Hormone-calcium interactions with the plasma membrane of rat liver cells.

The binding constants and the number of binding sites for insulin, glucagon, epinephrine, cyclic adenosine monophosphate, and calcium ions for the plasma membrane of rat liver were determined by Scatchard plots. The plots are biphasic or multiphasic, an indication of at least two types of binding sites for each ligand. At least three types of binding sites were found for insulin. In the concentration range of 10(-6) to 10(-8) molar, glucagon, epinephrine, and hydro-cortisone increased calcium ion binding to the plasma membrane, whereas insulin decreased this binding. At hormone concentrations of 10(-6) to 10(-7) molar, glucagon was the most effective in increasing calcium binding, but at a hormone concentration of 10(-8) molar, hydrocortisone was the most effective in stimulating calcium binding. Adenosine triphosphate reversed the effect of insulin and inhibited the effect of the other hormones. These studies suggest a relation between hormones and calcium with respect to membrane structure and function.

Yolk pigments of the Mexican leaf frog.

Eggs of the Mexican leaf frog contain blue and yellow pigments identified as biliverdin and lutein, respectively. Both pigments are bound to proteins that occur in crystalline form in the yolk platelet. The major blue pigment is biliverdin IX alpha. The eggs vary in color from brilliant blue to pale yellow-green depending on the amount of each pigment. These pigments may provide protective coloration to the eggs.

Arrangement of phosphatidylserine and phosphatidylethanolamine in the erythrocyte membrane.

Cross-linking of phosphatidylethanolamine and phosphatidylserine in the erythrocyte membrane with the reagent difluorodinitrobenzene was studied as a function of temperature, time and concentration of difluorodinitrobenzene. The optimal extent of cross-linking of phosphatidylethanolamine to phosphatidylethanolamine, phosphatidylethanolamine to phosphatidylserine and phosphatidylserine to phosphatidylserine was expressed as molar ratios of these three different cross-linked species. The experimental results were compared to different models of a phospholipid monolayer containing phosphatidylethanolamine and phosphatidylserine in which phosphatidylserine was arranged primarily as singles (having 6 phosphatidylethanolamine neighbors) as clusters of dimers, trimer and tetramers or as large clusters. In the various model monolayers each lipid component has 6 neighbors. The models which are consistent with the experimental results are those in which phosphatidylserine and phosphatidylethanolamine occur as small clusters in a non-random array.

Hormone action at the membrane level. IV. Epinephrine binding to rat liver plasma membranes and rat epididymal fat cells.

