An initial screening of serum lipids and fatty acid profiles of hypertensive and normotensive subjects

Serum lipids and their acyl group profiles from a group of hypertensive patients with elevated systolic and diastolic pressure were compared with normotensive subjects of matched age, body weight and dietary habits. The level of serum triacylglycerols was elevated in the hypertensive subjects, but the cholesterol level remained normal. The acyl groups of serum triacylglycerols and cholesterylesters from hypertensive subjects indicated a higher proportion of the saturated fatty acids (16:0 and 18:0) and a lower proportion of linoleic acid (18:2) as compared to normal controls. There was no obvious change in the level and acyl group composition of serum phosphatidylcholine between the two groups. Since the hypertensive and normotensive subjects indicated similar dietary habits, the resulting differences in serum lipids reflected an abnormality in the lipolytic process in the hypertensive subjects.     

Differential miscibility properties of various phosphatidylcholine/lysophosphatidylcholine mixtures

Using enthalphy data from differential scanning calorimetry experiments and ¹³C-NMR linewidths of specifically ($\text{N-Me-}{}^{13}\text{C)-labelled}$ lipids, the miscibility properties of phosphatidylcholines and lysophosphatidylcholines in liposomal dispersions have been investigated. It was found that 16 : 0 lysophosphatidylcholine mixes homogeneously in 16 : 0/16 : 0 phosphatidylcholine bilayers. Mixtures of 16 : 0 lysophosphatidylcholine with 18 : 1_c/18 : 1_c phosphatidylcholine, of 18 : 1_c lysophosphatidylcholine with 16 : 0/16 : 0 phosphatidylcholine and of 18 : 1_c lysophosphatidylcholine with 18 : 1_c/18 : 1_c phosphatidylcholine exhibited immiscibility in the phosphatidylcholine gel state.     

Morphine-induced changes in prostaglandin precursor fatty acids in phospholipids of mouse liver and serum.

Changes in phosphoglyceride acyl groups known to be the precursor fatty acids of prostaglandis were observed in mouse liver and serum with respect to morphine administration. The changes correlated with a significant decrease in the proportion of dihomo-γ-linolenic acid, 20:3(n-6), and an increase in arachidonic acid, 20:4(n-6) in the phosphoglycerides of liver and serum. At 12–24 hrs after morphine pellet implantation, the diacyl-$\text{sn}$-glycero-3-phosphocholines in liver and serum showed a 50% decrease in 20:3(n-6)/20:4(n-6) ratio as compared to controls. During this period, the lysolecithin in serum showed an increase in the proportion of 16:0 and a decrease in the proportion of unsaturated acyl groups. Most changes returned gradually to control values by 9 days although new morphine pellets were implanted into the mice every third day. Since fatty acids are released from membrane phospholipids prior to prostaglandin biosynthesis, the morphine-induced changes in phosphoglyceride acyl groups is reflective of an altered prostaglandin metabolism in liver and serum.     

Drug-induced changes in lipid composition of E. coli and of mammalian cells in culture: ethanol, pentobarbital, and chlorpromazine.

Both Chinese hamster ovary cells in culture and $\text{E.}$$\text{coli}$ cells change their lipid composition when grown in the presence of ethanol, pentobarbital, and chlorpromazine. The effects of ethanol and the cross-tolerant drug, pentobarbital, are similar. Both cause a shift from 18:0 fatty acid to 16:0 fatty acids in CHO cells and a decrease in the proportion of saturated fatty acids in $\text{E.}$$\text{coli}$. Chlorpromazine, a non-cross-tolerant drug, causes the opposite effect in $\text{E.}$$\text{coli}$, a decrease in the proportion of unsaturated fatty acids. Chlorpromazine has little effect on the fatty acid composition of CHO cells. These changes in lipid composition are proposed as an adaptive response and a part of the mechanism for the development of drug tolerance.     

Fluorescence polarisation and composition of membranes in genetic obesity

There was a decrease in the polarisation value of the fluorescent probe diphenylhexatriene in a wide range of purified plasma and subcellular membranes of obese ($\text{ob}\text{ob}$) mice. These changes were consistent with alterations in the fatty acyl chain content of specific membrane phospholipids. An increase in 22:6 and a loss of 18:2 in phosphatidyl ethanolamine was the major compositional change in adipocyte plasma membranes of $\text{ob}\text{ob}$ mice.     

