Separation of phosphatidylethanolamine from its oxidation and hydrolysis products by high-performance liquid chromatography.

1-Palmitoyl-2-linoleoyl-phosphatidylethanolamine degrades relatively quickly when subjected to common storage and handling procedures. The degradation products consist of compounds in which double bonds in the sn-2 position acyl chain are partially oxidized and of products arising from the hydrolysis of the acyl ester bonds. Thin-layer chromatography (TLC), which is widely utilized to isolate and to ascertain the purity of phospholipids, does not readily separate the oxidation products from the parent lipid class. High-performance liquid chromatography (HPLC), however, employing a normal phase column and an isocratic, UV-transparent solvent system, can be employed to produce a rapid analytical or preparative of phosphatidylethanolamine (PE) from these degradative impurities.

Factors affecting solute entrapment in phospholipid vesicles prepared by the freeze-thaw extrusion method: a possible general method for improving the efficiency of entrapment.

It is often assumed that the internal solute concentrations of phospholipid vesicles are equal to those in the medium in which they were prepared, particularly when freeze-thaw cycles are employed during the procedure. Conditions are reported here which when used to prepare vesicles by the polycarbonate filter extrusion method, produce approximately 12- and approximately 7-fold higher internal concentrations of Ca2+ and sucrose, respectively, than exist in the external medium. Formation of these large gradients is dependent upon the use of freeze-thaw cycles during preparation, on the presence of tetraethylammonium perchlorate in the medium, and is independent of media pH across the region of pH 5-9. Gradient formation is antagonized by high concentrations of an impermeant solute (NaCl). It is proposed that gradients form because solutes are concentrated by exclusion from ice during freezing but that they are normally dissipated by osmotic lysis during thawing. The presence of a permeant solute such as tetraethylammonium perchlorate provides an alternative mechanism to balance osmotic pressure, thereby preserving the gradients of impermeable species.

A new system for lipid analysis by liquid chromatography-mass spectrometry.

A simple system for interfacing liquid chromatography with mass spectrometry for the analysis of lipids is described. The system is based on the moving chain transport principle and employs an endless stainless steel belt of perforated construction that gives it superior surface properties and capacity to entrain solvent. The entire column eluent is collected on the belt which transports it into an evaporator where the solvent is removed. The solute, which remains as a residue on the belt, is transported into a reactor where it is converted to hydrocarbons by reaction with hydrogen at 400-450 C. The hydrocarbons, which are characteristic of the structures of the parent compounds, are swept into an outlet tube where ca. 15% are drawn into the ion source of a mass spectrometer operating in the chemical ionization mode using methane as the reagent gas. The spectrum is recorded on an oscillographic recorder for identification purposes. Detection and quantitative analysis is performed by single ion monitoring of the most intense ion using a conventional analog recorder. The system is domonstrated by application to a standard mixture of tripalmitin, cholesteryl palmitate, and cholesterol separated on a 3.2 x 250 mm silica column, and exhibited a sensitivity of ca. 1 nanogram per component injected on the column.

Quantitative analysis of lipid classes by liquid chromatography via a flame ionization detector.

A method is described for the direct quantitative analysis of the lipid classes of mammalian tissue lipids using high performance liquid chromatography (HPLC) with a flame ionization detector (FID). The lipid is extracted from the tissue with chloroform/methanol after deactivation of hydrolytic enzymes and removal of nonlipid substances by extraction with hot dilute acetic acid (0.05N). Separation of the lipid classes is performed with a column (45 cm × 0.2 cm id) of 8 µm silica (Spherisorb, Phase Sep, Hauppague, NY) treated with concentrated ammonium hydroxide at a solvent flow rate of 0.5 ml/min, which requires a pressure of ca. 900 psi. Cholesteryl esters (CE) and triglycerides (TG) are eluted first with Skellysolve B/methylene chloride (1∶1, v/v); cholesterol (CH) is eluted with chloroform/methylene chloride (1∶2, v/v) and the phospholipids with methanol containing 6% ammonium hydroxide added to the latter solvent in a linear gradient. The neutral lipids are eluted in ca. 12 min and the phospholipids in an additional 30 min. The relative amount of each lipid class was determined from standard curves of the peak areas obtained according to response factors using erucyl alcohol as an internal standard. The method was applied to samples of kidney, liver and serum of rats. Duplicate analyses were generally within ca. 1.0% and good agreement was obtained in the analysis of the lipid classes of Azolectin and liver mitochondria lipid compared to thin layer chromatography (TLC) via photodensitometry of charred spots or phosphorus analysis of recovered phospholipids.

