Implants of quail thymic epithelium generate permanent tolerance in embryonically constructed quail/chick chimeras

In situ implantation of a quail wing bud into a chick embryo at 4 days of incubation (E4) regularly results in the normal development of the implant followed by its acute rejection starting within two weeks post-hatching. If the epithelial thymic rudiments of the quail donor are implanted into the branchial arch area of the chick recipient after partial removal of its own thymic primordia, a chimeric thymus develops in the chick host and this induces tolerance to the quail wing by the chick recipient. The species identity of cells in chimeric thymuses was mapped using Feulgen-Rossenbeck' staining and immunolabelling with monoclonal antibodies directed against quail or chick B-L antigens. Certain lobes contained only chick cells both at the stromal and hemopoietic cell levels. Others had a quail epithelial stroma containing host hemopoietically derived cells. Only chimeras in which at least one third of the thymic lobes were chimeric showed permanent tolerance to the grafted wing. Since the two species exhibit distinct developmental rates, we decided to study the kinetics of thymic involution after birth. Although the changes in thymus weight and histological structure are fundamentally similar in quail and chick, those in the quail start about 7-8 weeks earlier. In the chimeric thymuses, the lobes whose epithelial cells were quail involuted at the rate of control quail showing no influence of the hemopoietic thymic compartment in this process. Tolerance induced by the thymic epithelium during embryogenesis and in early postnatal life was maintained after a profound involution of the quail thymic graft had occurred.     

Relationships between terminal transferase expression, stem cell colonization, and thymic maturation in the avian embryo: studies in thymic chimeras resulting from homospecific and heterospecific grafts

Terminal deoxynucleotidyl transferase (TdT) can be detected in 11- to 12-day-old embryonic chick thymuses 5 to 6 days after the first influx of lymphoid stem cells into the thymic rudiment. To identify the main factors of TdT induction, grafting experiments were devised in such a way that the age of the grafted thymus and that of the host were different. Uncolonized embryonic chick thymuses were grafted into chick hosts of different ages. Under these conditions, lymphoid differentiation arose from host lymphoid stem cells (LSC) invading the thymic rudiment. TdT immunofluorescent detection in the first wave of thymocytes showed that the percentages of TdT+ cells were related to the total age of the explant and not to the age of the host (11 to 17 days). Similar results were obtained when the chick thymic rudiment was transplanted into quail embryos, showing that quail LSC have TdT inducibility similar to that of chick LSC while developing in a chick thymic environment. Colonized chick thymuses were also grafted into quail embryos to compare the TdT inducibility of the first lymphoid generation (of chick type) and of the second (of quail origin), taking advantage of the different chromatin structure of quail and chick cells. In these experiments, the majority of chick cells remained TdT negative for as long as 10 days, whereas most lymphocytes of the second generation became TdT+ soon after their arrival in the grafted thymus. Therefore, during embryonic life, most TdT+ cells were derived from the second wave of stem cells, but some early stem cells were also able to acquire the enzyme. In a final series of experiments, early thymic rudiments were cultured in vitro with 14- to 16-day-old bone marrow and then grafted into 3-day-old host embryos. Under these conditions, bone marrow LSC contributed to a variable proportion of the first generation of thymocytes. The percentage of TdT+ cells among the progeny of these bone marrow stem cells was found to be two times higher than that of thymocytes derived from host LSC. These results suggest that, in addition to intrathymic environmental factors, the origin of LSC influences the frequency of TdT expression in their progeny.     

Control of helper-T-cell proliferation by recognition of Ia and Mac-1 antigens on phagocytic cells of the thymic reticulum

