氯虫苯甲酰胺胁迫下小菜蛾ABCC1～ABCC5 mRNA的表达特征

【目的】为探讨小菜蛾Plutella xylostella ABC转运蛋白(ATP-binding cassette transporter)与氯虫苯甲酰胺代谢的关系【方法】采用实时荧光定量RT-PCR技术,测定了氯虫苯甲酰胺敏感和抗性小菜蛾及用LC50剂量的氯虫苯甲酰胺处理敏感种群不同时间后ABCC1~ABCC5 mRNA的表达量;并检测了其中过表达的ABCC3~ABCC5在小菜蛾不同发育阶段和4龄幼虫不同组织中的表达量。【结果】所检测的5个ABCC基因在氯虫苯甲酰胺抗性品系中均上调表达,最高为敏感品系的2倍;LC50的氯虫苯甲酰胺处理后ABCC3、ABCC4和ABCC5 mRNA的表达量分别上调2.16倍、2.81倍和1.85倍,ABCC1和ABCC2则分别下调为对照组的65.8%和37.2%。ABCC3的mRNA在幼虫期和雄性成虫中表达量显著高于其它时期;ABCC4的mRNA在各发育阶段表达量差异不大,其中在预蛹期最高;ABCC5的mRNA在3龄幼虫中表达量显著高于其它龄期。在4龄幼虫各组织中,ABCC3、ABCC4和ABCC5在中肠中的表达量均显著高于其它组织。【结论】小菜蛾ABCC3、ABCC4和ABCC5可能在其对氯虫苯甲酰胺的代谢中起作用,该研究结果为进一步探究小菜蛾对氯虫苯甲酰胺的抗性与ABCC1~ABCC5的关系奠定了基础。     

Sphingosine 1-phosphate lyase blockade elicits myogenic differentiation of murine myoblasts acting via Spns2/S1P2 receptor axis

The bioactive sphingolipid sphingosine 1-phosphate (S1P) has emerged in the last three decades as main regulator of key cellular processes including cell proliferation, survival, migration and differentiation. A crucial role for this sphingolipid has been recognized in skeletal muscle cell biology both in vitro and in vivo. S1P lyase (SPL) is responsible for the irreversible degradation of S1P and together with sphingosine kinases, the S1P producing enzymes, regulates cellular S1P levels. In this study is clearly showed that the blockade of SPL by pharmacological or RNA interference approaches induces myogenic differentiation of C2C12 myoblasts. Moreover, down-regulation of the specific S1P transporter spinster homolog 2 (Spns2) abrogates myogenic differentiation brought about by SPL inhibition or down-regulation, pointing at a role of extracellular S1P in the pro-myogenic action induced by SPL blockade. Furthermore, also S1P₂ receptor down-regulation was found to abrogate the pro-myogenic effect of SPL blockade. These results provide further proof that inside-out S1P signaling is critically implicated in skeletal muscle biology and provide support to the concept that the specific targeting of SPL could represent an exploitable strategy to treat skeletal muscle disorders.     

Higher level of plasma bioactive molecule sphingosine 1-phosphate in women is associated with estrogen

Both sphingosine 1-phosphate (S1P) and estrogen have been documented to play endothelial protective roles. However, it remains unclear whether estrogen could regulate the anabolism of the bioactive molecule S1P and the underlying mechanisms. In this study, 108 healthy participants were separated into three age groups, and their plasma S1P levels were analyzed by liquid chromatography tandem mass spectrometry. Results showed that the plasma S1P levels were significantly higher in women than those in men within the age of 16–55 years old and higher in pre-menopausal than post-menopausal women. The experiment in C57 BL/6 mice confirmed the gender difference of plasma S1P level. In vitro study demonstrated that after the stimulation of 17β-estradiol (E2), S1P levels both in EA.hy926 cells and the culture media were increased about 9 and 3 times, respectively; the mRNA expression, the protein level and the activity of sphingosine kinase (SphK) 1, not SphK2, were markedly increased; the mRNA and protein expression of ATP-binding cassette transporter (ABC) C1, G2 and S1P transporter spinster homolog 2 (Spns2) were significantly elevated; furthermore, the mRNA and protein expressions of S1P receptors (S1PRs) 1–2 were increased in a time-dependent manner. This study suggests that E2 markedly improves S1P synthesis by activating SphK1 and induces S1P export via activating ABCC1, G2 and Spns2 from endothelium system, which may consequently lead to the gender difference of plasma S1P in adult human and mouse. The results of this study suggest that E2 may exert its vasculoprotective function by activation of the SphK1–S1P–S1PR signaling axis.     

