Apoptosis

Apoptosis and inflammation

During the last few decades it has been recognized that cell death is not the consequence of accidental injury, but is the expression of a cell suicide programme. Kerr et al. (1972) introduced the term apoptosis. This form of cell death is under the influence of hormones, growth factors and cytokines, which depending upon the receptors present on the target cells, may activate a genetically controlled cell elimination process. During apoptosis the cell membrane remains intact and the cell breaks into apoptotic bodies, which are phagocytosed. Apoptosis, in contrast to necrosis, is not harmful to the host and does not induce any inflammatory reaction. The principal event that leads to inflammatory disease is cell damage, induced by chemical/physical injury, anoxia or starvation. Cell damage means leakage of cell contents into the adjacent tissues, resulting in the capillary transmigration of granulocytes to the injured tissue. The accumulation of neutrophils and release of enzymes and oxygen radicals enhances the inflammatory reaction. Until now there has been little research into the factors controlling the accumulation and the tissue load of granulocytes and their histotoxic products in inflammatory processes. Neutrophil apoptosis may represent an important event in the control of intlamtnation. It has been assumed that granulocytes disintegrate to apoptotic bodies before their fragments are removed by local macrophages. Removal of neutrophils from the inflammatory site without release of granule contents is of paramount importance for cessation of inflammation. In conclusion, apoptotic cell death plays an important role in inflammatory processes and in the resolution of inflammatory reactions. The facts known at present should stimulate further research into the role of neutrophil, eosinophil and macrophage apoptosis in inflammatory diseases.

Cellular functions of tissue transglutaminase

Transglutaminase 2 (TG2 or tissue transglutaminase) is a highly complex multifunctional protein that acts as transglutaminase, GTPase/ATPase, protein disulfide isomerase, and protein kinase. Moreover, TG2 has many well-documented nonenzymatic functions that are based on its noncovalent interactions with multiple cellular proteins. A vast array of biochemical activities of TG2 accounts for its involvement in a variety of cellular processes, including adhesion, migration, growth, survival, apoptosis, differentiation, and extracellular matrix organization. In turn, the impact of TG2 on these processes implicates this protein in various physiological responses and pathological states, contributing to wound healing, inflammation, autoimmunity, neurodegeneration, vascular remodeling, tumor growth and metastasis, and tissue fibrosis. TG2 is ubiquitously expressed and is particularly abundant in endothelial cells, fibroblasts, osteoblasts, monocytes/macrophages, and smooth muscle cells. The protein is localized in multiple cellular compartments, including the nucleus, cytosol, mitochondria, endolysosomes, plasma membrane, and cell surface and extracellular matrix, where Ca(2+), nucleotides, nitric oxide, reactive oxygen species, membrane lipids, and distinct protein-protein interactions in the local microenvironment jointly regulate its activities. In this review, we discuss the complex biochemical activities and molecular interactions of TG2 in the context of diverse subcellular compartments and evaluate its wide ranging and cell type-specific biological functions and their regulation.

Role of apoptosis in the kidney after reperfusion

A szervtranszplantáció klinikai megvalósulása a 20. század orvostudományának egyik legfontosabb vívmánya. Az ischaemiareperfúzió befolyást gyakorol a transzplantált szerv azonnali és hosszú távú működésére. A szervtranszplantáció az ischaemiareperfúzió klinikai modelljének tekinthető. Célkitűzés: Az ischaemiareperfúzió során létrejött károsodások megelőzési lehetőségeinek vizsgálata, melyben az apoptosis kulcsfontosságú szerepet játszik. Módszerek: Humán vesetranszplantációban vizsgálták az apoptosist. Állatkísérletben átmeneti ischaemiát követően elemezték az apoptosis kialakulását, és megkísérelték kalciumantagonisták: verapamil, nifedipin, bepridil, fendilin, valamint a B-típusú monoamino-oxidáz irreverzíbilis szelektív inhibitor (–)-deprenyl (MAO-B) adásával megelőzni kialakulását. Eredmények: Transzplantált humán vesében mind apoptoticus, mind necroticus sejtek előfordulnak, regenerációs sejtproliferációs jelekkel kísérve. Patkányvesében a kalciumantagonisták csökkentették az apoptosis előfordulását. A (–)-deprenylnek preventív hatása volt a renalis tubularis sejtek ischaemiareperfúziót követő apoptosisának kialakulásában. Következtetések: A tubulussejtek funkcionális kapacitása szignifikánsan hozzájárul az adekvát veseműködéshez. A tubularis sejtek apoptosisának csökkentése feltehetően javíthatná a transzplantált vese funkcióját.

