Raphael A. Zoeller scite author profile

Sphingosine 1-phosphate (S1P) functions not only as a bioactive lipid molecule, but also as an important intermediate of the sole sphingolipid-to-glycerolipid metabolic pathway. However, the precise reactions and the enzymes involved in this pathway remain unresolved. We report here that yeast HFD1 and the Sjögren-Larsson syndrome (SLS)-causative mammalian gene ALDH3A2 are responsible for conversion of the S1P degradation product hexadecenal to hexadecenoic acid. The absence of ALDH3A2 in CHO-K1 mutant cells caused abnormal metabolism of S1P/hexadecenal to ether-linked glycerolipids. Moreover, we demonstrate that yeast Faa1 and Faa4 and mammalian ACSL family members are acyl-CoA synthetases involved in the sphingolipid-to-glycerolipid metabolic pathway and that hexadecenoic acid accumulates in Δfaa1 Δfaa4 mutant cells. These results unveil the entire S1P metabolic pathway: S1P is metabolized to glycerolipids via hexadecenal, hexadecenoic acid, hexadecenoyl-CoA, and palmitoyl-CoA. From our results we propose a possibility that accumulation of the S1P metabolite hexadecenal contributes to the pathogenesis of SLS.

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The TMEM189 gene encodes plasmanylethanolamine desaturase which introduces the characteristic vinyl ether double bond into plasmalogens

Werner

Keller

Sailer

et al. 2020

Proc. Natl. Acad. Sci. U.S.A.

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A significant fraction of the glycerophospholipids in the human body is composed of plasmalogens, particularly in the brain, cardiac, and immune cell membranes. A decline in these lipids has been observed in such diseases as Alzheimer’s and chronic obstructive pulmonary disease. Plasmalogens contain a characteristic 1-O-alk-1′-enyl ether (vinyl ether) double bond that confers special biophysical, biochemical, and chemical properties to these lipids. However, the genetics of their biosynthesis is not fully understood, since no gene has been identified that encodes plasmanylethanolamine desaturase (E.C. 1.14.99.19), the enzyme introducing the crucial alk-1′-enyl ether double bond. The present work identifies this gene as transmembrane protein 189 (TMEM189). Inactivation of theTMEM189gene in human HAP1 cells led to a total loss of plasmanylethanolamine desaturase activity, strongly decreased plasmalogen levels, and accumulation of plasmanylethanolamine substrates and resulted in an inability of these cells to form labeled plasmalogens from labeled alkylglycerols. Transient expression of TMEM189 protein, but not of other selected desaturases, recovered this deficit. TMEM189 proteins contain a conserved protein motif (pfam10520) with eight conserved histidines that is shared by an alternative type of plant desaturase but not by other mammalian proteins. Each of these histidines is essential for plasmanylethanolamine desaturase activity. Mice homozygous for an inactivatedTmem189gene lacked plasmanylethanolamine desaturase activity and had dramatically lowered plasmalogen levels in their tissues. These results assign theTMEM189gene to plasmanylethanolamine desaturase and suggest that the previously characterized phenotype ofTmem189-deficient mice may be caused by a lack of plasmalogens.

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Isolation of animal cell mutants deficient in plasmalogen biosynthesis and peroxisome assembly.

Zoeller¹,

Raetz²

1986

Proc. Natl. Acad. Sci. U.S.A.

