Microwaves and the cell membrane. IV. Protein shedding in the human erythrocyte: quantitative analysis by high-performance liquid chromatography

The erythrocyte responds to microwave fields by shedding at least 11 low-molecular-weight proteins of less than or equal to 31,000 Da, with components of 28,000-31,000 Da released during the destabilization of divalent calcium-protein bridges [R.P. Liburdy and P.F. Vanek, Radiat. Res. 109, 382-395 (1987)]. Significantly, protein shedding was shown to be restricted to exposure temperatures coinciding with the cell membrane phase/structural transition temperature, Tc, of 17-25 degrees C. We report here a further characterization of protein shedding at Tc using high-performance liquid chromatography and membrane-associated blood group antigen testing. Proteins shed from human erythrocytes in microwave fields (2450 MHz, CW) compared to sham-heating displayed a twofold increase in total protein mass released concomitant with the appearance of unique protein species during reverse-phase, hydrophobic interaction, and anion-exchange HPLC. These HPLC analyses indicate that microwaves result in the shedding of proteins which are relatively nonpolar and hydrophobic and which carry a net positive electrostatic charge compared to those released during sham-heat treatment. Assessment of 23 blood group antigens that represent integral protein markers on the erythrocyte cell surface indicates that microwave fields do not result in the exhaustive loss of these proteins. The class of proteins that is shed in response to microwave fields most likely is the loosely bound "peripheral" or extrinsic proteins associated with the exterior of the cell surface. Such proteins play a major role in the transduction of signals to integral membrane proteins which span the bilayer. That this class of proteins is susceptible to release by microwave fields is discussed in relation to microwave absorption at the cell surface by membrane-associated bound water, field interaction with dipolar side groups, and the disruption of divalent cation bridges known to stabilize peripheral membrane proteins.     

Isolation and partial characterization of the human erythrocyte band 7 integral membrane protein.

Monoclonal antibodies to the Mr 31,000 major integral membrane protein of the human erythrocyte band 7 region were used to identify the corresponding polypeptide chain and epitope-carrying fragments on immunoblots. Analysis of the erythrocyte membrane, membrane fractions, and cytosol revealed that the Mr 31,000 band 7 integral membrane protein is unique and not related to any of the other water-soluble or membrane-bound band 7 components. Cross-reacting proteins were identified in the membranes of other mammalian erythrocytes and in cell lines of epithelial and lymphoid origin. Proteolytic digestion of intact human erythrocytes or erythrocyte membranes demonstrated that the band 7 integral membrane protein has an intracellular domain larger than Mr 12,000; it does not have an extracellular one. One of the monoclonal antibodies was employed for the isolation of band 7 integral membrane protein by immunoaffinity chromatography; subsequent Edman degradation revealed a blocked N-terminus.     

Microwave bioeffects in the erythrocyte are temperature and pO2 dependent: Cation permeability and protein shedding occur at the membrane phase transition

Microwave exposure (2450 MHz, 60 mW/g, CW) of rabbit erythrocytes increases Na passive transport only at membrane phase transition temperatures (T_c) of 17–19°C. This permeability effect is enhanced for relative hypoxia which is characteristic of intracellular oxygen tension (pO₂ ? 5 mm Hg). Neither the permeability nor the pO₂ effects are observed in temperature-matched (± 0.05°C), sham-exposed controls. In addition, at T_c, microwave exposure is observed to induce the shedding or release of two erythrocyte proteins not seen in sham-exposed controls. Moreover, the enhanced shedding of at least seven other proteins all of molecular weight ? 28,000 D was detected in the microwave-treated samples. Using sensitive silver staining we estimate that approximately 450 fg of protein were shed per erythrocyte. These results demonstrate that temperature and pO₂ are important influences on both functional and structural responses of cell membranes to microwave radiation.     

Biogenesis of mitochondrial ubiquinol:cytochrome c reductase (cytochrome bc1 complex). Precursor proteins and their transfer into mitochondria

The precursor proteins to the subunits of ubiquinol:cytochrome c reductase (cytochrome bc1 complex) of Neurospora crassa were synthesized in a reticulocyte lysate. These precursors were immunoprecipitated with antibodies prepared against the individual subunits and compared to the mature subunits immunoprecipitated or isolated from mitochondria. Most subunits were synthesized as precursors with larger apparent molecular weights (subunits I, 51,500 versus 50,000; subunit II, 47,500 versus 45,000; subunit IV (cytochrome c1), 38,000 versus 31,000; subunit V (Fe-S protein), 28,000 versus 25,000; subunit VII, 12,000 versus 11,500; subunit VIII, 11,600 versus 11,200). Subunit VI (14,000) was synthesized with the same apparent molecular weight. The post-translational transfer of subunits I, IV, V, and VII was studied in an in vitro system employing reticulocyte lysate and isolated mitochondria. The transfer and proteolytic processing of these precursors was found to be dependent on the mitochondrial membrane potential. In the transfer of cytochrome c1, the proteolytic processing appears to take place in two separate steps via an intermediate both in vivo and in vitro. In vivo, the intermediate form accumulated when cells were kept at 8 degrees C and was chased into mature cytochrome c1 at 25 degrees C. Both processing steps were energy-dependent.     

