Preparation and characterization of well defined d-erythro sphingomyelins

A simple semisynthetic procedure for the preparation of various d-erythro sphingomyelins (SPMs), differing in their acyl chains, is described. They were prepared by one-step condensation of the desired free fatty acid with sphingosyl phosphorylcholine (SPC) using dicyclohexylcarbodiimide. The d-erythro SPMs were obtained in high purity, high yields and resemble bovine brain SPM in their chromatographic behavior, infrared, circular dichroism (CD) and proton NMR (PMR) spectra as well as in their rate of hydrolysis by Staphylococcus aureus sphingomyelinase. Multilamellar vesicles can be prepared from the semisynthetic SPMs. Their thermotropic behavior is dependent mainly on the acyl chain though it is also affected by the heterogeneity of the sphingosine base composition. Intact sealed small unilamellar vesicles (SUV) cannot be prepared from a single semisynthetic saturated SPM but can be prepared from their mixtures. This acylation procedure can also be applied for preparing simple neutral glycosphingolipids. The sphingolipids prepared by this method can be used to study metabolism, enzymology and physicochemical properties of d-erythro well defined simple sphingolipids.     

METABOLISM OF BRAIN SPHINGOMYELINS: HALF-LIVES OF SPHINGOSINE, FATTY ACIDS AND PHOSPHATE FROM TWO TYPES OF RAT BRAIN SPHINGOMYELIN

Abstract— The metabolism of rat brain sphingomyelins containing short-chain (C₁₆-C₁₈) and long-chain (C₂₀- C₂₄) fatty acids has been studied by determination of the content of radioactivity in the sphingo-sinc. fatty acids and phosphate of the sphingomyelins over a period of 60 days following the intracisternal injection of [¹⁴C]acetate and [³²P]phosphate. From the rate of decrease of the specific radioactivities of the different constituents of short-chain fatty acid sphingomyelins, we have calculated a half-life of 65 days for sphingosine. 41 days for fatty acids and 62 days for phosphate. For the long-chain fatty acid sphingomyelins the half-life of sphingosine was approximately 465 days. The fatty acids and phosphate from these sphingomyelins had fast and slow turnover pools. The half-life for the fast pool was 7 days for the two constituents and the estimated half-lives for the slow pool were 220 days for fatty acids and 480 days for phosphate. These results suggest that one can distinguish at least three metabolic pools of brain sphingomyelins: (a) sphingomyelins with long-chain fatty acids situated in myelin whose half-lives are 465 days for sphingosine, 220 days for fatty acids and 480 days for phosphate; (b) sphingomyelins with long-chain fatty acids located mainly in non-myelin structures having half-lives of 465 days for sphingosine. 7 days for fatty acids and 7 days for phosphate; (c) sphingomyeiins with short-chain fatty acids with half-lives of 65 days for sphingosine. 41 days for fatty acids and 62 days for phosphate. The differences between the half-lives of the three metabolic pools of sphingomyelin, together with the subcellular localizations of the two molecular species of these compounds, suggest that the metabolism of the different molecular species of sphingomyelin are independent and that in various subcellular fractions the long-chain fatty acid and short-chain fatty acid sphingomyelins have different turnover rates.     

An expedient synthesis of fluorescent labeled ceramide-1-phosphate analogues

A synthesis for fluorescent analogs of ceramide-1-phosphate bearing 9-anthrylvinyl or 4,4-difluoro-3a,4a-diaza-s-indacene-8-yl (Me₄-BODIPY) fluorophore at co-position of fatty acid residue was carried out. The key stage of the synthesis is hydrolysis of corresponding sphingomyelins catalyzed by phospholipase D from Streptomyces chromofuscus; the enzymatic yield has been raised to 50–70% by appliance of organic solvent in the incubation medium.     

