Development of lymphoid tissue in a marsupial, Setonix brachyurus (quokka).

The development of the lymphoid tissues in a macropod marsupial is described. The liver is the only functional haemopoietic tissue at birth. Large lymphocytes first appear in the cervical thymus at 2 days, and in the thoracic thymus at 4 days after birth. Small lymphocytes appear 1-2 days later. The histological development of the two glands is similar, but the thoracic thymus develops much more slowly than the cervical. The appearance of Hassall's corpuscles in both thymus glands correlates with the onset of humoral immune responses in this animal. Lymph nodes first appear as aggregates of lymphocytes around the lymphatic vessels at 5 days, differentiate into cortex and medulla at about 14 days, but do not develop germinal centres until about 90 days. Small lymphocytes are not observed in the spleen until the 2nd week, and reactive centres do not appear until after 90 days of pouch life. Peyer's patches are not found until 60 days of age. Large lymphocytes are seen in the bone marrow at 14 days, but small lymphocytes are not found until the 1st month. Although the sequence of lymphoid development is similar to that seen in other animals, the rapidly with which it becomes functional suggests that it is an adaptive response to early contact with environment pathogens.     

Morphology of germ-free piglets

The postnatal ontogeny of primary (thymus) and secondary (spleen, lymph node, lingual tonsil) lymphoid tissues was studied in germ-free colostrum-deprived piglets up to age of 68 days. The thymus, which is morphologically fully developed by the end of gestation, showed no significant differences in the germ-free and conventional state. In germ-free piglets, slow development of periarteriolarly organized lymph follicles occurred in the spleen up to the end of the observation period. As distinct from the conditions in the spleen of conventional animals, the presence of a large number of pyroninophilic cells was not observed in germ-free piglets and no germinal centres were found. A similar situation was seen in the mesenteric lymph nodes, in which, in conventional piglets, cells belonging to the plasmacyte series, as well as the germinal centres, proliferate by the 13th day. Differences were also found in the organization of the follicular lymphoid tissue in the wall of the terminal ileum. In germ-free piglets, the lymph follicles increased only very slowly in size during the observation period and germinal centres were absent, while in conventional piglots germinal centres were present from the 12th day. The view is expressed that the intestinal lymphoid tissue ought rather to be classified as peripheral lymphoid tissue.     

IgG Fc receptor-bearing cells during early lymphoid cell development in the chicken

Cells from intraembryonic mesenchyme, yolk sac, bursa of Fabricius, and thymus from chicken embryos at different stages of development were studied for the presence of IgG Fc receptors by EA-rosette formation and binding of heat-aggregated chicken IgG (agg IgG). Cells with Fc receptors were found in high frequency in the intraembryonic mesenchyme as early as on the third day of incubation, in the yolk sac on the 7th day, in the bursa on the 10th day, and in the thymus on the 16th day of embryonic development. In the bursa the number of agg IgG binding cells increased with the age of the embryo and remained high after hatching, whereas in the thymus the peak value (76%) was observed on the 16th embryonic day, and after hatching only about 10% of the cells expressed the agg IgG receptors. The results also suggest that the appearance of IgG Fc receptors precedes the expression of B-L (Ia-like) antigens and of cytoplasmic and surface immunoglobulins on early lymphoid cells of the chicken embryo.     

Ontogeny of lymphatic structures in the pig omentum

Summary The development of lymphoid populations in the omentum majus during the prenatal and postnatal life of the pig was studied. T lymphocytes, monocytes and mast cells were first found on the 40th day of gestation. B lymphocytes appeared on the 72nd day of gestation when the first macrophage aggregates were formed. Macrophages appeared to be the prerequisite for the formation of dense lymphatic areas (DLA's). At later stages T cells were observed only in the omentum of germfree pigs. DLA's of conventional pig omentum are filled exclusively with B cells.     