[3-H]Epinephrine binding to isolated purified rat liver plasma membranes is a reversible process. An initial peak in binding occurs at about 15 min and a plateau occurs by 50 min. Optimal binding occurred at a membrane protein concentration of 125mug. Rat liver plasma membranes stored at-70 degrees C up to 4 weeks showed no difference in epinephrine binding capacity as compared to control fresh membranes. Epinephrine binding to liver plasma membranes was decreased by 79% by phospholipase A2 (phosphatide acylhydrolase EC 3.1.1.4), 81% by phospholipase C (phosphatidylcholine choline phosphohydrolase EC 3.1.4.3) and 59% by phospholipase D (phosphatidylcholine phosphatidohydrolase EC 3.1.4.4). Trypsin and pronase digestion of the membrane decreased epinephrine binding by 97 and 47% respectively. In the presence of 10-3M Mg-2+ ions, increasing concentrations of QTP decreased epinephrine binding to liver plasma membranes. A maximal effect was demonstrated with 10-5M GTP, representing an inhibition of 52% of the control. In a Mg-2+ -free system, epinephrine binding was unaffected by GTP. However, in a Mg-2+ -free system, increasing concentrations of ATP cause increasing inhibition of hormone binding. ATP at 10-3 M reduced epinephrine binding to 28% of the control. GRP (10-5 M) was shown to inhibit epinephrine uptake rather than epinephrine release from the membrane. [3-H]Epinephrine binding to isolated rat epididymal fat cells shows an initial peak within 5 min followed by a gradual rise which plateaus after 60 min. Epinephrine binding increased nearly linearly with increasing fat cell protein concentration (40-200 mug protein). GTP (10-5 M) and ATP (10-4 M) decreased epinephrine binding to rat epididymal fat cells by 41%. Nearly complete inhibition of binding was demonstrated with 10-2-10-3M ATP. Epinephrine analogs that contain two hydroxyl groups in the 3 and 4 position on the benzene ring act as inhibitors of [3-H]epinephrine binding to rat adipocytes. Alteration of the epinephrine side chain has relatively little influence on binding. Analogs in which one of the ring hydroxyl groups is missing or methylated are poor inhibitors of [3-H]epinephrine binding. Alpha-(phentolamine and phenoxybenzamine) and beta-(propranolol and dichorisoproterenol) adrenergic blocking agents were tested with respect to their ability to influence [3-H]epinephrine binding and their influence on epinephrine-stimulated lipolysis. Only dichloroisoproterenol significantly inhibited epinephrine binding (by 25%). The two beta-adrenergic blocking agents caused an inhibition of epinephrine-stimulated glycerol release, with propranolol being most effective. Phentolamine and phenoxybenzamine had no significant effect on the epinephrine stimulation of glycerol release by fat cells.

Hormone action at the membrane level. VIII. Adrenergic receptors in rat heart and adipocytes and their modulation by thyroxine.

The regulation of adrenergic receptors in rat heart was measured in rats made hyperthyroid by injection with thyroxine and made hypothyroid by addition of propylthiouracil to the drinking water. Hyperthyroid rats display cardiac hypertrophy and a decrease in epididymal fat pad weight. The maximal beta-receptor level of ventricular membranes, as determined by (-)-[3H]dihydroalprenolol binding, was increased 60% by thyroxine treatment and decreased about 30% by propylthiouracil treatment. The affinity of the beta receptor was unchanged after thyroxine or propylthiouracil treatment. The maximal activity of the isoproterenol-stimulated adenylate cyclase (EC 4.6.1.1) varied with thyroid state in a manner parallel to the increase in beta-adrenergic binding sites. Thyroxine treatment also increases by 2-fold the beta receptors in isolated rat fat cells. Propylthiouracil treatment lowered the level of alpha receptors in heart by 30% as measured by [3H]dihydroergocryptine binding, but increased the affinity about 2.5-fold. The highest level of alpha receptors was seen in control hearts. These studies indicate that thyroxine may control the turnover of beta-adrenergic receptors in heart and fat cells and regulate physiological responses in these tissues via a hormone-hormone interplay system. Thyroxine treatment reduced the activity of the membrane-bound Mg2+-ATPase (EC 3.6.1.3) and 5'-mononucleotidase (EC 3.1.3.5) but appears to increase the activity of the (Na+ + K+)ATPase (EC 3.6.1.4).

Hormone action at the membrane level. V. Binding of (+/-)-[3H]isoproterenol to intact chicken erythrocytes and erythrocyte ghosts.

The binding of (+/-)-[7-3H]isoproterenol to intact chicken erythrocytes has been investigated by a rapid centrifugation technique. The binding is displaceable by a one thousand-fold excess of cold isoproterenol and consists of two fractions, only one of which is inhibitable by the beta antagonist (--)-propranolol. The total displaceable binding to intact cells amounts to 80 or 127 molecules per cell at a (+/-)-isoproterenol concentration of 0.4 muM depending on the method employed to analyze the binding. Under similar conditions, the total displaceable binding to isolated membrane ghosts is 12600 molecules per cell. The propranolol-inhibitable binding to intact cell reaches saturation within 5 min at 4 degrees C and gives by scatchard analysis a maximum binding of 108 molecules per cell and with a KD of 0.4 muM. 50% inhibition of binding is obtained with 0.3 muM unlabeled (--)-isoproterenol as compared to 20 muM unlabeled (+)-isoproterenol. The binding of isoproterenol thus shows a marked stereospecific preference for the (--)-isomer.

