The urodele amphibian Pleurodeles waltl has a diverse repertoire of immunoglobulin heavy chains with polyreactive and species-specific features.

Urodele amphibians are an interesting model because although they possess the cardinal elements of the vertebrate immune system, their immune response is apparently subdued. This phenomenon, sometimes regarded as a state of immunodeficiency, has been attributed by some authors to limited antibody diversity. We reinvestigated this issue in Pleurodeles waltl, a metamorphosing urodele, and noted that upsilon transcripts of its IgY repertoire were as diverse as alpha transcripts of the mammalian IgA repertoire. Mu transcripts encoding the IgM repertoire were less diverse, but could confer more plasticity. Both isotypes present potential polyreactive features that may confer urodele antibodies with the ability to bind to a variety of antigens. Finally, we observed additional cysteines in CDR1 and 2 of the IGHV5 and IGHV6 domains, some of which specific to urodeles, that could allow the establishment of a disulfide bond between these CDRs. Together, these data suggest that urodele antibody diversity is not as low as previously thought.

Contribution of the urodele amphibian Pleurodeles waltl to the analysis of spaceflight-associated immune system deregulation.

Immune system deregulation has been demonstrated to occur during and immediately following spaceflight. Several animal models have been used to study this phenomenon because of the limited availability of human subjects in space as well as of the need to carry out experiments requiring samples and experimental conditions that cannot be performed using humans. Here, we review major spaceflight-induced microbial and immunological modifications, some of the existing hardware developed to host amphibians in a space station and immunological information provided by space experiments performed with Pleurodeles waltl as an animal model. These data show that the urodele amphibian P. waltl fulfills many technical requirements associated with spaceflight experimentation and that this model is interesting to improve our understanding of the immunosuppressive effects of spaceflight, data required for the preparation of future deep-space missions.

Decrease in antibody somatic hypermutation frequency under extreme, extended spaceflight conditions.

Somatic hypermutation diversifies antibody binding sites by introducing point mutations in the variable domains of rearranged immunoglobulin genes. In this study, we analyzed somatic hypermutation in variable heavy-chain (VH) domains of specific IgM antibodies of the urodele amphibian Pleurodeles waltl, immunized either on Earth or onboard the Mir space station. To detect somatic hypermutation, we aligned the variable domains of IgM heavy-chain transcripts with the corresponding VH gene. We also quantified NF-κB and activation-induced cytidine deaminase transcripts. Results were compared with those obtained using control animals immunized on Earth. Our data show that, as in most species of ectotherms, somatic hypermutation in P. waltl exhibits a mutational bias toward G and C bases. Furthermore, we show for the first time that somatic hypermutation occurs in space following immunization but at a lower frequency. This decrease is not due to a decrease in food intake or of the B-cell receptor/antigen interaction or to the absence of the germinal center-associated nuclear protein. It likely results from the combination of several spaceflight-associated changes, such as the severe reduction in T-cell activation, important perturbations of the cytoskeleton, and changes in the distribution of lymphocyte subpopulations and adhesion molecule expression.

Spaceflight-associated changes in immunoglobulin VH gene expression in the amphibian Pleurodeles waltl.

Understanding why the immune system is depressed during spaceflight is of obvious importance for future human deep-space missions, such as the foreseen missions to Mars. However, little is known about the effects of these flights on humoral immunity. We previously immunized adult Pleurodeles waltl (urodele amphibian) onboard the Mir space station and showed that heavy-chain variable (VH) domains of specific IgM antibodies are encoded by genes belonging to the VHII and VHVI families. We have now determined how these animals use their individual VHII and VHVI genes by screening IgM heavy-chain cDNA libraries and by quantifying IgM heavy-chain transcripts encoded by these genes. Results were compared with those obtained using control animals immunized on Earth under the same conditions as onboard Mir. Our experiments revealed an increase in the expression of IgM heavy-chain mRNAs encoded by the VHII and VHVI.C genes and a strong decrease in the expression of IgM heavy-chain mRNAs encoded by the VHVI.A and VHVI.B genes in spaceflight animals. Consequently, different heavy-chain mRNAs are expressed by spaceflight animals, demonstrating that this environment affects the humoral response. These observations may be due to a change in B-cell selection under spaceflight conditions.

Effects of a long-term spaceflight on immunoglobulin heavy chains of the urodele amphibian Pleurodeles waltl.