New approaches to synthesis of stereospecific sphingomyelin

Enormous progress in the asymmetric synthesis of stereochemically and chemically pure D-erythro-sphingosine and ceramides led to the development of a practical, efficient, easily scaleable process to provide industrial quantities of chiral sphingosine and ceramides. This established a new platform of chiral starting materials which facilitate the synthesis of complex sphingolipids. Utilizing stereochemically homogeneous, fully synthetic ceramides, two efficient synthetic methods were developed for the preparation of ultra pure stereochemically homogeneous sphingomyelins. The first method adapted highly efficient phosphoramidite technology from oligonucleotide chemistry. This method allows selective insertion of a phosphocholine moiety into 3-O-protected ceramide through phosphitylation, followed by choline attachment, phosphite oxidation and deprotection. This route provides stereochemically homogeneous sphingomyelin in 35-79% yield. The second route is based on the reaction of selectively protected ceramides with cyclic chlorophosphate followed by treatment with trimethylamine to give the desired sphingomyelins in 50% yield. Multigram quantities of 14C-labeled N-palmitoyl-D-erythro-sphingomyelin were produced with specific activity > 1000 dpm/nmol.     

Age-Dependent Changes in the Sphingolipid Composition of Mouse CD4+ T Cell Membranes and Immune Synapses Implicate Glucosylceramides in Age-Related T Cell Dysfunction

To determine whether changes in sphingolipid composition are associated with age-related immune dysfunction, we analyzed the core sphingolipidome (i.e., all of the metabolites through the first headgroup additions) of young and aged CD4⁺ T cells. Since sphingolipids influence the biophysical properties of membranes, we evaluated the compositions of immune synapse (IS) and non-IS fractions prepared by magnetic immuno-isolation. Broadly, increased amounts of sphingomyelins, dihydrosphingomyelins and ceramides were found in aged CD4⁺ T cells. After normalizing for total sphingolipid content, a statistically significant decrease in the molar fraction of glucosylceramides was evident in both the non-IS and IS fractions of aged T cells. This change was balanced by less dramatic increases in the molar fractions of sphingomyelins and dihydrosphingomyelins in aged CD4⁺ T cells. In vitro, the direct or enzymatic enhancement of ceramide levels decreased CD4⁺ T cell proliferation without regard for the age of the responding T cells. In contrast, the in vitro inhibition of glucosylceramidase preferentially increased the proliferation of aged CD4⁺ T cells. These results suggest that reductions in glucosylceramide abundance contribute to age-related impairments in CD4⁺ T cell function.     

Individual profiles of free ceramide species and the constituent ceramide species of sphingomyelin and neutral glycosphingolipid and their alteration according to the sequential changes of environmental oxygen content in human colorectal cancer Caco-2 cells

We previously performed a systematic analysis of free ceramide (Cers) species, the constituent ceramide species of sphingomyelins and neutral glycosphingolipids (NGSLs) using matrix-assisted laser desorption/ionization time-of-flight mass spectrometry with high-energy collision-induced dissociation. As a result, distinct species differences were found among Cers, sphingomyelins and NGSLs in the kidneys. Using this method, we investigated various sphingolipid species from human colon cancer Caco-2 cells as well as the influence of environmental oxygen on these species in detail. Unexpectedly, even in normoxia, all Cers species were composed of dihydrosphingosine (d18:0) and non-hydroxy fatty acid (NFA), and 34 % of sphingomyelins were composed of dihydrosphingomyelins with NFA. In contrast, major constituent ceramide species of NGSLs were composed of the usual long-chain base of sphingosine (d18:1) and hydroxy fatty acid (HFA). When the cells were cultured under hypoxic condition for 3 days, all the Cers and nearly 80 % of the sphingomyelins were dihydrosphingolipids composed of d18:0-NFAs, but a significant proportion of d18:1-HFAs still remained in the NGSLs. When the cells were transferred from conditions of hypoxia to normoxia again (reoxygenation), Cer species composed of d18:1-NFAs, which were not found in Cers under the original normoxic conditions, appeared. Such Cers were probably synthesized as precursors for the constituent ceramides of sphingomyelins and NGSLs.     

