Evolutionary origin and diversification of the mammalian CD1 antigen genes.

CD1 antigens are cell-surface glycoproteins which have a molecular structure which is similar (consisting of extracellular domains alpha 1, alpha 2, and alpha 3, a transmembrane portion, and a cytoplasmic tail) to that of class I MHC molecules. Phylogenetic analysis of mammalian CD1 DNA sequences revealed that these genes are more closely related to the class I major histocompatibility complex (MHC) than to the class II MHC and that mammalian genes are more closely related to avian class I MHC genes than they are to mammalian class I MHC genes. The CD1 genes form a multigene family with different numbers of genes in different species (five in human, eight in rabbit, and two in mouse). Known CD1 genes are grouped into the following three families, on the basis of evolutionary relationship: (1) the human HCD1B gene and a partial sequence from the domestic rabbit, (2) the human HCD1A and HCD1C genes, and (3) the human HCD1D and HCD1E genes plus the two mouse genes and a sequence from the cottontail rabbit. The alpha 1 and alpha 2 domains of CD1 are much less conserved at the amino acid level than are the corresponding domains of class I MHC molecules, but the alpha 3 domain of CD1 seems to be still more conserved than the well-conserved alpha 3 domain of class I MHC molecules. Furthermore, in the human CD1 gene family, interlocus exon exchange has homogenized alpha 3 domains of all CD1 genes except HCD1C.     

Alpha chain of HLA-DR transplantation antigens is a member of the same protein superfamily as the immunoglobulins

Four cDNA clones, pDR-α-1, pDR-α-2, pDR-α-3 and pDR-α-4, corresponding to the alpha chain of HLADR antigens, have been sequenced. Restriction maps and sequences suggest that all clones are identical apart from a single-base substitution present in pDR-α-1. Amino acid sequence data, together with the nucleotide sequence data, allowed the complete amino acid sequence to be predicted. The alpha chain is composed of 229 amino acids, of which 191 are exposed on the outside of the plasma membrane. The membrane-embedded portion of the chain consists of 23 hydrophobic amino acids. The succeeding 15 amino acids form the cytoplasmically localized hydrophilic tail. The extracellular portion, with carbohydrate moieties linked to Asn⁷⁸ and Asn¹¹⁸, seems to be organized into two domains. The second domain, which contains the only disulfide bond of the alpha chain, displays amino acid sequence homology to immunoglobulin constant regions, to the second domain of the beta chain of a class II antigen, to the third domain of heavy chains of class I antigens and to β2-microglobulin. Thus the subunits of immunoglobulins, class I antigens and class II antigens are related evolutionarily.     

Structure, specificity and CDR mobility of a class II restricted single-chain T-cell receptor.

Using NMR spectroscopy, we determined the solution structure of a single-chain T-cell receptor (scTCR) derived from the major histocompatibility complex (MHC) class II-restricted D10 TCR. The conformations of complementarity-determining regions (CDRs) 3beta and 1alpha and surface properties of 2alpha are different from those of related class I-restricted TCRs. We infer a conserved orientation for TCR V(alpha) domains in complexes with both class I and II MHC-peptide ligands, which implies that small structural variations in V(alpha) confer MHC class preference. High mobility of CDR3 residues relative to other CDR or framework residues (picosecond time scale) provides insight into immune recognition and selection mechanisms.     

Role of oncogenes in the regulation of MHC antigen expression.

Class I and class II major histocompatibility complex (MHC) antigens are required for CD8+ cytotoxic T cells and CD4+ helper T-cells, respectively, to recognize foreign antigen. Regulating the levels of expression of these MHC antigens regulates the T-cell responses [1]. This regulation is mainly carried out by the interferons (IFN), which are produced in the disease state. Type I IFN (IFN alpha or IFN beta; collectively 'IFN alpha beta) up-regulates class I MHC and IFN gamma up-regulates class I and class II MHC. We and others [1-3] have shown that transfection of cells with a variety of oncogenes including ras and myc affects the level of MHC antigen expression. This and other data provide evidence for a scheme in which the signal transduction mechanisms whereby IFN up-regulates MHC antigens involve several (proto) oncogenes.     

