Complexity of the T cell receptor Cbeta isotypes in the Mexican axolotl: structure and diversity of the VDJCbeta3 and VDJCbeta4 chains.

We have reported previously the presence of two T cell receptor beta-chain constant region (Cbeta) isotypes in the Mexican axolotl. Specific Dbeta and Jbeta segments were present at the Vbeta-Cbeta1 and Vbeta-Cbeta2 junctions and nine Vbeta families which associate with both isotypes were characterized. This report describes two new Cbeta isotypes, Cbeta3 and Cbeta4. About 70 % of the amino acids in Cbeta3 are identical to Cbeta1 and Cbeta2. A Dbeta3 and a single Jbeta3 were found at the Vbeta-Cbeta3 junctions. The Dbeta3 consensus core sequence (TACGTGGCTACGTGGG) differs to all the presently known Dbeta and the CDR3beta loops of the Vbeta-Cbeta3 junctions (mean: 11.1 amino acids) contain a majority of aromatic, small hydrophobic and basic residues. The CDR3beta loops of the other isotypes are shorter (mean: 8.5 amino acids), contain a majority of acidic residues and very few aromatic residues. The axolotl Cbeta4 sequence has about 46 % similarity to Cbeta1, Cbeta2 and Cbeta3. Dbeta4 is identical to Dbeta2 and six new Jbeta segments are used at the Vbeta-Cbeta4 junctions. Four new families of Vbeta segments (Vbeta10-Vbeta13) are preferentially associated to Cbeta4. A strong selective pressure must operate in most vertebrates to preserve the structural stability of the extracellular part of the Cbeta chain. The four axolotl Cbeta seem to have evolved more freely, perhaps to favor the early emergence of a large diversity of T cell receptors in an amphibian species which is not fully immunocompetent before the 5th month of development.

T-cell receptors in ectothermic vertebrates.

The structure and expression of genes encoding molecules homologous to mammalian T-cell receptors (TCR) have been recently studied in ectothermic vertebrate species representative of chondrychthians, teleosts, and amphibians. The overall TCR chain structure is well conserved in phylogeny: TCR beta- and TCR alpha-like chains were detected in all the species analyzed; TCR gamma- and TCR delta-like chains were also present in a chondrychthian species. The diversity potential of the variable (V) and joining (J) segments is rather large and, as in mammals, conserved diversity (D) segments are associated to the TCR beta and TCR delta chains. An important level of junctional diversity occurred at the V-(D)-J junctions, with the potential addition of N- and P-nucleotides. Thus, the conservation of the structure and of the potential of diversity of TCR molecules have been under a permanent selective pressure during vertebrate evolution. The structure of MHC class I and class II molecules was also well conserved in jawed vertebrates. TCR and MHC molecules are strongly functionally linked and play a determinant role in the initiation and the regulation of the specific immune responses; thus, it is not surprising that their structures have been reciprocally frozen during evolution.

Structure and diversity of the T-cell receptor alpha chain in the Mexican axolotl.

Polymerase chain reaction was used to isolate cDNA clones encoding putative T-cell receptor (TCR) alpha chains in an amphibian, the Mexican axolotl (Ambystoma mexicanum). Five TCRalpha-V chain-encoding segments were identified, each belonging to a separate family. The best identity scores for these axolotl TCRalpha-V segments were all provided by sequences belonging to the human TCRalpha-V1 family and the mouse TCRalpha-V3 and TCRalpha-V8 families. A total of 14 different TCRA-J segments were identified from 44 TCRA-V/TCRA-J regions sequenced, suggesting that a large repertoire of TCRA-J segments is a characteristic of most vertebrates. The structure of the axolotl CDR3 alpha chain loop is in good agreement with that of mammals, including a majority of small hydrophobic residues at position 92 and of charged, hydrophilic, or polar residues at positions 93 and 94, which are highly variable and correspond to the TCRA-V/J junction. This suggests that some positions of the axolotl CDR3 alpha chain loop are positively selected during T-cell differentiation, particularly around residue 93 that could be selected for its ability to makes contacts with major histocompatibility complex-associated antigenic peptides, as in mammals. The axolotl Calpha domain had the typical structure of mammalian and avian Calpha domains, including the charged residues in the TM segment that are thought to interact with other proteins in the membrane, as well as most of the residues forming the conserved antigen receptor transmembrane motif.

The structure, rearrangement, and ontogenic expression of DB and JB gene segments of the Mexican axolotl T-cell antigen receptor beta chain (TCRB).

