Long-chain Base Phosphates Research Articles

Regulation of the Sphingoid Long-chain Base Kinase Lcb4p by Ergosterol and Heme: STUDIES IN PHYTOSPHINGOSINE-RESISTANT MUTANTS

Sphingoid long-chain base 1-phosphates (LCBPs) are widely conserved, bioactive lipid molecules. In yeast, LCBPs are known to be involved in several cellular responses such as heat shock resistance and Ca(2+) mobilization, although their target molecules and signaling pathways remain unclear. To identify genes involved in LCBP signaling and in regulation of LCBP synthesis, we performed transposon mutagenesis in cells lacking the LCBP lyase DPL1 and LCBP phosphatase LCB3 genes and screened for phytosphingosine-resistant clones. Further isolation and identification revealed eight genes (PBP1, HEM14, UFD4, HMG1, TPS1, KES1, WHI2, and ERG5), in addition to the previously characterized LCB4 and PDR5 genes, that are involved in phytosphingosine resistance. Of these eight, four are ergosterol-related genes (HEM14, HMG1, KES1, and ERG5). We also demonstrated that protein expression of the long-chain base kinase Lcb4p was reduced in Deltahem14 and Deltahmg1 cells, likely as a consequence of decreased activity of the heme-dependent transcription factor Hap1p. In addition, phosphorylation of Lcb4p was decreased in all the ergosterol-related mutants isolated and other ergosterol mutants constructed (Deltaerg2, Deltaerg3, and Deltaerg6). Finally, plasma membrane localization of Lcb4p was found to be reduced in Deltaerg6 cells. These results suggest that changes in sterol composition affect the phosphorylation of Lcb4p because of the altered localization. The other genes isolated (PBP1, UFD4, TPS1, and WHI2) may be involved in LCBP signaling.

Long-Chain Base Kinase Lcb4 Is Anchored to the Membrane through Its Palmitoylation by Akr1

Sphingoid long-chain base kinase Lcb4 catalyzes the production of the bioactive lipid molecules the long-chain base 1-phosphates. Although Lcb4 has no apparent transmembrane-spanning domain, it is tightly associated with the membrane. Here, we demonstrate that Lcb4 is modified by palmitoylation. This modification was greatly reduced in mutants for AKR1, which was recently identified as encoding a protein acyltransferase. In vitro experiments revealed that Akr1 indeed acts as a protein acyltransferase for Lcb4. Studies using site-directed mutagenesis indicated that Cys-43 and Cys-46 are palmitoylated. The loss of palmitoylation on Lcb4 caused several effects, including mislocalization of the protein to the cytosol, reduced phosphorylation, and loss of downregulation during the stationary phase. Although Akr2 is highly homologous to Akr1, the deletion of AKR2 did not result in any remarkable phenotypes. However, overproduction of Akr2 resulted in reduced amounts of Lcb4. We demonstrated that Akr2 is an unstable protein and is degraded in the vacuole. Akr2 exhibits high affinity for Lcb4, and in Akr2-overproducing cells this interaction caused unusual delivery of Lcb4 to the vacuole and degradation.

Phosphorylation by Pho85 Cyclin-dependent Kinase Acts as a Signal for the Down-regulation of the Yeast Sphingoid Long-chain Base Kinase Lcb4 during the Stationary Phase

Sphingoid long-chain base 1-phosphates (LCBPs) act as bioactive lipid molecules in eukaryotic cells. In yeast, LCBPs are synthesized mainly by the long-chain base kinase Lcb4p. Until now, the regulatory mechanism for Lcb4p has been unclear. In the present study, we found that Lcb4p is post-translationally modified by phosphorylation. Using a protein kinase mutant yeast collection, we further demonstrated that the cyclin-dependent kinase Pho85p is involved in this phosphorylation. Pho85p functions in a number of cellular processes, especially in response to environmental changes. Two of 10 Pho85p cyclins, Pcl1p and Pcl2p had overlapping functions in the phosphorylation of Lcb4p. Site-directed mutagenesis identified the phosphorylation sites in Lcb4p as Ser(451) and Ser(455). Additionally, pulse-chase experiments revealed that Lcb4p is degraded via the ubiquitin-dependent pathway. The protein was stabilized in Deltapho85 cells, suggesting that phosphorylation acts as a signal for the degradation. Lcb4p is down-regulated in the stationary phase of cell growth, and both phosphorylation and ubiquitination appear to be important for this process. Moreover, we demonstrated that Lcb4p is delivered to the vacuole for degradation via the multivesicular body. Since forced accumulation of LCBPs results in prolonged growth during the stationary phase, down-regulation of Lcb4p may be physiologically important for proper cellular responses to nutrient deprivation.

