Megalencephalic leukoencephalopathy with subcortical cysts protein-1: A new calcium-sensitive protein functionally activated by endoplasmic reticulum calcium release and calmodulin binding in astrocytes.

BACKGROUND: MLC1 is a membrane protein highly expressed in brain perivascular astrocytes and whose mutations account for the rare leukodystrophy (LD) megalencephalic leukoencephalopathy with subcortical cysts disease (MLC). MLC is characterized by macrocephaly, brain edema and cysts, myelin vacuolation and astrocyte swelling which cause cognitive and motor dysfunctions and epilepsy. In cultured astrocytes, lack of functional MLC1 disturbs cell volume regulation by affecting anion channel (VRAC) currents and the consequent regulatory volume decrease (RVD) occurring in response to osmotic changes. Moreover, MLC1 represses intracellular signaling molecules (EGFR, ERK1/2, NF-kB) inducing astrocyte activation and swelling following brain insults. Nevertheless, to date, MLC1 proper function and MLC molecular pathogenesis are still elusive. We recently reported that in astrocytes MLC1 phosphorylation by the Ca2+/Calmodulin-dependent kinase II (CaMKII) in response to intracellular Ca2+ release potentiates MLC1 activation of VRAC. These results highlighted the importance of Ca2+ signaling in the regulation of MLC1 functions, prompting us to further investigate the relationships between intracellular Ca2+ and MLC1 properties. METHODS: We used U251 astrocytoma cells stably expressing wild-type (WT) or mutated MLC1, primary mouse astrocytes and mouse brain tissue, and applied biochemistry, molecular biology, video imaging and electrophysiology techniques. RESULTS: We revealed that WT but not mutant MLC1 oligomerization and trafficking to the astrocyte plasma membrane is favored by Ca2+ release from endoplasmic reticulum (ER) but not by capacitive Ca2+ entry in response to ER depletion. We also clarified the molecular events underlining MLC1 response to cytoplasmic Ca2+ increase, demonstrating that, following Ca2+ release, MLC1 binds the Ca2+ effector protein calmodulin (CaM) at the carboxyl terminal where a CaM binding sequence was identified. Using a CaM inhibitor and generating U251 cells expressing MLC1 with CaM binding site mutations, we found that CaM regulates MLC1 assembly, trafficking and function, being RVD and MLC-linked signaling molecules abnormally regulated in these latter cells. CONCLUSION: Overall, we qualified MLC1 as a Ca2+ sensitive protein involved in the control of volume changes in response to ER Ca2+ release and astrocyte activation. These findings provide new insights for the comprehension of the molecular mechanisms responsible for the myelin degeneration occurring in MLC and other LD where astrocytes have a primary role in the pathological process.

Nitrotyrosine mimics phosphotyrosine binding to the SH2 domain of the src family tyrosine kinase lyn.

The nitration of tyrosine residues in protein occurs through the action of reactive oxygen and nitrogen species and is considered a marker of oxidative stress under pathological conditions. The most active nitrating species so far identified is peroxynitrite, the product of the reaction between nitric oxide and superoxide anion. Previously, we have reported that in erythrocytes peroxynitrite irreversibly upregulates lyn, a tyrosine kinase of the src family. In this study we investigated the possible role of tyrosine nitration in the mechanism of lyn activation. We found that tyrosine containing peptides modelled either on the C-terminal tail of src kinases or corresponding to the first 15 amino acids of human erythrocyte band 3 were able to activate lyn when the tyrosine was substituted with 3-nitrotyrosine. The activity of nitrated peptides was shared with phosphorylated but not with unphosphorylated, chlorinated or scrambled peptides. Recombinant lyn src homology 2 (SH2) domain blocked the capacity of the band 3-derived nitrotyrosine peptide to activate lyn and we demonstrated that this peptide specifically binds the SH2 domain of lyn. We propose that nitropeptides may activate src kinases through the displacement of the phosphotyrosine in the tail from its binding site in the SH2 domain. These observations suggest a new mechanism of peroxynitrite-mediated signalling that may be correlated with the upregulation of tyrosine phosphorylation observed in several pathological conditions.

