Use of nile red for the rapid in situ quantitation of lipids on thin-layer chromatograms

We describe the use of the fluorescent dye nile red, 9-diethylamino-5H-benzo[alpha]phenoxazine-5-one, as a general-purpose reagent for the rapid detection and quantitation of a wide variety of lipids and other hydrophobic compounds separated by thin-layer chromatography. After samples are applied to silica gel plates and chromatographed, the plate is briefly dipped into a nile red solution (8 micrograms/ml of methanol-water 80:20, v/v). Background fluorescence of nile red dye adsorbed to the silica gel is then preferentially destroyed by dipping the plate in a dilute aqueous solution of bleach. After drying, lipid bands are visualized under ultraviolet light. Reflectance fluorometry (Ex: 580 nm; Em: 640 nm) is utilized for in situ quantitative analysis of the fluorescence of the lipids on the nile red-stained plate. Neutral lipids, phospholipids, sphingolipids, and fatty acids can be examined, although the nile red fluorescence intensity varies significantly among the lipid classes. Also, staining is stronger for unsaturated lipids than for saturated lipids. The lower detection limit of the assay is 25-100 ng for cholesterol, cholesteryl esters, triacylglycerols, and phospholipids.     

Recovery of gangliosides from aqueous solutions on styrene-divinylbenzene copolymer columns

An investigation was made using a styrene-divinylbenzene copolymer as a solid phase sorbent to recover gangliosides from aqueous solutions. A comparison with octadecyl-bonded (C18) silica gel showed that the general procedure used to purify gangliosides on C18 silica gel could be used with the copolymer. The yield of gangliosides depended on various parameters such as the composition of the conditioning solution, the salt concentration of the loading solution, and the amount of applied gangliosides per gram of copolymer. In optimal conditions, the recovery of gangliosides and other lipids present in the upper phases of partition was higher than 95%. Using radiolabeled gangliosides, it was found that gangliosides present in serum-containing medium could also be quantitatively recovered on copolymer, provided the medium was diluted with an equal volume of methanol prior to its application onto the column. The major advantage of the copolymer is its high stability in acidic or alkaline conditions that allows multiple cycles of cleaning and reconditioning of the sorbent without alteration of its chromatographic properties.     

Purification and Characterization of Lipid Bioflocculant Produced by Rhodococcus erythropolis

The bioflocculant produced by Rhodococcus erythropolis S-1 was found to exist as huge assemblies, the molecular mass of which is over one million daltons, composed of many polypeptides and lipids in aqueous solution. We have isolated and purified this lipid bioflocculant by ultracentrifugation, extracting with 90% acetone, and two successive silica gel chromatographies from the culture broth. It was homogeneous on silica gel thin-layer chromatography. ¹H-NMR and HPLC studies showed that it was a kind of glycolipid that contained a C₁₆ methylene chain on the average and glucose in its chemical structure. The flocculating activity against kaolin clay suspension was dependent on the Ca²⁺ concentration.     

Counting efficiency in the radioassay of 3H- and 14C-labeled lipids adsorbed on silica gel by liquid scintillation

The effect of silica gel on the recovery of radioactivity from ¹⁴C- and ³H-labeled lipids by liquid scintillation is analyzed. In the most unfavorable ease, when counting with a toluenefluor solution directly added to the vials containing the adserbed lipid, drastic reductions in the counting efficiency were found, which depended on the amount of silica gel, sample activity, and chemical nature of the lipid. For certain lipids like phosphatidylcholine, these effects were not completely overcome even by introducing water and detergents in the counting system. This paper intends to draw attention to the fact that these factors should be especially taken into account when comparing different lipids from thin-layer chromatograms.     

