Phosphorylated cis-4-methylsphingosine mimics the mitogenic effect of sphingosine-1-phosphate in Swiss 3T3 fibroblasts

Sphingosine-1-phosphate links glycosphingolipid metabolism to neurodegeneration via a calpain-mediated mechanism

We have recently reported that the bioactive lipid sphingosine-1-phosphate (S1P), usually signaling proliferation and anti-apoptosis induces neuronal death when generated by sphingosine-kinase2 and when accumulation due to S1P-lyase deficiency occurs. In the present study, we identify the signaling cascade involved in the neurotoxic effect of sphingoid-base phosphates. We demonstrate that the calcium-dependent cysteine protease calpain mediates neurotoxicity by induction of the endoplasmic reticulum stress-specific caspase cascade and activation of cyclin-dependent kinase5 (CDK5). The latter is involved in an abortive reactivation of the cell cycle and also enhances tau phosphorylation. Neuroanatomical studies in the cerebellum document for the first time that indeed neurons with abundant S1P-lyase expression are those, which degenerate first in S1P-lyase-deficient mice. We therefore propose that an impaired metabolism of glycosphingolipids, which are prevalent in the central nervous system, might be linked via S1P, their common catabolic intermediate, to neuronal death.

Subcellular origin of sphingosine 1-phosphate is essential for its toxic effect in lyase-deficient neurons

Cerebellar granule cells from sphingosine 1-phosphate (S1P) lyase-deficient mice were used to study the toxicity of this potent sphingolipid metabolite in terminally differentiated postmitotic neurons. Based on earlier findings with the lyase-stable, semi-synthetic, cis-4-methylsphingosine phosphate, we hypothesized that accumulation of S1P above a certain threshold induces neuronal apoptosis. The present studies confirmed this conclusion and further revealed that for S1P to induce apoptosis in lyase-deficient neurons it must also be produced by sphingosine-kinase2 (SK2). These conclusions are based on the finding that incubation of lyase-deficient neurons with either sphingosine or S1P results in a similar elevation in cellular S1P; however, only S1P addition to the culture medium induces apoptosis. This was not due to S1P acting on the S1P receptor but to hydrolysis of S1P to sphingosine that was phosphorylated by the cells, as described before for cis-4-methylsphingosine. Although the cells produced S1P from both exogenously added sphingosine as well as sphingosine derived from exogenous S1P, the S1P from these two sources were not equivalent, because the former was primarily produced by SK1, whereas the latter was mainly formed by SK2 (as also was cis-4-methylsphingosine phosphate), based on studies in neurons lacking SK1 or SK2 activity. Thus, these investigations show that, due to the existence of at least two functionally distinct intracellular origins for S1P, exogenous S1P can be neurotoxic. In this model, S1P accumulated due to a defective lyase, however, this cause of toxicity might also be important in other cases, as illustrated by the neurotoxicity of cis-4-methylsphingosine phosphate.

Chemical tools to investigate sphingolipid metabolism and functions

Sphingolipids comprise an important group of biomolecules, some of which have been shown to play important roles in the regulation of many cell functions. From a structural standpoint, they all share a long 2-amino-1,3-diol chain, which can be either saturated (sphinganine), hydroxylated at C4 (phytosphingosine), or unsaturated at C4 (sphingosine) as in most mammalian cells. N-acylation of sphingosine leads to ceramide, a key intermediate in sphingolipid metabolism that can be enzymatically modified at the C1-OH position to other biologically important sphingolipids, such as sphingomyelin or glycosphingolipids. In addition, both ceramide and sphingosine can be phosphorylated at C1-OH to give ceramide-1-phosphate and sphingosine-1-phosphate, respectively. To better understand the biological and biophysical roles of sphingolipids, many efforts have been made to design synthetic analogues as chemical tools able to unravel their structure-activity relationships, and to alter their cellular levels. This last approach has been thoroughly studied by the development of specific inhibitors of some key enzymes that play an important role in biosynthesis or metabolism of these intriguing lipids. With the above premises in mind, the aim of this review is to collect, in a systematic way, the recent efforts described in the literature leading to the development of new chemical entities specifically designed to achieve the above goals.

Sphingolipid metabolism in neural cells

Sphingolipids were discovered more than a century ago in the brain. Cerebrosides and sphingomyelins were named so because they were first isolated from neural tissue. Although glycosphingolipids and especially those containing sialic acid in their oligosaccharide moiety are particularly abundant in the brain, sphingolipids are ubiquitous cellular membrane components. They form cell- and species-specific profiles at the cell surfaces that characteristically change in development, differentiation, and oncogenic transformation, indicating the significance of these lipid molecules for cell-cell and cell-matrix interactions as well as for cell adhesion, modulation of membrane receptors and signal transduction. This review summarizes sphingolipid metabolism with emphasis on aspects particularly relevant in neural cell types, including neurons, oligodendrocytes and neuroblastoma cells. In addition, the reader is briefly introduced into the methodology of lipid evaluation techniques and also into the putative physiological functions of glycosphingolipids and their metabolites in neural tissue.

