Mechanisms by which autophagy promotes cell survival or death are unclear. We provide evidence that C18-pyridinium ceramide (C18-Pyr-Cer) treatment, or endogenous C18-ceramide generation by ceramide synthase 1 (CerS1) expression mediates autophagic cell death, independent of apoptosis in human cancer cells. C18-ceramide-induced lethal autophagy was regulated via microtubule-associated protein 1 light chain 3 beta lipidation (LC3B-II) and selective targeting of mitochondria by LC3B-II-containing autophagolysosomes (mitophagy) through direct interaction between ceramide and LC3B-II upon Drp1-dependent mitochondrial fission, leading to inhibition of mitochondrial function and oxygen consumption. Accordingly, expression of mutant LC3B with impaired ceramide binding, as predicted by molecular modeling, prevented CerS1-mediated mitochondrial targeting, recovering oxygen consumption. Moreover, knockdown of CerS1 abrogated sodium selenite-induced mitophagy, and stable LC3B knockdown protected against CerS1-C18-ceramide-dependent mitophagy and blocked tumor suppression in vivo. Thus, these data suggest a novel receptor function of ceramide for anchoring LC3B-II-autophagolysosomes to mitochondrial membranes, defining a key mechanism for the induction of lethal mitophagy.
Involvement of Dihydroceramide Desaturase in Cell Cycle Progression in Human Neuroblastoma Cells
The role of dihydroceramide desaturase as a key enzyme in the de-novo pathway of ceramide generation was investigated in human neuroblastoma cells (SMS-KCNR). A novel assay using water soluble analogs of dihydroceramide, dihydroceramidoids (D-e-dhCCPS analogs) was used to measure desaturase activity in-situ. Conversion of D-e-C12-dhCCPS (C12-dhCCPS) to its 4,5-desaturated counterpart: D-e-C12-CCPS (C12-CCPS) was determined by LC/MS analysis. The validity of the assay was confirmed by C8-cyclopropenylceramide, a competitive inhibitor of dihydroceramide desaturase. A human homologue (DEGS-1) of the Drosophila melanogaster degenerative-spermatocyte-gene-1 (des-1) was recently identified, and reported to have desaturase activity. Transfection of SMS-KCNR cells with siRNA to DEGS-1 significantly blocked the conversion of C12-dhCCPS to C12-CCPS. The associated accumulation of endogenous dihydroceramides confirmed DEGS-1 as the main active dihydroceramide desaturase in these cells. The partial loss of DEGS-1 inhibited cell growth with cell cycle arrest at G0/G1. This was accompanied by significant decrease in the amount of phosphorylated retinoblastoma protein (pRb). This hypophosphorylation was inhibited by tautomycin and not by okadaic acid, suggesting the involvement of protein phosphatase 1. Additionally, we found that treatment of SMS-KCNR cells with fenretinide inhibited desaturase activity in a dose dependent manner. Increase of dihydroceramides, but not ceramides, paralled this process as measured by LC/MS. There were no effects on the mRNA or protein levels of DEGS-1, suggesting that fenretinide acts at the posttranslational level as an inhibitor of this enzyme. Tautomycin was also able to block the hypophosphorylation of Rb observed with fenretinide treatment. These findings suggest a novel biologic function for dihydroceramides.Sphingolipids, in addition to their roles as structural components of cell membranes, play important roles as regulators of signal transduction in cell differentiation, cell proliferation, and apoptosis. One of the most studied sphingolipids is ceramide (1-5). Ceramide (Cer) is the central building block for sphingolipids. It serves as a precursor for the synthesis of more complex sphingolipids; and is generated in cells by multiple pathways. Ceramide can be produced de-novo from serine and palmitoyl-CoA via dihydroceramide (dhCer), followed by its desaturation to Cer by dihydroceramide desaturase. While there has been a great body of *Address correspondence to: Jacqueline M. Kraveka, Division of Pediatric Hematology-Oncology, Medical University of South Carolina, 135 Rutledge Avenue, PO Box 250558, Charleston, SC 29425. Tel: 843-792-2957; Fax: 843-792-8912; Email: kravekjm@musc.edu. Dihydroceramide desaturase is responsible for inserting the 4,5-trans-double bond to the sphingoid backbone of dhCer. The enzyme was previously characterized and an in-vitro assay was developed to determine its activity (6-9). A crude enzyme preparation was isolated from rat liver microsomes. In a...
