Conservation of immunoglobulin variable and joining region structure and the design of universal anti-immunoglobulin antibodies reactive with antigen-binding T cell receptors

Physical and epitope analysis of a recombinant human T-cell receptor V alpha/V beta construct support the similarity to immunoglobulin

The genetic organization and protein structure of T-cell receptors (TCR) and immunoglobulins (Ig) are remarkably similar. Through recombinant, physical, and peptide-based immunological studies we demonstrated that rabbit antisera generated against a recombinant single-chain TCR (scTCR) react with defined peptide epitopes of their constituent TCR alpha and beta chains. These antisera cross-react with the lambda light-chain Mcg as well as with peptides duplicating its covalent structure. Conversely, rabbit antisera generated to human lambda light chains cross-reacted with the recombinant scTCR. Rabbit anti-lambda antibodies purified on an scTCR affinity column bound to T-cell lines and to T and B lymphocytes from peripheral blood. Circular dichroism analysis demonstrated plots characteristic of beta-sheets for both Mcg and recombinant scTCR. Antisera directed against TCR alpha-chain synthetic peptides reacted with scTCR, Mcg lambda light-chain protein, synthetic peptides from regions of sequence homology in beta-chains, and Mcg. Based upon this homology and the serological cross-reactions which reflect conformational determinants, we suggest that the V alpha/V beta antigen-binding domain of this particular monoclonal scTCR construct is substantially similar to the conformational structure of lambda light chains.

Autoantibodies to the alpha/beta T-cell receptors in human immunodeficiency virus infection: dysregulation and mimicry

Autoimmune reactivity is a consequence of infection with human immunodeficiency virus (HIV). We studied serological cross-reactions of purified pooled IgG from sera of HIV-infected individuals by using nested sets of synthetic overlapping peptides duplicating the covalent structures of T-cell receptors (TCRs) and immunoglobulin light chains and report that two processes of autoantibody production occur. (i) IgG autoantibodies to putative regulatory variable domain CDR1 and FR3 epitopes (where CDR is complementarity-determining region and FR is framework region) are present in pooled IgG from HIV-infected individuals at levels 10-fold greater than that in pooled IgG from healthy humans. (ii) Anti-TCR autoimmunization involves antigenic mimicry between a conserved peptide stretch of the major neutralizing V3 loop determinant of HIV-1 gp120 and the conserved FR4 segment of the TCR V beta. Affinity-purified antibodies to the synthetic V3 loop peptide bound to a recombinant single-chain TCR and to a synthetic TCR joining segment peptide containing the FR4 sequence. Conversely, affinity-purified autoantibodies from pooled IgG from HIV-infected individuals to the TCR peptide bound the V3 loop peptide and a single-chain TCR. Inhibition studies indicated that the cross-reactive immunizing antigen was the V3 loop. These results bear upon the impact of HIV infection on immune regulation and on the selection of peptides for vaccine development.

Cell surface recognition and the immunoglobulin superfamily

Immunoglobulins serve as humoral recognition and effector molecules and as antigen-specific cell surface receptors on B and T cells. These molecules are constructed according to a characteristic domain pattern. Variable and constant domains diverged from one another early in vertebrate evolution, and they are joined by a "switch peptide" specified by the joining gene segments. Peptides specified by J-gene segments are strongly conserved in evolution in comparison among Ig light chains and T-cell receptors. Molecules less strongly related to Ig domains have been assembled into an Ig "superfamily" where the identities to classical IgC or V domains are < or = 20%. Among these are cell surface adhesion molecules, receptors for cytokines, and Fc receptors. Moreover, MHC antigens have an Ig-like membrane-proximal domain significantly related to IgC regions. We will analyze putative evolutionary relationships among canonical Igs and members of the Ig superfamily using highly conserved sequences from light and heavy chains of primitive vertebrates (e.g., the sandbar shark) as prototypes to ascertain similarities between Ig-related molecules of vertebrates and invertebrates.

