Showing papers on "Apoptosis published in 1988"

Tumor necrosis factor can induce both apoptic and necrotic forms of cell lysis.

Abstract: TNF is a protein toxin which is secreted by activated macrophages and monocytes. Although the cytotoxic activity of TNF has been well documented, the mechanism of TNF-induced lysis is not well understood. The goal of this investigation was to determine whether TNF caused one of the classic forms of cell death, i.e., apoptosis, which is characterized by nuclear disintegration and cytoplasmic "boiling," or necrosis, which is characterized by the formation of a "balloon-like" plasma membrane and a lack of nuclear disintegration. Therefore, to distinguish apoptosis from necrosis, we have used time-lapse video microscopy to observe the death of several TNF-sensitive target cell lines while measuring the release of Na2(51)CrO4 and [3H]TdR from cytoplasmic and nuclear compartments, respectively. As targets we selected two spontaneously sensitive cell lines, F17 and L-M, and one resistant cell line, C3HA, which was sensitized by treatment with cycloheximide or by infection with the adeno-SV40 hybrid virus Ad2+ND2. We find that the type of cell death observed depends on the cell being tested. For example, in F17 cells we found that TNF treatment induced a classical form of apoptosis. In contrast, TNF induced a necrotic form of cell death in L-M cells, similar to the lysis induced by antibody and C. Finally, we found that sensitized C3HA cells displayed a novel cytolytic phenotype which resembled apoptosis but did not include DNA fragmentation. These results emphasize the complex nature of the TNF-induced cytotoxic response.

Activation of programmed cell death in the rat ventral prostate after castration.

Abstract: The rapid involution of the rat ventral prostate after castration is an active process initiated by removal of the inhibitory effects of androgen on prostatic cell death. The present studies demonstrate that after castration-induced androgen deprivation a series of temporally discrete biochemical events are activated which result in the rapid programmed death of the subset of androgen-dependent cells within the rat ventral prostate. These biochemical steps involve 1) rapid loss of nuclear androgen receptor retention; by 12 h after castration, androgen receptors are no longer detectable in ventral prostatic nuclei; 2) an initial fragmentation of nuclear DNA into low mol wt (less than 1000 basepairs) nucleosomal oligomers which lack intranucleosomal break points; and 3) eventual complete digestion of these nucleosomal oligomers into component nucleotides. Additional studies demonstrate that activation of a Ca2+-Mg2+-dependent endonuclease is associated with this DNA fragmentation. By 4 days after castration, maximal DNA fragmentation is obtained, with 15% of the total nuclear DNA extractable as low mol wt fragments. Proteolytic enzymes are apparently not involved initially in this process, suggesting that DNA fragmentation is a discrete event in, rather than a result of, cell death. Flow cytometric analysis of nuclear DNA content demonstrated that each day after castration, a subpopulation of androgen-dependent cells in rat ventral prostate fragmented all of their genomic DNA, as opposed to the whole population of cells fragmenting an increasing portion of their DNA daily.

Patterns of cell death.

Abstract: Cell death takes two distinct forms, necrosis and apoptosis. Necrosis is a degenerative phenomenon that follows irreversible injury. Apoptosis, in contrast, appears to be an active process requiring protein synthesis for its execution; it is implicated in physiological regulation of tissue size, and, where it occurs pathologically, a homeostatic role for the death is often evident. Morphologically, apoptosis involves condensation of the nuclear chromatin and cytoplasm, fragmentation of the nucleus, and budding of the whole cell to produce membrane-bounded bodies in which organelles are initially intact. These bodies are disposed of by adjacent cells without inflammation. Biochemically, there is distinctive internucleosome cleavage of DNA in apoptosis, which is quite different from the random DNA degradation observed in necrosis.

Activation of a Ca2+-Mg2+-dependent endonuclease as an early event in castration-induced prostatic cell death.

