Avian T cell ontogeny

Effects of aging and sex steroids on the localization of T cell subsets in the ovary of chicken, Gallus domesticus

The goal of this study was to determine the effects of aging and sex steroids on the frequency of T cells in hen ovary. Cryostat sections of ovarian tissues of immature and laying hens and those of immature hens treated with or without diethylstilbestrol (DES) or progesterone were immunostained for T cells using mouse anti-chicken CD3 (antigen of mature T cells), CD4 (antigen of helper T cells), and CD8 (antigen of cytotoxic T cells) monoclonal antibodies. Positive cells were observed under a light microscope and counted using a computer-assisted image analyzer. The frequency of CD3(+), CD4(+), and CD8(+) cells in the ovarian stroma and theca of primary follicles was significantly greater in young laying hens than in immature and old laying hens (P < 0.01). The CD4:CD8 ratio was significantly higher in the ovarian stroma of old laying hens than that of immature hens (P < 0.01), which was due to a greater decrease of CD8(+) cells than of CD4(+) cells. The frequency of CD3(+), CD4(+), and CD8(+) cells was significantly greater in the stroma and theca of primary follicles of DES-treated birds than in those of progesterone-treated and control birds (P < 0.01). Progesterone had no significant effect on the population of each subset of T cells. These results suggest that T cell frequency increases in association with sexual maturation and decreases thereafter during aging with an increase of CD4:CD8 ratio. Also, it is likely that estrogen is one of the factors which stimulates the influx of T cells in the hen ovary.

T cell receptor gene deletion circles identify recent thymic emigrants in the peripheral T cell pool

Progenitor cells undergo T cell receptor (TCR) gene rearrangements during their intrathymic differentiation to become T cells. Rearrangements of the variable (V), diversity (D), and joining (J) segments of the TCR genes result in deletion of the intervening chromosomal DNA and the formation of circular episomes as a byproduct. Detection of these extrachromosomal excision circles in T cells located in the peripheral lymphoid tissues has been viewed as evidence for the existence of extrathymic T cell generation. Because all of the T cells in chickens apparently are generated in the thymus, we have employed this avian model to determine the fate of the V(D)J deletion circles. In normal animals we identified TCR Vgamma-Jgamma and Vbeta-Dbeta deletion circles in the blood, spleen, and intestines, as well as in the thymus. Thymectomy resulted in the gradual loss of these DNA deletion circles in all of the peripheral lymphoid tissues. A quantitative PCR analysis of Vgamma1-Jgamma1 and Vbeta1-Dbeta deletion circles in splenic gamma delta and Vbeta1(+) alphabeta T cells indicated that their numbers progressively decline after thymectomy with a half-life of approximately 2 weeks. Although TCR deletion circles therefore cannot be regarded as reliable indicators of in situ V(D)J rearrangement, measuring their levels in peripheral T cell samples can provide a valuable index of newly generated T cells entering the T cell pool.

Characterization of prethymic progenitors within the chicken embryo

The thymic primordium in both birds and mammals is first colonized by cells emerging from the intra-embryonic mesenchyme but the nature of these precursors is poorly understood. We demonstrate here an early embryonic day 7 prethymic population with T lymphoid potential. Our work is a phenotypic analysis of, to date, the earliest embryonic prethymic progenitors arising in the avian para-aortic area during ontogeny. The phenotype of these cells, expressing the cell surface molecules alpha2beta1 integrin, c-kit, thrombomucin/MEP21, HEMCAM and chL12, reflects functional properties required for cell adhesion, migration and growth factor responsiveness. Importantly, the presence of these antigens was found to correlate with the recolonization of the recipient thymus following intrathymic cell transfers. These intra-embryonic cells were also found to express the Ikaros transcription factor, the molecular function of which is considered to be prerequisite for embryonic lymphoid development.

Chicken CD4, CD8alphabeta, and CD8alphaalpha T cell co-receptor molecules

New knowledge has recently been obtained about the evolutionary conservation of CD4, CD8alphaalpha, and CD8alphabeta T cell receptor (TCR) co-receptor molecules between chicken and mammals. This conservation extends from biochemical structure and tissue distribution to function. Panels of monoclonal antibodies and polyclonal antisera against different epitopes of chicken CD8 and CD4 molecules have proven their value in several recent studies. Chicken CD8 allotypes and homozygous strains carrying these allotypes have been established and these strains provide excellent models for further studies. The extensive polymorphism of CD8alpha in chickens has not been observed in any other species, suggesting that CD8alpha and CD8beta have evolved under different selective pressure in the chicken. A large peripheral blood CD4+CD8+ T cell population in chicken resembles that observed in some human individuals but the inheritance of peripheral blood CD4CD8alphaalpha T cells in the chicken is a unique observation, which suggests the presence of a single gene responsible for CD8alpha, but not CD8beta, specific expression. Despite these unique findings in chicken, the data on CD4, CD8alphaalpha, and CD8alphabeta molecules show that they have evolved before the divergence of mammalian and avian branches from their reptilian ancestors.