Shared antigenic determinants of immunoglobulins in phylogeny and in comparison with T-cell receptors

1. Immunoglobulins are a complex multigene family of proteins specified by genes encoding variable (V), sometimes diversity (D), joining (J), and constant (C) domains. 2. Cross-reactions involving conformational determinants related to the VHa system of rabbits occur on heavy chains of vertebrate species ranging from elasmobranchs to man. 3. Serological markers characteristic of mu chains, the heavy chain of the IgM macroglobulins, occur on homologous heavy chains of species representing all vertebrate classes. 4. Serological markers characteristic of gamma type heavy chains, the major isotype in man, are restricted to the mammals, but are found on representatives of even the most primitive mammals, the egg-laying monotremes. 5. Variable region markers characteristic of lambda light chains are shared by light chains of shark and man. 6. Certain idiotypic markers defined by combining site V region sequences are broadly distributed in evolution. 7. Use of synthetic peptides as antigens and in epitope mapping show that amino acid sequences from the third framework region of the variable domain are broadly shared among light chain in phylogeny and between light chains and T-cell receptor beta chains. 8. The "switch peptides" linking the V and C domains of light chains and T-cell receptors, specified by the C-terminal portion of the J segment and the N-terminus of the constant region, are exposed in the three-dimensional structure of immunoglobulin or Tcrs, show striking homology, and form broadly shared antigenic determinants characteristic of immunoglobulins. 9. Although the multigene nature of the immunoglobulins and the complexity of antigenic determinants expressed by these large proteins renders comparison among molecules difficult, serum immunoglobulins and the closely related T-cell receptors express numerous shared determinants defined on the basis of amino acid sequence homology and three-dimensional conformations.

Antigenic cross-reactions among immunoglobulin of diverse vertebrates (elasmobranchs to man) detected using xenoantisera

1. Antisera raised in rabbits and goats against intact immunoglobulins or their constituent light and heavy chains from man, mouse and the galapagos shark (Carcharhinus galapagenesis) were tested for their reactivity with immunoglobulins of elasmobranchs, other lower vertebrates and eutherian and prototherian mammals. 2. Xenoantisera directed against human heavy chain isotypes allowed the serological identification of IgM and IgG immunoglobulins in the echidna (Tachyglossus aculeatus), a monotreme which is one of the most primitive species of extant mammals. 3. The antisera to heavy chains reacted to varying degrees with purified immunoglobulins of non-mammalian species, including the chicken, teleost fish and elasmobranchs in a fashion that was specific for immunoglobulins, but was not related to defined human isotypic markers. 4. The reactions of some antisera seem to skip species known to possess homologous immunoglobulins. 5. Antisera directed against isotypic markers of human kappa and lambda light chains reacted with shark light chains in a manner that was specific for light chain determinants but was not isotype-related. 6. Antisera directed against heavy chains of either sharks or mammals reacted with heavy chains, but not with light chains of diverse species. 7. A rabbit antiserum specific for shark light chain reacted with human and murine monoclonal lambda chains and with two synthetic peptides corresponding to human V lambda Fr3 and Fr4 sequences. 8. These results establish that a variety of antigenic markers including conformational and linear determinants can be shared among immunoglobulins of vertebrates species that had an ancestral divergence more than 400 million years ago.

Evolution of immunoglobulin light chains: cDNA clones specifying sandbar shark constant regions

Sharks are living fossils that are indistinguishable morphologically from their Devonian ancestors of approximately equal to 400 million years ago. If parallel conservatism characterizes their biochemical evolution, characterization of their immunoglobulin chains could provide information regarding the primordial features of these essential defense molecules. Shark immunoglobulins are polydisperse like those of mammals, but these species lack homogeneous myeloma proteins. This heterogeneity has precluded direct determination of the sequence of elasmobranch light-chain proteins. We have sequenced four cDNA clones that contain the constant-region sequence as well as varying degrees of variable- or joining-region segments. The sandbar shark (Carcharhinus plumbeus) has at least four distinct light-chain constant regions, and these can be considered homologs of mammalian lambda chains. Approximately 40% identity was found in comparison from sharks to mammals. Certain stretches of sequence were remarkably conserved, whereas others varied in a manner consistent with accepted concepts of speciation. One hexapeptide (Ala-Thr-Leu-Val-Cys-Leu) occurred in lambda constant regions of all vertebrate species. There was a universal conservation of certain cysteines, phenylalanines, tryptophans, and glycines and strong identities in the block of residues from Ser-176 to Trp-186. Comparison of the shark sequence with that of the characterized human lambda myeloma protein Mcg indicates a strong conservation of three-dimensional structure in this light-chain domain representing species whose ancestors diverged early in vertebrate evolution. The shark light-chain sequence contains primordial features shared by mammalian kappa and lambda chains and by T-cell receptor beta chains.

