Utilization of membranous lipid substrates by membranous enzymes. Hydrolysis of sphingomyelin in erythrocyte ''ghosts'' and liposomes by the membranous sphingomyelinase of chicken erythrocyte ''ghosts''.

Incubation at 37 degrees C of haemolysed chicken erythrocytes ('chicken erythrocyte ghosts') resulted in hydrolysis of the membrane sphingomyelin, suggesting an activation of a latent sphingomyelinase during the haemolysis procedure. When this incubation was continued for several hours, the entire sphingomyelin of the erythrocyte 'ghosts' was hydrolysed and membranes were obtained that were devoid of sphingomyelin, but had an active sphingomyelinase. Mixing the latter membranes with human erythrocyte 'ghosts' or positively charged liposomes led to hydrolysis of the sphingomyelin in these two membranes. This suggested that, after haemolysis, the activated sphingomyelinase in the membrane of the chicken erythrocyte 'ghosts' could hydrolyse sphingomyelin in its own membrane ('intramembrane utilization') or adjacent membranes ('intermembrane utilization').     

Utilization of membranous lipid substrates by membrane-bound enzymes: Intramembrane and intermembrane hydrolysis of diacylglycerol by lipase of rat liver microsomes

The membranous lipase of rat liver microsomes was used to hydrolyze diacylglycerol (DG), generated within the microsomal membrane by treatment with phospholipase C, in two separate interactions. For an intramembrane enzyme-substrate interaction, the enzyme and DG were present in the same microsomes. For intermembrane interactions, native microsomes of rat liver were used as carriers of the enzyme, while heated and phospholipase C-treated microsomes of rat liver or brain were employed as carriers of the substrate. The v vs S curves of the intermembrane interaction were hyperbolic while those of the intramembrane utilization were parabolic.     

Interaction of membranous enzymes with membranous lipid substrates. Hydrolysis of diacylglycerol by lipase in rat brain microsomes.

The phospholipids in rat brain microsomes were labeled with tritium by intracerebral administration of radioactive fatty acids and converted to diacylglycerol with phospholipase C. The latter lipid was hydrolyzed in situ at pH 4.8, to monoacylglycerol and fatty acid by the endogenous microsomal lipase. This paper provides an experimental approach to determine whether the lipid was degraded by enzyme molecules residing in its own membrane (intramembrane interaction) or an adjacent membrane (intermembrane interaction). Direct interaction between separate membranes containing enzyme or substrate showed the existence of the inter-membrane route while dilution experiments provided evidence for the presence of the intramembrane interaction as well. A probable difference in the mechanisms of these two interactions is suggested by different shapes of the curves that describe the reaction rate as a function of the endogenous substrate. The curve resulting from the intermembrane interaction was hyperbolic while that representing the intramembrane route was of a parabola-like shape. Competition experiments suggested that when given a choice between the two, the enzyme utilized preferentially the substrate molecules in its own membrane.     

Phosphorylation and dephosphorylation reactions by erythrocyte plasma membrane enzymes

Human erythrocyte membranes contain a phosphoprotein phosphatase able to dephosphorylate membrane protein previously phosphorylated by the endogenous protein kinase.The level of dephosphorylation obtained after prolonged incubation is about one half of the phosphorylated residues.The characteristics of this enzyme are similar to those described for the cytoplasmic phosphoprotein phosphatase.In a membrane preparation the phosphorylation and dephosphorylation reactions can be repeated, at least twice, achieving similar levels of phosphate esterified or hydrolyzed.The coordination of these two enzyme systems might play a role in some of the functions attributed to the protein kinase system.     