Presence of unsaturated sphingomyelins and changes in their composition during the life cycle of the moth Manduca sexta

NMR and electrospray ionization tandem mass spectrometry were used to show for the first time the presence of sphingomyelins in extracts of the tobacco hornworm Manduca sexta (Lepidoptera). The sphingosine in the ceramide was identified as tetradecasphing-4-enine, and the fatty acids were C18:0, C20:0, C22:0, and C24:0 (compound 1). Heterogeneity in the ceramide was observed in sphingomyelins from M. sexta. All of the sphingomyelins were associated with their doubly unsaturated sphingosine, tetradecasphing-4,6-dienine (compound 2), which contained the same set of fatty acids as compound 1 and represents a novel set of sphingomyelins not previously reported in Lepidoptera. Lipid rafts were isolated from brains of M. sexta, and the association of these novel sphingomyelins with rafts was confirmed. The existence of the additional double bond was also observed in ceramide and ceramide phosphoethanolamine isolated from M. sexta. The levels of the doubly unsaturated ceramide showed modest changes during metamorphosis of M. sexta. These results suggest that Manduca sphingomyelins may participate in the formation of lipid rafts, in keeping with their function in vertebrates.     

Dihydroceramides: From Bit Players to Lead Actors

Sphingolipid synthesis involves a highly conserved biosynthetic pathway that produces fundamental precursors of complex sphingolipids. The final reaction involves the insertion of a double bond into dihydroceramides to generate the more abundant ceramides, which are converted to sphingomyelins and glucosylceramides/gangliosides by the addition of polar head groups. Although ceramides have long been known to mediate cellular stress responses, the dihydroceramides that are transiently produced during de novo sphingolipid synthesis were deemed inert. Evidence published in the last few years suggests that these dihydroceramides accumulate to a far greater extent in tissues than previously thought. Moreover, they have biological functions that are distinct and non-overlapping with those of the more prevalent ceramides. Roles are being uncovered in autophagy, hypoxia, and cellular proliferation, and the lipids are now implicated in the etiology, treatment, and/or diagnosis of diabetes, cancer, ischemia/reperfusion injury, and neurodegenerative diseases. This minireview summarizes recent findings on this emerging class of bioactive lipids.     

Quantitation and molecular species determination of diacylglycerols, phosphatidylcholines, ceramides, and sphingomyelins with gas chromatography

In addition to the role of building block for biological membranes, phospholipids and their metabolites have been implicated in other important cellular functions, such as proliferation and apoptosis. Ceramides and their precursor, sphingomyelin, are thought to play a role in cellular apoptosis. In contrast, the metabolism of diacylglycerols and one of their precursors, phosphatidylcholine, is thought to be partly responsible for the opposite effect, cellular proliferation. Quantitative determination of these lipids in biological samples is important in investigating the complicated interactions between these molecules. In this report, we describe a capillary gas chromatographic procedure for the quantitative determination of molecular species of diacylglycerols, ceramides, phosphatidylcholines, and sphingomyelins. Lipid extracts are separated into these classes with a silica gel column. Diacylglycerols and ceramides are analyzed as trimethylsilyl derivatives. Phosphatidylcholines and sphingomyelins are converted to their diacylglycerol and ceramide components with sphingomyelinase hydrolysis. Internal standards for each analyzed fraction are used in the procedure. This method is used to determine the lipids in liver homogenate and subcellular fractions, including mitochondria, light mitochondria, and microsomes from young and old Fischer 344 rats. Our data show that the ceramide and sphingomyelin content is higher in the mitochondria of old rats. This relationship is consistent with the potential role of ceramide in mitochondria-induced apoptosis. More study is needed to substantiate this relationship.     