Analytical prenyl pigment separation from a total green-plant lipid extract

A one-step method for the analytical separation of the major prenyl pigments out of a total green-plant lipid extract is described. Thin-layer chromatography on prepared silica gel plates rapidly separates the pigments from the relatively greater amount of noncolored lipids and simultaneously resolves the four major carotenoids and chlorophylls a and b. Each resolved colored band contains a single pigment as identified by visible absorption spectrophotometry. Radiochemical analysis of the colored and nonpigmented regions from resulting chromatograms confirms that no pigment is contaminated with colorless lipid, allowing reliable analysis of the resolved pigments beyond spectrophotometry. The method can also resolve the carotenoids in a saponified fraction of total green-plant lipid and simultaneously separate them from fatty acid ester products of acyl lipid saponification.     

A solvent partition method for microscale ganglioside purification

A simple and rapid method for the purification of gangliosides from the total lipid extract of plasma, cells, or tissue is described. The novel component of the method is the partition of the dried total lipid extract in the three-component solvent system consisting of diisopropyl ether, 1-butanol, and 50 mM aqueous NaCl (6/4/5, v/v/v). Gangliosides partition nearly quantitatively into the lower aqueous phase, and other lipids into the upper organic phase, resulting from the mixture of these three solvents. The ganglioside-containing aqueous phase is then freed of salts and other low-molecular-weight impurities by gel filtration. The thin-layer chromatographic patterns of total gangliosides thus obtained are clear and distinct, even when small samples with very low ganglioside concentrations (e.g., 1-ml samples of plasma) are processed by this method. Thus, this new ganglioside purification method is especially applicable to comparative qualitative studies of gangliosides requiring the analysis of multiple small samples.     

Immobilization and biocatalysis of chlorophyllase in selected organic solvent systems

Chlorophyllase extract from Phaeodactylum tricornutum was immobilized by physical adsorption on DEAE-cellulose and silica gel as well as by covalent binding on Eupergit C, Eupergit C250L, Eupergit C/ethylenediamine (EDA) and Eupergit C250L/EDA. Although the highest immobilization yield (83-93%) and efficiency (51-53%) were obtained when chlorophyllase extract was immobilized on DEAE-cellulose and silica gel, there was no improvement in the thermal stability of chlorophyllase as compared to that of the free one. The immobilization of chlorophyllase extract on Eupergit C250L/EDA resulted by a high recovery of enzymatic activity, with an immobilization efficiency of 44%, and promoted a higher stabilization of chlorophyllase (four times) in the aqueous/miscible organic solvent medium. On the other hand, the inhibitory effect of refined bleached deodorized (RBD) canola oil was reduced by immobilization of chlorophyllase extract onto silica gel as compared to those obtained with other enzyme preparations. However, the re-cycled chlorophyllase extract immobilized on Eupergit C250L/EDA retained more than 75% of its initial enzyme activity after 6 cycles, whereas that immobilized on silica gel was completely inactivated. The highest catalytic efficiency, for both free and immobilized chlorophyllase on Eupergit C250L/EDA, was obtained in the ternary micellar system as compared to the aqueous/miscible organic solvent and biphasic media.     

Purification and characterization of a liposomal-forming tetraether lipid fraction

Polar lipid E, PLE, a native tetraether lipid mixture from Sulfolobus acidocaldarius is shown to spontaneously form multilamellar liposomes in aqueous media. PLE lipids were isolated as a single fraction from the crude lipid extract of S. acidocaldarius on a reverse-phase column followed by TLC and methanol precipitation. The methanol-precipitated mixture was able to form liposomes, whereas the non-precipitated material did not. It has thus been demonstrated, for the first time, that tetraether lipids from S. acidocaldarius can form liposomes, per se, in aqueous media.     