Transmembrane topology of sphingoid long-chain base-1-phosphate phosphatase, Lcb3p.

Sphingoid long-chain base-1-phosphates (LCBPs) are thought to act as intracellular signalling molecules in yeast. Lcb3p is a member of the LCBPs-specific phosphatase family (SPP family). Other yeast phosphatases, Lpp1p and Dpp1p, are members of a different lipid phosphatase family (LPP family) known to exhibit broader substrate specificities. Until now, only the membrane topology of mammalian LPP family members has been reported, whereas that of the SPP family has remained unclear. In our in vitro system, Lcb3p displayed major phosphatase activity against dihydrosphingosine-1-phosphate, while Dpp1p and Lpp1p also exhibited activities. Here, we determined that Lpp1p and Dpp1p exhibit the topology common to the LPP family. Moreover, we examined the transmembrane topology of Lcb3p using a C-terminal reporter approach. From our results we deduced a structural model illustrating that Lcb3p has eight membrane-spanning domains with its highly conserved phosphatase motifs positioned within the endoplasmic reticulum (ER) lumen. Consistent with this result, Lcb3p collected in low speed pellet fractions was highly resistant to exogenous proteinase K unless the membrane was disrupted. Our results suggest that the active site of Lcb3p is located in the ER lumen and, thus, the phosphate group of the LCBP is hydrolysed on the lumenal side.

Ceramide/long-chain base phosphate rheostat in Saccharomyces cerevisiae: regulation of ceramide synthesis by Elo3p and Cka2p.

Sphingolipid precursors, namely, ceramide and long-chain base phosphates (LCBPs), are important growth regulators with often opposite effects on mammalian cells. A set of enzymes that regulate the levels of these precursors, referred to as a ceramide/LCBP rheostat, is conserved in all eukaryotes. In order to gain further insight into the function of the rheostat in Saccharomyces cerevisiae, we searched for mutants that are synthetically lethal with a deletion of the LCB3 gene encoding LCBP phosphatase. In addition to acquiring expected mutants lacking the LCBP lyase, the screen revealed elo3 (sur4) mutants that were defective in fatty acid elongation and cka2 mutants lacking the alpha' subunit of the protein kinase CK2 (casein kinase). Both mutations affected the in vivo activity of the acyl coenzyme A (acyl-CoA)-dependent and fumonisin B(1)-sensitive ceramide synthase (CS). The Elo3 protein is necessary for synthesis of C(26)-CoA, which in wild-type yeast is a source of C(26) fatty acyls found in the ceramide moieties of all sphingolipids. In the in vitro assay, CS had a strong preference for acyl-CoAs containing longer acyl chains. This finding suggests that a block in the formation of C(26)-CoA in yeast may cause a reduction in the conversion of LCBs into ceramides and lead to an overaccumulation of LCBPs that is lethal in strains lacking the Lcb3 phosphatase. In fact, elo3 mutants were found to accumulate high levels of LCBs and LCBPs. The cka2 mutants, on the other hand, exhibited only 25 to 30% of the in vitro CS activity found in wild-type membranes, indicating that the alpha' subunit of CK2 kinase is necessary for full activation of CS. The cka2 mutants also accumulated high levels of LCBs and had elevated levels of LCBPs. In addition, both the elo3 and cka2 mutants showed increased sensitivity to the CS inhibitors australifungin and fumonisin B(1). Together, our data demonstrate that the levels of LCBPs in yeast are regulated by the rate of ceramide synthesis, which depends on CK2 kinase activity and is also strongly affected by the supply of C(26)-CoA. This is the first evidence indicating the involvement of protein kinase in the regulation of de novo sphingolipid synthesis in any organism.

Lcb4p sphingoid base kinase localizes to the Golgi and late endosomes

Sphingoid long chain base phosphates (LCBPs) regulate cell proliferation, survival and motility in mammals. To learn more about LCBPs in Saccharomyces cerevisiae, we determined the cellular location of Lcb4p, the major enzyme catalyzing LCBP synthesis. By indirect immunofluorescence microscopy and subcellular fractionation, Lcb4p localizes to the trans-Golgi network and late endosomes and cycles between these compartments. Lcb4p faces the cytosol and is probably bound to membranes by protein–protein interactions. These results indicate that LCBs made in the endoplasmic reticulum must transit to the Golgi to be converted into LCBPs, which must then return to the endoplasmic reticulum to be degraded.