Clonogenic hemopoietic cells (CFU-S) in mouse pre- and postnatal ontogeny

Content of three classes of clonogenic haemopoietic cells (CFU-S-7, CFU-S-11 and CFU-S-ep) was determined in haemopoietic organs of mouse during embryogenesis (10, 14 and 18 day) and postnatal ontogenesis (2, 3 and 7 day, 1, 2, 3 and 18 month). CFU-S-7 and CFU-S-11 that from big splenic colonies on 7th and 11th days of transplantation are present in liver, spleen and bone marrow at all developmental stages. However their concentration and CFU-S-7 CFU-S-11 ratio change in haemopoietic organs. CFU-S-ep that form small colonies on 11th day are observed before birth in liver and spleen and 1 week after birth there and also in bone marrow but are practically absent from haemopoietic organs of older animals. Thus, CFU-S compartment structure is characterized by definite ratio of its subpopulations. It seems to reflect functional state of haemopoietic system during development.     

The histogenesis of the lymphoid organs in the carp Cyprinus carpio L. and the ontogenetic development of allograft reactivity

A functional T cell population matures rapidly in the carp, Cyprinus carpio L. At 22 ± 1° C, the thymus first appears at two days post-hatch and becomes actively lymphopoietic by day 5. The kidney, which contains haemopoietic tissue at day 2, shows differentiating lymphoid cells by day 6–8. The spleen first appears at day 5 but develops more slowly than the kidney.
Lymphocytes are capable of effecting allograft rejection as early as day 16 post-hatch but the number of cells invading a skin allograft is low if the graft is applied in the first month of life. Thereafter the numbers increase rapidly, possibly correlated with the large increase in lymphocytes in the pronephric and mesonephric kidneys at this time.     

Cellular distribution of prothymosin alpha and parathymosin in rat thymus and spleen

By means of immunohistochemical methods, we have investigated the cellular distribution of prothymosin alpha and parathymosin in rat thymus and spleen, using specific antibodies raised against thymosin alpha-1 and against parathymosin. We observed prothymosin alpha immunoreactivity in lymphoid cells both in thymus and spleen. In the thymus, prothymosin alpha staining was more marked in cortex than in medulla. In the spleen, prothymosin alpha was found in lymphocytes of the periarteriolar lymphatic sheaths and was especially prominent in the germinal centers. Parathymosin immunoreactivity in the thymus was mainly localized in the medulla; positive cells were reticuloepithelial cells from the thymic reticulum and the blood barrier. Thymocytes were negative. In spleen, parathymosin was found in reticular cells arranged in a ring between the periarteriolar lymphatic sheath and the marginal zone. Our results do not support an exclusive role for these peptides as immune system hormones or cytokines.     

Morphology of lymphoid organs in a cichlid teleost, Tilapia mossambica (Peters).

In Tilapia mossambica organized lymphoid tissues are present in the thymus, head-kidney and spleen, whereas they are lacking in pericardial tissue, liver, mesonephros, intestine and rectum. No lymphoid tissue was observed in the chondrocranium and cartilaginous viscerocranium of young adults. The thymus in Tilapia is encapsulated by thin strands of collagen fibers and consists of outer, middle and inner zones. While middle and inner zones are comparable to the thymic cortex and medulla of higher vertebrates, the homology of the outer zone is not clear. At the anterior end of the thymus, a loose aggregation of lymphocytes without a definite boundary has been observed. The head-kidney is characterized by the presence of lymphoid follicles, a subcapsular sinus, a hilus-like area and lymphatic vessels. The spleen is grossly divisible into white pulp and red pulp; the white pulp contains only a reticular area without definite lymphoid centers and the latter contains predominantly erythrocytes. Morphological changes in the lymphoid organs associated with immune response have been discussed.     

Growth of the jugular lymph sacs and establishment of the topography of the cervical portion of the thoracic duct during early human ontogenesis

In 196 human embryos, prefetuses, fetuses and newborns, by means of a complex of morphological methods, development of the jugular lymphatic sacs and the process of settling of the thoracic duct cervical part topography have been studied. The jugular lymphatic sac anlages take place on the 6th week of the development. From the lymphatic cleft, situating in the mesenchyme near the anterior cardinal veins, multichambered cavities laid with endotheliocytes are forming,--the jugular lymphatic sacs. Connection of the initially close lymphatic sacs with the venous system takes place secondarily by the end of the embryonic period of development. In the area of the sac ostia a valve is formed, that makes morphological premises for unidirected lymph flow into the venous system. The lymph nodes developing at the place of the reducing jugular lymphatic sacs, ensure formation: from the left jugular lymphatic sac--the cervical part of the thoracic duct, from the right jugular lymphatic sac--the right lymphatic duct and the jugular and the subclavicular lymphatic trunks. Variability in the form and topography of these structures are determined both by the form and construction of the jugular lymphatic sacs and by developmental peculiarities of the lymph nodes at their place. The process of settling of the thoracic duct cervical part topography depends on age changes of its size and form, as well as on development of structures situating nearby, and by the time of birth it is not completed.     

