual class II chains, to a degradation compartment by a pathway circumventing the Golgi. When this truncated li binds alpha-beta dimers, a third signal dominates, directing the complex by way of the Golgi to vesicles in the cell periphery, which may represent a subcompartment of recycling endosomes.

Proteoglycans in haemopoietic cells

Proteoglycans are produced by all types of haemopoietic cells including mature cells and the undifferentiated stem cells. The proteinase-resistant secretory granule proteoglycan (serglycin; Ref. 14), is the most prevalent and best characterised of these proteoglycans. Although its complete pattern of distribution in the haemopoietic system is unknown, serglycin has been identified in the mast cells, basophils and NK cells, in which secretion is regulated, and in HL-60 cells and a monocytoid cell line (Kolset, S.O., unpublished data) in which secretion is constitutive. Proteinase-resistant proteoglycans have been detected in human T-lymphocytes and murine stem cells (FDCP-mix) and the core proteins may be closely related to serglycin. A variety of glycosaminoglycan chains are assembled on the serglycin protein and it is likely that this class of proteoglycan can carry out a wide variety of functions in haemopoietic cells including the regulation of immune responses, inflammatory reactions and blood coagulation. There is strong evidence that in mast cells, NK cells and platelets, the proteoglycans are complexed to basic proteins (including enzymes and cytolytic agents) and amines in secretory granules and such complexes may dissociate following secretion from the cell. The stability of the complexes may be regulated by the ambient pH which may be acidic in the granules and neutral or above in the external medium. However, proteinase-proteoglycan complexes in mast cell granules seem to remain stable after secretion and it has been proposed that the proteoglycan regulates activity of proteinases released into the pericellular domain. The functions of proteoglycans which are constitutively secreted from cells are less clear. If cells have no requirement for storage of basic proteins why do they utilise the same design of proteoglycan as cells which accumulate secretory material prior to regulated release? We should stress that the so-called constitutive secretory pathway has been identified in haemopoietic cells in culture, which are usually maintained and grown in the presence of mitogenic factors (e.g., IL-2, IL-3). the cells are therefore activated and it has not been established that continuous proteoglycan secretion occurs in quiescent cells circulating in the peripheral blood. It is possible that lymphocytes, monocytes and macrophages, in which the constitutive secretion pathway operates in vitro, may store proteoglycan in vivo unless stimulated by mitogens or other activating agents.(ABSTRACT TRUNCATED AT 400 WORDS)

Dissociation of the stimulatory activities of staphylococcal enterotoxins for T cells and monocytes

The staphylococcal enterotoxins (SEs) are homologous proteins related in their capacity for stimulating both T cells and monocytes. To assess the importance of conserved structure and sequence to functional activity, the role of the disulfide loop and adjacent sequence in these toxins was evaluated. Contrary to previous reports, we demonstrate here that the disulfide loop was required for the mitogenic activity of SEA and SEB. While T cell-stimulatory activity was compromised, reduced and alkylated SEs retained major histocompatibility complex class II-binding and monocyte-stimulatory activities, suggesting that their inability to induce T cell proliferation was due to failure to interact with T cell receptor (TCR) rather than with class II molecules. Reduction and alkylation did not affect the far-ultraviolet circular dichroic spectrum of SEA, suggesting that the loss of mitogenic activity was not associated with significant changes in secondary structure. The disulfide linkage imparts considerable stability to these toxins as peptide cleavages within the loop of SEB were not associated with detectable loss of function, although cleavage in the conserved sequence outside the loop of SEA resulted in loss of mitogenic activity. This report thus establishes a functional role for a conserved element in SEs, the disulfide loop, and further indicates that their class II- and TCR-binding activities can be dissociated.

MHC class II-associated invariant chain contains a sorting signal for endosomal compartments

The invariant chain (Ii) is a transmembrane protein that associates with the MHC class II molecules in the endoplasmic reticulum. Expression of Ii in MHC class II-negative CV1 cells showed that it acquired complex-type oligosaccharide side chains and was retained in endosomal compartments. To search for a sorting signal, we made progressive deletions from the cytoplasmic N-terminus of Ii. Deleting 11 amino acid residues resulted in a protein that was still sorted and retained in endosomal vesicles, whereas deletion of 15 or more amino acid residues resulted in a protein that became resident in the plasma membrane. Amino acids 12-15 are thus essential for intracellular transport to endosomal compartments. As Ii is intracellularly associated with the MHC class II molecules, it is proposed that Ii determines the intracellular transport route of these molecules.