Hormone action at the membrane level. VII. Stimulation of dihydroalprenolol binding to beta-adrenergic receptors in isolated rat heart ventricle slices by triiodothyronine and thyroxine.

Thyroxine (T4) and triiodothyronine (T3) increase the number of beta-adrenergic receptors in heart ventricle slices. A short term effect reaches a maximum by 1.5-2 h and requires added amino acids for consistent results. The apparent Km for the L-T3 effect is 15 pM. This effect, measured by an increase in stereospecific binding of (-)-[3H]dihydroalprenolol is not inhibited by cycloheximide or puromycin and is produced more effectively by L-T3 than D-T3. However, cycloheximide nearly completely inhibits protein synthesis in the 2-3 h incubation time. T3 also gives a small inhibition of protein synthesis during this time interval. The early effect of T3 stimulation of dihydroalprenolol binding is considered to be a post-translational event shereby T3 enhances the transport of existing beta-adrenergic receptors from the cytosol into the membrane. A long term (15 h) stimulation of dihydroalprenolol binding to ventricle membranes is also produced by L-T3. This effect is stereospecific, is inhibited by cycloheximide, and is believed to be a transcriptional-translational event leading to the synthesis of new beta-adrenergic receptors by T3.

Differential inactivation of the "L" and "Ly+" amino acid transport systems by a sulfhydryl reagent and a photo-affinity probe.

Using a substrate-stimulated amino acid efflux system, it has been shown that the "Ly+" and "L" amino acid transport systems of mouse embryo cells in culture are differentially inhibited by parachloromercuribenzene sulfonate (PCMB-S) and the photoaffinity probe 4-fluoro-3-nitrophenylazide (FNPA). Three types of evidence support the conclusion that these transport systems are mediated by separate carrier proteins. (1) The specificity of substrate-stimulated efflux is high for each system; (2) PCMB-S inhibits L-phenylalanine and L-leucine stimulated L-[3H]phenylalanine efflux with no effect on L-lysine stimulated L-[3H]lysine efflux, and (3) the photo-affinity probe FNPA inhibits L-lysine efflux with little effect on the L-phenylalanine-stimulated efflux.

Light-enhanced cross-linking of rhodopsin in rod outer segment membranes as detected by chemical probes.

Bovine rod outer segment membranes were treated with cross-linking reagents before and after light exposure. Bleached membranes showed enhanced cross-linking with difluorodinitrobenzene or methyl acetimidate compared to dark-adapted membranes. The light-induced enhancement of cross-linking may be due to increased association of rhodopsin monomers in the light and/or due to increased reactivity of amino and sulfhydryl groups of bleached rhodopsin. In some instances, the band ascribed to the rhodopsin monomer in gel electrophoresis appears as a partially resolved doublet. Treatment of bleached rod outer segment membranes with methyl acetimidate improved the resolution of the doublet into two closely migrating bands.

alpha 2-Adrenergic receptors in human polymorphonuclear leukocyte membranes.

Human polymorphonuclear cell membranes contain alpha 2-adrenergic receptors which are measured by binding of the alpha 2-adrenergic antagonist [3H]yohimbine. The alpha 1-adrenergic antagonist [3H]prazosin showed no specific binding. High and low affinity sites were detected which had Kd values of 2.38 +/- 0.4 and 139 +/- 12 nM, respectively, and which bound maximally 4.82 +/- 0.9 and 81 +/- 9 fmoles of [3H]yohimbine/mg membrane protein. The high and low affinity sites were also detected by competition studies with phentolamine, epinephrine and norepinephrine and by dissociation kinetics of bound [3H]yohimbine. [3H]Yohimbine binding was stereospecifically inhibited by (-)- and (+)-epinephrine and norepinephrine. [3H]Yohimbine binding to intact cells showed about 500 high affinity sites per cell (Kd 0.5 nM) and approximately 4000 lower affinity sites per cell (Kd 3-4 nM). Yohimbine enhanced the (-)-norepinephrine stimulation of cAMP production in intact cells.

