Progressive hypoxia inhibits the de novo synthesis of galactosylceramide in cultured oligodendrocytes

Cross-Regulation of the Cellular Redox System, Oxygen, and Sphingolipid Signalling

Redox-active mediators are now appreciated as powerful molecules to regulate cellular dynamics such as viability, proliferation, migration, cell contraction, and relaxation, as well as gene expression under physiological and pathophysiological conditions. These molecules include the various reactive oxygen species (ROS), and the gasotransmitters nitric oxide (NO∙), carbon monoxide (CO), and hydrogen sulfide (H2S). For each of these molecules, direct targets have been identified which transmit the signal from the cellular redox state to a cellular response. Besides these redox mediators, various sphingolipid species have turned out as highly bioactive with strong signalling potential. Recent data suggest that there is a cross-regulation existing between the redox mediators and sphingolipid molecules that have a fundamental impact on a cell’s fate and organ function. This review will summarize the effects of the different redox-active mediators on sphingolipid signalling and metabolism, and the impact of this cross-talk on pathophysiological processes. The relevance of therapeutic approaches will be highlighted.

Silencing of HIF-1alpha by RNA interference in human glioma cells in vitro and in vivo

Higher-grade gliomas are distinguished by increased vascular endothelial cell proliferation and peritumoral edema. These are thought to be instigated by vascular endothelial growth factor, which in turn is regulated by cellular oxygen tension. Hypoxia inducible factor-1alpha (HIF-1alpha) is a main responder to intracellular hypoxia and is overexpressed in many human cancers, including gliomas. Here we present methods for investigating the role of HIF-1alpha in glioma growth in vivo and in vitro using RNA interference in U251, U87, and U373 glioma cells.

Tissue-specific ceramide response in the chronically hypoxic rat model mimicking cyanotic heart disease

BACKGROUND AND OBJECTIVE

Acute hypoxia is associated with apoptosis and increase in ceramide levels in various organs. To assess the effect of chronic hypoxia on ceramide accumulation in the lungs and kidneys, we utilized an animal model mimicking cyanotic heart disease.

METHODS

Rats were placed in a hypoxic environment at birth and oxygen levels were maintained at 10% in an air-tight Plexiglas chamber. Controls remained in room air. Animals were sacrificed and the lung and kidneys were harvested and weighed at 1 and 4 weeks, respectively. Ceramide levels were measured using a modified diacylglycerol kinase assay.

RESULTS

Significant polycythemia developed in the hypoxic rats at 1 and 4 weeks. Indexed lung and kidney masses were significantly increased in the hypoxic animals as compared to controls at 1 and 4 weeks, respectively. The ceramide levels in the hypoxic lungs and kidneys were not significantly different from control groups at 1 and 4 weeks. [Ceramide/phosphate ratio in the kidneys was 1.28 +/- 0.17 (C) versus 1.18 +/- 0.12 (H) at 1 week; P = 0.39, and 1.46 +/- 0.08 (C) versus 1.33 +/- 0.15 (H) at 4 weeks (P = 0.44)] and [ceramide/phosphate ratio (pmol/nmol) in the lungs was 2.29 +/- 0.14 (C) versus 1.98 +/- 0.12 (H) at 1 week (P = 0.17), and 2.42 +/- 0.16 (C) versus 2.30 +/- 0.05 (H) at 4 weeks, P = 0.34].

CONCLUSION

The response of lungs and kidneys to chronic hypoxia includes increase in indexed mass and lack of ceramide accumulation. This is similar to the response previously reported in the chronically hypoxic brain and heart. Thus, various organs appear to have similar ceramide response pattern to chronic hypoxia.

Hypoxia-induced cell death in human malignant glioma cells: energy deprivation promotes decoupling of mitochondrial cytochrome c release from caspase processing and necrotic cell death

Hypoxia induces apoptosis in primary and transformed cells and in various tumor cell lines in vitro. In contrast, there is little apoptosis and predominant necrosis despite extensive hypoxia in human glioblastomas in vivo. We here characterize ultrastructural and biochemical features of cell death in LN-229, LN-18 and U87MG malignant glioma cells in a paradigm of hypoxia with partial glucose deprivation in vitro. Electron microscopic analysis of hypoxia-challenged glioma cells demonstrated early stages of apoptosis but predominant necrosis. ATP levels declined during hypoxia, but recovered with re-exposure to normoxic conditions unless hypoxia exceeded 8 h. Longer hypoxic exposure resulted in irreversible ATP depletion and delayed cell death. Hypoxia induced mitochondrial release of cytochrome c, but there was no cleavage of caspases 3, 7, 8 or 9, and no DNA fragmentation. Ectopic expression of BCL-XL conferred protection from hypoxia-induced cell death, whereas the overexpression of the antiapoptotic proteins X-linked-inhibitor-of-apoptosis-protein and cytokine response modifier-A had no effect. These findings suggest that glioma cells resist adverse effects of hypoxia until energy stores are depleted and then undergo necrosis rather than apoptosis because of energy deprivation.

