Ultracentrifugation studies of the location of the site involved in the interaction of pig heart lactate dehydrogenase with acidic phospholipids at low pH. A comparison with the muscle form of the enzyme

Lactate dehydrogenase (LDH) from the pig heart interacts with liposomes made of acidic phospholipids most effectively at low pH, close to the isoelectric point of the protein (pH = 5.5). This binding is not observed at neutral pH or high ionic strength. LDH-liposome complex formation requires an absence of nicotinamide adenine dinucleotides and adenine nucleotides in the interaction environment. Their presence limits the interaction of LDH with liposomes in a concentration-dependent manner. This phenomenon is not observed for pig skeletal muscle LDH. The heart LDH-liposome complexes formed in the absence of nicotinamide adenine dinucleotides and adenine nucleotides are stable after the addition of these substances even in millimolar concentrations. The LDH substrates and studied nucleotides that inhibit the interaction of pig heart LDH with acidic liposomes can be ordered according to their effectiveness as follows: NADH > NAD > ATP = ADP > AMP > pyruvate. The phosphorylated form of NAD (NADP), nonadenine nucleotides (GTP, CTP, UTP) and lactate are ineffective. Chemically cross-linked pig heart LDH, with a tetrameric structure stable at low pH, behaves analogously to the unmodified enzyme, which excludes the participation of the interfacing parts of subunits in the interaction with acidic phospholipids. The presented results indicate that in lowered pH conditions, the NADH-cofactor binding site of pig heart LDH is strongly involved in the interaction of the enzyme with acidic phospholipids. The contribution of the ATP/ADP binding site to this process can also be considered. In the case of pig skeletal muscle LDH, neither the cofactor binding site nor the subunit interfacing areas seem to be involved in the interaction.     

Acylation of 1-alkenylglycerophosphoethanolamine and 1-acylglycerophosphoethanolamine in guinea-pig heart microsomes

Although the acylation of 1-alkenylglycerophosphocholine in mammalian heart is well documented, the acylation of 1-alkenylglycerophosphoethanolamine in the heart was not reported. In this study, the presence of acyl CoA: 1-alkenylglycerophosphoethanolamine acyltransferase in the guinea pig heart microsomes was demonstrated. 1-Alkenylglycerophosphoethanolamine acyltransferase displayed a high degree of specificity towards acyl-CoA. The order of reactivity with acyl-CoA was found to be: linoleoyl much greater than arachidonyl greater than palmitoyl greater than stearoyl = oleoyl. 1-Acylglycerophosphoethanolamine acyltransferase in the microsomes also exhibited specificity towards acyl-CoA in the following manner: linoleoyl greater than arachidonyl much greater than palmitoyl greater than oleoyl greater than stearoyl. However, such specificity appeared to be dependent on acyl-CoA concentration. The acyl-CoA specificities of both enzymes did not correlate with the C-2 acyl distribution observed in the corresponding microsomal phospholipids. Our results suggest that in addition to the acyl specificity of the acyltransferases, intracellular concentrations of acyl-CoAs may also have an important role in determining the observed acyl patterns of the phospholipids. Based on the acyl specificities, pH profiles, and their responses to heat inactivation and thiol reagents, we conclude that 1-alkenylglycerophosphoethanolamine acyltransferase and 1-acylglycerophosphoethanolamine acyltransferase in guinea-pig heart microsomes are not the same enzyme.     

Effects of fatty acid deficiency on the lipid composition and physical properties of guinea pig rough endoplasmic reticulum

Twenty-six days of fat deficiency brought about a decrease of linoleic and an increase of oleic acid in rough endoplasmic reticulum (RER) of guinea pig liver. Arachidonic acid was only slightly decreased in some phospholipids whereas eicose-5,8,11-trienoic acid was not enhanced except in phosphatidyl-inositol. All these changes were relevant specifically in phosphatidylinositol molecules and less important in phosphatidylcholine and phosphatidylethanolamine. Fat deficiency did not modify the relative proportion of phospholipids and cholesterol. Therefore, fat deficient guinea pig microsomes are a good model to study the effect of unsaturated fatty acids on membrane properties. Fluorescent anisotropy of RER membranes, lipids and phospholipids labeled with diphenylhexatriene, was increased by the fat deficiency. The most important increase was observed in liposomes of a mixture of RER phosphatidylinositol, phosphatidylserine and sphingomyelin. A small change was found in phosphatidylcholine and phosphatidylethanolamine dispersions at 37°C. The modification of the lipid unsaturation evoked fluorescent anisotropy changes. Temperature-dependent fluorescent polarization curves of RER membranes labeled with trans-parinaric acid did not show inflections in the temperature range from 5 to 45°C but, RER lipids and phospholipids presented a phase separation at about 20°C. This inflection point was not modified by the fat deficient diet. In those liposomes prepared with a mixture of RER phosphatidylinositol, phosphatidylserine and sphingomyelin, the inflection point was produced at about 37°C.The author is member of the Carrera del Investigador Cientifico, Consejo Nacional de Investigaciones Cientificas y Técnicas, Argentina.     