Kinetics of lymphocytes in mice with alloxan diabetes

Alloxan diabetes (sucrose blood concentrate greater than or equal to 14 mmol/l decreased the life time of blood lymphocytes and increased the migration of these cells from lymphatic organs in BALB/c male mice. The proliferation pools of lymphoblasts and prolymphocytes in the thymus of diabetic mice were depressed, but in the lymphatic nodes remained unchanged. It has been shown that in lymphoid cells of the thymus of mice with diabetes the generation time and the time of G1- and G2-phase were significantly increased, but the time of the S-phase of the life cycle of these cells was normal. Proliferation of the lymphoid cells in lymphatic nodes was insulin-dependent. It has been shown that in the prolymphocytes of lymphatic nodes from diabetic mice the duration of the G1-phase was significantly decreased.     

Ontogeny of IgM-producing cells in the lymphoid organs of rainbow trout, Salmo gairdneri Richardson: an immuno- and enzyme-histochemical study

The ontogenetic development of IgM-containing cells is described as demonstrated by immunoperoxidase staining with a mouse anti-trout IgM monoclonal antibody and the differentiation of enzyme-histochemical markers in the non-lymphoid cells forming the stroma of the thymus, spleen and kidney of the rainbow trout. The first lymphoid cells staining with the monoclonal antibody occurred at day 4-5 after hatching in the renal lympho-haemopoietic tissue. By 1 month after hatching IgM-positive cells also appeared in the spleen and thymus. Enzyme-histochemical demonstration of the alkaline and acid phosphatase and non-specific σ-naphthyl acetate esterase enzymatic activities in the non-lymphoid cells indicated that a certain degree of maturation of the cellular stroma of the developing lymphoid organs of trout was reached before or at the time when IgM-expressing cells could be observed. The relationships of the stromal components of the various lymphoid organs to the development of IgM-positive cells, and the possible role of the renal lympho-haemopoietic tissue as a primary lymphoid organ for B-cell differentiation in the trout are discussed.     

Thymus, peripheral lymphoid tissues and immunological responsiveness of the pituitary dward mouse (author's transl)]

Snell's pituitary dwarf mice (dw) were used for studies on the relationship between hypophysis and lymphoid organs. The age-dependent changes of thymus or spleen weights of dwarf mice were compared with those of normal littermates. The suppression of growth of the thymus or spleen in dwarf mice was recognized at 5th day of age. Although involution of the thymus varied among animals, a strong positive correlation was demonstrated between relative thymus weight and body weight in 30 approximately 40 days old dwarf mice. Lymphoid organs of dwarf mice were reconstituted by injection of growth hormone and or thyroxin. Relative thymus weight significantly increased in dwarf mice when the treatment with growth hormone started at 7 days of age, but the same treatment at 3 months of age did not show any effect on the increment of relative thymus weight. On the other hand, the antibody-forming capacitiy against sheep erythrocytes of dwarf mice was significantly increased even when the treatment with growth hormone was started at 3 months of age. A marked increase in the number of lymphoid cells in dwarf mice was observed by treatment with thyroxin, even if treatment was started either at 7 days or 3 months of age. Similar changes were also obtained in the antibody-forming capacity.     

Histopathological study on six cases of calf leukosis.

