Deep carbon export from a Southern Ocean iron-fertilized diatom bloom.

Fertilization of the ocean by adding iron compounds has induced diatom-dominated phytoplankton blooms accompanied by considerable carbon dioxide drawdown in the ocean surface layer. However, because the fate of bloom biomass could not be adequately resolved in these experiments, the timescales of carbon sequestration from the atmosphere are uncertain. Here we report the results of a five-week experiment carried out in the closed core of a vertically coherent, mesoscale eddy of the Antarctic Circumpolar Current, during which we tracked sinking particles from the surface to the deep-sea floor. A large diatom bloom peaked in the fourth week after fertilization. This was followed by mass mortality of several diatom species that formed rapidly sinking, mucilaginous aggregates of entangled cells and chains. Taken together, multiple lines of evidence-although each with important uncertainties-lead us to conclude that at least half the bloom biomass sank far below a depth of 1,000 metres and that a substantial portion is likely to have reached the sea floor. Thus, iron-fertilized diatom blooms may sequester carbon for timescales of centuries in ocean bottom water and for longer in the sediments.

Adsorption and orientation of the physiological extracellular peptide glutathione disulfide on surface functionalized colloidal alumina particles.

Understanding the interrelation between surface chemistry of colloidal particles and surface adsorption of biomolecules is a crucial prerequisite for the design of materials for biotechnological and nanomedical applications. Here, we elucidate how tailoring the surface chemistry of colloidal alumina particles (d50 = 180 nm) with amino (-NH2), carboxylate (-COOH), phosphate (-PO3H2) or sulfonate (-SO3H) groups affects adsorption and orientation of the model peptide glutathione disulfide (GSSG). GSSG adsorbed on native, -NH2-functionalized, and -SO3H-functionalized alumina but not on -COOH- and -PO3H2-functionalized particles. When adsorption occurred, the process was rapid (≤5 min), reversible by application of salts, and followed a Langmuir adsorption isotherm dependent on the particle surface functionalization and ζ potential. The orientation of particle bound GSSG was assessed by the release of glutathione after reducing the GSSG disulfide bond and by ζ potential measurements. GSSG is likely to bind via the carboxylate groups of one of its two glutathionyl (GS) moieties onto native and -NH2-modified alumina, whereas GSSG is suggested to bind to -SO3H-modified alumina via the primary amino groups of both GS moieties. Thus, GSSG adsorption and orientation can be tailored by varying the molecular composition of the particle surface, demonstrating a step toward guiding interactions of biomolecules with colloidal particles.

The antiretroviral protease inhibitors indinavir and nelfinavir stimulate Mrp1-mediated GSH export from cultured brain astrocytes.

Combinations of antiretroviral drugs are successfully used for the treatment of acquired immune deficiency syndrome and reduce the incidence of severe human immunodeficiency virus (HIV)-associated dementia. To test whether such drugs affect the GSH metabolism of brain cells, we have exposed astrocyte-rich primary cultures to various antiretroviral compounds. Treatment of the cultures with the protease inhibitors indinavir or nelfinavir in low micromolar concentrations resulted in a time- and concentration-dependent depletion of cellular GSH from viable cells which was accompanied by a matching increase in the extracellular GSH content. In contrast, the reverse transcriptase inhibitors zidovudine, lamivudine, efavirenz or nevirapine did not alter cellular or extracellular GSH levels. Removal of indinavir from the medium by washing the cells terminated the stimulated GSH export immediately, while the nelfinavir-induced accelerated GSH export was maintained even after removal of nelfinavir. The stimulation of the GSH export from viable astrocytes by indinavir or nelfinavir was completely prevented by the application of MK571, an inhibitor of the multidrug resistance protein 1. These data demonstrate that indinavir and nelfinavir stimulate multidrug resistance protein 1-mediated GSH export from viable astrocytes and suggest that treatment of patients with such inhibitors may affect the GSH homeostasis in brain.

Characterisation and metabolism of astroglia-rich primary cultures from cathepsin K-deficient mice.