Lipid composition and protein profiles of outer and inner membranes from pig heart mitochondria. Comparison with microsomes.

1. Mitochondria, inner and outer mitochondrial membranes and microsomes were isolated and purified from pig heart. Their lipid composition and protein components were studied. 2. The fatty acid distribution in the main phospholipids seemed specific rather of a given phospholipid and not of one type of membrane. 3. Inner mitochondrial membranes were characterized by a high content in cardiolipin and a very low level of triglycerides together with a high degree of unsaturation and C18 acids. Gel electrophoresis revealed 13 different polypeptide subunits of which 5 were major ranging in molecular weights from 10000 to 215000. 4. In outer mitochondrial membranes, total lipid, phosphatidylcholine, phosphatidylinositol, plasmologen and triglyceride contents were much higher than in inner membranes. Fatty acids of phospholipids were mostly saturated and the polypeptide pattern showed 12 components, of which 4 were major of mol. wt 75000, 60000, 20000 and below 10000. 5. Compared to outer membrane, microsomes exhibited a much higher cholesterol content and markedly different protein profiles. They contained significant amounts of cardiolipin and phosphatidylserine, this latter phospholipid being exclusively located in microsomes. However odd similarities were observed in some lipid components of microsomes and inner mitochondrial membranes, but fatty acids were more saturated in microsomes and electrophoretic profiles of protein components appeared very different and revealed components of high mol. wt.     

Regulatory properties of 14 day embryo and adult hen heart AMP-deaminase

Chromatography on phosphocellulose column revealed changes in the elution profile of chicken heart AMP-deaminase during ontogenesis. The extracts from the heart of adult hen and 14 day-old embryo displayed a single peak of the enzyme activity at a slightly different elution volume, whereas in the heart extract of 1 day-old chicken two molecular forms of adenylate deaminase have been eluted. The kinetic and regulatory properties of the purified adult hen heart AMP-deaminase were studied and compared with those of the corresponding enzyme from 14 day-old embryo heart. Both enzymes exhibited a slightly sigmoid-shaped plot of the reaction rate versus substrate concentration, which shifted to hyperbolic form when ATP or ADP were added into the incubation medium. The enzymes were strongly activated by ATP, less efficiently by ADP and the activatory effect was enhanced at low substrate concentration. Orthophosphate inhibited both enzymes but this inhibition was more potent for the embryo heart enzyme. Palmitoyl-CoA inhibited adult hen but not the embryo heart AMP-deaminase. The data presented indicate that the differences also in the regulatory properties of the molecular forms studied do exist and correspond with the ontogenetic differences observed previously (Kaletha and Skladanowski (1981) Experientia 37, 232-234) concerning the effect of temperature on the chicken heart adenylate deaminase.     

AMPD1 C34T mutation selectively affects AMP-deaminase activity in the human heart

Possession of the nonsense mutation in AMPD 1 C34T gene has been linked to improved survival in patients with heart failure, possibly by promoting the formation of adenosine. This mutation is known to decrease the activity of AMP-deaminase in skeletal muscle. We have found that the AMPD1 mutation decreases the activity of AMP-deaminase in the heart without changing the activity of any other enzymes of adenine nucleotide metabolism. Protective mechanism of this mutation may be thus induced by local cardiac metabolic changes.     

Partial purification and characterization of the phosphate transporter from bovine heart mitochondria.

