Hemoglobin oxidation products extract phospholipids from the membrane of human erythrocytes.

Hydrogen peroxide oxidation of human erythrocytes induces a transfer of phospholipid from the membrane into the cytosol [Brunauer, L.S., Moxness, M.S., & Huestis, W.H. (1994) Biochemistry 33, 4527-4532]. The current study examines the mechanism of lipid reorganization in oxidized cells. Exogenous phosphatidylserine was introduced into the inner monolayer of erythrocytes, and its distribution was monitored by microscopy and radioisotopic labeling. Pretreatment of cells with carbon monoxide prevented both hemoglobin oxidation and the transfer of phosphatidyserine into the cytosolic compartment. The roles of the various hemoglobin oxidation products in lipid extraction were investigated using selective oxidants. Nitrite treatment of intact cells produced almost complete conversion to methemoglobin, but no detectable lipid extraction. Treatments designed to produce the green hemoglobin derivatives, sulfhemoglobin and choleglobin, resulted in cytosolic extraction of phosphatidylserine. Ion exchange and size exclusion chromatography of oxidized cytosolic components revealed a lipid-hemoglobin complex. The interaction between lipid and hemoglobin oxidation products was verified in a model system. Purified hemoglobin, enriched in sulfhemoglobin and choleglobin by treatment with H2O2, H2S, or ascorbate, extracted phospholipid from small unilamellar phospholipid vesicles. Electron paramagnetic resonance studies demonstrated that hemoglobin oxidation products also adsorb fatty acids from solution. This newly described activity of hemoglobin may play a role in the clearance of oxidatively damaged and senescent cells from circulation.

Physical determinants of intermembrane protein transfer.

Intermembrane protein transfer between erythrocytes and phospholipid vesicles was examined under a variety of conditions to investigate physical factors governing this process. Human erythrocytes were incubated with sonicated dimyristoylphosphatidylcholine vesicles containing trace [14C]dipalmitoylphosphatidylcholine. Protein-vesicle complexes were separated from cells and from membrane fragments by density gradient centrifugation. The yield of isolated protein vesicles was determined from the 14C-vesicle marker; protein compositions were analyzed by SDS-polyacrylamide gel electrophoresis. Enzymatic removal of portions of the cytoplasmic or exoplasmic domains of cell membrane proteins had little effect on the extent of protein transfer. Membrane additives such as cholate produced a 2-fold increase in protein-vesicle yield. The selectivity of protein transfer from erythrocytes was influenced by the lipid composition of recipient vesicles: inclusion of cholesterol increased band 3 content while the presence of anionic phospholipids reduced transfer. Proteins transferred from 32P-labeled cells differed in specific radioactivity from bulk cell proteins: glycophorin, highly phosphorylated in the cell membrane, showed no detectable labeling in the corresponding protein-vesicle band. These observations suggest that cell-to-vesicle protein transfer is insensitive to bulk steric and electrostatic properties of cell membranes, but enhanced by membrane defects. Recipient membrane composition influences the selectivity of transferred proteins and may reveal subtle differences in the membrane association of protein subpopulations.

Hydrogen peroxide oxidation induces the transfer of phospholipids from the membrane into the cytosol of human erythrocytes.

The effects of oxidative damage on membrane phospholipid organization were examined in human erythrocytes. Exposure to H2O2 induced shape changes in these cells; normal discocytes became echinocytic, and stomatocytes generated by foreign phosphatidylserine incorporation reverted to discoid morphology. H2O2 treatment also inhibited phosphatidylserine transport from the outer to inner membrane monolayer, consistent with earlier reports on oxidative sensitivity of the aminophospholipid translocator. The morphological changes are consistent with movement of inner monolayer lipids to the outer monolayer, as might be expected if aminophospholipid sequestration is compromised. However, lipid extraction and prothrombinase activation assays showed no increased exposure of phosphatidylserine on the cell surface. Instead, phosphatidylserine was found associated with the cytosolic fraction of H2O2-treated cells. These observations suggest that oxidative damage alters the lipid organization of erythrocyte membranes, not by randomizing the lipid classes within the bilayer, but by inducing extraction of inner monolayer components into the cytosol.

Effects of exogenous phospholipids on platelet activation.