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.     

Structural reorganizations of the lipids and proteins of erythrocyte membranes under the action of low temperatures

The reversible structural rearrangement of lipids and protein oligomerization has been shown to occur during cooling in membranes of model systems (liposome, erythrocyte shadows) and native erythrocytes. Analysing the dependence of Azz in membrane probes (5- or 15-doxylstearic acids) in the Arrhenius plots a conclusion on the structural changes at 13-19 degrees C and within the range of interior water freezing from -17 up to -19 degrees C has been drawn, the last transition is smoothed out in the presence of glycerin. Using diamide joining spectrin and electrophoresis in polyacrylamide gel it has been determined that the low temperatures cause the spatial approach of proteins of spectrin-actinic complex and formation connections between the erythrocyte membrane proteins which aren't destroyed by dodecylsulfate.     

Microwaves and the cell membrane. II. Temperature, plasma, and oxygen mediate microwave-induced membrane permeability in the erythrocyte

Microwaves (2450 MHz) are shown to increase 22Na permeability of rabbit erythrocytes for exposures only within the narrow temperature range of 17.7 to 19.5 degrees C (Tc) which coincides with a nonlinearity in the Arrhenius plot reflecting an apparent membrane phase transition. Significantly, this response is not observed for cholesterol-loaded erythrocyte membranes which exhibit a linear Arrhenius plot and no apparent phase transition at Tc. The permeability increase at Tc is a nonlinear function of absorbed power but is a linear function of the internal electric field strength of the sample and saturates at approximately 400 mW/g and 600 V/m, respectively. The permeability increase was found to be reversible and transient in that immediately following termination of exposure sodium influx is significantly reduced but returns to normal within 60 min. Extracellular factors exert a significant influence on the microwave effect. The presence of plasma markedly potentiates the increase in 22Na permeability at Tc. Oxygen also modulates the microwave effect with relative hypoxia (5 mm Hg) and hyperoxia (760 mm Hg) enhancing the permeability increase. In contrast, the presence of two antioxidants, ascorbic acid or mercaptoethanol, inhibits the effect. These findings raise important questions about the physical and chemical nature of microwave interactions with cell membranes and also shed light on earlier studies reporting either positive or negative effects on membrane permeability.     

Purification of the mosquitocidal and cytolytic proteins of Bacillus thuringiensis subsp. israelensis.

Two proteins from parasporal crystals of Bacillus thuringiensis subsp. israelensis were purified to electrophoretic homogeneity by gel filtration and anion-exchange chromatography. The larger of the two proteins (molecular weight, 68,000) was not cytolytic, whereas the smaller protein (molecular weight, 28,000) was highly cytolytic when assayed against rat erythrocytes. When these proteins were assayed against larvae of the yellow fever mosquito, Aedes aegypti, the larger protein was at least 100-fold more toxic than the smaller protein. Although proteolytic activity was not detected in solubilized crystals nor in purified protein preparations, the toxin (molecular weight, 68,000) was readily degraded to smaller, nontoxic molecules, even when maintained at 4 degrees C. Mixtures of the two purified proteins were significantly more toxic to mosquito larvae than was either protein alone. Thus, it is likely that both the mosquitocidal and the cytolytic protein play roles in the overall insecticidal action of the parasporal crystal produced by this bacterium.     

Purification of the mosquitocidal and cytolytic proteins of Bacillus thuringiensis subsp. israelensis

Two proteins from parasporal crystals of Bacillus thuringiensis subsp. israelensis were purified to electrophoretic homogeneity by gel filtration and anion-exchange chromatography. The larger of the two proteins (molecular weight, 68,000) was not cytolytic, whereas the smaller protein (molecular weight, 28,000) was highly cytolytic when assayed against rat erythrocytes. When these proteins were assayed against larvae of the yellow fever mosquito, Aedes aegypti, the larger protein was at least 100-fold more toxic than the smaller protein. Although proteolytic activity was not detected in solubilized crystals nor in purified protein preparations, the toxin (molecular weight, 68,000) was readily degraded to smaller, nontoxic molecules, even when maintained at 4 degrees C. Mixtures of the two purified proteins were significantly more toxic to mosquito larvae than was either protein alone. Thus, it is likely that both the mosquitocidal and the cytolytic protein play roles in the overall insecticidal action of the parasporal crystal produced by this bacterium.     