A highly active phosphate transporter was extracted with octylglucoside from bovine heart submitochondrial particles that were first partially depleted of other membrane components. It was then partially purified by ammonium sulfate fractionation. After reconstitution of the transporter into liposomes prepared with a crude mixture of soybean phospholipids, the Pi/OH exchange, but not the Pi/Pi exchange, was stimulated three- to fourfold by valinomycin and nigericin in the presence of K+. Both Pi/OH and Pi/Pi exchange activities were sensitive to mercurials and other SH reagents. The rutamycin-sensitive ATPase complex from mitochondria was reconstituted together with the phosphate transporter and adenine nucleotide transporter into liposomes. After inhibition of externally located ATPase, the hydrolysis of ATP was sensitive to atractyloside and mersalyl.     

Binding of cardiolipin/lecithin and monoamine oxidase to lipid-depleted mitochondrial membrane structure.

Lipid-depleted pig liver mitochondrial residues were incubated with different proportions of the acidic phospholipid cardiolipin and the zwitterionic phospholipid lecithin in either separate or mixed liposomes. When cardiolipin and lecithin were present in separate liposomes all of the cardiolipin but no lecithin bound to the residues. When present in the same liposomes, cardiolipin also caused binding of lecithin to the mitochondrial residues. When monoamine oxidase solubilized from pig liver mitochondria by extraction of the phospholipids was included in the incubation, binding of the enzyme to the residues occurred in the presence of cardiolipin. The percentage of enzyme bound followed the same trend as the binding of phospholipids to the mitochondrial residues.     

Characterization of highly purified ornithine decarboxylase from rat heart

The fatty acid composition of cultured Friend erythroleukemia cells was modified by supplementation of the medium with oleic or linoleic acid. There was a 30% reduction in saturated and a 35% reduction in polyunsaturated fatty acids in microsomal phospholipids when the cells were grown in media supplemented with oleic acid, and a 3-fold increase in polyunsaturated fatty acids when the cells were grown in linoleic acid-supplemented media. Electron-spin resonance studies with the 5- nitroxystearate probe demonstrated that there was no appreciable change in microsomal lipid mobility as measured by the order parameters. In contrast, changes in lipid mobility were detected with the spin-label probe when microsomes were first isolated from Friend erythroleukemia cells and subsequently modified by incubation with liposomes composed of either dioleoyl- or dilinoleoylphosphatidylcholine plus bovine liver phospholipid-exchange protein. The fatty acid compositional changes produced in these microsomes were similar to those obtained when the intact cells were grown in media containing supplemental fatty acids. These findings indicate that the lipid mobility of Friend cell microsomes can be altered by phospholipid replacements in vitro, but that this does not occur when similar microsomal fatty acid modifications are produced during culture of the intact cell.     

Ultrastructural changes in the sarcolemma in the early stages of immune damage to the heart

Early ultrastructural alterations were studied in cardiomyocyte sarcolemma on the model of acute local immune injury after the treatment of the dog's heart with anticardiac cytotoxic serum. It has been shown that immunotherapy results in the formation of numerous liposomal structures originating from the membrane material and located in subsarcolemmal space and near cardiomyocyte mitochondria. Depending on the method of fixation liposomes had the form of circular membrane vesicles or multilaminar structures. The structure and location of these liposomes near plasmalemma or mitochondrial membranes and sarcoplasmic reticulum have led to the assumption that they originate from unstable membrane phospholipids. The present data give evidence of the early and rapid phospholipid degradation in cardiomyocyte membranes during immune heart damage.     

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.     

Regulation by Lipids of Plant Microsomal Enzymes: III. Phospholipid Dependence of the Cytidine-Diphospho-Choline Phosphotransferase of Potato Microsomes

Cytidine-diphospho-choline diacyl-glycerol phosphorylcholine phosphotransferase activity was demonstrated in potato (Solanum tuberosum L.) microsomes and the incorporation of cytidine-diphospho[¹⁴C]choline into phosphatidylcholine was characterized by the time course of ¹⁴C incorporation and the effect of microsomal protein concentration on choline incorporation.

Potato microsomes were progressively delipidated by treatments (2 min at 0°C) with increasing amounts of phospholipase C from Bacillus cereus. A decrease in choline phosphotransferase activity was observed in parallel with the progressive hydrolysis of membrane phospholipids. A 70% (or more) phospholipid hydrolysis provoked the total inactivation of the enzyme.

