Systematic crosstalk in plasmalogen and diacyl lipid biosynthesis for their differential yet concerted molecular functions in the cell

Plasmalogen is a major phospholipid of mammalian cell membranes. Recently it is becoming evident that the sn-1 vinyl-ether linkage in plasmalogen, contrasting to the ester linkage in the counterpart diacyl glycerophospholipid, yields differential molecular characteristics for these lipids especially related to hydrocarbon-chain order, so as to concertedly regulate biological membrane processes. A role played by NMR in gaining information in this respect, ranging from molecular to tissue levels, draws particular attention. We note here that a broad range of enzymes in de novo synthesis pathway of plasmalogen commonly constitute that of diacyl glycerophospholipid. This fact forms the basis for systematic crosstalk that not only controls a quantitative balance between these lipids, but also senses a defect causing loss of lipid in either pathway for compensation by increase of the counterpart lipid. However, this inherent counterbalancing mechanism paradoxically amplifies imbalance in differential effects of these lipids in a diseased state on membrane processes. While sharing of enzymes has been recognized, it is now possible to overview the crosstalk with growing information for specific enzymes involved. The overview provides a fundamental clue to consider cell and tissue type-dependent schemes in regulating membrane processes by plasmalogen and diacyl glycerophospholipid in health and disease.     

Mutants in a macrophage-like cell line are defective in plasmalogen biosynthesis, but contain functional peroxisomes.

We have used a fluorescence-activated cytotoxicity protocol, 9-(1'-pyrene)nonanol (P9OH)/UV selection (Morand, O. H., Allen, L.-A. H., Zoeller, R. A., and Raetz, C. R. H. (1990) Biochim. Biophys. Acta 1034, 132-141), to isolate a series of plasmalogen-deficient mutants in a murine, macrophage-like cell line, RAW 264.7. Three of these mutants, RAW.7, RAW.12, and RAW.108, displayed varying degrees of plasmalogen deficiency (48, 17, and 14% of wild-type levels, respectively), and all three mutants were deficient in peroxisomal dihydroxyacetone phosphate (DHAP) acyltransferase activity (5% of wild-type). Unlike previously described Chinese hamster ovary (CHO) cell mutants, the RAW mutants contained intact, functional, peroxisomes and normal levels of alkyl-DHAP synthase activity, a peroxisomal, membrane-bound enzyme. In RAW.7 and RAW.108 cells, the loss of peroxisomal DHAP acyltransferase is the primary lesion. RAW.12 displayed not only a deficiency in the DHAP acyltransferase activity, but also displayed a second lesion in the biosynthetic pathway, a deficiency in delta 1'-desaturase activity (plasmanylethanolamine desaturase, EC 1.14.99.19), the final step in plasmenylethanolamine biosynthesis. The deficiencies expressed in the mutants represent unique lesions in plasmalogen biosynthesis. Since the RAW cell line is a macrophage-like responsive cell line, these mutants can be used to examine the role of plasmalogens in cellular functions such as arachidonic acid metabolism, prostaglandin synthesis, protein secretion, and signal transduction.     

Identification of a soluble protein stimulator of plasmalogen biosynthesis and stearoyl-coenzyme a desaturase

Stimulation of the desaturation of 1-alkyl-2-acyl-sn-glycero-3-phosphoethanolamine (GPE), which forms ethanolamine plasmalogens, by a component of the 105,000g supernatant has been previously reported. We have isolated the stimulatory protein and identified it as catalase. Purified rat liver catalase or commercial bovine liver catalase is as effective in stimulating microsomal 1-alkyl-2-acyl-GPE desaturation as the soluble proteins. The stimulatory effect of these proteins is eliminated by catalase inhibitors. It appears that catalase stimulates the desaturation of 1-alkyl-2-acyl-GPE by preventing inactivation of the enzyme system by H₂O₂ or a decomposition product of H₂O₂. The cytochrome b₅ content and NADH oxidation are depressed in Fischer R-3259 sarcoma microsomes by H₂O₂; this effect is eliminated by catalase. However, since measurable inhibition of 1-alkyl-2-acyl-GPE desaturase by H₂O₂ still occurred in the presence of catalase, the inhibition by H₂O₂ cannot be explained solely on the basis of cytochrome b₅ inactivation. The desaturation of stearoyl-coenzyme A, a reaction analogous in many respects to 1-alkyl-2-acyl-GPE desaturation, was also found to be stimulated by catalase.     

