Evidence for a cyclic renewal of lymphocyte precursor cells in the embryonic chick thymus

Experiments involving sequential transplantations of the chick embryonic thymus at E9 to E12 into a first 3-day host quail embryo and then into a second chick host allowed demonstration of the cyclic periodicity of hemopoietic cell seeding of the embryonic thymus. After a first wave of colonization occurring between E6.5 and E8, the thymus becomes refractory to hemopoietic cell entry for about 4 days. It resumes its capacity to be seeded by a second wave of blood-borne stem cells at E12. After a second period of non receptivity starting at E14, a third wave of incoming cells reaches the thymus around E18. Therefore, with a slightly different periodicity, the same cyclic mechanism regulates the renewal of lymphocytes in chick and quail embryos. Quail hemopoietic cells were immunostained in the chimeric thymuses, with a species specific monoclonal antibody (anti-MB1) which recognizes a common surface antigenic determinant on all endothelial and blood cells of the quail (except erythrocytes). Two steps could thus be distinguished in the seeding process. When the thymus becomes receptive for hemopoietic cells, the latter first accumulate in the intrathymic blood vessels before penetrating massively in the thymic parenchyma. The quail chick-chimera system combined with the use of a species- and cell-type-specific antibody provides a unique tool for studying thymic colonization by lymphocyte precursors.     

Avian thymic accessory cells

On the basis of morphologic criteria and ingestion of latex particles, two basic types of accessory cells can be identified from quail and chick thymuses, dendritic cells, and macrophages. By using embryonic grafting techniques, we show that cells of this lineage enter the thymus during the initial colonization of the epithelial thymic rudiment by hemopoietic cells, and within a few days differentiate into cells exhibiting properties of glass adherence, Ia expression, and formation of rosettes with thymocytes. It appears that the precursors of this lineage undergo extensive, but finite, proliferation and are eventually replaced by further influx of the accessory cell lineage. In chimeric grafts, quail thymocytes were seen forming rosettes with chick accessory cells, and vice versa, indicating, as in the interaction between the epithelial cells and thymocytes, that the molecules involved in thymocyte-accessory cell association can interact across species barriers in our system.     

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.     

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.     

Split tolerance induced by chick embryo thymic epithelium allografted to embryonic recipients

To test the capacity of the epithelial component of the chick embryo thymus to induce tolerance to major histocompatibility complex (MHC) antigens, pre-colonized thymic rudiments were grafted into chick embryonic recipients. Semi-allogeneic or allogeneic transplantations were done between two lines of chickens histocompatible at the MHC locus. Approximately 10% of these thymic chimeras hatched and were studied 3 mo after hatching. Thymic grafts were not rejected by the allogeneic host. The tolerance of chimeric chickens to thymus donor MHC antigens was tested by using a skin graft rejection test and a graft-vs-host (GvH) assay. Chimeric chickens that received an MHC-incompatible thymic graft during the embryonic life tolerated skin graft with the MHC haplotype of the thymus donor. Nevertheless, the lymphocytes within the thymic graft, the host thymus, and the blood were tolerant to the host MHC antigens but were alloreactive in GvH reaction for the MHC antigens of the thymic graft type. These results suggest that the epithelial component of the thymus when taken before the starting of the colonization by hemopoietic precursors and grafted into an early chick embryonic host can induce a tolerance for the MHC determinants involved in allograft rejection but not in the GvH reaction.     

Preservation of the ability of dissociated quail wing bud mesoderm to elicit a position-related differentiative response