Peroxynitrite-dependent activation of src tyrosine kinases lyn and hck in erythrocytes is under mechanistically different pathways of redox control.

Peroxynitrite, the product of superoxide and nitric oxide radicals, is considered one of the major oxidants formed in vivo under intense oxidative stress. We have previously reported the upregulation by peroxynitrite of src kinase activity in red blood cells. In this study, we investigated the mechanisms of peroxynitrite action and we demonstrate that two src kinases (lyn and hck) are activated through different pathways involving cysteine-dependent or -independent oxidations. Activation of hck by peroxynitrite or by hydrogen peroxide could be explained by reversible SH redox changes, whereas lyn was unaffected by hydrogen peroxide and its direct activation by peroxynitrite occurred through a still unknown modification(s) not reverted by SH reduction or inhibited by SH alkylation. Moreover, lyn could be activated also downstream by peroxynitrite-activated hck. The cross talk between lyn and hck was selective, since activated hck did not activate the non-src kinase syk. This study illustrates the complexity of redox-dependent src regulation and suggests that one reason for src heterogeneity may be a peculiar difference in their sensitivity to physiological oxidants. Irrespectively of the activation pathway, the final effect of peroxynitrite is the amplification of tyrosine-dependent signaling, a finding of general interest in nitric oxide-related pathophysiology.

Activation of src tyrosine kinases by peroxynitrite.

In this study, we demonstrate that the phosphorylation activity of five tyrosine kinases of the src family from both human erythrocytes (lyn, hck and c-fgr) and bovine synaptosomes (lyn and fyn) was stimulated by treatment with 30-250 microM peroxynitrite. This effect was not observed with syk, a non-src family tyrosine kinase. Treatment of kinase immunoprecipitates with 0.01-10 microM peroxynitrite showed that the interaction of these enzymes with the oxidant also activated the src kinases. Higher concentrations of peroxynitrite inhibited the activity of all kinases, indicating enzyme inactivation. The addition of bicarbonate (1.3 mM CO2) did not modify the upregulation of src kinases but significantly protected the kinases against peroxynitrite-mediated inhibition. Upregulation of src kinase activity by 1 microM peroxynitrite was 3.5-5-fold in erythrocytes and 1.2-2-fold in synaptosomes, but this could be the result, at least in part, of the higher basal level of src kinase activity in synaptosomes. Our results indicate that peroxynitrite can upregulate the tyrosine phosphorylation signal through the activation of src kinases.

Peroxynitrite induces tryosine nitration and modulates tyrosine phosphorylation of synaptic proteins.

Peroxynitrite, the product of the radical-radical reaction between nitric oxide and superoxide anion, is a potent oxidant involved in tissue damage in neurodegenerative disorders. We investigated the modifications induced by peroxynitrite in tyrosine residues of proteins from synaptosomes. Peroxynitrite treatment (> or =50 microM) induced tyrosine nitration and increased tyrosine phosphorylation. Synaptophysin was identified as one of the major nitrated proteins and pp60src kinase as one of the major phosphorylated substrates. Further fractionation of synaptosomes revealed nitrated synaptophysin in the synaptic vesicles, whereas phosphorylated pp60src was enriched in the postsynaptic density fraction. Tyrosine phosphorylation was increased by treatment with 50-500 microM peroxynitrite and decreased by higher concentrations, suggesting a possible activation/inactivation of kinases. Immunocomplex kinase assay proved that peroxynitrite treatment of synaptosomes modulated the pp60src autophosphorylation activity. The addition of bicarbonate (CO2 1.3 mM) produced a moderate enhancing effect on some nitrated proteins but significantly protected the activity of pp60src against peroxynitrite-mediated inhibition so that at 1 mM peroxynitrite, the kinase was still more active than in untreated synaptosomes. The phosphotyrosine phosphatase activity of synaptosomes was inhibited by peroxynitrite (> or =50 microM) but significantly protected by CO2. Thus, the increase of phosphorylation cannot be attributed to peroxynitrite-mediated inhibition of phosphatases. We suggest that peroxynitrite may regulate the posttranslational modification of tyrosine residues in pre- and postsynaptic proteins. Identification of the major protein targets gives insight into the pathways possibly involved in neuronal degeneration associated with peroxynitrite overproduction.