Sphingosine-1-phosphate and lipid phosphohydrolases

Sphingosine-1-phosphate (S1P) is a bioactive sphingolipid that acts as both an extracellular ligand for the endothelial differentiation gene-1 (EDG-1) G-protein coupled receptor (GPCR) family and as an intracellular messenger. Cellular levels of S1P are low and tightly regulated in a spatial-temporal manner not only by sphingosine kinase (SPHK) but also by degradation catalyzed by S1P lyase, specific S1P phosphohydrolases, and by general lipid phosphate phosphohydrolases (LPPs). LPPs are characterized as magnesium-independent, insensitive to inhibition by N-ethylmaleimide (NEM) and possessing broad substrate specificity with a variety of phosphorylated lipids, including S1P, phosphatidic acid (PA), and lysophosphatidic acid (LPA). LPPs contain three highly conserved domains that define a phosphohydrolase superfamily. Recently, several specific S1P phosphohydrolases have been identified in yeast and mammalian cells. Phylogenetic and biochemical analyses indicate that these enzymes constitute a new subset of the LPP family. As further evidence, S1P phosphohydrolases exhibit high specificity for phosphorylated sphingoid bases. Enforced expression of S1P phosphohydrolase alters the cellular levels of sphingolipid metabolites in yeast and mammalian cells, increasing sphingosine and ceramide, bioactive sphingolipids that often have opposing biological actions to S1P. By regulating the cellular ratio between ceramide/sphingosine and S1P, S1P phosphohydrolase is poised to be a critical factor in cell survival/cell death decisions. Indeed, expression of S1P phosphohydrolase in mammalian cells increases apoptosis, whereas deletion of S1P phosphohydrolases in yeast correlates with resistance to heat stress. In this review, we discuss the role of phosphohydrolases in the metabolism of S1P and how turnover of S1P can regulate sphingolipid metabolites signaling.     

Sphingosine kinases, sphingosine 1-phosphate, apoptosis and diseases

Sphingolipids are ubiquitous components of cell membranes and their metabolites ceramide (Cer), sphingosine (Sph), and sphingosine-1-phosphate (S1P) have important physiological functions, including regulation of cell growth and survival. Cer and Sph are associated with growth arrest and apoptosis. Many stress stimuli increase levels of Cer and Sph, whereas suppression of apoptosis is associated with increased intracellular levels of S1P. In addition, extracellular/secreted S1P regulates cellular processes by binding to five specific G protein coupled-receptors (GPCRs). S1P is generated by phosphorylation of Sph catalyzed by two isoforms of sphingosine kinases (SphK), type 1 and type 2, which are critical regulators of the “sphingolipid rheostat”, producing pro-survival S1P and decreasing levels of pro-apoptotic Sph. Since sphingolipid metabolism is often dysregulated in many diseases, targeting SphKs is potentially clinically relevant. Here we review the growing recent literature on the regulation and the roles of SphKs and S1P in apoptosis and diseases.     

Sphingosine 1-phosphate protects mouse extensor digitorum longus skeletal muscle during fatigue

Sphingomyelin derivatives exert various second messenger actions in numerous tissues. Sphingosine (SPH) and sphingosine 1-phosphate (S1P) are two major sphingomyelin derivatives present at high levels in blood. The aim of the present work was to investigate whether S1P and SPH exert relevant actions in mouse skeletal muscle contractility and fatigue. Exogenous S1P and SPH administration caused a significant reduction of tension decline during fatigue of extensor digitorum longus muscle. Final tension after the fatiguing protocol was 40% higher than in untreated muscle. Interestingly, N,N-dimethylsphingosine, an inhibitor of SPH kinase (SK), abolished the effect of supplemented SPH but not that of S1P, suggesting that SPH acts through its conversion to S1P. Moreover, SPH was not effective in Ca²⁺-free solutions, in agreement with the hypothesis that SPH action is dependent on its conversion to S1P by the Ca²⁺-requiring enzyme SK. In contrast to SPH, S1P produced its positive effects on fatigue in Ca²⁺-free conditions, indicating that S1P action does not require Ca²⁺ entry and most likely is receptor mediated. The effects of S1P could be ascribed in part to its ability to prevent the reduction (–20 mV) of action potential amplitude caused by fatigue. In conclusion, these results indicate that extracellular S1P has protective effects during the development of muscle fatigue and that the extracellular conversion of SPH to S1P may represent a rheostat mechanism to protect skeletal muscle from possible cytotoxic actions of SPH. sphingosine kinase; action potential; sphingosine     