Interfacial regulation of bacterial sphingomyelinase activity

The objective of this study was to define how the quality of the buffer/membrane interface influences the activity of bacterial sphingomyelinase acting at the interface. The enzyme reaction was carried out in a zero-order trough using a surface barostat. This approach allowed for proper control of the physico-chemical properties of the substrate molecules. Since the molecular area of ceramide is smaller than that of sphingomyelin, the hydrolysis reaction could be followed `on-line' from the monolayer area decrease at constant surface pressure. The hydrolysis reaction could be divided into two separate phases, the first being the lag-phase (time between enzyme addition and commencement of the monolayer area change), and the second phase being the actual hydrolysis reaction (from which a maximal degradation rate could be determined). The activity of sphingomyelinase (Staphylococcus aureus) toward bovine brain sphingomyelin (bb-SM) was markedly enhanced by Mg²⁺ (maximal activation at 5 mM). Mg²⁺ also influenced the lag-phase of the reaction (the lag-time increased markedly when the Mg²⁺ concentration decreased below 1 mM). Saturated sphingomyelins (bb-SM and N-palmitoyl sphingomyelin [N-P-SM]) were more slowly degraded than the mono-unsaturated N-oleoyl sphingomyelin (N-O-SM). Both bb-SM and N-P-SM monolayers underwent a phase-transition at room temperature, whereas the N-O-SM monolayer did not. The phase-transition (liquid-expanded to liquid-condensed) was observed to greatly increase the lag-time of the hydrolysis reaction. The activity of sphingomyelinase was also sensitive to the lateral surface pressure of the monolayer membrane. Maximal degradation rate was achieved at 20 mN/m (with bb-SM, 30°C); above this pressure the lag-time of the reaction increased sharply. The inclusion of 4 mol% of cholesterol into a [³H]sphingomyelin monolayer markedly increased the extent of [³H]sphingomyelin degradation, and shortened the lag-time of the reaction. The inclusion of 10 mol% of zwitterionic or negatively charged phospholipids to the [³H]sphingomyelin monolayer did not affect the sphingomyelinase reaction significantly. In conclusion, this study has demonstrated that the physico-chemical properties of the substrate molecules have a dominating influence on the activity of a bacterial sphingomyelinase acting at the buffer/membrane interface.     

Evidence for a high activity of sphingomyelin biosynthesis by phosphocholine transfer from phosphatidylcholine to ceramides in lung lamellar bodies

Biosynthesis of sphingomyelin from ceramides was investigated in lung subcellular fractions by incubating a lyophilized mixture of albumin and subcellular fraction (0.1-0.2 mg of protein) coated with [acyl-14C]-ceramide and phosphatidyl[methyl-3H]choline in Tris-buffer. The lamellar-body-rich fraction exhibited the highest specific activity for sphingomyelin biosynthesis measured by 14C incorporation into sphingomyelins or by [3H]phosphocholine transfer from phosphatidylcholines. Plasma membranes formed the next most active fraction, followed by the 'smooth' and, then, the 'rough' endoplasmic reticulum. Sphingomyelin biosynthesis by lamellar bodies was optimum at pH 7.4 and was inhibited by sphingomyelins formed. Slight inhibitory effects were also observed with Mn2+, Ca2+ and lysophosphatidylcholine. Phosphocholine transfer from CDPcholine was not observed under the reaction conditions employed. Ceramide conversion and phosphocholine transfer increased with ceramide concentration to reach a maximum at about 0.06 mM. The highest conversion rate was observed when 18:1 ceramide was used as an acceptor. When 1-palmitoyl-2-oleoylphosphatidylcholine was the phosphocholine donor, the overall biosynthesis of sphingomyelin was much higher than when using dipalmitoylphosphatidylcholine. These results suggest the possible involvement of the studied reaction in the control of the degree of saturation of the surfactant phosphatidylcholine.     