Analysis of the rat major histocompatibility system by Southern blot hybridization

The organization of the rat major histocompatibility complex, RT1, was studied at the DNA level by Southern blot hybridization. Genomic DNA from eight different RT1 congenic rat strains was digested by various restriction enzymes and was hybridized under stringent conditions with probes of mouse class I and class II H-2 genes. Few cross-hybridizing DNA fragments, showing no polymorphism, were seen with class II A alpha and A beta probes. The class I probes allowed for the distinction of about 8 to 19 cross-hybridizing bands, which exhibited extensive polymorphism. With the use of five RT1 recombinants, about 20% of the DNA fragments could be mapped to the RT1.A region, which codes for the ubiquitously expressed class I antigens, and about 80% to the RT1.C region-determining class I-like antigens, which are different from RT1.A antigens with respect to tissue distribution, restriction function in immune responses, and allograft rejection. The number of class I genes present in the rat genome and the possible relationship of RT1.C to H-2Qa, Tla of the mouse are discussed.     

The E3/19K protein of adenovirus type 2 binds to the domains of histocompatibility antigens required for CTL recognition

The E3/19K protein of human adenovirus type 2 binds to HLA class I antigens and blocks their terminal glycosylation and cell surface expression. The nature of this interaction is non-covalent and involves neither disulfide bridges between the two molecules nor their carbohydrates. The murine H-2 Kd antigen associates with the E3/19K protein in a similar fashion to human HLA antigens whereas the allelic product H-2 Kk does not. Hybrid genes between the Kd and Kk alleles were constructed and their products were expressed in embryonic kidney cells together with the E3/19K protein. This allowed us to identify the alpha 1 and alpha 2 domains as the essential structures of the histocompatibility antigens for binding the viral protein. Interestingly, these domains are also crucial for T cell recognition. The implications for the evolution of adenoviruses and their ability to cause persistent infections are discussed.     

Proteolysis of the heavy chain of major histocompatibility complex class I antigens by complement component C1s.

The major histocompatibility complex (MHC) class I antigens contain a light chain, beta 2-microglobulin, non-covalently associated to the transmembrane heavy alpha-chain carrying the allotypic determinants. Since the C1q complement component is known to associate with beta 2-microglobulin, and we recently found that activated C1s complement was capable of cleaving beta 2-microglobulin, we decided to investigate the proteolytic activity of C1 complement towards the heavy chain of class I antigens. Our results demonstrate that human C1s complement cleaves the heavy chain of human class I antigens into at least two fragments, with apparent molecular weights of 22,000 and 24,000 g/mol on sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE), under both reducing and non-reducing conditions. The cleavage of the heavy chain is inhibited by the presence of C1 esterase inhibitor. The molecular weights of the fragments are in agreement with the cleavage located in the area between the disulphide loops of the alpha 2-and alpha 3-domains of the heavy chain. In addition human C1s complement is able to cleave H-2 antigens from mouse in a similar fashion but not rat MHC class I antigen or mouse MHC class II antigen (I-Ad). Mouse MHC class I antigen-specific determinants could also be detected in supernatant from mouse spleen cells incubated with C1r and C1s. These results indicate the presence in the body fluids of a non-membrane-bound soluble form of the alpha 1-and alpha 2-domains which represent the binding site for antigenic peptides.     

Design, engineering and production of functional single-chain T cell receptor ligands.

Major histocompatibility complex (MHC) class II molecules are membrane-anchored heterodimers on the surface of antigen presenting cells (APCs) that bind the T cell receptor, initiating a cascade of interactions that results in antigen-specific activation of clonal populations of T cells. The peptide binding/T cell recognition domains of rat MHC class II (alpha-1 and beta-1 domains) were expressed as a single exon for structural and functional characterization. These recombinant single-chain T cell receptor ligands (termed 'beta1alpha1' molecules) of approximately 200 amino acid residues were designed using the structural backbone of MHC class II molecules as template, and have been produced in Escherichia coli with and without N-terminal extensions containing antigenic peptides. Structural characterization using circular dichroism predicted that these molecules retained the antiparallel beta-sheet platform and antiparallel alpha-helices observed in the native MHC class II heterodimer. The proteins exhibited a cooperative two-state thermal folding-unfolding transition. Beta1alpha1 molecules with a covalently linked MBP-72-89 peptide showed increased stability to thermal unfolding relative to the empty beta1alpha1 molecules. This new class of small soluble polypeptide provides a template for designing and refining human homologues useful in detecting and regulating pathogenic T cells.     