Cathepsin K is important for the brain, because its deficiency in mice is associated with a marked decrease in differentiated astrocytes and changes in neuronal patterning in the hippocampus as well as with learning and memory deficits. As cathepsin K activity is most prominent in hippocampal regions of wild type animals, we hypothesised alterations in astrocyte-mediated support of neurons as a potential mechanism underlying the impaired brain functions in cathepsin K-deficient mice. To address this hypothesis, we have generated and characterised astroglia-rich primary cell cultures from cathepsin K-deficient and wild type mice and compared these cultures for possible changes in metabolic support functions and cell composition. Interestingly, cells expressing the oligodendrocytic markers myelin-associated glycoprotein and myelin basic protein were more frequent in astroglia-rich cultures from cathepsin K-deficient mice. However, cell cultures from both genotypes were morphologically comparable and similar with respect to glucose metabolism. In addition, specific glutathione content, glutathione export and γ-glutamyl-transpeptidase activity remained unchanged, whereas the specific activities of glutathione reductase and glutathione-S-transferase were increased by around 50% in cathepsin K-deficient cultures. Thus, lack of cathepsin K in astroglia-rich cultures appears not to affect metabolic supply functions of astrocytes but to facilitate the maturation of oligodendrocytes.

Upregulation of metallothioneins after exposure of cultured primary astrocytes to silver nanoparticles.

To test for the prolonged consequences of a short transient exposure of astrocytes to silver nanoparticles (AgNP), cultured primary astrocytes were incubated for 4 h in the presence of AgNP and the cell viability as well as various metabolic parameters were investigated during a subsequent incubation in AgNP-free medium. Acute exposure of astrocytes to AgNP led to a concentration-dependent increase in the specific cellular silver content to up to 46 nmol/mg protein, but did not compromise cell viability. During a subsequent incubation of the cells in AgNP-free medium, the cellular silver content of AgNP-treated astrocytes remained almost constant for up to 7 days. The cellular presence of AgNP did neither induce any delayed cell toxicity nor were alterations in cellular glucose consumption, lactate production or in the cellular ratio of glutathione to glutathione disulfide observed. However, Western blot analysis and immunocytochemical staining revealed that AgNP-treated astrocytes strongly upregulated the expression of metallothioneins. These results demonstrate that a prolonged presence of accumulated AgNP does not compromise the viability and the basal metabolism of cultured astrocytes and suggest that the upregulation of metallothioneins may help to prevent silver-mediated toxicity that could be induced by AgNP-derived silver ions.

Adsorption and reduction of glutathione disulfide on α-Al2O3 nanoparticles: experiments and modeling.

Glutathione disulfide (GSSG; γ-GluCysGly disulfide) was used as a physiologically relevant model molecule to investigate the fundamental adsorption mechanisms of polypeptides onto α-alumina nanoparticles. Its adsorption/desorption behavior was studied by enzymatic quantification of the bound GSSG combined with zeta potential measurements of the particles. The adsorption of GSSG to alumina nanoparticles was rapid, was prevented by alkaline pH, was reversed by increasing ionic strength, and followed a nearly ideal Langmuir isotherm with a standard Gibbs adsorption energy of -34.7 kJ/mol. Molecular dynamics simulations suggest that only one of the two glutathionyl moieties contained in GSSG binds stably to the nanoparticle surface. This was confirmed experimentally by the release of GSH from the bound GSSG upon reducing its disulfide bond with dithiothreitol. Our data indicate that electrostatic interactions via the carboxylate groups of one of the two glutathionyl moieties of GSSG are predominantly responsible for the binding of GSSG to the alumina surface. The results and conclusions presented here can provide a base for further experimental and modeling studies on the interactions of biomolecules with ceramic materials.

Metabolic and physiological responses in tissues of the long-lived bivalve Arctica islandica to oxygen deficiency.

