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。     

‘3H-testosterone distribution and binding in RAT thymus cells in vivo’

Summary Autoradiography and biochemical investigations showed that [³H]-testosterone where injected intraperitoneally into male white rats was incorporated rapidly into thymus lymphocytes. Thymic cortex contained more silver grains than medulla, and larger lymphocytes were more labelled than medium or small lymphocytes.Cytosol fraction of thymus cells labelledin vivo with [³H]-testosterone, contained the largest quantity of labelled hormone. A 4S cytosol fraction binds [³H]-testosterone. This could be separated by Sephadex chromatography or by linear sucrose gradient centrifugation. Nuclear extract contained also a small quantity of the labelled hormone.     

Ultrastructure of the developing thymus of the leopard frog (Rana pipiens)

Summary A study of the ultrastructure of the developing thymus of the leopard frog (Rana pipiens) revealed that the thymus had undergone all of the major changes which would persist through larval life and metamorphosis by the time that the animals had reached larval stage IV of Taylor and Kollros (1946). These changes included development of an outer, lymphoid cortical region and an inner, essentially nonlymphoid medulla; mitotic activity among lymphoid cell precursors and the formation of the first small lymphocytes; development of complex cysts containing PAS-positive material and the appearance of other signs of secretory activity among epithelial cells of the medulla; and differentiation of large myoid cells containing bundles of striated muscle fibrils. The changes are particularly noteworthy because they first appear during a period in which the animals are known to be developing the capacity to respond immunologically to allografts.Supported by a grant from the National Institutes of Health number GM-11782 to E.P.V.     

中华鳖胸腺显微和亚显微结构及其在进化上的意义

应用透射电子显微镜观察了中华鳖胸腺的显微和亚显微结构。发现中华鳖胸腺从结构上可分为皮质和髓质,皮质富含淋巴细胞,髓质富含上皮性网状细胞。在各发育期中华鳖胸腺皮质、髓质交界处和髓质区有明显的囊状胸腺小体和交错突细胞。在２００ｇ以上的成年鳖胸腺内发现有同心圆状胸腺小体。电镜下,胸腺内淋巴细胞分为大、中、小３型。上皮性网状细胞从亚显微结构上分为支持型和分泌型。胸腺囊包括细胞内囊和细胞间囊,以细胞内囊居多     

Histological changes of the mouse thymus during involution and regeneration following administration of hydrocortisone

Summary A histological study has been made of the thymus in mice during acute involution and regeneration following administration of hydrocortisone. The cortex undergoes remarkable changes in the microscopic structure during involution and regeneration. During involution the lymphocytes in the cortex rapidly decrease and are removed. Then a rapid replacement of lymphocytes occurs during regeneration. On the basis of formation and repopulation of lymphocytes the regenerative process of the cortex is divided into seven phases. The reconstitution of the cortex proceeds more rapidly in females than in males. Newly formed lymphocytes take origin from the mesenchymal cells in the cortex. Such mesenchymal cells become distinguishable from epithelial reticular cells during involution. They appear to engulf destroyed lymphocytes and debris during involution and then transform into immature lymphoid cells during early regeneration. The findings may support the recent reutilization concept that destroyed lymphocytes are phagocytized and reutilized by reticular cells in heteroplastic differentiation into immature lymphoid cells. In the cortex PAS-positive sudanophilic cells which are derived from the perivascular and subcapsular connective tissue appear with involutionary changes. They become gradually reduced again with progress of the regeneration of the cortex. During involution the medulla are temporarily filled with lymphocytes migrated from the cortex. The epithelial reticular cells in the medulla are found grouped in cords or clumps in the severely involuted thymus. In the medulla there are two types of PAS-positive epithelial reticular cells; one contains a large, colloid-like, PAS-positive inclusion within the cytoplasm and the other has cytoplasm diffusely filled with PAS-positive substance. During involution and early regeneration, the former type increases while the other shows almost no significant changes. Hassall's corpuscles somewhat increase in frequency during involution and early regeneration.     

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     

A cytophotometric and flow cytofluorometric approach to the differentiation of T lymphocytes in the thymus

Summary By cytophotometric and flow cytofluorometric DNA and protein determinations two main proliferating subpopulations of thymus lymphocytes with a different percentage of cells in the S phase could be distinguished. One subpopulation had a very low protein content, was cortisone sensitive and located in the cortex. Cells with comparable low protein contents were not found amongst lymphocytes of the peripheral blood. The other lymphocyte subpopulation had a higher protein content, was cortisone resistant and situated in the cortex around a group of epithelial cells and in the medulla. The protein content of these thymus lymphocytes appeared to be comparable to that of the peripheral blood lymphocytes. On the basis of the protein content per cell, it is possible to identify and isolate the more often described major subpopulation of cortisone sensitive thymus lymphocytes remaining and dying in the thymus, and the minor cortisone resistant subpopulation of thymus lymphocytes which is the source of the peripheral T lymphocyte.     

