Calcineurin and mitochondrial function in glutamate-induced neuronal cell death.

We have previously reported that glutamate can trigger a succession of necrosis and apoptosis in cerebellar granule cells (CGC). Since specific blockers of the N-methyl-D-aspartate (NMDA) receptor channel prevented both types of cell death, the role of Ca2+-dependent processes in the initiation of glutamate toxicity was further investigated. We examined the possible involvement of mitochondria and the role of the Ca2+/calmodulin-regulated protein phosphatase, calcineurin, in the development of either type of cell death. Cyclosporin A and the more selective calcineurin inhibitor, FK-506, prevented the development of both early necrosis and delayed apoptosis. In addition, cyclosporin A prevented the collapse of mitochondrial membrane potential observed during the exposure to glutamate and the concomitant necrotic phase. When CsA was added immediately after glutamate removal, it also prevented delayed apoptosis of neurons that had survived the necrotic phase. Altogether, these results suggest the involvement of calcineurin and a role for mitochondrial deenergization as early signals in neuronal apoptosis induced by glutamate.

Glutamate-induced neuronal death: a succession of necrosis or apoptosis depending on mitochondrial function.

During ischemic brain injury, glutamate accumulation leads to overstimulation of postsynaptic glutamate receptors with intracellular Ca2+ overload and neuronal cell death. Here we show that glutamate can induce either early necrosis or delayed apoptosis in cultures of cerebellar granule cells. During and shortly after exposure to glutamate, a subpopulation of neurons died by necrosis. In these cells, mitochondrial membrane potential collapsed, nuclei swelled, and intracellular debris were scattered in the incubation medium. Neurons surviving the early necrotic phase recovered mitochondrial potential and energy levels. Later, they underwent apoptosis, as shown by the formation of apoptotic nuclei and by chromatin degradation into high and low molecular weight fragments. These results suggest that mitochondrial function is a critical factor that determines the mode of neuronal death in excitotoxicity.

Different prooxidant levels stimulate growth, trigger apoptosis, or produce necrosis of insulin-secreting RINm5F cells. The role of intracellular polyamines.

Increasing concentrations (1-100 microM) of the redox cycling quinone, 2,3-dimethoxy-1,4-naphthoquinone (DMNQ), stimulated growth, triggered apoptosis, or caused necrosis of pancreatic RINm5F cells, depending on the dose and duration of the exposure. Following the exposure of RINm5F cells to 10 microM DMNQ, ornithine decarboxylase activity and polyamine biosynthesis increased. This was accompanied by enhanced cell proliferation. Conversely, exposure to 30 microM DMNQ for 3 h resulted in the inhibition of ornithine decarboxylase, intracellular polyamine depletion, and apoptotic cell killing. Pretreatment of the cultures with the phorbol ester, 12-O-tetradecanoylphorbol-13-acetate, restored polyamine levels and prevented apoptosis. Exposure to the same DMNQ concentration for only 1 h, with subsequent re-incubation in growth medium, neither caused polyamine depletion nor resulted in apoptosis. Finally, exposure to an even higher DMNQ concentration (100 microM) for either 1 or 3 h caused rapid intracellular Ca2+ overload, ATP, NAD+, and glutathione depletion, and extensive DNA single strand breakage, which resulted in necrotic cell death. Our results show that a disturbance of polyamine biosynthesis occurred prior to cell growth or apoptosis elicited by oxidative stress. In addition, we show that effects as opposite as cell proliferation and deletion, by either apoptosis or necrosis, can be induced, in the same system, by varying the exposure to a prooxidant.

Interleukin-1 beta-induced nitric oxide production activates apoptosis in pancreatic RINm5F cells.