Quantitative analysis of triglyceride species of vegetable oils by high performance liquid chromatography via a flame ionization detector.

A method for the quantitative analysis of triglyceride species composition of vegetable oils by reversed-phase high performance liquid chromatography (RP-HPLC) via a flame ionization detector (FID) is described. Triglycerides are separated into molecular species via Zorbax chemically bonded octadecylsilane (ODS) columns using gradient elution with methylene chloride in acetonitrile. Identification of species is made by matching the retention times of the peaks in the chromatogram with the order of elution of all of the species that could be present in the sample on the basis of a random distribution of the fatty acids and comparison of experimental and calculated theoretical carbon numbers (TCN). Quantitative analysis is based on a direct proportionality of peak areas. Differences in the response of individual species were small and did not dictate the use of response factors. The method is applied to cocoa butter before and after randomization, soybean oil and pure olive oil.

Analysis of triglyceride species by high-performance liquid chromatography via a flame lonization detector.

The analysis of triglyceride species by high performance liquid chromatography (HPLC) with a flame ionization detector (FID) and reversed-phase chromatography using chemically bonded octadecyl silane (ODS) Zorbax columns and gradient or isocratic solvent elution with methylene chloride/acetonitrile is described. Triglycerides containing acyl groups of critical pairs,trans and positional isomers, as well as mixtures of even and odd chain lengths are separated. Identification of triglycerides is made on the basis of retention times compared with equivalent and theoretical carbon numbers, and comparison with chromatograms of reference triglyceride mixtures. The methodology is demonstrated by fractionizing the triglycerides of olive oil under different chromatographic conditions using single and coupled conventional 250×4.6 mm columns and a short 80×6.2 mm column for fast separations.

A comparison of phospholipid degradation by oxidation and hydrolysis during the mitochondrial permeability transition.

The peroxidation and hydrolysis of mitochondrial phospholipids has been examined under conditions which are referable to induction of the permeability transition by t-butylhydroperoxide. Over a 30-min time course, the peroxide causes formation of 0.3 nmol/mg protein of malondialdehyde. This value is little effected by Ca2+, Sr2+, or Mn2+ but is increased approximately fivefold by Fe2+. The latter cation, but not the others, results in malondialdehyde formation in the absence of added peroxide. Partially oxidized phosphatidylethanolamine is present in normal mitochondria and is increased by approximately 50% following t-butylhydroperoxide treatment; however, the amounts observed are in the range of 0.4-0.6 mol% of total phosphatidylethanolamine. The minor degradation by peroxidation is in contrast to approximately 2.5 mol% degradation which occurs by hydrolysis. This degree of hydrolysis is accompanied by mitochondrial swelling and Mg2+ release, while a comparable level of peroxidation (malondialdehyde formation) is not. It is concluded that induction of the permeability transition by t-butylhydroperoxide does not represent damage to the membrane lipid phase caused by peroxidation. It is possible, however, that peroxidation accelerates the accumulation of phospholipid hydrolysis products and is thereby a factor which favors the transition.

Ionomycin, a carboxylic acid ionophore, transports Pb(2+) with high selectivity.

Studies utilizing phospholipid vesicle loaded with chelator/indicators for polyvalent cations show that ionomycin transports divalent cations with the selectivity sequence Pb(2+) > Cd(2+) > Zn(2+) > Mn(2+) > Ca(2+) > Cu(2+) > Co(2+) > Ni(2+) > Sr(2+). The selectivity of this ionophore for Pb(2+) is in contrast to that observed for A23178 and 4-BrA23187, which transport Pb(2+) at efficiencies that are intermediate between those of other cations. When the selectivity difference of ionomycin for Pb(2+) versus Ca(2+) was calculated from relative rates of transport, with either cation present individually and all other conditions held constant, a value of approximately 450 was obtained. This rose to approximately 3200 when both cations were present and transported simultaneously. 1 microM Pb(2+) inhibited the transport of 1 mM Ca(2+) by approximately 50%, whereas the rate of Pb(2+) transport approached a maximum at a concentration of 10 microM Pb(2+) when 1 mM Ca(2+) was also present. Plots of log rate versus log ionomycin or log Pb(2+) concentration indicated that the transporting species is of 1:1 stoichiometry, ionophore to Pb(2+), but that complexes containing an additional Pb(2+) may occur. The species transporting Pb(2+) may include H.IPb.OH, wherein ionomycin is ionized once and the presence of OH(-) maintains charge neutrality. Ionomycin retained a high efficiency for Pb(2+) transport in A20 B lymphoma cells loaded with Indo-1. Both Pb(2+) entry and efflux were observed. Ionomycin should be considered primarily as an ionophore for Pb(2+), rather than Ca(2+), of possible value for the investigation and treatment of Pb(2+) intoxication.

