Cross-linking CTX, a novel thymocyte-specific molecule, inhibits the growth of lymphoid tumor cells in Xenopus

The amphibian invitrome: Past, present, and future contributions to our understanding of amphibian immunity

Many amphibian populations are declining worldwide, and infectious diseases are a leading cause. Given the eminent threat infectious diseases pose to amphibian populations, there is a need to understand the host-pathogen-environment interactions that govern amphibian susceptibility to disease and mortality events. However, using animals in research raises an ethical dilemma, which is magnified by the alarming rates at which many amphibian populations are declining. Thus, in vitro study systems such as cell lines represent valuable tools for furthering our understanding of amphibian immune systems. In this review, we curate a list of the amphibian cell lines established to date (the amphibian invitrome), highlight how research using amphibian cell lines has advanced our understanding of the amphibian immune system, anti-ranaviral defence mechanisms, and Batrachochytrium dendrobatidis replication in host cells, and offer our perspective on how future use of amphibian cell lines can advance the field of amphibian immunology.

Evolution of nonclassical MHC-dependent invariant T cells

TCR-mediated specific recognition of antigenic peptides in the context of classical MHC molecules is a cornerstone of adaptive immunity of jawed vertebrate. Ancillary to these interactions, the T cell repertoire also includes unconventional T cells that recognize endogenous and/or exogenous antigens in a classical MHC-unrestricted manner. Among these, the mammalian nonclassical MHC class I-restricted invariant T cell (iT) subsets, such as iNKT and MAIT cells, are now believed to be integral to immune response initiation as well as in orchestrating subsequent adaptive immunity. Until recently the evolutionary origins of these cells were unknown. Here we review our current understanding of a nonclassical MHC class I-restricted iT cell population in the amphibian Xenopus laevis. Parallels with the mammalian iNKT and MAIT cells underline the crucial biological roles of these evolutionarily ancient immune subsets.

In vivo study of T-cell responses to skin alloantigens in Xenopus using a novel whole-mount immunohistology method

BACKGROUND

The African clawed frog, Xenopus, is a widely used comparative model for studying the immune response to transplantation antigens.

METHODS

To better define the effector cells involved in the immune response to skin alloantigens of the frog Xenopus laevis, we have adapted a whole-mount immunohistology procedure used in mice that enables us to visualize leukocyte infiltration into unfixed transplanted skin tissues using fluorescent antibodies. We characterized the leukocyte populations present in donor skin at different times after transplantation using anti-class II and CD8 monoclonal antibodies.

RESULTS

In autografts, only class II Langerhans or dendritic-like cells and very few CD8 T cells were detected. In contrast, major histocompatibility complex (MHC) disparate skin grafts at the peak of acute rejection (seven days posttransplantation, 50% rejection of pigment cells) were infiltrated with a large number of bright class II leukocytes, the majority of which were CD8 T cells. Most of these cells were located outside blood vessels and often near areas lacking pigmentation. Compared to MHC-disparate skin grafts, skin differing from the host only by minor histocompatibility antigens undergoes slower (i.e., chronic) rejection; interestingly, however, it was infiltrated by similar numbers of class II and CD8 T cell effectors, but with delayed kinetics (i.e., peaked around 15 days posttransplantation).

CONCLUSIONS

Our data provide direct in vivo evidence of marked infiltration of effector leukocytes, a majority of which are CD8 T cells that occurs at the onset of tissue destruction of skin allografts.