Adding back exogenous phospholipids (in the form of liposomes) to phospholipase C-treated membranes restored the enzymic activity. Restoration could be obtained with egg yolk phospholipids as well as with potato phospholipids. Restoration was time dependent and completed after 10 minutes; restoration was also dependent on the quantity of liposomes added to lipid-depleted membranes: the best restorations were obtained with 1 to 2.5 milligrams of phospholipid per mg of microsomal protein; higher phospholipid to protein ratios were less efficient or inhibitory.

These results clearly demonstrate the phospholipid dependence of the cytidine-diphospho-choline phosphotransferase from potato microsomes.

     

The role of cardiolipin as an acyl donor in dog heart N-acylethanolamine phospholipid biosynthesis

N-Acylethanolamine phospholipids were produced from endogenous substrates with dog heart mitochondrial and microsomal preparations. With mitochondria the N-acyl group contained 13.8% linoleate, with microsomes only 3.6%. Cardiolipin comprised 18.5% of mitochondrial and 3.3% of microsomal lipid P and contained 93.7 and 72.4% linoleic acid, respectively. Incubation of dog heart subcellular fractions with [1-14C]linoleoyl cardiolipin in the presence of Ca2+ resulted in the formation of N-acylethanolamine phospholipids labeled primarily in the N-acyl and 1-O-acyl moieties. The data indicate that cardiolipin is the major source of linoleic acid used in the N-acylation of ethanolamine phospholipids by transacylase activity.     

Phosphatidylinositol exchange protein. Effects of membrane structure on activity and evidence for a ping-pong mechanism.

Phosphatidylinositol exchange protein, purified from bovine cerebral cortex, catalyzes the transfer of phosphatidylinositol and, to a lesser extent, phosphatidylcholine between rat liver microsomes and egg phosphatidylcholine liposomes. Transfer activity is sensitive to pH, temperature, and the method of liposome preparation. Variation of the phospholipid composition of the liposomes produces vesicles for which the apparent Michaelis constant decreases with increasing molar proportions of phosphatidylinositol. Interaction of exchange protein with liposomes containing radioactively labeled phosphatidylcholine allows the isolation of a phospholipid-protein complex; dissociation of this complex occurs upon subsequent interaction with unlabeled liposomes. Changes in the concentration of the two membrane species, microsomes and liposomes, yield results which are interpreted in terms of a ping-pong kinetic mechanism for the protein-catalyzed, intermembrane transfer of phospholipids.     

Characterization and binding properties of fatty acid-binding proteins from human, pig, and rat heart

Fatty acid-binding proteins (FABPs) were isolated from the cytosols of hearts of man, pig, and rat by gel filtration and anion-exchange chromatography. The heart FABPs had a Mr of about 15,000 (pig, rat) and 15,500 (man); pI values were 5.2, 4.9, and 5.0 for human, pig, and rat heart, respectively. In contrast to liver FABPs, tryptophan was present in the heart FABPs. Binding characteristics for long-chain fatty acids determined with the radiochemical Lipidex assay were comparable for all three proteins. Heart FABPs also bind palmitoyl-CoA and -carnitine with an affinity comparable to that for palmitic acid. Other ligands investigated, heme, bilirubin, cholesterol, retinoids, and prostaglandins, could not compete with oleic acid for binding by human heart FABP. Binding parameters of FABP for oleic acid from multilamellar liposomes were comparable to those from the Lipidex binding assay. Immunological interspecies cross-reactivity with antisera against the heart FABPs was much higher between man and pig than between rat and man or pig. None of the antisera reacted with liver FABPs. The IgG fraction of anti-human heart FABP serum inhibited fatty acid binding to human heart FABP.     

The phospholipase A2-induced increase in the permeability of phospholipid membranes to Ca2+ and H+ ions

The permeability of liposomes prepared from beef heart mitochondrial phospholipids was studied after treatment with phospholipase A2. The permeability to H+ ions was measured by recording the rate of change of pH in the external medium following an addition of an aliquot of alkali to liposomes with a highly buffered inner medium, while the penetration of Ca2+ ions into liposomes was measured in liposomes loaded with arsenazo III. There was a doubling of H+ permeability when the lysophospholipid content was increased to 2% by treatment with phospholipase A2, and a tripling at 4%. Entrapped sucrose leakage from liposomes became apparent at above 6% lysophospholipid. Treatment with phospholipase A2 stimulated Ca2+ penetration into liposomes driven by a valinomycin-induced diffusion potential or a nigericin-induced H+ gradient. The data are discussed in relation to the mechanism of damage to mitochondria occurring in Ca2+ overload as well as in phospholipase A2-induced cellular damage.     

