The stem cell antigens Sca-1 and Sca-2 subdivide thymic and peripheral T lymphocytes into unique subsets

Stem cell Ag 1 and 2 (Sca-1 and Sca-2), so named due to their expression by mouse bone marrow stem cells, were evaluated for expression by populations of cells within the thymus. Immunohistochemical analysis demonstrated that Sca-1 was expressed by cells in the thymic medulla and by some subcapsular blast cells, as well as by the thymic blood vessels and capsule. Sca-2 expression, which was limited to the thymic cortex, could be associated with large cycling thymic blast cells. Both Sca-1 and Sca-2 were expressed on a sub-population of CD4-CD8- thymocytes, and this subpopulation was entirely contained within the Ly-1lo progenitor fraction of cells. Sca-1 expression by a phenotypically mature subset of CD4+CD8- thymocytes was also noted. Conversely, Sca-2 expression was observed on a phenotypically immature or nonmature subpopulation of CD4-CD8- thymocytes. MEL-14, an antibody that defines functional expression of a lymphocyte homing molecule, identified a small population of thymocytes that contained all four major thymic subsets. Sca-2 split the MEL-14hi thymocyte subset into two Sca-2+ non-mature/immature phenotype fractions and two Sca-2- mature phenotype fractions. In peripheral lymphoid organs, Sca-1 identified a sub-population of mature T lymphocytes that is predominantly CD4+CD8-, in agreement with the thymic distribution of Sca-1. Peripheral T cells of the CD4-CD8+ phenotype were predominantly Sca-1-. In contrast, Sca-2 did not appear to stain peripheral T lymphocytes, but recognized only a subset of B lymphocytes which could be localized by immunohistochemistry to germinal centers. Thus, expression of Sca-1 is observed throughout T cell ontogeny, whereas Sca-2 is expressed by some subsets of thymocytes, including at least one half of thymic blasts, but not by mature peripheral T lymphocytes.     

Hydrolase histochemistry of the thymus: development and species variations

In the present investigation the localization and activity of alkaline, neutral, and acid hydrolases of the thymus were studied during development of rats and mice and of various adult species using histochemical methods. If different procedures of tissue pretreatment were employed, several inhibition effects and morphological as well as enzyme histochemical artifacts occurred dependent on the mode of tissue pretreatment. After embedding in glycol methacrylate, sections of the thymus showed a better structural preservation than cryostat sections but were accompanied by a drastic decrease of activity and low localization quality of the final reaction products especially in the case of protease studies with 4-methoxy-2-naphthylamine peptides as substrates. Smears of thymic cells facilitated the allocation of enzymes to mobile or fixed cells in the stroma of the thymus. The perivascular localization of aminopeptidase M could only be shown with combined techniques. In comparison, primarily the proteases yielded information on the thymic stroma and in this context especially on the epithelial reticular cells and the stroma proper but also on thymocytes (lymphocytes) and enabled a species-dependent subdivision of the thymic reticulum already in the light microscope. Enzyme histochemically the development of the rat and mouse thymus could be subdivided into an early period and perinatal (pre- and postnatal) period of functional differentiation. Morphological (proliferation of cortical lymphocytes) and enzyme histochemical changes (disappearance of dipeptidylpeptidase IV, significant loss of alkaline phosphatase activity and beginning activity increase of aminopeptidase M) occurred primarily at the transition from the early to the prenatal period. During the postnatal phase, a significant activation of lysosomal enzymes in the thymic medulla and general enzymatic differentiation of the cortical epithelial reticular cells were found. Species differences and species similarities for the respective enzymes and their localization as well as for the thymic cells were noticed for adult rats, mice, guinea-pigs, hamsters, and marmoset monkeys. Differences were true especially for the thymocytes; less species differences were seen for the epithelial reticular cells; capsular and perivascular connective tissue and the macrophages behaved rather similarly. Species-independently certain medullary epithelial reticular cells showed high and typically localized alkaline phosphatase activities and species-dependently also high activities of neutral hydrolases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Production of a monoclonal antibody strongly reacting with immature thymic T lymphocytes and its immunohistological application