Dexamethasone-induced apoptosis in immune cells from peripheral circulation and lymphomyeloid tissues of juvenile clearnose skates, Raja eglanteria

Juvenile clearnose skates (Raja eglanteria) were injected intramuscularly with dexamethasone-21-phosphate at 50, 75, and 100mg/kg body weight. After 24h, skates were sacrificed and lymphomyeloid tissues (thymus, spleen, Leydig organ, and epigonal organ) were removed and whole blood was sampled. Tissues were used fresh for imprints or prepared for histology by solvent fixation or freezing in liquid nitrogen. Apoptosis in fixed tissues was assessed by transmission electron microscopy. Frozen sections and cytospin preparations of peripheral blood leukocytes (PBL) were evaluated by the TUNEL reaction to detect DNA strand breaks. Dexamethasone treatment increased apoptotic activity in all lymphomyeloid tissues as well as in PBL. These studies demonstrate that immune cells of elasmobranchs have the capacity for glucocorticoid-driven apoptosis, and that programmed cell death as a mechanism to regulate immune cell production appears to have been conserved during vertebrate evolution.

Antigen receptor signalling in apoptosis-resistant mutants of WEHI 231 cells

Ligation of membrane immunoglobulin M (mIgM) induces cell cycle arrest and apoptosis in the WEHI 231 B-lymphoma cell line. The molecular mechanisms which link receptor ligation and the nuclear events that underlie this response, have yet to be fully elucidated. Here we have examined the signals induced following mIgM cross-linking in variants of WEHI 231 that no longer undergo apoptosis in response to this stimulus. Tyrosine phosphorylation of cellular substrates in two of the variants is identical to that seen in wild-type cells but in one of the mutants, VS2.12, a restricted set of substrates becomes tyrosine phosphorylated. In a second variant (E8), mIgM cross-linking does not induce elevation of intracellular Ca2+, although tyrosine phosphorylation of PLCgamma2 is induced to an equivalent extent to that seen in WEHI 231 cells. A third variant, 2E10.F9, is resistant to apoptosis despite the fact that all signals analysed appear to be similar to those induced in wild-type cells. Our findings show that resistance to apoptosis can arise as a result of mutations affecting discrete stages of the mIgM signalling pathway. The mutant lines reported here show defects that have not yet been identified in previous studies and are likely to be useful tools in dissecting the signalling of cell death in B lymphocytes.

Cutaneous CD30+ lymphoproliferative disorders: expression of bcl-2 and proteins of the tumor necrosis factor receptor superfamily

The spectrum of CD30+ cutaneous lymphoproliferative disorders is characterized by the histology of a high-grade lymphoma but frequent clinical regression of skin lesions in lymphomatoid papulosis (LyP) and occasional regression in CD30+ large cell lymphomas (LCLs). A recent study shows that apoptosis may be a significant mechanism of regression of LyP (Arch Dermatol 133:828-833, 1997). Therefore, we studied expression of proteins that induce apoptosis, including CD27, CD40, CD95, and nerve growth factor receptor (NGF-R), as well as anti-apoptotic protein bcl-2 in skin lesions from 25 patients within the spectrum of CD30+ cutaneous lymphoma. Our results show consistent expression of CD95 (APO-1/Fas), but rare or absent expression of CD27, CD40, and NGF-R on tumor cells from both regressing LyP lesions and nonregressing CD30+ lymphomas. Bcl-2 was expressed at low levels in LyP and at high levels in pleomorphic CD30+ lymphomas. These results indicate that, in addition to CD30, CD95 expression is preferentially expressed at high levels in all cutaneous CD30+ lymphomas and suggest that CD95 may play a role in the regression of CD30+ skin lesions. Expression of bcl-2 appears to protect tumor cells from apoptosis in CD30+ lymphoproliferative disorders.