Cytokine production during type I insulin-dependent diabetes mellitus has been linked to alterations in beta-cell function such as inhibition of glucose-stimulated insulin secretion. This and other adverse effects of cytokines, including interleukin-1 beta (IL-1 beta) involve the induction of nitric oxide synthase, with production of nitric oxide. Here, we show that IL-1 beta induces apoptosis in a pancreatic beta-cell line, RINm5F cells. Cells treated with IL-1 beta underwent DNA fragmentation, nuclear condensation, and apoptotic body formation. The production of nitric oxide preceded the appearance of these typical features of apoptosis. Inhibition of the nitric oxide synthase activity by NG-monomethyl-L-arginine prevented IL-1 beta-induced nitric oxide generation and apoptotic cell killing. These results show that--besides the known alterations in beta-cell function--IL-1 beta-induced nitric oxide production activates the cell death program.

Pathobiological effects of acetaldehyde in cultured human epithelial cells and fibroblasts.

The ability of acetaldehyde, a respiratory carcinogen present in tobacco smoke and automotive emissions, to affect cell viability, thiol status and intracellular Ca2+ levels and to cause DNA damage and mutations has been studied using cultured human cells. Within a concentration range of 3-100 mM, a 1 h exposure to acetaldehyde decreases colony survival and inhibits uptake of the vital dye neutral red in bronchial epithelial cells. Acetaldehyde also causes both DNA interstrand cross-links and DNA protein cross-links whereas no DNA single strand breaks are detected. The cellular content of glutathione is also decreased by acetaldehyde, albeit, without concomitant changes in the glutathione redox status or in the content of protein thiols. Transient or sustained increases in cytosolic Ca2+ occur within minutes following exposure of cells to acetaldehyde. Moreover, acetaldehyde significantly decreases the activity of the DNA repair enzyme O6-methylguanine-DNA methyltransferase. Finally, a 5 h exposure to acetaldehyde causes significant levels of 6-thioguanine resistance mutations in an established mutagenesis model involving skin fibroblasts. The results indicate that mM concentrations of acetaldehyde cause a wide range of cytopathic effects associated with multistep carcinogenesis. The fact that acetaldehyde, in relation to its cytotoxicity, causes comparatively higher genotoxicity and inhibits DNA repair more readily than other major aldehydes in tobacco smoke and automotive emissions is discussed.

Modifications of cellular thiols during growth and squamous differentiation of cultured human bronchial epithelial cells.

Thiol modifications during growth and differentiation of cultured normal human bronchial epithelial cells was studied by analysis of their content and redox state of low-molecular-weight thiols and protein thiols. Subculture of the cells with trypsin decreased the cellular content of the major low-molecular-weight thiol, i.e., reduced glutathione, although the glutathione content had returned to levels comparable to those before subculture already after 4 h in conjunction with cell attachment. During subsequent culture, increases in the cellular contents of glutathione, total cysteine equivalents, and total protein thiols occurred. These modifications in the amounts and redox balance of thiols were transient and preceded the major growth phase. Exposure of cells at clonal density to either diethylmaleate, a thiol-depleting agent, or buthionine sulfoximine, an inhibitor of glutathione synthesis, decreased the proliferative ability of the cells as demonstrated by a markedly decreased colony forming efficiency. Moreover, in mass cultures exposed to buthionine sulfoximine, a marked depletion of the glutathione content was again accompanied by inhibition of growth. Exposure of the cells to agents known to induce growth arrest and terminal squamous differentiation, i.e., fetal bovine serum, Ca2+, or transforming growth factor-beta 1, resulted in increased levels of reduced glutathione. No consistent alteration in the contents of the other thiols was noted. Overall, the results demonstrate consistent variations in the amounts and redox state of cellular thiols, particularly reduced glutathione, supporting a role of thiols in regulation of growth and squamous differentiation of human bronchial epithelial cells.

Thiol status and cytopathological effects of acrolein in normal and xeroderma pigmentosum skin fibroblasts.