A monoclonal antibody Th-5 has been produced against mouse immature thymic lymphocytes and employed to study the process of T cell differentiation in the thymus. Immunohistologically, Th-5 positive thymic T lymphocytes were first found at Day 12 of gestation. They increased in number as well as staining intensity until Day 18 of gestation and decreased thereafter. Th-5 antigen expression was not seen in lymphoid cells in the fetal liver. In the newborn thymus, lymphocytes in the subcapsular layer were still strongly positive, while other cortical lymphocytes became moderately positive for Th-5. Th-5 positiveness was more pronounced in the medulla than in the cortex in the thymus of young adult mice. The staining pattern of Th-5 in the thymus was apparently different from those with other T cell markers (Thy-1, CD3, CD4, CD5, CD8) including J11d, Pgp-1, IL-2R, and 3A10 (TCR gamma delta). Flow cytometric analyses showed that the expression of Th-5 was mostly associated with the Thy-1 antigen. However, the fluorescent intensity of Th-5 gradually declined with ontogenic development of the thymus, and the molecular size of the antigen was approximately 100 kDa, which is different from Thy-1 antigen (25-30 kDa). Considering these findings, the strong expression of Th-5 could be one of the markers of immature thymic T lymphocytes in the early phase of the ontogenic development.     

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     

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.     

Differential regulation of Ca2+ mobilization in human thymocytes by coaggregation of surface molecules.

Variations in intracellular Ca2+ levels in developing thymocytes are likely to play a major role in both the activation-associated differentiation of thymocytes and in the selection or clonal deletion of cells. Here we examine the role of CD4, CD8, CD2, and CD45 in the regulation of intracellular Ca2+ levels in mature and immature thymocytes. Mature and immature thymocytes, distinguished on the basis of their CD5 expression, were analyzed simultaneously for their ability to mobilize Ca2+ after coaggregation of their CD3/TCR with other thymic surface Ag. Flow cytometric analysis by using Indo-1 showed that coaggregation of CD4, CD8, and CD2 with CD3/TCR clearly enhances a minimal signal delivered via CD3/TCR on immature thymocytes. Coaggregation with class I MHC had no discernible effect. The responsiveness of immature thymocytes correlated strictly with CD3 surface expression, such that loss of responsiveness occurred with reduced CD3 cell-surface density. However, even thymocytes with very low CD3 expression were able to respond to triggering via CD3 under optimal conditions, indicating that the CD3 signal-transducing mechanism is functional on early thymic cells. Intracellular increases in Ca2+ concentrations induced via CD3, could effectively be inhibited by cross-linking of CD45 and CD3 on immature thymocytes. Although triggering via CD2 alone induced a strong Ca2+ flux, prolonged incubation with activating anti-CD2 antibodies made thymocytes refractory to subsequent triggering. Refractoriness was associated with partial loss of surface CD3 and CD3 zeta. Our results indicate that thymic surface Ag are differentially involved in the regulation of intracellular Ca2+ levels in immature as well as mature thymocytes.     

Characteristics of the immature cells involved in T cell-mediated enhancement of syngeneic tumor growth.

Enhancement of tumor growth was observed when non-sensitized thymocytes were injected together with tumor cells into syngeneic mice, although this tumor enhancement was less pronounced than that caused by tumor-sensitized T lymphocytes. The cells within the thymus which are responsible for this tumor enhancement were found to be rapidly dividing and to be absent from the thymus a day after cortisone administration. At a longer time interval the cortison-depleted thymus was repopulated by dividing cells which exhibited tumor-enhancing reactivity. The characteristics of these cells suggest that they are in the early stages of thymic processing. The enhancing thymocytes were sensitive to treatment with the thymic humoral factor which functions in T cell maturation, and their enhancing activity was cancelled by such treatment. These results are compatible with our hypothesis that exposure of immature T cells to a tumor stimulus may lead to tumor enhancement whereas interaction between mature T lymphocytes and tumor cells may be required for tumor inhibition.     