Modification of the erythrocyte membrane by a non-specific lipid transfer protein

The non-specific phospholipid transfer protein purified from bovine liver has been used to modify the phospholipid content and phospholipid composition of the membrane of intact human erythrocytes. Apart from an exchange of phosphatidylcholine between the red cell and PC-containing vesicles, the protein appeared to facilitate net transfer of phosphatidylcholine from the donor vesicles to the erythrocyte and sphingomyelin transfer in the opposite direction. Phosphatidylcholine transfer was accompanied by an equivalent transfer (on a molar basis) of cholesterol. An increase in phosphatidylcholine content in the erythrocyte membrane from 90 to 282 nmol per 100 microliters packed cells was observed. Phospholipase C treatment of modified cells showed that all of the phosphatidylcholine which was transferred to the erythrocyte was incorporated in the lipid bilayer. The nonspecific lipid transfer protein used here appeared to be a suitable tool to modify lipid content and composition of the erythrocyte membrane, and possible applications of this approach are discussed.     

Modulation of erythrocyte membrane proteins by membrane cholesterol and lipid fluidity.

Human erythrocyte membranes were enriched or depleted of cholesterol and effects on membrane proteins assessed with a membrane-impermeant sulfhydryl reagent, [35S]glutathione-maleimide. Reaction of the probe with intact cells quantifies exofacial sulfhydryl groups and reaction with leaky ghost membranes permits quantification of endofacial sulfhydryl groups. The mean endofacial sulfhydryl titer of cholesterol-enriched membranes exceeded that of cholesterol-depleted membrane by approximately 45 nmol/mg of protein or 64%. The corresponding exofacial titer of cholesterol-enriched cells was less than that of cholesterol-depleted cells by approximately 0.4 nmol/mg of protein, or 14%. Labeled membranes were examined by autoradiography of sodium dodecyl sulfate-polyacrylamide gel electropherograms to determine the labeling patterns of individual protein bands. Cholesterol enrichment enhanced the surface labeling of Coomassie brilliant blue stained bands 1,2,3, and 5, decreased the labeling of band 6, and did not change significantly that of band 4. The results demonstrate that changes in membrane cholesterol which influence lipid fluidity can alter the surface labeling of both intrinsic and extrinsic membrane proteins.     

Modification of the erythrocyte membrane by a non-specific lipid transfer protein

The non-specific phospholipid transfer protein purified from bovine liver has been used to modify the phospholipid content and phospholipid composition of the membrane of intact human erythrocytes. Apart from an exchange of phosphatidylcholine between the red cell and PC-containing vesicles, the protein appeared to facilitate net transfer of phosphatidylcholine from the donor vesicles to the erythrocyte and sphingomyelin transfer in the opposite direction. Phosphatidylcholine transfer was accompanied by an equivalent transfer (on a molar basis) of cholesterol. An increase in phosphatidylcholine content in the erythrocyte membrane from 90 to 282 nmol per 100 μl packed cells was observed. Phospholipase C treatment of modified cells showed that all of the phosphatidylcholine which was transferred to the erythrocyte was incorporated in the lipid bilayer. The nonspecific lipid transfer protein used here appeared to be a suitable tool to modify lipid content and composition of the erythrocyte membrane, and possible applications of this approach are discussed.     

Hydrolysis of the hen egg vitelline membrane by cock sperm acrosin and other enzymes.

A technique utilizing Pregnant Mare's Serum Gonadotropin and Human Chorionic Gonadotropin treatment of hens (Gallus domesticus), followed by manual ovulation of the excised follicles, was developed to obtain a large number of mature ova. The intact ova were used to test whether acrosin, partially purified from the spermatozoa of the cock (Gallus domesticus), partially purified rabbit testicular acrosin and commercial preparations of several hydrolytic enzymes could dissolve the inner vitelline membrane. Enzymes were applied to pieces of filter paper placed on the ovum. Cock acrosin and endopeptidases such as trypsin, chymotrypsin, collagenase and elastase hydrolyzed the membrane whereas exopeptidases such as leucine aminopeptidase and carboxypeptidase A did not. Phospholipase A, sulfatase, hyaluronidase, beta-glucuronidase and rabbit testicular acrosin also failed to hydrolyze the membrane. Cock acrosin hydrolysis of the ovum surface was inhibited by soybean trypsin inhibitor. The surface of the ovum over the germinal disc region was hydrolyzed more quickly by cock acrosin than the surface over other regions of the ovum. Acrosin from cock sperm caused the release of trichloroacetic acid soluble material absorbing at 280 nm from sonicated preparations of inner vitelline membranes. Hydrolysis was greatest at pH 8.0 and was inhibited by soybean trypsin inhibitor.     