Intercalation of amphipaths into the plasma membrane of platelets has a marked effect on their morphology. Incubation of platelets with phosphatidylcholines (PC) results in rounding of the platelet body and speculation, while incubation with aminophospholipids such as dilauroylphosphatidylserine (DLPS) results in a biphasic shape change consistent with the bilayer couple model (Sheetz, M.P. and Singer, S.J. (1982) Proc. Natl. Acad. Sci. USA 71, 4457-4461) and with the activity of an aminophospholipid translocator facilitating transverse bilayer diffusion (Daleke, D.L. and Huestis, W.H. (1985) Biochemistry 24, 5406-5416). The present study extends this work to investigate the effects of PC and PS on platelet responses to a natural agonist, thrombin. PC incorporation produces a concentration-dependent progression of shape changes, beginning with surface ruffling and development of fine spicules, followed by sphering of the cell body, and ending with the apparent loss of spicules. PC reduces platelet responses to thrombin only under conditions that promote membrane vesiculation, seen morphologically as a loss of spicules and biochemically as a loss of 14C-PC labeled membrane. PS homologues of varying acyl chain composition induce concentration- and time-dependent platelet sphering. Incorporation of PS inhibits thrombin-induced platelet shape change, granule secretion, and protein phosphorylation. Inhibition of these responses requires transit of the exogenous PS to the cytofacial leaflet of the membrane bilayer.

Age-dependent accumulation of protein residues which can be hydrolyzed to D-aspartic acid in human erythrocytes.

We have measured the rate of accumulation of amino acid residues in human erythrocyte membrane and cytosolic proteins which give D-aspartic acid upon acid hydrolysis. These residues would include D-aspartic acid, D-asparagine, as well as the beta-transpeptidation product, D-isoaspartic acid. Measurements made using age (density) fractionated cells indicate that racemization at these residues occurs on membrane proteins with a t1% (the time required to convert 1% to the D configuration) of about 38.6 days. Fractionation of membrane components revealed a faster rate of racemization for intrinsic proteins than for extrinsic proteins. On the other hand, significant age-dependent racemization was not detected for cytosolic proteins, and the calculated t1% value for these proteins is at least 4 times larger. These results suggest that in the 120-day life span of an erythrocyte, significant racemization of membrane (but not cytosolic) proteins can occur. We have also determined that the rates of accumulation of these residues for erythrocyte membrane and cytosolic proteins incubated in vitro are similar to those observed in vivo. These observations are discussed in terms of the possible cellular metabolism of racemized proteins.

Methylation of calmodulin at carboxylic acid residues in erythrocytes. A non-regulatory covalent modification?

The physiological role of protein carboxy-group methylation reactions in human erythrocytes was studied with calmodulin as an endogenous methyl-group acceptor. The steady-state degree of calmodulin carboxy-group methylation is substoichiometric both in intact cells and in a lysed-cell system (about 0.0003 mol of methyl groups/mol of polypeptide). Purified erythrocyte calmodulin is a substrate for a partially purified erythrocyte carboxy-group methyltransferase and can be methylated to the extent of about 0.0007-0.001 mol of methyl groups/mol of polypeptide. This erythrocyte protein methyltransferase displays an apparent specificity for atypical racemized and/or isomerized D-aspartate and L-isoaspartate residues [McFadden & Clarke (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 2460-2464; Murray & Clarke (1984) J. Biol. Chem. 259, 10722-10732]. Exposure of calmodulin to elevated temperatures before methylation results in racemization of aspartate and/or asparagine residues, and may result in isoaspartate formation as well. The methylatability of these samples also increases as a function of time of heating, independent of the pH (over the range pH 5-9) or Ca2+ concentration; the most significant increase occurs during the initial 60 min, when calmodulin retains a fraction of its biological activity. These results are consistent with the hypothesis that methylation of calmodulin may occur at these uncommon aspartate residues, but are not consistent with a regulatory role for the methylation reaction.

Metabolism of S-adenosyl-L-methionine in intact human erythrocytes.

Freshly isolated human erythrocytes contain S-adenosyl-L-methionine (AdoMet) at a concentration of about 3.5 mumol/l cells. When such cells are incubated in a medium containing 30 microM L-methionine, 18 mM D-glucose and 118 mM sodium phosphate (pH 7.4), intracellular AdoMet levels continuously decrease to a value of about 0.1 microM after 24 h. This occurs in spite of the fact that the cellular concentrations of the substrates for the AdoMet synthetase reaction, ATP and L-methionine, remain relatively constant. In a search for incubation conditions that lead to stable levels of AdoMet in incubated cells, we have developed a sodium-Hepes-buffered medium which includes 1 mM adenine and a stoichiometric excess of MgCl2 over its ligand, phosphate. The inclusion of magnesium ion (and a reduction in phosphate) appears to increase intracellular free Mg2+, which is required for full activity of the erythrocyte AdoMet synthetase. Even in the presence of MgCl2, however, the AdoMet pool level can drop 4-6-fold within the first 2 h of incubation. We present evidence that suggests that this initial fall in the cellular AdoMet level may be due to the activation of AdoMet-dependent protein carboxyl methyltransferase, an enzyme which accounts for a large fraction of the total cellular AdoMet utilization. Adenine, or related compounds in the medium may prevent this activation, although the mechanism of this action is not clear at present.