Tumour necrosis factor alpha, lipid peroxidation and NO* are increased and associated with decreased free-radical scavenging enzymes in patients with Weill-Marchesani syndrome

AIM: Weill-Marchesani syndrome (WMS) is a rare systemic disorder with both autosomal recessive and dominant inheritances. Accumulation of reactive oxygen species such as O2*-, H2O2 and OH* causes lipid peroxidation (LPO), whereas antioxidant enzymes (superoxide dismutase (SOD), glutathione peroxidase (GSHPx)) mediate defence against oxidative stress. Excess tumour necrosis factor (TNF)-alpha and NO* react with O2*- and cause further antioxidant depletion with an increase in mutation frequency by H2O2. This study investigated the levels of SOD, GSHPx, catalase (CAT), TNF-alpha, NO and LPO in patients with WMS. METHODS: A group of 10 WMS patients (four males, six females; age, 26.5+/-19.0 years) and 10 age-matched and sex-matched controls (five males, five females; age, 27.3+/-18.2 years) were included. Serum TNF-alpha levels were determined by a spectrophotometer technique using immulite chemiluminescent immunometric assay. Malondialdehyde (MDA) was determined in plasma; CAT in red blood cells (RBCs), and SOD and GSHPx in both plasma and RBCs. Total serum NO* levels were evaluated by Griess reaction. RESULTS: Mean levels of TNF-alpha (8.3+/-0.6 pg/ml) in WMS patients were significantly (p<0.001) higher than controls (4.3+/-0.2 pg/ml). Plasma MDA levels in patients and controls were 5.4+/-0.8 and 1.8+/-0.6 micromol/l, respectively, and the difference was significant (p=0.0002). SOD and GSHPx activities were significantly lower in both RBCs and plasma of WMS than in controls (RBC-SOD, 3981.9+/-626.6 versus 5261.6+/-523.0 U/g haemoglobin (Hb), p=0.0005; plasma-SOD, 529.4+/-49.3 versus 713.4+/-55.7 U/g protein, p=0.0002; RBC-GSHPx, 682.7+/-42.0 versus 756.5+/-47.6 U/g Hb, p=0.0011; plasma-GSHPx, 107.3+/-15.0 versus 131.4+/-19.7 U/g protein, p=0.0113). In addition, serum NO (NO*-2 + NO*-3) levels were also significantly (p = 0.0002) increased in WMS patients (54.4+/-5.7 versus 26.9+/-6.7 micromol/l). RBC-CAT levels were similar between groups (125.6+/-21.3 versus 131.0+/-21.5 k/g Hb, p = 0.8798). CONCLUSIONS: The elevated LPO, TNF-alpha and NO* with decreased antioxidant enzyme activities indicated impaired antioxidative defence mechanisms with an oxidative injury and cell toxicity in WMS patients. The use of multiple antioxidants and free radical scavengers might be helpful in this genetic disorder.     

cPKC-dependent sequestration of membrane-recycling components in a subset of recycling endosomes

In addition to the classical role of protein kinase C (PKC) as a mediator of transmembrane signals initiated at the plasma membrane, there is also significant evidence to suggest that a more sustained PKC activity is necessary for a variety of long term cellular responses. To date, the subcellular localization of PKC during sustained activation has not been extensively studied. We report here that long term activation of PKC (1 h) leads to the selective translocation of classical PKC isoenzymes, alpha and betaII, to a juxtanuclear compartment. Juxtanuclear translocation of PKC required an intact C1 and C2 domain, and occurred in a microtubule-dependent manner. This juxtanuclear compartment was localized close to the Golgi complex but displayed no overlap with Golgi markers, and was resistant to dispersal with Golgi disrupting agents, brefeldin A and nocodazole. Further characterization revealed that PKCalpha and betaII translocated to a compartment that colocalized with the small GTPase, rab11, which is a marker for the subset of recycling endosomes concentrated around the microtubule-organizing center/centrosome. Analysis of the functional consequence of cPKC translocation on membrane recycling demonstrated a cPKC-dependent sequestration of transferrin, a marker of membrane recycling, in the cPKC compartment. These results identify a novel site for cPKC translocation and define a novel function for the sustained activation of PKCalpha and betaII in regulation of recycling components.     