Phase transitions of phospholipid single-wall vesicles and multilayers. Measurement by vibrational raman spectroscopic frequency differences

Raman spectroscopic frequency differences between selected carbon-carbon stretching modes of lipid hydrocarbon chains were determined as a function of temperature for use in monitoring lipid phase transition behavior and acyl chain disorder in both multilamellar and single-wall vesicles. Transition temperatues detected by this procedure for pure dipalmitoyl phosphatidylcholine and dimyristoyl phosphatidylcholine multilayers were observed at $\text{39±1 °}\text{C}$ and $\text{23±1 °}\text{C}$, respectively. Although the phase transition for unilamellar vesicles of dipalmitoyl phosphatidylcholine occurred at nearly the same temperature as the multilayers, the crystal-liquid crystalline transition for the single-shell vesicles appeared to span a slightly broader temperature range, a characteristic consistent with irregularities in the packing arrangement of the hydrocarbon chains. Within the precision of the Raman spectroscopic method, however, the temperature behavior of both the multilamellar and the unilamellar dimyristoyl phosphatidylcholine assemblies appeared nearly identical. The temperature profile for the Raman frequency differences of an excess water sonicate of 25 mol percent cholesterol in dipalmitoyl phosphatidylcholine served as an example of the effect upon lipid phase transition characteristics of a bilayer component intercalated between the acyl chains. For this particular cholesterol-lipid system the phase transition was broadened over a 30 °C temperature range, in contrast to the narrow 5?4 °C range observed for pure multilayer and single-shell vesicle particles.     

Remodeling of rat hepatocyte phospholipids by selective acyl turnover

Acyl turnover of rat hepatocyte phospholipids and triacylglycerols was assessed by incubating the cells in media containing 40% H2(18)O and measuring the time-dependent incorporation of 18O into ester carbonyls by gas chromatography-mass spectrometry of hydrogenated methyl esters. Incorporation of 18O into 22-carbon acyl groups was low in phosphatidylcholine, phosphatidylinositol, and phosphatidylserine, whereas in phosphatidylethanolamine, it was about the same as in the other acyl groups. Incorporation of 18O into individual molecular species of phosphatidylcholine and phosphatidylethanolamine was determined after phospholipase C hydrolysis, derivatization to dinitrobenzoates, and separation by high-performance liquid chromatography. In most molecular species, acyl groups at the sn-1 and sn-2 positions became 18O-labeled at drastically different rates, indicating remodeling through deacylation-reacylation. Molecular species expected to arise de novo from acylation of glycerophosphate exhibited similar rates of 18O incorporation at the sn-1 and sn-2 positions. The data suggest that hepatocyte phospholipids are continually synthesized, remodeled by deacylation-reacylation at specific turnover rates up to 10-15%/h, and degraded. This acyl turnover probably does not involve the majority of intracellular unesterified fatty acids whose 18O incorporation was found to be very low. In contrast, the oxygens of extracellular unesterified fatty acids were readily exchanged with the media. This exchange was enzyme-catalyzed, possibly by lipases released into the media from damaged cells. Incorporation of 18O into exogenously added fatty acids was also rapid and resulted in enhanced uptake of 18O-labeled fatty acids into cellular lipids, primarily triacylglycerols and phosphatidylcholine, without drastic change of the intracellular free fatty acid pool.     

Molecular species specificity of phospholipid breakdown in microsomal membranes of senescing carnation flowers

During senescence of cut carnation flowers, there is extensive breakdown of microsomal phospholipid. This is attributable, at least in part, to lipolytic activity associated directly with the microsomal membranes. Evidence indicating that one or more of the lipid-degrading enzymes in these membranes preferentially degrade phospholipid molecular species containing two diunsaturated acyl chains or at least one polyunsaturated acyl chain has been obtained by using radiolabeled phosphatidylcholine substrates. 16:0^*/16:0^*, 16:0/18:2^*, and 18:1^*/18:1^* phosphatidylcholine were degraded only minimally over a 3 hour period by microsomes isolated from senescing flowers. By contrast, [U-¹⁴C]phosphatidylcholine, which comprises various molecular species including those containing polyunsaturated acyl chains, and 18:0/20:4^* phosphatidylcholine were extensively degraded. Under identical conditions, but in the absence of added radiolabeled substrate, endogenous 18:2/18:2, 18:1/18:3, and 18:2/18:3 phosphatidylcholine were selectively depleted from the membranes. During natural senescence of the flowers, there was a sharp decline in microsomal 16:0/18:1 and 18:1/18:2 phosphatidylcholine, whereas molecular species containing two diunsaturated acyl chains or at least one polyunsaturated acyl chain remained unchanged or decreased only slightly. The data have been interpreted as indicating that provision of particular molecular species susceptible to lipase attack is a prerequisite to phospholipid catabolism in senescing membranes.     