Exposure of developing oligodendrocytes to cadmium causes HSP72 induction, free radical generation, reduction in glutathione levels, and cell death

Primary cultures of oligodendrocytes were used to study the toxic effects of cadmium chloride. Cell viability was evaluated by the mitochondrial dehydrogenase activity and confirmed by propidium iodide (PI) fluorescence staining. The expression of the 72 kDa stress protein, HSP72, was assayed by Western blot analysis. The results showed that Cd(2+)-induced toxicity was dependent on the time and dose of exposure, as well as on the developmental stage of the cultures. Oligodendrocyte progenitors were more vulnerable to Cd(2+) toxicity than were mature oligodendrocytes. Mature oligodendrocytes accumulated relatively higher levels of Cd(2+) than did progenitors, as determined by (109)CdCl(2) uptake; treatment with the metal ion caused a more pronounced reduction in intracellular glutathione levels and significantly higher free radical accumulation in progenitors. The latter could explain the observed differences in Cd(2+) susceptibility. HSP72 protein expression was increased both in progenitors and in mature cells exposed to Cd(2+). Pretreatment with N-acetylcysteine, a thiocompound with antioxidant activity and a precursor of glutathione, prevented Cd(2+)-induced (i) reduction in glutathione levels and (ii) induction of HSP72 and diminished (i) Cd(2+) uptake and (ii) Cd(2+)-evoked cell death. In contrast, buthionine sulfoximine, an inhibitor of gamma-glutamyl-cysteine synthetase, depleted glutathione, and potentiated the toxic effect of Cd(2+). These results strongly suggest that Cd(2+)-induced cytotoxicity in oligodendrocytes is mediated by reactive oxygen species and is modulated by glutathione levels.

Caspases determine the vulnerability of oligodendrocytes in the ischemic brain

Although oligodendrocytes (OLGs) are thought to be vulnerable to hypoxia and ischemia, little is known about the detailed mechanism by which these insults induce OLG death. From the clinical viewpoint, it is imperative to protect OLGs as well as neurons against ischemic injury (stroke), because they are the only myelin-forming cells of the central nervous system. Using the Cre/loxP system, we have established a transgenic mouse line that selectively expresses p35, a broad-spectrum caspase inhibitor, in OLGs. After hypoxia, cultured OLGs derived from wild-type mice exhibited significant upregulation of caspase-11 and substantial activation of caspase-3, which led to cell loss. Expression of p35 or elimination of caspase-11 suppressed the caspase-3 activation and conferred significant protection against hypoxic injury. Expression of p35 in OLGs in vivo resulted in significant protection from ischemia-induced cell injury, thus indicating that caspases are involved in the ischemia-induced cell death of OLGs. Furthermore, the induction of caspase-11 was evident in the ischemic brains of wild-type mice, and OLGs exhibited resistance to brain ischemia in mice deficient in caspase-11, suggesting that caspase-11 is critically implicated in the mechanism(s) underlying ischemia-induced OLG death. Caspases may therefore offer a good therapeutic target for reducing ischemia-induced damage to OLGs.

Does ceramide play a role in neural cell apoptosis?

Ceramide is a lipid second messenger, that is generated in response to stimulation of the cell death pathways by a number of ligands binding to surface receptors, growth factor withdrawal, treatment with chemotherapeutic agents, or high doses of ionizing radiation or oxidizing agents. Depending on the target cell, ceramide induces diverse biological responses including apoptosis, cell-cycle arrest, differentiation, and also proliferation. In this review we consider the evidence for its role in apoptosis in cells of the nervous system.