Ceramide kinase mediates cytokine- and calcium ionophore-induced arachidonic acid release

Despite the importance of prostaglandins, little is known about the regulation of prostanoid synthesis proximal to the activation of cytosolic phospholipase A2, the initial rate-limiting step. In this study, ceramide-1-phosphate (C-1-P) was shown to be a specific and potent inducer of arachidonic acid (AA) and prostanoid synthesis in cells. This study also demonstrates that two well established activators of AA release and prostanoid synthesis, the cytokine, interleukin-1beta (IL-1beta), and the calcium ionophore, A23187, induce an increase in C-1-P levels within the relevant time-frame of AA release. Furthermore, the enzyme responsible for the production of C-1-P in mammalian cells, ceramide kinase, was activated in response to IL-1beta and A23187. RNA interference targeted to ceramide kinase specifically down-regulated ceramide kinase mRNA and activity with a concomitant decrease of AA release in response to IL-1beta and A23187. Down-regulation of ceramide kinase had no effect on AA release induced by exogenous C-1-P. Collectively, these results indicate that ceramide kinase, via the formation of C-1-P, is an upstream modulator of phospholipase A2 activation. This study identifies previously unknown roles for ceramide kinase and its product, C-1-P, in AA release and production of eicosanoids and provides clues for potential new targets to block inflammatory responses.     

Functional analysis of ISC1 by site-directed mutagenesis

We previously reported that the yeast Saccharomyces cerevisiae ISC1 gene (Yer019w), which has homology to the bacterial sphingomyelinase gene, encodes inositol phosphosphingolipids-phospholipase C, Isc1p [Sawai, H., Okamoto, Y., Luberto, C., Mao, C., Bielawska, A., Domae, M., and Hannun, Y. A. (2000) J. Biol. Chem. 275, 39793-39798]. The present study was conducted to determine specific domains in Isc1p required for catalysis. Several amino acid residues are conserved from bacterial sphingomyelinase to mammalian sphingomyelinase and are also found in ISC1. Individual mutation of the conserved E100, N233, and H334 resulted in complete loss of Isc1p activity, suggesting an essential role in catalysis for these amino acid residues. Isc1p also contains a domain (from G162 to S169) with homology to P-loop domains, found in nucleotide-binding proteins. In addition, two amino acid residues from this domain, D163 and K168, are conserved from bacterial to mammalian sphingomyelinases in this "P-loop-like domain". G162, D163, G167, K168, and S169 were replaced individually with alanine using site-directed mutagenesis. D163A and K168A lost activity completely. Mutations in the other three positions rendered enzyme versions with much reduced but detectable activity. The V(max) values for G162A, G167A, and S169A were reduced, compared with wild type, but the K(m) values for G162A, G167A, and S169A were similar to that of wild type, indicating that the substrate binding efficiency was not greatly altered in these mutants and that the P-loop-like domain of ISC1 might be essential in catalysis of Isc1p. Furthermore, the Mg(2+) K(a) constants for G162A, G167, and S169A were higher than that for wild type, suggesting that this P-loop-like domain may be involved in Mg(2+) binding. Although cell lysates from yeast cells overexpressing all mutants similarly bound to phosphatidylserine (PS), an anionic lipid activator of Isc1p, G162A and G167A required 13.3 mol % PS to achieve maximum activity compared to 6.7 mol % for the wild-type enzyme, suggesting that PS might play a role in optimal catalytic efficiency of Isc1p via this P-loop-like domain. This study provides novel insight into a new domain found in Isc1p and related enzymes.     

Botryococcus braunii: a renewable source of hydrocarbons and other chemicals

Botryococcus braunii, a green colonial microalga, is an unusually rich renewable source of hydrocarbons and other chemicals. Hydrocarbons can constitute up to 75% of the dry mass of B. braunii. This review details the various facets of biotechnology of B. braunii, including its microbiology and physiology; production of hydrocarbons and other compounds by the alga; methods of culture; downstream recovery and processing of algal hydrocarbons; and cloning of the algal genes into other microorganisms. B. braunii converts simple inorganic compounds and sunlight to potential hydrocarbon fuels and feedstocks for the chemical industry. Microorganisms such as B. braunii can, in the long run, reduce our dependence on fossil fuels and because of this B. braunii continues to attract much attention.     