Participation of π-Electrons of Phospholipid Molecules in Absorption of Ultraviolet Light in the Range of 260–280 nm

The UV-spectra (230–260 nm) of the rat brain lipid extract and of individual extract lipid fractions obtained on a column with silica gel (10 µm) were studied. It was found out that hydration of the lipid extract led to a decrease of the absorption intensity of the UV-spectrum by 70% as compared with the initial intensity. Addition of silica gel to the lipid extract decreases twice the UV-spectrum intensity, whereas the repeated addition of silica gel does not decrease intensity of the UV absorption, with no changes of the amount of phospholipids in the lipid extract. Some lipid fractions isolated from the column shift the UV-spectra towards the shorter wavelength region, while the fractions containing phosphatidylcholine shift the spectrum towards the longer wavelength region. It has been established that the phosphatidylcholine fractions containing different amounts of polyenic acids differ by the UV-spectrum intensity. It was concluded that chromophore groups of polyunsaturated acids of phospholipids participated in absorption of energy in the range of 260–280 nm, which lead to excitation of valence electrons of multiple (double) bonds. Energy of such electrons can be used in interactions with other molecules, in particular, for energy transfer inside the membrane monolayer.__________Translated from Zhurnal Evolyutsionnoi Biokhimii i Fiziologii, Vol. 41, No. 3, 2005, pp. 236–239.Original Russian Text Copyright © 2005 by Zabelinskii, Chebotareva, Shukolyukova, Furaev, Krivchenko.     

Thehalose mycolates from Nocardia asteroides,Nocardia farcinica,Gordona lentifragmenta and Gordona bronchialis

Isolation of glycolipids from Nocardia asteroides, N. farcinica, Gordona lentifragmenta and G. bronchialis, by column chromatography of lipid extracts on a 50% (w/w) mixture of silicic acid and silica gel H, is described. The isolated materials were partially characterized by infrared spectroscopy, optical rotation and refractive index measurements, and by identifying the products of alkaline hydrolysis. Analytical studies showed that the glycolipids released only trehalose in the aqueous phase while mycolic acids were the constituent fatty acids identified.The isolated lipids are trehalose esters in which the trehalose molecule is esterified with mycolic acids.     

Miniature two-dimensional thin-layer chromatographic separation of lecithin and sphingomyelin

A miniature two-dimensional thin-layer chromatographic procedure employing silica gel impregnated glass-microfiber chromatography sheets (commercial product, ITLC-type SG sheets) has been developed for the separation of lecithin (L) and sphingomyelin (S) from a standard lipid mixture containing L, S, lysolecithin, phosphatidyl inositol (PI), phosphatidyl serine (PS), phosphatidyl ethanolamine, phosphatidyl glycerol, and diphosphatidyl glycerol. The newly developed procedure eliminates possible interference from PI and PS. Complete separation of L and S was easily achieved with chromatographic solvent migration times of approximately 3 and 2 min for the first and second dimensions, respectively. The lipids were visualized by charring and fluorescent staining techniques. The procedure has been adapted for the separation of L and S from amniotic fluid samples.     

Variable recoveries of fatty acids following the separation of lipids on commercial silica gel TLC plates Selective loss of unsaturated fatty acids on certain brands of plates

Since we recently noticed poor recoveries of unsaturated fatty acids (UFA) when the parent lipids were first separated on TLC plates, we investigated the source of this error by examining several variables, including the brand of TLC plate, nature of the lipid, and conditions of methylation. Of the five commercial brands of plates used, two (Baker and Whatman) showed loss of UFA, and three (Alltech Hardlayer, Alltech Softlayer, and Merck) did not. This loss occurred in both neutral and phospholipids, did not affect saturated acids, and was independent of the methylation reagent used. No loss occurred, however, if the lipids were eluted from the silica gel before methylation, indicating that the loss is due to oxidation of UFA in presence of certain brands of silica gel. These results show that some brands of TLC plates may be unsuitable for lipid analysis, if the aim is to determine the fatty acid composition by GC using direct methylation.     