Differential responses of oligodendrocytes to tumor necrosis factor and other pro-apoptotic agents: role of ceramide in apoptosis

Staurosporine induced apoptosis in a human oligodendroglioma cell line (HOG), neonatal rat oligodendrocyte (O2A(+)) precursors, and mature rat oligodendrocytes. In all three cell culture systems, the activation of caspase-3-like activity (CPP32) coincided with the increased formation of ceramide from sphingomyelin and the onset of DNA fragmentation. Further, the addition of exogenous C(2)-ceramide induced CPP32 activation and DNA fragmentation in all three culture systems. Raising endogenous ceramide levels by the addition of the ceramidase inhibitor, oleoylethanolamine, enhanced apoptosis in both a time- and concentration-dependent manner. Inhibitors of phosphatidylinositol 3-kinase (wortmannin and LY294002) also induced caspase-3 (CPP32) activation, increased ceramide formation, induced DNA fragmentation, and reduced cell viability. In contrast, cytokines such as tumor necrosis factor-alpha (TNF-alpha) had a differential effect on the three cell cultures. Thus, TNF-alpha (160 ng/ml) induced 70% apoptosis in 24 hr in freshly isolated rat brain O2A(+) precursor cells, 60% apoptosis in 24 hr in a human oligodendroglioma (HOG) cell line, but no apoptosis in mature neonatal rat oligodendrocytes. Interferon-gamma augmented the activation of CPP32 by TNF-alpha in HOG cells and O2A(+) oligodendrocyte precursor cells but had no effect on mature oligodendrocytes. Thus, the death pathway appears to be similar in the three cell lines but the lack of coupling between TNF-alpha receptors and the apoptotic pathway leads to a lack of response to cytokines in mature oligodendrocytes.

Effects of hypoxia on oligodendrocyte signal transduction

We have previously established that 21-day-old postnatal rat oligodendrocytes, maintained in monolayer culture and subjected to 6 h of hypoxia, show reversible inhibition of synthesis of alpha-hydroxy fatty acid and myelin basic protein but a dramatic induction of a 22-kDa protein, suggesting that this is a good model to study the mechanism of CNS demyelination caused by hypoxic injury. We now report that hypoxia also dramatically inhibits the basal protein kinase C-mediated phosphorylation of myelin basic protein and myelin 2',3'-cyclic nucleotide phosphohydrolase by 80%, but that the inhibition of phosphorylation can be reversed by addition of a protein kinase C activator, phorbol 12-myristate 13-acetate. The mechanism of action appears to involve the uncoupling of signal transduction at a site before phospholipase C, because hypoxia did not affect protein kinase C activity or its translocation to the membrane fraction. The most potent activator of phospholipase C (as measured by inositol phosphate release) was carbachol (muscarinic M1 receptor agonist), followed by L-phenylephrine (alpha 1-adrenergic receptor agonist) in normal oligodendrocytes. Excitatory amino acids and histamine were ineffective. Hypoxia for 6 h completely inhibited both muscarinic and alpha 1-adrenergic receptor-mediated inositol monophosphate release but did not affect phospholipase D-coupled phosphatidylethanol production in response to carbachol. We therefore conclude from this and earlier work that early, reversible changes in oligodendrocyte metabolism result not simply from ATP depletion, but may specifically target GTP binding protein-mediated processes.

Hypoxia induces synthesis of a novel 22-kDa protein in neonatal rat oligodendrocytes

Neonatal (3-day-old) rat oligodendrocytes grown in monolayer culture and exposed to increasingly hypoxic culture conditions showed a dramatic reduction in myelin basic protein synthesis but no significant inhibition of Tran35S-label incorporation into oligodendrocyte proteins in general or into structural proteins such as actin. However, there was a dramatic increase in synthesis of a novel 22-kDa protein. Reoxygenation of cultures reversed the synthesis of the 22-kDa protein, and thiol and calpain protease inhibitors (EP-459 and leupeptin) did not prevent synthesis of the protein, suggesting that it did not result from proteolysis. The 22-kDa protein (which we have called hypoxin) was coimmunoprecipitated by a polyclonal antibody to actin but did not react with the anti-actin antibody on western blots. The synthesis of hypoxin accounted for up to 50% of the Tran35S-label incorporated into immunoprecipitated protein, suggesting that it plays a major role in the cell's response to hypoxia. Subcellular fractionation revealed that the 22-kDa protein was largely associated with the cytosolic/cytoskeletal compartment. However, it is unlikely to be one of the cytoskeleton-associated Rho or Rac low-molecular-mass (20-24 kDa) GTP-binding proteins because it did not bind [alpha-32P]GTP on western blots. Oligodendrocytes did not synthesize a 22-kDa protein in response to heat shock but did synthesize the typical 70- and 90-kDa heat-shock proteins.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of a cell line derived from a human oligodendroglioma