CD4, CD8 and TCR defined T-cell subsets in thymus and spleen of 2- and 7-week old commercial broiler chickens

To better understand immune development and function in meat-type chickens (broilers), the proportions of T-cells expressing CD4, CD8, and T-cell receptors (TCR) in the thymus and spleen were determined by three-color fluorescence and flow cytometry in 2- and 7-week old broilers raised in commercial growing conditions. Broiler thymocytes consisted of single-(CD4+CD8- and CD4-CD8+) and double-(CD4+CD8+) positive subpopulations. Within these CD4+ and/or CD8+ thymocyte populations, all types of TCR (y delta, V beta 1 alpha beta, and V beta 2 alpha beta) could be identified. In the thymus, percentages of CD4+CD8- cells increased, CD4-CD8+ cells remained unchanged, and CD4+CD8+ cells decreased between 2 and 7 weeks of age. In the spleen, in addition to single-positive lymphocytes, double-positive populations were identified, expressing either y delta or alpha beta TCR. The percentage of CD4+CD8- splenocytes decreased, and the percentages of both CD4-CD8+ and CD4+CD8+ splenocytes increased between 2 and 7 weeks of age. Age-associated shifts in TCR usage (the proportion of cells expressing a certain type of TCR) were observed in the single-positive, but not in the double-positive, T-cell populations of both thymus and spleen. This multiparameter cell population analysis in broilers demonstrates thymic and splenic T-cell subsets similar to those previously described in layers. Differences in the proportions among T-cell subsets between 2- and 7-week old broilers likely reflect a more competent immune system in the older birds.

Expression of chL12 surface antigen is associated with cell survival in the avian bursa of Fabricius

During B-cell development in the avian bursa of Fabricius most of the developing B cells die by apoptosis and only a minority survive to emigrate into the periphery. Recently, it has been shown that when developing bursal cells become mature and ready to migrate they start to express chL12 antigen. The expression of this cell-surface molecule was found to be associated with the survival of the bursal cells both after in vitro culture and after in vivo cyclophosphamide (CY) treatment. The frequency of early apoptotic cells in freshly isolated bursal cells was found to be high. The high susceptibility of these cells to apoptosis is in line with the finding of low bcl-2 mRNA expression. We conclude that expression of avian chL12 antigen is associated with the survival of bursal cells.

Thymic function can be accurately monitored by the level of recent T cell emigrants in the circulation

Expression of the avian chT1 thymocyte antigen persists on a subpopulation of peripheral T cells enriched in the DNA deletion circles created by alphabeta and gammadelta TCR gene rearrangements. The chT1+ cells are evenly distributed among all of the peripheral T lymphocyte compartments. The levels of chT1+ T cells in the periphery gradually decline in parallel with age-related thymic involution, and these cells disappear following early thymectomy. Experiments in which variable numbers of the 14 thymic lobes are removed in young chicks indicate a direct correlation between the levels of circulating chT1+ cells and residual thymic mass. Measurement of recent thymic emigrants in the periphery thus provides an accurate indication of thymic function.

Ontogeny of the immune system: gamma/delta and alpha/beta T cells migrate from thymus to the periphery in alternating waves

The embryonic thymus is colonized by the influx of hemopoietic progenitors in waves. To characterize the T cell progeny of the initial colonization waves, we used intravenous adoptive transfer of bone marrow progenitors into congenic embryos. The experiments were performed in birds because intravenous cell infusions can be performed more efficiently in avian than in mammalian embryos. Progenitor cells, which entered the vascularized thymus via interlobular venules in the capsular region and capillaries located at the corticomedullary junction, homed to the outer cortex to begin thymocyte differentiation. The kinetics of differentiation and emigration of the T cell progeny were analyzed for the first three waves of progenitors. Each progenitor wave gave rise to gamma/delta T cells 3 d earlier than alpha/beta T cells. Although the flow of T cell migration from the thymus was uninterrupted, distinct colonization and differentiation kinetics defined three successive waves of gamma/delta and alpha/beta T cells that depart sequentially the thymus en route to the periphery. Each wave of precursors rearranged all three TCR Vgamma gene families, but displayed a variable repertoire. The data indicate a complex pattern of repertoire diversification by the progeny of founder thymocyte progenitors.

Identification and analysis of the chicken CD3epsilon gene

The chicken T cell receptor CD3epsilon gene was isolated using a degenerate polymerase chain reaction. The 1883 bp long cDNA encoded a transmembrane protein of 16.9 kDa lacking N-linked glycosylation sites. Comparison of the chicken and mammalian CD3epsilon proteins revealed low homology in the extracellular domain with clusters of similarities located around the N-terminal cysteine residue and proximal to the transmembrane region. The high conservation of the cytoplasmic domain included motifs important for signal transduction. The alignment of all CD3gamma, CD3delta and CD3epsilon proteins allowed the identification of highly conserved residues and motifs. Southern blot analysis indicated the presence of a single copy CD3epsilon gene. The expression of the CD3epsilon transcript was limited to T cells and natural killer cells. A recessive mutation of the CD3epsilon gene in the CB chicken strain enabled the mapping of the epitope recognized by the CT3 monoclonal antibody. This analysis of the first non-mammalian CD3epsilon gene provides novel information about evolutionary conserved structural features and its expression in natural killer cells.