In Arctica islandica, a long lifespan is associated with low metabolic activity, and with a pronounced tolerance to low environmental oxygen. In order to study metabolic and physiological responses to low oxygen conditions vs. no oxygen in mantle, gill, adductor muscle and hemocytes of the ocean quahog, specimens from the German Bight were maintained for 3.5 days under normoxia (21 kPa=controls), hypoxia (2 kPa) or anoxia (0 kPa). Tissue levels of anaerobic metabolites octopine, lactate and succinate as well as specific activities of octopine dehydrogenase (ODH) and lactate dehydrogenase (LDH) were unaffected by hypoxic incubation, suggesting that the metabolism of A. islandica remains fully aerobic down to environmental oxygen levels of 2 kPa. PO(2)-dependent respiration rates of isolated gills indicated the onset of metabolic rate depression (MRD) below 5 kPa in A. islandica, while anaerobiosis was switched on in bivalve tissues only at anoxia. Tissue-specific levels of glutathione (GSH), a scavenger of reactive oxygen species (ROS), indicate no anticipatory antioxidant response takes place under experimental hypoxia and anoxia exposure. Highest specific ODH activity and a mean ODH/LDH ratio of 95 in the adductor muscle contrasted with maximal specific LDH activity and a mean ODH/LDH ratio of 0.3 in hemocytes. These differences in anaerobic enzyme activity patterns indicate that LDH and ODH play specific roles in different tissues of A. islandica which are likely to economize metabolism during anoxia and reoxygenation.

2-deoxyribose deprives cultured astrocytes of their glutathione.

High concentrations of 2-deoxy-D-ribose (2dRib) have been reported to cause oxidative stress and to disturb the glutathione (GSH) metabolism of various cell types. Exposure of astrocyte-rich primary cultures to millimolar concentrations of 2dRib or its stereoisomer 2-deoxy-L-ribose, but not the incubation with ribose, 2-deoxyglucose, glucose, fructose or saccharose, lowered the cellular GSH content in a time and concentration dependent manner. After exposure for 4 h to 30 mM 2dRib the cells contained 2dRib in a concentration of about 24 mM. Under these conditions 2dRib did not compromise cell viability and the ability of the cells to synthesise GSH, nor were the cellular ratio of glutathione disulfide (GSSG) to GSH and the extracellular concentrations of GSH or GSSG increased. These data demonstrate that 2dRib deprives viable cultured astrocytes of GSH and suggest that a cellular reaction of GSH with 2dRib or its metabolites is involved in the deprivation of astrocytic GSH.

Sustained hydrogen peroxide stress decreases lactate production by cultured astrocytes.

Oxidative stress and disrupted energy metabolism are common to many pathological conditions of the brain. Because astrocytes play an important role in the glucose metabolism of the brain, we have investigated whether sustained oxidative stress affects astroglial glucose metabolism with cultured primary rat astrocytes as a model system. Cultured astrocytes were exposed to a sustained concentration of approximately 50 muM H(2)O(2) in the presence of [U-(13)C]glucose, and cellular and extracellular contents of lactate and glucose were analysed by enzymatic assays and NMR spectroscopy. Exposure of the cells to sustained H(2)O(2) stress for up to 120 min significantly lowered the rate of lactate accumulation in the media to 61% +/- 14% of that in cultures incubated without peroxide. In addition, the ratio of lactate release to glucose consumption was lowered in peroxide-treated astrocytes to 77% +/- 13% of that in control cells, and the specific activity of glyceraldehyde-3-phosphate dehydrogenase had declined to about 10% of control cells within 90 min. In addition, the (13)C enrichment of intracellular and extracellular [(13)C]lactate was about 30% and 95%, respectively, and was not affected by the presence of peroxide, demonstrating that two metabolic pools of lactate are present in cultured astrocytes. The decreased rate of lactate production by astrocytes that have been exposed to peroxide stress is a new example of an alteration by oxidative stress of an important metabolic pathway in astrocytes. Such alterations could contribute to the pathological conditions that have been connected with oxidative stress and disrupted energy metabolism in the brain.

Copper export from cultured astrocytes.