Identification and in situ localization of the "thymic nurse cell" in man

The observation of the "thymic nurse cell" (TNC), a reticuloepithelial cell with intracytoplasmic lymphocytes, in suspension of murine thymic tissue prompted us to investigate the existence of this cell in cell suspension, as well as in tissue sections of the human thymus. TNC-like cells were enriched in suspension by enzymatic disintegration of thymic tissue and 1 X G sedimentation over 50% fetal calf serum gradients. TNC-like cells were negative for lysosomal enzymes: in this respect, as well as in light microscopic morphology, the cells were different from tissue macrophages with intracytoplasmic lymphocytes. In electron microscopy, TNC-like cells showed reticuloepithelial characteristics. In 1-micron tissue sections, clusters of lymphocytes with a possible reticuloepithelial nucleus were observed close to blood capillaries in the cortical area. Ultrastructural analysis confirmed the epithelial nature of this cell, as well as its location adjacent to blood capillaries. We concluded that there is in situ existence of TNC in man. This observation enables studies on the role of TNC in intrathymic T cell maturation.     

A peripheral and central T cell antigen recognized by a monoclonal thymocytotoxic autoantibody from New Zealand black mice

Naturally occurring thymocytotoxic autoantibodies (NTA) have been suggested to be the cause of thymic atrophy and T cell disorders in human and murine lupus. Definitive studies on NTA's role in the induction of SLE, however, have been lacking due to the lack of a pure source of NTA. Although it is clear that NTA are a heterogeneous group of antibodies, the nature of their antigens has remained obscure. We report the characteristics of a monoclonal NTA, designated SAG-3, which appears more reflective of the activities previously reported of serum NTA than other NTA-secreting clones. SAG-3 is an IgM autoantibody cytotoxic for 80 to 90% of thymocytes, 20 to 25% of splenic lymphocytes, 25 to 30% of lymph node cells, and less than 3% cortisol-resistant thymocytes, bone marrow, and fetal liver cells. SAG-3 is murine-specific without reactivity towards rat, hamster, or guinea pig, and appears very early in thymic development, on day 17 fetal thymocytes. SAG-3 is equally cytotoxic against several strains of mice, including both Thy-1.1 and Thy-1.2 allotypes, and the cytotoxicity is absorbed by brain but not liver cells. Reactive thymocytes occurred throughout the cortical regions of the thymus, indicating preferential affinity towards immature thymocytes. Although the serologic activities of SAG-3 suggest that Thy-1 alloantigen is its target, SAG-3 antigen is found to be distinct from Thy-1 and also from Lyt-1, Lyt-2, or L3T4 antigens. The binding of SAG-3 to thymocytes could be competitively inhibited by NTA-positive NZB sera.     

Induction of allospecific suppressor T cells in vitro.

Incubation of mouse thymic lymphocytes with irradiated allogeneic spleen cells gave rise to suppressor cells. The suppressor activity was assayed by adding the incubated cell mixture to a mixed lymphocyte culture (MLC) in which the responder cells were syngeneic with the sensitized thymocytes and the stimulator cells were syngeneic with the sensitizing spleen cells. Such addition suppressed significantly thymidine incorporation in the mixed lymphocyte reaction (MLR). The suppressor cells were found to carry the θ antigen and to function allospecifically, as shown by cross-testing in three allogeneic combinations. Our data suggest that these cells may originate from immature cortisone-sensitive thymic lymphocytes and also provide some preliminary information concerning their mode of action.     

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。     

A novel T cell-activating molecule (THAM) highly expressed on CD4-CD8- murine thymocytes

Recent studies have focused on the potential role of accessory molecules such as CD2, CD28, Thy-1, or TAP in the delivery of activating signals to thymocytes through antigen-independent pathways. To better understand the molecular interactions involved in the expansion of early thymic immigrants, rat mAb were raised against murine thymocyte-surface molecules and screened for their capacity to trigger thymocyte proliferation. One of these mAb (H194-112, IgG2a) was found to recognize a novel heterodimeric thymocyte-activating molecule (THAM) of Mr = 110,000 to 128,000. Flow cytometric analyses and staining patterns on frozen thymus sections subdivided adult thymocytes in three subsets expressing THAM at either low (10%), moderate (80%), or high (5 to 8%) cell-surface density; these cell groups were found to correspond, respectively, to the medullary, the cortical, and the immature CD4-CD8-, J11d+ thymocytes, in which the T cell precursor pool is included. Moreover, most (90%) day 16 fetal thymocytes were also found to upregulate THAM cell-surface expression. The THAMhigh cells were localized in the subcapsular area of the neonatal thymus and scattered throughout the adult organ. Cross-linked mAb H194-112 induced the proliferation of both immature and mature thymocytes in the presence of either PMA or IL-1 and IL-2. The observation that early thymocytes up-regulate THAM along with the IL-2R suggests that this molecule might be involved in an important activation pathway during thymocyte differentiation.     

