Carlo Riccardi

A rapid and simple method for measuring thymocyte apoptosis by propidium iodide staining and flow cytometry

Corticosteroids, calcium ionophores and anti-CD3 monoclonal antibodies kill mouse thymocytes incubated in vitro. Cell death is preceded by extensive DNA fragmentation into oligonucleosomal subunits. This type of cell death (apoptosis), which physiologically occurs in the intrathymic process of immune cell selection, is usually evaluated by either electrophoretic or colorimetric methods which measure DNA fragmentation in the nuclear extracts. These techniques are unable to determine the percentage of apoptotic nuclei or recognize the apoptotic cells in a heterogeneous cell population. We have developed a flow cytometric method for measuring the percentage of apoptotic nuclei after propidium iodide staining in hypotonic buffer and have compared it with the classical colorimetric and electrophoretic techniques using dexamethasone (DEX)-treated mouse thymocytes. Apoptotic nuclei appeared as a broad hypodiploid DNA peak which was easily discriminable from the narrow peak of thymocytes with normal (diploid) DNA content in the red fluorescence channels. When the DEX-induced apoptosis was inhibited by either low-temperature (4 degrees C) incubation or cycloheximide treatment, no hypodiploid DNA peak appeared. Similarly, thymocyte death induced by sodium azide, a substance with cell-killing activity through non-apoptotic mechanisms, did not result in any variation in the normal DNA peak. The flow cytometric data showed an excellent correlation with the results obtained with both electrophoretic and colorimetric methods. This new rapid, simple and reproducible method should prove useful for assessing apoptosis of specific cell populations in heterogeneous tissues such as bone marrow, thymus and lymph nodes.

Analysis of apoptosis by propidium iodide staining and flow cytometry

Since its introduction, the propidium iodide (PI) flow cytometric assay has been widely used for the evaluation of apoptosis in different experimental models. It is based on the principle that apoptotic cells, among other typical features, are characterized by DNA fragmentation and, consequently, loss of nuclear DNA content. Use of a fluorochrome, such as PI, that is capable of binding and labeling DNA makes it possible to obtain a rapid (the protocol can be completed in about 2 h) and precise evaluation of cellular DNA content by flow cytometric analysis, and subsequent identification of hypodiploid cells. The original protocol enhanced the capacity for a rapid, quantitative measure of cell apoptosis. For this reason, since its publication, the PI assay has been widely used, as demonstrated by the large number of citations of the original paper and/or the continuous use of the method in many laboratories.

Natural killer cells. Characteristics and regulation of activity.

Recently there has been increasing recognition of natural cell-mediated cytotoxicity as a potentially important antitumor effector mechanism in addition to that of specifically immune T cells and of activated macrophages. Although natural cellular cytotoxicity was first recognized only a few years ago (Herberman et al. 1973,1974, McCoy et al. 1973b, Oldham et al. 1973, Rosenberg et al. 1972,1974), there has already been extensive research in many laboratories on the nature of the effector cells, the possible mechanisms of cytotoxicity, the factors regulating the levels of reactivity, and the relevance of natural immunity to in vivo resistance against tumor growth and immune surveillance. A principal component of natural cell-mediated cytotoxicity in rodents and man has been found to be a particular subpopulation of lymphocytes which have been termed natural killer (NK) cells. We have recently reviewed in detail much of the available information on NK cells (Herberman & Holden 1978). In this paper we will only summarize our views on the characteristics of NK cells and focus on a few issues of current interest in our laboratory.

A New Dexamethasone-Induced Gene of the Leucine Zipper Family Protects T Lymphocytes from TCR/CD3-Activated Cell Death

By comparing mRNA species expressed in dexamethasone (DEX)-treated and untreated murine thymocytes, we have identified a gene, glucocorticoid-induced leucine zipper (GILZ), encoding a new member of the leucine zipper family. GILZ was found expressed in normal lymphocytes from thymus, spleen, and lymph nodes, whereas low or no expression was detected in other nonlymphoid tissues, including brain, kidney, and liver. In thymocytes and peripheral T cells, GILZ gene expression is induced by DEX. Furthermore, GILZ expression selectively protects T cells from apoptosis induced by treatment with anti-CD3 monoclonal antibody but not by treatment with other apoptotic stimuli. This antiapoptotic effect correlates with inhibition of Fas and Fas ligand expression. Thus, GILZ is a candidate transcription factor involved in the regulation of apoptosis of T cells.

GITR, a member of the TNF receptor superfamily, is costimulatory to mouse T lymphocyte subpopulations

GITR (glucocorticoid‐induced TNFR family related gene) is a member of the TNFR superfamily (TNFRSF) that is expressed in different cell types, including T lymphocytes. Because of a high homology in its cytoplasmic region with other known costimulatory members of the TNFRSF, we investigated whether GITR played a costimulatory role in T lymphocyte subpopulations. Our results show that the proliferation response of CD8+ and CD4+ peripheral T cell subpopulations was potentiated when a GITR costimulus was added to an anti‐CD3 stimulus. Furthermore, expression of the main activation‐induced receptor (IL‐2Rα) and production of IL‐2 and IFN‐γ were increased more with a GITR costimulus than with anti‐CD3 alone. GITR stimulation also enhanced anti‐CD3‐induced ERK phosphorylation, suggesting that GITR is involved in MAPK‐pathway activation. Interestingly, CD4+CD25+ regulatory T cell (Treg cell) proliferation was triggered by the GITR costimulus; Treg cell proliferation was paralleled by the loss of the anergic phenotype and suppressor activity. Nevertheless, unstimulated GITR–/– CD4+CD25+ and GITR+/+ CD4+CD25+ cells were equally able to exert suppressor activity on CD4+CD25– responder cells. These results indicate a novel function for GITR as costimulatory molecule of T cell subsets.