Phagocytic cells of the thymic reticulum (P-TR) have been previously described as being Ia-positive, Mac-1-positive accessory cells which pursue a close relationship with thymocytes. They form rosettes with thymocytes, and these rosettes are inhibited by antibody directed against the complement receptor type 3 CR3 (anti-Mac-1). P-TR induce the proliferation of syngeneic thymocytes. In the present paper, we show that thymocytes enriched in mature medullary type are induced to proliferate in coculture with syngeneic P-TR, while the cortical type does not. After 5 days of culture, 85% of the thymocytes are of helper L3T4+Lyt-2- phenotype. As previously shown by others for syngeneic reactions, antibodies directed against related class II antigens (anti-I-A and anti-I-E) block this helper-T-cell syngeneic proliferation. A new finding is the blockage of helper-T-cell proliferation by anti-Mac-1 as well as with anti-LFA-1 antibodies, showing that accessory molecules may be as important as specific recognition of class II antigen molecules in the control of thymocyte proliferation and hence in thymocyte selection. Mac-1, like LFA-1, belongs to a novel family of differentiation antigens involved in cell interactions. The blockage of cell recognition and interaction between P-TR and thymocytes by either anti-Ia or anti-Mac-1 during the early induction phase of the syngeneic response leads to its inhibition. We demonstrate that P-TR/thymocyte interaction stimulates the enhanced expression of IL-2 receptors on thymocytes, a step which is necessary for helper-T-cell proliferation. The mechanism of syngeneic proliferation inhibition by anti-Ia, anti-Mac-1, and LFA-1 antibodies may be the prevention of IL-2 receptor expression on thymocytes, and/or the inhibition of IL-2 secretion. Although this is an in vitro model, which may not totally reflect in situ situation, our results indicate that thymic accessory cells may participate in a positive selection process which leads to helper-T-cell proliferation.     

Interspecific cell markers and cell lineage in birds

A cell marking technique based on the structural differences existing between the interphase nucleus in two closely related species of birds, the chick and the Japanese quail, is described. In all embryonic and adult cell types of the quail, a large mass of heterochromatin is associated with the nucleolus making quail and chick cells easy to identify at the single cell level after application of any DNA-specific staining procedure and also at the electron microscope level. This method has been largely used to construct chimeras in ovo and to study dynamic processes such as cell migrations or cell lineage segregation during ontogeny. Recently monoclonal antibodies specific for either quail or chick antigenic determinants (for example, class II MHC antigens) have been prepared, increasing the interest of the quail-chick chimera system as an experimental model.     

Transdifferentiation of putative neuronal cells of neural retina into lens: A demonstration by chick-quail chimeric cultures

Summary To elucidate the cell-type origin of lens cells, which differentiate in stationary cultures of neural retina, chimeric cultures between chick and quail cells were made to recombine xenoplastically the different cell fractions separated from 8- to 9-day cultures of 3.5-day-old embryonic neural retinal cells by means of centrifugation in Percoll. Extensive lentoidogenesis occurred in the recombination of the N2-fraction (consisting mostly of small round cells) with the E-fraction (containing a number of flattened epithelial cells). Taking advantage of the difference in electrophoretic mobility of chick and quail -crystallin, it was shown that this lens-specific protein, synthesized in the chimeric cultures, was mostly of the species-specificity of N2. Microscopic observations of histological sections of cell sheets of quail N2- and chick E-fraction chimeric cultures revealed that most cells with -crystallin, as identified by means of immunohistological detection, are provided with a nuclear marker characteristic of quail. By determining the level of activity of choline acetyltransferase and by examining the stainability with a fluorescent dye (Merocyanine-540), it was suggested that cells in the N2-fraction are primitive neuroblast-like cells. Thus, we can conclude that putative neuronal cells in early cultures of avian embryonic neural retina can transdifferentiate into lens cells.     

Lymphocyte depletion in thymic nurse cells: a tool to identify in situ lympho-epithelial complexes having thymic nurse cell characteristics

Summary In situ pre-existing complexes of epithelial cells and thymocytes having thymic nurse cell characteristics were visualized in the murine thymus cortex using dexamethasone as a potent killer of cortisone-sensitive thymocytes. The degradation and subsequent depletion of cortisone-sensitive thymocytes enclosed within cortical epithelial cells appeared to be paralleled by thymocyte degradation and depletion in thymic nurse cells isolated from thymic tissue fragments from dexamethasone-treated animals. This suggests that thymic nurse cells are derived from pre-existing sealed complexes of cortical epithelial cells and thymocytes. Not all thymocytes situated within in situ epithelial or thymic nurse cells complexes appear to be cortisone-sensitive: a minority of 1–2 thymocytes per complex survives the dexamethasone-treatment, thus constituting a minor subset of cortical cortisone-resistant thymocytes predominantly localized within cortical epithelial cells in situ and within thymic nurse cells derived from such structures. Cortisone resistance in thymocytes thus seems to be acquired within the cortical epithelial cell microenvironment. Cortisone-resistant thymocytes in thymic nurse cells express the phenotype of mature precursors of the T helper lineage, indicating that the in situ correlates of thymic nurse cells may play an important role in T cell maturation and selection.     