Bilirubin is an effective antioxidant of peroxynitrite-mediated protein oxidation in human blood plasma.

Bilirubin is a bile pigment that may have an important role as an antioxidant. Its antioxidant potential is attributed mainly to the scavenging of peroxyl radicals. We investigated the reaction of bilirubin with peroxynitrite in phosphate buffer and in blood plasma. In phosphate buffer bilirubin was rapidly oxidized by micromolar concentrations of peroxynitrite, and its oxidation yield was higher at alkaline pH with an apparent pKa = 6.9. In contrast, the major oxidation product of bilirubin in plasma was biliverdin, and the pH profile of its oxidation yield showed a slightly increased oxidation at acidic pH without a clear inflection point. The addition of NaHCO3 to bilirubin decreased the peroxynitrite-dependent oxidation, suggesting that the reactive intermediates formed in the reaction between CO2 and peroxynitrite are less efficient oxidants of bilirubin. The antioxidant role of bilirubin was investigated in some peroxynitrite-mediated plasma protein modifications that are enhanced by CO2 (tryptophan oxidation and protein tyrosine nitration) or slightly decreased by CO2 (protein carbonyl groups). Bilirubin in the micromolar concentration range afforded a significant protection against all these oxidative modifications and, notably, protected plasma proteins even when the pigment was added 5 s after peroxynitrite (i.e., when peroxynitrite is completely decomposed). The loss of tryptophan fluorescence triggered by peroxynitrite was a relatively slow process fulfilled only after a few minutes. After this time, bilirubin was unable to reduce the tryptophan loss, and it was unable to reduce previously formed nitrated albumin or previously formed carbonyls. We deduce that bilirubin in plasma cannot react to a significant extent with peroxynitrite, and we suggest that bilirubin, through a hydrogen donation mechanism, participates as a scavenger of secondary oxidants formed in the oxidative process.

Peroxynitrite modulates tyrosine-dependent signal transduction pathway of human erythrocyte band 3.

Peroxynitrite, the product of the reaction between nitric oxide and superoxide anion, is able to nitrate protein tyrosines. If this modification occurs on phosphotyrosine kinase substrates, it can down-regulate cell signaling. We investigated the effects of peroxynitrite on band 3-mediated signal transduction of human erythrocytes. Peroxynitrite treatment induced two different responses. At low concentrations (10-100 microM) it stimulated a metabolic response, leading to 1) a reversible inhibition of phosphotyrosine phosphatase activity, 2) a rise of tyrosine phosphorylation in the 22K cytoplasmic domain of band 3, 3) the release of glyceraldehyde 3-phosphate dehydrogenase from the membrane, and 4) the enhancement of lactate production. At high concentrations (200-1000 microM), peroxynitrite induced 1) cross-linking of membrane proteins, 2) inhibition of band 3 tyrosine phosphorylation, 3) nitration of tyrosines in the 22K cytoplasmic domain of band 3, 4) binding of hemoglobin to the membrane, 5) irreversible inhibition of phosphotyrosine kinase activity, 6) massive methemoglobin production, and 7) irreversible inhibition of lactate production. Our results demonstrate that at concentrations that could conceivably be achieved in vivo (10-100 microM), peroxynitrite behaves like other oxidants, i.e., it stimulates band 3 tyrosine phosphorylation and increases glucose metabolism. Thus, one plausible physiologic effect of peroxynitrite is the up-regulation of signaling through the reversible inhibition of phosphotyrosine phosphatase activity. At high concentrations of peroxynitrite, the tyrosine phosphorylation ceases in parallel with the nitration of band 3 tyrosines, but at these concentrations phosphotyrosine kinase activity and glycolysis are also irreversibly inhibited. Thus, at least in red blood cells, the postulated down-regulation of signaling by peroxynitrite cannot merely be ascribed to the nitration of tyrosine kinase targets.

