Localization of thymocyte stem cell precursors in the pharyngeal endoderm of early amphibian embryos.

The embryonic germ layer derivation of thymic lymphocytes in the leopard frog (Rana pipiens) was invesigated. The ectoderm and mesoderm—but not the endoderm—from the developing gill bud was reciprocally and orthotopically transplanted between diploid and triploid chromosomally marked 72-hr old embryos. The lymphocytes which subsequently developed in the thymus were of host ploidy. Thus, the head mesenchyme adjacent to the thymic anlagen does not appear to be the source of the stem cells from which thymocytes differentiate. Rather, the stem cells can he localized in the endoderm of the pharyngeal pouch which initially gives rise to the thymic epithelium. These findings suggest either the endodermal origin of thymocytes or the very early migration of stem cells into the thymus anlagen prior to any thymus histogenesis.     

Development of Transplantation Immunity and Restoration Experiments in the Thymectomized Amphibian

This paper examines the thymic dependence of alloimmunity inamphibians. In Xenopus, the presence of a thymus during thefirst 2 weeks of life is essential for the development of normalfirst-set skin allograft immunity. Thymectomy during this earlyperiod always impairs the alloimmune response of young adulttoads. However, most of these thymectomized animals are ableto completely destroy skin allografts, albeit with prolongedrejection times. Chronic graft rejection, rather than tolerance,still occurs following thymectomy as early as 5 days, when thethymus contains no small lymphocytes. In contrast to the considerabledifferences in first-set allograft survival times in controland early-thymectomized Xenopus, second-set grafts, appliedsubsequent to first-set destruction, are rejected in acute fashion(<3 weeks) in both groups. That the defect in first-set alloimmunityis specifically related to absence of thymus has been confirmedby implanting allogeneic thymus 2 weeks post-thymectomy. Thedonor thymus remains healthy and restores the allograft responseto normal. In contrast, allogeneic spleen does not reconstituteand itself often undergoes destruction. Preliminary autoradiographicexperiments on lymphoid tissue involvement in first-set allograftrejection are also described.     

Ontogeny of the Immune System in Amphibians

SYNOPSIS. Experiments with amphibians have revealed that tissuesallografted in embryonic and early larval life may later succumbto a host immunological attack. In Xenopus, the ontogeny ofthis alloimmune response is correlated with the lymphoid maturationof the thymus. This article describes experiments primarilydesigned to ascertain if such a correlation exists in Rana pipiens. Initially, a histological study of the differentiation of thelymphomyeloid complex of the leopard frog was undertaken. At18–21°C lymphoid histogenesis is well under way inthe thymus and is beginning in many other organs during thethird week of larval life. Extensive growth and differentiationof these organs follow. Observations are also presented on thestructure, function and development of the lymphoid and Iymphomyeloidorgans from late larval life throughmetamorphosis to adulthood. Experiments were then performed to determine the onset of thealloimmune response to embryonically transplanted neural foldmaterial. At 18–21°C incompatibility phenomena, albeitslight, are first detected in these grafts as early as 17 daysafter fertilization, i.e. 15 days after transplantation. Thus,in the leopard frog, the alloimmune response develops soon afterlymphoid maturation of the thymus. At later stages of development,a more vigorous response is witnessed, concomitant with a rapidphase of lymphoid organ differentiation.     

Clarification of studies on the origin of thymic lymphocytes.

The thesis that lymphocytes originate in situ by the direct transformation of epithelial cells within the thymic primordium in anurous frogs is untenable. On the contrary, in both the leopard frog and the African clawed toad, the lymphocytes that first appear in the embryonic thymus are derived from extrathymic lymphopoietic cells that invaded the developing organ. The exact source of origin of the invading lymphopoietic cells remains problematic.     

