Sphingosine and Other Long-Chain Bases That Alter Cell Behavior

Normal and Dysregulated Sphingolipid Metabolism: Contributions to Podocyte Injury and Beyond

Podocyte health is vital for maintaining proper glomerular filtration in the kidney. Interdigitating foot processes from podocytes form slit diaphragms which regulate the filtration of molecules through size and charge selectivity. The abundance of lipid rafts, which are ordered membrane domains rich in cholesterol and sphingolipids, near the slit diaphragm highlights the importance of lipid metabolism in podocyte health. Emerging research shows the importance of sphingolipid metabolism to podocyte health through structural and signaling roles. Dysregulation in sphingolipid metabolism has been shown to cause podocyte injury and drive glomerular disease progression. In this review, we discuss the structure and metabolism of sphingolipids, as well as their role in proper podocyte function and how alterations in sphingolipid metabolism contributes to podocyte injury and drives glomerular disease progression.

Ceramide stabilizes beta-site amyloid precursor protein-cleaving enzyme 1 and promotes amyloid beta-peptide biogenesis

The lipid second messenger ceramide regulates several biochemical events that occur during aging. In addition, its level is highly elevated in the amyloid-burdened brains of Alzheimer's disease patients. Here, we analyzed the impact of aberrant ceramide levels on amyloid beta-peptide (Abeta) generation by using a cell-permeable analog of ceramide, C6-ceramide, and several biochemical inhibitors of the sphingomyelin/glycosphingolipid biosynthetic pathway. We found that C6-ceramide increased the biogenesis of Abeta by affecting beta-but not gamma-cleavage of the amyloid precursor protein. Similarly to C6-ceramide, increased levels of endogenous ceramide induced by neutral sphingomyelinase treatment also promoted the biogenesis of Abeta. Conversely, fumonisin B1, which inhibits the biosynthesis of endogenous ceramide, reduced Abeta production. Exogenous C6-ceramide restored both intracellular ceramide levels and Abeta generation in fumonisin B1-treated cells. These events were specific for amyloid precursor protein and were not associated with apoptotic cell death. Pulse-chase and time-course degradation experiments showed that ceramide post-translationally stabilizes the beta-secretase BACE1. Taken together, these data indicate that the lipid second messenger ceramide, which is elevated in the brains of Alzheimer's disease patients, increases the half-life of BACE1 and thereby promotes Abeta biogenesis.

Regulation of fatty acid biosynthesis as a possible mechanism for the mitoinhibitory effect of fumonisin B1 in primary rat hepatocytes

The mitoinhibitory effect of fumonisin B1 (FB1) on the mitogenic response of epidermal growth factor (EGF) was investigated in primary hepatocyte cultures with respect to the alterations in the omega6 fatty acid metabolic pathway. Fatty acid analyses of hepatocytes showed that EGF treatment resulted in a significant decrease in the relative levels of 20:4omega6 (arachidonic acid) and an increase in 18:2omega6 (linoleic acid). Supplementation of the hepatocyte cultures with 20:4omega6 in the absence of EGF resulted in an increase in the total omega6 and omega6/omega3 fatty acid ratio. Addition of 20:5omega3 (eicosapentaenoic acid) resulted in an increase of the relative levels of the long chain omega3 fatty acids at the expense of the omega6 fatty acids. When 20:4omega6 and 20:5omega3 was added in the presence of EGF, the mitogenic response of EGF was increased and decreased respectively. When compared to the fatty acid profiles in the absence of EGF, the decreased mitogenic response coincided with a decrease of total omega6 fatty acids and total polyunsaturated fatty acids (PUFA). In addition, the saturated and mono-unsaturated fatty acids increased and the polyunsaturated/saturated (P/S) fatty acid ratio decreased which implied a more rigid membrane structure. Addition of prostaglandin E2 (PGE2) and prostaglandin E1 (PGE1) stimulated and inhibited the mitogenic response respectively. Ibuprofen, a known cyclooxygenase inhibitor, and FB1 inhibited the EGF-induced mitogenic response in a dose-dependent manner. The mitoinhibitory effect of FB1 on the EGF response was counteracted by the addition of PGE2. FB1 also disrupts the omega6 fatty acid metabolic pathway in primary hepatocytes, resulting in the accumulation of C18:2omega6 in phospatidylcholine and triacylglicerol. The disruption of the omega6 fatty acid metabolic pathway and/or prostaglandin synthesis is likely to be an important event in the mitoinhibitory effect of FB1 on growth factor responses.

The formation of ceramide-1-phosphate during neutrophil phagocytosis and its role in liposome fusion

Ceramide, a product of agonist-stimulated sphingomyelinase activation, is known to be generated during the phagocytosis of antibody-coated erythrocytes by polymorphonuclear leukocytes. Agonist-stimulated formation of ceramide-1-phosphate is now shown to occur in 32PO4-labeled neutrophils. Ceramide-1-phosphate is formed by a calcium-dependent ceramide kinase, found predominately in the neutrophil plasma membrane. The neutrophil kinase is specific for ceramide because, in contrast to the bacterial diglyceride kinase, ceramide is not phosphorylated under conditions specific for diglyceride phosphorylation. Conversely, 1,2-diacylglycerol does not serve as substrate for the neutrophil ceramide kinase. Ceramide kinase activation occurs in a time-dependent fashion, reaching peak activity 10 min after formyl peptide stimulation and challenge with antibody-coated erythrocytes. The lipid kinase activity is optimal at pH 6.8. Because the formation of the phagolysosome is a critical event in phagocytosis, the effect of ceramide-1-phosphate in promoting the fusion of liposomes was determined. Both the addition of increasing concentrations of sphingomyelinase D and ceramide-1-phosphate promoted liposomal fusion. In summary, ceramide-1-phosphate is formed during phagocytosis through activation of ceramide kinase. Ceramide-1-phosphate may promote phagolysosome formation.