Characterization of avian T-cell receptor gamma genes

In birds and mammals T cells develop along two discrete pathways characterized by expression of either the alpha beta or the gamma delta T-cell antigen receptors (TCRs). To gain further insight into the evolutionary significance of the gamma delta T-cell lineage, the present studies sought to define the chicken TCR gamma locus. A splenic cDNA library was screened with two polymerase chain reaction products obtained from genomic DNA using primers for highly conserved regions of TCR and immunoglobulin genes. This strategy yielded cDNA clones with characteristics of mammalian TCR gamma chains, including canonical residues considered important for proper folding and stability. Northern blot analysis with the TCR gamma cDNA probe revealed 1.9-kb transcripts in the thymus, spleen, and a gamma delta T-cell line, but not in B or alpha beta T-cell lines. Three multimember V gamma subfamilies, three J gamma gene segments, and a single constant region C gamma gene were identified in the avian TCR gamma locus. Members of each of the three V gamma subfamilies were found to undergo rearrangement in parallel during the first wave of thymocyte development. TCR gamma repertoire diversification was initiated on embryonic day 10 by an apparently random pattern of V-J gamma recombination, nuclease activity, and P-and N-nucleotide additions to generate a diverse repertoire of avian TCR gamma genes early in ontogeny.

B-haplotype control of CD4/CD8 subsets and TCR V beta usage in chicken T lymphocytes

The major histocompatibility (B) complex of the chicken contains genes similar to Class I (B-F) and Class II (B-L beta) genes in mammals, as well as a highly-polymorphic gene family (B-G) whose exact function is not known. Specific B-haplotypes are strongly associated with resistance to a number of infectious diseases, and with immune responses to soluble and cellular antigens. In mammals, Class I and Class II molecules control development of the T cell repertoire, including selection of CD4+ and CD8+ T cells. One study of chickens reported that low CD4:CD8 ratio was associated with the B4 haplotype, which shares expressed B-F/B-L genes with the B13 haplotype. In studies reported here, chickens of two haplotypes carried in the Auburn R line, B302 and B305 (which is B13-related), were evaluated for percentages of T cells expressing the CD4, CD8, CD3, TCR1, TCR2 and TCR3 antigens in peripheral blood lymphocytes (PBL), thymus, and spleen. These two haplotypes were chosen for comparison because they differ in resistance to Marek's disease (MD) and are closely-related in B-F and B-L genes by restriction fragment length polymorphism analyses. Homozygous birds of each B haplotype were produced from crosses of (B302 x B305)F1 sires and dams. PBL, thymocytes, and splenocytes from B302 homozygotes had higher CD4:CD8 ratios than B305 homozygotes. However, CD4:CD8 ratio differences could not be attributed to haplotype-controlled differences in V beta usage within CD4/CD8 subsets, as has been described for certain V beta families in mice and humans. These results indicate that thymic selection events involving CD4 and CD8 subsets and TCR V beta usage are controlled by a gene or genes closely-linked to the B-complex, which may or may not be Class I or Class II genes.

Expression of an avian CD6 candidate is restricted to alpha beta T cells, splenic CD8+ gamma delta T cells and embryonic natural killer cells

A candidate avian CD6 homolog is identified by the S3 monoclonal antibody. The S3 antigen exists in a phosphorylated glycoprotein form of 130 kDa and a nonphosphorylated form of 110 kDa. Removal of phosphate groups and N-linked carbohydrates indicates a 78-kDa protein core. During thymocyte differentiation, the gamma delta T cells do not express S3, whereas mature CD4+ and CD8+ cells of alpha beta lineage acquire S3 antigen. All alpha beta T cells in the blood and spleen express the S3 antigen at relatively high levels. In contrast, only the CD8+ subpopulation of gamma delta T cells in the spleen expresses the antigen and neither alpha beta nor gamma delta T cells in the intestinal epithelium express the S3 antigen. The S3 antigen is also found on embryonic splenocytes with a phenotypic profile characteristic of avian natural killer cells. The biochemical characteristics and this cellular expression pattern imply that the S3 antigen is the chicken CD6 homolog.

Gamma delta T cells are secondary participants in acute graft-versus-host reactions initiated by CD4+ alpha beta T cells

To examine the role of T cell subpopulations in an acute graft-versus-host (GVH) reaction, gamma delta T cells and alpha beta T cells expressing one of the two prototypic V beta families were negatively isolated from adult blood samples and injected into allogeneic chick embryos. CD4+ alpha beta T cells expressing either V beta 1 or V beta 2 receptors were equally capable of inducing acute GVH reactions, consistent with the idea that alpha beta T cell alloreactivity is determined by CDR3 variability. By themselves, the gamma delta T cells were incapable of inducing GVH reactions. However, host gamma delta T cells were recruited into the donor alpha beta T cell-initiated lesions, where they were activated and induced to proliferate. The data suggest that gamma delta T cells may play a secondary role in GVH reactions.

