Mixed leukocyte reaction, graft-versus-host reaction, and skin allograft rejection in the lizard, Chalcides ocellatus

Combining immunological and molecular data to assess phylogenetic relations of some Greek Podarcis species

Most recent molecular studies revealed the phylogeny of Greek Podarcis species, which for years remained elusive, due to discordant data produced from various chromosomal, complement fixation and protein studies. In this report, we analyzed cellular immune responses of spleen-derived lymphocytes from six allopatric Podarcis species encountered in Greece, by assessing two-way mixed lymphocyte reaction (MLR)-induced proliferation. On the basis of stimulation indices (S.I.) as determined from cultures set up from xenogeneic splenocytes coincubated in pairs, we generated a phylogenetic tree, fully consistent with the phylogenetic relationships of Podarcis as determined by parallel analyses based on partial mitochondrial (mt) DNA sequences. Although the exact mechanisms triggering lymphocyte responses in lizard two-way xenogeneic MLR are not fully understood, our results show the potential use of cell-mediated immune responses as an additional approach to mtDNA analysis, for species delimitation within specific lizard taxa.

Graft-versus-host reaction (GVHR) in clonal amago salmon, Oncorhynchus rhodurus

The graft-versus-host reaction (GVHR) was demonstrated in a salmonid model system of clonal diploid and triploid amago salmon. Triploid operculum grafts on clonal diploid evoked an acute rejection within 12 days. Grafts exchanged among triploid amago salmon exhibited prolonged survival for 18 days. In contrast, diploid grafts on triploid, and allografts among clonal diploid amago salmon were accepted. A typical GVHR was induced in triploid recipients by intraperitonal injection of head kidney cells from sensitised diploid donors. The clinical signs of graft-versus-host disease (GVHD) were observed in the recipients after 1 week of cell injection as a loss of appetite and appearance of solid faeces, followed by haemorrhage, local swelling of ventral skin and an enlarged spleen. Three of six fish died within 1 month. Water temperature and frequency of sensitisation are critical to induce GVHR. Diploid donors had to be sensitised three times at 20 degrees C to induce the typical GVHR. GVHR was most effectively induced by head kidney cells, followed by peripheral blood leucocytes (PBL) and spleen cells. Ploidy analysis by flow cytometry revealed that the donor head kidney cells greatly increased in the recipient liver, head kidney and spleen, and reached the peak after 9 days of donor cell injection. The results in the present study are quite similar to the findings in ginbuna and ginbuna-gold fish hybrid system, suggesting the presence of T cells in salmonid as well as cyprinid fish.

The graft-versus-host reaction (GVHR) in the ginbuna crucian carp, Carassius auratus langsdorfii

A model system of clonal triploid ginbuna and tetraploid ginbuna-goldfish hybrids was employed to demonstrate the presence of graft-versus-host reaction (GVHR) in a teleost fish. Tetraploid scale grafts on triploid clone members evoked an acute rejection, whereas the reverse transplants were accepted. When sensitized triploid cells were injected into tetraploid recipients, a typical GVHR was induced, leading to death of the recipients within one month. The onset of illness appeared about one week after cell injection as a loss of appetite and constipation, followed by a scale protrusion, severe haemorrhage, local destruction of the ventral skin and prominent splenomegaly. GVHR was most effectively induced by head-kidney cells and peripheral blood leukocytes (PBL), followed by spleen and thymus cells. Donors had to be sensitized at least twice by scale grafting to induce the reaction. A considerable number of recipients injected with cells from donors which had been sensitized by allogenetically different tetraploids died, suggesting a limited polymorphism or heavy cross-reactions between the alleles of the histocompatibility antigens. Ploidy analyses revealed that donor cells greatly increased in the host liver and spleen, constituting approximately 30% of total cells after 2 3 weeks. Most of these features of acute GVHR observed in this fish system are quite similar to those found in mammals and birds. thereby suggesting the presence of allo-reactive cytotoxic T lymphocytes in teleosts.