Activation of p38 mitogen-activated protein kinase and partial reactivation of the cell cycle by cis-4-methylsphingosine direct postmitotic neurons towards apoptosis

As shown before in three different cell types, cis-4-methylsphingosine is a synthetic, membrane permeable, pro-drug, that is taken up by cells and phosphorylated to a metabolically stable cis-4-methylsphingosine-phosphate. The synthetic compound mimicked the mitogenic effect of sphingosine-1-phosphate (S1P) in Swiss 3T3 fibroblasts, but induced apoptosis in B104 neuroblastoma cells. We now investigated its effect in differentiated primary cultured neurons. In contrast to S1P, which had no effect on growth of these postmitotic cells, cis-4-methylsphingosine-phosphate induced apoptosis. Interestingly, both compounds stimulated extracellular regulated kinase (ERK) and also p38 mitogen-activated protein kinase (MAPK). Additionally, both compounds induced an increased expression of cyclin D1 but not of cyclin E. Our results document that the different physiological effects, apoptosis in the case of the accumulating metabolically stable synthetic compound vs. no apoptosis in the case of the short-living S1P, rely only on nuances of impact. In other words both sphingoid phosphates affect similar pathways albeit in a sustained and more pronounced manner in case of the metabolically stable synthetic compound. Experiments with several pharmacological inhibitors indicate that cis-4-methylsphingosine-phosphate-induced neuronal apoptosis is mediated on the one hand by a caspase dependent and p38 MAPK forwarded pathway and on the other hand by an abortive reactivation of the cell cycle, a caspase independent process.

Metabolism of the unnatural anticancer lipid safingol, L-threo-dihydrosphingosine, in cultured cells

We studied the metabolism of radioactively labeled safingol (l-threo-dihydrosphingosine) in primary cultured neurons, B104 neuroblastoma cells, and Swiss 3T3 fibroblasts, and compared it to that of its natural stereoisomer d-erythro-dihydrosphingosine. Both sphingoid bases are used as biosynthetic precursors for complex sphingolipids, albeit to different rates. Whereas a considerable amount of the natural sphingoid base is also directed to the catabolic pathway (20-66%, cell type dependent), only a minor amount of the nonnatural safingol is subjected to catabolic cleavage, most of it being N-acylated to the respective stereochemical variant of dihydroceramide. Interestingly, N-acylation of safingol to l-threo-dihydroceramide is less sensitive to fumonisin B1 than the formation of the natural d-erythro-dihydroceramide. In addition, safingol-derived l-threo-dihydroceramide, unlike its physiologic counterpart, is not desaturated. Most of it either accumulates in the cells (up to 50%) or is used as a biosynthetic precursor of the respective dihydrosphingomyelin (up to 45%). About 5% is, however, glucosylated and channeled into the glycosphingolipid biosynthetic pathway. Our results demonstrate that, despite its nonnatural stereochemistry, safingol is recognized and metabolized preferentially by enzymes of the sphingolipid biosynthetic pathway. Furthermore, our data suggest that the cytotoxic potential of safingol is reduced rather than enhanced via its metabolic conversion.

Cis-4-methylsphingosine phosphate induces apoptosis in neuroblastoma cells by opposite effects on p38 and ERK mitogen-activated protein kinases

Intracellular phosphorylation of cis-4-methylsphingosine was previously shown to result in a metabolically stable compound that accumulates in Swiss 3T3 fibroblasts and mimics the mitogenic effect induced by the short-lived sphingosine metabolite, sphingosine-1-phosphate. In the present study incubation of neuroblastoma B104 cells with cis-4-methylsphingosine (10 microM) also resulted in an intracellular accumulation of its phosphorylated derivative that was, however, associated with the concentration-dependent induction of apoptosis, not observed after treatment with 10 microM of sphingosine-1-phosphate or sphingosine, respectively. In B104 cells, cis-4-methylsphingosine stimulated p38 mitogen-activated protein kinase (p38 MAPK) and simultaneously inhibited extracellular signal-regulated kinase (ERK), whereas sphingosine and sphingosine-1-phosphate only stimulated p38 MAPK without suppression of ERK. Inhibition of cis-4-methylsphingosine phosphorylation reduced both, apoptosis and concurrent regulation of mitogen-activated protein kinases (MAPKs), suggesting that the unusual accumulation of the phosphorylated sphingoid base was responsible for the biological effects. Furthermore, inhibition of p38 MAPK prevented cis-4-methylsphingosine-induced apoptosis, while suppression of the ERK pathway in the presence of sphingosine or sphingosine-1-phosphate resulted in apoptosis, indicating that the simultaneous opposite regulation of the two MAPKs was required for the induction of apoptosis.

Advances in the signal transduction of ceramide and related sphingolipids

Recently, the sphingolipid metabolites ceramide, sphingosine, ceramide 1-P, and sphingosine 1-P have been implicated as second messengers involved in many different cellular functions. Publications on this topic are appearing at a rapidly increasing rate and new developments in this field are also appearing rapidly. It is thus important to summarize the results obtained from many different laboratories and from different fields of research to obtain a clearer picture of the importance of sphingolipid metabolites. This article reviews the studies from the last few years and includes the effects of a variety of extracellular agents on sphingolipid signal transduction pathways in different tissues and cells and on the mechanisms of regulation. Sphingomyelin exists in a number of functionally distinct pools and is composed of distinct molecular species. Sphingomyelin metabolites may be formed by many different pathways. For example, the generation of ceramide from sphingomyelin can be catalyzed by at least five different sphingomyelinases. A large variety of stimuli can induce the generation of ceramide, leading to activation or inhibition of various cellular events such as proliferation, differentiation, apoptosis, and inflammation. The effect of ceramide on these physiological processes is due to its many different downstream targets. It can activate ceramide-activated protein kinases and ceramide-activated protein phosphatases. It also activates or inhibits PKCs, PLD, PLA2, PC-PLC, nitric oxide synthase, and the ERK and SAPK/JNK signaling cascades. Ceramide activates or inhibits transcription factors, modulates calcium homeostasis and interacts with the retinoblastoma protein to regulate cell cycle progression. Most of the work in this field has involved the study of ceramide effects, but the roles of the other three sphingomyelin metabolites is now attracting much attention. The complex interactions between signaling components and ceramide and the controls regulating these interactions are now being identified and are presented in this review.