ATP-binding cassette ABCC1 is involved in the release of sphingosine 1-phosphate from rat uterine leiomyoma ELT3 cells and late pregnant rat myometrium

Sphingosine 1-phosphate (S1P), a bioactive lipid generated by sphingosine kinases (SphK1/2), initiates different signalling pathways involved in physiological and pathological processes. We previously demonstrated that in rat myometrium at late (day 19) gestation, SphK1 increases the expression of COX2 via S1P generation and release. In rat uterine leiomyoma cells (ELT3), SphK1/S1P axis controls survival and proliferation. In the present study we demonstrate that PDBu activates SphK1 but not SphK2. SphK1 activation requires PKC and MAPK ERK1/2. S1P produced by PDBu is released in the medium. PDBu-induced S1P export is abolished by Ro-318220 and BIM (PKC inhibitors), by U0126 and PD98059 (MEK inhibitors), SKI-II (SphKI/2 inhibitor) and SphK1-siRNA, suggesting the involvement of PKC, ERK and SphK1 respectively. The release of S1P is insensitive to inhibitors of ATP Binding Cassette (ABC)A1 and ABCB1 transporters, but is abolished when ABCC1 transporters are inhibited by MK571 or down-regulated by ABCC1-siRNA. PDBu increases COX2 expression that is blocked by the inhibition of PKC, ERK1/2, SphK1, and when cells are treated with MK571 or transfected with ABCC1-siRNA. The induction of COX2 by the S1P release due to PDBu or by exogenous S1P involves S1P2 receptors coupled to Gi. In myometrium from rat at late gestation, the release of S1P is also strongly reduced when SphK and ABCC1 are inhibited. The data reveal that in rat leiomyoma cells and late pregnant rat myometrium, the release of S1P involves a similar signalling pathway and occurs through ABCC1.     

Intracellular role for sphingosine kinase 1 in intestinal adenoma cell proliferation

Sphingosine kinase (Sphk) enzymes are important in intracellular sphingolipid metabolism as well as in the biosynthesis of sphingosine 1-phosphate (S1P), an extracellular lipid mediator. Here, we show that Sphk1 is expressed and is required for small intestinal tumor cell proliferation in Apc Min/+ mice. Adenoma size but not incidence was dramatically reduced in Apc Min/+ Sphk(-/-) mice. Concomitantly, epithelial cell proliferation in the polyps was significantly attenuated, suggesting that Sphk1 regulates adenoma progression. Although the S1P receptors (S1P1R, S1P2R, and S1P3R) are expressed, polyp incidence or size was unaltered in Apc Min/+ S1p2r(-/-), Apc Min/+ S1p3r(-/-), and Apc Min/+ S1p1r(+/-) bigenic mice. These data suggest that extracellular S1P signaling via its receptors is not involved in adenoma cell proliferation. Interestingly, tissue sphingosine content was elevated in the adenomas of Apc Min/+ Sphk1(-/-) mice, whereas S1P levels were not significantly altered. Concomitantly, epithelial cell proliferation and the expression of the G1/S cell cycle regulator CDK4 and c-myc were diminished in the polyps of Apc Min/+ Sphk1(-/-) mice. In rat intestinal epithelial (RIE) cells in vitro, Sphk1 overexpression enhanced cell cycle traverse at the G1/S boundary. In addition, RIE cells treated with sphingosine but not C6-ceramide exhibited reduced cell proliferation, reduced retinoblastoma protein phosphorylation, and cyclin-dependent kinase 4 (Cdk4) expression. Our findings suggest that Sphk1 plays a critical role in intestinal tumor cell proliferation and that inhibitors of Sphk1 may be useful in the control of intestinal cancer.     