Beta-adrenergic receptors of human leukocytes. Studies with intact mononuclear and polymorphonuclear cells and membranes comparing two radioligands in the presence and absence of chloroquine.

Owing to the large differences in reported values for beta-adrenergic receptor numbers and binding affinity in normal leukocytes, we undertook a systematic re-examination of the binding of two widely used beta antagonists, (-)-[3H]dihydroalprenolol (DHA) and (+/-)-[125I]iodohydroxybenzylpindolol (HYP), to intact normal mononuclear (MN) leukocytes and polymorphonuclear (PMN) leukocytes and membrane preparations. Assays were conducted in the presence and absence of chloroquine, which has been proposed recently to eliminate ligand uptake into a non-receptor cell compartment such as lysosomes. The binding curves relating radioligand concentration to specific sitesper intact cell were biphasic. At high (10-24 nM) (-)-DHA ligand concentration in the absence of chloroquine, a large number (20,000-60,000 sites/cell) of low affinity (Kd 12-15 nM) stereospecific binding sites were detected in both cell types. This class of binding sites was eliminated by 10 microM chloroquine not only in PMN cells but also in the lysome-poor MN cells (greater than or equal to 90% lymphocytes), leaving 2000-3000 specific high affinity (-)-DHA sites/cell. In the absence of chloroquine, comparably low numbers of specific high affinity binding sites/cell were also obtained by the use of appropriately low concentrations of (-)-DHA or (+/-)-HYP (800 pM or less). However, even at these low radioligand concentrations chosen to measure high affinity specific binding, the addition of 10 microM chloroquine produced a moderate reduction in the number of sites/cell, without a detectable change in the apparent Kd. Mean (+/- S.E.M.) site numbers obtained in the presence of chloroquine were: 1331 +/- 100 sites/MN cell and 1135 +/- 129 sites/PMN cell (Kd 143-153 pM) using (-)-DHA; and 1487 +/- 210 sites/MN cell and 1065 +/- 69 sites/PMN cell [avg. Kd(+/-) 224-274 pM] using (+/-)-HYP. Chloroquine had no effect on agonist-stimulated cAMP production but produced an apparent increase in the effectiveness of (-)-propranolol as an inhibitor of DHA binding. Competition studies on the binding of DHA and HYP with zinterol and practolol confirmed that the receptor was of the beta 2-subtype for both MN and PMN cells. The detection of a moderately larger number of high affinity binding sites at saturation (Scatchard analysis) by (+/-)-HYP than by (-)-DHA was a consistent finding with either intact cells or membranes, with or without chloroquine. The possible overestimation of receptor numbers by a racemic ligand such as (+/-)-HYP is discussed and leads us to favor the use of a pure stereoisomer such as (-)-DHA. A system employing 800 pM (-)-[3H]DHA, 1 microM (-)-propranolol and 10 microM chloroquine with intact MN and PMN cells yielded reproducible and plausible results. Our values for beta-adrenergic receptor numbers of intact MN and PMN cells and membranes are compared to others in the literature.

Effects of radiopaque contrast media on calcium uptake and phosphatidylinositol metabolism in rat brain synaptosomes.