Histological and cytological studies on the developing thymus of mandarin fish Siniperca chuatsi (Perciformes: Teleostei)

The thymus of the mandarin fish, Siniperca chuatsi, was examined by light and transmission electron microscopy to understand its formation and cellular composition. Larvae of the mandarin fish were collected and sectioned from 1 to 35 days post‐hatching (dph). On dph 7 the thymus was packed with lymphocytes. From 12 dph onward, mucous cells were observed on the epithelial layer; from 23 dph, three zones could be differentiated in the thymic parenchyma. The thymus was connected with the extension of the third, fourth and fifth branchial pouches throughout early development, remaining in a superficial position in the adult S. chuatsi. In the thymus of the adult fish, thymic epithelial cells (TECs) characteristic of tonofilaments were observed, with limiting TECs (LECs) found in subcapsular, subseptal, perivascular and nurse‐like TECs containing viable intact lymphocytes inside their vacuoles. In addition, three kinds of granulocytes were observed throughout the thymus, and an incomplete blood–thymus barrier was found in the inner zone. Other cell components such as cystic cells, macrophages and plasma cells, were also described in the thymus of the adult S. chuatsi. The thymus development in mandarin fish agrees, to some extent, with the ontogenetic patterns observed in other fish species.     

Analysis of hemopoietic lineage of accessory cells in the developing thymus of Xenopus laevis

The developmental history of accessory cells in the thymus was studied by grafting hemopoietic stem cells into cytogenetically distinct frog embryos (diploid-2N or triploid-3N) before the establishment of circulation and overt differentiation and colonization of the thymus. The DNA content of cortical thymocytes and circulating erythrocytes was quantified by staining with propidium iodide and measuring the amount of red fluorescence emitted by individual nuclei with the use of flow cytometry. Accessory cells from thymic medulla were separated by incubating for 2 hr on glass slides. For comparison, the developmental history of peritoneal macrophages was examined as representative, myeloid-derived phagocytic cells. DNA content of adherent cells was quantified by staining with the DNA-specific Feulgen reaction and measuring light absorption of individual nuclei by microdensitometry. Thymic accessory cells were subdivided into phagocytic and nonphagocytic phenotypes on the basis of latex bead ingestion. Phagocytic cells in the thymus were usually nonspecific esterase positive and phenotypically resembled peritoneal macrophages. Nonphagocytic cells from the thymus were usually esterase negative and had a dendritic morphology characterized by branched cytoplasmic extensions. Nonphagocytic cells were positive for cytoplasmic RNA based on staining with methyl green-pyronin Y. Phagocytic cells from both the thymus and the peritoneal cavity had no levels of cytoplasmic RNA detectable by this method. Analysis of the embryonic derivation of thymic accessory cells, based on the proportion of cells carrying the cytogenetic marker, demonstrated that thymic lymphocytes and thymic accessory cells were a concordant pair of cells, distinct from myeloid-derived erythrocytes and possibly macrophages. These experiments provide circumstantial evidence suggesting thymocytes and thymic accessory cells could arise from a bipotential precursor that diverges into these separate lineages after colonization of the epithelial thymic rudiment during early development.     

Electron microscopic study on the early histogenesis of thymus in the toad,Xenopus laevis

Summary Sequential electron microscopic observations of thymic histogenesis in the toad, Xenopus laevis, reveal that the thymus arises as epithelial buddings of the visceral pouches at Nieuwkoop-Faber stage 40, and acquires its basic histological features at stages 48–49. In the rudiments and the surrounding mesenchyme at stages 43–45, there are non-epithelial cells with pseudopodia, abundant ribosomes, and marginated heterochromatin. These cells, possible precursor cells of thymic lymphocytes, are frequently observed to attach and pass through the basal lamina which coats the thymic rudiment. The proliferation and differentiation of large lymphocytes are evident at stage 47. During stages 48–49 the small lymphocytes, lymphoid cortex and epithelial medulla including the thymic cysts, differentiate, and vascularization occurs.The results provide an ultrastructural basis for recent experimental evidence that the thymus exerts its essential function at stages 47–48. The possibility of non-epithelial derivation of thymic lymphocytes is discussed.The author wishes to express his thanks to Asst. Prof. Ch. Katagiri for his helpful advice during the course of this study     

