Marianne Weis

Involvement of multiple proteases during Fas-mediated apoptosis in T lymphocytes.

The mechanism of Fas antigen‐mediated apoptosis is at present unclear. We show here that the100,000 × g supernatant from cell lysates prepared from anti‐Fas‐stimulated JURKAT T cells, induces chromatin fragmentation in isolated nuclei with concomitant morphological changes typically seen in apoptosis. The formation of this apoptotic nuclei promoting activity (ANPA) in JURKAT T cells after Fas antigen ligation was blocked by the serine protease inhibitors, TPCK and DCI, and by the interleukin 1‐β‐converting enzyme inhibitor, VAD‐FMK. In addition, chromatin degradation and morphological changes mediated by the ANPA in isolated nuclei were inhibited by TPCK, but not by DCI or VAD‐FMK. These results suggest that Fas‐mediated apoptosis in T cells involves the activation of a cascade of proteases.

Further characterization of the events involved in mitochondrial Ca2+ release and pore formation by prooxidants

Addition of the prooxidant 3,5-dimethyl-N-acetyl-p-benzoquinone imine (3,5(Me)2NAPQI) to Ca(2+)-loaded mitochondria caused a rapid and extensive release of the sequestered Ca2+. Ca2+ release was accompanied by irreversible NAD(P)H oxidation and was followed by the release of adenine and pyridine nucleotides into the extramitochondrial medium; this is evidence of the opening of the pore in the inner mitochondrial membrane. Preincubation of the mitochondria with ADP, cyclosporin A (CSA), m-iodobenzylguanidine (MIBG) or Mg2+ inhibited the prooxidant-induced Ca2+ release and prevented pore-opening. When mitochondria were preincubated with ruthenium red, Ca2+ release was only minimally stimulated by 3,5(Me)2NAPQI. However, increasing the concentration of the prooxidant caused release of an increasing fraction of the sequestered Ca2+. Alternatively, increasing the intramitochondrial Ca2+ load resulted in a lowering of the concentration of 3,5(Me)2NAPQI required for near complete Ca2+ release to occur. In the presence of ruthenium red, 3,5(Me)2NAPQI-induced Ca2+ release was accompanied by irreversible pyridine nucleotide oxidation and followed by the release of nucleotides into the extramitochondrial medium, events which were prevented on preincubation with CSA. Similarly, the addition of CSA, ADP or MIBG during 3,5(Me)2NAPQI-induced Ca2+ release arrested further Ca2+ release. In addition to their inhibitory effect on the 3,5(Me)2NAPQI-induced Ca2+ release, CSA, ADP or MIBG also decreased the rate of the basal, ruthenium red-induced mitochondrial Ca2+ release by 45-70%. It is proposed that the basal, ruthenium red-induced and the prooxidant-induced mitochondrial Ca2+ release occur through a common component that is sensitive to inhibition by CSA, ADP and MIBG and that is involved in mitochondrial pore formation. Furthermore, 3,5(Me)2NAPQI-induced pore opening does not involve Ca(2+)-cycling, but rather involves a site(s) that is (are) synergistically activated by Ca2+ and the prooxidant.

Role of sulfhydryl groups in benzoquinone-induced Ca2+ release by rat liver mitochondria

Incubation of rat liver mitochondria with benzoquinone derivatives in the presence of succinate plus rotenone has been shown to cause NAD(P)H oxidation followed by Ca2+ release. Further investigation revealed: (1)p-Benzoquinone-induced Ca2+ release was not initiated by a collapse of the mitochondrial membrane potential. However, Ca2+ release and subsequent Ca2+ cycling caused limited increased membrane permeability. (2) p-Benzoquinone-induced NAD(P)H oxidation and Ca2+ release were prevented by isocitrate, 3-hydroxybutyrate, and glutamate but not by pyruvate or 2-oxoglutarate. (3) Inhibition of pyruvate and 2-oxoglutarate dehydrogenases by p-benzoquinone was attributed to arylation of the SH groups of the cofactors, CoA and lipoic acid. Isocitrate dehydrogenase was also inhibited by p-benzoquinone, but the cofactors NAD(P)H and Mn2+ protected the enzyme. Glutamate dehydrogenase was not inhibited by p-benzoquinone. (4) Arylation of mitochondrial protein thiols by p-benzoquinone was associated with an inhibition of state 3 respiration, which was attributed to the inactivation of the phosphate translocase. In contrast, state 4 respiration, and the F1.F0-ATPase and ATP/ADP translocase activities were not inhibited. It was concluded that inhibition of mitochondrial NAD(P)H dehydrogenases by arylation of critical thiol groups will decrease the NAD(P)+-reducing capacity, and possibly lower the NAD(P)H/NAD(P)+ redox status in favor of Ca2+ release.