A polysaccharides MDG-1 augments survival in the ischemic heart by inducing S1P release and S1P1 expression

Ophiopogon japonicus is a traditional Chinese medicine used to treat cardiovascular disease. Recent studies have confirmed the anti-ischemic properties of a water-soluble β-D-fructan (MDG-1) from O. japonicus. The sphingosine 1-phosphate (S1P) signaling pathway is involved in its cytoprotective effects. Herein, we explore the role of the S1P signaling pathway in the anti-ischemic effect of MDG-1 and assess one possible mechanism by which it induces S1P release and sphingosine 1-phosphate receptor 1 (S1P(1)) expression in human microvascular endothelial cells (HMEC-1) and cardiomyocytes. Our evidence demonstrates that MDG-1 promotes sphingosine kinase (SPHK) activity in HMEC-1 cells. An analytical method for measuring the mass of S1P using ESI/MS/MS was developed and we found that MDG-1 increases intracellular S1P levels. Meanwhile, MDG-1 is protective during hypoxia and ischemia through mechanisms that require S1P(1) receptor activation, which was confirmed both in oxygen glucose deprivation (OGD) and coronary artery ligation models by using transfection of cloned human S1P(1) receptor and RNA interference. These data indicate that the increase of intracellular S1P generation, particularly by activation of the SPHK enzyme, coupled with the autocrine and paracrine stimulation of cell surface S1P receptors, is a potential mechanism in the anti-ischemic and cell protective effect of MDG-1.     

Identification of two lipid phosphatases that regulate sphingosine-1-phosphate cellular uptake and recycling

Sphingosine-1-phosphate (S1P) is a sphingolipid metabolite that serves as a potent extracellular signaling molecule. Metabolic regulation of extracellular S1P levels impacts key cellular activities through altered S1P receptor signaling. Although the pathway through which S1P is degraded within the cell and thereby eliminated from reuse has been previously described, the mechanism used for S1P cellular uptake and the subsequent recycling of its sphingoid base into the sphingolipid synthesis pathway is not completely understood. To identify the genes within this S1P uptake and recycling pathway, we performed a genome-wide CRISPR/Cas9 KO screen using a positive-selection scheme with Shiga toxin, which binds a cell-surface glycosphingolipid receptor, globotriaosylceramide (Gb3), and causes lethality upon internalization. The screen was performed in HeLa cells with their sphingolipid de novo pathway disabled so that Gb3 cell-surface expression was dependent on salvage of the sphingoid base of S1P taken up from the medium. The screen identified a suite of genes necessary for S1P uptake and the recycling of its sphingoid base to synthesize Gb3, including two lipid phosphatases, PLPP3 (phospholipid phosphatase 3) and SGPP1 (S1P phosphatase 1). The results delineate a pathway in which plasma membrane–bound PLPP3 dephosphorylates extracellular S1P to sphingosine, which then enters cells and is rephosphorylated to S1P by the sphingosine kinases. This rephosphorylation step is important to regenerate intracellular S1P as a branch-point substrate that can be routed either for dephosphorylation to salvage sphingosine for recycling into complex sphingolipid synthesis or for degradation to remove it from the sphingolipid synthesis pathway.     

Development of leydig cells in the insulin-like growth factor-I (igf-I) knockout mouse: effects of igf-I replacement and gonadotropic stimulation