Radiographic contrast media (RCM) used in the subarachnoid space are associated with occasional adverse reactions. This study examines the possibility that RCM reactions are caused by interactions with the plasma membrane phosphatidylinositol (PI) second messenger system. Isolated nerve endings, known as synaptosomes, were produced from rat brain homogenates. The synaptosomes were then incubated with RCM to determine if 32Pi labeling of the PIs or the uptake of 45Ca were influenced in a manner consistent with known mechanisms. The RCM metrizamide, iopamidol, iodixanol, and iotrol (but not iohexol) increased the 32Pi labeling. Hyperosmolality produced large increases in phosphatidylinositol-4-phosphate (PIP) and phosphatidylinositol-4, 5,-bisphosphate (PIP2) labeling. In the non-depolarized state iodixanol, but not metrizamide or iohexol, caused a time-dependent increase in 45Ca uptake. Iodixanol, iohexol, and metrizamide also augmented the veratrine-stimulated uptake of calcium, but none of the RCM affected the uptake of Ca resulting from potassium depolarization. The increased 32Pi labeling of the PIs caused by RCM is not directly related to Ca uptake, because the direction of change is wrong. RCM perturbations of the plasma membrane may cause an inhibition of other membrane components and systems. Hyperosmolality also may cause inhibition of membrane components. It is not known if these effects are important in clinically observed RCM toxicity.

In vitro models for testing the metabolic effects of myelographic contrast media.

Water-soluble nonionic x-ray contrast media have greatly improved the quality and safety of myelography. Toxic side effects are still observed however. The side effects are generally worse with the first nonionic agent, metrizamide, which has a glucoselike side group. Two in vitro models were developed to examine the effects of contrast media on glucose metabolism. Using rat hippocampus slices, the authors observed significant depression of carbon dioxide production by metrizamide and by deoxyglucose, a known metabolic inhibitor. Iohexol and iopamidol did not cause significant depressions. In rat brain synaptosomes the authors did not observe a depression of the uptake of deoxyglucose 14C by any media tested. These studies indicate that metrizamide can create metabolic depression but that it does not compete with glucose for the membrane glucose carrier.

Effects of contrast media on neural tissue glucose uptake in vitro.

The authors previously showed that metrizamide causes an inhibition in CO2 production in rat neural tissue. The purposes of this work were to test if this inhibition was the result of a competitive inhibition of metrizamide with the D-glucose transport system and to test the effect of other contrast media. Deoxyglucose was used as a marker for glucose. The first cellular system using rat hippocampus slices was designed to examine the effect of 15 mM and 80 mM metrizamide on deoxyglucose uptake. The second cell-free system, using isolated rat brain synaptosomes, was designed to evaluate more accurately the mechanism and kinetics of metrizamide's inhibitory effect on the uptake of deoxyglucose and to compare metrizamide to other nonionic contrast media (iohexol, iopamidol, iotrol, and iodixanol). These experiments demonstrate that there is inhibition of D-glucose uptake only in hippocampus slices and that the inhibition is dependent on the concentration of metrizamide. This does not, however, appear to be a competitive inhibitory effect on the carrier such as that between D-glucose and 2-deoxy-D-glucose. In synaptosomes, none of the contrast media had a significant effect on the uptake of 2-deoxyglucose.

Differential reaction of cell membrane phospholipids and proteins with chemical probes.