Isolation of soluble proteins capable of stimulating aerobic plasmalogen biosynthesis

The terminal step during aerobic plasmalogen biosynthesis is catalyzed by a microsomal desaturase system which converts 1-O-alkyl-2-acyl-sn-glycerophosphoethanolamine to 1-O-alk-1'-enyl-2-acyl-sn-glycerophosphoethanolamine (ethanolamine plasmalogen). The reaction depends on oxygen and NAD(P)H and is stimulated 3-10-fold by soluble activating factors contained in the 100 000 X g supernatant. Two stimulating proteins have been isolated from pig kidney; the partially purified proteins have identical molecular weights (27 000) but differ in their respective isoelectric points (protein I, 5.1 and protein II, 4.9). Both proteins behave identically in the biochemical studies conducted. Exogenous substrate binds to the stimulating proteins; the transfer of ethanolamine, but not of choline phospholipids, from liposomes to microsomes is enhanced by the stimulating proteins. They stimulate plasmalogen synthesis from either exogenous or endogenous substrate (synthesized from alkylglycerophosphoethanolamine by microsomal transacylases). The stimulating proteins have no enzymatic activity themselves; it is suggested that they affect events within the membrane and function as specific mediators between the membrane-bound enzyme system and the lipophilic substrate.     

Monolysocardiolipin in cultured fibroblasts is a sensitive and specific marker for Barth Syndrome

Barth Syndrome (BTHS) is an X-linked recessive disorder that results in abnormal metabolism of the mitochondrial phospholipid cardiolipin (CL). CLs are decreased and monolysocardiolipins (MLCLs), intermediates in CL metabolism, are increased in a variety of tissues. Measurement of decreased CL levels in skin fibroblasts has previously been proposed as a diagnostic test for BTHS. We investigated whether elevated MLCL is specific for BTHS and whether the MLCL-to-CL ratio is a more sensitive and specific marker for BTHS. We measured CLs and MLCLs in skin fibroblasts from 5 BTHS patients, 8 controls, and 14 patients with biochemical and clinical findings similar to those in BTHS (group D), using high performance liquid chromatography-mass spectrometry. Our results showed a clear decrease of CL in combination with a marked increase of MLCL in fibroblasts from BTHS patients when compared with controls. MLCL/CL ratios ranged from 0.03-0.12 in control fibroblasts and from 5.41-13.83 in BTHS fibroblasts. In group D, the MLCL/CL ratio range was 0.02-0.06. We therefore conclude that elevations of MLCLs are specific for BTHS and that the MLCL/CL ratio in fibroblasts is a better diagnostic marker than CL alone. We also report the finding of two novel mutations in the TAZ gene that cause BTHS.     

pH-dependent changes of ganglioside biosynthesis in neuronal cell culture

Ganglioside biosynthesis was studied in primary cultured murine cerebellar cells after labeling with [14C]galactose. A shift in biosynthesis from "a"-series to "b"-series gangliosides was observed after lowering the pH of the culture medium from 7.4 to 6.2; this effect was fully reversible on changing back to pH 7.4. The observed regulatory effect of pH is in accordance with a recent model of ganglioside biosynthesis. Sialyltransferase II (ST II), the first enzyme for biosynthesis of "b"-series gangliosides, is more active at pH 6.2 than Gal-NAc-transferase, the first enzyme for synthesis of "a"-series gangliosides, which is more active than sialyltransferase II at pH 7.4.     

Imaging of lipid biosynthesis: how a neutral lipid enters lipid droplets

The biosynthesis and storage of triglyceride (TG) is an important cellular process conserved from yeast to man. Most mammalian cells accumulate TG in lipid droplets, most prominent in adipocytes, which are specialized to store large amounts of the TG over long periods. In this study, we followed TG biosynthesis and targeting by fluorescence imaging in living 3T3-L1 adipocytes and COS7 fibroblasts. Key findings were (i) not only TG but also its direct metabolic precursor diacylglycerol, DG, accumulates on lipid droplets; (ii) the essential enzyme diacylglycerol acyltransferase 2 associates specifically with lipid droplets where it catalyzes the conversion of DG to TG and (iii) individual lipid droplets within one cell acquire TG at very different rates, suggesting unequal access to the biosynthetic machinery. We conclude that at least part of TG biosynthesis takes place in the immediate vicinity of lipid droplets. In vitro assays on purified lipid droplets show that this fraction of the biosynthetic TG is directly inserted into the growing droplet.     