Targeted gene deletion of insulin-like growth factor-I (IGF-I) results in diminished numbers of Leydig cells (LCs) and lower circulating testosterone (T) levels in adult males. The impact of endogenous IGF-I withdrawal on proliferation (labeling index, LI) and differentiation of LCs was investigated, testing for restorative effects of IGF-I replacement and/or LH stimulation. With IGF-I replacement in mutant mice, LIs increased more than 200% (P < 0.05). LC numbers were also increased by 200%, whereas the numbers of intermediate cell progenitors (PLCs) were unchanged compared to mutant vehicle controls. LIs of PLCs in wild-type males increased by 200% after LH stimulation, and LC numbers increased by 50% compared to vehicle-treated controls (P < 0.05). In contrast, there was no effect of LH on LI in mutant mice, but LC numbers still increased by 30% (P < 0.05). Additive effects on LI and cell numbers were observed in response to IGF-I plus LH in mutants, implying that the two hormones use separate signaling pathways. Serum T and LH levels in wild-type and mutant males were equivalent. Exogenous LH increased T production 8-fold in wild-type males (P < 0.01). In mutant mice, neither LH stimulation nor IGF-I alone affected serum T levels, but IGF-I plus LH stimulation increased serum T 2-fold (P < 0.05). These data support the conclusions that 1) IGF-I is a critical autocrine and/or paracrine factor in the control of adult LC numbers and function; and 2) LH is not a direct mitogenic factor for LCs, and acts in part through IGF-I to stimulate proliferative activity.     

Sphingosine kinase 1 (SPHK1) is induced by transforming growth factor-beta and mediates TIMP-1 up-regulation

Transforming growth factor-beta (TGF-beta) signaling plays a pivotal role in extracellular matrix deposition by stimulating collagen production and other extracellular matrix proteins and by inhibiting matrix degradation. The present study was undertaken to define the role of sphingosine kinase (SphK) in TGF-beta signaling. TGF-beta markedly up-regulated SphK1 mRNA and protein amounts and caused a prolonged increase in SphK activity in dermal fibroblasts. Concomitantly, TGF-beta reduced sphingosine-1-phosphate phosphatase activity. Consistent with the changes in enzyme activity, corresponding changes in sphingolipid levels were observed such that sphingosine 1-phosphate (S1P) was increased (approximately 2-fold), whereas sphingosine and ceramide were reduced after 24 h of TGF-beta treatment. Given the relatively early induction of SphK gene expression in response to TGF-beta, we examined whether SphK1 may be involved in the regulation of TGF-beta-inducible genes that exhibit compatible kinetics, e.g. tissue inhibitor of metalloproteinase-1 (TIMP-1). We demonstrate that decreasing SphK1 expression by small interfering RNA (siRNA) blocked TGF-beta-mediated up-regulation of TIMP-1 protein suggesting that up-regulation of SphK1 contributes to the induction of TIMP-1 in response to TGF-beta. The role of SphK1 as a positive regulator of TIMP-1 gene expression was further corroborated by using ectopically expressed SphK1 in the absence of TGF-beta. Adenovirally expressed SphK1 led to a 2-fold increase of endogenous S1P and to increased TIMP-1 mRNA and protein production. In addition, ectopic SphK1 and TGF-beta cooperated in TIMP-1 up-regulation. Mechanistically, experiments utilizing TIMP-1 promoter constructs demonstrated that the action of SphK1 on the TIMP-1 promoter is through the AP1-response element, consistent with the SphK1-mediated up-regulation of phospho-c-Jun levels, a key component of AP1. Together, these experiments demonstrate that SphK/S1P are important components of the TGF-beta signaling pathway involved in up-regulation of the TIMP-1 gene.     

Sphingosine kinases, sphingosine 1-phosphate, apoptosis and diseases

Sphingolipids are ubiquitous components of cell membranes and their metabolites ceramide (Cer), sphingosine (Sph), and sphingosine-1-phosphate (S1P) have important physiological functions, including regulation of cell growth and survival. Cer and Sph are associated with growth arrest and apoptosis. Many stress stimuli increase levels of Cer and Sph, whereas suppression of apoptosis is associated with increased intracellular levels of S1P. In addition, extracellular/secreted S1P regulates cellular processes by binding to five specific G protein coupled-receptors (GPCRs). S1P is generated by phosphorylation of Sph catalyzed by two isoforms of sphingosine kinases (SphK), type 1 and type 2, which are critical regulators of the "sphingolipid rheostat", producing pro-survival S1P and decreasing levels of pro-apoptotic Sph. Since sphingolipid metabolism is often dysregulated in many diseases, targeting SphKs is potentially clinically relevant. Here we review the growing recent literature on the regulation and the roles of SphKs and S1P in apoptosis and diseases.     

