Hemolysis of human erythrocytes under hydrostatic pressure is suppressed by cross-linking of membrane proteins

The effects of cross-linking of membrane proteins on hemolysis of human erythrocytes under high pressure (2.0 kbar) were examined. The membrane proteins were cross-linked by oxidation of their SH-groups with diamide (0.05-0.5 mM) under different pressures (1-1,000 bar) at which no hemolysis occurs. As the pressure during diamide treatment was raised, the degree of hemolysis under 2.0 kbar and the quantity of cytoskeletal proteins extracted in a low ionic strength medium were gradually decreased. However, both values were increased by reduction with dithiothreitol. From the determination of membrane SH-groups, it was found that cross-linking of membrane proteins by diamide was accelerated under pressure. Only in erythrocytes treated with diamide under pressure were parts of spectrin and ankyrin, in addition to band 3 and band 4.2 proteins, extracted by using Triton X-100. One- and two-dimensional SDS-PAGE of membrane proteins showed that cross-linking of the membrane with cytoskeletal meshwork through linking proteins, in addition to that of membrane proteins themselves, was formed only in the diamide treatment under pressure. These results indicate that pressure-induced hemolysis is greatly suppressed by the supramolecular-weight polymers formed among membrane proteins, and that the high pressure technique is useful for cross-linking membrane proteins with diamide.     

Characterization of immunoglobulin binding to isolated human erythrocyte membranes: evidence for selective, temperature-induced binding of naturally occurring autoantibodies to the cytoskeleton

Human plasma contains naturally occurring autoantibodies to the predominant components of the erythrocyte membrane: band 3 and spectrin bands 1 and 2 of the cytoskeleton. The titer of cytoskeletal plasma autoantibodies increases in various hemolytic conditions, suggesting that opsonization of the cytoskeleton may play an important role in the clearance of hemolyzed (not senescent) erythrocytes from the circulation. In this study, we use Alexa Fluor 488 goat anti-human IgG conjugate (Molecular Probes, Eugene, OR, USA), to characterize plasma immunoglobulin binding to erythrocyte membranes from osmotically hemolyzed cells ('ghosts'). The results show that exposure of ghosts to plasma results in 4-fold more immunoglobulin binding to the cytoskeleton than is bound to the proteins contained within the lipid bilayer. Preincubation of the ghosts at 37 degrees C causes 8-fold more immunoglobulin binding to the cytoskeleton compared to bilayer proteins. This temperature-induced change resulted from selective immunoglobulin binding to the cytoskeleton, with no change in immunoglobulin binding to bilayer proteins. However, the rate of increase in cytoskeletal antigenicity at 37 degrees C did correlate with the rate of a conformational change in band 3, a transmembrane protein which serves as a major membrane attachment site for the cytoskeleton. The results of this study suggest that the cytoskeleton is the primary target in the opsonization of hemolyzed erythrocyte membranes by naturally occurring plasma autoantibodies. The conformational changes which occur in ghosts at 37 degrees C are associated with selective exposure of new immunoglobulin binding sites on the cytoskeleton, and with a change in the structure of band 3. We propose a model suggesting that opsonization of the cytoskeleton occurs prior to the decomposition of hemolyzed erythrocytes at 37 degrees C.     