Characterization of chicken CD8-specific monoclonal antibodies recognizing novel epitopes

CD8 is a heterodimeric cell surface glycoprotein expressed primarily on thymocytes and a subpopulation of mature T lymphocytes. It binds to the invariant part of the major histocompatibility complex class I molecule and participates in antigen recognition by the major histocompatibility complex class I restricted T cells. As in mammalian species, the majority of chicken thymocytes express both CD4 and CD8, whereas peripheral T cells are either CD4- or CD8-positive. We have created a panel of mouse monoclonal antibodies detecting different cell surface epitopes on chicken CD8. The antibodies precipitate a 32-34 kDa dimeric protein from surface labelled thymocytes under reducing conditions. The identical N-deglycosylation pattern confirms that these MoAb precipitate the same heterodimeric molecule from chicken thymocyte lysates. Binding of 11-38 and 11-39 MoAb to peripheral blood T cells is totally inhibited by 11-39 and previously characterized CT8 and EP72 MoAb, further confirming their CD8 specificity. CD8 alpha-chain specificity of MoAb 11-39, 11-38, 11-30 and 11-13 is conclusively proven by staining COS-cells transfected with a plasmid containing CD8 alpha cDNA. However, MoAb 11-13, 11-30 and 11-38 do not compete with MoAb 11-39 in binding to CD8. These results demonstrate recognition of different epitopes by these MoAb. Monoclonal antibodies detecting novel epitopes on chicken CD8 provide a valuable tool for further studies on T cell development.

T-cell specific avian TdT: characterization of the cDNA and recombinant enzyme

A cDNA clone coding for avian terminal deoxynucleotidyl transferase (TdT) has been isolated and sequenced. The size of this cDNA was 2545 bp with an open reading frame of 1521 bp and a predicted translation product of 58 kDa. Comparison of this TdT sequence with other known TdT sequences has revealed a very high degree of homology at both the DNA and predicted amino acid levels. The chicken TdT cDNA was expressed in a bacterial system and the protein was purified by affinity chromatography. The purified recombinant enzyme, with a specific activity of approximately 1700 U/mg protein, was significantly less active than TdTs from mammalian species. This finding correlates with the observation that TdT isolated from avian thymus has lower activity than that isolated from any mammalian thymus source. Northern blot hybridization analyses and reverse transcription PCR of RNA preparations were carried out with the chicken cDNA. The data generated from these experiments revealed that the TdT RNA was only expressed in the thymus and not in the bone marrow or the bursa of Fabricius during pre- and post hatching chicken development. These data suggest that while TdT is probably involved in N region addition in chicken T-cell receptor genes, it is unlikely to play a role in diversification of immunoglobulin genes.

Intraembryonic haemopoietic cells and early T cell development

T cell precursors in the chick embryo have been localized into the intraembryonic mesenchyme (IEM) and into the para-aortic region before the first wave of the thymic colonization on embryonic day (ED) 6,5-8. The cell surface markers of avian prethymic stem cells are not known. It is also not known whether these precursor cells are already committed to the T cell lineage before their thymic colonization. In 7-day-old chick embryos Ov+ cells were found in the para-aortic region. Also the endothelial cells of the embryonic dorsal aorta were positively stained. Ov antigen might represent a very primitive marker for precursor cells having the potentiality to differentiate both to haemopoietic and endothelial cells. Scattered CD45+ cells were observed in the same para-aortic area as in many haemopoietic areas in the loose embryonic mesenchymal tissues. CD8 alpha (MoAb 3-298) expressing haemopoietic cells were detected before thymic colonization on ED6. In flow cytometric analysis of IEM precursors Ov, CD45 and CD8 alpha expressing cells seemed to form distinct subsets suggesting heterogeneity of these haemopoietic cells.

Regulation of RAG-2 protein expression in avian thymocytes

The recombinase-activating genes, RAG-1 and RAG-2, have been shown to be necessary to initiate the process of V(D)J recombination during the ontogeny of lymphocytes. While much is known about the end products of this rearrangement process, little is known about the function or regulation of the components of the recombinase system. To this end, we have generated a monoclonal antibody to the chicken RAG-2 protein. Chicken thymocytes were found to express high levels of RAG-2, part of which is phosphorylated. Within thymocytes, RAG-2 is expressed primarily within the nucleus. RAG-2 protein levels are high in the CD4- CD8- and CD4+ CD8+ immature thymocytes but absent at the single-positive CD4+ CD8- or CD4- CD8+ stage of thymocyte development. Mitogenic stimulation of thymocytes with phorbol myristate acetate and ionomycin results in down-regulation of RAG-2 expression. Consistent with these data, in vivo levels of RAG-2 are markedly lower in proliferating thymocytes than in smaller, G0/G1 cells. Down-regulation of RAG-2 expression appears to occur before cells enter S phase, suggesting that RAG-2 function may be limited to noncycling cells.

Prolactin and early T-cell development in embryonic chicken

Currently, the information available on the ontogeny of the immune-neuroendocrine network is somewhat scant. However, increasing data suggest a role for prolactin, an important immunoregulatory molecule that resembles cytokines, in early T-cell development. In this article, Javier Moreno and colleagues present evidence for this role using the chicken embryo as a model system.

