Characterization of apoptosis-like endonuclease activity in avian thymocytes.

In the current study the internucleosomal DNA cleavage activity associated with apoptosis was investigated in avian thymocytes. Thymocyte nuclear proteins from glucocorticoid-treated chickens were incubated with chicken red blood cell (cRBC) nuclei, and DNA degradation was analyzed by agarose gel electrophoresis and fluorescence-activated flow cytometry. The thymocyte nuclear extract contained an endonuclease activity that degraded cRBC chromatin at internucleosomal sites as detected by agarose gel electrophoresis. Flow cytometry analysis of cRBC nuclei that were treated with thymocyte nuclear proteins demonstrated a loss of cellular DNA as a function of the amount of added nuclease activity. Furthermore, it was demonstrated that the thymocyte nuclear extract contained a nuclease activity that was capable of degrading radiolabelled naked 32P-DNA into acid soluble DNA fragments. All three assay methods demonstrate that the thymocyte nuclease activity can be inhibited by EDTA, zinc ions and the nuclease inhibitor aurintricarboxylic acid. Based on the analysis of cofactor requirement of this nuclease activity and its susceptibility to inhibitors, the endonuclease activity present in avian apoptotic thymocytes appears to be identical to the mammalian counterpart.     

A rapid cell membrane permeability test using flourescent dyes and flow cytometry

A reliable and rapid test to detect cytotoxic chemicals which affect cell membranes is described. Fluorescein diacetate freely penetrates intact cells where it is hydrolyzed to its fluorochrome, fluorescein, which is retained in the cell due to its polarity. On the other hand, ethidium bromide is known to be excluded from the intact cell, staining only nucleic acids of membrane-damaged cells. The combination of both fluorochromes results in counter-staining: intact cells fluoresce green (cytoplasm) and membrane-damaged cells fluoresce red (nucleus and RNA). Rat thymocytes freshly isolated without enzyme treatment were incubated simultaneously with test substance and dye solution fluorescein diacetate and ethidium bromide. A two-parameter analysis was performed on a flow cytometer with an on-line computer. Concentration-dependent effects of various detergents and solvents were quantified by measuring the amount of dye retention, i.e., the decrease or increase in fluorescein—fluorescence (peak shift), and the decrease in dye exclusion (increase in ethidium bromide-staining) relative to the untreated control. The assay can be used for rapid monitoring of chemical insults to cell membranes which precede the decrease of the viability measured by pure dye exclusion techniques.Abbreviations DMA dimethyl sulfate - DMSO dimethyl sulfoxide - EB ethidium bromide - F fluorescein - FDA fluorescein diacetate - FS₂₅ concentration of test substance resulting in a F-peak left-shift of 25% from control - PBS phosphate buffered saline - SCT forward light scatter - SDS sodium dodecyl sulfate     

Lack of expression on cultured human T-lymphocytes of a T-cell antigen shared by the molt-4 cell line and normal human thymocytes

Summary Four hematopoietic cell lines (CCRF-CEM, HSB-2, MOLT-4, and RPMI-8402), derived from acute lymphoblastic leukemia and expressing T-cell surface markers (T-HCL), were studied with two specific anti-T-cell sera. The sera were raised in rabbits against human thymocytes (anti-HTY) and against T-cells cultured in the presence of conditioned medium derived from lymphocytes stimulated with PHA (anti-CTC). Both sera were absorbed to obtain a T-cell specific pattern of reaction and were further absorbed with normal peripheral blood lymphocytes or with each of the four T-HCL. The anti-HTY sera absorbed with CEM, 8402, and HSB-2 still reacted with MOLT-4. A similar pattern of reactivity was found only with the anti-CTC absorbed with 8402, whereas, after absorptions with the other cell lines, this antiserum was unreactive against MOLT-4. After absorption with normal peripheral blood lymphocytes, anti-HTY still reacted with thymocytes and MOLT-4 but was negative on CTC. In contrast, anti-CTC absorbed with peripheral blood lymphocytes (PBL) was negative on thymocytes and MOLT-4 but still reacted against CTC. Our data confirm the existence of a T-cell antigen (probably an early T-cell differentiation antigen) shared between thymus and MOLT-4. This antigen is not expressed on CTC, although these cells express an antigenic pattern more complex than PBL. Antisera to CTC represents a source of anti-T-cell sera free of contamination with antibodies to early thymus-related antigens but containing other T-cell-related specificities. Supported in part by Naval Medical Research and Development Command, Research Task No. ZF51.524.013.1025, and National Cancer Institute Contract No. Y01-CB-00319. The opinions and assertions contained herein are the private ones of the writers and are not to be construed as official or reflecting the views of the Navy Department or the naval service at large. The experiments reported herein were conducted according to the principles set forth in the current edition of the “Guide for the Care and Use of Laboratory Animals,” Institute of Laboratory Animal Resources, National Research Council.     