Comparative studies on heart and skeletal muscle AMP-deaminase from rainbow trout (Salmo gairdneri).

1. AMP-deaminases from fish heart and skeletal muscle have been isolated, and their kinetic and regulatory properties compared. 2. The results obtained indicate that the enzyme variants present in fish heart and skeletal muscle, in contrast to their mammalian counterparts, show very similar chromatographic, kinetic and regulatory characteristics. 3. The above may reflect evolutionary programmed differences in AMP-deaminase gene(s) organization.     

Membrane damage of liposomes by the mushroom toxin phallolysin

We have investigated the membrane-damaging effect of phallolysin on liposomes varying in phospholipid composition, net charge and physical constitution. Liposomes were prepared from lipids extracted from bovine or human erythrocyte ghosts. The liposomes composed of bovine lipids (the intact cell showing little sensitivity to phallolysin) were found comparably sensitive to those prepared from lipids of human red cells (these cells being of high sensitivity). In addition, artificial mixtures of lipids were used for the preparation of liposomes, consisting of (a) negatively charged phospholipids such as dicetyl phosphate or phosphatidylserine, (b) cholesterol, and (c) either sphingomyelin (as the major component of erythrocytes from ruminants) or phosphatidylcholine (as the major component of erythrocytes from non-ruminants). Again, we found only little difference in the susceptibilities of sphingomyelin- and phosphatidylcholine-containing liposomes. On the other hand, the susceptibility depended on the presence of phospholipids with negative net charges. Omittance of phosphatidylcholine or dicetyl phosphate, or replacement by the positively charged stearylamine, decreased the susceptibility by a factor of more than 20. Finally, we prepared liposomes from dicetyl phosphate, cholesterol and phosphatidylcholine in two physical states: large unilamellar and smaller multilamellar liposomes. The unilamellar liposomes were about 10-times more sensitive to phallolysin. We conclude: (1) Phallolysin damages phospholipid-membranes in the absence of receptor proteins, but high concentrations of the toxin are required. (2) Membrane damage takes place with liposomes containing phosphatidylcholine as well as those containing sphingomyelin. (3) Phallolysin damages only liposomes containing phospholipids with a negative net charge.     

Acylation of 1-alkenyl-glycerophosphocholine and 1-acyl-glycerophosphocholine in guinea pig heart.

The deacylation-reacylation process has been shown to be an important pathway for phospholipids to attain the desired acyl groups at the C-2 position. The acylation of 1-acyl-glycerophosphocholine (-GPC) in mammalian hearts has been well documented, but the acylation of 1-alkenyl-GPC has not been described. In this paper, we demonstrate the presence of acyl-CoA: 1-alkenyl-GPC acyltransferase for the acylation of 1-alkenyl-GPC in mammalian hearts; the highest activity is found in guinea pig heart. The guinea pig heart 1-alkenyl-GPC acyltransferase has only 10-40% of the 1-acyl-GPC acyltransferase activity, and both activities are located in the microsomal fraction. However, these two enzymes respond differently to cations, detergents and heat treatment, and the two enzymes also display different acyl specificity. Kinetic studies indicate that both reactions could not be accommodated by the same catalytic site. The results provide strong evidence that the two activities are from separate and distinct proteins. The specificity of 1-alkenyl-GPC acyltransferase for unsaturated species of acyl-CoA may play an important role in the maintenance of the high degree of unsaturated acyl groups found in guinea pig heart plasmalogens.     

Polymer-coated liposomes resistant to enzymatic hydrolysis

A polymerizable electrolyte, 2-aminoethyl 1,6-heptadien-4-yl phosphate (AEHDP), which has the same hydrophilic head group as naturally occurring phospholipids, was prepared. Five equivalents of AEHDP were added to a suspension of liposomes (closed bilayer vesicles made of phospholipids) and layered on the liposomes. After polymerization by UV irradiation, the resulting polymer-coated liposomes were resistant to hydrolysis of their constituent phospholipids by phospholipase A2.