Seasonal variations in the immune system of lower vertebrates

Seasonal variation, affecting the structure and function of the ectotherm immune system, is an excellent 'natural' model of the influence of neuroendocrine rhythms on immunity. In this review, Agustín Zapata, Alberto Varas and Marta Torroba examine the correlations between seasonal changes and circulating steroid levels, and investigate the possibility of a neuroendocrine-immune network in lower vertebrates.

Functional markers of the major histocompatibility gene complex of snakes

In optimal seasonal conditions, outbred adult snakes Psammophis sibilans displayed the major immunological functions related, in mammals, to the presence of the major histocompatibility gene complex (MHC). Thus, out of 30 snake random pairs that exchanged skin transplants 72.9% rejected their allograft in an acute or subacute manner. Strongly significant proliferative response was recorded in 67.3% of 168 separate one-way mixed leukocyte reaction (MLR) cultures. Lymphocytes from 6/11 snakes immunized by skin allografting displayed, after secondary stimulation in vitro, cell-mediated lympholysis (CML) in vitro of 51Cr-labeled lymphoblasts derived from the donor snake. Finally, cytotoxic alloantibodies were readily generated after snake priming with skin allograft and blood cells. Snakes did not only exhibit the major cell- and humoral-mediated immune functions, but these functions appeared to be linked with the degree of MLR disparity. Thus, animals with different MLR rejected skin allografts acutely and produced cytotoxic effector cells. In contrast, MLR-identical animals rejected the skin allograft of their partner chronically and failed to produce killer cells in CML. This significant positive correlation between MLR disparity, graft rejection and CML suggests that the responsible antigens are encoded, as in other vertebrates, by the same genetic system, the MHC.

Blood testosterone level: a season-dependent factor regulating immune reactivity in lizards

An attempt to study the interaction between testosterone (Ts) and the immune system of the lizard Chalcides ocellatus led to three major findings: 1) Endogenous serum Ts levels in both males and females peak in spring and are minimal during summer; 2) Injection of Ts in either male or female lizards induces significant depletion of lymphoid elements, reduction in serum antibody titers to rat erythrocytes and increase in skin allograft survival; 3) A distinct inverse correlation between endogenous serum Ts levels and lizard immunocompetence is observed from March to September. The data obtained strongly suggested that concentration of circulating Ts is a season-related factor that is critical in defining the immune profile of lizards.

The MHC molecules of nonmammalian vertebrates

There is very little known about the long-term evolution of the MHC and MHC-like molecules. This is because both the theory (the evolutionary questions and models) and the practice (the animals systems, functional assays and reagents to identify and characterize these molecules) have been difficult to develop. There is no molecular evidence yet to decide whether vertebrate immune systems (and particularly the MHC molecules) are evolutionarily related to invertebrate allorecognition systems, and the functional evidence can be interpreted either way. Even among the vertebrates, there is great heterogeneity in the quality and quantity of the immune response. The functional evidence for T-lymphocyte function in jawless and cartilagenous fish is poor, while the bony fish seem to have many characteristics of a mammalian immune system. The organization and sequence of fish Ig genes also indicate that important events in the evolution of the immune system and the MHC occurred in the fish, but thus far there is no molecular evidence for recognizable MHC-like molecules in any fish. There is clearly an MHC in amphibians and birds with many characteristics like the MHC of mammals (a single genetic region encoding polymorphic class I and class II molecules) and evidence for polymorphic class I and class II molecules in reptiles. However, many details differ from the mammals, and it is not clear whether these reflect historical accident or selection for different lifestyles or environment. For example, the adult frog Xenopus has a vigorous immune system with many similarities to mammals, a ubiquitous class I molecule, but a much wider class II tissue distribution than human, mouse and chicken. The Xenopus tadpole has a much more restricted immune response, no cell surface class I molecules and a mammalian class II distribution. The axolotl has a very poor immune response (as though there are no helper T cells), a wide class II distribution and, for most animals, no cell surface class I molecule. It would be enlightening to understand both the mechanisms for the regulation of the MHC molecules during ontogeny and the consequences for the immune system and survival of the animals. These animals also differ markedly in the level of MHC polymorphism. Another difference from mammals is the presence of previously uncharacterized molecules. In Xenopus and reptiles, there are two populations of class I alpha chain on the surface of erythrocytes, those in association with beta 2m and those in association with a disulfide-linked homodimer.(ABSTRACT TRUNCATED AT 400 WORDS)