Previous studies showed that grafting wedges of fresh or cultured anterior quail wing mesoderm into posterior slits in chick wing buds resulted in the formation of supernumerary cartilage in a high percentage of cases. When anterior quail mesoderm, which had been dissociated into single cells and pelleted by centrifugation, was grafted into posterior slits of host chick wing buds, supernumerary rods or nodules of cartilage formed in 74.3% of the cases. Few supernumerary skeletal structures formed following control operations in which pelleted dissociated anterior or posterior mesoderm was grafted into homologous locations in host chick wing buds. When pelleted, dissociated anterior mesoderm was cultured in vitro for 1 or 2 days prior to being implanted in posterior locations, the incidence of supernumerary cartilage formation increased to 95.5% and 93.8%, respectively. The incidence of supernumerary cartilage formation following control orthotopic grafts of cultured mesoderm was 11.8% for 1-day and 31% for 2-day cultured anterior mesoderm; for 1- and 2-day cultured posterior mesoderm, the incidence of supernumerary cartilage formation was 20% and 41.7%, respectively. Longer-term culture resulted in a substantial decrease in the percentage of supernumerary cartilage after anterior to posterior grafts and an increase in the incidence of supernumerary cartilage from control grafts. The results demonstrate that quail anterior wing bud mesodermal cells do not need to maintain constant contact with one another in order to retain the ability to form or stimulate the formation of supernumerary cartilage after being grafted into a posterior location in a host wing bud. This ability is retained when the pelleted dissociated mesoderm is cultured in vitro outside the limb field for at least 1 to 2 days.     

Thymocyte/stromal cell chimaerism in allothymus-grafted Xenopus: developmental studies using the X. borealis fluorescence marker

These experiments employ the X. borealis (quinacrine-fluorescence) cell marker to illustrate that froglet (normal or in vivo-irradiated) thymuses, alloimplanted to 4- to 6-week-old, 7-day-thymectomized hosts, become filled with host lymphoid cells, while a range of thymic stromal cell types (e.g. epithelial derivatives and reticuloendothelial cells) remain donor derived. A time-course study of 4 micron historesin-embedded sections reveals that for normal thymus implants, host cells begin to immigrate in good number only after metamorphosis. In contrast, 3000 rad-irradiated thymus implants begin to be repopulated with host lymphocytes within 2 weeks postimplantation, when hosts are still at a late larval stage of development. Despite rapid colonization by host lymphoid cells, irradiated thymuses remain small and often disappear in early adult life. Donor-derived lymphocytes frequent the blood and both the red pulp and perifollicular regions of the spleen following normal thymus implantation, whereas such thymic emigrants were not seen in the periphery of thymectomized hosts grafted with irradiated thymus glands.     

Development and Involution of Thymus Grafts in Rats with reference to Age and Sex

Two weeks after grafting, whole thymus implants had the characteristic appearance of a normal young thymus. They increased in weight until 6 weeks post-operation and then underwent involution. Maximum weights attained by grafts in male hosts were significantly higher than those attained in female hosts. Initial rates of graft involution were higher in males than in females. Weights attained by grafts in young hosts of either sex reached maxima that were significantly higher than those attained by grafts of the same age in old hosts. The number of thymuses grafted separately into a single host did not influence the weight of the host's own thymus or the mass of individual grafts. However, when multiple grafts were linked together on transplantation, they behaved as an individual graft with respect to general morphology, growth rate and maximum size. With respect to growth and involution, it is suggested that thymic lymphopoiesis is mainly regulated by intrinsic factors emanating from the tissue which survives implantation. Further, the regulators appear to be clone-specific.     

Seeding of the 10-day mouse embryo thymic rudiment by lymphocyte precursors in vitro

The thymic rudiment was removed from the mouse embryo at 10 days of gestation, while it was still included in the 3rd branchial arch. When cultured alone, either in vitro or on the chick chorioallantoic membrane (CAM), it failed to develop as a lymphopoietic organ and remained in an epithelial state. If it was associated in transfilter culture with various types of hemopoietic organs from either embryonic or adult mice (e.g. yolk sac, fetal liver, thymus, bone marrow), it became seeded by lymphoid precursor cells and underwent a normal histogenetic process. If the donor and the receptor explants belonged to different strains of mice, the thymus that developed in culture was chimeric: thymic stroma cells (i.e., epithelial and connective cells) were of the receptor explant type, whereas the lymphoid population was of the donor type. Two genetic markers were used to label the thymic cell types, the Thy-1-1-Thy-1-2 system and the isozymes of the glucose phosphate isomerase.     

Histochemical identification and behavior of quail primordial germ cells injected into chick embryos by the intravascular route.