Invariant chain distinguishes between the exogenous and endogenous antigen presentation pathways

Class I MHC molecules acquire peptides from endogenously synthesized proteins, whereas class II antigens present peptides derived from extracellular compartment molecules. This dichotomy is due to the fact that the invariant chain associates with class II molecules in the endoplasmic reticulum, preventing binding of endogenous peptides. The mutually exclusive binding of peptide and invariant chain to class II molecules suggests that the invariant chain might play a part in autoimmune disease.

The function of the invariant chain in antigen presentation by MHC class II molecules

The existence of different pathways of antigen presentation by class I and class II molecules raises two fundamental questions. (1) Why are class II, but not class I molecules, transported to the endosomal compartment where the exogenous antigen is met? (2) What are the mechanisms that prevent class II molecules from being occupied and blocked by endogenous peptides before they reach endosomes? These and other questions were discussed at the recent 7th International HLA/H-2 Workshop. In round table discussions particular attention was paid to the class-II-associated invariant chain, because it was considered that this molecule was a likely candidate to explain some of the differences of class I and class II molecules in antigen presentation.

Invariant chain trimers are sequestered in the rough endoplasmic reticulum in the absence of association with HLA class II antigens

HLA class II antigens are heterodimeric cell surface glycoproteins that interact with antigenic peptides to form complexes recognizable by CD4-positive T cells. During their biosynthesis, class II antigens are retained in a post-Golgi compartment in association with the invariant chain, which dissociates before class II cell surface expression. To address whether the invariant chain mediates this post-Golgi retention, its transport and assembly were examined in cells that do not express HLA class II antigens. Pulse-chase analysis and endoglycosidase digestions showed that very little invariant chain proceeded as far as the trans-Golgi in class II-negative cell lines. Immunofluorescence studies suggested that in these cells the invariant chain is sequestered in the RER. Gel filtration and cross-linking data showed that RER-localized invariant chain is present as trimers or aggregated trimers. Multimerization is mediated by lumenal interactions; a proteolytic fragment of the invariant chain corresponding to the lumenal domain remained trimeric as determined by cross-linking analysis. Similar transport and structural characteristics were observed for a pool of excess invariant chain in class II-positive cells, suggesting that an excess of invariant chain in the ER may be important for class II antigen function. These results have important implications for the transport of cellular proteins in general and for the role of the invariant chain in class II antigen biosynthesis.

Transcriptional control of the invariant chain gene involves promoter and enhancer elements common to and distinct from major histocompatibility complex class II genes

The invariant chain (Ii) is a glycoprotein coexpressed with the major histocompatibility complex (MHC) class II antigens. Although Ii is encoded by a single gene unlinked to the MHC gene complex, Ii and MHC class II appear to have similar patterns of tissue specific expression and generally are coordinately regulated by cytokines. Here we present evidence that transcription of the murine Ii gene is controlled by multiple cis-acting elements. The 5' regulatory region of the Ii gene appears to be combined of conserved class II regulatory elements with promoter elements commonly found in other eucaryotic genes. A region containing characteristic class II promoter elements (H box, X box, and a modified Y box) serves as an upstream enhancer in the Ii gene and might contribute to the coexpression of MHC class II and Ii genes. A series of positive control elements, the kappa B element, Sp1-binding site, and CCAAT box, are present in the Ii promoter and apparently serve distinct regulatory functions. The kappa B site in the Ii gene is a cell type-specific element, contributing to expression in a B-cell line but not in a fibroblast cell line, and the Sp1 site is required by the H-X-Y' enhancer element to stimulate promoter activity. In addition, an Ii enhancer in the first intron that specifically stimulates its own promoter has been identified. Our results suggest that a sequence match between enhancers and certain promoter elements is critical.