Human thymic epithelial cells function as accessory cells for autologous mature thymocyte activation

Using human thymocytes and autologous thymic epithelial (TE) cells grown in vitro in long-term culture, we have found TE cells can function as accessory cells for mitogen-induced mature thymocyte activation. Tritiated thymidine incorporation, blast formation, and protein synthesis were all induced in accessory cell-depleted thymocytes by autologous TE cells in the presence of suboptimal concentrations of PHA. After 3 days of mitogen stimulation of thymocyte-TE cell cocultures in vitro, thymocyte blasts bound to TE cells and 77 +/- 4% (mean +/- SEM) of TE cells acquired expression of major histocompatibility complex (MHC) class II (DR) antigen. TE accessory cell function for thymocyte activation was dependent on the number of TE cells added to thymocyte cultures, was not dependent on TE cell division, but did require TE cell protein synthesis. In thymocyte separation experiments, the predominant cell type responding to PHA in the presence of TE cells was T6- mature (stage III) thymocytes. Thus, human TE cells are capable of providing signals that lead to mature thymocyte activation.     

Thymic accessory cell complexes in vitro and in vivo: morphological study

Summary Murine thymic macrophages and interdigitating cells, also called thymic accessory cells, were characterized by means of light- and electron microscopy. The cells were studied in suspension, during isolation by enzymatic digestion and in vivo. They were observed as isolated cells or as components of multicellular complexes, some of which were rosettes and were composed of lymphoid cells centered on each type of accessory cell. We also noted other cell complexes including macrophages that resembled classical epithelial nurse cells. We consider that multicellular complexes represent lymphostromal associations already existing in vivo, because we observed them at the periphery of thymic pieces undergoing enzymatic treatment. The heterogeneity of macrophages that we observed in vitro was also noted in vivo. In vivo macrophages were of three types: classical phagocytic cells distributed throughout the gland, cortical elongated cells in close contact with lymphoid blast cells, and atypical nurse cells containing mitotic cells and located in the inner cortex. The morphological aspects of the latter two cell types suggest that cortical macrophages in vivo have other roles: they can be interpreted as images of positive or negative cell selection. We also believe that rosettes are formed by elongated cortical macrophages when they are enzymatically isolated from the thymus.Part of this work was presented at the Second Thymus Workshop, Rolduc, The Netherlands, April 1989     

A new marker for identifying quail cells in embryonic avian chimeras: a quail-specific antiserum

The characterization of cell behavior in quail chick chimeras has greatly increased our knowledge of the ontogeny of embryonic cell populations and the role of cell-cell interactions in development. We sought to extend the value of avian chimeras by producing a marker that would recognize cell surface components and that could be used instead of the traditional nuclear marker to identify quail cells within chimeras. We describe here a quail-specific antiserum produced by injecting chickens with a membrane fraction of 6-10-day quail embryos. By use of peroxidase coupling of a second antibody, serum reactivity was tested in tissue sections of normal quail and chick embryos and of somitic mesoderm and neural tube chimeras. The primary time period examined was 6-10 days of development. At these stages, the antiserum recognizes only quail cells and stains both plasma membrane-associated and cytoplasmic cell components. The latter characteristics allow the identification of quail axons in chimeras and facilitate visualization of quail cells at low magnification. We show that antiserum staining can also be used to identify quail cells in culture and can be combined with orthograde HRP labeling of neurons.     

Monoclonal antibodies to CD2 and lymphocyte function-associated antigen 3 inhibit human thymic epithelial cell-dependent mature thymocyte activation

Recent study of human thymocyte-thymic epithelial (TE) cell interactions has demonstrated that thymocytes bind to TE cells, and a consequence of this binding is the provision of accessory cell signals by TE cells for phytohemagglutinin (PHA)-induced mature thymocyte activation. In this paper we report on studies of the molecules involved in TE cell-dependent mature thymocyte activation. TE-thymocyte interactions necessary for PHA-induced thymocyte activation were inhibited by monoclonal antibodies against the cluster of differentiation (CD)2 antigen on thymocytes and lymphocyte function-associated (LFA)-3 antigen on TE cells. Inhibition of TE accessory cell signals by antibodies against CD2 (alpha CD2) and LFA-3 (alpha LFA-3) antigens occurred early on during thymocyte activation and prevented thymocyte interleukin 2 receptor expression. Further, alpha CD2 and alpha LFA-3 inhibited PHA-induced thymocyte activation in whole thymic explant cultures suggesting a significant role of the CD2 and LFA-3 antigens in thymocyte activation when accessory cell signals for PHA-induced thymocyte triggering were delivered by cells within an intact thymic microenvironment.     