Ca2+ transport properties of ionophores A23187, ionomycin, and 4-BrA23187 in a well defined model system.

Models for the electroneutral transport of Ca2+ by ionophores A23187, ionomycin, and 4-BrA23187 have been tested in a defined system comprised of 1-palmitoyl-2-oleoyl-sn-glycerophosphatidylcholine vesicles prepared by freeze-thaw extrusion. Quin-2-loaded and CaCl2-loaded vesicles were employed to allow the investigation of transport in both directions. Simultaneous or parallel measurements of H+ transport and membrane potential, respectively, indicate that for any of these ionophores, electrogenic transport events do not exceed 1 in 10,000 when there is no preexisting transmembrane potential. When a potential of approximately 150 mV is imposed across the membrane, transport catalyzed by A23187 remains electroneutral; however, for ionomycin and 4-BrA23187, approximately 10% of transport events may be electrogenic. The defined vesicle system has also been utilized to determine how the rate of Ca2+ transport varies as a function of ionophore and Ca2+ concentration and with the direction of transport. Some aspects of the results are unexpected and should be considered by investigators using ionophores in biological systems. These include the apparent failure of these compounds to fully equilibrate Ca2+ with a high affinity Ca2+ indicator when these species are separated by a membrane, rates of transport that vary markedly with the direction of transport, and extents of transport that are a function of ionophore concentration. At least some of these unexpected behaviors can be explained by a strong influence of delta pH on forward and reverse transport kinetics. In the case of A23187, the data also give some initial insights into the relationship between formation of the transporting species and the entry of this species into the membrane hydrophobic region.

The peptide mastoparan is a potent facilitator of the mitochondrial permeability transition.

Mastoparan facilitates opening of the mitochondrial permeability transition pore through an apparent bimodal mechanism of action. In the submicromolar concentration range, the action of mastoparan is dependent upon the medium Ca2+ and phosphate concentration and is subject to inhibition by cyclosporin A. At concentrations above 1 microM, pore induction by mastoparan occurs without an apparent Ca2+ requirement and in a cyclosporin A insensitive manner. Studies utilizing phospholipid vesicles show that mastoparan perturbs bilayer membranes across both concentration ranges, through a mechanism which is strongly dependent upon transmembrane potential. However, solute size exclusion studies suggest that the pores formed in mitochondria in response to both low and high concentrations of mastoparan are the permeability transition pore. It is proposed that low concentrations of mastoparan influence the pore per se, with higher concentrations having the additional effect of depolarizing the mitochondrial inner membrane through an action exerted upon the lipid phase. It may be the combination of these effects which allow pore opening in the absence of Ca2+ and in the presence of cyclosporin A, although other interpretations remain viable. A comparison of the activities of mastoparan and its analog, MP14, on mitochondria and phospholipid vesicles provides an initial indication that a G-protein may participate in regulation of the permeability transition pore. These studies draw attention to peptides, in a broad sense, as potential pore regulators in cells, under both physiological and pathological conditions.

Effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin suggest problems with common applications of these compounds in biological systems.