Relationship between structure and T-lymphocyte maturation in human thymomas. Enzyme histochemical and immunohistological studies

Twenty-six human thymomas were studied in an attempt to correlate their morphological appearance with the type and degree of T-lymphocyte maturation, as determined by acid alpha-naphthyl-acetate esterase (ANAE) activity and immunological analysis. Four normal human thymuses were used for purposes of comparison. Two morphological patterns were identified in the thymomas. The distinction was based largely on similarities between the neoplastic epithelial cells and normal cortical and medullary epithelial cells, and on the relative proportions of epithelial cells and lymphocytes. By these criteria "medullary" and "cortical" patterns were identified. In several thymomas both patterns were present in the same tumor ("mixed-type pattern"), producing alternating dark cortical-like areas and lighter foci of medullary differentiation. A good correlation was found between the two patterns and the phenotype of the T-associated lymphoid component. ANAE activity, which was completely lacking in normal cortical thymocytes, was almost absent in the phenotypically immature T-cells of cortical-type thymomas. By contrast, in the medullary-type thymomas, T-cells showed immunological features in common with medullary thymocytes. This was characterized by strong ANAE activity in the majority of cells with a staining pattern corresponding to that of peripheral T-lymphocytes. In addition, most of the proliferating epithelial cells in medullary-type thymomas stained strongly with anti-cytokeratin and anti-epidermal-type keratin antisera. In the mixed-type thymomas the epithelial cell morphology and the immunohistochemical and enzymic features of the T-cells were found to be closely related to the respective cortical--or medullary-like areas. It was concluded that the various characteristics of normal thymic cortex and medulla studied are also present in thymomas. In particular, in medullar-type thymomas the presence of many of the features of normal thymic medulla, such as a squamous cell component, macrophages and interdigitating reticulum cells, may constitute a microenvironment which operates actively in T-cell education. This may account for the functional activities, characteristic of peripheral T-lymphocytes, which T-lymphocytes attain in these thymomas.     

Lectin target cells in human central nervous system and the pituitary gland

Peanut lectin (PNL), Concanavalin A (Con A) and Ulex europaeus lectin I (Ulex) were chosen to map their binding sites in different regions of formalin fixed and paraffin embedded human central nervous system tissue and pituitary gland tissues. An extended PaP method was used for PNL and Ulex, whereas a direct peroxidase technique was employed for Con A. In astrocytes, the cytoplasm as well as the delicate processes were stained by PNL and Con A; the most conspicuous binding of PNL was seen in the ependymal cells and on the surface of plexus epithelial cells; in the anterior part of the pituitary gland a selective population was PNL positive. Intracytoplasmic Con A acceptors could be demonstrated in neurons, in ependymal cells, and in plexus epithelial cells. Intracytoplasmic Con A receptors were finely granular in astrocytes, oligodendrocytes, and in some cells in the pituitary gland. Ulex binding was restricted to the vascular endothelial cells and a selective population of cells in the pituitary gland. Our results suggest that lectins may be good tools for the evaluation of their respective target cells in the central nervous system and in the pituitary gland.     

Lectin target cells in human central nervous system and the pituitary gland

Summary Peanut lectin (PNL), Concanavalin A (Con A) and Ulex europaeus lectin I (Ulex) were chosen to map their binding sites in different regions of formalin fixed and paraffin embedded human central nervous system tissue and pituitary gland tissues. An extended PaP method was used for PNL and Ulex, whereas a direct peroxidase technique was employed for Con A. In astrocytes, the cytoplasm as well as the delicate processes were stained by PNL and Con A; the most conspicious binding of PNL was seen in the ependymal cells and on the surface of plexus epithelial cells; in the anterior part of the pituitary gland a selective population was PNL positive. Intracytoplasmic Con A acceptors could be demonstrated in neurons, in ependymal cells, and in plexus epithelial cells. Intracytoplasmic Con A receptors were finely granular in astrocytes, oligodendrocytes, and in some cells in the pituitary gland. Ulex binding was restricted to the vascular endothelial cells and a selective population of cells in the pituitary gland. Our results suggest that lectins may be good tools for the evaluation of their respective target cells in the central nervous system and in the pituitary gland.     