Apoptosis: programmed cell death in fetal development

Controlled death of cells is as much a part of embryonal development as is cell proliferation and differentiation. This cell suicide is controlled by cell genes involved in induction or prevention of programmed cell death (PCD). During embryogenesis PCD implicates cell elimination, necessary in fashioning of the body, moulding of tissues. PCD is often used synonymous with the designation apoptosis, which indicates an endogenous cell suicide program by which useless or crippled cells are eliminated. Apoptosis occurs in normal tissue turnover, in organ involution after withdrawal of trophic hormones, in distinct cells after deprivation of growth factors or specific stimuli and in cells which have undergone sublethal damage. During PCD the nucleus breaks up into DNA fragments of 180-200 kD and the endoplasmic reticulum transforms into vesicles, which are released as apoptotic bodies into the extracellular space. The apoptotic bodies, containing cell organelles and nuclear fragments, are phagocytosed by neighboring cells. Electron micrographs of embryos have revealed the presence of numerous cells with the characteristic features of apoptosis. Experiments, in which small tissue fragments were explanted to other regions, have proven that focal apoptosis is under control of genetic, hormonal and local tissue factors. Morphological analysis has shown that most of the ovarian follicles undergo during development apoptosis, resulting in follicle atresia. Only a small proportion escapes PCD. Growth factors and estrogens have been identified as follicle survival factors, androgens and gonadotropin releasing hormones are potentiating apoptosis of the follicle. An exaggerated PCD or a defective apoptosis during embryogenesis may cause developmental abnormalities. Certain viruses can inhibit apoptosis, while metabolic stress or damage of cell structures can induce apoptosis. Therefore not only viral infections, also drugs and chemical or physical injuries during embryogenesis may interfere with the balanced PCD and thus induce malformations. Drugs and therapy designs directed to modulate the apoptotic process will offer new approaches to the prevention of congenital malformations.

Apoptosis overview emphasizing the role of oxidative stress, DNA damage and signal-transduction pathways

Apoptosis (programmed cell death) is a central protective response to excess oxidative damage (especially DNA damage), and is also essential to embryogenesis, morphogenesis and normal immune function. An understanding of the cellular events leading to apoptosis is important for the design of new chemotherapeutic agents directed against the types of leukemias and lymphomas that are resistant to currently used chemotherapeutic protocols. We present here a review of the characteristic features of apoptosis, the cell types and situations in which it occurs, the types of oxidative stress that induce apoptosis, the signal-transduction pathways that either induce or prevent apoptosis, the biologic significance of apoptosis, the role of apoptosis in cancer, and an evaluation of the methodologies used to identify apoptotic cells. Two accompanying articles, demonstrating classic apoptosis and non-classic apoptosis in the same Epstein-Barr virus-transformed lymphoid cell line, are used to illustrate the value of employing multiple criteria to determine the type of cell death occurring in a given experimental system. Aspects of apoptosis and programmed cell death that are not covered in this review include histochemistry, details of cell deletion processes in the sculpting of tissues and organs in embryogenesis and morphogenesis, and the specific pathways leading to apoptosis in specific cell types. The readers should refer to the excellent books and reviews on the morphology, biochemistry and molecular biology of apoptosis already published on these topics. Emphasis is placed, in this review, on a proposed common pathway of apoptosis that may be relevant to all cell types.

Chondrocyte apoptosis in endochondral ossification of chick sterna

In the process of endochondral ossification, chondrocytes progress through a series of maturational changes, including division and hypertrophy, that culminate in chondrocyte loss and cartilage resorption. From an investigation of morphology, DNA fragmentation and collagen synthesis in the developing chick sterna we have characterized chondrocytes death in this process. Light microscopy of resorbing sterna demonstrated chondrocyte condensation at the interface with the invading vasculature and electron microscopy demonstrated a range of chondrocyte morphologies, including retraction from the pericellular matrix, cytoplasmic and nuclear condensation, and vesiculation suggestive of sequential changes characteristic of apoptosis. Isolation and end-labeling of DNA from chick primary ossification centers demonstrated fragmentation to nucleosome sized units, only in primary ossification centers exhibiting active resorption, and in situ detection of DNA fragmentation showed a restriction to chondrocytes at the interface with invading blood. We conclude that terminal differentiation of chondrocytes results in death by an apoptotic process prior to resorption of the tissue and invasion by blood vessels. The extent of DNA fragmentation correlated closely with the proportion of cells displaying a condensed phenotype in contralateral primary ossification centers and peaked at an early stage of resorption, suggesting that chondrocyte apoptosis may be an initiating event in tissue resorption and vascular invasion. Comparison of DNA fragmentation with expression of the hypertrophic chondrocyte phenotype, as indicated by type X collagen synthesis, suggested that DNA fragmentation was a late event in the process of chondrocyte hypertrophy and probably corresponded with chondrocyte condensation