Pressure increases oxygen affinity of whole blood and erythrocyte suspensions

Effect of hydrostatic pressure (HP) on whole blood (WB) or erythrocyte suspension hemoglobin (Hb) O2 affinity has been studied using newly developed techniques. O2 partial pressure at which hemoglobin is half-saturated with O2 (P50) measurements were made at 5 HP (1, 26, 51, 76, and 126 ATA) on thin films of human WB or erythrocytes at 37 degrees C. CO2 partial pressure of WB was either 28 or 57 Torr (film pH 7.51 or 7.31). HP increased affinity of erythrocytes and WB. For erythrocytes in tris(hydroxymethyl)aminomethane buffer, the ratio (r) of P50 (1 ATA)/P50 (51 ATA) was 1.089 (P less than 0.01) at pH 7.0. WB P50 decreased with HP at a rate of -3.3 X 10(-2) Torr X atm-1; change in P50 at higher HP vs. 1 ATA was highly significant (P less than 0.01). No effect of HP was seen on the CO2 Bohr coefficient. Inert gas choice, N2 vs. helium (He), had no effect. Measurement of decrease of P50 with HP at 76 ATA in hemolyzed WB gave an r of 1.15, as great or greater than that found in WB, indicates that Donnan equilibrium alteration is not involved. No effect of HP was found in WB on the ratio of P50 of erythrocytes with normal (5 mmol/l erythrocytes) 2,3-diphosphoglycerate (DPG) to P50 of erythrocytes with less than 5% of normal DPG; i.e., no effect of pressure was seen on the independent influence of DPG on P50. WB measurements of Hb O2 uptake under simulated physiological conditions are characterized by a net decrease in partial molal volume on oxygenation of 30-35 ml/mol Hb4.     

Effect of Ouabain, Iodacetamide, and pH on Human Erythrocyte Hemolysis Induced by Calcium Ions in the Presence of Ionophore A23187

The effect of inhibitors of Na⁺, K⁺-ATPase (ouabain) and glycolysis (iodacetamide) as well as pH on calcium ion-induced erythrocyte hemolysis in the presence of ionophore A23187 is described. The release of hemoglobin from erythrocytes decreases under the influence of ouabain, iodacetamide, and low pH, which is commonly observed at low temperature and in the samples studied in spring and summer. It is proposed that the process of hemolysis involves active hemoglobin release through defects of the erythrocyte membrane under the influence of transmembrane electrical potential.     

Enhancement of (Ca2+ + Mg2+)-ATPase activity of human erythrocyte membranes by hemolysis in isosmotic imidazole buffer. I. General properties of variously prepared membranes and the mechanism of the isosmotic imidazole effect.

1. Membranes prepared from human erythrocytes hemolyzed in isosmotic (310 imosM) imidazole buffer, pH 7.4, show enhanced and stabilized (Ca2+ + Mg2+)-ATPase activity compared with membranes prepared from erythrocytes hemolyzed in hypotonic (20 imosM) phosphate or imidazole buffer, pH 7.4. 2. Exposure of intact erythrocytes or well-washed erythrocyte membranes to isosmotic imidazole does not cause enhanced (Ca2+ + Mg2+)-ATPase activity. 3. Exposure of erythrocyte membranes, in the presence of isosmotic imidazole, to the supernatant of erythrocyte hemolysis or to a partially purified endogenous (Ca2+ + Mg2+)-ATPase activator, promotes enhanced (Ca2+ + Mg2+)-ATPase activity. Under appropriate conditions, NaCl can be shown to substitute for imidazole. The results demonstrate that imidazole does not act directly on the erythrocyte membrane but rather by promoting interaction between an endogenous (Ca2+ + Mg2+)-ATPase activator and the erythrocyte membrane.     

GPI-linked proteins do not transfer spontaneously from erythrocytes to liposomes. New aspects of reorganization of the cell membrane

Exposure of cells to liposomes results in the release of integral membrane proteins. However, it is still controversial whether the release is due to spontaneous protein transfer from cells to liposomes or shed vesicles released from cells. We investigated this issue in an erythrocyte-liposome system by examining the location of acetylcholinesterase (AChE, an integral membrane protein marker), cholesterol (erythrocyte membrane lipid marker), hemoglobin (cytosolic protein marker), and a nonexchangeable lipid marker in liposomes in a sucrose density gradient at high resolution. The density distribution showed that AChE is not transferred to the liposomes but is located on small (about 50 nm) light (10-20 wt % sucrose) or large (about 200 nm) heavy shed vesicles (more than 30 wt % sucrose). AChE in the light shed-vesicle fraction markedly increased even after its level in the heavy fraction reached a plateau. AChE was also released from isolated heavy shed vesicles and accumulated in the small light shed-vesicle fraction in the presence of liposomes. After incubation of spherical erythrocytes (morphological index, 5.0) with liposomes, AChE hardly appeared in the heavy shed-vesicle fraction, and the majority (>99%) appeared in the light shed-vesicle fraction, indicating that AChE is released from both the erythrocytes and heavy shed vesicles to the light shed-vesicle fraction, which becomes rich in AChE. Our results demonstrated for the first time that GPI-linked proteins do not spontaneously transfer from erythrocytes to liposomes. Our study also suggests that in vivo GPI-linked membrane proteins do not spontaneously transfer between cell membranes but that some catalyst is needed.     