Expression inEscherichia coli of active human alcohol dehydrogenase lacking N-terminal acetylation

Human alcohol dehydrogenase (ADH, tiff isozyme of class I) was expressed in Escherichia coli, purified to homogeneity, and characterized regarding N-terminal processing. The expression system was obtained by ligation of a cDNA fragment corresponding to the fl-subunit of human liver alcohol dehydrogenase into the vector pKK 223-3 containing the tac promoter. The enzyme, detected by Western-blot analysis and ethanol oxidizing activity, constituted up to 3 ~o of the total amount of protein. Recombinant ADH was separated from E. coli ADH by ion-exchange chromatography and the isolated enzyme was essentially pure as judged by SDS-polyacrylamide gel electrophoresis and sequence analysis. The N-terminal sequence was identical to that of the authentic fl-subunit except that the N-terminus was non-acetylated, indicating a correct removal of the initiator methionine, but lack of further processing.

Determination of the intracellular protein thiol distribution of hepatocytes using monobromobimane derivatisation of intact cells and isolated subcellular fractions

The derivatisation of intact rat hepatocytes with monobromobimane resulted in rapid labelling of accessible protein thiols in several subcellular fractions. The derivatisation procedure did not cause acute cytotoxicity, nor did it alter the buoyant densities of the fractions or their gross protein compositions. Quantitation of the fluorescence irreversibly associated with the fractions demonstrated considerable intracellular heterogeneity in this pool of thiols. Values were highest in cytosol (ca. 90 nmol/mg protein), intermediate in microsomes (ca. 65 nmol/mg protein) and mitochondria (ca. 45 nmol/mg protein) and lowest in a crude fraction containing both nuclei and plasma membrane (ca. 35 nmol/mg protein). Similar values were obtained from microsomes and cytosol derivatised after fractionation but there were significant increases of ca. 100% in corresponding values from isolated mitochondria and the nuclear/plasma membrane fraction. These results are discussed in terms of the dynamic fluxes in monobromobimane protein thiols during fractionation and the applicability of this noninvasive method to studies of the mechanism(s) of toxicity of reactive xenobiotics and the role(s) of protein thiols in normal cellular function.

N-acetyl-p-benzoquinone imine-induced protein thiol modification in isolated rat hepatocytes

Incubation of isolated rat hepatocytes with N-acetyl-p-benzoquinone imine (NAPQI) or 3,5-dimethyl-N-acetyl-p-benzoquinone imine (3,5-Me2-NAPQI) resulted in a concentration-dependent decrease in the protein thiol content of the mitochondrial, cytosolic and microsomal fractions. On a concentration basis, 3,5-Me2-NAPQI induced a more marked depletion of protein thiols than did NAPQI. Sodium dodecyl sulphate-polyacrylamide gel electrophoretic separation of the proteins of each fraction showed that different proteins had different susceptibilities to modification of their cysteine residues by the quinone imines. A few protein bands showed a decreased protein thiol content following incubation with non-toxic concentrations of quinone imines, whereas other proteins were affected by higher concentrations. Concentrations of quinone imines that were highly cytotoxic induced a general loss of protein thiols. NAPQI-induced protein thiol depletion occurred within 5 min and remained essentially unchanged for at least 30 min. In contrast, protein thiol depletion induced by 3,5-Me2-NAPQI increased over the 30-min time course of the experiment. Toxic concentrations of 3,5-Me2-NAPQI caused the formation of high molecular mass aggregates in all three subcellular fractions after 30 min of incubation. The observed crosslinking was not due to protein disulfide formation. However, no aggregate formation was observed after exposure of hepatocytes to NAPQI. One of the major target proteins of quinone imine-induced protein thiol depletion was a 17 kDa microsomal protein that was identified as the microsomal glutathione S-transferase. Exposure of hepatocytes and isolated liver microsomes to the quinone imines resulted in an up to four-fold increase in the specific activity of the microsomal glutathione S-transferase. In conclusion, our results are consistent with the suggestion of a critical role of protein thiol depletion in quinone imine-induced cytotoxicity.