A role for calnexin (IP90) in the assembly of class II MHC molecules.

Major histocompatibility complex (MHC) class II antigens consist of alpha and beta chains that associate intracellularly with the invariant (I) chain. The HLA-DR alpha beta I complex assembles in the endoplasmic reticulum (ER) into a nonameric structure via progressive addition of three alpha beta dimers to a core invariant chain trimer. We have examined intracellular association of alpha beta I complexes with the resident ER protein calnexin. Calnexin associates rapidly (within 3 min) with newly synthesized alpha, beta and I chains, and remains associated with the assembling alpha beta I complex until the final alpha beta dimer is added, forming the complete nonamer. Dissociation of calnexin parallels egress of alpha beta I from the ER. These results suggest that calnexin retains and stabilizes both free class II subunits and partially assembled class II-I chain complexes until assembly of the nonamer is complete.     

Variability and conformation of HLA class I antigens: a predictive approach to the spatial arrangement of polymorphic regions

Comparison of available sequences of HLA-A and HLA-B antigens shows that variable positions are predominantly localized in four segments spanning residues 63-85, 105-116, 138-156, and 177-194. The fourth segment is unique in that it contains no differences between antigens of the same locus. Secondary folding of HLA heavy chain was estimated by three independent predictive methods and areas of defined structure were correlated with the distribution of local hydrophobicity to outline putative internal and external portions. The three analyses each independently predict a high probability for beta structure in the alpha 1, alpha 2, and alpha 3 domains. A single alpha-helix is predicted within residues 146-160, a segment of likely importance in cytotoxic T cell recognition and graft rejection. Substitutions within this segment are spatially related by the helical turn. Variable residues usually lie in areas of high local hydrophilicity, and therefore they are probably on the surface of the molecule. The model predicts that they are frequently located in beta strands, beta-turns, or the above-mentioned alpha-helix, so that most substitutions would be accommodated within rigid frameworks that may impose structural constraints to variability. The secondary structure of alpha 1, alpha 2, and alpha 3 domains presents some analogies that suggest that they might share common features in their tertiary folding. The predicted structure of alpha 3 is strongly reminiscent of that of immunoglobulin constant domains. Possible arrangements of elements of secondary structure are discussed, as an attempt to situating the polymorphic regions of HLA class I antigens in a spatial context.     

The T cell repertoire may be biased in favor of MHC recognition

The receptors of two T cell hybridomas that recognize class I and class II major histocompatibility complex (MHC) molecules, respectively, have been compared. In both cases these receptors are hybrid molecules formed as a result of cellular fusion. The receptors contain the same alpha chain, contributed by the tumor cell fusion partner, and related beta chains, contributed by the normal T cell component. Thus, surprisingly, the same alpha chain can contribute to recognition of class I and class II MHC molecules. Moreover, the finding that in two independent examples hybrid receptor molecules created randomly by in vitro cell fusion recognize MHC supports the theory that the T cell repertoire has an intrinsic affinity for MHC.     

Superantigens interact with MHC class II molecules outside of the antigen groove

Superantigens, including the staphylococcal enterotoxins and the minor lymphocyte stimulatory antigens, are highly potent immunostimulatory molecules, capable of activating virtually all T cells that express particular T cell receptor (TCR) variable regions. Superantigen stimulation of T lymphocytes depends on major histocompatibility complex (MHC) class II molecules, so there has been some debate as to whether superantigens interact with the antigen binding "groove" on class II complexes, just like conventional peptide antigens, or whether they bind elsewhere and serve as TCR coligands. We compared the presentation of peptide antigens and superantigens by a panel of mutant-presenting cell lines, each displaying an A kappa alpha chain with a single alanine replacement along the alpha helix proposed to form one face of the groove. The negligible effect of these 30 mutations on superantigen presentation, versus their drastic consequences for peptide presentation, prompts us to conclude that superantigens interact with MHC class II molecules outside the groove.     