Plant Microsomal Phospholipid Acyl Hydrolases Have Selectivities for Uncommon Fatty Acids

Developing endosperms and embryos accumulating triacylglycerols rich in caproyl (decanoyl) groups (i.e. developing embryos of Cuphea procumbens and Ulmus glabra) had microsomal acyl hydrolases with high selectivities toward phosphatidylcholine with this acyl group. Similarly, membranes from Euphorbia lagascae and Ricinus communis endosperms, which accumulate triacylglycerols with vernoleate (12-epoxy-octadeca-9-enoate) and ricinoleate (12-hydroxy-octadeca-9-enoate), respectively, had acyl hydrolases that selectively removed their respective oxygenated acyl group from the phospholipids. The activities toward phospholipid substrates with epoxy, hydroxy, and medium-chain acyl groups varied greatly between microsomal preparations from different plant species. Epoxidated and hydroxylated acyl groups in sn-1 and sn-2 positions of phosphatidylcholine and in sn-1-lysophosphatidylcholine were hydrolyzed to a similar extent, whereas the hydrolysis of caproyl groups was highly dependent on the positional localization.     

ACYL GROUP COMPOSITION OF METABOLICALLY ACTIVE LIPIDS IN BRAIN: VARIANCES AMONG SUBCELLULAR FRACTIONS AND DURING POSTNATAL DEVELOPMENT

Using a combination of preparative TLC and GLC technique, the content and acyl group composition of diacyl-glycerophosphoinositols, diacyl-glycerophosphates, diacylglycerols and triacyl-glycerols in brain tissue were determined. The level of diacyl-glycerophosphoinositols in 40 day-old mouse brain was 2.7 μmol/g tissue as compared to 40–170 nmol/g for other minor lipids. The acyl groups of diacyl-glycerophosphoinositols were enriched in 18:0 and 20:4 (n-6). This characteristic acyl group profile was found in microsomes, synaptosomes, and in myelin. The acyl groups of diacyl-glycerophosphates and diacylglycerols were comprised mainly of 16:0, 18:0, 18:1 and 20:4 (n-6). In rat brain subcellular fractions, the acyl groups of diacylglycerols and diacyl-glycerophosphates in the microsomal fraction had a higher proportion of 22:6 (n-3) than those in the myelin and synaptosomal fractions. The acyl groups of the myelin lipids were higher in 18:l and lower in 20:4 (n-6) as compared to those in the microsomal and synaptosomal fractions. The triacylglycerols in brain exhibited an unusual acyl group profile which included small proportions of 14:0, 16:1, 20:4 (n-6), 22:4 (n-6) and 22:6 (n-3). Except for an increase in 18:1 and a corresponding decrease in 16:0 which was found in diacyl-glycerophosphoinositols, no apparent acyl group change was observed in other metabolically active lipids during postnatal brain development.     

Incorporation of newly synthesized fatty acids into cytosolic glycerolipids in pea leaves occurs via acyl editing

In expanding pea leaves, over 95% of fatty acids (FA) synthesized in the plastid are exported for assembly of eukaryotic glycerolipids. It is often assumed that the major products of plastid FA synthesis (18:1 and 16:0) are first incorporated into 16:0/18:1 and 18:1/18:1 molecular species of phosphatidic acid (PA), which are then converted to phosphatidylcholine (PC), the major eukaryotic phospholipid and site of acyl desaturation. However, by labeling lipids of pea leaves with [(14)C]acetate, [(14)C]glycerol, and [(14)C]carbon dioxide, we demonstrate that acyl editing is an integral component of eukaryotic glycerolipid synthesis. First, no precursor-product relationship between PA and PC [(14)C]acyl chains was observed at very early time points. Second, analysis of PC molecular species at these early time points showed that >90% of newly synthesized [(14)C]18:1 and [(14)C]16:0 acyl groups were incorporated into PC alongside a previously synthesized unlabeled acyl group (18:2, 18:3, or 16:0). And third, [(14)C]glycerol labeling produced PC molecular species highly enriched with 18:2, 18:3, and 16:0 FA, and not 18:1, the major product of plastid fatty acid synthesis. In conclusion, we propose that most newly synthesized acyl groups are not immediately utilized for PA synthesis, but instead are incorporated directly into PC through an acyl editing mechanism that operates at both sn-1 and sn-2 positions. Additionally, the acyl groups removed by acyl editing are largely used for the net synthesis of PC through glycerol 3-phosphate acylation.     

Emission-wavelength-dependent decay of the fluorescent probe N-phenyl-1-naphthylamine

We have measured the fluorescence decay of $\text{N-}\text{phenyl}\text{-1-}\text{naphthylamine}$ using the phase-modulation method, in several solvent systems and egg phosphatidylcholine vesicles. The decay is monoexponential in pure solvents (both polar and non-polar) of low viscosity. In polar viscous solvents or in non-polar solvents containing an added polar solute, the decay is heterogeneous and emission wavelength dependent. In such cases, dielectric relaxation and/or excited-state complexing give rise to a shift of the emission spectrum on the nanosecond time scale. Emission-wavelength-dependent decay was also observed when $\text{N-}\text{phenyl}\text{-1-}\text{naphthylamine}$ was bound to egg phosphatidylcholine vesicles. From these results as well as the position of the emission spectral maximum, we conclude that $\text{N-}\text{phenyl}\text{-1-}\text{naphthylamine}$ probes the ester-carbonyl region of the phospholipid acyl chains, where it undergoes an excited-state reaction. This result contradicts the often made assumption that $\text{N-}\text{phenyl}\text{-1-}\text{naphthylamine}$ probes the deeper hydrocarbon region of the bilayer.     