Hybridization by cosonication of pigeon erythrocyte membrane with exogenous lipid vesicles

Summary Concentrated mixtures of lipid vesicles and pigeon erythrocyte membrane were cosonicated in order to produce functional hybrid vesicles. From the properties of the resulting material, we conclude that hybrids were very probably formed. These properties were as follows: (i) The presence of membrane increased the sonic fragmentability of lipid vesicles. Sonic fragmentability was assessed by measuring sonication-induced release of previously trapped [¹⁴C]-choline and trapping of external [³H]-choline. (ii) Space enclosed by lipid was served by the membrane-like properties of³⁶Cl^– permeability and ATP-dependent⁴⁵Ca⁺⁺ uptake activity. (iii)³⁶Cl-permeability was more readily and fully induced into the more easily fragmented lipid vesicles. Further sonication caused loss of the induced³⁶Cl^–-permeability. This loss was less rapid with the less easily fragmented lipid vesicles; i.e., less easily fragmented lipids protected³⁶Cl^–-permeability better. (iv) Glycine uptake activity was partially protected from sonic damage by the presence of lipid vesicles. (v) On centrifugation in bovine serum albumin density gradients, cosonicated material showed lipid properties (enclosed choline and³²P_i space and [³H]-cholesterol) and membrane properties (³⁶Cl^–-permeability and ATP-dependent⁴⁵Ca²⁺ uptake) coinciding at a density intermediate between those reached by separately sonicated membrane and lipid vesicles. (vi) Electron micrographs showed the disappearance of pure membrane-like structures and the appearance of large amounts of new vesicles whose appearance is consistent with a hybrid structure.     

Radiation-induced lipid peroxidation and the fluidity of erythrocyte membrane lipids

The effect of radiation-induced peroxidation on the fluidity of the phospholipids of the erythrocyte membrane was studied using both erythrocyte ghosts and liposomes formed from the polar lipids of erythrocytes. In liposomes, the oxidation of the phospholipids increased with radiation dose, but there was no change in the fluidity of the lipids as measured by spin-label motion. Under the same conditions of irradiation, no oxidation of phospholipid was detected in erythrocyte ghosts, although changes occurred in the motion of spin labels intercalated with the membrane. These changes were attributed to radiation-induced alterations in the membrane proteins. It is concluded that alterations in motion of spin labels, observed with intact membranes after irradiation, are most likely the result of changes in the structure of membrane proteins rather than the lipids.     

Protein and lipid components of the pigeon erythrocyte membrane.

The plasma membrane of the nucleated pigeon erythrocyte was isolated by a method that is simple, reproducible and minimally disruptive, the final preparation consisting of whole cell 'ghosts', recovered at over 40% yield. Alternative methods, which yield membrane fragments, were also tested and some of their possible disadvantages demonstrated. Analysis of the protein components of the isolated membranes by gel elctrophoresis in the presence of sodium dodecyl sulphate revealed that their composition is very similar to that of the proteins of human erythrocyte membranes. However, two major proteins are unique to the nucleated cell membrane; these have apparent mol.wts. of 97000 and 57000. Also, the bands designated 4.2 (74500 mol.wt.) and 6 (35000 mol wt.) by Steck [(1974) J. Cell Biol. 62, 1-19] for the human cell membrane are absent from pigon cell membrane. Glycosylated membrane proteins could not be detected in gels stained with the periodate-Schiff-base procedure. Analysis of membrane phospholipids revealed the same components known to be present in mammalian erythrocytes, though in different proportions. These findings are discussed in the light of known physiological and biochemical differences between avian and mature mammalian erythrocytes.     

Active transport and enzymes of the erythrocyte membrane under protein deprivation

1. Starvation for 3 days causes membrane damage of the rat erythrocyte manifested by several alterations. The adenosine-triphosphatase activity is decreased but that of acetylcholinesterase is not affected. 2. The ouabain-sensitive adenosine-triphosphatase activity increases at the expense of the non-sensitive enzyme moiety. 3. The Rb(+) uptake is not altered but the galactose transport is accelerated by the stated experimental conditions. 4. The modifications induced by starvation do not recover on re-feeding.     