Sphingosine-1-phosphate (S1P), a sphingolipid metabolite, promotes cell proliferation and survival whereas its precursor, sphingosine, has the opposite effects. However, much remains unknown about their regulation. Here we identify a novel human ceramidase (haCER2) that regulates the levels of both sphingosine and S1P by controlling the hydrolysis of ceramides. haCER2 is localized to the Golgi complex and is highly expressed in the placenta. High ectopic expression of haCER2 caused fragmentation of the Golgi complex and growth arrest in HeLa cells due to sphingosine accumulation. Low ectopic expression of haCER2 increased S1P without sphingosine accumulation, promoting cell proliferation in serum-free medium. This proliferative effect was suppressed by dimethylsphingosine, an inhibitor of the S1P formation, or by the RNA interference (RNAi) -mediated inhibition of S1P(1,) a G-protein-coupled receptor for S1P. The RNAi-mediated down-regulation of haCER2 enhanced the serum deprivation-induced growth arrest and apoptosis of HeLa cells, which was inhibited by addition of exogenous S1P. Serum deprivation up-regulated both haCER2 mRNA and activity in HeLa cells. haCER2 mRNA is also up-regulated in some tumors. Taken together, these results suggest that haCER2 is important for the generation of S1P and S1P-mediated cell proliferation and survival, but that its overexpression may cause cell growth arrest due to an accumulation of sphingosine.
Treatment of A549 cells with C 6 -ceramide resulted in a significant increase in the endogenous long chain ceramide levels, which was inhibited by fumonisin B1 (FB1), and not by myriocin (MYR). The biochemical mechanisms of generation of endogenous ceramide were investigated using A549 cells treated with selectively labeled C 6 -ceramides, [sphingosine-3- The results demonstrated that 3 H label was incorporated into newly synthesized long chain ceramides, which was inhibited by FB1 and not by MYR. Interestingly, the 14 C label was not incorporated into long chain ceramides. Taken together, these results show that generation of endogenous ceramide in response to C 6 -ceramide is due to recycling of the sphingosine backbone of C 6 -ceramide via deacylation/ reacylation and not due to the elongation of its fatty acid moiety. Moreover, the generation of endogenous long chain ceramide in response to C 6 -ceramide was completely blocked by brefeldin A, which causes Golgi disassembly, suggesting a role for the Golgi in the metabolism of ceramide. In addition, the generation of endogenous ceramide in response to short chain exogenous ceramide was induced by D-erythro-but not L-erythro-C 6 -ceramide, demonstrating the stereospecificity of this process. Interestingly, several key downstream biological activities of ceramide, such as growth inhibition, cell cycle arrest, and modulation of telomerase activity were induced by D-erythro-C 6 -ceramide, and not L-erythro-C 6 -ceramide (and inhibited by FB1) in A549 cells, suggesting a role for endogenous long chain ceramide in the regulation of these responses.
These data collectively suggest that, similar to the yeast phytoceramidase YPC1p, aPHC has phytoceramidase activity both in vitro and in cells; hence, it is a functional homolog of the yeast phytoceramidase YPC1p. However, in contrast to YPC1p, aPHC exhibited no reverse activity of ceramidase either in vitro or in cells. Biochemical characterization showed that aPHC had a pH optimum of 9.5, was activated by Ca 2؉ , but was inhibited by Zn 2؉ and sphingosine. Substrate specificity showed that aPHC hydrolyzed phytoceramide preferentially. Together, these data demonstrate that aPHC is a novel human alkaline phytoceramidase, the first mammalian alkaline ceramidase to be identified as being specific for the hydrolysis of phytoceramide.Ceramide and its intermediate breakdown product sphingosine have been shown to mediate many cellular events including growth arrest, stress responses, and apoptosis (for review, see Refs.