A crystalline lipid phase in a dry biological system: evidence from X-ray diffraction analysis of Typha latifolia pollen

The temperature limits for germination in Typha latifolia pollen lie within the range 4-40 degrees C. These limits correlate at the low-temperature end with the 'crystallization' of endogenous triacylglycerols and on the high-temperature end with the 'melting' of a gel-like lipid component in intact pollen. X-ray diffraction analysis was used to structurally characterize and to trace the latter gel-like lipid from the intact pollen through a range of pollen lipid fractions. We tentatively identify this component as a fatty acyl sterol ester and present evidence that it resides in the exine of the pollen grain. Its thermotropic behavior is insensitive to pollen hydration. The possibility of interpreting a crystalline lipid phase as being membrane-derived when in fact it originates from contaminating non-membranous neutral lipid is discussed. The total lipid content of T. latifolia pollen is 123 mg/g dry weight, of which 37% is polar lipid. The neutral lipid consists primarily of triacylglycerols and of the aforementioned sterol ester, which represents 0.34% (w/w) of pollen dry weight. The polar lipid fraction has phosphatidylcholine, phosphatidylethanolamine and phosphatidic acid as major components with lesser amounts of phosphatidylglycerol and phosphatidylinositol. Palmitic (16:0) and linoleic (18:2) acids, in a 1:2 molar ratio, constitute the major fatty acids of both polar and neutral lipid fractions with lesser amounts of linolenic (18:3), oleic (18:1) and stearic (18:0) acid in evidence.     

On the possibility of the MN blood group determination in human bones

After a series of preliminary tests on inert substances and on saliva drawn from donors of know MN blood group, 31 right femura from Pisa cemetery buried for 25–30 years and 37 eneolithic femura from Gaudo necropolis near Paestum (2500 – 2000 B.C.) were submitted to 140 assays for the MN system using the standard technique already devised in our Laboratory for ABO blood group determination.Positive and reproducible results were obtained in 18:31 recent femura (58%) and in 24:37 eneolithic bones (65%). The following phenotype and gene frequencies were obtained:

$\text{recent femura:}\text{8.}\text{M}\text{+3.}\text{N}\text{+7.}\text{MN}\text{=18; 0·64m+0.·36n=1}$

$\text{eneolithic femura:}\text{9.}\text{M}\text{+6.}\text{N}\text{+9.}\text{MN}\text{=24; 0·56m+0·44n=1}$

When the ABO and the MN blood group determinations are performed in parallel, a significant positive connection between the two diagnosabilities is observable: P = 0·0387 in the case of the eneolithic bones, $\text{P ? 0·02}$ in the case of the total sample of 59 eneolithic and recent bones tested in parallel. This fact could be reasonably explained considering the similarity of the chemical structure of MN and ABO glycoproteins, which would account for a similar behaviour in preservation.The absence or the very low concentration of M and N substances in tissues and body fluids would on the other hand agree with the percentage of diagnosability: lower in the MN system (60–65%) than in the ABO system (75–80%). The more problematical character of MN blood group typing of bones could be better approached if further research were done.     

Phosphatidylinositol distribution and translocation in sonicated vesicles. A study with exchange protein and phospholipase C

The distribution of phosphatidylinositol and phosphatidylcholine in sonicated phospholipid vesicles (phosphatidylcholine: diphosphatidylglycerol: phosphatidylinositol, 90:5:5 mol%) has been determined by the use of exchange protein from beef heart and phosphatidylinositol-specific phospholipase C from Staphylococcus aureus. Approximately 70% of the phosphatidylinositol in the sonicated vesicles was accessible to the exchange protein and 70–75% was accessible to the phospholipase C. A similar proportion (65%) of the phosphatidylcholine was accessible to the exchange protein suggesting that phosphatidylinositol was not preferentially located in either surface of the phospholipid bilayer. The rate of translocation of both phospholipids was very slow but the rate for phosphatidylcholine ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 4–7}\text{days}$) appeared to be greater than that for phosphatidylinositol ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{= 8–60}\text{days}$). Production of asymmetric vesicles by removing phosphatidylinositol from the outer surface with either exchange protein or phospholipase C did not induce rapid phospholipid translocation.