Copper is an essential trace metal that is required as a catalytic co-factor or a structural component of several important enzymes. However, since excess of copper can also harm cells due to its potential to catalyse the generation of toxic reactive oxygen species, transport of copper and the cellular copper content are tightly regulated. Astrocytes are known to efficiently take up copper ions, but it was not known whether these cells are also able to export copper. Treatment of astrocyte-rich primary cultures for 24 h with copper chloride caused a concentration-dependent increase in the specific cellular copper content. During further 24 h incubation in the absence of copper chloride, the copper-loaded astrocytes remained viable and released up to 45% of the accumulated copper. The rate of copper export was proportional to the amount of cellular copper, was almost completely prevented by lowering the incubation temperature to 4 °C and was partly prevented by the endocytosis inhibitor amiloride. Copper export is most likely mediated by the copper ATPase ATP7A, since this transporter is expressed in astrocyte cultures and its cellular location is strongly affected by the absence or the presence of extracellular copper. The potential of cultured astrocytes to export copper suggests that astrocytes provide neighbouring cells in brain with this essential trace element.

Magnetic field-induced acceleration of the accumulation of magnetic iron oxide nanoparticles by cultured brain astrocytes.

Magnetic iron oxide nanoparticles (Fe-NPs) are considered for various biomedical and neurobiological applications that involve the presence of external magnetic fields. However, little is known on the effects of a magnetic field on the uptake of such particles by brain cells. Cultured brain astrocytes accumulated dimercaptosuccinate-coated Fe-NP in a time-, temperature-, and concentration-dependent manner. This accumulation was strongly enhanced by the presence of the magnetic field generated by a permanent neodymium iron boron magnet that had been positioned below the cells. The magnetic field-induced acceleration of the accumulation of Fe-NP increased almost proportional to the strength of the magnetic field applied, increasing the cellular-specific iron content from an initial 10 nmol/mg protein within 4 h of incubation at 37°C to up to 12,000 nmol/mg protein. However, presence of a magnetic field also increased the amounts of iron that attached to the cells during incubation with Fe-NP at 4°C. These results suggest that the presence of an external magnetic field promotes in cultured astrocytes both the binding of Fe-NP to the cell membrane and the internalization of Fe-NP.

Formaldehyde induces rapid glutathione export from viable oligodendroglial OLN-93 cells.

Formaldehyde is a neurotoxic environmental pollutant that can also be produced in the body by certain enzymatic reactions. To test for the potential consequences of an exposure of oligodendrocytes to formaldehyde, we used OLN-93 cells as a model system. Treatment with formaldehyde altered the cellular glutathione (GSH) content of these cells by inducing a rapid time- and concentration-dependent export of GSH. Half-maximal effects were observed for a formaldehyde concentration of about 0.2 mM. While the basal GSH efflux from OLN-93 cells was negligible even when the cellular GSH content was doubled by pre-incubation of the cells with cadmium chloride, the formaldehyde-stimulated export increased almost proportionally to the cellular GSH content. In addition, the stimulated GSH export required the presence of formaldehyde and was almost completely abolished after removal of the aldehyde. Analysis of kinetic parameters of the formaldehyde-induced GSH export revealed similar K(m) and V(max) values of around 100 nmol/mg and 40 nmol/(hmg), respectively, for both OLN-93 cells and cultured astrocytes. The transporter responsible for the formaldehyde-induced GSH export from OLN-93 cells is most likely the multidrug resistance protein 1 (Mrp1), since this transporter is expressed in these cells and since the inhibitor MK571 completely prevented the formaldehyde-induced GSH export. The rapid export of GSH from formaldehyde-treated viable oligodendroglial cells is likely to compromise the cellular antioxidative and detoxification potential which may contribute to the known neurotoxicity of formaldehyde.

Effects of chlorinated acetates on the glutathione metabolism and on glycolysis of cultured astrocytes.

