Francesca Mirabelli

Formation and reduction of glutathione-protein mixed disulfides during oxidative stress: A study with isolated hepatocytes and menadione (2-methyl-1,4-naphthoquinone)

Incubation of isolated rat hepatocytes with menadione (2-methyl-1,4-naphthoquinone) resulted in a dose-dependent depletion of intracellular reduced glutathione (GSH), most of which was oxidized to glutathione disulfide (GSSG). Menadione metabolism was also associated with a dose- and time-dependent inhibition of glutathione reductase, impairing the regeneration of GSH from GSSG produced during menadione-induced oxidative stress. Inhibition of glutathione reductase by pretreatment of hepatocytes with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) greatly potentiated both GSH depletion and GSSG formation during the metabolism of low concentrations of menadione. Concomitant with GSH oxidation, mixed disulfides between glutathione and protein thiols were formed. The amount of mixed disulfides produced and the kinetics of their formation were dependent on both the intracellular GSH/GSSG ratio and the activity of glutathione reductase. The mixed disulfides were mainly recovered in the cytosolic fraction and, to a lesser extent, in the microsomal and mitochondrial fractions. The removal of glutathione from protein mixed disulfides formed in hepatocytes exposed to oxidative stress was dependent on GSH and/or cysteine and appeared to occur predominantly via a thiol-disulfide exchange mechanism. However, incubation of the microsomal fraction from menadione-treated hepatocytes with purified glutathione reductase in the presence of NADPH also resulted in the reduction of a significant portion of the glutathione-protein mixed disulfides present in this fraction. Our results suggest that the formation of glutathione-protein mixed disulfides occurs as a result of increased GSSG formation and inhibition of glutathione reductase activity during menadione metabolism in hepatocytes.

Menadione-induced bleb formation in hepatocytes is associated with the oxidation of thiol groups in actin

Incubation of isolated rat hepatocytes with menadione (2-methyl-1,4-naphthoquinone) or the thiol oxidant, diamide (azodicarboxylic acid bis(dimethylamide)), resulted in the appearance of numerous plasma membrane protrusions (blebs) preceding cell death. Analysis of the Triton X-100-insoluble fraction (cytoskeleton) extracted from treated cells revealed a dose- and time-dependent increase in the amount of cytoskeletal protein and a concomitant loss of protein thiols. These changes were associated with the disappearance of actin and formation of large-molecular-weight aggregates, when the cytoskeletal proteins were analyzed by polyacrylamide gel electrophoresis under nonreducing conditions. However, if the cytoskeletal proteins were treated with the thiol reductants, dithiothreitol or beta-mercaptoethanol, no changes in the relative abundance of actin or formation of large-molecular-weight aggregates were detected in the cytoskeletal preparations from treated cells. Moreover, addition of dithiothreitol to menadione- or diamide-treated hepatocytes protected the cells from both the appearance of surface blebs and the occurrence of alterations in cytoskeletal protein composition. Our findings show that oxidative stress induced by the metabolism of menadione in isolated hepatocytes causes cytoskeletal abnormalities, of which protein thiol oxidation seems to be intimately related to the appearance of surface blebs.

Cytoskeletal alterations in human platelets exposed to oxidative stress are mediated by oxidative and Ca2+-dependent mechanisms

The metabolism of the redox-active quinone, menadione (2-methyl-1,4-naphthoquinone), in human platelets was associated with superoxide anion production, oxidation and depletion of intracellular glutathione, and modification of protein thiols. The cytoskeletal fraction extracted from menadione-treated platelets exhibited a dose-dependent increase in the amount of cytoskeleton-associated protein and a concomitant loss of protein thiols. These alterations were associated with oxidative modifications of actin, including beta-mercaptoethanol-sensitive crosslinking of actin to form dimers, trimers, and high-molecular-weight aggregates which also contained other cytoskeletal proteins, i.e., alpha-actinin and actin-binding protein. In addition, analysis of the cytoskeletal fraction from platelets treated with high concentrations (greater than or equal to 100 microM) of menadione by polyacrylamide gel electrophoresis under reducing conditions revealed a net decrease in the relative abundance of the individual cytoskeletal polypeptides. Under the same incubation conditions the platelets exhibited a sustained increase in cytosolic Ca2+ concentration. The presence of glucose, or the omission of Ca2+ from the incubation medium, prevented both the increase in cytosolic Ca2+ and the decrease in the relative amounts of cytoskeletal proteins. The latter effect was also largely prevented in platelets loaded with Quin-2 tetraacetoxymethyl ester to buffer the menadione-induced elevation of cytosolic Ca2+. Finally, the presence of a protease inhibitor, leupeptin, in the incubation medium prevented the menadione-induced decrease in the amount of actin-binding protein but not the decrease in the other cytoskeletal proteins. Our findings demonstrate that the multiple effects of oxidative stress on the platelet cytoskeleton are mediated by oxidative as well as by Ca2+-dependent mechanisms.