Regulation of RAG-2 protein expression in avian thymocytes

The recombinase-activating genes, RAG-1 and RAG-2, have been shown to be necessary to initiate the process of V(D)J recombination during the ontogeny of lymphocytes. While much is known about the end products of this rearrangement process, little is known about the function or regulation of the components of the recombinase system. To this end, we have generated a monoclonal antibody to the chicken RAG-2 protein. Chicken thymocytes were found to express high levels of RAG-2, part of which is phosphorylated. Within thymocytes, RAG-2 is expressed primarily within the nucleus. RAG-2 protein levels are high in the CD4- CD8- and CD4+ CD8+ immature thymocytes but absent at the single-positive CD4+ CD8- or CD4- CD8+ stage of thymocyte development. Mitogenic stimulation of thymocytes with phorbol myristate acetate and ionomycin results in down-regulation of RAG-2 expression. Consistent with these data, in vivo levels of RAG-2 are markedly lower in proliferating thymocytes than in smaller, G0/G1 cells. Down-regulation of RAG-2 expression appears to occur before cells enter S phase, suggesting that RAG-2 function may be limited to noncycling cells.

Evolutionarily conserved function of CD28 in alpha beta T cell activation

The functional role of the chicken homologue of CD28 was studied. It is expressed on all thymocytes, and both V beta 1- and V beta 2-family expressing peripheral alpha beta T cells. Peripheral gamma delta T cells are CD28-negative. Monoclonal antibody against CD28 had a costimulatory effect on T cells stimulated by phorbol myristate acetate (PMA), concanavalin A or MoAb against TCR. V beta 1 and V beta 2 expressing cells responded equally well to stimulation with anti-CD28 in combination with PMA. These responses were resistant to cyclosporin A, but inhibited by herbimycin A, suggesting that CD28 employs a signalling pathway at least partly distinct from that triggered by TCR/CD3. These data indicate a striking conservation of the costimulatory function of CD28 and emphasize the importance of this costimulatory pathway.

Gamma delta and alpha beta T cells are equally susceptible to apoptosis

Little is known about the role of apoptosis in the regulation of gamma delta T cell development and function. We have used chicken as a model to study apoptosis of gamma delta T cells at different stages of their development. Apoptosis was measured with electrophoretic analysis of DNA fragmentation and flow cytometric determination of DNA content combined with immunofluorescence staining of cell surface molecules. In vitro culture, dexamethasone, and gamma-irradiation induced apoptosis of both gamma delta TCR+ thymocytes and peripheral gamma delta T cells. Apoptosis could be induced even in the earliest thymic gamma delta thymocytes on embryonic day 13. Resting peripheral blood gamma delta T cells were more resistant to apoptosis than thymocytes and spleen cells. Following polyclonal activation of splenic gamma delta T cells by Con A, the proportion of the CD8+ gamma delta T cell blasts decreased significantly when recultured without further stimulation. These results indicate that gamma delta T cells are susceptible to apoptosis in a manner similar to alpha beta T cells, and suggest that apoptosis plays an important role in the regulation of the development and function of both thymic and peripheral gamma delta T cells.

Central role of CD4+ T cells in avian immune response

Chicken alpha beta T cells express either CD4 or CD8 accessory molecules, whereas most of the gamma delta T cells do not. The functional significance of the alpha beta T cells is relatively well understood. The CD4+ alpha beta T cells function as coordinators of the immune response, and CD8+ alpha beta T cells are the effector cells in cytotoxic responses, killing infected target cells. In comparison, the role of gamma delta T cells is so far poorly known. In chicken, the gamma delta T cells comprise a large lymphocyte subset. They can be induced to proliferate by various stimuli, but the proliferative response is dependent on CD4+ alpha beta T cells. The CD4+ T cells are also essential for the generation of antibody responses by providing help for the B cells and can influence cytotoxic responses as well. Thus, the CD4+ alpha beta T cells have a central role in the avian immune system, and their activation is a prerequisite for responses by other types of cells, including gamma delta T cells.

Characterization of avian natural killer cells and their intracellular CD3 protein complex

Natural killer (NK) cell activity appears to be conserved throughout vertebrate development but NK cells have only been well characterized in mammals. Candidate NK cells have been identified in the chicken as cytoplasmic CD3+ and surface T cell receptor (TCR)/CD3- (TCRO) lymphocytes that often express CD8. The fact that the TCRO cells are abundant in the embryonic spleen before T cells enter this organ allowed us to cultivate the embryonic TCRO cells using growth factors derived from activated adult lymphocytes. These TCRO cells were cytotoxic for an NK target cell line. They expressed cell surface CD8, a putative interleukin-2 receptor, CD45 and a receptor for IgG, but did not express CD4, major histocompatibility complex class II or immunoglobulin. Biochemical analysis of the cytoplasmic CD3 antigen revealed two of the three CD3 gamma, delta and epsilon homologues, and RNA transcripts for the third. The CD3 monoclonal antibody also precipitated a 32-kDa dimer that may represent a heterodimer of different CD3 constituents. TCR alpha and beta gene transcripts were not detected in the TCRO cells. These results indicate that the avian TCRO cell is the mammalian NK cell homologue. The shared evolutionary features of T cells and NK cells in birds and mammals support the idea that they derive from a common progenitor.

T cell development in the chicken

This review summarizes our current view of gamma delta and alpha beta T cell development in the chicken. In it we emphasize the functional interplay between the gamma delta and alpha beta T cell subpopulations.