Transcriptional control of the invariant chain gene involves promoter and enhancer elements common to and distinct from major histocompatibility complex class II genes

The invariant chain (Ii) is a glycoprotein coexpressed with the major histocompatibility complex (MHC) class II antigens. Although Ii is encoded by a single gene unlinked to the MHC gene complex, Ii and MHC class II appear to have similar patterns of tissue specific expression and generally are coordinately regulated by cytokines. Here we present evidence that transcription of the murine Ii gene is controlled by multiple cis-acting elements. The 5' regulatory region of the Ii gene appears to be combined of conserved class II regulatory elements with promoter elements commonly found in other eucaryotic genes. A region containing characteristic class II promoter elements (H box, X box, and a modified Y box) serves as an upstream enhancer in the Ii gene and might contribute to the coexpression of MHC class II and Ii genes. A series of positive control elements, the kappa B element, Sp1-binding site, and CCAAT box, are present in the Ii promoter and apparently serve distinct regulatory functions. The kappa B site in the Ii gene is a cell type-specific element, contributing to expression in a B-cell line but not in a fibroblast cell line, and the Sp1 site is required by the H-X-Y' enhancer element to stimulate promoter activity. In addition, an Ii enhancer in the first intron that specifically stimulates its own promoter has been identified. Our results suggest that a sequence match between enhancers and certain promoter elements is critical.

Effect of gamma interferon on HLA class-I and -II transcription and protein expression in human breast adenocarcinoma cell lines

The spontaneous expression of HLA class-I and class-II molecules in 5 human breast carcinoma cell lines, MCF-7, T47D, ZR75-1, HSL-53, MDA-MB 231, and their modulation during IFN-gamma treatment, are reported. The expression of cell-surface determinants was examined by indirect immunofluorescence using monoclonal antibodies (MAbs) specific for HLA class-I and class-II (DR, DQ and DP) antigens. The biosynthesis and maturation of these molecules were analyzed by 2-dimensional gel electrophoresis analysis (2D-PAGE) of class I, DR alpha, beta and invariant immunoprecipitates. Transcription was analyzed by Northern blot hybridization with HLA class-I and -II cDNA-specific probes. In all cell lines, more than 80% of cells expressed HLA class-I antigens at their surface. 2D-PAGE and mRNA studies showed a variable basal level of HLA class-I biosynthesis and transcription with a constant increase after 1,000 U/ml IFN-gamma treatment. HLA class-II determinants were totally absent from the surface of MCF-7, MDA MB231, ZR75-1 and T47D but they were detected in a small subpopulation of HSL-53 cells (DR 6%, DQ 6%, DP 20%). Spontaneous biosynthesis of HLA-DR molecules in immunoprecipitates analyzed by 2D-PAGE or transcripts in Northern blot were not detected in the 5 cell lines. Treatment with 1000 U/ml IFN-gamma induced or increased the expression of HLA class-II molecules in all cell lines but DQ expression was variable. While T47D, ZR75-1 and HSL-53 increased their transcripts and antigen expression, MDA, MB231 and MCF-7 showed no DQ mRNA transcript. Biochemical analysis of the DR products revealed a classical alpha, beta and invariant (li) chain pattern, but indicated a constant glycosylation defect in the invariant chain in all cell lines, associated with weak expression of the beta chain and the presence of an extra spot of low molecular weight in the acidic part of the gel. Thus, post-transcriptional events did not appear to be totally controlled by IFN-gamma in the different cell lines. These differences in DQ expression and glycosylation process in different breast cancer cells may be important in the activation of the immune response among different individuals.

Regulation of the class II-associated invariant chain gene in normal and mutant B lymphocytes

The invariant chain protein is intracellularly associated with class II major histocompatibility proteins. In many cases, the expression of these molecules appears to be regulated in a similar manner. Contained within the promoter of the invariant chain gene are sequences (X and I gamma 1) that are similar to the X and Y box elements of class II genes, suggesting that these sequences might be involved in its regulation. DNase I footprinting reveals additional cis-acting elements (I gamma 2 and I gamma 3) that contain sequence similarities to NF-kappa B and/or H2TF1/KBF1 recognition sequences. A series of fusion constructs with the chloramphenicol acetyltransferase reporter gene were used to analyze the role of these sequences (I gamma 1, I gamma 2, I gamma 3, and X and Y elements) in both normal and mutant B lymphocytes. These data suggest the likelihood of multiple X box proteins in B cells, which can act as both negative and positive regulatory factors.