A novel clonal cell line derived from a human glioma (HOG) was found to express some oligodendrocyte-specific proteins including a 15-kDa form of myelin basic protein (MBP) and high 2',3'-cyclic nucleotide 3'-phosphodiesterase (CNPase) activity. Expression of the myelin lipids galactosylceramide and sulfogalactosylceramide (sulfatide) was low. HOG cells did not express the characteristic astrocyte markers glial fibrillary acidic protein (GFAP) or significant glutamine synthetase (GS) activity. After initial plating, HOG cells were flat and epitheloid and thus showed a limited oligodendrocyte-like morphology. However, after cells became more confluent, some cells were phase-bright and elaborated short processes. Receptor types expressed by HOG cells included A2-adenosine, prostaglandin E1 (PGE1), and beta 2-adrenergic receptors (beta-ARs) linked to stimulation of adenylate cyclase, and muscarinic cholinergic and H1-histamine coupled to phosphatidyinositol turnover (Post and Dawson, 1991). HOG cells should therefore provide a useful model for studying the extracellular regulation and phosphorylation of oligodendrocyte-specific proteins.

Hypoxic injury to oligodendrocytes: reversible inhibition of ATP-dependent transport of ceramide from the endoplasmic reticulum to the Golgi

Previous studies have shown that gradual progressive hypoxia specifically inhibits the synthesis of the major myelin lipid galactosylceramide (GalCer) in cultured neonatal rat oligodendrocytes (OLG) (Kendler and Dawson, J Biol Chem 265:12259-12266, 1990). The inhibition of de novo synthesized GalCer (measured by [3H]palmitate incorporation) was accompanied by an increase in the [3H]labeled pool of nonhydroxy fatty acid ceramide, the precursor of GalCer. The decreased galactosylation of NFACer was not due to an inhibition of UDP-Gal:ceramide:galactosyltransferase activity or to a depletion in available UDP-Gal. Analysis of subcellular fractionations of OLG membranes on Percoll gradients indicated that NFA ceramide was accumulating in the endoplasmic reticulum (ER) during hypoxia, suggesting that the transport of NFACer from its site of synthesis (ER) to its site of galactosylation, presumably the Golgi, was blocked by hypoxia. This accumulation of ceramide was replicated by lowering ATP levels to 80-90% of control by treating OLG with 12 nM oligomycin, and was reversed by reoxygenation of the cells. Conversion of [3H]palmitate-labeled NFACer to GalCer in semi-intact OLG required both exogenous UDP-Gal and ATP, further suggesting that the transport of NFACer from the ER to its site of synthesis (cis-Golgi) is an energy-dependent step that is highly susceptible to relatively minor ATP depletion associated with early hypoxic injury. Our results further suggest that ceramide appears to be a good marker for ER and GalCer is a good marker for the cis-Golgi.

Differential sensitivity to hypoxia of the peripheral versus central trajectory of primary afferent axons

Myelinated primary afferent fibers have both peripheral and central nervous system components. As the fibers course through peripheral nerve and dorsal roots they are myelinated by Schwann cells, but after they invade the spinal cord they become myelinated by oligodendrocytes and have associations with astrocytes. This presents the opportunity to compare the pathophysiology of PNS (Schwann cell-associated) vs. CNS (oligodendrocyte/astrocyte-associated) portions of the same axonal trunk located in the dorsal roots and dorsal columns, respectively. Dorsal spinal roots and slices of dorsal columns isolated from adult rats were studied in a sucrose gap chamber from which compound action potential and membrane potential changes could be recorded. The results indicate that the peripheral component of the afferent fibers is resistant to hypoxia as evidenced by stable action and membrane potential when O2 in the bathing medium was completely replaced with N2 for periods up to 2 h. In contrast, the axons become sensitive to hypoxia as they project through the dorsal columns as evidenced by rapid reduction in action potential amplitude accompanied by membrane depolarization when O2 is replaced by N2. This differential response to hypoxia, observed on the same axon branches but over CNS vs. PNS trajectories, suggests that differences related to the extracellular environment or in axo-glial organization in dorsal root vs. dorsal column may confer different degrees of susceptibility to anoxia.