A cytophotometric and flow cytofluorometric approach to the differentiation of T lymphocytes in the thymus.

By cytophotometric and flow cytofluorometric DNA and protein determinations two main proliferating subpopulations of thymus lymphocytes with a different percentage of cells in the S phase could be distinguished. One subpopulation had a very low protein content, was cortisone sensitive and located in the cortex. Cells with comparable low protein contents were not found amongst lymphocytes of the peripheral blood. The other lymphocyte subpopulation had a higher protein content, was cortisone resistant and situated in the cortex around a group of epithelial cells and in the medulla. The protein content of these thymus lymphocytes appeared to be comparable to that of the peripheral blood lymphocytes. On the basis of the protein content per cell, it is possible to identify and isolate the more often described major subpopulation of cortisone sensitive thymus lymphocytes remaining and dying in the thymus, and the minor cortisone resistant subpopulation of thymus lymphocytes which is the source of the peripheral T lymphocyte.     

Cytolytic effects of glucocorticoid on thymus-medullary lymphocytes incubated in vitro

Thymus cortical and medullary lymphocytes (TCL and TML) were incubated in vitro with or without cortisol. The cytolytic effects of the steroid on both thymocytes were examined in the microscope and by measurements of protein and RNA synthetic activities. There did not appear to be significant differences in the extent of damage by glucocorticoid exposure between both thymocytes, although the reduction of RNA synthesis in TML was less marked as compared with that in TCL. The facts that lymphocytes in thymus medulla were able to survive after cortisone injection and that the cells incubated in vitro were affected by the steroid presented the hypothesis that there might be some particular mechanisms in thymus medulla to protect lymphocytes from the cytolytic action of glucocorticoid.     

B lymphocytes in the guinea pig thymus are specifically localized in the central area.

Since the central area is an integral part of the guinea pig thymus, the cells in this area were compared with those in the thymic cortex and medulla in cryostat-sections by using methods for demonstration of E-, EA-, EAC-adherence and surface membrane immunoglobulins. In the extra cortical central area (ECCA) 15 to 25% of the lymphocytes showed EAC-adherence and 5 to 10% appeared to bear surface membrane immunoglobulins (SIg). In the lymph sinuses up to 70% of the lymphocytes were EAC- and SIg-positive. A small amount of EAC-adhering cells was present in the medulla of the central area. Cortical lymphocytes were EAC- and SIg-negative. From these results we conclude that in the guinea pig thymus B lymphocytes are specifically localized in the central area.     

Ontogeny and organization of the stationary non-lymphoid cells in the human thymus

Summary Ontogenetic differentiation of the human thymus was investigated in 50 embryos by means of light and electron microscopic methods in an attempt to clarify the morphogenesis of the complicated microecology of thymic tissue. At the 8th gestational week (g.w.), the primordium of the thymus contains almost exclusively undifferentiated epithelial cells. At the 10th g.w., the epithelial cells in the central part are spindle-shaped. During the subsequent weeks the cortical region of the thymus becomes separated into lobes by mesenchymal septa containing hemopoietic precursor cells and large electronlucent cells with irregularly shaped nuclei. The latter cells are also found in the deeper presumptive medullary regions of the thymus; they differentiate into interdigitating reticulum cells (IDC). The permeation of the medulla of the thymus by non-epithelial IDC occurs concurrently with the formation of cortical and medullary epithelial cells. Between the 12th and 14th g.w. the cortical and medullary differentiation is completed. At this time-stage cortical small lymphocytes differ in morphological shape from medullary lymphocytes, the latter acquiring the appearance of immunocompetent T cells and establishing intimate contact with the IDC.These findings indicate that the thymic cortex and medulla contain different epithelial cells. In addition, the thymic medulla displays cells characterized by the morphology of typical interdigitating reticulum cells of peripheral lymphoid tissue. The structural pattern of the thymus is correlated to morphologically differing lymphoid cell populations in the cortical and medullary regions.This investigation was supported by grants from the Deutsche Forschungsgemeinschaft and by the Sonderforschungsbereich 111The authors dedicate this paper to Professor Helmut Leonhardt on the occasion of his 60th birthday. The authors also appreciate the excellent technical assistance of Mrs. I. Knauer, Mrs. H. Waluk and Mrs. H. Siebke     

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.     