Role of apoptosis in biology and pathology: resistance to apoptosis in colon carcinogenesis

The overview of apoptosis presented here emphasizes cell deletion in the immune system, with particular reference to T- and B-lymphocyte development, and the in vivo and in vitro senescence of human neutrophils. Some biochemical criteria that are used to identify apoptotic cells are described. Pitfalls in using agarose gel electrophoresis as the sole method for the identification of apoptotic cells are discussed. There are multiple modes of cell death that can be identified at the morphologic level. Thus the central role of microscopic methods, and in particular, electron microscopy, as an important tool in the study of cell death mechanisms, is presented. Apoptosis has a protective role against disease and could, a priori, have an important role in either the initiation or progression of cancer. Two paradoxes concerning the relationship of tumor aggressiveness at the clinical level to mitotic activity have been explained by an evaluation of apoptotic index. In the first case, basal cell carcinomas grow slowly but show a high rate of mitosis. Here, the apoptotic rate is quite high, but just below the mitotic rate, thereby accounting for the slow rate of growth. A second instance is follicular lymphoma, which has a low rate of mitosis that is less than that described for reactive germinal centers. However, apoptosis is markedly reduced in follicular lymphomas compared with that seen in reactive germinal centers, thus providing an explanation for the progressive growth of the follicle. We present a brief description of recent work from our laboratory that indicates that apoptosis may play an important role in colon carcinogenesis. We have shown that sodium deoxycholate, the particular bile salt present in highest concentration in the colon, induces apoptosis in the goblet cells of the human colonic mucosa in an in vitro assay. The intriguing finding is that cells of the normal-appearing mucosa of colon cancer patients are resistant to bile salt-induced apoptosis. This suggests a novel hypothesis about the etiologic role of bile salts in colon cancer. The chronic presence of bile salts that accompany a high-fat diet could select for apoptosis-resistant epithelial cells in the colon over time. Thus, a resistance-to-apoptosis bioassay may prove useful as an intermediate biomarker for determining which individuals are at high risk for colon cancer.

Isolation and characterization of the human tissue transglutaminase gene promoter

Tissue transglutaminase belongs to a family of calcium-dependent enzymes, the transglutaminases that catalyze the covalent cross-linking of specific proteins by the formation of epsilon (gamma-glutamyl)lysine isopeptide bonds. The goal of this study has been the isolation and characterization of the human tissue transglutaminase gene promoter. Genomic DNA clones, spanning the 5' region of the gene, were isolated and the structure of the 5'-end of the human tissue transglutaminase gene was determined. 1.74 kilobases of flanking DNA were sequenced and were found to contain a TATA box element (TATAA), a CAAT box element (GGACAAT), a series of potential transcription factor-binding sites (AP1, SP1, interleukin-6 response element), and a glucocorticoid response elements. Transient transfection experiments showed that this DNA fragment included a functional promoter, which is constitutively active in multiple cell types.

Spatial distribution of mitosis, apoptosis and small blood vessels in malignant diffuse follicular-center-cell lymphomas: a nearest-neighbor analysis

To better comprehend the relationships between cell birth and cell death in neoplastic disorders, the topography of these events needs to be considered. We applied a computerized nearest-neighbor analysis to malignant, diffuse follicular-center-cell lymphomas in order to examine the spatial distribution of pyknotic (apoptotic) cells/bodies (A) and mitotic figures (M) in relation to capillaries (C) and venules (V). The results revealed a complex dispersion pattern, with significant aggregations of A and M, in addition to an even greater random distribution component. The greatest clustering displayed by A was around capillaries (A-C, 42% reduction of object frequency between the first and second distance class), followed by A-A (33%), A-V (24%) and A-M (12%). Additional values for mitotic figures were: M-M (45%), M-V (33%) and M-C (22%). These findings may reflect the relative importance of inherent properties of the neoplastic and host factors, respectively, in the regulation of cell birth and cell death rates.