An acid protease in human erythrocytes and its localization in the inner membrane.

The isolation of erythrocytes of high purity from human blood was achieved by a combination of the two well established methods cells in erythrocyte preparations of different purities was studied. The acid protease activity was recovered to a level comparable with the recovery of erythrocytes, while the neutral protease activity as detected by the release of acid-soluble peptides from hemoglobin or casein disappeared in proportion to the removal of white blood cells. An acid protease was solubilized from the membranes of the purified erythrocytes by the extraction with 1-butanol. The enzyme was active in a pH range from 2 to 4, and sensitive to pepstatin. It was named pH-3 protease after its pH optimum. Sealed ghosts with right-side-out membranes and inside-out vesicles with reverted membranes were prepared from the purified erythrocytes and compared with respect to pH-3 protease activity for its latency as well as its inactivation by tryptic digestion. The results obtained indicate that pH-3 protase is localized on the inner surface of erythrocyte membranes. The self-digestion experiments at pH 4 using the sealed ghosts showed higher availability to pH-3 protease of spectrin and IVa protein than the other membrane proteins, also suggesting the localization of an acid protease in the inner membranes of erythrocytes.     

Thermohemolysis of erythrocytes in the temperature range including physiologic (autohemolysis)]

The activation energy of thermohemolysis of erythrocytes changes from 36 +/- 5 kcal/mol (35-45 degrees C) to 97 +/- 5 kcal/mol (45-55 degrees C) at the temperature about 45 degrees C in isotonic buffer. The break on Arhenius' plot is preserved also when erythrocytes are placed into plasma. The character of Arhenius' plot is the same when erythrocyte hemoglobin is totally oxidated into methemoglobin by chemical way, though thermal stability of such erythrocytes is decreased. The scheme is presented in which thermohemolysis of erythrocytes occurs by two independent ways: thermodenaturation of hemoglobin (limiting stage of the process when t greater than 45 degrees C) and modification of membrane proteins by hemin, the last being a product of hemoglobin oxidation (limiting stage of the process when t less than 45 degrees C).     

Studies on the role of goat heart galectin-1 as an erythrocyte membrane perturbing agent

Galectins are β-galactoside binding lectins with a potential hemolytic role on erythrocyte membrane integrity and permeability. In the present study, goat heart galectin-1 (GHG-1) was purified and investigated for its hemolytic actions on erythrocyte membrane. When exposed to various saccharides, lactose and sucrose provided maximum protection against hemolysis, while glucose and galactose provided lesser protection against hemolysis. GHG-1 agglutinated erythrocytes were found to be significantly hemolyzed in comparison with unagglutinated erythrocytes. A concentration dependent rise in the hemolysis of trypsinized rabbit erythrocytes was observed in the presence of GHG-1. Similarly, a temperature dependent gradual increase in percent hemolysis was observed in GHG-1 agglutinated erythrocytes as compared to negligible hemolysis in unagglutinated cells. The hemolysis of GHG-1 treated erythrocytes showed a sharp rise with the increasing pH up to 7.5 which became constant till pH 9.5. The extent of erythrocyte hemolysis increased with the increase in the incubation period, with maximum hemolysis after 5 h of incubation. The results of this study establish the ability of galectins as a potential hemolytic agent of erythrocyte membrane, which in turn opens an interesting avenue in the field of proteomics and glycobiology.     