Endogenous corticosteroids mediate seasonal cyclic changes in immunity of lizards

Endogenous corticosteroid (CS) blood levels were radioimmunoassayed in fresh, field-collected lizards Chalcides ocellatus at two week-intervals throughout the four consecutive seasons. These animals were used in parallel to investigate the splenic T and B lymphocyte level, lymphoproliferative responsiveness to concanavalin A and primary antibody production in vitro against rat erythrocytes (RRBC). The recorded data indicated that fully developed splenic lymphoid tissue and powerful immune responsiveness are coincident with a continuously low CS level, and characterize the period from spring through early autumn. On the other hand, the dramatic lymphocytic destruction and impairment of immune reactivity observed in autumn and winter are associated with not only a high, but above all sustained, rise in endogenous CS levels. Apparently, exposure of lizard lymphocytes to comparatively high, yet physiologic, levels of endogenous CS for prolonged periods of time lead to impairment of their immune functions. In support, long-term administration of exogenous hydrocortisone acetate (HC) to "summer" lizards resulted in a high and lasting elevation in blood CS levels that was associated with a considerable depletion of lymphoid elements and abrogation of immune reactivity, exactly as in normal lizards collected from the field in autumn through winter. In addition, pharmacologic inhibition of CS synthesis by administration of metyrapone at the beginning of autumn greatly modulated the lizard lymphocyte response to the autumn-related immunodepression. The study thus strongly suggests that the autumn/winter-dependent immunosuppression in lizards is essentially due to a high and lasting rise in levels of endogenous CS. The results are discussed from the perspective of the role played by CS in mediating the seasonal rhythms that affect reptilian immunity.

Primary in vitro stimulation of antibody production by lizard splenocytes

Single-cell suspensions of adult lizard (Chalcides ocellatus) spleen have been induced, in vitro, to produce a primary immune response. Using rat red cells (RRBC) as antigen and the culture conditions normally used in most vertebrate species but new for reptilia, it has been found that, in vitro at 37 degrees C, lizard spleen cells produce an antibody-forming response optimal at day 10. The response depends on the number of cultured cells and the dose of antigen, and parallels that obtained in vivo. Leibovitz (L-15) medium supplemented with 10% normal adult lizard serum was a satisfactory culture medium. 2-mercaptoethanol (2-ME), an ingredient used in mammalian cell culture, enhanced antibody production in lizard cells.

Concanavalin A responsiveness and interleukin 2 production in the snake Spalerosophis diadema

Thymocytes and splenocytes (SC) of adult snakes, Spalerosophis diadema, responded to concanavalin A (Con A) in vitro by strong proliferation during the spring and autumn seasons. Con A-mediated mitogenesis was, however, abrogated in summer and winter. Conditioned medium (CM) collected from snake SC cultures stimulated with Con A in spring or autumn could enhance the Con A summer and winter responses and support the proliferation of splenic lymphoblasts. Gel filtration of native CM on Sephadex G-100 revealed the presence of two biologically active peaks of molecular weight 39-42 and 15 KD. However, only one peak of activity corresponding to molecular weight (m.w.) of 14-15 KD was observed when CM was subjected to analysis by sodium dodecyl sulphate gel electrophoresis (SDS-PAGE). The active molecular forms exhibited isoelectric points of 5.5-5.8 and 6.4-6.6. The findings suggest that Con A activation of snake lymphocytes in optimal seasonal conditions is associated with the secretion of a lymphokine analogous to the interleukin 2 (IL 2) of endothermic vertebrates.