Mitochondrial respiratory chain supercomplexes are destabilized in Barth Syndrome patients

Mutations in the human TAZ gene are associated with Barth Syndrome, an often fatal X-linked disorder that presents with cardiomyopathy and neutropenia. The TAZ gene encodes Tafazzin, a putative phospholipid acyltranferase that is involved in the remodeling of cardiolipin, a phospholipid unique to the inner mitochondrial membrane. It has been shown that the disruption of the Tafazzin gene in yeast (Taz1) affects the assembly and stability of respiratory chain Complex IV and its supercomplex forms. However, the implications of these results for Barth Syndrome are restricted due to the additional presence of Complex I in humans that forms a supercomplex with Complexes III and IV. Here, we investigated the effects of Tafazzin, and hence cardiolipin deficiency in lymphoblasts from patients with Barth Syndrome, using blue-native polyacrylamide gel electrophoresis. Digitonin extraction revealed a more labile Complex I/III(2)/IV supercomplex in mitochondria from Barth Syndrome cells, with Complex IV dissociating more readily from the supercomplex. The interaction between Complexes I and III was also less stable, with decreased levels of the Complex I/III(2) supercomplex. Reduction of Complex I holoenzyme levels was observed also in the Barth Syndrome patients, with a corresponding decrease in steady-state subunit levels. We propose that the loss of mature cardiolipin species in Barth Syndrome results in unstable respiratory chain supercomplexes, thereby affecting Complex I biogenesis, respiratory activities and subsequent pathology.     

Inhibition of peroxyl radical-mediated lipid oxidation by plasmalogen phospholipids and alpha-tocopherol

The recently discovered peroxyl radical scavenging properties of plasmalogen phospholipids led us to evaluate their potential interactions with alpha-tocopherol. The oxidative decay of plasmalogen phospholipids and of polyunsaturated fatty acids as induced by peroxyl radicals (generated from 2,2'-azobis-2-amidinopropane hydrochloride; AAPH) was studied in micelles using 1H-NMR and chemical analyses. In comparison with alpha-tocopherol, a 20- to 25-fold higher concentration of plasmalogen phospholipids was needed to induce a similar inhibition of peroxyl radical-mediated oxidation of polyunsaturated fatty acids. Plasmalogen phospholipids and alpha-tocopherol protected each other from oxidative degradation. In low-density lipoproteins (LDL) and micelles supplemented with plasmalogen phospholipids plus alpha-tocopherol, the peroxyl radical-promoted oxidation was additively diminished. The differences in the capacities to inhibit oxidation processes induced by peroxyl radicals between the plasmalogen phospholipids and alpha-tocopherol were less pronounced in the LDL particles than in the micelles. In conclusion, plasmalogen phospholipids and alpha-tocopherol apparently compete for the interaction with the peroxyl radicals. Oxidation processes induced by peroxyl radicals are inhibited in an additive manner in the presence of the two radical scavengers. The contribution of the plasmalogen phospholipids to the protection against peroxyl radical promoted oxidation in vivo is expected to be at least as important as that of alpha-tocopherol.     

Cardiac Metabolic Pathways Affected in the Mouse Model of Barth Syndrome

Cardiolipin (CL) is a mitochondrial phospholipid essential for electron transport chain (ETC) integrity. CL-deficiency in humans is caused by mutations in the tafazzin (Taz) gene and results in a multisystem pediatric disorder, Barth syndrome (BTHS). It has been reported that tafazzin deficiency destabilizes mitochondrial respiratory chain complexes and affects supercomplex assembly. The aim of this study was to investigate the impact of Taz-knockdown on the mitochondrial proteomic landscape and metabolic processes, such as stability of respiratory chain supercomplexes and their interactions with fatty acid oxidation enzymes in cardiac muscle. Proteomic analysis demonstrated reduction of several polypeptides of the mitochondrial respiratory chain, including Rieske and cytochrome c1 subunits of complex III, NADH dehydrogenase alpha subunit 5 of complex I and the catalytic core-forming subunit of F₀F₁-ATP synthase. Taz gene knockdown resulted in upregulation of enzymes of folate and amino acid metabolic pathways in heart mitochondria, demonstrating that Taz-deficiency causes substantive metabolic remodeling in cardiac muscle. Mitochondrial respiratory chain supercomplexes are destabilized in CL-depleted mitochondria from Taz knockdown hearts resulting in disruption of the interactions between ETC and the fatty acid oxidation enzymes, very long-chain acyl-CoA dehydrogenase and long-chain 3-hydroxyacyl-CoA dehydrogenase, potentially affecting the metabolic channeling of reducing equivalents between these two metabolic pathways. Mitochondria-bound myoglobin was significantly reduced in Taz-knockdown hearts, potentially disrupting intracellular oxygen delivery to the oxidative phosphorylation system. Our results identify the critical pathways affected by the Taz-deficiency in mitochondria and establish a future framework for development of therapeutic options for BTHS.     