Phosphatidylcholine removal from brain lipid extracts expands lipid detection and enhances phosphoinositide quantification by matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry

The utilization of matrix-assisted laser desorption/ionization time-of-flight mass spectrometry for the analytical detection and quantification of phosphoinositides and other lipids in lipid extracts from biological samples was explored. Since phosphatidylcholine species in crude extracts have been shown to cause ion suppression of the MS signals for other lipids, a minicolumn of a silica gel cation exchanger was used to adsorb the cationic lipids including the phosphatidylcholine species from the chloroform phase of fetal and adult murine brain extracts. In positive ion mode, lipid peaks that had been completely suppressed in the crude extract became readily detectable and quantifiable in the flow-through fraction from the column. In negative ion mode, improved sensitivity made it possible to readily detect and measure phosphatidylinositol-4,5-bisphosphate (PIP(2)) which had been only marginally detectable before the fractionation. By incorporating an internal standard into the samples, the relative MALDI-TOF MS signals obtained for increasing concentrations of mammalian phosphatidylinositol (PtdIns) increased linearly with correlation coefficients >0.95. Using strong cation exchange minicolumn treated extracts, the levels of PtdIns and PIP(2) in adult and fetal murine brains were measured and compared. The removal of cationic lipids from the chloroform-methanol murine brain extracts resulted in improved overall detection of neutral and anionic lipids and quantification of phosphoinositides by MALDI-TOF MS.     

Studies on the Lipid Components of Endotoxin II. Chemical Analyses and Biological Properties of Neutral,Polar-I and Polar-II Subfractions

Lipid components obtained from Salmonella typhosa O-901 endotoxin by acid hydrolysis were separated into neutral, polar-I and polar-II lipid fractions by silica gel column chromatography. These lipids were further separated by silica gel column and/or thin-layer chromatography. The subfractions were analyzed by thin-layer chromatography, gas chromatography and infrared spectrophotometry. Seven subfractions obtained from the neutral lipid fraction contained lauric, myristic, palmitic, 3-OH-myristic acid, artificial products of 3-OH-myristic acid, or a small amount of two unidentified fatty acids. These fatty acids and glucosamine were commonly detected in six subfractions obtained from the polar-I lipid fraction. Fatty acids, glucosamine, and O-phosphorylethanolamine were detected in all of the 13 subfractions obtained from the polar-II lipid fraction. Chick embryo lethal activity, rabbit pyrogenicity and in vitro interferon inducing activity were found in three polar-I lipid subfractions and five polar-II lipid subfractions, but not in neutral lipids. The activities were highest in a polar-II lipid subfraction, which contained smaller amounts of O-phosphorylethanolamine and glucosamine than the other subfractions. However, no particular chemical constituent (s) related to the biological activities could be found. Prolonged acid hydrolysis of the polar-II lipids gave rise to neutral and polar-I lipids. Chemical and biological aspects of the lipid constituents of endotoxin are discussed.     

A rapid column chromatographic method for the isolation of catechol-type siderophores.

The ester groups of glycerophospholipids in tissue extracts can be cleaved in less than 10 min at room temperature if the lipids are extracted with hexane-isopropanol and the filtrate is treated with methanolic NaOH. The resulting mixture can be treated with aqueous Na-sulfate containing sulfuric acid and partitioned to remove the inorganic reagents and hydrophilic ester degradation products. When the procedure is applied to brain lipid extracts, the addition of alkali produces a second, lower phase that contains much of the hydroxycerebroside, virtually all of the sulfatide in the extract, and small amounts of other lipids. The sulfatide can be isolated from the lower phase by neutralizing it with HCl in aqueous methanol, and partitioning with chloroform to remove nonlipid components. The lower phase is evaporated to dryness and treated with periodic acid to convert the cerebroside to a less polar product. The lipids recovered from the reaction mixture are then fractionated with a Florisil column, which yields highly purified sulfatide. Starting with 300 g of pig brain one can obtain about 1.1 g of sulfatide in 4 working days, using conventional, compact equipment. Since the precipitation step is almost complete, and the procedure can be scaled down to very low levels, the method has promise for quantitation methods and isotopic studies of sulfatide metabolism.     