Abstract: Previous studies have demonstrated that castration-induced androgen withdrawal results in the fragmentation of prostatic DNA into nucleosomal oligomers, and this process comprises an early event in the activation of programed cell death in the rat ventral prostate. This DNA fragmentation could be due to changes in the chromatin conformation increasing its sensitivity to preexisting nucleases and/or to increases in the activity of the nucleases themselves. However, comparative kinetic analysis of in vitro DNA fragmentation induced by exogenous nucleases did not reveal any differences in the sensitivity of prostatic chromatin between intact and castrated rats. In contrast to these negative findings, using [3H] DNA as an exogenous substrate, it was shown that within the first day following castration there was a twofold increase in a Ca2+-Mg2+-dependent nuclease activity without a concomitant increase in other nuclear nucleases. This Ca2+-Mg2+-dependent nuclease activation occurred coincidental with the initial increase in nuclear DNA fragmentation following castration and preceded the enhanced appearance of morphological changes characteristic of dying cells (i.e., apoptosis), as well as the major increase in prostatic DNA loss. These results suggest that castration-induced androgen deprivation leads to a sequential activation of a Ca2+-Mg2+-dependent nuclease leading to the fragmentation of the genome into discrete nucleosomal-sized fragments of DNA, subsequently followed by the fragmentation of the nucleus itself (i.e., apoptosis) and eventually with the complete digestion of the nucleosomal oligomers into component nucleotides (i.e., DNA loss). Since the castration-induced nuclease is dependent upon calcium ions for maximal activity, a potential role of intracellular calcium in the early events activating prostatic cell death was investigated. Acute disturbances in intracellular calcium homeostasis within the ventral prostate by means of a potent calcium influx blocker, nifedipine, simultaneous with castration, resulted in a significant delay in the biochemical and morphological changes associated with prostatic cell death (i.e., prostatic weight loss, prostatic DNA loss, and DNA fragmentation). These results point to a potential role of intracellular calcium levels in the mechanism of activation of castration-induced death of the androgen-dependent epithelial cells in the ventral prostate.

Searching For the Function of Tissue Transglutaminase: Its Possible Involvement in the Biochemical Pathway of Programmed Cell Death

Abstract: Although several details are still missing, the biological role of two of the three well characterized transglutaminases in mammals, namely blood coagulation factor XIII and keratinocyte transglutaminase, is established. The function of the third one called the tissue type is still an enigma. Its constant localization in endothelial and smooth muscle cells of all organs, in heart muscle, in medullary interstitial and mesangial cells of kidney, and its induction in a number of other cell types under a variety of conditions suggest multiple functions. According to our results its participation in the biochemical pathway leading to programmed cell death (apoptosis), a basic cellular phenomenon of physiological significance, may be one of these functions.

Circadian Rhythms in the Incidence of Apoptotic Cells and Number of Clonogenic Cells in Intestinal Crypts after Radiation Using Normal and Reversed Light Conditions

Abstract: SummaryVariations in the number of radiation-induced morphologically dead or dying cells (apoptotic cells) in the crypts in the small intestine of the mouse have been studied throughout a 24-h period under a normal light regimen (light on, 07.00–19.00 h; light off, 19.00–07.00 h). A clear circadian rhythm was displayed in the apoptotic incidence 3 or 6 h after irradiation for each gamma-ray dose studied (range 0·14–9·0 Gy). The most prominent circadian rhythm was obtained after 0·5 Gy. The peak time of day for inducing apoptosis was 06.00–09.00 h, and the trough occurred at 18.00–21.00 h.Some mice were also transferred to a room with the light cycle reversed, and were irradiated on different days after the transfer. The apoptosis induced by 0·5 Gy or 9·0 Gy, or the number of surviving crypts (microcolonies) after 11·0 Gy or 13·0 Gy was examined. The transition point for reversal (i.e. the switch time from the normal-light pattern to the reversed-light pattern) of the circadian rhythm in apoptosis (after 0...

X-ray-induced cell death by apoptosis in the immature rat cerebellum.