A biological nuclear marker in cell culture: recognition of nuclei in single cells and in heterokaryons.

The biological marking technique based on quail and chick cell combinations, previously devised for in vivo experiments and organotypic cultures, can also be applied to cell cultures. In the experiments reported in this note, quail and chick fibroblasts and cardiac cells have been cultivated from 2–8 days. Up to the end of the second day of cultivation, the nucleolar structure of quail cells remains similar to that observed in organized tissues. Afterwards, the nucleolar enlargement which occurs in rapidly growing monolayer cultures results in the fragmentation of the characteristic nucleolus-associated heterochromatin in quail nuclei. However, since chick nuclei show only small dispersed chromocenters, cells of the two species can be identified even after several days in culture. Acridine orange staining is shown to be an easy and reliable procedure for identifying the nuclear marker, even in heterokaryons. Cytoplasm stains to distinguish cell types can also be applied to the same preparations.     

A study of the development of the hemopoietic system using quail-chick chimeras obtained by blastoderm recombination

The anterior part of the area pellucida from quail blastoderms extending to the 10th or the 17th somite level was substituted for the corresponding region of chick blastoderms in ovo. Reciprocal grafts were also carried out. In external appearance the resulting chimeras had a composite body, one species contributing the head and neck or the head, neck, and wing regions while the other species provided the remainder. The chimeras were always grafted on a chick yolk sac. The cellular composition of hemopoietic organs according to species was analyzed by means of the quail-chick nuclear difference, in 39 viable chimeras at 11–13 days of incubation. The thymus composition depended on the level of the boundary between the two species. In chimeras in which the quail contributed head and neck, the thymic epithelial stroma was made of quail cells while the lymphoid population was of chick origin. In contrast, when the quail contribution also extended to the wings, both thymic stroma and lymphoid cells were of quail origin. In reciprocal combinations, in which head and neck were of chicken origin on a quail body, a different result was obtained: no lymphoid cells were present in the thymus which was reduced to its epithelial component and this was of chick origin. On the other hand, if the chick contribution extended to the wings, as in the reciprocal combination, all thymus components were of chick origin. The spleen and the bursa of Fabricius in most instances did not differ in their cellular composition from the surrounding tissues; however in some chimeras a minor admixture of cells of the other species was also found. Overall these results suggest that hemopoietic stem cells destined to colonize intraembryonic organs arise in territories derived from the whole area pellucida excluding the prospective head-neck region. Furthermore, each hemopoietic organ rudiment appears to be colonized by precursors derived from adjacent territories.     

Induction of Mucous Metaplasia in Chick Embryonic Skin by Retinol-Pretreated Embryonic Chick or Quail Dermal Fibroblasts through Cell-Cell Interaction: Correlation of a Transient Increase in Retinoic Acid Receptor β mRNA in Retinol-Treated Dermal Fibroblasts with Their Competence to Induce Epidermal Mucous Metaplasia

Epidermal mucous metaplasia of 13-day-old chick embryonic tarsometatarsal skin can be induced by culture in medium containing 20 μM retinol for only 8 hr and then in a chemically defined medium without retinol for 2 days. Retinol primarily affects the dermal cells, which then transform the epithelial cells into mucus-secreting cells. In this study, we developed a system using a combination of retinol-pretreated chick or quail dermal fibroblasts and chick skin, and showed that retinol-pretreated quail embryonic dermal fibroblasts invaded the dermis of chick embryonic skin to beneath the epidermal basal cells within 1 day of culture and induced metaplasia, suggesting that epidermal mucous metaplasia of the skin was induced by the direct interaction of retinol-pretreated dermal fibroblasts with the epidermal cells or by low diffusible paracrine factor produced by the fibroblasts.
Increase in retinoic acid receptor β (RARβ) mRNA in dermal fibroblasts was observed after 8 hr-treatment with retinol which preceded morphological changes induced by retinol and this increase was correlated with the competence of the dermal fibroblasts to induce epidermal mucous metaplasia. Thus some gene product(s) controlled by RARβ in dermal fibroblasts may be an essential signal for induction of epidermal mucous metaplasia.     