Development of T cell immune responsiveness in the chicken

Chickens are highly susceptible to infection by opportunistic pathogens during the first few days after hatching. This observation has generally been attributed to an immaturity of the immune system; however, the mechanisms responsible are not known. This study investigated the ability of T cells from chickens of various ages to respond to immune stimulation. Splenic T cells were cultured in vitro and stimulated with various mitogens including Con A, PHA and monoclonal anti-CD3 antibody. T cells obtained from adult chickens proliferated extensively and produced high levels of IL-2, haemopoietic growth factors and IFN following stimulation. In contrast, it was found that T cells from 1 day old chickens failed to proliferate and secrete cytokines when similarly cultured. Reactivity to mitogens gradually developed between days 2 and 4, and by 1 week of age the level of responsiveness was equivalent to that observed with T cells obtained from adult chickens. Whereas T cells from 1 day old chicks were found to be phenotypically mature and capable of binding mitogens as effectively as T cells from adult birds, they were functionally immature as assessed by their inability to proliferate or produce cytokines following immune stimulation. In addition, cells present in the spleen of 1 day old chicks constitutively produced a soluble inhibitor that prevented the proliferation of stimulated adult T cells. The production of inhibitor decreased dramatically by the second day post-hatching which coincided with an enhanced ability of T cells to respond to immune stimulation.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of T-cell receptor alpha-chain genes in the chicken

T-cell receptor (TCR) alpha-chain (TCR alpha) and beta-chain (TCR beta) genes are well characterized in mammals, while only TCR beta genes have been identified in other vertebrates. To identify avian TCR alpha genes, we used monoclonal anti-CD3 antibodies to isolate chicken TCR alpha for peptide sequence analysis. Degenerate oligonucleotide probes were then used to isolate a candidate TCR alpha cDNA clone that hybridized with a 1.7-kb mRNA species present only in alpha beta T cells and in tissues populated by these cells. Southern blot analysis revealed gene rearrangement in thymocytes and alpha beta T-cell lines. The TCR alpha cDNA candidate encoded an open reading frame of 275 amino acids, the predicted variable (V)-, joining (J)-, and constant (C)-region amino acid sequences of which shared approximately 40%, 60%, and 25% homology with corresponding mammalian sequences. A single C alpha gene and approximately 25 V alpha genes were identified by using region-specific probes. The V alpha cDNA probe isolated from a V beta 1+ cell line reacted with transcripts from one of five V beta 2+ cell lines, suggesting shared use of V alpha genes by V beta 1+ and V beta 2+ T cells and the existence of other V alpha gene families. A genomic V alpha sequence was flanked by classical recombination signal sequences but, unlike previously defined V genes, the leader and V alpha region were encoded by a single exon. The data indicate evolutionary conservation of the basic TCR alpha gene structure in birds and mammals.

Distribution of Ia antigen positive cells in chicken embryos infected with oncogenic Marek's disease virus (MDV) and MD vaccine viruses of serotypes 1, 2 and 3

Chick embryos infected at Day 13 of embryonic development (ED) with the oncogenic serotype 1 Marek's Disease Virus, isolate B (MDV-B) and three MDV vaccines (CVI988, SB1 and HVT, serotypes 1, 2 and 3, respectively) and uninfected chick embryos were studied for the distribution of Ia antigen positive dendritic cells (DC), B cells and MDV antigen positive (Ag+) cells in the lymphoid organs and chorioallantoic membrane (CAM). The immunofluorescence study was conducted on acetone-fixed organ touch impressions using monoclonal antibodies to Ia antigen, and MDV serotypes 1, 2 and 3 and polyclonal antibodies to bursal Ig-bearing (Ig+) B cells. DC were found mainly in the thymus and spleen and Ig+ cells in the bursa, thymus and spleen of normal embryos. All virus-infected embryos had MDV Ag+ cells in the spleen. MDV-B and SB1 infected embryos also had MDV Ag+ cells in the bursa, MDV-B Ag+ cells in the CAM and SB1-Ag+ cells in the thymus. Infection with MDV altered the distribution pattern of DC in a serotype-specific manner: to a lesser extent, infection with MDV-B and SB1 induced their appearance in the CAM, while HVT and CVI988 depleted the DC population from all organs except the bursa and the thymus, respectively. Infection with MDV-B depleted the Ig+ cells from all organs. These results suggest that virus-specific patterns of change in the distribution of DC and B cells occur in various tissues and organs of the chick embryo as a result of infection with oncogenic and apathogenic strains of MDV.

v-rel induces expression of three avian immunoregulatory surface receptors more efficiently than c-rel