The role of aromatic residues in the hydrophobic core of the villin headpiece subdomain

Small autonomously folding proteins are of interest as model systems to study protein folding, as the same molecule can be used for both experimental and computational approaches. The question remains as to how well these minimized peptide model systems represent larger native proteins. For example, is the core of a minimized protein tolerant to mutation like larger proteins are? Also, do minimized proteins use special strategies for specifying and stabilizing their folded structure? Here we examine these questions in the 35‐residue autonomously folding villin headpiece subdomain (VHP subdomain). Specifically, we focus on a cluster of three conserved phenylalanine (F) residues F47, F51, and F58, that form most of the hydrophobic core. These three residues are oriented such that they may provide stabilizing aromatic–aromatic interactions that could be critical for specifying the fold. Circular dichroism and 1D‐NMR spectroscopy show that point mutations that individually replace any of these three residues with leucine were destabilized, but retained the native VHP subdomain fold. In pair‐wise replacements, the double mutant that retains F58 can adopt the native fold, while the two double mutants that lack F58 cannot. The folding of the double mutant that retains F58 demonstrates that aromatic–aromatic interactions within the aromatic cluster are not essential for specifying the VHP subdomain fold. The ability of the VHP subdomain to tolerate mutations within its hydrophobic core indicates that the information specifying the three dimensional structure is distributed throughout the sequence, as observed in larger proteins. Thus, the VHP subdomain is a legitimate model for larger, native proteins.     

Human thrombocytes are able to induce a myocardial dysfunction in the ischemic and reperfused guinea pig heart mediated by free radicals-role of the GPIIb/IIIa-blocker tirofiban

In recent studies, we could demonstrate a myocardial dysfunction induced by homologous platelets in ischemic and reperfused guinea pig hearts. Aim of the current study was to find out whether or not this is a phenomenon specific for platelets isolated from guinea pigs and to further examine the mechanisms of a possible cardiodepressive effect of human platelets. Isolated guinea pig hearts were exposed to a 30 min low-flow ischemia (1 ml/min) and reperfused. Human thrombocytes were administered as bolus (20.000 thrombocytes/microl perfusion buffer) in the 15(th) min of ischemia or in the 1(st) or 5(th) min of reperfusion in the presence of thrombin. Recovery of external heart work (REHW) and intracoronary platelet retention (RET) were quantified in percent. In additional experiments, the GPIIb/IIIa-blocker tirofiban (10 microg/ml perfusion buffer) or the radical scavenger superoxide dismutase (SOD-10 U/ml perfusion buffer) were added. Platelet application in the absence of tirofiban, either during ischemia (REHW 75.4 +/- 4%, RET 22.2 +/- 2%) or the 1st min (REHW 71.6 +/- 1%, RET 31.2 +/- 2%) or the 5th min of reperfusion (REHW 63.2 +/- 4%, RET 40.5 +/- 1%) led to a significant reduction of REHW and a significant increase of RET. The coapplication of tirofiban, on the other hand, prevented RET at all three times of platelet application (1.1 +/- 1.7%, 0% or 2.1 +/- 1.2%, respectively). An improvement of REHW, however, could only be noticed during ischemia (89 +/- 2%), whereas coapplication of tirofiban in early (72.9 +/- 3%) or in late reperfusion (74.6 +/- 2%) did not lead to a significant increase of REHW. Coapplication of SOD, on the other hand, significantly improved REHW in early (88.1 +/- 1) or late (95.9 +/- 1) reperfusion but not during ischemia (83.5 +/- 2). Corresponding to REHW, RET was changed significantly by coapplication of SOD during early (1 +/- 2%) or late (0%) reperfusion but not during ischemia (21.1 +/- 4%). We conclude that human thrombocytes are able to induce a myocardial dysfunction in ischemic and reperfused guinea pig hearts mediated by reactive oxygen species and independent of intracoronary platelet adhesion.     