Abstract: The cells of the external granular layer (EGL) of the developing cerebellum are known to be particularly sensitive to radiation. In the past, changes induced in this layer by irradiation have been referred to by non-specific terms such as "pyknotic cells" and the mode of cell death has been assumed to be necrosis. However, in published light micrographs of these dying cells, the appearance is suggestive of apoptosis, a distinctive mode of cell death which occurs spontaneously in normal adult and embryonic tissues and can also be triggered by certain pathological stimuli. This light and transmission electron microscopic study of control and irradiated (7 h post-irradiation) rat cerebellum from 18 day fetuses and 5 day-old neonates showed that the cell death was effected by apoptosis. The apoptosis was markedly enhanced by x-irradiation and quantification of the cell death in the EGL of 5 day-old rats exposed to 4, 8, 25, 100, and 400 cGy x-irradiation demonstrated that there was a positive dose response relationship. The extent of cell death by apoptosis which was 0.2% in control, ranged from 0.8% after 4 cGy to 62.3% after 400 cGy x-irradiation. The recognition that cell death by apoptosis can be a major component of x-irradiation damage has important implications for radiobiological studies.

Cell death by apoptosis following X-irradiation of the foetal and neonatal rat kidney.

Abstract: A light and electron microscopic study was undertaken to determine the type of cell death induced by X-irradiation in the developing kidney. Five-day-old Sprague-Dawley rats were exposed to a whole-body dose of either 2 or 5 Gy, and foetuses in the eighteenth day of development were exposed to a dose of 4 Gy. The kidneys were examined at 4, 8 and 24 h, and at 1 and 2 weeks post-irradiation. The dying cells from both control and treated kidneys showed the morphological features of apoptosis, a distinct form of cell death that has been identified in mammalian tissues under physiological as well as pathological conditions. Necrosis was not detected. Apoptosis was infrequent in control kidneys and insignificant in extent when compared with the proliferative activity of the cells of the superficial nephrons. There was a pronounced increase in apoptosis during the first day after irradiation. The findings are in agreement with recent ultrastructural studies which report the presence of apoptosis following irradiation of rapidly proliferating adult cell populations, and irradiation of other immature mammalian tissues. There is evidence that apoptosis involves active cellular self-destruction, and it has been suggested that activation of apoptosis might bring about selective elimination of cells with critical DNA damage in irradiated tissues, thus minimizing propagation of genetic abnormalities.

Sertoli cell death by apoptosis in the immature rat testis following x-irradiation.

Abstract: The importance of the morphological study of cell death has recently been emphasized by the recognition that the ultrastructural features of dying cells allow categorization of the death as either apoptosis or necrosis. This classification enables inferences to be drawn about the mechanism and biological significance of the death occurring in a particular set of circumstances. In this study, Sertoli cell death induced in the immature testis of three and four day old rats by 5 Gy (500 rads) x-irradiation was described by light and transmission electron microscopy with the objective of categorizing the death as apoptosis or necrosis. The testes were examined 1, 2, 3, 4, 8, and 24 h after irradiation. Following irradiation, there was a wave of apoptosis of the Sertoli cells starting in three to four hours and reaching a peak between four and eight hours. At 24 hours, only 61% of the expected number of Sertoli cells remained. These findings are in accord with recent ultrastructural reports that ionizing radiation induces cell death by apoptosis in rapidly proliferating cell populations. New insights into the pathogenesis of radiation-induced cell death might thus be expected to stem from future elucidation of the general molecular events involved in triggering apoptosis.

Cell Death by Apoptosis in Normal, Preneoplastic and Neoplastic Tissue

Abstract: Cells of hiher organisms can die through different causes and under different circumstances which can be classified broadly into at least 3 different categories: 1. Massive tissue injury such as after hypoxia or after CCl4 in the liver. Some authors restrict use of the term necrosis to cell death occurring after massive tissue damage1,2. 2. Terminal differentiation of tissues such as skin, intestine or blood cells. 3. Regression of organs, elimination of excessive cells, cell turnover in healthy tissues. During development certain organs regress such as the Mullerian duct in the male embryo. In the adult organism atrophy or removal of hyperplasia may occur in hormone-dependent organs. The type of cell death involved has recently been designated “apoptosis”1,3–8. It is conceived as a genetically encoded cellular suicide program that can be activated in situations where cell elimination appears physiologically advantageous or even necessary. Examples of physiological states in which apoptosis is believed to occur are given in Table 1. It appears that apoptosis is a widespread phenomenon which has been observed in a variety of species throughout the animal kingdom and in various organs during developmental stages and adulthood.