Solid-phase antigen binding by purified immunoproteins from antigen-specific monoclonal T cell hybridomas

We have developed two distinct solid-phase immunoassays for the detection of antigen binding activity by products of antigen binding T cell hybridomas in the absence of MHC. Two suppressor T cell hybridomas studied (34s-18 and 34s-704) are specific for keyhole limpet hemocyanin, a protein antigen, and the other suppressor T cell hybridoma (51H7D) binds specifically to the arsonate hapten. We have adapted these hybridomas to growth in serum-free medium and have isolated molecules with antigen binding activity both from the cell membranes and from the culture fluid in which the cells had been grown. The antigen binding molecules (ABM) produced by the KLH-specific hybridomas bound best to native hemocyanin; binding was decreased when KLH was denatured by reduction and alkylation and no binding was found to an arthropod (Limulus) hemocyanin. The arsonate binding hybridoma, on the other hand, produced molecules specific for this hapten; they showed no capacity to bind KLH. The antigen binding molecules affinity-purified from all three T hybridomas have intact masses of either 145,000, 67,000 or 48,000 when run in SDS-PAGE under non-reducing conditions. Following reduction, ABM resolve in SDS-PAGE into a complex of polypeptide chains having apparent masses of 65,000, 56,000 and 49,000, with either a pair of bands at 26,000 and 22,000, or with a single band at 32,000, which is consistent with the size of translation products of mRNA previously isolated from these hybridomas. Two of the hybridomas, 34s-18 and 34s-704, used for isolation of antigen binding products in this study, were previously reported to lack detectable rearranged gamma or beta genes and therefore to lack expression of the alpha/beta or gamma/delta heterodimers. The antigen binding molecules react in solid-phase immunoassay with some antibodies specific for variable (first framework) region and joining (J) region peptide sequences predicted from T cell receptor gene sequence. Furthermore, the affinity-purified antigen binding molecules from mouse T cell hybridomas cross-react in ELISA with goat anti-rabbit IgG and not with protein G, thus allowing the use of these commercially available reagents in standard laboratory assays. Interestingly, ABM anchored in intact cell membranes, which could be shown to specifically bind antigen, did not cross-react with goat anti-rabbit IgG, indicating that the cross-reactive moiety is not detectable when the ABM are in this situation.(ABSTRACT TRUNCATED AT 400 WORDS)

Antibodies to synthetic peptides corresponding to variable-region first-framework segments of T cell receptor. Detection of T cell products and cross-reactions with classical immunoglobulins

Recent studies at the gene level have shown that T cells express rearranged genes for four types of T cell receptors that are strongly homologous to classical immunoglobulins in the joining region and in the framework 1 (Fr1) and 3 segments of the variable region. Based upon the homologies in gene sequence, it follows that the gene products would show similarities in amino acid sequence and in the folding of the proteins so that cross-reactivities in antigenic determinants would be expected between variable regions of the T cell receptors and classical immunoglobulins. We have synthesized peptides corresponding to predicted protein sequences of the Fr1 residues of T cell receptor alpha, beta- and gamma-chains and have produced antibodies in rabbits against these synthetic peptides. Use of antisera and affinity-purified antipeptide antibodies indicated that high-titer antibodies could be raised that were specific for individual Fr1 peptides. Cross-reactions among Fr1 peptides of T cell receptors and immunoglobulin light chains were observed. In addition, some rabbit antisera raised against classical polyclonal immunoglobulins or affinity-purified immunoglobulin-like T cell receptors were found to exhibit binding activity against Fr1 peptides of T cell receptor beta- and gamma-chains. The sequence homology, although real among the Fr1 of T cell receptors and immunoglobulin light chains, is moderate and the antigenic cross-reaction must reflect the configuration and types of amino acids present. The development of antipeptide antibodies holds promise for the characterization of T cell receptors of various T cell sources and also offers a new means for the identification of molecules related to rearranging immunoglobulins.