Cellular and molecular background of Wolffian lens regeneration

Based on studies of wolffian lens regeneration in the newt, in which the lens can be regenerated from the iris pigmented epithelium, we have shown by cell culture studies that the capacity of lens transdifferentiation is not limited to the newt cells, but widely conserved in pigmented epithelial cells (PECs) of chick and quail embryos and even of human fetuses. Recently, we have established a unique in vitro model system of chick embryonic PECs. In this culture system we are able to control each step of transdifferentiation from PECs into lens cells by regulating culture conditions and to produce a homogeneous cell population with potential for synchronous differentiation into either lens or pigment cell phenotype. These multipotent (at least bipotent) cells showed cellular characteristics resembling neoplastic cells in many ways. They did not express both lens and pigment cell specific genes analyzed so far, except δ-crystallin gene, which is expressed in developing lens of chick embryos. It has been proved by application of cell culture procedures of the system that PECs dissociated from fully-grown human eyes readily transdifferentiated into lens phenotypes in the manner observed in chick embryo PECs. In addition, we could predict that molecules detected in either cell surface or intercellular space stabilized the differentiated state of PECs in the newt and that the loss of these molecules might be one of the key steps of lens regeneration from the iris epithelium.     

Expression of a nonpolymorphic MHC class I-like molecule, CD1D, by human intestinal epithelial cells.

The human CD1 locus encodes three nonpolymorphic MHC class I-like cell surface glycoproteins, CD1a-c, which are expressed primarily by immature thymocytes. A mAb and antipeptide antiserum were utilized to determine the tissue distribution of a fourth CD1 molecule, CD1d. Within the lymphoid lineage, CD1d was expressed on B cells but not on thymocytes. Immunoperoxidase staining of fresh frozen intestinal tissues demonstrated that the majority of intestinal epithelial cells, with the exception of cells at the base of some crypts, expressed CD1d. The CD1d staining was observed in the cytoplasm and along the basolateral membranes of the epithelial cells. The intestinal epithelial cell expression of CD1d was confirmed by immunoblotting with a CD1d antipeptide antiserum. Further immunoperoxidase studies indicated that CD1d, unlike murine CD1, was also expressed by nonlymphoid tissues outside of the gastrointestinal tract. The expression of CD1d outside the lymphoid and myeloid lineages clearly distinguishes this molecule from CD1a-c and suggests that it may serve a distinct function. The prominent expression of CD1d by intestinal epithelial cells suggests that this molecule may be an important ligand for T lymphocytes within the gut-associated lymphoid tissue.     

The Claude Bernard lecture, 1987. Embryonic chimeras: a tool for studying the development of the nervous and immune systems

Chimeras have been constructed in the avian embryo following the observation of the particular structure of the interphase nucleus in the Japanese quail (Coturnix coturnix japonica). In all embryonic and adult cell types of this species a large amount of heterochromatin is associated with the nucleolus, making quail cells readily distinguishable from those of the chick where the constitutive heterochromatin is evenly dispersed in the nucleus. These structural differences have been used to devise a cell-marking technique through which cell migrations and cell interactions during embryogenesis can be followed in the embryo in ovo by grafting quail cells into chick embryos or vice versa. This method was applied to the ontogeny of the neural crest and of the immune system. Recently quail-chick chimeras have been allowed to hatch and the immunological status of the embryonic grafts after birth scrutinized. Xenogeneic tissue grafts made in the embryo are rejected after birth with a more or less prolonged delay according to the nature of the graft. However, rejection can be prevented and a permanent state of tolerance induced for the embryonic tissue grafts by isotopically implanting the thymic epithelium from the same quail donor.     