The behavior of quail primordial germ cells (PGC) after injection into chick embryos by the intravascular route was examined. The quail (donor) PGC, taken from the bloodstream of quail embryos (recipient) at stage 13-14, were injected into the vitelline vessels of chick embryos (recipient) at stage 15. In the recipient embryos, the PGC of the quail and the chick were histochemically distinguished by a double-staining technique involving a lectin, from Wistaria floribunda (WFA) and the PAS reaction. One day after injection, quail PGC appeared in the prospective gonadal region of recipient chick embryos, being localized among the recipient chick PGC. This result indicates that a staining technique specific for WFA lectin is useful for identification of quail PGC and that quail PGC can be transferred by a vascular route for the production of germline chimeras.     

Early appearance of donor-type antigen-presenting cells in the thymuses of 1200 R radiation-induced bone marrow chimeras correlates with self-recognition of donor I region gene products

The thymus exerts a potent influence on the development of I region self-recognition and antigen recognition by T cells. The mechanism by which the thymus acts on nascent T cells is unknown. It is assumed, however, that a cell interaction between the developing T cell and an la antigen-bearing cell in the thymus is involved. There are several candidates for the critical thymic cell; thymic epithelial, nurse, and antigen-presenting cells (APC) or dendritic cells. Because thymic epithelial cells derive from the third pharyngeal pouch and thymic APC derive from bone marrow, radiation-induced bone marrow chimeras allow the artificial creation of a chimeric thymus gland in which thymic epithelial cells and APC can be genetically different. We made radiation-induced bone marrow chimeras (F1 leads to P) using supralethal radiation doses (1200 R) and found bone marrow donor- (F1) type APC in the thymuses 3 wk after radiation. When such mice fully reconstitute their immune systems, their T cells behave as donor F1 phenotype T cells. Thus, the I region self-restriction and antigen-recognition repertoire of the T cells correlates with the genotype of the bone marrow-derived thymic APC, not the thymic epithelial cell.     

Supernumerary limb structures after juxtaposing dorsal and ventral chick wing bud cells

The formation of duplicated wing skeletal elements and/or extra wing muscles was studied by juxtaposing normally nonadjacent embryonic chick wing bud cells. A wedge of right or left stage 21 wing bud ectoderm and mesoderm was inserted in a slit made in a host stage 20 to 22 right wing bud at the same anteroposterior position as its position of origin. The distal edge of the donor wedge and host wing bud were aligned with each other. Donor tissue was grafted into a host wing bud in one of the following four axial relationships: both the anteroposterior and dorsoventral axes corresponded with each other (aadd); only the anteroposterior axes were opposed (apdd); only the dorsoventral axes were opposed (aadv); both the anteroposterior and dorsoventral axes were opposed (apdv). Of the 63 wings resulting from the control aadd operation and the 45 wings from the apdd operation, only 12 wings had a duplicated skeletal element; of the 69 wings sectioned from these two groups of operations, only one had an extra muscle. However, of the wings resulting from the aadv and apdv operations (48 and 52 cases, respectively), 23 had a duplicated skeletal element; of the 54 wings sectioned from these operations, 43 wings had one to four extra muscles. Furthermore, when the aadv operation was performed with a wedge of donor quail wing bud ectoderm and mesoderm or mesoderm alone, supernumerary muscles formed in these chimeric wings and they were made up of donor quail and host chick cells or only donor quail cells.     

On the Role of the Reticular-epithelial Complex in Transplantation of the Thymus

Transplantation of the neonatal thymus, into young, adult hosts, resulted in massive cell death of graft cortical lymphoid tissue with apparent selective survival of the reticular-epithelial cells. The central area of the graft was progressively cleared of cell debris and the characteristic thymic architecture restored within fourteen days of grafting. Evidence obtained from the regeneration of different-sized transplants suggested that the size and shape attained by the regenerated graft was closely related to the size and shape of the donor tissue.
When donor rat thymuses were transplanted in Millipore chambers, the lymphocyte population did not reappear and after seven days only reticular-epithelial cells remained, retaining their normal appearance. However, when these thymic remnants were removed from the chambers and transplanted into secondary hosts, the thymus regenerated normally, suggesting that the lymphocytes in the regenerated gland were derived from the host. Thymic remnants after cortisol treatment of donors also formed distinct organs after grafting despite the fact that they contained few donor lymphocytes. From the differential effects of cortisol on host and transplanted thymus and the different growth characteristics of transplants it appears that transplants differ in their growth/involution control system from the host thymus.     