The structure of the mouse immunoglobulin in gamma 3 membrane gene segment

The genomic region containing the mouse immunoglobulin gamma 3 heavy chain membrane (M) exons has been located and sequenced. The exon structure is highly similar to that of the other mouse gamma chains, with strong sequence conservation in the coding regions and the intron 5' to the M1 exon. The intron between M1 and M2 shows moderate sequence homology but very strong conservation of size. RNA blots suggest that gamma 3 membrane exon usage is similar to that seen in other immunoglobulin membrane heavy chain mRNAs. The transmembrane region contains the invariant residues which have been noted in all other heavy chain sequences and which were previously proposed to be interactive in a two-chain model for insertion through the lymphocyte membrane. Conserved residues with similar spacing have been seen in class II histocompatibility antigens, which are also two-chain transmembrane molecules, but not in class I antigens, which span cell membranes with a single chain.     

Evolutionary Development of the Immunoglobulin Family

The origin of the ability of immunoglobulins (Ig) and T-cell receptors (TCRs) to specifically recognize antigens is related to the evolutionary development of proteins of the immunoglobulin superfamily (IgSF). The IgSF proteins are characterized by specific domain organization of molecules and statistically significant homology with known Ig. Four types of Ig domains (V1, V2, C1, and C2), differing from one another both in variations of their spatial organization and in the number of amino acid residues have been distinguished. Immunoglobulin superfamily comprises Ig; TCRs; class I and II major histocompatibility complex (MHC) molecules; one-domain proteins of thymocytes and T-cells (Thy-1); myelin protein P₀; ₂-microglobulin; two-domain proteins, such as sponge receptor tyrosine kinase (RTK), sponge adhesive protein (SAP), Drosophila tyrosine-kinase receptor (DTCR), Xenopus and human cortical-thymocyte receptors (CTX and CTH), etc.; and a large group of adhesins, coreceptors, and Ig receptors with varying number of domains. Evolutionary development of IgSF began with the evolvement of chaperones, Thy-1, and P₀ of prokaryotes and unicellular eukaryotes. Mutations, duplications, and translocations of the genes controlling both V and C domains yielded proteins with different numbers and combinations of these domains. All IgSF proteins are divided into two groups. The first group includes the proteins with nonrearranging V2 domains and homophilic mode of interaction; the second, the proteins with rearranging V1 domains and heterophilic mode of interaction (Ig, TCRs). The ability for heterophilic antigen-binding mode of interaction was apparently acquired due to the introduction of recombination-activating retroviral genes (RAG1 and RAG2) into the genome of Gnathostomata ancestors.     

The Eb beta gene may have acted as the donor gene in a gene conversion-like event generating the Abm 12 beta mutant

At least two different class II histocompatibility antigens, I-A and I-E, are encoded by the murine major histocompatibility complex. Both types of class II antigens are composed of polypeptide chains called alpha and beta. Class II antigens display extensive genetic polymorphism, the main part of which resides in the NH2-terminal domains of the A alpha, A beta and E beta chains. Recently it was shown that the mutant gene Abm 12 beta differed from the wild-type gene Ab beta by three nucleotide substitutions, which all occur within a stretch of 14 nucleotides. Multiple substitutions of the type found in the Abm 12 beta gene suggest that the mutant arose by a gene conversion-like event. To examine whether the Eb beta gene may have served as the donor gene in the generation of the Abm 12 beta gene, we have isolated and sequenced a cDNA clone corresponding to the Eb beta gene. Comparisons of the Eb beta, the Ab beta and the Abm 12 beta nucleotide sequences revealed that the Eb beta sequence is identical to that of Abm 12 beta in the positions where the latter differs from the Ab beta sequence. This observation is consistent with the notion that the Abm 12 beta mutant gene arose by a gene conversion-like event involving the Eb beta gene.     

The subunit structure of the insulin receptor and molecular interactions with major histocompatibility complex antigens

Insulin receptors were labeled with 125I-photoreactive insulin (specifically labeling alpha-subunits) and by insulin-stimulated autophosphorylation (specifically labeling beta-subunits). The results show that the insulin receptor exists under different free and disulfide-linked combinations of alpha and beta subunits. Moreover, the insulin receptor is closely associated to class I antigens of the major histocompatibility complex to form a high molecular weight multi-molecular membrane complex.     