Thiol redox status was determined in normal human skin fibroblasts and a DNA repair-deficient xeroderma pigmentosum (XP) fibroblast cell line (XP12BE, group A), and cytotoxic and genotoxic effects of the thiol-reactive aldehyde acrolein were studied in these cell types. Normal cells contained higher amounts of the reduced glutathione and cysteine respectively, and higher amounts of these thiols as protein-bound disulfides than the XP cells. However, in both cell types total glutathione was present in 6- to 7-fold higher amounts than total cysteine, and total protein thiols corresponded to approximately 30% of total thiols. A 1 h exposure to acrolein caused a quantitatively similar depletion of reduced glutathione and free protein thiols in both cell types, without causing changes in the thiol redox state. However, acrolein caused higher toxicity measured as trypan blue exclusion, and also a higher extent of DNA single-strand breaks in the XP cells than in the normal cells. Exposure to acrolein, followed by incubation in fresh medium resulted in continued formation of DNA single-strand breaks in the normal cells, whereas no such accumulation occurred in the XP cells. In the normal cells, the DNA single-strand breaks accumulated to a similar extent as in the presence of 1-beta-D-arabinofuranosyl-cytosine and hydroxyurea, i.e. two agents which together efficiently inhibit DNA repair synthesis. The results indicate quantitative and qualitative differences in the thiol redox state between normal and XP cells, and that these differences may contribute to the higher cytotoxicity and genotoxicity of acrolein in XP cells. Moreover, the results indicate that acrolein is a potent inhibitor of DNA excision repair.

Thiol modification and cell signalling in chemical toxicity.

Exposure of cells to thiol oxidizing agents can result in the modification of key proteins involved in cell signalling. Such changes have been shown to affect agonist-stimulated phosphoinositide metabolism, activation of protein kinases and intracellular Ca2+ signals, which result in abnormalities in cell metabolisms and growth. Here, we show that moderate levels of oxidants potentiate growth signals and either enhance cell proliferation or facilitate cell differentiation, whereas inhibition of growth signals by higher oxidant concentrations can block cell proliferation and activate programmed cell death (PCD). Finally, a general alteration of multiple signalling pathways associated with increased catabolic reactions results in cell death by necrosis. Our data suggest that oxidant interaction with cell signalling systems may exert opposite effects, depending on the dose, and that oxidative reactions may either mimic growth factor stimulation and stimulate cell proliferation or inhibit growth signals and activate PCD, in the same cell systems.

Cytotoxic and genotoxic effects of styrene-7,8-oxide in neuroadrenergic Pc 12 cells.

Exposure of Pc 12 cells to styrene-7,8-oxide (SO) (0.5-1 mM) caused a rapid increase in cytosolic Ca2+, depletion of intracellular glutathione and ATP, DNA damage and loss of cell viability. Lower SO concentrations (less than or equal to 100 microM), did not cause loss of cell viability or affect cell growth rate. However, at 30 and 100 microM, SO stimulated the formation of alkali-sensitive, DNA single-strand breaks (SSB). DNA SSB were fully repaired when cells exposed to 30 microM SO were subsequently incubated for 3 h in fresh medium, whereas DNA repair was only partial after exposure to 100 microM SO. When cells exposed to 30 or 100 microM SO were incubated with the inhibitors of repair synthesis 1-beta-D-arabinofuranosyl-cytosine (AraC) and hydroxyurea (HU), SSB accumulated, indicating the involvement of the excision-repair system in the removal of DNA lesions. A SO adduct with guanine at the N7 position was detected in the DNA extracted from treated cells. SO did not induce the formation of double-strand breaks, interstrand cross-links, or DNA-protein cross-links. Although cells exposed to 30 or 100 microM SO underwent normal cell division, latent DNA damage was retained for up to 14 subsequent replicative cycles. In addition, SO-treated cells partially lost their normal ability to differentiate in response to nerve growth factor (NGF) stimulation. NGF failed to induce differentiation in cells that had replicated for 20 generations after exposure to 100 microM SO. Spontaneous differentiation stimulated by high-density culture was also inhibited in SO-treated cells. These results indicate that non-lethal concentrations of SO can cause modifications that compromise the ability of Pc 12 cells to respond to NGF and differentiate.

Calcium ions and oxidative cell injury.