We sequenced a total of 189 independent rearrangements in which the VB7.1 element is associated with CB1 (99 clones) or CB2 (90 clones) isotypes of the T-cell receptor (TCR) beta chain in the Mexican axolotl. Three stages of development were analyzed: 2.5 months, 10 months, and 25 months. Three JB1 segments were associated with the VB-CB1 rearrangements and six JB2 segments with VB-CB2. As in other vertebrates, some amino acid positions were conserved in all Jbetas (e. g., Phe-108, Gly-109, Gly-111, Thr-112, and Val-116). Two 11 nucleotides DB-like sequences, differed by one (A or T) central residue and could be productively read in the three putative reading frames. Most of the DB1 and JB1 segments were in the VB-CB1 clones, and most of the DB2 and JB2 segments were in the VB-CB2 clones, suggesting that the TCRB locus is organized into independent DB-JB-CB clusters that used the same collection of VB segments. About 40% of the beta-chain VDJ junctions in 2.5-month-old larvae had N nucleotides, compared with about 73% in 10 - 25-month old animals. The beta-chain VDJ junctions had about 30% of defective rearrangements at all stages of development, which could be due to the slow rate of cell division in the axolotl lymphoid organs, and the large genome in this urodele. Many of the axolotl CDRbeta3 sequences deduced for in frame VDJ rearrangements are the same in animals of different origins. Such redundancy could be a statistical effect due to the small number of thymocytes in the developing axolotl, rather than to some bias due to junctional preferences.

Evolution of T cell receptor genes. Extensive diversity of V beta families in the Mexican axolotl.

We have cloned 36 different rearranged variable regions (V beta) genes encoding the beta-chain of the T cell receptor in an amphibian species, Ambystoma mexicanum (the Mexican axolotl). Eleven different V beta segments were identified, which can be classified into 9 families on the basis of a minimum of 75% nucleotide identity. All the cloned V beta segments have the canonical features of known mammalian and avian V beta, including conserved residues Cys23, Trp34, Arg69, Tyr90, and Cys92. There seems to be a greater genetic distance between the axolotl V beta families than between the different V beta families of any mammalian species examined to date: most of the axolotl V beta s have fewer than 35% identical nucleotides and the less related families (V beta 4 and V beta 8) have no more than 23.2% identity (13.5% at the amino acid level). Despite their great mutual divergence, several axolotl V beta are sequence-related to some mammalian V beta genes, like the human V beta 13 and V beta 20 segments and their murine V beta 8 and V beta 14 homologues. However, the axolotl V beta 8 and V beta 9 families are not significantly related to any other V beta sequence at the nucleotide level and show limited amino acid similarity to mammalian V alpha, V kappa III, or VH sequences. The detection of nine V beta families among 35 randomly cloned V beta segments suggests that the V beta gene repertoire in the axolotl is probably larger than presently estimated.

Characterization of a multimeric polypeptide complex on the surface of thymus-derived cells in the Mexican axolotl.

We previously raised a rabbit antiserum (L12) against a 38 kD polypeptide which is expressed on the surface of thymocytes and peripheral T cells of an Urodele Amphibian, the Mexican axolotl (Ambystoma mexicanum). Here we show that L12 antibodies immunoprecipitate several labelled molecules from surface iodinated axolotl spleen cells, including the 38 kD molecule, but also two polypeptides of 43 and 22 kD which are covalently linked to other elements. Another rabbit antiserum (L10) was raised against detergent-solubilized axolotl thymocyte membranes and shown to recognize the majority of thymocytes and about half of the splenocytes in immunofluorescence. In Western blotting, L10 antibodies recognized a limited number of surface polypeptides in thymocyte and splenocyte lysates, including 43, 38, and 22 kD elements. Immune complexes formed between L10 antibodies and solubilized splenocyte membranes were used to immunize BALB/c mice intrasplenically in the aim of raising MoAbs specific for axolotl T cells. Monoclonal antibody 87.16 was shown to stain in immunofluorescence 26.7% of thymocytes and 26.8% of spleen cells. This MoAb recognized a 43 kD polypeptide that can covalently associate on the T-cell surface with several other molecules to form a multimeric complex.

Conserved structure of amphibian T-cell antigen receptor beta chain.