The thymus microenvironment in regulating thymocyte differentiation

The thymus plays a crucial role in the development of T lymphocytes by providing an inductive microenvironment in which committed progenitors undergo proliferation, T-cell receptor gene rearrangements and thymocyte differentiate into mature T cells. The thymus microenvironment forms a complex network of interaction that comprises non lymphoid cells (e.g., thymic epithelial cells, TEC), cytokines, chemokines, extracellular matrix elements (ECM), matrix metalloproteinases and other soluble proteins. The thymic epithelial meshwork is the major component of the thymic microenvironment, both morphologically and phenotypically limiting heterogeneous regions in thymic lobules and fulfilling an important role during specific stages of T-cell maturation. The process starts when bone marrow-derived lymphocyte precursors arrive at the outer cortical region of the thymic gland and begin to mature into functional T lymphocytes that will finally exit the thymus and populate the peripheral lymphoid organs. During their journey inside the thymus, thymocytes must interact with stromal cells (and their soluble products) and extracellular matrix proteins to receive appropriate signals for survival, proliferation and differentiation. The crucial components of the thymus microenvironment, and their complex interactions during the T-cell maturation process are summarized here with the objective of contributing to a better understanding of the function of the thymus, as well as assisting in the search for new therapeutic approaches to improve the immune response in various pathological conditions.Key words: thymus, T-cell maturation, thymic microenvironment, thymocyte differantiation, chemokines, extracellular matrix, thymic nurse cells, metalloproteinases     

斜带石斑鱼胸腺的显微和超微结构

本文通过解剖及组织切片技术、光学显微镜、透射和扫描电子显微镜技术,对斜带石斑鱼(Epinephelus coioides)胸腺器官组织进行了观察研究。结果表明:斜带石斑鱼胸腺实质主要由胸腺细胞(淋巴细胞)和网状上皮细胞构成。鱼体从Ⅰ龄之后,其胸腺发生明显的变化,与幼鱼有所不同,主要是胸腺可明显区分为三个区域:胸腺外皮质区、内皮质区和髓质区。外皮质区主要由网状上皮细胞、黏液细胞、成纤维细胞和少量淋巴细胞构成,细胞排列疏松;内皮质区主要由密集的淋巴细胞和网状上皮细胞组成,以含有大量的淋巴细胞为特征;髓质区主要由淋巴细胞和较多的网状上皮细胞构成,总体特征是淋巴细胞数量比内皮质区的少,且细胞排列较疏松。外皮质区、内皮质区相当于高等脊椎动物的皮质;髓质区相当于高等脊椎动物的髓质。髓质区之下有结缔组织,在Ⅱ龄以上的成体出现胸腺小体(Hassall's corpuscles)或类似胸腺小体的结构,而且随着年龄的增加,胸腺外皮质区增厚,结缔组织增加,还表现在内皮质区和髓质区组织逐渐萎缩变薄,胸腺的细胞组成类型和淋巴细胞数量上有所变化等等。这些现象在Ⅱ龄鱼开始出现,即胸腺呈现退化迹象,在Ⅲ龄以上鱼体呈现明显的退化和萎缩。胸腺表面扫描电镜结果表明:其上皮细胞表面具有微嵴以及由微嵴组成的指纹状结构,有一些微孔分布。透射和断面扫描电镜的结果进一步表明:胸腺组织内的细胞成分复杂,除了淋巴细胞和网状上皮细胞外,还具有巨噬细胞、肥大细胞、肌样细胞、浆细胞、指状镶嵌细胞和纤维细胞等。     

Modulation of antibody synthesis by cholera exotoxin: Influence on helper thymocytes