Establishment of a lipid accumulation model in an insect cell line

The study of adipocyte differentiation and lipid accumulation in insects has been limited by the lack of a system suitable for analysis of molecular mechanisms. Here, we describe the establishment of a model system of lipid accumulation in BmN4 cells, which are derived from silkworm ovary. In BmN4 cells, dexamethasone treatment induced accumulation of lipid, suppressed cellular proliferation, and caused the cells to form aggregates. We isolated the Bombyx mori fatty acid binding protein 1 gene (BmFABP1), which is the silkworm homologue of mouse Fabp4 (aP2), a marker of adipocyte differentiation in mammals. BmFABP1 expression was increased by dexamethasone treatment. We also isolated the BmFABP1 promoter, and found that it was activated by a combination of drugs that included dexamethasone. The demonstration of dexamethasone-stimulated lipid accumulation and BmFABP1 expression in BmN4 cells provides a useful model of inducible adipogenesis. This system should be valuable for investigation of the molecular mechanisms of fat body formation, adipocyte differentiation, and lipid accumulation in the silkworm and other Lepidopteran insects.     

Undecaprenyl diphosphate synthase,a cis-prenyltransferase synthesizing lipid carrier for bacterial cell wall biosynthesis

Abstract

A group of prenyltransferases produce linear lipids by catalyzing consecutive condensation reactions of farnesyl diphosphate (FPP) with specific numbers of isopentenyl diphosphate (IPP), a common building block of isoprenoid compounds. Depending on the stereochemistry of the double bonds formed during IPP condensation, these prenyltransferases are categorized as cis- and trans-types. Undecaprenyl diphosphate synthase (UPPS) that catalyzes chain elongation of FPP by consecutive condensation reactions with eight IPP, to form C₅₅ lipid carrier for bacterial cell wall biosynthesis, serves as a model for understanding cis-prenyltransferases. In this review, the current knowledge in UPPS kinetics, mechanisms, structures, and inhibitors is summarized.     

Compartmentalization of lipid biosynthesis in mycobacteria

The plasma membrane of Mycobacterium sp. is the site of synthesis of several distinct classes of lipids that are either retained in the membrane or exported to the overlying cell envelope. Here, we provide evidence that enzymes involved in the biosynthesis of two major lipid classes, the phosphatidylinositol mannosides (PIMs) and aminophospholipids, are compartmentalized within the plasma membrane. Enzymes involved in the synthesis of early PIM intermediates were localized to a membrane subdomain termed PMf, that was clearly resolved from the cell wall by isopyknic density centrifugation and amplified in rapidly dividing Mycobacterium smegmatis. In contrast, the major pool of apolar PIMs and enzymes involved in polar PIM biosynthesis were localized to a denser fraction that contained both plasma membrane and cell wall markers (PM-CW). Based on the resistance of the PIMs to solvent extraction in live but not lysed cells, we propose that polar PIM biosynthesis occurs in the plasma membrane rather than the cell wall component of the PM-CW. Enzymes involved in phosphatidylethanolamine biosynthesis also displayed a highly polarized distribution between the PMf and PM-CW fractions. The PMf was greatly reduced in non-dividing cells, concomitant with a reduction in the synthesis and steady-state levels of PIMs and amino-phospholipids and the redistribution of PMf marker enzymes to non-PM-CW fractions. The formation of the PMf and recruitment of enzymes to this domain may thus play a role in regulating growth-specific changes in the biosynthesis of membrane and cell wall lipids.