On the role of thiol groups in the inhibition of liver microsomal Ca2+ sequestration by toxic agents

ATP-dependent Ca2+ sequestration by rat liver microsomes was assayed using three different methods, and characterized with regard to the effect of various inhibitors. When glucose and hexokinase were added in combination to deplete ATP in the incubation, Ca2+ uptake was followed by rapid release of Ca2+ from the microsomes. Ca2+ sequestration was inhibited by reagents that cause alkylation (e.g. p-chloromercuribenzoate) or oxidation (e.g. diamide) of protein sulfhydryl groups. Moreover, pretreatment of the microsomes with cystamine, which causes formation of mixed disulfides with protein thiols, also resulted in the inhibition of Ca2+ sequestration. It is concluded that microsomal Ca2+ sequestration is critically dependent on protein sulfhydryl groups, and that modification of protein thiols may be an important mechanism for the inhibition of microsomal Ca2+ sequestration by a variety of toxic agents.

Alterations of surface morphology caused by the metabolism of menadione in mammalian cells are associated with the oxidation of critical sulfhydryl groups in cytoskeletal proteins

Incubation of freshly-isolated (rat hepatocytes) or cultured (HeLa, GH3, and McCoy) mammalian cells with menadione (2-methyl-1,4-naphthoquinone) resulted in the appearance of numerous cell surface protrusions. The perturbation of surface structure was associated with an increase in the amount of cytoskeletal protein and the oxidation of sulfhydryl groups in actin, leading to the formation of high-molecular weight aggregates sensitive to treatment with thiol reductants. Our findings indicate that the oxidation of thiol groups in cytoskeletal proteins may be responsible for menadione-induced cell surface abnormalities in mammalian cells.

Calcium‐dependent DNA fragmentation in human synovial cells exposed to cold shock

Exposure of confluent human synovial McCoys cells to near‐freezing temperatures followed by rewarming at 37°C resulted in endonuclease activation and cell death characteristic of a suicide process known as apoptosis. Both DNA fragmentation and cell killing were dependent on a sustained increase in the cytosolic Ca2+ concentration. Sensitivity to cold shock‐induced endonuclease activation was critically dependent on the cell cycle (proliferative) status and limited to confluent cells, whereas cells in the logarithmic growth phase were completely resistant. However, DNA fragmentation was promoted in the proliferating McCoys cells pretreated with H‐7 or sphingosine, inhibitors of protein kinase C. In addition, phorbol ester, known to activate PKC, inhibited DNA fragmentation in the confluent cells. Our findings indicate that cold shock‐induced DNA fragmentation in McCoys cells is dependent on a sustained Ca2+ increase, and sensitivity to the process appears to be regulated by the status of protein kinase C.

Oxidative Stress and Cytoskeletal Alterationsa

Increasing numbers of studies suggest the involvement of multiple processes in the pathogenesis of cell injury during oxidative They are linked to the depletion of critical intracellular coenzymes as well as the activation of cytotoxic mechanisms that disrupt the structural organization and the physiological activities in different intracellular compartments. The demonstration of the multifactoriality of oxidative cell injury led to the search for and characterization of intracellular targets of the different pathophysiological processes. Among them are breakage and fragmentation of DNA,3 peroxidation of membrane lipid^,^ oxidation and fragmentation of proteins,5 mitochondria1 damage,h impairment of cell energy s t a t ~ s , ~ and disruption of ion homcos tas i~ .~ One of the early events in cell injury caused by oxidative stress is represented by the appearance of multiple surface protrusions called blebs.Y The pathophysiology of bleb formation has not been fully elucidated, probably because several mechanisms participate independently, but it is generally accepted that disruption of the cytoskeleta1 organization and of the membrane-cytoskeleton interaction could play a relevant role. This assumption is supported by the ultrastructural evidence of a marked reorganization of scvcral cytoskeletal elements preceding and accompanying the appearance of plasma membrane blebs“) and by the demonstration that wellknown cytoskeletal toxins such as cytochalasins and phalloidin cause blebbing in a variety of different cell types.12 Historically, these findings suggested the possibility that the cytoskeleton could actually represent an important target in oxidative stress-induced cell injury and stimulated active research to identify the biochemical mechanisms involved.