Mechanisms of sphingosine and sphingosine 1-phosphate generation in human platelets

The bioactive molecule sphingosine 1-phosphate (S1P) is abundantly stored in platelets and can be released extracellularly. However, although they have high sphingosine (Sph) kinase activity, platelets lack the de novo sphingolipid biosynthesis necessary to provide the substrates. Here, we reveal a generation pathway for Sph, the precursor of S1P, in human platelets. Platelets incorporated extracellular 3H-labeled Sph much faster than human megakaryoblastic cells and rapidly converted it to S1P. Furthermore, Sph formed from plasma sphingomyelin (SM) by bacterial sphingomyelinase (SMase) and neutral ceramidase (CDase) was rapidly incorporated into platelets and converted to S1P, suggesting that platelets use extracellular Sph as a source of S1P. Platelets abundantly express SM, possibly supplied from plasma lipoproteins, at the cell surface. Treating platelets with bacterial SMase resulted in Sph generation at the cell surface, conceivably by the action of membrane-bound neutral CDase. Simultaneously, a time-dependent increase in S1P levels was observed. Finally, we demonstrated that secretory acid SMase also induces S1P increases in platelets. In conclusion, our results suggest that in platelets, Sph is supplied from at least two sources: generation in the plasma followed by incorporation, and generation at the outer leaflet of the plasma membrane, initiated by cell surface SM degradation.     

HDL-like lipoproteins in cerebrospinal fluid affect neural cell activity through lipoprotein-associated sphingosine 1-phosphate

High-density lipoprotein (HDL)-associated sphingosine 1-phosphate mediates a variety of lipoprotein-induced actions in vascular cell systems. However, it remains unknown whether extracellular S1P is associated with lipoproteins to exert biological actions in central nervous system. Human cerebrospinal fluid (CSF) induced rat astrocyte migration in a manner sensitive to S1P receptor antagonist VPC23019 and the migration activity was recovered in S1P fraction by thin-layer chromatography. Density-gradient separation of CSF revealed that the major S1P activity was detected in the HDL fraction. In conditioned medium of rat astrocytes cultured with sphingosine, the S1P activity was recovered again in the HDL fraction. The HDL fraction also induced migration of astrocytes and process retraction of oligodendrocytes in a manner similar to S1P. We concluded that S1P is accumulated in HDL-like lipoproteins in CSF and mediates some of lipoprotein-induced neural cell functions in central nervous system.     

The sphingosine 1-phosphate receptor 5 and sphingosine kinases 1 and 2 are localised in centrosomes: Possible role in regulating cell division

We show here that the endogenous sphingosine 1-phosphate 5 receptor (S1P₅, a G protein coupled receptor (GPCR) whose natural ligand is sphingosine 1-phosphate (S1P)) and sphingosine kinases 1 and 2 (SK1 and SK2), which catalyse formation of S1P, are co-localised in the centrosome of mammalian cells, where they may participate in regulating mitosis. The centrosome is a site for active GTP–GDP cycling involving the G-protein, G_i and tubulin, which are required for spindle pole organization and force generation during cell division. Therefore, the presence of S1P₅ (which normally functions as a plasma membrane guanine nucleotide exchange factor, GEF) and sphingosine kinases in the centrosome might suggest that S1P₅ may function as a ligand activated GEF in regulating G-protein-dependent spindle formation and mitosis. The addition of S1P to cells inhibits trafficking of S1P₅ to the centrosome, suggesting a dynamic shuttling endocytic mechanism controlled by ligand occupancy of cell surface receptor. We therefore propose that the centrosomal S1P₅ receptor might function as an intracellular target of S1P linked to regulation of mitosis.     

Insulin Protects Apoptotic Cardiomyocytes from Hypoxia/Reoxygenation Injury through the Sphingosine Kinase/Sphingosine 1-Phosphate Axis

Objective

Experimental and clinical studies have shown that administration of insulin during reperfusion is cardioprotective, but the mechanisms underlying this effect are still unknown. In this study, the ability of insulin to protect apoptotic cardiomyocytes from hypoxia/reoxygenation injury using the sphingosine kinase/sphingosine 1-phosphate axis was investigated.