This report demonstrates that a major biological influence of cholera exotoxin (CT) on antibody formation to sheep erythrocytes is mediated by the toxin's influence on the helper function of thymic lymphocytes. Hemolytic plaque-forming cell (PFC) responses for lethally X-irradiated mice repopulated with isologous thymus-marrow cell suspensions were stimulated three- to fivefold when 1.0 μg CT was administered at cell transfer. For mice given marrow cells only, CT did not elevate the PFC response; however, CT stimulated as many PFC in spleens of mice given marrow and 1 × 10⁷ thymus cells as mice given marrow and 4 × 10⁷ thymus cells. In other transfer experiments, depressed PFC responses were observed when irradiated mice were given marrow and thymus cells from donor mice inoculated with CT 24 hr prior to cell preparation and infusion, or given marrow cells from normal mice and thymus cells from CT-treated mice. In contrast, mice given marrow from CT-treated mice and thymus cells from normal mice responded as well as mice repopulated with normal thymus-marrow cell suspensions.     

Loss of Pten Disrupts the Thymic Epithelium and Alters Thymic Function

The thymus is the site of T cell development and selection. In addition to lymphocytes, the thymus is composed of several types of stromal cells that are exquisitely organized to create the appropriate environment and microenvironment to support the development and selection of maturing T cells. Thymic epithelial cells (TECs) are one of the more important cell types in the thymic stroma, and they play a critical role in selecting functional T cell clones and supporting their development. In this study, we used a mouse genetics approach to investigate the consequences of deleting the Pten tumor suppressor gene in the TEC compartment of the developing thymus. We found that PTEN deficiency in TECs results in a smaller thymus with significantly disordered architecture and histology. Accordingly, loss of PTEN function also results in decreased T cells with a shift in the distribution of T cell subtypes towards CD8⁺ T cells. These experiments demonstrate that PTEN is critically required for the development of a functional thymic epithelium in mice. This work may help better understand the effects that certain medical conditions or clinical interventions have upon the thymus and immune function.     

Age-related hyperplasia of the thymus and T-cell system in the Buffalo rat

This report describes the development of hyperplasia of both the thymus and the peripheral T-cell system with advancing age in the Buffalo rat. Buffalo/Mna rats do not show age-related thymic involution, but rather develop thymic hyperplasia with advancing age. This thymic growth is expansile and there is no infiltration of the surrounding tissues. Because the enlarging thymus occupies the thoracic cavity, most of the rats die of respiratory failure by the age of 24 months. Thymic enlargement is due to primary hyperplasia of cortical epithelial cells and the large number of proliferating lymphocytes. The hyperplastic epithelial cells are bizarre in shape and strongly positive when stained with Th-3 monoclonal antibody (MoAb), anti-thymosin antibody and anti-EGF antibody, but negative with Th-4 MoAb. The patterns of distribution of CD-5+, CD-4+ and CD-8+ lymphocytes within the hyperplastic thymus are similar to those seen in young rats of other species. The high level of T-cell emigration from the thymus to the periphery appears to persist throughout life, since the percentage of normal splenic T-cells also increase with advancing age and exceed 70% of the total by 24 months of age. This thymic enlargement with abnormal hyperplasia of cortical epithelial cells can be prevented by hypophysectomy.     

STUDIES ON LYMPHOCYTES

Tritiated thymidine was administered to calves continually for 2 to 8 days via the thymic artery in an attempt to label intensively thymic lymphocytes. Heavily labeled cells which had migrated from the thymus were observed in the spleen, lymph nodes and Peyer's patches. Cell maps were made for the various lymphoid tissues and in all cases the majority of labeled thymic cells were found in the ‘thymus dependent areas’of the spleen and lymph nodes. The number of labeled thymic cells per thousand lymphocytes was highest in the ‘thymus dependent areas’. A few labeled thymic cells were seen in or near the post capillary venules. The labeling pattern in the Peyer's patches was different from that in the spleen and lymph nodes. Labeled thymic cells were not observed in the bone marrow. Heavily labeled cells were not detected in any of the lymphoid tissues of those calves which received continuous intravenous infusion of comparable amounts of tritiated thymidine.     