Bcl-xL interrupts oxidative activation of neutral sphingomyelinase

Recent studies demonstrate a role for intracellular oxidation in the regulation of neutral sphingomyelinase (N-SMase). Glutathione (GSH) has been shown to regulate N-SMase in vitro and in cells. However, it has not been established whether the effects of GSH in cells are due to direct action on N-SMase. In this study, treatment of human mammary carcinoma MCF-7 cells with diamide, a thiol-depleting agent, caused a decrease in intracellular GSH and degradation of sphingomyelin (SM) to ceramide. The SM pool hydrolyzed in response to diamide belonged to the bacterial SMase-resistant pool of SM. Importantly, pretreatment of MCF-7 cells with GSH, N-acetylcysteine, an antioxidant, or GW69A, a specific N-SMase inhibitor, prevented diamide-induced degradation of SM to ceramide, suggesting that intracellular levels of GSH regulate the extent to which SM is degraded to ceramide and that this probably involves a GW69A-sensitive N-SMase. Unexpectedly, expression of Bcl-xL prevented tumor necrosis factor--induced SM hydrolysis and ceramide accumulation but not the decrease in intracellular GSH. Furthermore, Bcl-xL inhibited diamide-induced SM hydrolysis and ceramide accumulation but not the decrease in intracellular GSH. These results suggest that the site of action of Bcl-xL is downstream of GSH depletion and upstream of ceramide accumulation, and that GSH probably does not exert direct physiologic effects on N-SMase.     

Tight binding inhibition of protein phosphatase-1 by phosphatidic acid. Specificity of inhibition by the phospholipid

Phosphatidic acid (PA) has been identified as a bioactive lipid second messenger, yet despite extensive investigation, no cellular target has emerged as a mediator of its described biological effects. In this study, we identify the gamma isoform of the human protein phosphatase-1 catalytic subunit (PP1c gamma) as a high affinity in vitro target of PA. PA inhibited the enzyme dose-dependently with an IC(50) of 15 nm. Mechanistically, PA inhibited the enzyme noncompetitively with the kinetics of a tight binding inhibitor and a K(i) value of 0.97 +/- 0.24 nm. Together, these data describe one of the most potent in vitro effects of PA. To further elucidate the interaction between PA and PP1c gamma, structure/function analysis of the lipid was carried out using commercially available and synthetically generated analogs of PA. These studies disclosed that the lipid-protein interaction is dependent on the presence of the lipid phosphate as well as the presence of the fatty acid side chains, because lipids lacking either of these substituents resulted in complete loss of inhibition. However, the specific composition of the fatty acid side chains was not important for inhibition. Using 1-O-hexadecyl,2-oleoyl-PA, it was also shown that the carbonyl group of the sn-1 acyl linkage is not required for the lipid-protein interaction. Finally, using a lipid-protein overlay assay, it was demonstrated that PP1c gamma specifically and directly interacts with phosphatidic acid while not significantly binding other phospholipids. These results identify PA as a tight binding and specific inhibitor of PP1, and they raise the hypothesis that PP1c gamma may function as a mediator of PA action in cells. They also argue for the existence of a specific high affinity PA-binding domain on the enzyme.     

Acute activation of de novo sphingolipid biosynthesis upon heat shock causes an accumulation of ceramide and subsequent dephosphorylation of SR proteins

Recent studies are beginning to implicate sphingolipids in the heat stress response. In the yeast Saccharomyces cerevisiae, heat stress has been shown to activate de novo biosynthesis of sphingolipids, whereas in mammalian cells the sphingolipid ceramide has been implicated in the heat shock responses. In the current study, we found an increase in the ceramide mass of Molt-4 cells in response to heat shock, corroborating findings in HL-60 cells. Increased ceramide was determined to be from de novo biosynthesis by two major lines of evidence. First, the accumulation of ceramide was dependent upon the activities of both ceramide synthase and serine palmitoyltransferase. Second, pulse labeling studies demonstrated increased production of ceramide through the de novo biosynthetic pathway. Significantly, the de novo sphingolipid biosynthetic pathway was acutely induced upon heat shock, which resulted in a 2-fold increased flux in newly made ceramides within 1-2 min of exposure to 42.5 degrees C. Functionally, heat shock induced the dephosphorylation of the SR proteins, and this effect was demonstrated to be dependent upon the accumulation of de novo-produced ceramides. Thus, these studies disclose an evolutionary conserved activation of the de novo pathway in response to heat shock. Moreover, SR dephosphorylation is emerging as a specific downstream target of accumulation of newly made ceramides in mammalian cells.