A quantitative study of the complexation of cadmium in hemolyzed human erythrocytes by 1H NMR spectroscopy

The stability of complexes formed by Cd2+ in hemolyzed human erythrocytes was studied by spin-echo 1H NMR spectroscopy. Changes in resonances for the carbon-bonded protons of glutathione (GSH) upon addition of the ethylenediaminetetraacetic acid complex of Cd2+ (Cd(EDTA)2-) and the appearance of resonances for Mg(EDTA)2- indicate that the Cd(EDTA)2- complex dissociates in hemolyzed erythrocytes with the formation of Cd(GSH)x and Mg(EDTA)2- complexes. A semiquantitative estimate of the overall stability constant for the complexation of Cd2+ in hemolyzed erythrocytes was obtained from spin-echo 1H NMR data. The stability constant is consistent with the majority of the Cd2+ in erythrocytes present as Cd(SG)2(2-). A conditional equilibrium constant was also determined for the complexation of Mg2+ by ligands in hemolyzed human erythrocytes.     

Hemin-promoted peroxidation of red cell cytoskeletal proteins

Hemin-induced crosslinking of the erythrocyte membrane proteins was analyzed at three levels: (i) whole membranes, (ii) integrated or dissociated cytoskeletons, and (iii) isolated forms of the three main cytoskeletal proteins, spectrin, actin, and protein 4.1. Addition of H2O2 and hemoglobin to resealed membranes from without did not affect any of the membrane proteins. Hemin that can transport across the membrane induced, in the presence of H2O2, crosslinking of protein 4.1 and spectrin. Both free hemin and hemoglobin added with H2O2 induced crosslinking of integer cytoskeletons and mixtures of isolated cytoskeletal proteins, but hemin was always more active. Of the three major cytoskeletal proteins, spectrin and protein 4.1 were most active while the participation of actin was only minor. The yield of crosslinked products was increased in all reaction mixtures with pH, with an apparent pK above 9.0. Replacement of H2O2 by phenylhydrazine and tert-butyl hydroperoxide resulted in crosslinking of the same proteins, but with lower activity than H2O2. Bityrosines, which were identified by their specific fluorescence emission characteristics, were formed in reaction mixtures containing hemin and hydrogen peroxide and either spectrin or protein 4.1, but not actin. On the basis of fact that bityrosines were revealed only in reaction mixtures that produced protein adducts, formation of intermolecular bityrosines was analyzed to be involved in crosslinking of the cytoskeletal proteins. Since the levels of membrane-intercalated hemin are correlated with aggregation of membrane proteins, it is suggested that the peroxidative properties of hemin are responsible for its toxicity.     

Differential turnover of methyl groups on methyl-accepting membrane proteins of irreversibly sickled erythrocytes

Methyl group turnover rates for specific methyl-accepting membrane proteins in intact irreversibly sickled cells (ISCs) have been determined. The turnover of methyl groups on all methyl acceptor membrane proteins carboxylmethylated in ISCs is not concerted but proceeds in an ordered sequence which is markedly different from that exhibited by unfractionated normal erythrocytes (AA). In ISCs methyl group turnover based on initial demethylation rate constants is most rapid for membrane polypeptides migrating in sodium dodecyl sulfate at 30,000-39,000 Da, 40,000-55,000 Da, polypeptides comigrating with cytoskeletal component band 4.1, and band 4.5. In contrast, initial methyl group turnover rates obtained after less than 20% of the total methyl groups are turned over in (AA) cells show most rapid demethylation rates for membrane polypeptides migrating at 40,000-55,000 Da, polypeptides comigrating with band 4.5, cytoskeletal components bands 2.1 and 4.1. Results also show significant differences between ISCs and most dense fractions from normal (AA) and nonsickle hemolytic anemias in the demethylation of cytoskeletal proteins, bands 2.1 and 4.1. These findings indicate qualitative differences in accessibility of methyl acceptor substrates to the methylating-demethylating enzyme activity in the cytosol of irreversibly sickled cells compared to discocytic control erythrocytes.     