126

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A rapid autoradiographic screening procedure has been developed for identifying Chinese hamster ovary cell mutants defective in the peroxisomal enzyme dihydroxyacetonephosphate (DHAP) acyltransferase. Ten mutants were found among 60,000 colonies grown from a stock of mutagentreated cells, and 3 have been characterized with respect to their enzymology and phospholipid biosynthesis. All three contain 3% (or less) of the parental DHAP acyltransferase activity measured at pH 5.5, the optimum for the peroxisomal enzyme. When measured at pH 7.4, all three contained 70-85% of the wild-type activity, but it was sensitive to Nethylmaleimide. Glycerol-3-phosphate acyltransferase activities were identical in mutant and parent strains. Two other peroxisomal enzymes, alkyl-DHAP synthase and particulate catalase, were also reduced by factors of 5-10 in all three mutants, suggesting that these strains are deficient in some aspect of peroxisome assembly, possibly like cells from patients with Zellweger syndrome. Short-term and long-term labeling with 32Pi revealed that these mutants are grossly deficient in the de novo synthesis and content of plasmalogens. In parental cells the plasmalogen form of phosphatidylethanolamine constitutes 7.1% of the total phospholipid, but it is reduced to 0.7% in the mutants. This decrease is accompanied by a compensatory increase in the diacyl form of phosphatidylethanolamine. The results presented here support the view that there are two DHAP acyltransferases in animal cells and that the peroxisome is essential for the biosynthesis of plasmalogens.In animal cells, the acylation of dihydroxyacetonephosphate (DHAP) represents one of two biosynthetic pathways leading to phosphatidic acid, and it is thought to be an obligatory step in the production of ether lipids (1). It is generally accepted that the acylation of DHAP is catalyzed by a peroxisomal DHAP acyltransferase (acylTase) (1), but evidence suggests the presence of a second, microsomal isozyme (2, 3). The latter may represent a dual catalytic function of the microsomal glycerol-3-phosphate (Gro-3-P) acylTase and can be distinguished from the peroxisomal activity by its neutral pH optimum (pH 7.2 vs. pH 5.5-6.0) and its sensitivity to inhibition by N-ethylmaleimide (MalNEt) (2, 3). The existence of a second DHAP acylTase activity is considered controversial, since some studies attribute any activity found in the microsomal fraction to peroxisomal contamination (4, 5). Consequently, the number of DHAP acylTases and their roles in phospholipid biosynthesis remain uncertain.In an effort to resolve these issues and to study the function of plasmalogens, we have designed a rapid colony screening procedure for identifying Chinese hamster ovary (CHO) cell mutants deficient in the peroxisomal DHAP acylTase. Initial characterization of three such CHO mutant strains supports a central role for peroxisomes in plasmalogen biosynthesis and also provides strong evidence for the existence of a second DHAP acylTase activity. Furthermore, these muta...

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Plasmalogens as endogenous antioxidants: somatic cell mutants reveal the importance of the vinyl ether

et al. 1999

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Exposure of plasmalogen-deficient variants of the murine cell line RAW 264.7 to short-term (0-100 min) treatment with electron transport inhibitors antimycin A or cyanide (chemical hypoxia) resulted in a more rapid loss of viability than in the parent strain. Results suggested that plasmalogen-deficient cells were more sensitive to reactive oxygen species (ROS) generated during chemical hypoxia; the mutants could be rescued from chemical hypoxia by using the antioxidant Trolox, an alpha-tocopherol analogue, and they were more sensitive to ROS generation by plumbagin or by rose bengal treatment coupled with irradiation. In addition, the use of buffers containing 2H2O greatly enhanced the cytotoxic effect of chemical hypoxia, suggesting the involvement of singlet oxygen. We used the unique enzymic deficiencies displayed by the mutants to differentially restore either plasmenylethanolamine (the major plasmalogen species normally found in this cell line) or its biosynthetic precursor, plasmanylethanolamine. Restoration of plasmenylethanolamine, which contains the vinyl ether, resulted in wild-type-like resistance to chemical hypoxia and ROS generators, whereas increasing levels of its precursor, which bears the saturated ether, had no effect on cell survival. These findings identify the vinyl ether double bond as a crucial element in cellular protection under these conditions and support the hypothesis that plasmalogens, through the vinyl ether, act as antioxidants to protect cells against ROS. These phospholipids might protect cells from ROS-mediated damage during events such as chemical hypoxia.

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