An MHC interaction site maps to the amino-terminal half of the T cell receptor alpha chain variable domain.

We have used cloned T cell receptor (TCR) genes from closely related CD4 T cell lines to probe the interaction of the TCR with several specific major histocompatibility complex (MHC) class II ligands. Complementarity determining region 3 (CDR3) equivalents of both alpha and beta TCR chains are required for antigen-MHC recognition. Our data provide novel information about the rotational orientation of TCR-MHC contacts in that exchange of the amino terminal portion of the TCR alpha chain containing the putative CDR1 and CDR2 regions results in both gain and loss of MHC class II specificity by the resulting receptor. These two TCRs differ primarily in recognition of polymorphisms in the second hypervariable region of the MHC class II alpha chain. These results document the involvement of CDR1 and/or CDR2 of the TCR alpha chain in MHC recognition and suggest a rotational orientation of this TCR to its MHC ligand.     

Immune interferon suppresses levels of procollagen mRNA and type II collagen synthesis in cultured human articular and costal chondrocytes

Cultured human articular and costal chondrocytes were used as a model system to examine the effects of recombinant gamma-interferon (IFN-gamma) on synthesis of procollagens, the steady state levels of types I and II procollagen mRNAs, and the expression of major histocompatibility complex class II (Ia-like) antigens on the cell surface. Adult articular chondrocytes synthesized mainly type II collagen during weeks 1-3 of primary culture, whereas types I and III collagens were also produced after longer incubation and predominated after the first subculture. Juvenile costal chondrocytes synthesized no detectable alpha 2(I) collagen chains until after week 1 of primary culture; type II collagen was the predominant species even after weeks of culture. The relative amounts of types I and II collagens synthesized were reflected in the levels of alpha 1(I), alpha 2(I), and alpha 1(II) procollagen mRNAs. In articular chondrocytes, the levels of alpha 1(I) procollagen mRNA were disproportionately low (alpha 1(I)/alpha 2(I) less than 1.0) compared with costal chondrocytes (alpha 1 (I)/alpha 2(I) approximately 2). Recombinant IFN-gamma (0.1-100 units/ml) inhibited synthesis of type II as well as types I and III collagens associated with suppression of the levels of alpha 1(I), alpha 2(I), and alpha 1(II) procollagen mRNAs. IFN-gamma suppressed the levels of alpha 1(I) and alpha 1(II) procollagen mRNAs to a greater extent than alpha 2(I) procollagen mRNA in articular but not in costal chondrocytes. Human leukocyte interferon (IFN-alpha) at 1000 units/ml suppressed collagen synthesis and procollagen mRNA levels to a similar extent as IFN-gamma at 1.0 unit/ml. In addition, IFN-gamma but not IFN-alpha induced the expression of HLA-DR antigens on intact cells. The lymphokine IFN-gamma could, therefore, have a role in suppressing cartilage matrix synthesis in vivo under conditions in which the chondrocytes are in proximity to T lymphocytes and their products.     

Production and characterization of alloantisera specific for bovine class II major histocompatibility complex antigens

Ten alloantisera defining five major histocompatibility complex (MHC) class II specificities of the bovine lymphocyte antigen (BoLA) complex were produced and characterized. Eight antisera defining four of the specificities were generated by immunizing cattle with class I compatible-class II incompatible lymphocytes. The alloantiserum defining the fifth class II specificity was produced by skin implant immunization. A pregnancy serum specific for one of the class II specificities was also identified. The class II antigens recognized by these antisera were designated 'Dx' antigens to indicate that they are BoLA-D region antigens encoded by one or more undetermined class II loci. The molecules identified by the alloantisera are heterodimers composed of a 34-kd alpha and a 26- to 28-kd beta chain, and are expressed on B-lymphocytes but not on resting T-lymphocytes. In family studies the BoLA-Dx antigens segregated in linkage with the BoLA-A locus alleles. Most of the BoLA-A alleles present in the Cornell Holstein herd at a high frequency were found to exist in gametic association with two or more serologically defined class II haplotypes. On the basis of a population study it was determined that three pairs of class I and class II alleles (w10-Dx4, w31-Dx5, and c3-Dx2) were present in the Cornell herd at significantly increased frequencies.