Invariant chain influences the immunological recognition of MHC class II molecules

Recent experiments have implicated intracellular events in the formation of the MHC class II-peptide complexes recognized by CD4-positive T cells. These data raise the possibility that the intracellular association of class II with the non-polymorphic glycoprotein, invariant chain (Ii), may regulate the interaction between processed antigen and MHC class II molecules. To address this possibility, we have generated a series of transfected fibroblast cell lines that express class II with and without Ii. Although the presence of Ii does not seem to affect the ability of the cells to process and present intact antigen, Ii-negative cells express an altered form of class II at the cell surface. This modified conformation of class II in Ii-negative cells is detectable by an increase in the ability to present antigenic peptides to T cells and a decrease in the binding of several class II-specific monoclonal antibodies.

Biosynthesis and intracellular transport of MHC class II molecules associated with a mutated, glycosaminoglycan-negative invariant chain

The MHC Class II molecular complex is composed of polymorphic alpha and beta chains and a non-polymorphic "invariant" chain (Ii) that can be converted to a chondroitin sulfate proteoglycan. To determine whether the proteoglycan form of invariant chain (Ii-CS) had a role in the expression of the Class II complex, we studied the biosynthetic fate of alpha-beta in cells transfected either with normal Ii cDNA or with a site-directed mutant of Ii (IiAla201) that lacked the site of glycosaminoglycan addition. We had reported [Miller J., Hatch J. A., Simonis S. and Cullen S. E. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 1359-1363] that the mutant protein associated stably with alpha and beta chains, and that it showed charge heterogeneity suggesting some oligosaccharide processing. In this study we demonstrated that the rate and extent of alpha-beta processing and the rate of alpha-beta cell surface expression is the same in the presence of either normal or mutant Ii. Examination of the mutant Ii protein itself revealed normal transport through different processing compartments, as evidenced by the addition of fatty acid and by maturation of N-linked oligosaccharides. Moreover, though the rate of conversion of IiAla201 into more processed forms was slower in the absence of alpha-beta than in its presence, this was also typical of the wild type invariant chain. The ability to alter glycosaminoglycan addition without significantly disturbing other processing events or trafficking should allow a rigorous assessment of the impact of glycosaminoglycan addition on Class II function.

Isolation of early immunoglobulin lambda-like gene transcripts in human fetal liver

In an attempt to identify early events of human Ig gene expression, we have screened a human fetal liver cDNA library (less than 90 days of gestation) with C mu-, C gamma-, C kappa-, C lambda-specific probes and we report the characterization of two clones, F lambda 1 and F lambda 8, that hybridized with a human C lambda gene. These two clones, which are only 85% homologous to the functional C lambda genes, were shown to be additional nonallelic members of the 14.1/16.1 C lambda-like family. Using pulsed field gel electrophoresis these three C lambda-like genes were shown to be present on a 200-kb DNA fragment, defining a cluster distinct from that of the C lambda one. F lambda 1 and F lambda 8 contained an identical C lambda-like region, and differed from each other by a splicing event which joins a J lambda-like to the C lambda-like exon in the F lambda 1 clone in the absence of any rearrangement. Homologies observed between F lambda 1 and the mouse lambda 5 gene suggest that this human clone may contain the exon 2 and 3 equivalents of lambda 5. Since lambda 5 is selectively expressed in pre-B cells, our proposal is also supported by the early expression of this clone, together with the presence of full-length mu and gamma transcripts and the absence of functional Ig light chain transcripts. The presence of one nucleotide deletion in the C region of F lambda 1 conferring it a pseudogene status, the actual lambda 5 equivalent might be either one of the 14.1 or 16.1 human C lambda-like genes, the function of which is so far unknown.