The c-rel gene is a member of NF-kappa B/rel family of transcription factors that regulate expression of a variety of immunoregulatory molecules. The viral oncogene, v-rel, is a truncated and mutated form of the turkey c-rel gene expressed by reticuloendotheliosis virus, strain T. In this study, we demonstrated that three avian immunoregulatory receptors, major histocompatibility (MHC) antigens class I and class II as well as the interleukin-2 receptor (IL-2R), were induced on the surface of splenic tumor cells isolated from chickens infected with reticuloendotheliosis virus, strain T. All cell lines derived from splenic tumors expressed these three proteins. Their expression also correlated with the appearance of endogenous c-rel during a graft-versus-host reaction. In vitro, both c-rel and v-rel induced MHC class I, MHC class II, and IL-2R on an avian B-lymphoid cell line, DT95, and a T-lymphoid cell line, MSB-1. Quantitative kinetic analysis demonstrated both the accumulation of MHC class II mRNA and the appearance of surface MHC class II protein in response to the synthesis of either v-rel or c-rel. We show that v-rel induced the expression of MHC class II in the avian B-cell lines DT40 and DT95 more rapidly than c-rel and that, several weeks after infection, v-rel induced MHC class II as much as 50-fold more efficiently than c-rel. Finally, in vitro infection of splenocytes with retroviruses that express v-rel or c-rel induced MHC class I, MHC class II, and IL-2R expression. Quantitative analysis confirmed that p59v-rel was consistently more efficient at inducing expression of all three immunoregulatory receptors than exogenous p68c-rel. These data suggest that during tumor development, v-rel functions to induce (or suppress) the expression of genes similarly induced (or suppressed) by c-rel. The observations reported in this study are not in agreement with a model in which v-rel promotes tumor development by functioning as a dominant negative mutant of c-rel. In contrast, these findings support the hypothesis that lymphocyte immortalization and tumor development are the result, at least in part, of the capacity of v-rel to function as a dominant positive mutant that induces expression of genes normally regulated by c-rel.

Studies on lymphocyte subpopulations and the effect of age on immune competence in turkeys

We characterized the lymphocyte subpopulations and investigated the effect of age on cellular and humoral immunity, development of lymphoid organs, and the relative proportions of CD4+ and CD8+ cells in turkeys. The mitogenic responses of peripheral T cells were poorly developed at hatch but developed rapidly after hatch and reached adult levels by 2 weeks-of-age. The average percentage of CD4+ cells was 45, 29.8, and 26.3 in the thymi, peripheral blood, and spleens, respectively, in turkeys. The mean percentage of CD8+ cells in the thymi, peripheral blood, and spleens of turkeys was 53.8, 13.6, and 15.5, respectively. Age did not influence the relative proportions of CD4+ and CD8+ T cells in the spleens and peripheral blood of turkeys. The mean percentages of IgM+ cells in the bursae and spleens were 78.5 and 26.8, respectively. Day-old turkeys did not develop detectable antibodies to either thymus dependent or independent antigens. However, 2 week or older turkeys showed good humoral responses. Inoculation of BSA at hatch induced tolerance, whereas injection of SRBC did not. Analysis of relative organ weights of turkey lymphoid organs showed that spleens and thymi developed rapidly during the first week-of-age.

bcl-x, a bcl-2-related gene that functions as a dominant regulator of apoptotic cell death

We report the isolation of bcl-x, a bcl-2-related gene that can function as a bcl-2-independent regulator of programmed cell death (apoptosis). Alternative splicing results in two distinct bcl-x mRNAs. The protein product of the larger mRNA, bcl-xL, is similar in size and predicted structure to Bcl-2. When stably transfected into an IL-3-dependent cell line, bcl-xL inhibits cell death upon growth factor withdrawal at least as well as bcl-2. Surprisingly, the second mRNA species, bcl-xS, encodes a protein that inhibits the ability of bcl-2 to enhance the survival of growth factor-deprived cells. In vivo, bcl-xS mRNA is expressed at high levels in cells that undergo a high rate of turnover, such as developing lymphocytes. In contrast, bcl-xL is found in tissues containing long-lived postmitotic cells, such as adult brain. Together these data suggest that bcl-x plays an important role in both positive and negative regulation of programmed cell death.

Helper activity of CD4+ alpha beta T cells is required for the avian gamma delta T cell response

We have studied the in vitro activation of chicken gamma delta T cells. Both splenic alpha beta and gamma delta T cells obtained from complete Freund's adjuvant-primed chickens proliferated in vitro when stimulated with mycobacterial sonicate or purified protein derivative of Mycobacterium tuberculosis. When CD4+ cells or alpha beta T cell receptor (TcR)-positive cells were removed, both the proliferation and the blast formation of gamma delta T cells in response to mycobacterial antigens were abrogated. The response was restored if supernatant from concanavalin A (Con A)-activated lymphocyte cultures (CAS) as a source of helper factors was added together with the specific antigen purified protein derivative. The CD4- or alpha beta TcR-depleted cells still proliferated in response to Con A, although a decrease of the response was observed. To analyze the gamma delta T cell response more specifically we stimulated peripheral blood cells with immobilized monoclonal antibodies against T cell receptor. Anti-gamma delta TcR antibody alone did not induce significant proliferation. When CAS was added together with the anti-gamma delta TcR monoclonal antibody, a strong proliferation of gamma delta T cells was observed. In contrast, both V beta 1- and V beta 2-expressing alpha beta T cells proliferated in vitro in response to stimulation with the relevant anti-TcR monoclonal antibody alone. Depletion of either V beta 1+ or V beta 2+ T cell subset alone had no negative effect on the proliferation or blast formation of gamma delta T cells stimulated with mycobacterial antigens. Taken together our results suggest that CD4+ alpha beta T cells (both V beta 1- and V beta 2-expressing) play a role in the activation and response of chicken gamma delta T cells.