Quinone imine-induced Ca2+ release from isolated rat liver mitochondria

Incubation of Ca2(+)-loaded rat liver mitochondria with N-acetyl-p-benzoquinone imine (NAPQI) or its two dimethylated analogues resulted in a concentration dependent Ca2+ release, with the following order of potency: 2,6-(Me)2-NAPQI greater than NAPQI greater than 3,5-(Me)2-NAPQI. The quinone imine-induced Ca2+ release was associated with NAD(P)H oxidation and was prevented when NAD(P)+ reduction was stimulated by the addition of 3-hydroxybutyrate. Mitochondrial glutathione was completely depleted within 0.5 min by all three quinone imines, even at low concentrations that did not result in Ca2+ release. Depletion of mitochondrial GSH by pretreatment with 1-chloro-2,4-dinitrobenzene enhanced quinone imine-induced NAD(P)H oxidation and Ca2+ release. However, 3-hydroxybutyrate protected from quinone imine-induced Ca2+ release in GSH-depleted mitochondria. Mitochondrial membrane potential was lost after the addition of quinone imines at concentrations that caused rapid Ca2+ release; however, subsequent addition of EGTA led to the complete recovery of the transmembrane potential. In the absence of Ca2+, the quinone imines caused only a small and transient loss of the transmembrane potential. Taken together, our results suggests that the quinone imine-induced Ca2+ release from mitochondria is a consequence of NAD(P)H oxidation rather than GSH depletion, GSSG formation, or mitochondrial inner membrane damage.

Accessibility of hepatocyte protein thiols to monobromobimane

The amino-acid residue specificity of monobromobimane (mBBr) and its accessibility to cellular protein cysteine residues were investigated. mBBr reacted selectively with the sulfhydryl group of both the free amino acid cysteine and bovine serum albumin. Incubation of isolated hepatocytes with mBBr resulted in a concentration-dependent formation of protein-bound mBBr fluorescence in the cytosolic, mitochondrial and microsomal fractions, which was not fully saturated with up to 16 mM mBBr. SDS-PAGE resolution of the proteins revealed that the major portion of increased protein-bound mBBr fluorescence that occurred at high mBBr concentrations was due to covalent binding to proteins. A minor portion (10-16% in the microsomal fraction) of protein-bound mBBr fluorescence was removed by SDS-PAGE and is therefore concluded to be due to physical entrapment of fluorescent mBBr reaction products. The accessibility of mBBr, assayed as the degree of depletion of total protein cysteine residues, was similar to N-ethylmaleimide (NEM) in isolated microsomes. By contrast, in the cytosol a markedly lower amount of protein cysteine residues were labelled by mBBr as compared to NEM. In both organelle fractions p-BQ was the most efficient thiol-depleting reagent. It is concluded that mBBr is a suitable reagent for the analysis of the cellular protein thiol status and of its xenobiotic-induced alterations when used at high concentrations; however, it should be considered that, (i) the relative accessibility of mBBr and a particular xenobiotic to cellular protein thiol residues may be different, and (ii) physically entrapped fluorescent reaction products of mBBr should be removed when quantitating protein thiol levels.

Peroxidase-catalyzed oxidation of 3,5-dimethyl acetaminophen causes cell death by selective protein thiol modification in isolated rat hepatocytes

In this study we used a peroxidase model system (glucose/glucose oxidase and horseradish peroxidase) to investigate the effect of extracellularly generated reactive metabolites of 3,5-Me2-acetaminophen on cell viability and on cellular thiol levels. Incubation of hepatocytes with 3,5-Me2-acetaminophen in the presence of glucose/glucose oxidase and horseradish peroxidase caused a concentration-dependent loss of cell viability. Loss of viability was associated with decreased protein thiol levels. Addition of the reducing agent DTT, but not catalase, during the incubation restored cellular protein thiol levels and arrested the cell killing. Protein thiol depletion occurred selectively to the mitochondrial and microsomal fractions and was specific for a very limited number of protein bands. The data suggest that the oxidative modification of individual protein cysteine residues within the latter two organelle fractions is critically involved in the mechanism of toxicity.