Exposure of mammalian cells to oxidative stress induced by oxidation-reduction-active quinones and other prooxidants results in depletion of intracellular glutathione, followed by modification of protein thiols and loss of cell viability. Protein thiol modification during oxidative stress is normally associated with impairment of various cell functions, including inhibition of agonist-stimulated phosphoinositide metabolism, disruption of intracellular Ca2+ homeostasis, and perturbation of normal cytoskeletal organization. The latter effect appears to be responsible for formation of the numerous plasma membrane blebs typically seen in cells exposed to cytotoxic concentrations of prooxidants. Following disruption of thiol homeostasis in prooxidant-treated cells, there is impairment of Ca2+ transport and subsequent perturbation of intracellular Ca2+ homeostasis, resulting in a sustained increase in cytosolic Ca2+ concentration. This increase in Ca2+ can cause activation of various Ca(2+)-dependent degradative enzymes (e.g., phospholipases, proteases, endonucleases), which may contribute to cell death. In contrast to the cytotoxic effects of excessive oxidative damage, low levels of oxidative stress can lead to activation of enzymes involved in cell signaling. In particular, the activity of protein kinase C is markedly increased by oxidation-reduction-cycling quinones through a thiol/disulfide exchange mechanism, which may represent a mechanism by which prooxidants can modulate cell growth and differentiation.

Growth-associated modifications of low-molecular-weight thiols and protein sulfhydryls in human bronchial fibroblasts.

The thiol redox status of cultured human bronchial fibroblasts has been characterized at various growth conditions using thiol-reactive monobromobimane, with or without the combination of dithiotreitol, a strong reducing agent. This procedure has enabled measurement of the cellular content of reduced glutathione (GSH), total glutathione equivalents, cysteine, total cysteine equivalents, protein sulfhydryls, protein disulfides, and mixed disulfides. Passage of cells with trypsin perturbs the cellular thiol homeostasis and causes a 50% decrease in the GSH content, whereas the total cysteine content is subsequently increased severalfold during cell attachment. During subsequent culture, transient severalfold increased levels of GSH, protein-bound thiols, and protein disulfides are reached, whereas the total cysteine content gradually declines. These changes in the redox balance of both low-molecular-weight thiols and protein-bound thiols correlate with cell proliferation and mostly precede the major growth phase. When the onset of proliferation is inhibited by maintenance of cells in medium containing decreased amounts of serum, the GSH content remains significantly increased. Subsequent stimulation of growth by addition of serum results in decreased GSH levels at the onset of proliferation. In thiol-depleted medium, proliferation is also inhibited, whereas GSH levels are increased to a lesser extent than in complete medium. Exposure to buthionine sulfoximine inhibits growth, prevents GSH synthesis, and results in accumulation of total cysteine, protein-bound cysteine, and protein disulfides. For extracellular cystine, variable rates of cellular uptake correlate with the initial increase in the total cysteine content observed following subculture and with the GSH peak that precedes active proliferation. The results strongly suggest that specific fluctuations in the cellular redox balance of both free low-molecular-weight thiols and protein sulfhydryls are involved in growth regulation of normal human fibroblasts.

Intracellular Ca2+ chelators prevent DNA damage and protect hepatoma 1C1C7 cells from quinone-induced cell killing.

Exposure of hepatoma 1c1c7 cells to 2,3-dimethoxy-1,4-naphthoquinone (DMNQ) resulted in a sustained elevation of cytosolic Ca2+, DNA single strand breaks and cell killing. DNA single strand break formation was prevented when cells were preloaded with either of the intracellular Ca2+ chelators, Quin 2 or BAPTA, to buffer the increase in cytosolic Ca2+ concentration induced by the quinone. DMNQ caused marked NAD+ depletion which was prevented when cells were preincubated with 3-aminobenzamide, an inhibitor of nuclear poly-(ADP-ribose)-synthetase activity, or with either of the two Ca2+ chelators. However, 3-aminobenzamide did not protect the hepatoma cells from loss of viability. Our results indicate that quinone-induced DNA damage, NAD+ depletion and cell killing are mediated by a sustained elevation of cytosolic Ca2+.