The cytoskeleton as a target in quinone toxicity.

The exposure of mammalian cells to toxic concentrations of redox cycling and alkylating quinones causes marked changes in cell surface structure known as plasma membrane blebbing. These alterations are associated with the redistribution of plasma membrane proteins and the disruption of the normal organization of the cytoskeletal microfilaments which appears to be due mainly to actin cross-linking and dissociation of alpha-actinin from the actin network. The major biochemical mechanisms responsible for these effects seem to involve the depletion of cytoskeletal protein sulfhydryl groups and the increase in cytosolic Ca2+ concentration following the alkylation/oxidation of free sulfhydryl groups in several Ca2+ transport systems. Depletion of intracellular ATP is also associated with quinone-induced plasma membrane blebbing. However, ATP depletion occurs well after the onset of the morphological changes, and thus it does not seem to be causatively related to their appearance. Thiol reductants, such as dithiothreitol, efficiently prevent the oxidation of cytoskeletal protein thiols, the increase in cytosolic free Ca2+ concentration and cell blebbing induced by redox cycling, but not alkylating, quinones. These results demonstrate that alkylating and redox cycling quinones cause similar structural and biochemical modifications of the cytoskeleton by means of different mechanisms, namely alkylation and oxidation of critical sulfhydryl groups.

Alterations in hepatocyte cytoskeleton caused by redox cycling and alkylating quinones

Quinones may induce toxicity by a number of mechanisms, including alkylation and oxidative stress following redox cycling. The metabolism of quinones by isolated rat hepatocytes is associated with cytoskeletal alterations, plasma membrane blebbing, and subsequent cytotoxicity. The different mechanisms underlying the effects of alkylating (p-benzoquinone), redox cycling (2,3-dimethoxy-1,4-naphthoquinone), and mixed redox cycling/alkylating (2-methyl-1,4-naphthoquinone) quinones on hepatocyte cytoskeleton have been investigated in detail in this study. Analysis of the cytoskeletal fraction extracted from quinone-treated cells revealed a concentration-dependent increase in the amount of cytoskeletal protein and a concomitant loss of protein thiols, irrespective of the quinone employed. In the case of redox cycling quinones, these alterations were associated with an oxidation-dependent actin crosslinking (sensitive to the thiol reductant dithiothreitol). In contrast, with alkylating quinones an oxidation-independent cytoskeletal protein crosslinking (insensitive to thiol reductants) was observed. In addition to these changes, a dose-dependent increase in the relative abundance of F-actin was detected as a consequence of the metabolism of oxidizing quinones in hepatocytes. Addition of dithiothreitol solubilized a considerable amount of polypeptides from the cytoskeletal fraction isolated from hepatocytes exposed to redox cycling but not alkylating quinones. Our findings indicate that the hepatocyte cytoskeleton is an important target for the toxic effects of different quinones. However, the mechanisms underlying cytoskeletal damage differ depending on whether the quinone acts primarily by oxidative stress or alkylation.

On the role of mitochondria in cell injury caused by vanadate-induced Ca2+ overload

Incubation of isolated rat hepatocytes with vanadate (0.25, 0.5 and 1 mM) resulted in progressive accumulation of Ca2+ in the intracellular compartments. Vanadate- induced Ca2+ accumulation was related to inhibition of the plasma membrane Ca2+-extruding system, but did not involve either enhanced plasma membrane permeability to Ca2+ or the enhanced operation of a putative Na+/Ca2+ exchanger. After an initial rise in the cytosolic free Ca2+ concentration, as revealed by phosphorylase activation, Ca2+ was sequestered predominantly by the mitochondria with little contribution from the endoplasmic reticulum. As the amount of Ca2+ in the mitochondria increased, a progressive decrease in mitochondrial membrane potential occurred, together with an impairment of the ability of these organelles to further sequester Ca2+. Associated with this, there was a decrease in intracellular ATP level, formation of surface blebs and cytotoxicity. Addition of an uncoupler to vanadate-treated hepatocytes dramatically accelerated the appearance of plasma membrane blebs and toxicity. Our results demonstrate that under conditions in which the plasma membrane Ca2+ pump is inhibited, mitochondria play an important role in protecting hepatocytes against damage induced by Ca2+ overload.