Structural Phylogenetic Analysis of Activation-Induced Deaminase Function

In mammals, activation-induced deaminase (AID) initiates somatic hypermutation (SHM) and class switch recombination (CSR) of Ig genes. SHM and CSR activities require separate regions within AID. A chromosome region maintenance 1 (CRM1)-dependent nuclear export signal (NES) at the AID C terminus is necessary for CSR, and has been suggested to associate with CSR-specific cofactors. CSR appeared late in AID evolution, during the emergence of land vertebrates from bony fish, which only display SHM. Here, we show that AID from African clawed frog (Xenopus laevis), but not pufferfish (Takifugu rubripes), can induce CSR in AID-deficient mouse B cells, although both are catalytically active in bacteria and mammalian cell systems, albeit at decreased level. Like mammalian AID, Takifugu AID is actively exported from the cell nucleus by CRM1, and the Takifugu NES can substitute for the equivalent region in human AID, indicating that all the CSR-essential NES motif functions evolutionarily predated CSR activity. We also show that fusion of the Takifugu AID catalytic domain to the entire human noncatalytic domain restores activity in mammalian cells, suggesting that AID features mapping within the noncatalytic domain, but outside the NES, influence its function.

Innate immunity in early chordates and the appearance of adaptive immunity

In the urochordate Ciona intestinalis some membrane Immunoglobulin superfamily members with ancestral features of antigen receptors are homologs of vertebrate adhesion molecules acting as virus receptors. They include the following: the junction adhesion molecule (reovirus receptor) (JAM), the Cortical thymocyte marker of Xenopus (CTX family) (Coxsackie's virus receptor) and the poliovirus receptor (PVR). In humans these genes belong to the same linkage group, of which 4 paralogous groups exist. This situation is consistent with the notion that the Ciona set of genes would correspond to a preduplication state. In addition, the human region 3q13 and its paralogs, harbour genes remotely related to the nectin family that can be detected in Protostomes (human CRTAM and CD80-86 related to Drosophila Beat). In addition, this linkage group contains several CDs important for the immune system CD166, CD47 and many members of the tetraspanin family. The VC1-like core of the nectin is homologous to the VCI core of the MHC-linked tapasin and to the VC1 segments of, for example, specific antigen receptors of vertebrates, and could be related to a primitive antigen receptor gene. It is suggested that the virus binding property of the members of this family was exploited, and that they were recruited in the vertebrate immune system following the introduction of the somatic rearrangement machinery. In this way the adaptive immune system could have developed from a set of receptors involved in a primitive local innate immunity involving NF-kappaB-mediated apoptosis.

Immunoglobulin superfamily receptors in protochordates: before RAG time

Urochordates and cephalochordates do not have an adaptive immune system involving the somatic rearrangement of their antigen receptor genes. They do not have antigen-presenting molecules of the major histocompatibility complex (MHC)-linked class I and II types. In the absence of such a system, the status of their genes reflects perhaps a primitive pre-recombination-activating gene (RAG) stage that could suggest the pathway leading to the genesis of the T-cell receptor (TCR) and antibodies. In the genome of Ciona intestinalis, genes that encode molecules with membrane receptor features have been found among many members of the immunoglobulin superfamily (Igsf). They use the domains typical of vertebrate antigen receptors and class I and II: the V, and C1-like domains. These genes belong to two families with recognizable homologs in vertebrates: the junctional adhesion molecule (JAM)/cortical thymocyte marker of Xenopus (CTX) family and the nectin family. The human homologs of these genes segregate in a single unit of four paralogous segments on chromosomes 1q, 3q, 11p, and 21q. These regions contain nowadays several genes involved in the adaptive immune system, and some related members are present in the MHC paralogs as well. They also contain receptor-like genes without homologs in Ciona but with related members in the protostome Drosophila. It looks as if in Ciona one detects what looks like the 'fossil' of one group of genes bound to duplicate and give rise to many crucial elements of the adaptive immune system. The modern homologs of these JAM, CTX, and nectins are all or almost all virus receptors, and the hypothesis is formulated that this property was taken advantage of during evolution to participate in the elaboration of either or both the somatically generated antigen-recognizing receptors and the antigen-presenting molecules.