Cell death in the rat thymus: a minireview

During the last decades, the literature has clearly established the fundamental role of the thymus in the development of an effective immune system. During thymocyte development and maturation, potentially autoreactive thymocytes are eliminated by a process known as apoptosis or programmed cell death responsible for the negative selection occurring within the thymus. This process is in sharp contrast to other types of cell death referred to as necrosis. Actually, three different types of cell death have been recently observed morphologically in the rat thymus, i.e. necrosis, apoptosis and clustered cell death. Moreover, among the numerous factors influencing thymocyte cell death, particular attention has been paid to hormones, chemicals, biological compounds and physical agents that may influence the type and/or the extent of cell death. Finally, a brief overview has been devoted to the contribution of mitochondria, nitric oxide, glutathione and intracellular levels of cations in addition to the activity of genes as cdk2, p53, Fas and members' of the Bcl2 family in modulating rat thymus cell death.     

Automated technique to evaluate thymocyte adhesion to thymic epithelial cells

Thymocyte adhesion to thymic epithelial cells is a relevant issue during intrathymic T-cell differentiation, and directly intervenes in the generation and expansion of the T-cell repertoire. In view of these data, it was apparent the usefulness of an automated strategy to evaluate the degree of thymic epithelial cell-thymocyte adhesion. This prompted us to develop an ELISA procedure (using an anti-Thy1 reagent) to determine the degree of thymocyte adhesion onto cultured thymic epithelial cells. The procedure described herein is simple, non-radioactive and reproducible. Additionally, it can potentially be applied to quantitate the degree of thymocyte adhesion to any cellular or non-cellular substrate (for example, extracellular matrix). Moreover, it detected fluctuations of thymocyte adhesion secondary to glucocorticoid treatment of epithelial cells. Thus, it can be regarded as a further tool to analyze intrathymic interactions.     

In vitro enhancing effects of thymic dendritic cells on apoptotic cell death of thymocytes

Using terminal deoxynucleotide transferase-mediated dUTP-digoxigenin nick end labeling (TUNEL) assay and propidium iodide-DNA staining flow cytometry assay, the effects of mouse thymic dendritic cells (MTSC4) on the process of programmed cell death of thymocytesin vitro were investigated. It was noticed that thymocytes bound to MTSC4 used in this study. That the percentages of apoptotic nuclei of the bound thymocytes on MTSC4 were much higher than those of medium-cultured thymocytes, while the bound thymocytes on mouse thymic epithelial cell (MTEC1) showed much lower percentages of apoptosis. FACS analysis quantitatively confirmed the observation. Phenotype analysis showed that MTSC4 induced the deletion of CD4 + CD8 + cells and CD4 + CD8-.cells in 18 h of coculture. The results suggest that the negative selection of medullary thymocytes may be achieved by thymic dendritic cells through their enhancing effects on apoptosis. Project supported by the National Natural Science Foundation of China (Grant No.39670685) and FokYin Tung Education Foundation.     

Inducible gene expression with the Tet-on system in CD4+ T cells and thymocytes of mice

CD4+ T cells with their growing list of effector and regulatory subpopulations have vital functions within the immunohematopoietic system. We report here on the first mouse lines that allow temporally and quantitatively controlled expression of transgenes specifically in CD4+ thymocytes and T cells. These were constructed using the Tet-on system. The rtTA2(S)-M2 version of the reverse tetracycline-dependent transactivator was placed under control of all known CD4 regulatory elements. Reporter transgene expression in mice expressing these constructs is highly specific for CD4+ cells, is strictly dependent on the tetracycline derivative doxycycline, and can be regulated by up to five logs depending on the doxycycline concentration. Moreover, we demonstrate that these mice can be used for noninvasive in vivo imaging of a coexpressed luciferase reporter. These new mouse lines should be highly valuable for studying and manipulating numerous aspects of CD4+ T cell development, biology, and function.     