Effects of pH on membrane fluidity of human erythrocytes

The effects of pH on the membrane fluidity of intact human erythrocytes, ghosts, and their lipid vesicles were studied by spin label techniques in the range of pH 3.0 to 9.1. Two fatty acid spin labels, 5-nitroxide stearic acid (5NS) and 12-nitroxide stearic acid (12NS), and a maleimide spin label were used for the labeling of the membrane lipids and proteins, respectively. The outer hyperfine splitting (T parallel) was measured as a parameter of membrane fluidity. In the case of 5NS, the T parallel values for intact erythrocytes and ghosts remained almost constant over the entire pH range at 22 degrees C but those for their lipid vesicles changed slightly, indicating the vertical displacement of the labels in lipid bilayers. On the other hand, the ESR spectra of 12NS incorporated into intact erythrocytes and ghosts, as compared with their lipid vesicles, showed marked pH dependence. By means of spin labeling of membrane proteins, the conformational changes of the proteins were observed in the pH range mentioned above. These results suggest a possible association between the strong pH dependence of the T parallel values and the conformation changes of membrane proteins. The pH dependence of the membrane fluidity was also investigated in cholesterol-enriched and -depleted erythrocytes. The effects of cholesterol demonstrated that the membrane fluidity was significantly mediated by cholesterol at low pH, but not at high pH.     

Release of spectrin-free vesicles from human erythrocytes during ATP depletion: 1. characterization of spectrin-free vesicles

Human erythrocytes incubated without glucose at 37 degrees C (in vitro aging) release spectrin-free vesicles after 12 or more hours. The release of vesicles is dependent upon ATP depletion. If the endogenous level of ATP is maintained, vesicle release is completely inhibited up to 54 h. Vesicle release is independent of hemolysis because in vitro aged cells and cells that maintain their ATP levels lose identical amounts of hemoglobin up to 45 h. 93 percent of all membrane particles released constitute a uniform population of spheres with a diameter of 185 +/- 23nm. These vesicles are of slightly varying densities due to varying contents of hemoglobin. Vesicles contain half the amount of membrane protein that is found in intact membranes when referred to the content of phospholipids phosphorus. This is primarily due to the absence of spectrin. However, their content of protein component III, glycophorin, and cholesterol remains the same as in intact membranes. Thus, the major integral membrane proteins are present in vesicles in similar quantities were surface area as in cells except for the enzyme acetylcholinesterase that is enriched up to twofold. The phospholipids composition of these vesicles is representative of the intact membrane except that the amount of phosphatidic acid is 10-fold higher and the amount of phosphatidylethanolamine is slightly lower than in erythrocytes. These results suggest a selective release of membrane domains that lack peripheral membrane proteins and are enriched in acetylcholinesterase. This release of spectrin-free vesicles from cells aged in vitro could represent an acceleration of the physiological aging process.     

Microwaves and the cell membrane. III. Protein shedding is oxygen and temperature dependent: evidence for cation bridge involvement

Microwaves (2450 MHz, 60 mW/g) are shown to result in the release or shedding of at least 11 low-molecular-weight proteins (less than or equal to 31,000 Da) from rabbit erythrocytes maintained in physiological buffer. Protein release was detected by gel electrophoresis of cell-free supernatants using sensitive silver staining. This release is oxygen dependent and occurs in 30 min for exposures conducted within the special temperature region of 17-21 degrees C, which is linked to a structural or conformational transition in the cell membrane. Shedding of 26,000 and 24,000 Da proteins is unique to microwave treatment, with enhanced release of 28,000 and less than or equal to 15,000 Da species during microwave compared to sham exposures. Two-dimensional isoelectric focusing further reveals that proteins of less than or equal to 14,000 Da shed during microwave treatment exhibit a pI of 6.8-7.3 not seen in sham-treated cells. Treatment of erythrocytes with a serine-directed protease inhibitor does not prevent release of proteins. However, when erythrocytes are maintained at 17-21 degrees C by conventional heating in the absence of divalent cations, release of 28,000-31,000 and less than or equal to 14,000 Da components is detected. This indicates that cation-bridge stability may be important for release of these proteins. The above results provide evidence that microwaves alter erythrocyte protein composition at temperatures linked to a transition in the cell membrane and that destabilization of salt bridges may play a role in an interaction mechanism for protein release.     