Reverse signaling through GITR ligand enables dexamethasone to activate IDO in allergy

Glucocorticoid-induced tumor necrosis factor receptor (GITR) on T cells and its natural ligand, GITRL, on accessory cells contribute to the control of immune homeostasis. Here we show that reverse signaling through GITRL after engagement by soluble GITR initiates the immunoregulatory pathway of tryptophan catabolism in mouse plasmacytoid dendritic cells, by means of noncanonical NF-κB–dependent induction of indoleamine 2,3-dioxygenase (IDO). The synthetic glucocorticoid dexamethasone administered in vivo activated IDO through the symmetric induction of GITR in CD4+ T cells and GITRL in plasmacytoid dendritic cells. The drug exerted IDO-dependent protection in a model of allergic airway inflammation. Modulation of tryptophan catabolism via the GITR-GITRL coreceptor system might represent an effective therapeutic target in immune regulation. Induction of IDO could be an important mechanism underlying the anti-inflammatory action of corticosteroids.

Lymphokine-activated killer cell activity:Characteristics of effector cells and their progenitors in blood and spleen

Leukocytes in blood and spleen can be activated by interleukin 2 (IL-2) to become cytotoxic to certain tumor cell lines in vitro. Recent evidence suggests that such lymphokine-activated killer (LAK) cells can bring about the regression of solid tumors in animals and patients, under certain circumstances. Here, Ronald Herberman and colleagues from eight international laboratories, review what is known of the characteristics of LAK cell activity and conclude that most of it can be attributed to natural killer cells stimulated by IL-2.

Glucocorticoid-induced leucine zipper (GILZ): a new important mediator of glucocorticoid action

Glucocorticoids (GCs) represent the mainstay of current anti‐inflammatory and immunosuppressive strategies, mediating effects that mostly result in transcriptional regulation of glucocorticoid receptor target genes. A variety of actions are tied together in the response to GC treatment. Dissecting the beneficial from the detrimental actions in GC therapy is a major challenge in basic research, raising the critical issue of whether a single target gene or gene family might eventually be linked to a specific GC function. Glucocorticoid‐induced leucine zipper (GILZ) was originally discovered in studies aimed at characterizing genes targeted by dexamethasone. The first suggestion that GILZ plays an important role in GC immunomodulation came from observations of GILZ up‐regulation by GCs, mainly in lymphoid organs, and inhibition of anti‐CD3‐induced activation and apoptosis. The identification of GILZ interaction with and inhibition of NF‐κB provided a first molecular mechanistic basis for explaining GILZ effects on T cells. Subsequently, other GILZ targets have been identified, including AP‐1, Raf‐1, and Ras, all involved in GC effects. The finding that GILZ silencing abrogates the antiproliferative activity of dexamethasone and reduces GC inhibition of cytokine‐induced COX‐2 expression clearly gained GILZ a distinguished reputation within the critical mediators of GC effects. The multiple functions of GILZ and their potential biological relevance are here reviewed.—Ayroldi, E., Riccardi, C. Glucocorticoid‐induced leucine zipper (GILZ): a new important mediator of glucocorticoid action. FASEB J. 23, 3649‐3658 (2009). www.fasebj.org

The natural tyrosine kinase inhibitor genistein produces cell cycle arrest and apoptosis in Jurkat T-leukemia cells

Genistein, a natural isoflavonoid phytoestrogen, is a strong inhibitor of protein tyrosine kinases. We analyzed the effects of genistein on in vitro growth, cell-cycle progression and chromatin structure of Jurkat cells, a T-cell leukemia line with a constitutively increased tyrosine phosphorylation pattern. Exposure of in vitro cultured Jurkat cells to genistein resulted in a dose-dependent, growth inhibition. Cell-cycle analysis of genistein-treated cells revealed a G2/M arrest at low genistein concentrations (5-10 micrograms/ml), while at higher doses (20-30 micrograms/ml) there was also a perturbation in S-phase progression. The derangements in cell-cycle control were followed by apoptotic death of genistein-treated cells. Immunocytochemical analysis of cells stained with a FITC-conjugated anti-phosphotyrosine monoclonal antibody showed that 30 micrograms/ml genistein effectively inhibit tyrosine kinase activity in cultured Jurkat cells. Our results indicate that the natural isoflavone genistein antagonizes tumor cell growth through both cell-cycle arrest and induction of apoptosis and suggest that it could be a promising new agent in cancer therapy.

GITR: a multifaceted regulator of immunity belonging to the tumor necrosis factor receptor superfamily.

Glucocorticoid‐induced TNFR‐related gene (GITR; TNFRSF18), a receptor belonging to the TNFR superfamily (TNFRSF), is activated by GITRL. GITR is expressed at low levels on resting responder T lymphocytes and is up‐regulated in T regulatory cells (Treg cells) and in activated T cells. GITRL is expressed in endothelial and antigen‐presenting cells. The cytoplasmic region of GITR has a striking homology with other TNFRSF members (4‐1BB, CD27, OX40) and binds TRAF molecules and Siva. Over recent years, the role of GITR in the development and in the pathophysiology of the immune system has been actively explored by several groups. GITR triggering induces both pro‐ and anti‐apoptotic effects, abrogates the suppressive activity of Treg cells and co‐stimulates responder T cells, with the latter activities over‐stimulating the immune system. In vivo, GITR activation causes development of autoimmune diseases and restores immune responses in a persistent retroviral infection model and in a tumor model. Intriguingly, GITR knockout mice demonstrate lower mortality in an ischemia model. The GITR‐GITRL system appears crucial in regulating immunity and warrants further study.