Differential involvement of rat sperm choline glycerophospholipids and sphingomyelin in capacitation and the acrosomal reaction

Rat spermatozoa main lipid classes and their fatty acids were studied to assess their possible changes in capacitation and the acrosomal reaction (AR), induced in vitro. Capacitation-associated protein tyrosine phosphorylation, and the efflux of 30% of the total cholesterol from gametes to the medium, took place concomitantly with the release of a similar percentage, i.e., a larger amount, of the total phospholipid, mostly after hydrolysis of the major choline glycerophospholipids (CGP). Main medium lipid metabolites after capacitation were lyso-CGP and polyenoic fatty acids typical of CGP (22:4n-9, 22:5n-6), as free fatty acids (FFA). The AR, induced by a calcium ionophore, resulted in further phospholipid loss, but the produced metabolites remained in the gametes. CGP decrease in AR accounted for some additional FFA and lyso-CGP, but mostly for (22:5n-6-rich) diglycerides. Hydrolysis of sphingomyelins (SM) to ceramides also occurred, mostly affecting species with very long chain polyenoic fatty acids. Quantitatively, CGP and SM were the lipid classes decreasing the most after capacitation and AR, respectively. The massive cholesterol and phospholipid loss from the gametes during capacitation is thus associated with protein phosphorylation, a function that has been located to the sperm tail. The lipid metabolites produced during AR, by accumulating in the gamete heads, could be implicated in sperm–oocyte interactions.     

Comparison of the biophysical properties of racemic and d-erythro-N-acyl sphingomyelins.

In this study stereochemically pure d-erythro-sphingomyelins (SMs) with either 16:0 or 18:1(cisDelta9) as the N-linked acyl-chain were synthesized. Our purpose was to examine the properties of these sphingomyelins and acyl-chain matched racemic (d-erythro/l-threo) sphingomyelins in model membranes. Liquid-expanded d-erythro-N-16:0-SM in monolayers was observed to pack more densely than the corresponding racemic sphingomyelin. Cholesterol desorption to beta-cyclodextrin was significantly slower from d-erythro-N-16:0-SM monolayers than from racemic N-16:0-SM monolayers. Significantly more condensed domains were seen in cholesterol/d-erythro-N-16:0-SM monolayers than in the corresponding racemic mixed monolayers, when [7-nitrobenz-2-oxa-1, 3-diazol-4-yl]phosphatidylcholine was used as a probe in monolayer fluorescence microscopy. With monolayers of N-18:1-SMs, both the lateral packing densities (sphingomyelin monolayers) and the rates of cholesterol desorption (mixed cholesterol/sphingomyelin monolayers) was found to be similar for d-erythro and racemic sphingomyelins. The phase transition temperature and enthalpy of d-erythro-N-16:0-SM in bilayer membranes were slightly higher compared with the corresponding racemic sphingomyelin (41.1 degrees C and 8.4 +/- 0.4 kJ/mol, and 39.9 degrees C and 7.2 +/- 0.2 kJ/mol, respectively). Finally, d-erythro-sphingomyelins in monolayers (both N-16:0 and N-18:1 species) were not as easily degraded at 37 degrees C by sphingomyelinase (Staphylococcus aureus) as the corresponding racemic sphingomyelins. We conclude that racemic sphingomyelins differ significantly in their biophysical properties from the physiologically relevant d-erythro sphingomyelins.     

Correlation between the thermotropic behavior of sphingomyelin liposomes and sphingomyelin hydrolysis by sphingomyelinase of Staphylococcus aureus

The hydrolysis of d-erythro beef brain sphingomyelin and $\text{d,l}\text{-erythro}\text{-N-}\text{palmitoylsphingomyelin}$ dispersed as multilamellar liposomes by sphingomyelinase of Staphylococcus aureus is correlated with the thermotropic behavior of the sphingomyelins. In both cases maximal enzymatic hydrolysis was achieved at the beginning of the gel to liquid crystalline phase transition (30°C for beef brain sphingomyelin and 41°C for N-palmitoylsphingosinephosphorylcholine) with much lower activity both below and above these temperatures. The enzymatic activity was depressed in the presence of cholesterol in the bilayer which also depressed the phase transition. The profile of the enzymatic activity is explained by the uniqueness of the lipid molecules arrangement at the phase transition.     