Phospholipid vesicles loaded with Quin-2 and 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) have been used to investigate the effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin. At an external pH of 7.0, a delta pH (inside basic) of 0.4-0.6 U decreases the rate of Ca2+ transport into the vesicles by severalfold under some conditions. The apparent extent of transport is also decreased. In contrast, raising the pH by 0.4-0.6 U in the absence of a delta pH increases both of these parameters, although by smaller factors. The relatively large effects of a delta pH on the transport properties of Ca2+ ionophores seem to reflect a partial equilibration of the transmembrane ionophore distribution with the H+ concentration gradient across the vesicle membrane. This unequal distribution of ionophore can cause a very slow or incomplete ionophore-dependent equilibration of delta pCa with delta pH. A second factor of less certain origin retards full equilibration of delta pCa when delta pH = 0. These findings call into question several ionophore-based methods that are used to investigate the regulatory activities of Ca2+ and other divalent cations in biological systems. Notable among these are the null-point titration method for determining the concentration of free cations within cells and the use of ionophores plus external cation buffers to calibrate intracellular cation indicators. The present findings also indicate that the transport mode of Ca2+ ionophores is more strictly electroneutral than was thought, based upon previous studies.

Ionophore 4-BrA23187 transports Zn2+ and Mn2+ with high selectivity over Ca2+.

The cation transport selectivities of the Ca2+ ionophores A23187, Ionomycin, and 4-BrA23187 have been determined using a model system comprised of phospholipid vesicles loaded with the chelator/indicator Quin-2. At pH 7.00 and a 100 microM concentration of the cations, A23187 displays the transport selectivity sequence Zn2+ > Mn2+ > Ca2+ > Co2+ > Ni2+ > Sr2+, with the absolute rates of transport spanning approximately 3 orders of magnitude. Similar data are obtained with Ionomycin, although the relative transport rates of Zn2+ and Mn2+ are equivalent, and the range of absolute rates is decreased by a factor of approximately 3. When values are normalized to those of Ca2+, transport selectivity is seen to be only weakly related to complexation or extraction selectivity. It is also seen that, when used to manipulate Ca2+ (or Mg2+), both ionophores can be expected to alter the distribution of additional divalent cations which have known biological activities. 4-BrA23187 is a low-activity ionophore for Ca2+, compared to A23187 and Ionomycin, while retaining comparable activities as an ionophore for the other cations. As a consequence, 4-BrA23187 is highly selective for the transport of Zn2+ and Mn2+, compared to Ca2+, with selectivity ratios approaching that of valinomycin for K+ over Na+ when conditions are optimal. Plots of the log of the rate of cation transport vs the log of the ionophore concentration indicate that Ca2+ is transported primarily as a 2:1 complex by A23187 and 4-BrA23187, but Zn2+ and Mn2+ are transported, in part, as 1:1 complexes. These findings, together with a postulated low stability of 2:1, compared to 1:1 complexes between 4-BrA23187 and divalent cations, partially explain the novel transport selectivity of this compound. Unlike A23187 or Ionomycin, 4-BrA23187 may be useful for investigating cell regulation by Zn2+ and Mn2+, without interference by regulatory mechanisms which respond to Ca2+.

Transport properties of the calcium ionophore ETH-129.

The transport mechanism and specificities of ionophore ETH-29 have been investigated in a highly defined phospholipid vesicle system, with the goal of facilitating the application of this compound to biological problems. ETH-129 transports Ca(2+) via an electrogenic mechanism, in contrast to A23187 and ionomycin, which function in a charge neutral manner. The rate of transport is a function of membrane potential, increasing by 3.9-fold per 59 mV over a broad range of that parameter. Rate is independent of the transmembrane pH gradient and strongly stimulated by the uncoupler carbonyl cyanide m-chlorophenylhydrazone when no external potential has been applied. The effect of uncoupler reflects the collapse of an opposing potential arising during Ca(2+) transport, but also reflects the formation of a mixed complex between the uncoupler, ETH-129, and Ca(2+) that readily permeates the vesicle membrane. Oleate does not substitute for the uncoupler in either regard. ETH-129 transports polyvalent cations according to the selectivity sequence La(3+) > Ca(2+) > Zn(2+) approximately equal to Sr(2+) > Co(2+) approximately equal to Ni(2+) approximately equal to Mn(2+), with the magnitude of the selectivity coefficients reflecting the cation concentration range considered. There is little or no activity for the transport of Na(+), K(+), and Mg(2+). These properties suggest that ETH-129 will be useful for investigating the consequences of a mitochondrial Ca(2+) overload in mammalian cells, which is difficult to pursue through the application of electroneutral ionophores.