A variety of immune parameters are modified during and after a spaceflight. The effects of spaceflights on cellular immunity are well documented; however, little is known about the effects of these flights on humoral immunity. During the Genesis space experiment, two adult Pleurodeles waltl (urodele amphibian) stayed 5 mo onboard Mir and were subjected to oral immunization. Animals were killed 10 days after their return to earth. IgM and IgY heavy-chain transcripts in their spleens were quantified by Northern blotting. The use of the different VH families (coding for antibody heavy-chain variable domains) in IgM heavy chain transcripts was also analyzed. Results were compared with those obtained with ground control animals and animals reared in classical conditions in our animal facilities. We observed that, 10 days after the return on earth, the level of IgM heavy-chain transcription was normal but the level of IgY heavy-chain transcription was at least three times higher than in control animals. We also observed that the use of the different VH families in IgM heavy-chain transcripts was modified by the flight. These data suggest that the spaceflight affected the antibody response against the antigens contained in the food.

[Cytogenetic maps of lampbrush chromosomes of newts of the genus Pleurodeles: an algorithm of lampbrush chromosome identification in Pleurodeles waltl by immunocytochemical marker-loop staining with polyclonal anti-Ro52 antisera]. / Tsitogeneticheskie karty khromosom-lampovykh shchetok tritonov roda Pleurodeles: algoritm identifikatsii lampovykh shchetok Pleurodeles waltl s ispol'zovaniem immunokhimicheskogo okrashivaniia markernykh petel' poliklonal'noi syvorotki protiv proteina Ro52.

Our work was aimed at developing a simple and effective method of identification of most or all chromosomes of Pleurodeles newts. To this end, we used DAPI staining of the chromomeres of newt lampbrush chromosomes and immunochemical reactions between the ribonucleoprotein (RNP) marker loops and polyclonal antibodies against human zinc-finger protein Ro52 (52-kDa Ro/SS-A). A method has been developed to obtain newt lampbrush chromosome preparations. Cytological maps of P. waltl chromosomes (Spanish population/subspecies) showing distributions of chromomeres and marker loops along the chromosome length were constructed.

Sequencing and expression of the CD3 gamma/delta mRNA in Pleurodeles waltl (urodele amphibian).

The CD3 complex is an essential component of the T-cell receptor (TCR) implicated in T-cell maturation and activation. This TCR has been identified in both cartilaginous and bony vertebrates. In different studies where the CD3 chains were cloned and sequenced, it appeared that the CD3 complex is composed of several chains, all susceptible to phosphorylation and able to transduce signals. Here, by an approach combining degenerative oligonucleotide primers and RACE-PCR, we report the cloning and sequencing of a CD3 cDNA from the salamander Pleurodeles waltl, highly homologous to the Xenopus and chicken CD3 gamma/delta cDNAs. Using semi-quantitative PCR and Northern blot analysis, we found the highest CD3 gamma/delta mRNA expression in the thymus; weaker expression was observed in the spleen and blood, followed by the intestine, therefore confirming the tissue and lymphoid specificities of this mRNA. The signals in the spleen, blood and intestine represented 55%, 33% and 16%, respectively, of the signal detected in the thymus. During the embryonic and larval stages of Pleurodeles waltl development, CD3 gamma/delta mRNA expression begins early at the neurula stage (stage 15, 69 h after laying), increases up to stage 33 (9 days after laying) and afterwards remains stable, at least until the larval stage 42 (28 days after laying). As the thymus primordium appears much later, the question of the formation and maturation of the first T-cell precursors outside this organ is posed.

Characterization of Le(x), Le(y) and A Le(y) antigen determinants in KDN-containing O-linked glycan chains from Pleurodeles waltlii jelly coat eggs.

Novel acidic oligosaccharides were isolated in large amounts by reductive alkaline treatment of the jelly coat of Pleurodeles waltlii (Michah) eggs. The oligosaccharides were found to contain the newly described KDN as acidic monosaccharide and possess either the Le(x), Le(y) and A Le(y) antigenic determinants. Occurrence of Le(x) and Le(y) determinants previously recognized as tumor-associated antigen (TAA) demonstrates that mucins of lower animals may represent a rich and easily available source for preparing TAA. Moreover, it reinforces the hypothesis according to which TAA are evolution markers.