The chlorinated acetates monochloroacetate (MCA), dichloroacetate (DCA), and trichloroacetate (TCA) are generated in water disinfection processes and are formed during metabolic detoxification of industrial solvents such as trichloroethylene. In order to test for consequences of an exposure of brain cells to the different chlorinated acetates, glutathione levels and lactate production of primary astrocyte cultures were investigated as indicators for the potential of chlorinated acetates to disturb cellular detoxification processes and glucose metabolism, respectively. Application of MCA to cultured astrocytes caused a time and concentration dependent deprivation of cellular glutathione, inactivation of glyceraldehyde-3-phosphate dehydrogenase (GAPDH) activity, and loss in cell viability with halfmaximal effects observed for MCA concentrations between 0.3 and 3 mM. In contrast, the presence of acetate, DCA, or TCA in a concentration of 10 mM did not compromise cell viability nor affect cellular glutathione content or GAPDH activity. However, the presence of DCA and TCA significantly lowered the rate of cellular lactate production in viable astrocytes. These data demonstrate that the extent of chlorination strongly determines the potential of chlorinated acetates to disturb glutathione and/or glucose metabolism of astrocytes.

Exploring uncoupling proteins and antioxidant mechanisms under acute cold exposure in brains of fish.

Exposure to fluctuating temperatures accelerates the mitochondrial respiration and increases the formation of mitochondrial reactive oxygen species (ROS) in ectothermic vertebrates including fish. To date, little is known on potential oxidative damage and on protective antioxidative defense mechanisms in the brain of fish under cold shock. In this study, the concentration of cellular protein carbonyls in brain was significantly increased by 38% within 1 h after cold exposure (from 28 °C to 18 °C) of zebrafish (Danio rerio). In addition, the specific activity of superoxide dismutase (SOD) and the mRNA level of catalase (CAT) were increased after cold exposure by about 60% (6 h) and by 60%-90% (1 and 24 h), respectively, while the specific glutathione content as well as the ratio of glutathione disulfide to glutathione remained constant and at a very low level. In addition, cold exposure increased the protein level of hypoxia-inducible factor (HIF) by about 50% and the mRNA level of the glucose transporter zglut3 in brain by 50%-100%. To test for an involvement of uncoupling proteins (UCPs) in the cold adaptation of zebrafish, five UCP members were annotated and identified (zucp1-5). With the exception of zucp1, the mRNA levels of the other four zucps were significantly increased after cold exposure. In addition, the mRNA levels of four of the fish homologs (zppar) of the peroxisome proliferator-activated receptor (PPAR) were increased after cold exposure. These data suggest that PPARs and UCPs are involved in the alterations observed in zebrafish brain after exposure to 18°C. The observed stimulation of the PPAR-UCP axis may help to prevent oxidative damage and to maintain metabolic balance and cellular homeostasis in the brains of ectothermic zebrafish upon cold exposure.

Fumaric acid diesters deprive cultured primary astrocytes rapidly of glutathione.

Fumaric acid esters (FAE) are used for the systemic therapy of psoriasis and are now considered for the treatment of autoimmune-based neurological disorders such as multiple sclerosis. Currently, the cellular metabolism of FAE as well as the mechanisms of their therapeutic action are poorly understood. Since cellular glutathione (GSH) is involved in the detoxification of xenobiotics, we analysed the consequences of an application of FAE on the content of GSH in brain cells using astroglia-rich primary cultures as model system. Micromolar concentrations of dimethyl fumarate (DMF) or diethyl fumarate (DEF) lowered the cellular GSH content in a time- and concentration-dependent manner. Halfmaximal effects after 60 min of incubation were observed for 10 microM DMF or DEF. In contrast to the diesters, monomethyl fumarate (MMF), monoethyl fumarate (MEF) or fumarate had to be applied in concentrations of 10 mM for 60 min to significantly lower the cellular GSH content. During 60 min exposure, DMF or DEF did not significantly affect the cell viability, increase the cellular content of glutathione disulfide, nor altered the specific activities of glucose-6-phosphate dehydrogenase, glutathione reductase, or lactate dehydrogenase. After removal of DMF or DEF, cultured astrocytes restored their cellular GSH content completely within 4h. These data demonstrate that acute exposure to fumaric acid diesters deprives astrocytes of their GSH, most likely by the reaction of the reactive alpha,beta-unsaturated diesters with GSH.

Zinc prevents the copper-induced damage of cultured astrocytes.