The major aims of this study were to determine the degree of phospholipid asymmetry and the neighbor analysis of phospholipids in different types of cell membranes. For this study a penetrating probe (FDNB), a non-penetrating probe (TNBS) and a cross-linking probe (DFDNB) were used. The reaction of hemoglobin, membrane protein and membrane PE and PS of erythrocytes with DFNB and TNBS was studied over a concentration range of 0.5 to 10 mM probe. TNBS reacts to an extremely small extend with hemoglobin over the concentration range 0.4 to 4 mM whereas FDNB reacts with hemoglobin to a very large extent (50 fold more than TNBS). The reaction of membrane protein of intact erythrocytes reaches a sharp plateau at 1 mM TNBS whereas the reaction of membrane protein goes to a much larger extent with FDNB with no plateau seen up to 4 mM FDNB. This data shows that TNBS does not significantly penetrate into the cell under our conditions whereas FDNB does penetrate into the cell. The results show that there are four fold more reactive sites on proteins localized on the inner surface of the erythrocyte membrane as compared to the outer surface. TNBS at 0.5 to 2 mM concentration does not label membrane PS and labels membrane PE to a small extent. The reaction of PE with TNBS shows an initial plateau at 2 mM probe and a second slightly higher plateau between 4 to 10 mM probe. TNBS from 0.5-2.0 mM does not react with PS, but between 3 to 10 mM concentration, a very small amount of PS reacts with TNBS. Hence above 2 mM TNBS or FDNB a perturbation occurs in the membrane such that more PE and PS are exposed and react with these probes. These results demonstrate that essentially no PS is localized on the outer surface of the membrane and only 5% of the total membrane PE is localized on the outer surface of the erythrocyte membrane. TNBS and FDNB were reacted with yeast, E. coli, and Acholeplasma cells. With yeast cells, FDNB reacts to a much larger extent with PE than does TNBS, indicating that FDNB penetrates into the cell and labels more PE molecules. With E. coli, but not with erythrocytes or yeast cells, phospholipase A activity was very pronounced at pH 8.5 giving rise to a large amount of DNP-GPE from DNP-PE. A phosphodiesterase was also present which hydrolyized DNP-GPE to DNP-ethanolamine. The multilayered structure of the E. coli cell envelop did not permit a definitive interpretation of the results. It is clear, however, that TNBS and FDNB react to a different extent with PE in this cell. The Acholeplasma membrane had no detectable PE or PS but contains amino acid esters of phosphatidylglycerol. The reaction of these components with TNBS and FDNB indicate that these aminoacyl-PG are localized on both surfaces of the membrane, with 31% being on the outer surface and 69% on the inner surface...

Cross-linking of membrane phospholipid and protein using putative monofunctional imidoesters.

The reaction of methyl acetimidate or isethionyl acetimidate with mitoplasts at pH 8.5 yields two derivatives of phosphatidylethanolamine. These derivatives are shown to be the mono-amidine derivative and the bis-derivative of phosphatidylethanolamine. The bis-derivative represents one phosphatidylethanolamine cross-linked to another phosphatidylethanolamine. Similar derivatives are formed by the reaction of dipalmitoyl phosphatidylethanolamine with these imidoesters in organic solution with the exception that much more monoderivative is produced. Methyl picolinimidate reacts with phosphatidylethanolamine of mitoplasts to form primarily the mono-derivative. The bis-derivative was not detected. The reaction of bovine rod outer segment discs with methyl acetimidate causes cross-linking of 30% of the membrane rhodospin as dimers. Putative monofunctional imidoesters cause considerable cross-linking of both phospholipids and proteins in cell membranes. Cross-linking can be minimized at pH 9.0.

Interaction of membrane aminophospholipids of E. coli with fluorodinitrobenzene and trinitrobenzenesulfonate.