Nitric oxide-dependent NAD linkage to glyceraldehyde-3-phosphate dehydrogenase: possible involvement of a cysteine thiyl radical intermediate.

Previous studies have demonstrated that glyceraldehyde-3-phosphate dehydrogenase (GAPDH) undergoes NAD(H) linkage to an active site thiol when it comes into contact with .NO-related oxidants. We found that a free-radical generator 2,2'-azobis-(2-amidinopropane) hydrochloride (AAPH), which does not release either .NO or .NO-related species, was indeed able to induce the NAD(H) linkage to GAPDH. We performed spin-trapping studies with purified apo-GAPDH to identify a putative thiol intermediate produced by AAPH as well as by .NO-related oxidants. As .NO sources we used .NO gas and two .NO-donors, S-nitroso-N-acetyl-D,L-penicillamine and 3-morpholinosydno-nimine hydrochloride (SIN-1). Because SIN-1 produces .NO and a superoxide radical simultaneously, we also tested the effects of peroxynitrite. All the .NO-related oxidants were able to induce the linkage of NAD(H) to GAPDH and the formation of a protein free-radical identified as a thiyl radical (inhibited by N-ethylmaleimide). .NO gas and the .NO-donors required molecular oxygen to induce the formation of the GAPDH thiyl radical, suggesting the possible involvement of higher nitrogen oxides. Thiyl radical formation was decreased by the reconstitution of GAPDH with NAD+. Apo-GAPDH was a strong scavenger of AAPH radicals, but its scavenging ability was decreased when its cysteine residues were alkylated or when it was reconstituted with NAD+. In addition, after treatment with AAPH, a thiyl radical of GAPDH was trapped at high enzyme concentrations. We suggest that the NAD(H) linkage to GAPDH is mediated by a thiyl radical intermediate not specific to .NO or .NO-related oxidants. The cysteine residue located at the active site of GAPDH (Cys-149) is oxidized by free radicals to a thiyl radical, which reacts with the neighbouring coenzyme to form Cys-NAD(H) linkages. Studies with the NAD+ molecule radio-labelled in the nicotinamide or adenine portion revealed that both portions of the NAD+ molecule are linked to GAPDH.

Free radicals induce reversible membrane-cytoplasm translocation of glyceraldehyde-3-phosphate dehydrogenase in human erythrocytes.

We investigated the role of oxygen free radicals in the modulation of glyceraldehyde-3-phosphate dehydrogenase binding to the erythrocyte membrane. Previous studies have demonstrated that in vitro tyrosine phosphorylation of Band 3 prevents the binding of various glycolytic enzymes to its cytoplasmic domain. Since these enzymes are inhibited in their bound state, the functional consequence of Band 3 tyrosine phosphorylation in red blood cells should be to increase glycolysis. To generate free radicals, we used an azo-compound, the hydrophilic 2,2'-azobis(2-amidinopropane) hydrochloride, which, at 37 degrees C and in the presence of oxygen, decomposes and produces peroxyl radicals at a constant rate. The reaction of peroxyl radicals with intact red cells induced a time-dependent loss of the membrane-bound glycolytic enzyme, glyceraldehyde-3-phosphate dehydrogenase, associated with a concomitant decrease in enzyme activity. At the same time, Band 3 was phosphorylated in tyrosine. These results were completely reversible in plasma after removal of the oxidative stress. The peroxyl radicals also enhanced the production of lactate in intact cells. Our data reveal a powerful mechanism of erythrocyte metabolic regulation that can boost or reduce energy production in times of special need such as during a free radical attack.

Role of thiols in the targeting of S-nitroso thiols to red blood cells.