A pathological study was carried out on six calves 4 to 10 months of age affected with lymphoid tumors. Most of the lymph nodes enlarged in consequence of leukotic changes in all the calves. These changes occurred also in other various organs. When the leukotic lesions were investigated to clarify the distribution and histological manifestation, three pathological patterns were discriminated among them. One of the patterns was seen in four cases, in which leukotic lesions were present constantly in bone marrow, thymus, liver and kidney. In the lymph nodes, tonsils, and intestinal lymphatic apparatus, neoplastic cellular proliferation took place in paracortical or interfollicular areas and medullary cords obliterating the lymph follicles. Leukotic involvement was observed in the interstitial and the vascular connective tissue in the thymus, as well as in liver and kidney. A second pattern of lesion was revealed in one of the other two cases. Besides lymph nodes in which neoplastic proliferation was seen in the paracortical area, only the thymus manifested intralobular neoplastic involvement in this case. In the remaining case, the leukotic lesion was characterized by the presence of neoplastic cellular masses resembling large lymph follicles in appearance in the lymphatic tissues. It was manifested distinctly in the spleen. Severe thymic atrophy and granulocytic hyperplasia in bone marrow were present in this case.     

Histogenesis of the rat thymic medulla during first stages of development

We investigated first stages of thymic medulla organisation in foetuses of Wistar strain rats. between 13th and 17th days of foetal life (GD). Medullary cells were identified by immunocytochemical localisation of neuron-specific enolase (NSE) as well as by traits of ultrastructure. The first thymic medullary precursor cells which were reactive for NSE were at first spread all over the thymic primordium. In the period of thymus colonisation by lymphoid cells, the following stages were distinguished in medulla organisation: (1) migration of NSE+ cells to the central portion of the thymus (GD 14-15), (2) small medullary epithelial patches, distributed within the thymus (GD 16), and (3) expansion of medullary patches into medullary compartment (GD 17). At the second and third stages of the medulla organisation, an increase in the number of NSE+ cells, followed by differentiation of their ultrastructure and increase in their biological activity were observed. We conclude that formation of medullary architectural pattern is controlled by interactions between maturing epithelial cells and developing lymphoid cells and by angiogenesis in the region.     

Development of the lymphatic bed of the human esophageal wall]

The lymphatic capillaries are firstly determined in fetuses at the age of 3-4 months in the oesophagus submucous lamina. In fetuses of 5-6 months of age transition of the lymphatic capillaries from the submucous lamina into the mucous membrane proper is noted. In fetuses of 6 months of age perivascular lymphatic capillaries and vessels appear. They form peculiar paths around arterioles, venules, arterial branches and venous tributaries. The lymphatic bed of the oesophageal wall is rather well developed in mature fetuses and newborns. In adult and old persons a partial reduction of the lymphatic bed in the oesophageal wall is observed.     

Toxoplasma gondii: Effect of maternal infection in the development of lymphoid organs of BALB/c neonates

Toxoplasmosis is one of the worldwide parasitic zoonoses. Alterations in the lymphopoietic system are still poorly studied. We analyzed lymphoid organs of BALB/c mice neonates from Toxoplasma gondii-intraperitoneally-infected mothers on 19th day of gestation, with 30 tachyzoites of strain RH. Normal non-infected pregnant females were used as controls. At 7 days after birth, animals were classified as neonates from infected (NIM) and neonates from non-infected mothers (NNIM). Weight of the thymus and number of thymic cells in NIM were decreased, percentage of apoptosis was significantly increased. Decrease in lymphocytes and monocytes and an increase of plasma cells were observed in bone marrow of NIM. Peripheral blood of NIM showed an increase of monocytes and neutrophils and a decrease in lymphocytes. Infection of the mother during the last day of gestation provokes in the neonates changes in the lymphoid organs that could explain survival of 75% of them.     

Interdigitating cells in the lymphoid tissues of bovine fetuses and calves

Summary Electron-microscopic studies of lymphoid tissues from bovine fetuses and from calves disclosed a non-lymphoid cell type in the thymus-dependent zones of secondary lymphoid tissues and in the thymus that is distinguishable from reticulum cells, epithelial and endothelial cells, and macrophages. Based on morphological and topographical criteria, the cell is identified as the interdigitating cell. In addition, studies of the tissues of normal and virus-challenged fetuses, and of conventionally reared calves, indicated that the interdigitating cells originate from monocytoid cells, which undergo differentiation in the thymus-dependent zones during an immune response.     