A monoclonal antigen-binding T cell immunoprotein: antigenic relatedness to T cell receptor beta chain FR1 V and J peptide segments: physicochemical distinctiveness from classical immunoglobulins and T cell receptor heterodimers

The monoclonal murine T cell hybridoma, 51H7D, was previously shown to bind the arsazobenzene hapten and to produce a soluble antigen-binding molecule. In this paper we characterize this antigen-binding immunoprotein for its relationship to known T cell receptors serologically, using antibodies specific for variable region framework, or joining region peptides predicted from gene sequence and by biochemical means. The 51H7D cell expresses a protein with subunit size of approximately 31,000, that reacts antigenically with affinity-purified antibodies directed against synthetic first framework and joining segment peptides, corresponding to the gene sequence of the T cell receptor beta chain, YT35. This molecule does not react with affinity-purified antibodies directed against murine immunoglobulin, framework 1 sequences of alpha and gamma T cell receptors, or with antibodies against synthetic heavy chain joining segments. The subunit of mol. wt. 31,000 can form higher aggregates, notably in the mol. wt range of 60,000-70,000, depending upon extraction conditions. The soluble form of the antigen-binding molecule bears the J beta cross-reactive determinant and occurs predominantly as a charge restricted molecular species of approximate mol. wt 60,000-70,000. The purified molecule has a blocked N-terminus, but quantitative statistical analysis of its amino acid composition indicates a closer relatedness to T cell receptor beta chains and other antigen-binding T cell products, than it has to alpha, gamma or delta TCR chains. No evidence for more than one type of polypeptide chain was found and the polymerization is not dependent upon the formation of disulfide bonds. These studies raise the possibility that antigen-binding soluble T cell molecules might belong to a new family of immunoproteins, that is related to, but distinct from, classical immunoglobulins and alpha beta or gamma delta heterodimers.

Flow cytometric analysis of human lymphocytes using affinity-purified antibody to T cell receptor beta synthetic J region peptide

The purpose of this study was to use affinity-purified polyclonal antibodies produced against a synthetic peptide corresponding to the joining (J) region of a human T cell receptor beta chain to characterize antigen receptor expression on subpopulations of human lymphocytes. The synthetic peptide used was ANYGYTFGSGTRLTVV, corresponding to the J segment of the human beta-chain gene YT35. Biochemical characterization has previously demonstrated binding of anti-J beta peptide antibodies to the alpha/beta heterodimer and to certain immunoglobulin light chains. Flow cytometric analysis of normal human peripheral blood lymphocytes performed here, using affinity-purified antibodies to the J beta peptide, showed expression of the epitope on 50-60% of CD20 (B1)-positive B lymphocytes, and on 40-50% of CD8-positive T lymphocytes. Only background levels were observed on CD4-positive T cells.

Immunoglobulin epitopes defined by synthetic peptides corresponding to joining region sequence: conservation of determinants and dependence upon the presence of an arginyl or lysyl residue for cross-reaction between light chains and T-cell receptor chains

Joining or J region sequences of rearranging immunoglobulins and T-cell receptors show considerable sequence homology, particularly in their C-terminal portion corresponding to the fourth framework region of immunoglobulin variable regions. In order to test the question of whether serological cross-reactions between immunoglobulin variable regions and T-cell receptors were due to antigenic similarities in their J regions, we synthesized synthetic peptides corresponding to immunoglobulin J regions and to J regions predicted from gene sequence of the T-cell receptor beta chain. We found that antibodies produced against a synthetic 16-mer J beta sequence reacted with T-cell receptor chains and also with immunoglobulin light chains. The cross-reactivity was dependent upon the J signature sequence FG()GT(R or K)L where the presence of a positively charged lysyl or arginyl residue was essential for cross-reactivity. We were able to classify J region determinants into two distinct antigenic sets; one corresponding to JH and the other corresponding to J kappa, J lambda, J beta and J alpha. Although considerable homology occurs between JH and JL (or J beta) sequences, little cross-reactivity was observed between these two J subsets. Antibodies raised against polyclonal murine IgG immunoglobulins contained antibody subpopulations specifically reactive with either JH or J beta peptides. The serological data derived here using antipeptide antibodies are consistent with computer modeling studies that indicate that the conformations of T-cell receptor variable regions resemble those of classical immunoglobulins. Our data comparing cross-reactivities restricted to the J region indicate that the expression of the J region by intact T-cell receptor beta chains is probably more similar to that of light chains than it is to the corresponding region of heavy chains.