Identification and Characterization of aSaccharomyces cerevisiae Gene, RSB1, Involved in Sphingoid Long-chain Base Release

Sphingoid long-chain bases (LCBs) and long-chain base phosphates (LCBPs) act as signaling molecules in eukaryotic cells. Accumulation of LCBPs results in cell growth inhibition in yeast, although the mechanism is unknown. Here, we identified a novel yeast gene, RSB1 (resistance to sphingoid long-chain base), by screening a multicopy suppressor of the LCB-sensitive phenotype of the LCBP lyase mutant. RSB1 encodes a polypeptide of 354 amino acids with a molecular mass of 40.4 kDa. Rsb1p is predicted to be an integral membrane protein with seven transmembrane-spanning domains. We demonstrated that cells overproducing Rsb1p showed a decrease in accumulation of exogenously added sphingosine and dihydrosphingosine because of their increased release. This release was ATP-dependent, and a mutant of the predicted ATP binding motif had no activity. Substrate specificity analysis of Rsb1p demonstrated that it is active on LCBs but not on LCBPs or other hydrophobic compounds. These results suggest that Rsb1p is a transporter or flippase that translocates LCBs from the cytoplasmic side toward the extracytoplasmic side of the membrane.

Elevation of endogenous sphingolipid long-chain base phosphates kills Saccharomyces cerevisiae cells.

Sphingolipid long-chain base phosphates (LCBPs) regulate cell proliferation, movement and differentiation in higher eukaryotes. To study the function of LCBPs in Saccharomyces cerevisiae, we inactivated LCBP breakdown pathways. Elimination of both the Dpll lyase and the Lcb3 phosphatase pathways by gene deletion was lethal, indicating that these enzymes regulate LCBP levels to prevent accumulation. Lethality was prevented by eliminating the major LCB kinase. Lcb4p, which synthesizes LCBPs, but not by eliminating the minor LCB kinase, Lcb5p. These data imply that death results from an accumulation of LCBPs made by the Lcb4p kinase. By regulating Lcb4 kinase activity, we found that cell death correlates with LCBP accumulation and that C18 dihydrosphingosine-l-P (DHS-P) and C20 DHS-P are most likely the killing molecules. LCB levels were found to be most elevated in a strain lacking Lcb4 kinase, Dpll lyase and Lcb3 phosphatase activity. Analysis of mutant strains suggests that the C18 and C20 species of LCBPs are preferentially degraded by the Lcb3 phosphate phosphatase, while the Dpll lyase prefers C16 DHS-P as a substrate. These and other data indicate the existence of an unknown mechanism(s) for regulating LCB levels. Our results demonstrate that LCBPs may be used in some circumstances to regulate yeast cell growth.

Sphingoid base 1-phosphate phosphatase: a key regulator of sphingolipid metabolism and stress response.

The sphingolipid metabolites ceramide and sphingosine-1-phosphate are second messengers with opposing roles in mammalian cell growth arrest and survival; their relative cellular level has been proposed to be a rheostat that determines the fate of cells. This report demonstrates that this rheostat is an evolutionarily conserved stress-regulatory mechanism that influences growth and survival of yeast. Although the role of sphingosine-1-phosphate in yeast was not previously examined, accumulation of ceramide has been shown to induce G1 arrest and cell death. We now have identified a gene in Saccharomyces cerevisiae, LBP1, that regulates the levels of phosphorylated sphingoid bases and ceramide. LBP1 was cloned from a yeast mutant that accumulated phosphorylated long-chain sphingoid bases and diverted sphingoid base intermediates from sphingolipid pathways to glycerophospholipid biosynthesis. LBP1 and its homolog, LBP2, encode very hydrophobic proteins that contain a novel-conserved sequence motif for lipid phosphatases, and both have long-chain sphingoid base phosphate phosphatase activity. In vitro characterization of Lbp1p shows that this phosphatase is Mg2+-independent with high specificity for phosphorylated long-chain bases, phytosphingosine and sphingosine. The deletion of LBP1 results in the accumulation of phosphorylated long-chain sphingoid bases and reduced ceramide levels. Moreover, deletion of LBP1 and LBP2 results in dramatically enhanced survival upon severe heat shock. Thus, these phosphatases play a previously unappreciated role in regulating ceramide and phosphorylated sphingoid base levels in yeast, and they modulate stress responses through sphingolipid metabolites in a manner that is reminiscent of their effects on mammalian cells.