Nature of the thymocytes associated with dendritic cells and macrophages in thymic rosettes

Thymic rosettes, structures consisting of 3-30 thymic lymphoid cells attached to a central macrophage or dendritic cell, were released from mouse thymus tissue by collagenase digestion. They were shown to be preexistent structures within the thymus, but to be subject to extensive exchange with free thymocytes under certain conditions. An isolation procedure was developed, using a new technique of zonal unit-gravity elutriation, which minimized exchange and produced a completely pure sample of the larger rosettes. The rosette-associated thymocytes were analyzed by two- and three-color immunofluorescent staining and flow cytometry. The dominant cell type was a small, CD4+CD8+, cortical-type thymocyte. However, all of the established thymus subpopulations defined by CD4 and CD8, including CD4-CD8+ and CD4+CD8- mature thymocytes and CD4-CD8- early thymocytes, were also present in rosettes. Very few of the cells present were of an intermediate or transitional phenotype. Rosette-associated thymocytes were somewhat enriched in large dividing thymocytes, in CD4-CD8- thymocytes, and in mature thymocytes expressing the T-cell antigen receptor-CD3 complex. Their most striking characteristic was a marked depletion in small thymocytes lacking surface H-2K expression, a major population among free thymocytes. The physiological role of the rosette structure is discussed, and it is suggested that the heterogeneity of the associated thymocytes in part reflects the existence of different types of rosettes in different areas of the thymus.     

Engagement of CD4 and CD8 accessory molecules is required for T cell maturation

In order to address the role of CD4 and CD8 Ag in the process of positive selection in the thymus, antibodies against these molecules, which do not result in the elimination of mature lymph node T cells, were injected in vivo. The results indicate that even long-term injection of nondepleting anti-CD4 and anti-CD8 antibodies does not cause the loss of CD4 or CD8 positive lymph node cells, but it completely blocks the development of the corresponding subpopulation of mature thymocytes. Thus, it appears that the interaction of the CD4 and CD8 accessory molecules on developing thymocytes with a ligand in the thymic environment (probably MHC Ag) is necessary for the positive selection of thymocytes into the appropriate T cell lineage.     

Demonstration of a phagocytic cell system belonging to the hemopoietic lineage and originating from the yolk sac in the early avian embryo.

It is well established that hemopoietic cells arising from the yolk sac invade the avian embryo. To study the fate and role of these cells during the first 2.5-4.5 days of incubation, we constructed yolk sac chimeras (a chick embryo grafted on a quail yolk sac and vice versa) and immunostained them with antibodies specific to cells of quail hemangioblastic lineage (MB1 and QH1). This approach revealed that endothelial cells of the embryonic vessels are of intraembryonic origin. In contrast, numerous hemopoietic cells of yolk sac origin were seen in embryos ranging from 2.5 to 4.5 days of incubation. These cells were already present within the vessels and in the mesenchyme at the earliest developmental stages analyzed. Two hemopoietic cell types of yolk sac origin were distinguishable, undifferentiated cells and macrophage-like cells. The number of the latter cells increased progressively as development proceeded, and they showed marked acid phosphatase activity and phagocytic capacity, as revealed by the presence of numerous phagocytic inclusions in their cytoplasm. The macrophage-like cells were mostly distributed in the mesenchyme and also appeared within some organ primordia such as the neural tube, the liver anlage and the nephric rudiment. Comparison of the results in the two types of chimeras and the findings obtained with acid phosphatase/MB1 double labelling showed that some hemopoietic macrophage-like cells of intraembryonic origin were also present at the stages considered. These results support the existence in the early avian embryo of a phagocytic cell system of blood cell lineage, derived chiefly from the yolk sac. Cells belonging to this system perform phagocytosis in cell death and may also be involved in other morphogenetic processes.     

A simple method for culturing chick embryo liver and kidney parenchymal cells for microscopic studies

Differentiated parenchymal cells were cultured from chick embryo livers or kidneys. Tissues were trypsinized, fragmented under a dissecting microscope, suspended in culture medium and separated into microscopic cell clumps with a syringe and wide bore needle. These cell clumps were grown in culture chambers and after light microscopic study were fixed and sectioned for electron microscopy. Both liver and kidney parenchymal cells appeared as clusters of epithelial cells containing round nuclei surrounded by numerous large mitochondria. Electron microscopy revealed well-differentiated cytoplasm which, in the liver cells, contained glycogen rosettes closely associated with smooth endoplasmic reticulum.