Signaling pathways regulated by mutant Fms-like tyrosine kinase 3 (FLT3)-internal tandem duplication (ITD), which mediate resistance to acute myeloid leukemia (AML) cell death, are poorly understood. Here, we reveal that pro-cell death lipid ceramide generation is suppressed by FLT3-ITD signaling. Molecular or pharmacologic inhibition of FLT3-ITD reactivated ceramide synthesis, selectively inducing mitophagy and AML cell death. Mechanistically, FLT3-ITD targeting induced ceramide accumulation on the outer mitochondrial membrane, which then directly bound autophagy-inducing light chain 3 (LC3), involving its I35 and F52 residues, to recruit autophagosomes for execution of lethal mitophagy. Short hairpin RNA (shRNA)-mediated knockdown of LC3 prevented AML cell death in response to FLT3-ITD inhibition by crenolanib, which was restored by wild-type (WT)-LC3, but not mutants of LC3 with altered ceramide binding (I35A-LC3 or F52A-LC3). Mitochondrial ceramide accumulation and lethal mitophagy induction in response to FLT3-ITD targeting was mediated by dynamin-related protein 1 (Drp1) activation via inhibition of protein kinase A-regulated S637 phosphorylation, resulting in mitochondrial fission. Inhibition of Drp1 prevented ceramide-dependent lethal mitophagy, and reconstitution of WT-Drp1 or phospho-null S637A-Drp1 but not its inactive phospho-mimic mutant (S637D-Drp1), restored mitochondrial fission and mitophagy in response to crenolanib in FLT3-ITD AML cells expressing stable shRNA against endogenous Drp1. Moreover, activating FLT3-ITD signaling in crenolanib-resistant AML cells suppressed ceramide-dependent mitophagy and prevented cell death. FLT3-ITD AML drug resistance is attenuated by LCL-461, a mitochondria-targeted ceramide analog drug, in vivo, which also induced lethal mitophagy in human AML blasts with clinically relevant FLT3 mutations. Thus, these data reveal a novel mechanism which regulates AML cell death by ceramide-dependent mitophagy in response to FLT3-ITD targeting.
In a previous study, we reported that the Saccharomyces cerevisiae gene YPC1 encodes an alkaline ceramidase with a dual activity, catalyzing both hydrolysis and synthesis of yeast ceramide (Mao, C., Xu, R., Bielawska, A., and Obeid, L. M. (2000) J. Biol. Chem. 275, 6876 -6884). In this study, we have identified a YPC1 homologue in S. cerevisiae that also encodes an alkaline ceramidase. We show that these two ceramidases have different substrate specificity, such that YPC1p preferentially hydrolyzes phytoceramide, whereas the new ceramidase YDC1p hydrolyzes dihydroceramide preferentially and phytoceramide only slightly. Neither enzyme hydrolyzes unsaturated mammalian-type ceramide. In contrast to YPC1p, YDC1p had only minor in vitro reverse activity of catalyzing dihydroceramide formation from a free fatty acid and dihydrosphingosine and no activity with phytosphingosine. Overexpression of YDC1p had no reverse activity in non-stressed yeast cells, but like YPC1p suppressed the inhibition of growth by fumonisin B1 albeit more modestly. Deletion of YDC1 and YPC1 or both did not apparently affect growth, suggesting neither gene is essential. However, the ⌬ydc1 deletion mutant but not the ⌬ypc1 deletion mutant was sensitive to heat stress, indicating a role for dihydroceramide but not phytoceramide in heat stress responses, and suggesting that the two enzymes have distinct physiological functions.
Accumulating data support a role for bioactive lipids as mediators of lipotixicity in cardiomyocytes. One class of these, the ceramides, constitutes a family of molecules that differ in structure and are synthesized by distinct enzymes, ceramide synthase (CerS)1-CerS6. Data support that specific ceramides and the enzymes that catalyze their formation play distinct roles in cell function. In a mouse model of diabetic cardiomyopathy, sphingolipid profiling revealed increases in not only the CerS5-derived ceramides but also in very long chain (VLC) ceramides derived from CerS2. Overexpression of CerS2 elevated VLC ceramides caused insulin resistance, oxidative stress, mitochondrial dysfunction, and mitophagy. Palmitate induced CerS2 and oxidative stress, mitophagy, and apoptosis, which were prevented by depletion of CerS2. Neither overexpression nor knockdown of CerS5 had any function in these processes, suggesting a chain-length dependent impact of ceramides on mitochondrial function. This concept was also supported by the observation that synthetic mitochondria-targeted ceramides led to mitophagy in a manner proportional to N-acyl chain length. Finally, blocking mitophagy exacerbated cell death. Taken together, our results support a model by which CerS2 and VLC ceramides have a distinct role in lipotoxicity, leading to mitochondrial damage, which results in subsequent adaptive mitophagy. Our data reveal a novel lipotoxic pathway through CerS2.-Law, B. A., Liao, X., Moore, K. S., Southard, A., Roddy, P., Ji, R., Szulc, Z., Bielawska, A., Schulze, P. C., Cowart, L. A. Lipotoxic very-long-chain ceramides cause mitochondrial dysfunction, oxidative stress, and cell death in cardiomyocytes.
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