All jawed vertebrates possess well-differentiated thymuses and elicit T-cell-like cell-mediated responses; however, no surface T-cell receptor (TCR) molecules or TCR genes have been identified in ectothermic vertebrate species. Here we describe cDNA clones from an amphibian species, Ambystoma mexicanum (the Mexican axolotl), that have sequences highly homologous to the avian and mammalian TCR beta chains. The cloned amphibian beta chain variable region (V beta) shares most of the structural characteristics with the more evolved vertebrate V beta and presents approximately 56% amino acid identities with the murine V beta 14 and human V beta 18 families. The two different cloned axolotl beta chain joining regions (J beta) were found to have conserved all the invariant mammalian J beta residues, and in addition, the presence of a conserved glycine at the V beta-J beta junction suggests the existence of diversity elements. The extracellular domains of the two axolotl beta chain constant region isotypes C beta 1 and C beta 2 show an impressively high degree of identity, thus suggesting that a very efficient mechanism of gene correction has been in operation to preserve this structure at least from the early tetrapod evolution. The transmembrane axolotl C beta domains have been less well conserved when compared to the mammalian C beta but they do maintain the lysine residue that is thought to be involved in the charged interaction between the TCR alpha beta heterodimer and the CD3 complex.

Phylogeny of immunoglobulin heavy chain isotypes: structure of the constant region of Ambystoma mexicanum upsilon chain deduced from cDNA sequence.

An RNA polymerase chain reaction strategy was used to amplify and clone a cDNA segment encoding for the complete constant part of the axolotl IgY heavy (C upsilon) chain. C upsilon is 433 amino acids long and organized into four domains (C upsilon 1-C upsilon 4); each has the typical internal disulfide bond and invariant tryptophane residues. Axolotl C upsilon is most closely related to Xenopus C upsilon (40% identical amino acid residues) and C upsilon 1 shares 46.4% amino acid residues among these species. The presence of additional cysteines in C upsilon 1 and C upsilon 2 domains is consistent with an additional intradomain S-S bond similar to that suggested for Xenopus C upsilon and C chi, and for the avian C upsilon and the human C epsilon. C upsilon 4 ends with the Gly-Lys dipeptide characteristic of secreted mammalian C gamma 3, human C epsilon 4, and avian and anuran C upsilon 4, and contains the consensus [G/GT(AA)] nucleotide splice signal sequence for joining C upsilon 4 to the transmembrane region. These results are consistent with the hypothesis of an ancestral structural relationship between amphibian, avian upsilon chains, and mammalian epsilon chains. However, these molecules have different biological properties: axolotl IgY is secretory Ig, anuran and avian IgY behave like mammalian IgG, and mammalian IgE is implicated in anaphylactic reactions.

T-cell-specific membrane antigens in the Mexican axolotl (urodele amphibian).

Comparative analysis of SDS-PAGE patterns of axolotl spleen cells membrane detergent lysates showed important discrepancies between control and thymectomized animals. Among these, a 38-kD protein band, which appeared as a major protein in controls, was not or poorly expressed after thymectomy. A rabbit antiserum (L12) raised against the 38-kD eluted band labeled in indirect immunofluorescence 80-86% of thymocytes and 40-46% of mIg- lymphoid cells in the spleen. The anti-38-kD antibodies stained in Western blotting two antigenically related polypeptides of 38- and 36-kD on splenocyte membrane lysates. Two-dimensional NEPHGE-PAGE analysis indicated that the anti-38-kD antibodies reacted in the spleen with several gathered spots in the 7.8-8.2 pI range, corresponding to 38-36-kD microheterogeneous polypeptides. Most of these spots are not further expressed in thymectomized animals. These results support evidence that the 38-kD surface antigens can be considered as specific surface markers of the axolotl thymus-derived lymphocytes.

High levels of HMG1-2 protein expression in the cytoplasm and nucleus of hydrocortisone sensitive amphibian thymocytes.

A major 26 kDa protein was identified in the cytoplasmic and nuclear compartments of axolotl thymocytes. A polyclonal antiserum was produced against the denatured form of this protein. High levels of 26 kDa were expressed by hydrocortisone-sensitive lymphocytes which represent a major thymocyte subpopulation in young animals. However, no further expression of the 26 kDa protein was observed in involuted thymus of adult animals nor in thymus of young artificially metamorphosed axolotls. The 26 kDa was never expressed by splenic and blood peripheral lymphocytes at any stage of development. Partial N-terminal amino acid sequence and amino acid composition demonstrate that the 26 kDa polypeptide is strongly homologous to HMG1-2 proteins, the most abundant members of the high mobility group (HMG) non-histone chromosomal proteins. HMG1-2 are thought to be involved in the organization of chromatin structure, as well as in the stability, replication and transcription of DNA. It was confirmed that the 26 kDa axolotl polypeptide is recognized by a well characterized rabbit antiserum to rat HMG1-2 proteins.