E. coli cells were reacted with TNBS in bicarbonate-NaCl buffer, pH 8.5 (buffer A) and in phosphate-NaCl buffer, pH 7.0 (buffer B). In buffer A, DNP-GPE is the major product when FDNB is used. DNP-PE and DNP-LPE are formed in lesser amounts. Phospholipase A activity is high in buffer A. When TNBS is used, the labeling of the lipid components is less than with FDNB and more TNP-PE is formed relative to TNP-GPE. This data suggests that the phospholipases which are located primarily on the outer L-membrane of the cell wall act to a lesser extent on TNP-PE than on DNP-PE. E. coli cells were prelabeled with TNBS and FDNB in buffer A, washed and incubated in buffer A. The endogenous labeled DNP-PE gradually decreased with time with a concomitant increase in DNP-LPE and DNP-GPE due to phospholipase A activity. In contrast, the endogenous labeled TNP-PE also decreased with time as did the endogenous labeled TNP-LPE but a new orange lipid was produced. This lipid is believed to be a derivative of TNP-PE in which one of the nitro groups has been reduced to an amino group by nitroreductase. E. coli cells were prelabeled with TNBS and FDNB in buffer A, washed and incubated in buffer B. Under these conditions with both TNBS and FDNB there is an increase in TNP-PE and DNP-PE with a concomitant decrease in TNP-LPE, TNP-GPE, DNP-LPE and DNP-GPE. These results show that at neutral pH acylation occurs to regenerate TNP-PE and DNP-PE. E. coli cells were incubated with exogenous DNP-GPE or TNP-GPE in buffer A. The DNP-GPE and TNP-GPE were rapidly hydrolyzed by a phosphodiesterase to DNP-ethanolamine and TNP-ethanolamine. An orange derivative was formed which was provisionally identified as a derivative of DNP-ethanolamine or TNP-ethanolamine in which a nitro group has been reduced to an amino group by nitroreductase. The phospholipases and acylating enzymes present in the cell wall of E. coli are active on the dinitrophenyl and trinitrophenyl derivatives of PE and LPE and may act in concert to model and repair the plasma membrane.

The effect of imidoesters, fluorodinitrobenzene and trinitrobenzenesulfonate on ion transport in human erythrocytes.

Several amino-reactive chemical probes which differ in hydrophobicity and charge and in their ability to penetrate the red cell membrane were tested for their ability to modify K+ leak and inorganic phosphate (Pi) leak in intact human red cells. Methyl picolinimidate (MP), ethyl acetimidate (EA), methyl acetimidate (MA) are hydrophilic penetrating probes whereas isethionylacetimidate (IA) is a hydrophilic non-penetrating probe. The order of their effectiveness in inhibiting Pi leak was found to be MP > EA > MA > IA. This order is in decreasing hydrophobicity and suggests that some penetration into the bilayer or into hydrophoblic domains of the anion transport protein is required to modify an amino group required for Pi permeability through the membrane. These imidoesters have little or no effect on K+ leak in the red cell. Trinitrobenzenesulfonate (TNBS) a relatively non-penetrating hydrophobic anionic probe and fluorodinitrobenzene (FDNB) a penetrating hydrophobic neutral probe have markedly different effects on K+ and Pi leak. TNBS has little effect on K+ leak but markedly inhibits Pi leak. The effect of TNBS on Pi leak is not blocked by prior treatment with IA suggesting that these probes sense different populations of amino groups in the membrane. FDNB nearly completely blocks Pi leak and markedly increases K+ leak. The results with TNBS and FDNB indicate an asymmetric arrangement of amino groups on the red cell membrane. Certain amino groups on the outer surface of the membrane regulate Pi permeability whereas certain amino groups on the inner surface of the membrane regulate K+ permeability. The data also suggest that these amino groups are in a hydrophobic domain.

Composition and metabolism of phospholipids of human leukocytes.

Human mononuclear (MN) and polymorphonuclear (PMN) leukocytes were analyzed for their phospholipid, triglyceride, cholesterol and fatty acid content. The phospholipid/cholesterol ratio was 1.24 for both cells. MN cells contain more phosphatidylcholine (PC), but less phosphatidylserine (PS), Phosphatidylethanolamine (PE) and sphingomyelin (SPH) than PMN cells when expressed as percent of total phospholipid. When expressed on the basis of lipid content per cell, MN cells contain less PS, PE and SPH but more triglyceride than PMN cells. PMN cells incorporate palmitic, stearic, linoleic and linolenic acids into their phospholipids, triglycerides or cholesterol esters. The incorporation into triglycerides was highest for all fatty acids. Of the phospholipids, the incorporation was highest into PC. Labeled fatty acids also were found in proteins which had been delipidized by exhaustive extraction with organic solvents. These represent tightly or covalently bound fatty acids. The incorporation [3H] palmitic acid into this protein fraction is stimulated by insulin.