Glucose erythrocyte transporter in women with breast cancer: changes in lipid composition of erythrocyte membrane

Women with breast cancer show altered blood glucose compartmentation compared with healthy women, with lower concentrations in plasma and similar concentrations in blood cells. The goal of this paper was to study whether this pattern was the result of changes in the erythrocyte glucose transporter and, if so, to assess the possible changes in lipid environment of the erythrocyte membrane. In 12 women with different degrees of breast cancer and 12 age-matched healthy women, the lipid composition of erythrocyte membrane and erythrocyte glucose transport were studied. Women with breast cancer showed changes in both the kinetic variables and the lipid environment of the glucose transporter, in keeping with an increase in fluidity of the erythrocyte membrane. The results obtained would account, in part, for the changes in glucose compartmentation.     

Asymmetric lipid fluidity in human erythrocyte membrane: new spin-label evidence

We have synthesized spin-labeled analogues of phosphatidylcholine, phosphatidylserine, and phosphatidylethanolamine with a short beta chain (C5) bearing a doxyl group at the fourth position. When added to an erythrocyte suspension, the labels immediately incorporate in the membrane. The orientation of the spin-labels was assessed in the bilayer (i) by addition in the medium of a nonpermeant reducer (ascorbate at 5 degrees C) or (ii) by following spontaneous reduction at 37 degrees C due to the endogenous reducing agents present in the cytosol. Both techniques prove that the spin-labels are originally incorporated in the outer leaflet and redistribute differently after incubation. After a 5-h incubation at 5 degrees C, the phosphatidylcholine derivative remained in the outer layer, while the phosphatidylethanolamine and phosphatidylserine derivatives were found principally in the inner leaflet. During the incubation, a small fraction of the spin-labels is hydrolyzed, particularly the phosphatidylserine derivative, presumably by an endogenous phospholipase A2. Because the hydrolyzed spin-labeled fatty acids are rejected in the aqueous phase, the spectra of the intact membrane-bound phospholipids can be obtained by an adequate spectral subtraction. The ESR spectrum corresponding to a probe in the outer leaflet indicates a more restricted motion than that associated with probes in the inner leaflet. Additional experiments have been carried out to prove that the difference in viscosity, which is likely to be due to anisotropic cholesterol distribution, is not attributable to modification of the cell morphology.(ABSTRACT TRUNCATED AT 250 WORDS)     

Do membrane-bound enzymes access their substrates from the membrane or aqueous phase: interfacial versus non-interfacial enzymes

For membrane-bound enzymes that act on substrates that partition between the membrane and aqueous phases, it is possible to imagine two fundamentally different mechanisms. Interfacial enzymes must access their substrate from the membrane phase, in other words substrate in the membrane binds directly to the active site of the enzyme at the membrane without mixing with substrate molecules in the aqueous phase. On the other hand, non-interfacial enzymes, either bound to membranes or present in the aqueous phase, must access their substrates from the aqueous phase, i.e. substrate in the aqueous phase binds directly to the enzyme without mixing with substrates in the membrane phase. An interfacial mechanism for some enzymes including secreted and cytosolic phospholipase A(2) and phosphoinositide 3'-hydroxykinase was rigorously proven by demonstrating that these enzymes processively hydrolyze many phospholipids without desorbing from the surface of vesicles (scooting mode). The non-interfacial mechanism is more difficult to establish because it cannot be addressed by steady-state kinetics. Using a pre-steady-state method in which the enzymatic velocity is measured during the time it takes for substrate to exchange between vesicles, a non-interfacial mechanism was proven for vesicle-bound plasma platelet activating factor acetylhydrolase. This enzyme prefers more water-soluble phospholipids such as those with sn-2 acetyl or oxidatively truncated fatty acyl chains, and this is readily explained by the mandatory access of substrate from the aqueous phase.