Bu-1 andTh-1, two loci determining surface antigens of B or T lymphocytes in the chicken

Alloantisera were prepared by reciprocal immunizations with bursal or thymic lymphoid cells between chickens of two inbred lines identical at theB major histocompatibility locus. In cytotoxic assays, antibursa sera were specific for donor-line bursa cells without absorption; antithymus sera were similarly specific for donor-line thymus cells. Both types of sera cytolyzed some peripheral lymphoid cells from spleen, bone marrow, and blood. Absorption of either type of serum with peripheral blood leukocytes removed all cytotoxic reactivity for central lymphoid cells. The inheritance of the alloantigens detected by these specific antisera was studied in F₁, F₂, and backcross progeny from the two lines. Phenotypes were determined by a method in which antisera preabsorbed with progeny leukocytes were reacted against⁵¹Cr-labeled bursal or thymic cells from chickens of both lines. The results established two independent autosomal loci-Bu-1 andTh-1-determining antigens expressed, respectively, on bursal cells and peripheral B lymphocytes or on thymic cells and peripheral T lymphocytes. Cytotoxic testing of bursal or thymic cells from chickens of other inbred lines and F₁ populations led to the tentative conclusion that the number of alleles atBu-1 is restricted, whileTh-1 exhibits considerable multiple allelism.     

MIGRATION OF SMALL LYMPHOCYTES IN ADULT MICE DEMONSTRATED BY PARABIOSIS

Parabiotic BALB/C mice were used to study the traffic of small lymphocytes in immunological mature but unchallenged mice. By giving ³H-thymidine (³H-TdR) injections to only one member (A) of a pair by preventing the escape of the radioactive isotope to the other member (B), the kinetics of newly-formed cells was followed. Less than 10% labelled small lymphocytes were found in the peripheral lymphoid tissues of both A and B members, while the thymusses and bone marrows of A members showed labelling percentages up to 70% in this period. Hardly any labelled cells gained entrance into the thymus while a detectable number was found in the bone marrows of B members. Results from pairs set up to follow migration of long-lived lymphocytes revealed that labelled cells detected 4–5 weeks after injections were equilibrated between the peripheral tissues and the bone marrows of the partners. Very few labelled cells were seen in the thymic medulla and none were observed in the thymic cortex, germinal centres or medullary cords of lymph nodes from any B member. It was concluded that short-lived small lymphocytes are formed primarily in the thymus and bone marrow and the migration of these cells is limited in adult animals. Furthermore, the vast majority of long-lived small lymphocytes are freely recirculating, and these cells gain entrance to and are normal residents in the bone marrow.     

Phylogeny of immunocompetent cells: III. Mitogen response characteristics of lymphocyte subpopulations from normal and thymectomized frogs (Xenopus laevis)

Thymectomy during very early larval life, together with an analysis of in vitro proliferation of adult lymphocytes cultured with selective mitogens, has confirmed the existence of thymus-dependent and -independent populations of frog lymphoid cells. Mitogen reactivities of unfractionated lymphocyte suspensions from the spleen, blood, liver, bone marrow, and thymus revealed additional heterogeneity and organ compartmentalization; density gradient analyses of cells from the same tissues further disclosed that thymus-independent (PPD responsive) cells closely followed the total cell distribution, whereas thymus-dependent (Con A and PHA) responses were consistently a function of low density cells. Data are discussed from a phylogenetic perspective.     