Iron release, oxidative stress and erythrocyte ageing

Iron, to be redox cycling active, has to be released from its macromolecular complexes (ferritin, transferrin, hemoproteins, etc.). Iron is released from hemoglobin or its derivatives in a nonprotein-bound, desferrioxamine-chelatable form (DCI) in a number of conditions in which the erythrocytes are subjected to oxidative stress. Such conditions can be related to toxicological events (haemolytic drugs) or to physiological situations (erythrocyte ageing, reproduced in a model of prolonged aerobic incubation), but can also result from more subtle circumstances in which a state of ischemia-reperfusion is imposed on erythrocytes (e.g., childbirth). The released iron could play a central role in oxidation of membrane proteins and senescent cell antigen (SCA) formation, one of the major pathways for erythrocyte removal. Iron chelators able to enter cells (such as ferrozine, quercetin, and fluor-benzoil-pyridoxal hydrazone) prevent both membrane protein oxidation and SCA formation. The increased release of iron observed in beta-thalassemia patients and newborns (particularly premature babies) suggests that fetal hemoglobin is more prone to release iron than adult hemoglobin. In newborns the release of iron in erythrocytes is correlated with plasma nonprotein-bound iron and may contribute to its appearance.     

Effect of complement on the lateral mobility of erythrocyte membrane proteins. Evidence for terminal complex interaction with cytoskeletal components

The lateral mobilities of erythrocyte membrane proteins and terminal complement complexes (TCC) were measured on C-treated erythrocyte ghosts by the technique of fluorescence redistribution after photobleaching. Results showed that the lateral diffusion coefficient of the bulk membrane proteins decreased with the assembly of TCC on the membrane at low C dose and was significantly reduced with assembly of the full membrane attack complex (C5b-9), even in the absence of cell lysis. At high serum doses, the mobility of the membrane proteins increased slightly above that of the control cells. The diffusion coefficients of the TCC on the erythrocyte membrane range from 1.18 to 4.37 x 10(-11) cm2/s, values characteristic of anchored membrane proteins. Spectrin-depletion of the C-lysed erythrocytes results in 25- and 45-fold increases in the diffusion coefficients of the membrane proteins and the C5b-9 complex, respectively. Conversely, oxidative cross-linking of spectrin by diamide reduced the diffusion coefficients of both membrane and C proteins. These studies indicate that the deposition of TCC on an erythrocyte can result in a substantial change in the physical and structural properties of the target membrane, aside from the creation of functional lesions. The low mobilities of the terminal complexes on the target membrane suggest possible interactions with cytoskeletal elements or with anchored membrane proteins.     

Long-term intercalation of residual hemin in erythrocyte membranes distorts the cell

The effect of long-term incubation of residual globin-free hemin on whole red blood cell and isolated cytoskeletal proteins was studied. Hemin at concentrations found in pathological red cells was inserted to fresh erythrocytes. Increased hemolysis developed in the hemin-containing cells after a few days at 37 degrees C and after about four weeks at 4 degrees C. Since lipid and hemoglobin peroxidation did not depend on the presence of hemin, time-dependent effects on the cytoskeleton proteins were studied. Observations were: (1) spectrin and protein 4.1 exhibited a time-dependent increasing tendency to undergo hemin-induced peroxidative crosslinking. (2) The ability of the serum proteins, albumin and hemopexin, to draw hemin from spectrin, actin and protein 4.1 decreased with time of incubation with hemin. These results were attributed to time-dependent hemin-induced denaturation of the cytoskeletal proteins. Albumin taken as a control for physiological hemin trap was unaffected by hemin. Small amounts of hemo-spectrin (2-5%) were analyzed in circulating normal cells, and this in vivo hemo-spectrin also failed to release hemin. It was concluded that slow accumulation of hemin, a phenomenon increased in pathological cells, is a toxic event causing erythrocyte destruction.     