Class II MHC molecules are specific receptors for staphylococcus enterotoxin A

T cell proliferation in response to stimulation with Staphylococcus enterotoxin A (SEA) requires accessory cells that express class II major histocompatibility complex (MHC) molecules. Murine fibroblasts transfected with genes encoding the alpha and beta subunits of HLA-DR, DQ, or DP were used to show that the proliferative response of purified human T cells to SEA is dependent on class II molecules but is not restricted by the haplotype of the responder. Binding of fluoresceinated SEA to class II transfectants and precipitation of class II heterodimers with SEA-Sepharose show that the proliferative response is a result of SEA binding to class II molecules. The binding is specific for class II molecules and is independent of class II allotype or isotype. The ability of SEA to bind class II molecules may be a general characteristic of this class of antigens, now called "superantigens".

HLA class II-restricted presentation of cytoplasmic measles virus antigens to cytotoxic T cells

To analyze the nature of the HLA class II-restricted cytotoxic T-lymphocyte (CTL) response to measles virus, murine fibroblasts were transfected with expressible cDNA clones for human HLA-DR antigen and for measles virus matrix or nucleocapsid proteins. DR-positive murine fibroblasts transfected with measles virus matrix or nucleocapsid genes were lysed by class II-restricted measles virus-specific CTL lines. Lysis was as efficient as with infected autologous B-cell lines, even though the measles virus cytoplasmic proteins were undetectable by antibodies in the transfected target cells. These results demonstrate that cytoplasmic viral antigens can be presented to CTL in the context of HLA class II antigens and that measles virus matrix and nucleocapsid proteins contribute to class II-restricted measles virus-specific CTL responses. These results also show that endogenously synthesized measles virus proteins can be efficiently presented by class II antigens. The implications of these findings for measles virus pathogenesis and for antigen processing are discussed.

A role of Ia-associated invariant chains in antigen processing and presentation

Most native antigens require processing in a cellular compartment for efficient presentation to T helper cells. The cellular elements that permit processing are not known. We investigated a possible role of the class II MHC-associated invariant chains in antigen processing. Fibroblast cells that were transfected with class II genes were compared with fibroblasts supertransfected with the invariant chain gene for their capacity to present the fifth component of complement (C5) to C5-specific class II restricted T cell clones or influenza virus protein to a virus-specific T cell clone. Only fibroblasts supertransfected with the invariant chain gene were able to present native antigen, even at very low antigen concentration, whereas both fibroblast types could present cyanogen bromide-fragmented C5 or the virus peptide. Presentation of intact antigen but not of fragmented antigen was totally abrogated by treatment of fibroblasts with chloroquine. The invariant chain gene encodes two polypeptides, li31 and li41. Expression of either li31 or li41 was sufficient to render class II-expressing fibroblasts capable of presenting intact antigen.

Translation in Xenopus laevis oocytes of hybrid selected LEW rat RT1.B alpha- and beta-chain transcripts results in serologically discrete class II polypeptide chain complexes

Using the non-crossreactive mAb MRC-OX3 and MRC-OX6, two serologically distinct RT1.B-specific (I-A equivalent) alpha, beta heterodimers have previously been described by us as residing at the cell surface of LEW rat spleen cells. The two-chain elements were suggested to represent stable conformation isomers, diverged by dissociation of the mature gamma-chain from a mAb MRC-OX6 reactive biosynthetic intermediate, composed of terminally glycosylated alpha-, beta- and gamma-chains. In this study we addressed the question of whether or not the presence of terminally glycosylated invariant gamma-chain was obligatory for the formation of the two MRC-OX3 and MRC-OX6 reactive two-chain complexes. The synthesis of RT1.B-specific alpha, beta heterodimers was therefore initiated, in the absence of accompanying invariant gamma-chains, by microinjecting hybrid-selected RT1.B alpha- and beta-specific mRNA into oocytes of Xenopus laevis for translation. Class II molecules produced were analyzed by affinity chromatography of radioactive-labeled oocyte detergent lysates using the appropriate monoclonal immunoadsorbents for identification. Although rat gamma-chain mRNA was excluded in this assay system, distinct MRC-OX3 and MRC-OX6 reactive two-chain complexes were detected by two-dimensional gel electrophoresis. These findings clearly indicate that the formation of the two RT1.B-specific alpha, beta heterodimers is independent of the presence of the rat invariant gamma-chain.