蛇胸腺胚胎发育的组织学研究

该文应用光镜、电镜和细胞计数技术对胚胎发育期虎斑颈槽蛇胸腺的发育分化进行了研究。在胚胎发育１１期,胸腺原基内出现前淋巴细胞。从胚胎发育１２期至出生前（１６期）,淋巴细胞不断增殖分化,小淋巴细胞逐渐增多,而淋巴母细胞和中淋巴细胞逐渐减少。胸腺皮质和髓质形成于１６期。巨噬细胞以及肌样细胞和胸腺ＡＰＵＤ细胞分别形成于胚胎发育１４期和１５期,随后数量有所增加,分别分布于胸腺皮质和髓质。     

A scanning electron-microscopic study of the rat thymus with special reference to cell types and migration of lymphocytes into the general circulation

Summary The three-dimensional structure of the rat thymus was studied by combined scanning and transmission electron microscopy. The thymus consists mainly of four types of cells: epithelial cells, lymphocytes, macrophages, and interdigitating cells (IDCs).The epithelial cells form a meshwork in the thymus parenchyma. Cortical epithelial cells are stellate in shape, while the medullary cells comprise two types: stellate and large vacuolated elements. A continuous single layer of epithelial cells separates the parenchyma from connective tissue formations of the capsule, septa and vessels. Surrounding the blood vessels, this epithelial sheath is continuous in the cortex, while it is partly interrupted in the medulla, suggesting that the blood-thymus barrier might function more completely in the cortex.Cortical lymphocytes are round and vary in size, whereas medullary lymphocytes are mainly small, although they vary considerably in surface morphology.Two types of large wandering cells, macrophages and IDCs, could be distinguished, as well as intermediate forms. IDCs sometimes embraced or contacted lymphocytes, suggesting their role in the differentiation of the latter cells.Perivascular channels were present around venules and some arterioles in the cortico-medullary region and in the medulla. A few lymphatic vessels were present in extended perivascular spaces.The present study suggests the possible existence of two routes of passage of lymphocytes into the general circulation. One is via the lymphatics, while the other is through the postcapillary venules into the blood circulation. Our SEM images give evidence that lymphocytes use an intracellular route, i.e., the endothelium of venules.     

人胸腺内交错突细胞的免疫组织化学研究

本文用免疫组织化学方法检测胎儿期,儿童以及成人胸腺内交错突细胞的分布和ＨＬＡＤＲ抗原的表达．结果表明：Ｓ－１００抗体能够清楚显示胸腺内交错突细胞,这些细胞主要分布在皮,髓质交界处和髓质内,在皮质内的交错突细胞大都单个存在,偶而看到交错突细胞成团存在．交错突细胞的周围,常见有淋巴细胞形成玫瑰花结．出生后随年龄的增长,交错突细胞逐渐减少。ＨＬＡ－ＤＲ抗体能与胸腺内多种细胞反应,如皮,髓质内上皮细胞,巨噬细胞和交错突细胞,但它们染色强度不等．交错突细胞ＨＬＡ－ＤＲ抗体的阳性反应位于质膜和突起部,染色强阳性,巨噬细胞反应不尽一致一般多为阳性,胞质内未见有吞噬淋巴细胞碎片．上皮细胞染色一般由弱阳性到阳性,核阴性,仅有质膜呈阳性反应,有关ＨＬＡ－ＤＲ抗原表达的可能意义进行了讨论．     

Ultrastructural changes in the thymus of the turtle Mauremys caspica in relation to the seasonal cycle

Summary Changes in the ultrastructure of the thymus of the turtle Mauremys caspica, with special reference to its non-lymphoid components, were studied in relation to the seasonal cycle. The thymic cortex contains framework-forming epithelial-reticular cells and free macrophages, while the medulla includes, in addition, mature and presumptive pro-interdigitating cells. The ultrastructural features of these cells are generally similar to those described for non-lymphoid components of the mammalian thymus. The turtle thymus undergoes cortical involution in spring, with recovery periods in May–June and during autumn. A moderate involution occurs in winter. At the beginning of spring, cortical (but not medullary) epithelial-reticular cells show degenerative changes, probably related to high levels of circulating testosterone. In spring and autumn, mature interdigitating cells are absent, but macrophages, monocytes, and pro-interdigitating cells are found. During May–June, the cortical epithelial-reticular population recovers and macrophages, monocytes, and interdigitating cells are actively phagocytic. In summer, the epithelial-reticular cells in both cortex and medulla display normal ultrastructural features; mature and immature interdigitating cells are absent and some macrophages are detected occasionally. The results suggest that non-lymphoid components of the reptilian thymus can play a role in governing T-lymphocyte differentiation, and that the thymic cortex and medulla exhibit different cycles of seasonal activity.     