Reactivity of fecapentaene-12 toward thiols, DNA, and these constituents in human fibroblasts.

Micromolar concentrations of fecapentaene-12, a mutagen found in human feces, decrease survival measured as colony-forming efficiency and membrane integrity of cultured human fibroblasts. Fecapentaene-12 also decreases the content of cellular free low-molecular-weight thiols including glutathione. Fecapentaene-12 reacts directly with glutathione by causing both decreased levels of free thiol and some concomitant formation of oxidized glutathione, indicating that thiol depletion is a result of both alkylation and oxidative reactions. Exposure of cells to 2 or 5 microM fecapentaene-12 causes significant amounts of DNA-interstrand cross-links and DNA-single strand breaks, respectively, whereas exposure to a higher concentration of fecapentaene-12, i.e., 10 microM, also causes significant DNA-protein cross-links. Results from the reaction of fecapentaene-12 with isolated plasmid DNA parallel the cellular pattern of DNA damage; primarily interstrand cross-links and strand breaks occur also in plasmid DNA. Taken together, these studies show that fecapentaene-12 is a potent cytotoxic and genotoxic agent which can react with cellular thiols and cause several types of DNA damage.

Pathobiological effects of acrolein in cultured human bronchial epithelial cells.

The ability of the highly reactive aldehyde acrolein to affect growth, membrane integrity, differentiation, and thiol status and to cause DNA damage has been studied at serum- and thiol-free conditions using cultured human bronchial epithelial cells. Acrolein markedly decreases colony survival at 3 microM whereas about 10-fold higher concentrations are required to increase membrane permeability, measured as uptake of trypan blue dye. Acrolein at micromolar concentrations also causes epithelial cells to undergo squamous differentiation as indicated by decreased clonal growth rate, dose-dependent increased formation of cross-linked envelopes, and increased cell planar surface area. Acrolein causes a marked and dose-dependent cellular depletion of total and specific free low-molecular-weight thiols as well as protein thiols. Exposure to acrolein did not cause oxidation of glutathione indicating that thiol depletion occurred by direct conjugation of reduced glutathione to acrolein without concomitant generation of active oxygen species. Furthermore, acrolein is genotoxic and causes both DNA single strand breaks and DNA protein cross-links in human bronchial epithelial cells. The results indicate that acrolein causes several cytopathic effects that relate to multistage carcinogenesis in the human bronchial epithelium.

Pathobiological effects of aldehydes in cultured human bronchial cells.

Effects of the tobacco smoke-related aldehydes, i.e., acetaldehyde, formaldehyde and acrolein, have been investigated in cultured human bronchial epithelial cells and fibroblasts. As determined from loss of colony-forming efficiency of epithelial cells, acrolein is 200- and 5000-fold more toxic than formaldehyde and acetaldehyde, respectively. The aldehydes differ markedly in their potencies to induce terminal differentiation, as indicated by cessation of growth and enhanced formation of cross-linked envelopes. The cellular content of glutathione is markedly decreased by acrolein, whereas formaldehyde and acetaldehyde only slightly decrease glutathione levels. All three aldehydes produce DNA damage, as indicated by the formation of DNA single-strand breaks and DNA protein cross-links. Both formaldehyde and acrolein are weakly mutagenic in fibroblasts. In-vitro assays of O6-methylguanine-DNA methyltransferase (MMT) activity indicate that it is markedly inhibited by acrolein, and to a lesser extent by formaldehyde. However, formaldehyde significantly inhibits removal of O6-methylguanine (O6-meG) in N-methyl-N-nitrosourea (MNU)-exposed cells. Thus, the many biological effects induced by aldehydes include: inhibition of proliferation, enhanced cellular differentiation, thiol depletion, DNA damage, mutation and inhibition of DNA repair in human cells. Furthermore, we speculate that exogenous or metabolically generated aldehydes may increase the genotoxicity of N-nitroso compounds by the dual action of causing DNA damage and inhibiting the repair of promutagenic O6-meG DNA lesions in human cells.