Ontogeny of B cells expressing IgM in embryonic and larval tissues of the American grass frog, Rana pipiens

Affinity-purified, fluorochrome-tagged F(ab')(2) antibody fragments specific for heavy (mu) chains of Rana pipiens IgM were prepared from hyperimmune rabbit sera. By using two-color immunofluorescent procedures we observed that (1) the first cells expressing IgM, termed pre-B cells, lack detectable quantities of membrane or surface IgM but contain detectable quantities of cytoplasmic IgM (smu(-)/cmu(+)), (2) sIgM(+) B cells were the second type of IgM containing cell to appear in development, and (3) plasma cells, which contain copious quantities of cIgM, were the final phenotype to appear in the development of B cells expressing IgM. These cells were first observed in the pronephros of the developing urogenital system. Shortly after their appearance in the pronephros, cells in B lineages were observed in the liver. These observations (1) are consistent with recent studies of B lymphopoiesis in the aorta-gonad-mesonephros (AGM) region in endothermic vertebrates, including mice, (2) suggest that there are fundamental ontogenetic and phylogenetic similarities between cells and tissues of developing vertebrate immune systems, and (3) evoke questions concerning the possible function(s) of lymphocytes in developing anurans up to metamorphosis and beyond.

ChT1, an Ig Superfamily Molecule Required for T Cell Differentiation

The thymus is colonized by circulating progenitor cells that differentiate into mature T cells under the influence of the thymic microenvironment. We report here the cloning and function of the avian thymocyte Ag ChT1, a member of the Ig superfamily with one V-like and one C2-like domain. ChT1-positive embryonic bone marrow cells coexpressing c-kit give rise to mature T cells upon intrathymic cell transfer. ChT1-specific Ab inhibits T cell differentiation in embryonic thymic organ cultures and in thymocyte precursor cocultures on stromal cells. Thus, we provide clear evidence that ChT1 is a novel Ag on early T cell progenitors that plays an important role in the early stages of T cell development.

Duplication and MHC linkage of the CTX family of genes in Xenopus and in mammals

The effects of whole genome duplications that characterize the evolution of vertebrates have been studied on the gene of the Xenopus thymocyte molecule CTX and its mammalian relatives. CTX, with an extracellular part consisting of one V and one C2 external domain, defines a new subset of the immunoglobulin superfamily and is conserved from amphibians to mammals. The number of CTX loci, their polymorphism, and their genetic linkages have been studied in several Xenopus species and in humans. In the genetically simplest species, X. tropicalis (2n = 20), the unique CTX locus is linked to the MHC. In the polyploid species, all CTX genes, unlike many other immune system genes, have remained in the genome; i.e. there are two CTX loci in the tetraploid species X. laevis (2n = 6) and six CTX loci in the dodecaploid species X. ruwenzoriensis (2n = 108). In X. laevis, one CTX gene is linked to the MHC and the other not, presumably because one set of MHC class I and II has been deleted from the corresponding linkage group. The various mammalian homologues are less related to each other than are the Xenopus CTX genes among each other, and they do not cross-hybridize with each other because they stem from the ancient polyploidization. Some human CTX homologies are on chromosomes 11 and 21, but others are on chromosomes 1, 6 and 19, which contain MHC paralogous regions; this suggests that a very ancient linkage group has been preserved.

In vitro differentiation of a CD4/CD8 double-positive equivalent thymocyte subset in adult Xenopus

The thymus is the major site of selection and differentiation of T cells in mammals and birds. To begin to study the evolution of thymocyte differentiation, we have developed, in the frog Xenopus, an in vitro system that takes advantage of cortical thymocyte antigen (CTX), a recently discovered T cell antigen whose expression is restricted to Xenopus cortical thymocytes. Upon transient stimulation with suboptimal mitogenic concentrations of the phorbol ester phorbol myristate acetate (PMA) plus ionomycin, Xenopus thymocytes are induced to differentiate into cycling T lymphoblasts that actively synthesize and express high levels of surface MHC class I and class II molecules. This appearance of T lymphoblasts correlates with a rapid down-regulation of both surface CTX protein and CTX mRNA. A thymocyte subset with an immature phenotype (CTX+, CD8+, class II- or class II low and class I-) was characterized by depleting class II+ cells or by panning with anti-CTX mAb. This immature CTX+ thymocyte subset displays a limited proliferative capacity compared to total, class II+ or to CTX- thymocytes, and can be induced, by PMA/ionomycin, to differentiate into more mature T lymphoblasts expressing surface class II and class I molecules. These results provide the first in vitro evidence in an ectothermic vertebrate of a conserved intrathymic pathway of thymocyte differentiation. In addition, our data reveal that CTX can serve as a differentiation surface marker of a population of immature thymocytes that appears to be the equivalent of the mammalian CD4/CD8 double-positive subset.