Simple procedures for the rapid cleavage of ester lipids and for the large-scale isolation from brain of cerebroside sulfate

The ester groups of glycerophospholipids in tissue extracts can be cleaved in less than 10 min at room temperature if the lipids are extracted with hexane-isopropanol and the filtrate is treated with methanolic NaOH. The resulting mixture can be treated with aqueous Na-sulfate containing sulfuric acid and partitioned to remove the inorganic reagents and hydrophilic ester degradation products. When the procedure is applied to brain lipid extracts, the addition of alkali produces a second, lower phase that contains much of the hydroxycerebroside, virtually all of the sulfatide in the extract, and small amounts of other lipids. The sulfatide can be isolated from the lower phase by neutralizing it with HCl in aqueous methanol, and partitioning with chloroform to remove nonlipid components. The lower phase is evaporated to dryness and treated with periodic acid to convert the cerebroside to a less polar product. The lipids recovered from the reaction mixture are then fractionated with a Florisil column, which yields highly purified sulfatide. Starting with 300 g of pig brain one can obtain about 1.1 g of sulfatide in 4 working days, using conventional, compact equipment. Since the precipitation step is almost complete, and the procedure can be scaled down to very low levels, the method has promise for quantitation methods and isotopic studies of sulfatide metabolism.     

A rapid, isocratic method for phospholipid separation by high-performance liquid chromatography

A rapid, isocratic method for separating the most prevalent phospholipids by high-performance liquid chromatography is described. Baseline resolution of phosphatidylinositol, phosphatidylserine, phosphatidylethanolamine, phosphatidylcholine, lysophosphatidylcholine, and sphingomyelin is achieved in less than 40 min on a silica column. Lipids are injected in 10 microliter of chloroform-diethyl ether 1:2 (v/v) and eluted with a solvent mixture of acetonitrile-methanol-sulfuric acid 100:3:0.05 (v/v/v) at a flow rate of 1 ml/min. Neutral lipids and cardiolipin elute with the solvent front. Chromatography of a radioactive cell lipid extract indicates a recovery of better than 97%. The procedure is sensitive enough to permit the analysis of the main phospholipids present in a monolayer culture containing about 100 micrograms of cell protein.     

Thin-layer chromatography of tissue lipids without extraction

Frozen tissue sections were applied directly to silica gel plates, and the lipids were separated by developing the plates in different solvent systems. Quantitation of the lipid classes was achieved by direct transmission densitometry after the plates were treated with a chromic acid-sulfuric acid spray.     

Methods of chromatography and quantitative analysis of galacto- and phospholipids of plant leaves

Data in the literature on chromatography of glycerolipids of plant leaves on columns of DEAE-cellulose, Sephadex LH-20, silica gel, florisil, in a thin layer of silica gel, paper are generalized. Methods of obtaining chromatographically pure glycerolipids, their subfractionation, and the quantitative analysis of glycerolipids are described. Experimental data are presented on fractionation of lipids of potato leaves on columns of DEAE-cellulose, silica gel, on paper, and the quantitative determination of phospholipids. A method of rapid division of lipids into classes by means of their elution with silica gel KSC by different solvents is described.     

Separation of neutral glycosphingolipids and sulfatides by thin-layer chromatography

Two one-dimensional systems for separation of glycolipids from total lipid extracts of tissues by thin-layer chromatography are described. System I used, as adsorbent, an alkaline mixture of silica gel without CaSO(4) binder (75%) and magnesium silicate (25%), and the lipids were "developed" with three successive solvent mixtures. The separated compounds (from the fastest to the slowest moving) were: ceramide, ceramide monohexosides, sulfatides, ceramide dihexosides, psychosine, ceramide trihexosides, and ceramide N-acetylhexosamine trihexosides. In system II a two-step development was used on an adsorbent consisting of silica gel without CaSO(4) binder (80%) and magnesium silicate (20%). The separated compounds were: ceramides, ceramide monohexosides, and ceramide dihexosides. Psychosine and sulfatides as well as ceramide trihexosides and ceramide N-acetylhexosamine trihexosides were not separated. In both systems all neutral lipids moved to the very top of the chromatogram and phospholipids stayed at the origin. Application of systems I and II for separation of glycolipids was demonstrated on total lipid extracts from animal tissues.