Maintenance and mobility of hemoglobin and water within the human erythrocyte after detergent disruption of the plasma membrane.

Is an intact plasma membrane responsible for keeping hemoglobin and water within the human erythrocyte? If not, what is responsible? How free is Hb to move about within the erythrocyte? To answer these questions erythrocytes were taken for phase contrast microscopy, transmission electron microscopy (TEM), determination of water-holding capacity, and proton NMR studies both before and after membrane disruption with a nonionic detergent (Brij 58). Addition of 0.2% Brij to a D₂O saline solution of hemoglobin (Hb) caused particles of Hb to appear and to aggregate. This aggregation of Hb caused the amplitude of the Hb proton NMR spectra to decrease. Thus, the less mobile the Hb the lower the Hb proton spectra amplitude. Erythrocytes washed in D₂O saline showed proton NMR spectra of relatively low amplitude. Addition of Brij (0.2%) to these erythrocytes caused increased Hb mobility within these erythrocytes. The TEM of fixed and thin-sectioned erythrocytes treated with Brij showed disruption of the plasma membrane of all erythrocytes regardless of whether or not they had lost Hb. Brij-permeabilized erythrocytes washed in D₂O saline or in a D₂O K buffer maintained a higher heavy water-holding capacity upon centrifugation as compared to nonpermeabilized erythrocytes. The TEM of Brij-treated and washed erythrocyte “shells” revealed a continuous submembrane lamina but no other evidence of cytoskeletal elements. The water-holding capacity of the erythrocyte can be accounted for by the water-holding capacity of hemoglobin. The evidence favors a relatively immobile state of Hb and of water in the erythrocyte that is not immediately dependent on an intact plasma membrane but is attributed to interactions between Hb molecules and the submembrane lamina.     

Studies on an activator of the (Ca2+ plus Mg2+)-ATPase of human erythrocyte membranes.

1. An activator of the (Ca2+ plus Mg2+)-stimulated ATPase present in the human erythrocytes (membrane) has been isolated in soluble form from hemolysates of these cells. Partial purification has been achieved through use of carboxymethyl-Sephadex chromatography. The resulting activator fraction contained no hemoglobin and only 0.3% of the total adenylate kinase activity of the cell. 2. Whereas the activator was released from erythrocytes subjected to hemolysis in 20 miosM buffer at pH 7.6 or at pH 5.8, only the membranes prepared at pH 7.6 were affected by it. 2. Whereas the activator was released from erythrocytes subjected to hemolysis in 20 miosM buffer at pH 7.6 or at pH 5.8, only the membranes prepared at pH 7.6 were affected by it. 3. When (Ca2+ plus Mg2+)-ATPase activity was measured by 32Pi release from (gamma-32P)ATP, freeze-thawed erythrocytes, as well as membranes prepared at pH 5.8 and at pH 7.6, expressed lower values than noted by assay for total Pi release. When ADP instead of ATP was used as substrate, significant amount of Pi were released by these erythrocyte preparations. Further study revealed (a) production of ATP and AMP from ADP with membranes and hemolysate alone, and (b) exchange of the gamma-and B-position phosphate on (gama-32P)ATP in the presence of membranes plus hemolysates. These observations established the presence of adenylate kinase activity in the (membrane-free) hemolysates and in membranes. It further supports the conclusion that Pi release from ADP by human erythrocytes (freeze-thawed) and by their isolated membranes is due to formation of ATP by adenylate kinase and hydrolysis of this generated ATP by (Ca2+ plus Mg2+)-ATPase. 4. The following points were also established: (a) absence of an ADPase in human erythrocytes; (b) the (Ca2+ plus Mg2+)-ATPase activator enhanced cleavage only of the gama-position of ATP and (c) the (Ca2+ plus Mg2+)-ATPase activator is neither adenylate kinase nor hemoglobin.