Transplantation tolerance and autoimmunity after xenogeneic thymus transplantation

Successful grafting of vascularized xenografts (Xgs) depends on the ability to reliably induce both T cell-independent and -dependent immune tolerance. After temporary NK cell depletion, B cell suppression, and pretransplant infusion of donor Ags, athymic rats simultaneously transplanted with hamster heart and thymus Xgs developed immunocompetent rat-derived T cells that tolerated the hamster Xgs but provoked multiple-organ autoimmunity. The autoimmune syndrome was probably due to an insufficient development of tolerance for some rat organs; for example, it led to thyroiditis in the recipient rat thyroid, but not in simultaneously transplanted donor hamster thyroid. Moreover, grafting a mixed hamster/rat thymic epithelial cell graft could prevent the autoimmune syndrome. These experiments indicate that host-type thymic epithelial cells may be essential for the establishment of complete self-tolerance and that mixed host/donor thymus grafts may induce T cell xenotolerance while maintaining self-tolerance in the recipient.     

Analysis of the human neonatal thymus: evidence for a transient thymic involution

The neonatal period is marked by the impairment of the major components of both innate and adaptive immunity. We report a severe depletion of cortical CD4+CD8+ double-positive thymocytes in the human neonatal thymus. This drastic reduction in immature double-positive cells, largely provoked by an increased rate of cell death, could be observed as early as 1 day after birth, delaying the recovery of the normal proportion of this thymocyte subset until the end of the first month of postnatal life. Serum cortisol levels were not increased in newborn donors, indicating that the neonatal thymic involution is a physiological rather than a stress-associated pathological event occurring in the perinatal period. Newborn thymuses also showed increased proportions of both primitive CD34+CD1- precursor cells and mature TCRalphabetahighCD69-CD1-CD45RO+/RAdull and CD45ROdull/RA+ cells, which presumably correspond to recirculating T lymphocytes into the thymus. A notable reinforcement of the subcapsular epithelial cell layer as well as an increase in the intralobular extracellular matrix network accompanied modifications in the thymocyte population. Additionally neonatal thymic dendritic cells were found to be more effective than dendritic cells isolated from children's thymuses at stimulating proliferative responses in allogeneic T cells. All these findings can account for several alterations affecting the peripheral pool of T lymphocytes in the perinatal period.     

Neonatal tolerance induction in the thymus to MHC-class II-associated antigens. III. Significance of hemopoietic stem cells for induction and maintenance of Mls tolerance by continuous supply of tolerance-inducing nonlymphocytes

The role of hemopoietic stem cells and other cell types in the induction and maintenance of immunologic tolerance in the thymus was investigated by intravenous injection of Mls-semi-allogeneic cells into newborn mice less than 24 hr after birth. Mls-specific tolerance was induced by inoculation of peritoneal cells and thymus cells, and the tolerant state was compared with that induced by bone marrow cells which had hemopoietic stem cell activity and were able to create a stable chimera in both central and peripheral lymphoid organs. When peritoneal or thymus cells were injected, the level of tolerance attained was proportional to the number of cells injected, though peritoneal cells were 20 times as effective as thymus cells. In vivo functions of tolerance-inducing cells and their immediate precursors were radiosensitive and belonged to a Thy-1-, nylon-wool-nonadherent (probably non-B), weakly Sephadex G-10-adherent cell population. Tolerance induced by peritoneal cell injections was transient, starting to terminate within the first 2 weeks of life, while tolerance caused by bone marrow cell injections persisted through more than 6 weeks. Such transient tolerance induced by the former became long-lasting when followed by an additional injection of bone marrow cells, which did not cause thymic lymphocyte chimerism. All data indicated that bone marrow stem cells were engaged in tolerance induction and maintenance by continuously supplying tolerance-inducing nonlymphocytes.     