We compared the nitric oxide (.NO)-releasing characteristics of two NO donors, the S-nitroso adduct of bovine serum albumin (BSANO) and the S-nitroso adduct of L-glutathione (GSNO). In oxygenated phosphate buffer (pH 7.4) and in hemoglobin solution, both NO donors released .NO only in the presence of a low molecular weight thiol (the most active was L-cysteine). The requirement of thiol to release .NO strongly suggests that a transnitrosation reaction occurs between the S-nitroso adduct of the NO donor and the sulfhydryl group of the NO acceptor. The reaction produced a labile S-nitroso-L-cysteine intermediate that released .NO. As shown by spin-trapping experiments, the transnitrosation reaction involved the formation of .NO (trapped by 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl 3-oxide) and .S radicals (trapped by 5,5'-dimethyl-1-pyrroline N-oxide) of both the NO donors and the NO acceptor (L-cysteine). The reaction leading to .S radical formation was distinct from the transnitrosation reaction, since it was oxygen-dependent. We suggest that .S radicals are formed from oxidizing species produced after a reaction between .NO and molecular oxygen (.NO2 is a likely candidate). As for pure .NO gas, the major oxidation product of NO donors, in phosphate buffer (pH 7.4), was NO2-, with no formation of NO3-. In the presence of oxyhemoglobin, both NO donors produced only NO3-. BSANO and GSNO showed distinct patterns of .NO release both in phosphate buffer and in the presence of hemoglobin.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of oxygen and carbon radicals in hemoglobin oxidation.

We investigated the role of free radicals in hemoglobin (Hb) oxidation and denaturation. To generate free radicals, we used two azocompounds, the hydrophilic 2,2'-azobis(2-amidinopropane hydrochloride and the hydrophobic 2,2'-azobis(2,4-dimethylvaleronitrile) and a drug of the quinone family, phenazine methosulfate. The radical species involved were analyzed by direct EPR and spin trapping with 5,5-dimethyl-1-pyrroline N-oxide, and N-t-butyl-alpha-phenyl-nitrone. The free radicals generated by the azocompounds were carbon radicals and, in the presence of molecular oxygen, peroxyl/alkoxyl radicals. The reaction of phenazine with Hb produced a nitrogen-centered semiquinoid radical detectable by EPR only under N2 and reactive oxygen species (O2-. and H2O2) in the presence of molecular oxygen. Azocompounds oxidized Hb to methemoglobin, hemichromes, and choleglobin while phenazine produced methemoglobin and ferrylhemoglobin. For all three drugs, low oxygen tensions (pO2 = 62 mm Hg) increased the formation of Hb oxidation products, whereas high oxygen tensions (pO2 = 540 mm Hg) reduced Hb oxidation. The formation of irreversible Hb oxidation products (irreversible hemichromes and Hb cross-linking) was observed only with the azocompounds and was reduced at high pO2. Spin traps and thiourea protected Hb from the oxidative damage induced by the azocompounds, whereas enzymes scavenging reactive oxygen species, such as superoxide dismutase and catalase, affected Hb oxidation induced by phenazine and that induced by the hydrophobic azocompound. These results indicate distinct patterns of oxidation and denaturation with each agent. Damage induced by phenazine was dependent on the formation of reactive oxygen species, whereas the damage induced by the azocompounds was due mainly to carbon-centered radicals with some involvement by reactive oxygen species only for the hydrophobic azocompound. The preferential interaction of Hb with drug radicals scavenged by molecular oxygen indicates that this protein may be more reactive under hypoxic conditions and led to the view that a good supply of oxygen can provide an important defense against drug-induced Hb oxidation.

Effects of 2,5-hexanedione on the ovary and fertility. An experimental study in mice.

Sixty-day-old virgin female Swiss CD1 mice were treated with 1.5% 2,5-hexanedione in their drinking water; control mice received tap water; duration of treatment was either 4 or 6 weeks. Under these conditions the treated mice did not show any clinical symptoms although electromyography revealed some signs of polyneuropathy. Protein and DNA content per mg of ovarian tissue in treated mice were not significantly different from controls. Histological examination of ovarian sections at the light microscope level showed no significant alterations after exposure. A morphometric study revealed a statistically significant reduction in the number of growing oocytes after 6 weeks of treatment. For fertility studies three groups of 15 female mice each were treated for 0, 4 or 6 weeks as above and then permanently housed with untreated proven breeder male mice (one male per female); cages were checked daily for newly born mice. All litters appeared normal by gross examination. During the first 14 weeks of continuous mating the mean litter size (number of newborns per litter) remained about 11.4 in all groups; this number subsequently began to decrease. Control and 4-week treatment regression curves did not differ statistically, while the slope of the 6-week line was significantly steeper, indicating a faster decrease in litter size over time and a shortening of fertile life in the latter group of treated females.