Apoptosis in human skin development: morphogenesis, periderm, and stem cells

During human skin development, embryonic- and fetal-specific periderm cells and incompletely keratinized cells are replaced by keratinocytes that differentiate while stratifying to form the fully functional epidermis. Proliferating basal cells of fetal skin also develop into epidermal appendages such as hair follicles and glands. We demonstrate that programmed cell death, not emphasized in conventional epidermal biology, has an important function in establishing the final architecture of the human epidermis and its appendages. Immunohistochemical localization of transglutaminases in fetal periderm, intermediate epidermal cells, and within appendages coincides with DNA fragmentation indicating that apoptosis is involved in deletion of these stage-specific cells and remodeling of appendages. The data also suggest that terminal differentiation of epidermal cells might be a specialized form of apoptosis. The pattern of expression of bcl-2, a gene associated with survival of some cells, is exclusive of the distribution patterns of markers of the cell death pathway. Bcl-2 protein is correlated with specific morphogenetic events in hair follicles and eccrine sweat glands, and its presence in single cells of the hair follicle bulge suggests that Bcl-2 may be a stem cell marker.

DNA fragmentation during apoptosis is caused by frequent single-strand cuts

One of the hallmarks of apoptosis is the digestion of genomic DNA by an endonuclease, generating a ladder of small fragments of double-stranded DNA. We have examined the nature of the DNA breaks produced in mouse thymocytes triggered to undergo apoptosis by steroids or by stimulation of the T cell receptor. Whereas the typical ladder pattern of oligonucleosomal fragments was observed after agarose gel electrophoresis, numerous single-strand cuts were detected after electrophoresis under denaturing conditions. Single-strand nicks were found to be very frequent in the internucleosomal regions, but also to occur in the core particle-associated DNA. An identical pattern of single-strand nicks was obtained when chromatin DNA was exposed to the single-strand cleaving deoxyribonuclease I. The nicked DNA fragments, extracted from apoptotic thymocytes, were sensitive to the action of S1-nuclease. We propose that DNA fragmentation induced during apoptosis is not due to a double-strand cutting enzyme as previously postulated, but rather is the result of single-strand breaks. This ensures the dissociation of the DNA molecule at sites where cuts are found within close proximity.

Cell death by apoptosis in epidermal biology

Homeostasis in continually renewing tissues is maintained by a tightly regulated balance between cell proliferation, cell differentiation, and cell death. Until recently, proliferation was thought to be the primary point of control in the regulation of normal tissue kinetic homeostasis and as such has been the major focus of both understanding the etiology of disease and developing therapeutic strategies. Now, physiologic cell death, known as apoptosis (ă-pŏp-to' sĭs, ă-po-to' sĭs [Thomas CL (ed.): Taber's Cyclopedic Medical Dictionary. F.A. Davis, Co., Philadelphia, 1989)] has gained scientific recognition as an active regulatory mechanism, complementary, but functionally opposite, to proliferation with important roles in shaping and maintaining tissue size and prevention of disease. In this review we will describe the concept of apoptosis and discuss possible molecular mechanisms of its regulation that may have implications for skin biology.

Prostaglandin-induced apoptosis of ovarian surface epithelial cells

In a previous study we observed that expression of mRNA encoding prostaglandin endoperoxide synthase is elevated within ovarian epithelial cells that cover the surface of preovulatory ovine follicles. We report herein that during the process of ovulation these cells undergo degenerative morphological changes typical of apoptosis and are sloughed from the follicular apex. This response was circumvented by blockade of ovulation by indomethacin. The effect of indomethacin was reversed by prostaglandin E2 or F2 alpha. Prostaglandin-induced DNA fragmentation (a hallmark of apoptosis) was verified in primary cultures of sheep ovarian surface epithelial cells. Prostaglandins did not cause apoptosis in a human ovarian cancer cell line of epithelial origin.

Patterns of cell death: the significance of apoptosis for dermatology

Development, function, remodelling, and senescence of multicellular organisms depend on the coordinated occurrence of physiological, actively induced cell death in two major patterns: terminal differentiation and programmed cell death (apoptosis). Apoptosis is a highly selective form of "cell suicide" with characteristic morphological and biochemical features: chromatin condensation, formation of apoptotic bodies, and DNA fragmentation by activation of endonucleases. Here, we outline the current understanding of apoptosis and its subtypes, discuss their biological functions, and delineate why apoptosis is relevant to the skin and its diseases. We distinguish apoptosis from necrosis, and discuss the regulation of apoptosis by selected genes, hormones, growth factors and cytokines. The epidermis and the regressing hair follicle offer interesting models for studying the as yet ill-understood biology of epithelial cell apoptosis. The selective manipulation of cell death programs may become part of the therapeutic arsenal of clinical dermatology.