Methods and Results

Rat cardiomyocytes were isolated and subjected to hypoxia and reoxygenation. [γ-32P] ATP was used to assess sphingosine kinase activity. Insulin was found to increase sphingosine kinase activity. Immunocytochemistry and Western blot analysis showed changes in the subcellular location of sphingosine kinase 1 from cytosol to the membrane in cardiomyocytes. Insulin caused cardiomyocytes to accumulate of S1P in a dose-dependent manner. FRET efficiency showed that insulin also transactivates the S1P₁ receptor. TUNEL staining showed that administration of insulin during reoxygenation could to reduce the rate of reoxygenation-induced apoptosis, which is a requirement for SphK 1 activity. It also reduced the rate of activation of the S1P receptor and inhibited hypoxia/reoxygenation-induced cell death in cardiomyocytes.

Conclusion

The sphingosine kinase 1/sphingosine 1-phosphate/S1P receptor axis is one pathway through which insulin protects rat cardiomyocytes from apoptosis induced by hypoxia/reoxygenation injury.     

Intracellular S1P generation is essential for S1P-induced motility of human lung endothelial cells: role of sphingosine kinase 1 and S1P lyase

Background

Earlier we have shown that extracellular sphingosine-1-phosphate (S1P) induces migration of human pulmonary artery endothelial cells (HPAECs) through the activation of S1P₁ receptor, PKCε, and PLD2-PKCζ-Rac1 signaling cascade. As endothelial cells generate intracellular S1P, here we have investigated the role of sphingosine kinases (SphKs) and S1P lyase (S1PL), that regulate intracellular S1P accumulation, in HPAEC motility.

Methodology/Principal Findings

Inhibition of SphK activity with a SphK inhibitor 2-(p-Hydroxyanilino)-4-(p-Chlorophenyl) Thiazole or down-regulation of Sphk1, but not SphK2, with siRNA decreased S1P_int, and attenuated S1P_ext or serum-induced motility of HPAECs. On the contrary, inhibition of S1PL with 4-deoxypyridoxine or knockdown of S1PL with siRNA increased S1P_int and potentiated motility of HPAECs to S1P_ext or serum. S1P_ext mediates cell motility through activation of Rac1 and IQGAP1 signal transduction in HPAECs. Silencing of SphK1 by siRNA attenuated Rac1 and IQGAP1 translocation to the cell periphery; however, knockdown of S1PL with siRNA or 4-deoxypyridoxine augmented activated Rac1 and stimulated Rac1 and IQGAP1 translocation to cell periphery. The increased cell motility mediated by down-regulation was S1PL was pertussis toxin sensitive suggesting “inside-out” signaling of intracellularly generated S1P. Although S1P did not accumulate significantly in media under basal or S1PL knockdown conditions, addition of sodium vanadate increased S1P levels in the medium and inside the cells most likely by blocking phosphatases including lipid phosphate phosphatases (LPPs). Furthermore, addition of anti-S1P mAb to the incubation medium blocked S1P_ext or 4-deoxypyridoxine-dependent endothelial cell motility.

Conclusions/Significance

These results suggest S1P_ext mediated endothelial cell motility is dependent on intracellular S1P production, which is regulated, in part, by SphK1 and S1PL.     

Role of sphingosine kinases and lipid phosphate phosphatases in regulating spatial sphingosine 1-phosphate signalling in health and disease

Sphingosine 1-phosphate (S1P) is a bioactive lipid that is produced by the sphingosine kinase-catalysed phosphorylation of sphingosine. S1P is an important regulator of cell function, mediating many of its effects through a family of five closely related G protein-coupled receptors (GPCR) termed S1P(1-5) which exhibit high affinity for S1P. These receptors function to relay the effects of extracellular S1P via well-defined signal transduction networks linked to the regulation of cell proliferation, survival, migration etc. Diverse agonists (e.g. cytokines) also activate sphingosine kinase and the resulting S1P formed may bind to specific undefined intracellular targets to elicit cellular responses. The purpose of this review is to discuss some of the spatial/temporal aspects of intracellular S1P signalling and to define the function of sphingosine kinases and lipid phosphate phosphatases (which catalyse dephosphorylation of S1P) in terms of their regulation of cell function. Finally, we survey the function of S1P in relation to disease, where the major challenge is to dissect the role of intracellular versus extracellular actions of S1P in terms of association with defined diseased phenotypes.