Evolution of immune surveillance and tumor immunity: studies in Xenopus

We have developed a novel experimental model of cancer immunity in the frog, Xenopus, which may provide a useful alternative to murine tumor models and a way to assess whether the control of tumor development is a fundamental function of the immune system of vertebrates. In Xenopus, tumor immunity can be studied in two developmentally distinct immune systems. The larval immune system reflects characteristics of an ancestral system that appears to function without classical MHC class I antigen presentation and an efficient effector mechanism. The adult system appears more highly evolved in that it is remarkably similar to that of mammals and is able to generate a potent antitumor response. This amphibian model also provides a unique system with which to investigate a postulated role of heat shock proteins as components of an ancestral system of antigen presentation and/or immune surveillance that predates the antigen presentation pathway that exclusively involves MHC molecules.

CTX, a Xenopus thymocyte receptor, defines a molecular family conserved throughout vertebrates

CTX, a cortical thymocyte marker in Xenopus, is an immunoglobulin superfamily (Igsf) member comprising one variable and one constant C2-type Igsf domain, a transmembrane segment and a cytoplasmic tail. Although resembling that of the TCR and immunoglobulins, the variable domain is not encoded by somatic rearrangement of the gene but by splicing of two half-domain exons. The C2 domain, also encoded by two exons, has an extra pair of cysteines. The transmembrane segment is free of charged residues, and the cytoplasmic tail (70 amino acids) contains one tyrosine and many glutamic acid residues. ChT1, a chicken homologue of CTX, has the same structural and genetic features, and both molecules are expressed on the thymocyte surface. We cloned new mouse (CTM) and human (CTH) cDNA and genes which are highly homologous to CTX/ChT1 but not lymphocyte specific. Similarity with recently described human cell surface molecules, A33 antigen and CAR (coxsackie and adenovirus 5 receptor), and a number of expressed sequence tags leads us to propose that CTX defines a novel subset of the Igsf, conserved throughout vertebrates and extending beyond the immune system. Strong homologies within vertebrate sequences suggest that the V and C2 CTX domains are scions of a very ancient lineage.

Ontogeny of CTX expression in xenopus

In Xenopus, the type I transmembrane protein, CTX (cortical thymocyte-specific antigen of Xenopus), is hypothesized to play a role in thymocyte differentiation and/or thymic selection. The present studies were undertaken to gather additional evidence in support of a postulated association of CTX with a differentiation step of a cell population that corresponds to the murine immature double positive (CD4+CD8+TCR+) thymocyte subset. During ontogeny, cell surface expression of CTX on thymocytes can first be detected by immunocytochemistry and flow cytometry at 8 days post-fertilization, about 1 day after CD8+ cells first appear. By 12 days post-fertilization, T-cells in the entire cortex except for the outer most layer of cells, are intensely CTX positive, whereas those in the medulla are negative. This pattern persists throughout larval and postmetamorphic life.

Antibody cross-linking of the thymocyte-specific cell surface molecule CTX causes abnormal mitosis and multinucleation of tumor cells

The thymocyte-specific cell surface molecule CTX is a developmentally regulated type I transmembrane protein of the immunoglobulin superfamily which, in the amphibian Xenopus, is exclusively expressed by a large fraction of cortical thymocytes and by different cell lines derived from independent spontaneous thymic tumors. Antibody cross-linking of CTX in vitro inhibits the growth of tumor cells and causes morphological alterations. Cells divide abnormally, accumulate in the G2/M phase of the cell cycle, and become multinucleated. This demonstrates, for the first time, that multinucleation can be induced by specifically cross-linking a cell surface molecule.