Metabolic fate of exogenous sphingosine in neuroblastoma neuro2A cells. Dose-dependence and biological effects

The possible relationship between metabolism and biological effects of sphingosine was investigated in Neuro2a cells. [C3-3H]-sphingosine, administered at different doses (80 pmol-80 nmol/mg cell protein). Amounts up to hundredfold were rapidly taken up and metabolized, the intracellular content of sphingosine being processed within 2 h. At low doses, [3H]-sphingosine represented a minor portion of the cellular radiolabel, and N-acylated metabolites, particularly ceramide, prevailed over degradation products. Neuro2a cell differentiation took place in conjunction with ceramide increase. At increasing exogenous sphingosine/cell ratio, the acylation process became saturated while sphingosine degradation increased proportionally. From this point on [3H]-sphingosine accumulated and cell toxicity occurred. In conclusion, in Neuro2a cells the biological effects exerted by exogenous sphingosine are strictly connected to the exogenous sphingosine/cell ratio and to the capacity of the cell to metabolize sphingosine.

Chemoenzymatic Synthesis of All Four Stereoisomers of Sphingosine from Chlorobenzene: Glycosphingolipid Precursors(1)(a)

Advantageous use of homochiral cyclohexadiene-cis-1,2-diol 2, available by means of biocatalytic oxidation of chlorobenzene with toluene dioxygenase, has enabled the synthesis of all four enantiomerically pure C(18)-sphingosines 1. The four requisite diastereomers of azido alcohols 4a-d were accessed by regioselective opening of epoxides 7 and 8 with either azide or halide ions. The configuration of C4 and C5 in azides 4 defines the stereochemistry of the incipient sphingosine chain, liberated from 4 by the oxidative cleavage of the C1-C6 olefin. For L-threo-sphingosine (1b), lactol 20b generated by this cleavage was converted by periodate oxidation to azido deoxy L-threose 22b, which gave 1b upon Wittig olefination and reduction. Similarly, D-erythro-sphingosine (1a) and L-erythro-sphingosine (1c) were generated from 4a,c, respectively. The last sphingosine (1d) was synthesized from the silyl-protected azido alcohol 29d. Subsequent transformations provided silyl-protected azido deoxy D-threose 32d, which upon Wittig olefination and reduction gave D-threo-sphingosine (1d). Experimental and spectral data are provided for all new compounds.

Differential roles of de novo sphingolipid biosynthesis and turnover in the "burst" of free sphingosine and sphinganine, and their 1-phosphates and N-acyl-derivatives, that occurs upon changing the medium of cells in culture

Long-chain (sphingoid) bases are highly bioactive intermediates for sphingolipid metabolism, yet relatively little is known about how the amounts of these compounds are regulated. This study used J774A.1 cells to characterize the "burst" of sphinganine and sphingosine, or the transient increase of up to 10-fold in long-chain base mass, that occurs when cells in culture are changed to fresh medium. The increase in sphinganine was attributable to de novo sphingolipid biosynthesis because: 1) there is increased incorporation of [3H]serine and [3H]palmitate into sphinganine; 2) the incorporation of [3H]serine was equivalent to the increase in sphinganine mass; 3) beta-F-alanine, an inhibitor of serine palmitoyltransferase, blocked the sphinganine burst; 4) the magnitude of the burst depended on the concentration of serine in the medium, which is known to affect long-chain base biosynthesis; and 5) the appearance of sphinganine was relatively unaffected by lyso-osmotrophic agents (NH4Cl and chloroquine) that blocked sphingolipid hydrolysis in these cells. In contrast, the sphingosine burst arose mainly from turnover of complex sphingolipids because no incorporation of [3H]serine or [3H]palmitate into sphingosine was detected; sphingosine mass was not affected by beta-F-alanine or the serine concentration; and, the burst could be followed by the release of sphingosine and ceramide from complex sphingolipids (especially sphingomyelin) in a process that was inhibited by NH4Cl and chloroquine. Additionally, the fate of these long-chain bases differed: sphinganine was mostly (80-85%) acylated and incorporated into dihydroceramide and complex sphingolipids, whereas most of the sphingosine (70%) was phosphorylated and degraded, with incorporation of the resulting ethanolamine phosphate into phosphatidylethanolamine. Sphinganine, however, could be diverted toward degradation by adding an inhibitor of N-acylation (fumonisin B1). In accounting for the elevation in sphingosine and sphinganine after cells are changed to new medium, these studies have provided fundamental information about long-chain base metabolism. The existence of differential changes in sphinganine and sphingosine, as well as their 1-phosphates and N-acyl-derivatives, should be considered when evaluating the roles of sphingolipid metabolites in cell regulation.