Coupled assay of sphingomyelin and ceramide molecular species by gas liquid chromatography

This study reports a single-step analysis of the molecular species of endogenous ceramides and of the ceramide moiety of sphingomyelins in biological samples, using gas liquid chromatography (GLC). Silylated sphingomyelins were quantitatively converted to monosilylated ceramide upon injection into GLC, whereas the free ceramides were di-silylated on the primary and secondary alcohol function, as confirmed by mass spectrometry. The reproducible shift of the retention times between the mono- and di-silylated derivatives enables simultaneous quantification of the variety of sphingomyelin and ceramide molecular species. Overlapping diacylglycerols were first removed by a mild alkaline treatment of the lipid extract. The lowest detection limit (5 pmol) did not allow for identification of free ceramides in human plasma, but 17 molecular species of ceramides derived from sphingomyelins were quantified, from NC16:0 up to NC24:1. By contrast, three major free ceramides (NC16:0, NC24:0, and NC24:1) were quantified in HEPG2 and Chinese hamster ovary (CHO) cells. Upon induction of apoptosis in CHO cells by C6-ceramide, we could follow the disappearance of the C6-ceramide, its partial conversion to C6-sphingomyelin, and the prominent increase of NC16:0 ceramide. Thus, our method represents a unique procedure of simultaneous analysis of sphingomyelin and ceramide molecular species able to monitor the variation of the different pools in biological samples.     

Associations among circulating sphingolipids, β-cell function,and risk of developing type 2 diabetes: A population-based cohort study in China

BackgroundAnimal studies suggest vital roles of sphingolipids, especially ceramides, in the pathogenesis of type 2 diabetes (T2D) via pathways involved in insulin resistance, β-cell dysfunction, and inflammation, but human studies are limited. We aimed to evaluate the associations of circulating sphingolipids with incident T2D and to explore underlying mechanisms.Methods and findingsThe current study included 826 men and 1,148 women who were aged 50–70 years, from Beijing and Shanghai, and without T2D in 2005 and who were resurveyed in 2011. Cardiometabolic traits were measured at baseline and follow-up surveys. A total of 76 sphingolipids were quantified using high-coverage targeted lipidomics. Summary data for 2-sample Mendelian randomization were obtained from genome-wide association studies of circulating sphingolipids and the China Health and Nutrition Survey (n = 5,731). During the 6-year period, 529 participants developed T2D. Eleven novel and 3 reported sphingolipids, namely ceramides (d18:1/18:1, d18:1/20:0, d18:1/20:1, d18:1/22:1), saturated sphingomyelins (C34:0, C36:0, C38:0, C40:0), unsaturated sphingomyelins (C34:1, C36:1, C42:3), hydroxyl-sphingomyelins (C34:1, C38:3), and a hexosylceramide (d18:1/20:1), were positively associated with incident T2D (relative risks [RRs]: 1.14–1.21; all P < 0.001), after multivariate adjustment including lifestyle characteristics and BMI. Network analysis further identified 5 modules, and 2 modules containing saturated sphingomyelins showed the strongest associations with increased T2D risk (RR_{Q4 versus Q1} = 1.59 and 1.43; both P_trend < 0.001). Mediation analysis suggested that the detrimental associations of 13 sphingolipids with T2D were largely mediated through β-cell dysfunction, as indicated by HOMA-B (mediation proportion: 11.19%–42.42%; all P < 0.001). Moreover, Mendelian randomization evidenced a positive association between a genetically instrumented ceramide (d18:1/20:1) and T2D (odds ratio: 1.15 [95% CI 1.05–1.26]; P = 0.002). Main limitations in the current study included potential undiagnosed cases and lack of an independent population for replication.ConclusionsIn this study, we observed that a panel of novel sphingolipids with unique structures were positively associated with incident T2D, largely mediated through β-cell dysfunction, in Chinese individuals.     