Thymus of Rana perezi: presence of interdigitating cells

In the thymus of Rana perezi, as in other anuran amphibians, there exist two different portions, cortex and medulla. In both sections epithelio-reticular cells are observed as are lymphocytes, macrophages, and granulocytes. In addition, the medulla shows cysts and secretory, myoid, and hypertrophied epithelio-reticular cells. In the cortex, plasma cells and interdigitating cells were also observed. Interdigitating cells make contact with lymphocytes. This finding provides morphological support for the hypothesized role of interdigitating cells in antigen presentation.     

Macrophages and epithelial cells of the thymus gland. An ultrastructural study in the natterjack, Bufo calamita

In the present study, the ultrastructure of the stromal components, basically epithelial elements and macrophages, of the thymus of adult natterjacks, Bufo calamita has been analyzed. A network of stellate epithelial-reticular cells joined together by desmosomes, constitutes the main component of the thymic parenchyma in both cortex and medulla. In the medulla pale, electron-lucent epithelial cells, sometimes showing surface interdigitations, are striking elements. Moreover, uni- and multicellular epithelial cysts appear in the thymic medulla as well as granulated cells of possible endocrine significance. Remarkably, isolated or grouped gland cells whose morphology and cytoplasmic content resemble that of the skin glands, were occasionally found. Finally, macrophages, multinucleated giant cells and dendritic-like cells, the latter intimately associated to lymphocytes, occur in the thymus of Bufo calamita. The most remarkable morphologic characteristics of all those non-lymphoid cell types, as well as their possible functional significance are comparatively discussed with available information on the amphibian and higher vertebrate thymic cytoarchitecture.     

Sites of action of soltriol (vitamin D) in hamster spleen,thymus, and lymph node,studied by autoradiography

Summary Sibirian hamsters (Photopus sungorus) were injected with³H dihydroxycholecalciferol (vitamin D, soltriol). Autoradiograms of spleen, thymus, and lymph nodes revealed nuclear concentration of the hormone in a select population of cells in all of these organs. In the spleen, labeled cells were abundant in the red pulp, but sparse in the white pulp. In the periarterial lymphatic sheath (PALS) labeled cells were found predominatly at the outer rim, with a few scattered labeled cells in the inner PALS and in the marginal zone. Lymphocytes, including pyronin-positive plasma cells, did not display nuclear labeling. In the red pulp, some of the labeled cells contained pigmented inclusions in the cytoplsm, while most of the labeled cells did not appear phagocytic under the conditions of the experiment. In the thymus, labeled cells were most numerous in the medulla, but sparse in the cortex. Many of the thymic target cells were larger than the unlabeled lymphocytes, with a large and pale nucleus, sometimes containing a distinct nucleolus, and with large and dendritic cytoplasm, having the appearance and distribution of epithelio-reticular cells. In lymph nodes, scattered labeled cells were conspicuous in or near the subcapsular sinus, while other cells did not concentrate radioactivity in their nuclei. The results indicate that nuclear receptors and direct genomic actions for soltriol exist in certain cell populations of lymphatic tissues that probably include reticular cells and a subpopulation of macrophages. These target cells may mediate effects of the steroid on lymphocytes that appear to have no or only very low numbers of nuclear receptors.     

Thymic cell populations in amphibia: Quantitative study of the growth,stability, and regression of the cell populations in the thymus of the newtPleurodeles waltlii Michah

Summary Twenty days after fertilization (stage 40) the thymus ofPleurodeles waltlii consists of two main cell types: epithelial reticular cells (71%) and lymphoid stem-cells (24%).Between day 20 and day 72 (stage 53) the lymphoid stem-cells differentiate into lymphocytes, via the lymphoblast state. Commencing at day 20, epithelial reticular cells are transformed into epithelial reticular dense cells. Following day 65, other epithelial reticular cells begin to differentiate into epithelial hypertrophic cells, and these subsequently form thymic cysts. During this whole period intense proliferation takes place.The three types of polynuclear cells (neutrophil, eosinophil, and basophil), the macrophages, and the plasmocytes differentiate outside the thymus then migrate into it through the vascular system.Around day 72 (stage 53), the mature thymus consists of two parts: the first is visible as a background or cortex-like area, the second comprises medulla like spots, formed by small numbers of cysts.Around metamorphosis the cell populations reach a stable state.After metamorphosis the relative frequency of the lymphoid cell population progressively decreases, while the proportion of epithelial hypertrophic cells, together with cyst surface area, is increased. Consequently the ratio of cysts/background area increases with age.