In situ analyses of in ovo graft-vs.-host reaction induced by thymic nurse cell lymphocytes

In both mammalian and avian systems, thymic nurse cells (TNC) have been shown to harbor a heterogeneous population of T lymphocytes (TNC-L) some of which exhibit a postselectional phenotype. By transplanting micromanipulated single chicken TNC onto the chorionallantoic membrane (CAM) of major histocompatibility complex (MHC)-disparate embryos, an experimental system which allows for the detection of lymphocytes with graft-vs.-host (GVH) reactivity, we demonstrate here that TNC enclose lymphocytes that can develop into both CD4+ single-positive (sp) and CD8+ sp, T cell receptor (TcR) alpha beta+, or TcR gamma delta+ cells. This finding was additionally confirmed by serial transfer of primary expanded alloreactive T cells onto the CAM of secondary hosts. All donor TNC-L expressed MHC class II molecules and the interleukin-2 receptor alpha chain in primary and secondary GVH reactions. Furthermore, we observed selective accumulation of CD8+ and TcR gamma delta+ host lymphocytes in the CAM upon the induction of a local GVH reaction, most probably as a consequence of the pathological alteration of the epithelium.

Oligoclonality of human intestinal intraepithelial T cells

T cells bearing the T cell receptor alpha/beta (TCR-alpha/beta) are the predominant lymphocyte population in the human intestinal epithelium. To examine if normal intestinal intraepithelial lymphocytes (IEL) have a TCR repertoire distinct from the TCR-alpha/beta repertoire in peripheral blood lymphocytes (PBL), comparative analysis of relative V beta gene usage in IEL and PBL was performed by quantitative polymerase chain reaction. In each of the six individuals examined, one to three V beta families made up more than 40% of the total V beta transcripts detected in the IEL, whereas there was a more even distribution of V beta gene usage in the paired PBL. The predominant V beta families, especially V beta 1, V beta 2, V beta 3, and V beta 6, were frequently shared among IEL of different individuals. PCR cloning and sequence analysis of the predominant V beta 6 family in two individuals revealed an identical V-D-J-C sequence in 13 of 21 clones obtained from one donor, and a different repeated sequence in 18 of 27 clones examined in the second donor. These data suggest that the V beta skewing in IEL is due to an oligoclonal T cell expansion and may reflect the response of the intestinal mucosal immune system to a restricted set of as yet undefined antigens present in the gut.

Two distinct alpha beta T-cell lineages can be distinguished by the differential usage of T-cell receptor V beta gene segments

Avian T cells can be divided into three subpopulations based on their expression of distinct T-cell receptors (TCR1, TCR2, and TCR3), ontogeny, and tissue distribution. The TCR1 cells appear to be the equivalent of mammalian gamma delta cells, but the derivation of cells expressing TCR2 and TCR3 has been unclear. Here we report that chickens contain two families of TCR beta variable (V) gene segments, V beta 1 and V beta 2. Furthermore, TCR2 and TCR3 represent subsets of alpha beta cells that are defined by mutually exclusive usage of these two families of V beta gene segments. Sequence comparisons of V beta 1 and V beta 2 with mammalian TCR beta V segments reveal that V beta 1 gene segments encode the conserved amino acids used to define the mammalian V beta consensus subgroup I, while V beta 2 encodes the amino acids used to define the mammalian V beta subgroup II. Although the beta chains of TCR2 and TCR3 cells are encoded by the same diversity (D), joining (J), and constant (C) region segments, V beta 1 gene segments undergo rearrangement before V beta 2 gene segments during T-cell development. This may result from the fact that TCR2 cells undergo V-DJ joining by deletional rearrangement, whereas TCR3 cells undergo V-DJ joining by inversional rearrangement. These data suggest that the TCR alpha beta cells can be divided into two distinct and evolutionarily conserved lineages based on V beta gene segment usage. The clear-cut separation of these lineages in the chicken may help to define their immunologic role.

Chicken T-cell receptor beta-chain diversity: an evolutionarily conserved D beta-encoded glycine turn within the hypervariable CDR3 domain

Unlike mammals, chickens generate an immunoglobulin (Ig) repertoire by a developmentally regulated process of intrachromosomal gene conversion, which results in nucleotide substitutions throughout the variable regions of the Ig heavy- and light-chain genes. In contrast to chicken Ig genes, we show in this report that diversity of the rearranged chicken T-cell receptor (TCR) beta-chain gene is generated by junctional heterogeneity, as observed in rearranged mammalian TCR genes. This junctional diversity increases during chicken development as a result of an increasing base-pair addition at the V beta-D beta and D beta-J beta joints (where V, D, and J are the variable, diversity, and joining gene segments). Despite the junctional hypervariability, however, almost all functional V beta-D beta-J beta junctions appear to encode a glycine-containing beta-turn. Such a turn may serve to position the amino acid side chains of a hypervariable TCR beta-chain loop with respect to the antigen-binding groove of the major histocompatibility complex molecule. Consistent with this hypothesis, the germ-line D beta nucleotide sequences of chickens, mice, rabbits, and humans have been highly conserved and encode a glycine in all three reading frames.