Changes in the glycolipid composition and characteristic activation of GM3 synthase in the thymus of mouse after administration of dexamethasone

Glycolipids in the thymus of mice after administration of dexamethasone were compared with those in control mice. In parallel with a decrease in the tissue weight due to the disappearance of immature thymocytes in the cortex, the amounts of GlcCer, Gg₄Cer and GM1 decreased from 18 h after intraperitoneal administration of dexamethasone, but those of Gb₄Cer and Forssman glycolipid did not change, indicating the differential distribution of ganglio- and globo-series glycolipids in the thymus, GlcCer, Gg₄Cer and GM1 being on dexamethasone-sensitive cortical thymocytes, and Gb₄Cer and Forssman glycolipid on dexamethasone-resistant cells including thymic stromal cells, respectively. At the same time, a characteristic increase in GM3, whose amount per thymus and concentration per mg of thymus were increased 4-fold and 13-fold compared to those in the control mice, respectively, was observed at the onset of the decrease in tissue weight and was due to the increased activity of LacCer sialyltransferase with the enhanced expression of its gene and the concomitant decrease in cytosolic sialidase activity. One can suggest that endogenous accumulation of GM3 is involved in the dexamethasone-induced apoptosis of cortical thymocytes. On radiolabeling of the thymus with CMP-[¹⁴C]-NeuAc, the incorporation of radioactivity into GM3 was preferentially observed in the thymuses of dexamethasone-administered mice, but not in those of control mice, suggesting the possible involvement of plasma membrane-associated sialytransferase in GM3 synthesis in the thymuses of dexamethasone-administered mice. Published in 2005.     

Functional maturation of mouse CD4+CD8- thymocytes induced by medullary-type thymus epithelial cells

Murine CD4⁺CD8^- (CD4SP) thymocyte subset is a heterogeneous population, in which the Qa-2^- cells are less functional, whereas the Qa-2⁺ cells are fully functional. Evidence is provided here that the transition from Qa-2^- to Qa-2⁺ CD4SP thymocytes is an intrathymic process of differentiation induced by thymic medullary-type epithelial cells. The separated Qa-2^-CD4SP could be induced to express Qa-2 molecules up to 84%- 89% of the total viable celb after cocultured for 3d with MTEC1 cells, a murine thymic medullary type epithelial cell line established in our laboratory. Kinetic study showed that both the percentage of Qa-2⁺ cells and the density of the expressed Qa-2 molecules on CD4SP thymocytes induced by MTEC1 were progressively increasing in 72-h cultures. The MTECl-induced Qa-2⁺CD4SP thymocytes were fully functional, which exhibited capabilities of proliferation and cytokine secretion in response to Con A stimulation as high as those of freshly isolated Qa-2⁺CD4SP thymocytes. The profile of cytokines secreted by MTECl-induced Qa-2⁺CD4SP thymocytes was Thy 0 type specified by the production of IL-2, IL-4 and IL-6. The results suggest that Qa-2^-CD4SP thymocytes may give rise to the Qa-2⁺CD4SP thymocytes, and acquire fully functional competence in thymic medulla under the foster of local epithelial cells.     

Interaction of the B subunit of cholera toxin with endogenous ganglioside GM1 causes changes in membrane potential of rat thymocytes

Summary The fluorescent anionic dye, bisoxonol, and flow cytometry have been used to monitor changes in the membrane potential of rat thymocytes exposed to the B subunit of cholera toxin. The B subunit induced a rapid hyperpolarization, which was due to activation of a Ca²⁺-sensitive K⁺ channel. Reduction of extracellular Ca²⁺ to <1 m by the addition of [ethylenebis(oxyethylenenitrilo)]tetraacetic acid immediately abolished the hyperpolarization caused by the B subunit. Cells treated with quinine and tetraethylammonium lost their ability to respond to the B subunit, whereas 4-aminopyridine did not have any effect. Thus, calcium-sensitive and not voltage-gated K⁺ channels appeared to be responsible for the hyperpolarization. The results of ion substitution experiments indicated that extracellular Na⁺ was not essential for changes in membrane potential. Further studies with ouabain, amiloride and furosemide demonstrated that electrogenic Na⁺/K⁺ ATPase, Na⁺/H⁺ antiporter and Na⁺/K⁺/Cl^– cotransporter, respectively, were not involved in the hyperpolarization process induced by the B subunit. Thus, crosslinking of several molecules of ganglioside GM1 on the cell surface of rat thymocytes by the pentavalent B subunit of cholera toxin modulated plasma membrane permeability to K⁺ by triggering the opening of Ca²⁺-sensitive K⁺ channels. A role for gangliosides in regulating ion permeability would have important implications for the function of gangliosides in various cellular phenomena.