Copper is essential for several cellular processes, but an excess of cellular copper is known to be cell toxic. To study the consequences of a copper treatment of astrocytes, we have used astrocyte-rich primary cultures as model system to investigate cellular functions and cellular integrity of these cells after application of micromolar concentrations of copper chloride. After exposure of the cells to copper, the cell-associated copper content increased strongly in a time and concentration dependent manner. While incubation of cultured astrocytes with 3 microM copper hardly affected the cells during incubation for up to 4h, presence of 10 microM or 30 microM copper severly compromised cellular functions as demonstrated by a loss in total and soluble protein contents, a lowered MTT reduction capacity, lowered activities of the enzymes lactate dehydrogenase, glucose-6-phosphate dehydrogenase and glutathione reductase, a lowered cellular glutathione content, an increased lipid peroxidation, and an elevated membrane permeability for propidium iodide. Presence of an excess of zinc inhibited cellular copper accumulation and prevented most of the detrimental consequences of a copper exposure, suggesting that the beneficial effect of zinc against the copper-induced impairment of cultured astrocytes is mediated by inhibition of the cellular copper accumulation.

Fumaric acid dialkyl esters deprive cultured rat oligodendroglial cells of glutathione and upregulate the expression of heme oxygenase 1.

Fumaric acid esters (FAE) are currently tested in clinical studies for their potential to treat multiple sclerosis. Since cellular glutathione is involved in the detoxification of xenobiotics and has been reported to form conjugates with FAE, we have analysed the consequences of an application of various FAE to oligodendroglial cells, using the oligodendroglial cell line OLN-93 and oligodendroglia-rich secondary cultures as model systems. In a concentration of 100 microM, dimethylfumarate (DMF) and diethylfumarate (DEF), but not fumarate nor the monoalkyl esters monomethylfumarate or monoethylfumarate, almost completely deprived both OLN-93 cells and secondary oligodendroglial cultures within 60 min of their cellular glutathione. None of the FAE applied compromised cell viability, nor did a treatment with DMF or DEF cause any extracellular accumulation of glutathione. Half-maximal effects on the cellular glutathione content of OLN-93 cells after 60 min of incubation were observed in the presence of 10 microM DMF or DEF. In contrast, fumaric acid monoalkyl esters had to be applied in millimolar concentrations to decrease the cellular glutathione content significantly within 60 min. After removal of DMF, OLN-93 cells completely restored their cellular glutathione content and strongly upregulated heme oxygenase 1. Thus, alterations in glutathione and heme oxygenase metabolism have to be considered when oligodendrocytes are exposed to fumaric acid dialkyl esters.

Differential effects of iodoacetamide and iodoacetate on glycolysis and glutathione metabolism of cultured astrocytes.

Iodoacetamide (IAA) and iodoacetate (IA) have frequently been used to inhibit glycolysis, since these compounds are known for their ability to irreversibly inhibit the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH). However, the consequences of a treatment with such thiol reagents on the glutathione (GSH) metabolism of brain cells have not been explored. Exposure of astroglia-rich primary cultures to IAA or IA in concentrations of up to 1 mM deprived the cells of GSH, inhibited cellular GAPDH activity, lowered cellular lactate production and caused a delayed cell death that was detectable after 90 min of incubation. However, the two thiol reagents differed substantially in their potential to deprive cellular GSH and to inhibit astrocytic glycolysis. IAA depleted the cellular GSH content more efficiently than IA as demonstrated by half-maximal effects for IAA and IA that were observed at concentrations of about 10 and 100 muM, respectively. In contrast, IA was highly efficient in inactivating GAPDH and lactate production with half-maximal effects observed already at a concentration below 100 muM, whereas IAA had to be applied in 10 times higher concentration to inhibit lactate production by 50%. These substantial differences of IAA and IA to affect GSH content and glycolysis of cultured astrocytes suggest that in order to inhibit astrocytic glycolysis without substantially compromising the cellular GSH metabolism, IA - and not IAA - should be used in low concentrations and/or for short incubation periods.