Influence of surgical and chemical orchidectomy on weight and distribution of AChE-nerve fibres in thymuses of adult rats

The thymus is a crossroad between the immune and neuroendocrine systems. As such, it is innervated by acetylcholinesterase (AChE)-positive fibres of the vagus, the recurrent laryngeal and the phrenic nerves. It is well know, that the innervations density of the thymus increases with age. In our study, adult rats were orchidectomized (surgically and chemically by the application of a luteinizing hormone-releasing hormone). The density of AChE-positive nerve fibres in thymuses, as well as the weight of thymuses was examined. The authors found that both surgical and chemical orchidectomy result in macroscopic and microscopic regeneration of the atrophied thymuses. In regenerated rat's thymuses after orchidectomy the density of AChE-positive nerve fibres was markedly higher in comparison with the control animals. The distribution, as well as the density of AChE-positive nerve fibres in regenerated thymuses after orchidectomy evokes the images of its innervations like in young animals before age-related involution. The authors also found a markedly higher weight of thymuses of orchidectomized rats in comparison with the control groups. In recent study the authors proved that after 8 weeks surgical orchidectomy leads to the regeneration of thymic AChE-positive innervation and chemical orchidectomy by administration of luteinizing hormone-releasing hormone after 4 weeks of adult rats.     

Monoclonal antibodies specific to quail embryo tissues: their epitopes in the developing quail embryo and their application to identification of quail cells in quail-chick chimeras.

Quail-chick chimeras have been used extensively in the field of developmental biology. To detect quail cells more easily and to detect cellular processes of quail cells in quail-chick chimeras, we generated four monoclonal antibodies (MAb) specific to some quail tissues. MAb QCR1 recognizes blood vessels, blood cells, and cartilage cells, MAb QB1 recognizes quail blood vessels and blood cells, and MAb QB2 recognizes quail blood vessels, blood cells, and mesenchymal tissues. These antibodies bound to those tissues in 3-9-day quail embryos and did not bind to any tissues of 3-9-day chick embryos. MAb QSC1 is specific to the ventral half of spinal cord and thymus in 9-day quail embryo. No tissue in 9-day chick embryo reacted with this MAb. This antibody binds transiently to a small number of brain vesicle cells in developing chick embryo as well as in quail embryo. A preliminary application of two of these MAb, QCR1 and QSC1, on quail-chick chimeras of neural tube and somites is reported here.     

Split tolerance in nude mice transplanted with 2'-deoxyguanosine-treated allogeneic thymus lobes

To elucidate the acquisition of self tolerance in the thymus, full-allogeneic thymic chimeras were constructed. Athymic C3H and BALB/c nude mice were reconstituted with the thymic lobes of BALB/c and B10.BR fetuses, respectively, that were organ cultured for 5 days in the presence of 2'-deoxyguanosine. T cells in these chimeras were tolerized to the host MHC in both MLR and CTL assays. In contrast, T cells in the chimeras exhibited split tolerance for the thymic MHC haplotype. CTL specific for class I MHC of the thymic haplotype were generated not only from the peripheral T cells of the chimeras but also from thymocytes re-populated in the engrafted thymic lobes. However, T cells in these chimeras responded poorly to the class II MHC of the thymic haplotype in a standard MLR assay. In a syngeneic MLR culture upon stimulation with enriched APC of the thymic haplotype, only 22 to 48% of the responses were mediated by CD4+ cells, and proliferations of CD4- cells were prominent. There were no haplotype-specific suppressor cells detected which would cause the unresponsiveness to the thymic class II MHC. These results indicated that the thymic lobes treated with 2'-deoxyguanosine were defective in the ability to induce the transplantation tolerance for the class I MHC expressed on the thymus, although the same thymic lobes were able to induce the transplantation tolerance for the thymic class II MHC.     

A novel method to bursectomize avian embryos and obtain quail----chick bursal chimeras. I. Immunocytochemical analysis of such chimeras by using species-specific monoclonal antibodies

Chick embryos were bursectomized at 5 days of incubation according to a novel surgical technique described in this article. This method yields birds that are able to hatch and are devoid of the physiologic deficiencies resulting from the previously used method, which involved resection of the cloacal and posterior embryonic region. The bursectomized embryos were grafted in situ with a quail bursa of the same age, which thereafter became chimeric through chick host hemopoietic cell invasion. By means of species-specific antibodies, the chimeric condition revealed 1) that the bursal epithelium expresses a unique antigenic determinant (MB1 determinant), until now considered to be an exclusive feature of blood vessel endothelium and hemopoietic cells, and 2) that this determinant appears in bursal epithelium at the time and site of hemopoietic cell invasion. The other point arising from this work concerns the apparent constitutive Ia expression by perifollicular blood capillary endothelial cells in normal and chimeric bursas.