COMPARTMENTS AND CELL FLOWS WITHIN THE MOUSE HAEMOPOIETIC SYSTEM II. ESTIMATED RATES OF INTERCHANGE

Part-body irradiated CBA mice were injected with CBA-T6 bone marrow. In this way a predominantly donor population was established in the femora while the marrow of the humeri remained largely (average 94 %) of host origin. In animals examined cytologically up to 2 years later, no tendency was observed for the proportion of donor cells in the humeri to increase. Splenectomy had no effect on this. When femoral bone marrow from the experimental mice was injected into lethally (whole-body) irradiated recipients, cells originating from the primary host repopulated the lymph nodes to a disproportionate extent. Equilibration between the cell populations of femora and humeri occurred after re-exposure to 600 rad whole-body irradiation, but not after 100 rad or 350 rad; thus, regeneration of damaged bone marrow involved a significant contribution from extrinsic stem cells only after the highest dose of radiation. The data are compatible with an inflow of at most ten effective stem cells per humerus per day from the blood, and suggest a much lower figure. This means that few if any of the stem cells of peripheral blood enter the bone marrow and found haemopoietic clones. Evidence is adduced for the existence of a proliferating lymphoid sub-population in the bone marrow, contributing some 5–10% of the observed mitoses. The mitotic cells in the lymph nodes are replaced from marrow-derived progenitors at an estimated rate of 4–5 %/day. The relevant data for the thymus are more variable, but suggest an average figure of 8–11 %/day. Earlier data from mouse parabionts suggest a lower rate of inflow to the thymus.     

Repopulation of the mouse thymus after sublethal fission neutron irradiation. II. Sequential changes in the thymic microenvironment

The stromal cells of the thymus of sham-irradiated and sublethal fission neutron-irradiated CBA/H mice were analyzed with immunohistology, using monoclonal antibodies directed to I-A and H-2K antigens as well as specific determinants for cortical and medullary stromal elements. In the control thymuses, I-A expression in the thymus shows a reticular staining pattern in the cortex and a confluent staining pattern in the medulla. In contrast, H-2K expression is mainly confluently located in the medulla. Whole body irradiation with 2.5 Gy fission neutrons reduces within 24 hr the cortex to a rim of vacuolized "nurse cell-like" epithelial cells, largely depleted of lymphoid cells. The localization of I-A antigens changes in the cortex and I-A determinants are no longer associated with or localized on epithelial reticular cells. Medullary stromal cells, however, are more or less unaffected. A high rate of phagocytosis is observed during the first 3 days after irradiation. About 5 days after irradiation, the thymus becomes highly vascularized and lymphoid cells repopulate the cortex. The repopulation of the thymic cortex coincides with the appearance of a bright H-2K expression in the cortex which is associated with both stromal cells as well as lymphoid blasts. During the regeneration of the thymus, the thymic stromal architecture is restored before the expression of cell surface-associated reticular MHC staining patterns. The observed sequential changes in the thymic microenvironment are related to the lymphoid repopulation of the thymus.     

Phylogenetic development of melano–macrophage centres in fish

The haemopoietic tissues of 72 species of fish representative of Agnatha, Chondrichthyes and Osteichthyes were examined by light microscopy for melanin–containing macrophages. All were found to possess these pigmented cells except for the lamprey Lampetra fluviatilis Linnaeus. An evolutionary pattern was evident in both their distribution and degree of organization. There was a progressive increase in the abundance of pigment cells and their proclivity for the main lymphoid organs. Melano–macrophage centres appear to evolve structurally from the random distribution of individual pigmented macrophages observed in Agnatha and Chondrichthyes to the organized centres characteristic of all Osteichthyes except the salmonids. It is hypothesized that the change in organ location from the liver in Agnatha, Chondrichthyes and the primitive bony fishes to the spleen and kidney in the advanced bony fishes follows closely upon the evolution of the lymphoid system and represents a major advance in the evolution of the lympho–reticular relationships. The increasing sophistication in cytological organization of the melano–macrophage centres is concomitant with the increasing levels of complexity of the cytoarchitecture of the lymphoid system. These analogies provide additional evidence that these centres are of a lymphatic nature and may well represent the primitive analogues of germinal centres of birds and mammals.