2,5-Hexanedione modifies skeletal proteins of the red blood cells and increases the binding of hemoglobin to the membrane.

The effects of 2,5-hexanedione (2,5 HD) on skeletal proteins of red blood cells (RBCs) were investigated both in vitro (human RBCs) and in vivo in male Sprague-Dawley rats which had been treated with the drug for several days. We found that 2,5 HD induced the following major changes in the electrophoretic pattern of the skeletal proteins: (i) the appearance of high-molecular weight bands, (ii) a dose-dependent decrease in spectrin Bands 1 and 2, and (iii) a dose-dependent increase in the amount of hemoglobin (Hb) associated with the membrane. Membranoskeletons, prepared from resealed ghosts which had been previously treated with 2,5 HD, were able to bind an increased amount of Hb from untreated RBCs, thus suggesting a drug-induced modification of the membrane. Extraction of spectrin and actin from ghosts did not remove the membrane-bound Hb and, furthermore, Hb bound to 2,5 HD-treated membranes mainly bearing Band 3 and free of peripheral proteins. These data suggested a 2,5 HD-induced modification of an intrinsic membrane protein, probably Band 3. This hypothesis was consistent with the observation that 2,5 HD also induced a modification of Band 3 aminogroups, as evidenced by a dose-dependent decrease in the binding of eosin probes. Furthermore, RBCs treated in vitro with 2,5 HD bound an increased amount of autologous immunoglobulins (IgG). As reported by Kay and Low et al. the binding of autologous IgG is a phenomenon associated with the aging process of RBCs and may involve a modification of Band 3. Our data show that RBCs treated with 2,5 HD acquired various characteristics of senescent cells such as spectrin cross-linking, Hb-membrane binding and increased IgG binding, and suggest that 2,5 HD treatment might affect RBC survival.

Cholinesterases in blood plasma and tissues of rats treated with n-hexane or with its neurotoxic metabolite 2,5-hexanedione.

Adult male rats were subjected to 4 weeks' respiratory treatment with n-hexane (5000 ppm, 16h/day, 6 days/week); motor conduction velocity was significantly decreased in tail nerves at all weekly intervals and did not approach normal values in the 4 weeks following interruption of treatment. Plasma acetylcholinesterase (AChE) levels were significantly increased at all weekly intervals during treatment (25-40%); 2 weeks after the end of treatment they had returned to baseline. Oral treatment with 2,5-hexanedione (HD) (1% in drinking water) caused a similar increase in plasma levels; this increase was statistically significant also when compared with pair-fed (PF) control rats. A sucrose density gradient analysis showed only one peak of AChE activity at approximately 10 S (as in normal plasma). The levels of butyrylcholinesterase were unaltered in plasma of both n-hexane-and HD-treated rats. Both the fast-contracting EDL and the slow-contracting soleus muscles lost weight in HD-treated rats with respect to free-fed (AL) and PF controls. AChE levels responded differently to HD treatment in the two muscle types: in EDL total extracts, AChE activity increased considerably with respect to AL controls (+ 70%, p less than 0.001), while the levels of the 16 S and 4 S molecular forms were unaltered. The increased levels of AChE found in plasma of rats intoxicated with n-hexane or with its metabolite HD may originate from muscle and correspond to an increased secretion of this molecular form.

Factor analysis of the interpersonal trust scale with a noncollege population.

This study tested the invariance of the factorial structure of Rotter's Interpersonal Trust Scale (ITS) in a noncollege population. Exploratory factor analysis of the responses of 214 volunteers yielded three factors interpreted as Exploitation, Sincerity, and Institutional Trust. This factor solution was cross-validated in a confirmation sample of 196 volunteers. Cosines between corresponding factors were high across samples and across sex. The similarity was pointed out between the present factor structure and the results of earlier studies with college students. Implications for possible refinement of the ITS were discussed.