A procedure for the rapid, quantitative N-acetylation of amino sugar methyl glycosides.

A rapid and quantitative procedure is described for the re-N-acetylation of amino sugar methyl glycosides prior to their analysis by gas-liquid chromatography. Two equivalents of pyridine are added to acidic methanolysates containing amino sugars, serving both to neutralize the acid and to act as a catalyst for the subsequent N-acetylation reaction with acetic anhydride. The N-acetylation is quantitative and complete within 10 min at ambient temperature. Excess acetic anhydride is destroyed by solvolysis with the methanolic solvent. The procedure has been used effectively for methanolysates containing 0.01–2.0 mg/ml glucosamine. The procedures utilizing ion-exchange columns and insoluble salts are thus circumvented and all reaction byproducts are volatile. The procedure is therefore ideally suited for the simultaneous workup of numerous samples for analytical procedures such as gas-liquid chromatography.     

Sphingomyelins of Rat Liver: Biliary Enrichment with Molecular Species Containing 16:0 Fatty Acids as Compared to Canalicular-Enriched Plasma Membranes

We harvested canalicular-enriched plasma membranes of hepatocytes and collected fistula bile from male rats and isolated the sphingomyelins. Following sphingomyelinase hydrolysis, we identified the sphingomyelin molecular species on the basis of their benzoylated ceramide derivatives employing high performance liquid chromatography. Sphingomyelin constitutes ≤3% of total biliary phospholipids (which are mostly sn-1 16:0 long-chain phosphatidylcholines) and approximately 30% of canalicular-enriched membranes. In both cases, the principal molecular species were composed of 16:0, 18:0, 20:0, 22:0, 23:0, 24:0, 24:1 and 24:2 fatty acid classes. However, the 16:0 fatty acid species was enriched in biliary sphingomyelin to a significantly greater degree than in sphingomyelins of canalicular-enriched plasma membranes (46% vs. 25% of total). We argue a physical-chemical case for laterally separated domains of very long chain sphingomyelins on the exoplasmic leaflet of the canalicular membrane. We bolster our hypothesis by the likelihood that the least hydrophobic, e.g., 16:0 sphingomyelin molecular species, are miscible with biliary phosphatidylcholines, and are secreted into bile. Laterally separated domains of very long chain sphingomyelins on the exoplasmic leaflet of the canalicular membrane could provide a means of sequestering cholesterol molecules prior to secretion into bile. Received: 19 March 1998/Revised: 8 October 1998     

Sphinganine in Sphingomyelins of Tumors and Mouse Regenerating Liver

Contents of sphingenine (sphingosine) and sphinganine were studied in sphingomyelins of transplantable mouse tumors (hepatoma-22, melanoma B16, Lewis lung carcinoma, intestine carcinoma) and rat nephroma RA. The content of sphinganine was increased in sphingomyelins of hepatoma-22 and nephroma RA compared to sphingomyelins of liver and kidneys. Significant contents of sphinganine were also found in sphingomyelins of other studied tumors. The content of sphinganine in regenerating mouse liver (30 h after hepatectomy) was normal. The data suggest that disorders should exist in biosynthesis of sphingoid bases in tumors but not in normal rapidly proliferating tissue.     

A rapid procedure for the isolation and purification of photosynthetic reaction centers from Rhodopseudomonas sphaeroides R-26

A rapid purification procedure has been developed for the isolation of reaction centers From Rhodopseudomonas sphaeroides strain R-26. The procedure takes about 7 h and results in yields of 60–75%. The ratio of the optical absorbances at 280 and 800 nm is between 1.4 and 1.5, and preparations can be made with either one or two quinones per reaction center. EPR spectra show a sharp g 1.83 signal for the ubisemiquinone. The substitution of lauryl maltoside for lauryldimethylamine oxide suppresses reaction-center degradation in solution.