Thymic shared antigen-1. A novel thymocyte marker discriminating immature from mature thymocyte subsets.

In a previous study, we raised a mAb (MTS 35) reacting with a plasma membrane Ag expressed on both cortical thymocytes and a subset of thymic medullary epithelial cells. In view of the shared expression of this molecule, we have defined it as thymic shared Ag-1 (TSA-1). Considering its selective reactivity with cortical, but not medullary thymocytes, the relevance of TSA-1 as a marker of immature T cells was investigated in detail in this study, using multicolor flow cytometric analysis. TSA-1 was found on all immature thymocyte subsets (CD3-4-8-, CD3-4+8-, CD3-4-8+, CD3-4+8+, CD3low4+8+). Conversely, CD3high4+8- and CD3high4-8+ thymocytes, early thymic migrants and peripheral T cells were TSA-1-. More refined gating and analysis of the transitional CD3intermediate/high4+8+ thymocytes, proposed candidates for negative selection, demonstrated that approximately one half were TSA-1-. In fact, there was a directly inverse relationship between TSA-1 and CD3 expression on thymocytes. In the periphery, TSA-1 was detected on B lymphocytes. TSA-1 is PI-linked and has a molecular mass of 17 kDa nonreduced, or 12 to 13 kDa reduced. Through cross-correlation analysis, this molecule was distinct from H-2K, PNA-R, CD5, CD11a/18, Thy-1, HSA, Ly6A/E, Ly6C, ThB, CD25, CD44. Hence TSA-1 appears to be a unique marker which exquisitely separates mature from immature thymocytes.     

Mink cell focus-forming murine leukemia virus infection induces apoptosis of thymic lymphocytes

In a previous study we identified the subpopulations of thymus cells that were infected by the lymphomagenic MCF13 murine leukemia virus (MLV) (F. K. Yoshimura, T. Wang, and M. Cankovic, J. Virol. 73:4890-4898, 1999) and observed an effect on thymus size by virus infection. In this report we describe our results which demonstrate that MCF13 MLV infection of thymuses reduced the number of T lymphocytes in this organ. Histological examination showed diffuse lymphocyte depletion, which was most striking in the CD4(+) CD8(+) lymphocyte-enriched cortical zone. Consistent with this, flow cytometric analysis showed that the lymphocytes which were depleted were predominantly the immature CD3(-) CD4(+) CD8(+) and CD3(+) CD4(+) CD8(+) cells. A comparison of the percentages of live, apoptotic, and dead cells of the gp70(+) and gp70(-) thymic lymphocytes suggested that this effect on thymus cellularity is a result of virus infection. Studies of the survival of thymic T lymphocytes in culture showed that cells from MCF13 MLV-inoculated mice underwent greater apoptosis and death than cells from control animals. Assays for apoptosis included 7-amino-actinomycin D staining, DNA fragmentation, and cleavage of caspase-3 and poly(ADP-ribose) polymerase proenzymes. Our results suggest that apoptosis of thymic lymphocytes by virus infection is an important step in the early stages of MCF13 MLV tumorigenesis.     

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.     

Induction of B cell priming by neonatal injection of mice with thymic-independent (type 2) antigens.

Mice injected at birth with the thymus-independent type 2 antigen TNP-AECM-Ficoll have augmented anti-TNP antibody responses when their spleen cells subsequently are challenged in vitro with TNP-coupled thymic independent or thymic dependent antigens. This neonatal priming effect was shown to occur in neonatal nu/nu mice and thus does not appear to require T lymphocytes. The primary explanation for the priming effect seems to be an increase of approximately 10-fold in the numbers of TNP-specific precursors of antibody-forming cells. The neonatal injection of TNP-AECM-Ficoll induces little or no antibody formation directly. It appears, therefore, that some thymic independent antigens can deliver a signal to immature B cells, which causes clonal expansion, but is unable to induce differentiation into antibody-forming cells.