Maturational impairment of thymic lymphocytes in streptozotocin-induced diabetes in rats

Streptozotocin (STZ)-induced diabetes in rats was associated with marked decreases in thymus weight and the number of thymic lymphocytes. Histologically, the cortical lymphocytes which were present near the cortico-medullary junction in the thymus seemed to be reduced selectively in the STZ-induced diabetes. Rosette-forming cells, which bind to guinea pig erythrocytes in the presence of fetal calf serum, were also significantly decreased. Insulin treatment allayed these intrathymic changes. Preincubation of thymic lymphocytes from diabetic rats with thymosin fraction 5 significantly enhanced the percentage of rosette-forming cells to near the control level. These results suggest that a maturational impairment of thymus cortical lymphocytes may be caused in STZ-induced diabetes with hypoinsulinemia and it may be intimately related to reductions in thymus weight and the number of thymic lymphocytes.     

Ontogenesis of rat immune system: Proteasome expression in different cell populations of the developing thymus

Immune proteasomes in thymus are involved in processing of self-antigens, which are presented by MHC class I molecules for rejection of autoreactive thymocytes in adults and probably in perinatal rats. The distribution of immune proteasome subunits LMP7 and LMP2 in thymic cells have been investigated during rat perinatal ontogenesis. Double immunofluorescent labeling revealed LMP7 and LMP2 in thymic epithelial and dendritic cells, as well as in CD68 positive cells - macrophages, monocytes - at all developmental stages. LMP2 and LMP7 were also detected by flow cytometry in almost all thymic CD90 lymphocytes through pre- and postnatal ontogenesis. Our results demonstrate that the immune proteasomes are expressed in all types of thymic antigen presenting cells during perinatal ontogenesis, suggesting the establishment of the negative selection in the thymus at the end of fetal life. The observation of the immune proteasome expression in T lymphocytes suggests their role in thymocyte differentiation besides antigen processing in thymus.     

Ia-positive macrophages bind and internalize viable lymphocytes in murine thymus

Macrophages have been shown to be present in thymus throughout its development. In the present study monoclonal and polyclonal antimacrophage reagents were used to identify, quantitate, and determine the distribution of thymic macrophages. Those studies demonstrated that significant numbers of macrophages were evenly distributed throughout the cortex and medulla, and that macrophages account for most, if not all, Ia positivity in murine thymus. Suspensions of thymic cells prepared by enzyme digestion contained 2-4% macrophage antigen-positive cells, over 95% of which were I-Ak positive in double-labeling studies. Removal of lymphocytes and macrophages left only epithelial cells and those failed to label for Ia. Subsequent to mild enzymatic digestion, up to 80% of the thymic macrophages were in the form of lymphocyte/macrophage rosettes. Morphologic evaluation of the thymocyte rosettes revealed that some of the macrophages contained internalized lymphocytes. The proportion of macrophages with internalized lymphocytes generally was less than 10%, but during the first 4 weeks of life values often approached 30%. Nurse cells, which were shown through double labeling to express both Ia and macrophage-associated antigen, were included in the population of rosetted cells which had internalized lymphocytes. The results demonstrated that there is a high level of interaction between lymphocytes and Ia-positive macrophages in the thymus which is greatest during the immediate postnatal period.     

Acid phosphatase activity and cell death in mouse thymus

Summary The distribution of acid phosphatase activity in the thymus of young (8 week) and old (42 week) mice is presented. In 8 week old mice acid phosphatase positive cells represent 1.27±0.13% of the total population whereas in 42 week old mice, showing involution of the thymus, acid phosphatase positive cells represent 2.40±0.17% of the total population. Loci of free acid phosphatase activity have been interpreted as sites of cell lysis and death. This has been confirmed at electron microscope level where free acid phosphatase has been demonstrated in the cytoplasm of lysing thymic lymphocytes. Vacuolar sites of acid phosphatase activity have been demonstrated in macrophages which appear to dispose of the lymphocytes. Extensive autophagic activity occurs in the epithelial reticular cells. The role of acid phosphatase in thymic lymphocyte deletion and in the tissue dynamics of the thymus is discussed.