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 temperature and pH on hemoglobin release from hydrostatic pressure-treated erythrocytes

The release of hemoglobin from human erythrocytes hemolyzed beforehand by hydrostatic pressure, osmotic pressure, and freeze-thaw methods was examined as a function of temperature (0-45 degrees C) and pH (5.5-8.8) at atmospheric pressure. Only in the case of high pressure (2,000 bar) did the release of hemoglobin increase significantly with decreasing temperature and pH. Maleimide spin label studies showed that the temperature and pH dependences of hemoglobin release were qualitatively explicable in terms of those of the conformational changes of membrane proteins. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of membrane proteins showed the diminution of band intensities corresponding to spectrin, ankyrin, and actin in the erythrocytes hemolyzed by high pressure. Cross-linking of cytoskeletal proteins by diamide stabilized the membrane structure against high pressure and suppressed hemoglobin release. These results indicate that the disruption of cytoskeletal apparatus by high pressure makes the membrane more leaky.     

Purification of a hexokinase-binding protein from the outer mitochondrial membrane.

Brain hexokinase (ATP:D-hexose-6-phosphotransferase, EC 2.7.1.1) binds selectively to the outer membrane of rat liver mitochondria but not to inner mitochondrial or microsomal membranes nor to the plasma membrane of human erythrocytes. A protein having subunit molecular weight of 31,000, determined by sodium dodecyl sulfate-gel electrophoresis, has been highly purified from the outer mitochondrial membrane by repetitive solubilization with octyl-beta-D-glucopyranoside followed by reconstitution into membranous vesicles when the detergent is removed by dialysis. When incorporated into lipid vesicles, the protein confers the ability to bind brain hexokinase in a Glc-6-P-sensitive manner as is seen with the intact outer mitochondrial membrane. Hexokinase binding ability and the 31,000 subunit molecular weight protein co-sediment during sucrose density gradient centrifugation. Both hexokinase binding ability and the 31,000 subunit molecular weight protein are resistant to protease treatment of the intact outer mitochondrial membrane while other membrane proteins are extensively degraded. It is concluded that this protein, designated the hexokinase-binding protein (HBP), is an integral membrane protein responsible for the selective binding of hexokinase by the outer mitochondrial membrane.     

Cooling and freezing damage platelet membrane integrity.

Cytoskeletal rearrangements and a membrane lipid phase transition (liquid crystalline to gel) occur in platelets on cooling from 23 to 4 degrees C. A consequence of these structural alterations is irreversible cellular damage. We investigated whether platelet membrane integrity could be preserved by (a) previously studied combinations of a calcium chelator (EGTA) and microfilament stabilizer (cytochalasin B) with apparent benefit in protecting platelets from cooling injury or (b) agents of known benefit in protecting membranes and proteins from freezing injury. Platelet function and activation before and after freezing or cooling were measured by agglutination with ristocetin, aggregation with thrombin or ADP, platelet-induced clot retraction (PICR), and expression of P-selectin. Platelets were loaded with 10 nM fluorescein diacetate. After freezing or cooling, the preparations were centrifuged and the supernatant was measured for fluorescein. For cooling experiments, fresh platelets were chilled at 4 degrees C for 1 to 21 days with or without the combination of 80 microM EGTA/AM and 2 microM cytochalasin B (EGTA/AM-CytoB) and then warmed rapidly at 37 degrees C. For freezing experiments, 5% dimethyl sulfoxide (Me2SO) or 5 mM glycerol were added to fresh platelets. The preparations were then frozen at -1 degrees C/min to -70 degrees C and then thawed rapidly at 37 degrees C. Platelet membrane integrity, as measured by supernatant levels of fluorescein, correlated inversely with platelet function. Chilling platelets at 4 degrees C with EGTA/AM-CytoB showed a gradual loss of membrane integrity, with maximum loss reached on day 7. The loss of membrane integrity preceded complete loss of function as demonstrated by PICR. In contrast, platelets chilled without these agents had complete loss of membrane integrity and function after 1 day of storage. Freezing platelets in Me2SO resulted in far less release of fluorescein than did freezing with or without other cryoprotectants (P < 0.001). This result correlated with enhanced function as demonstrated by PICR and supports earlier observations that Me2SO protects platelet membranes from freezing injury. Release of fluorescein into the surrounding medium reflected loss of membrane integrity and function in both cooled and frozen platelets. Membrane cytoskeletal rearrangements are linked to membrane changes during storage. These results may be generally applicable to the study of platelet storage.     

Progressive muscular dystrophy type Duchenne. II. Viscosity and resistence to erythrolytic compounds of erythrocyte membranes

The transition temperature of erythrocyte ghosts of normal subjects is about 18-20 degrees C. We have studied the viscosity of erythrocyte ghosts of dystrophic children, showing that the transition shifts to lower temperatures (17-18 degrees C). After treatment with erythrocytic compounds like L-Lyso phosphatidyl-Choline dystrophic erythrocytes hemolize at lower Lysophosphatidyl-Choline concentration and at a greater extents than these of normal and carriers subjects.     

Dialysis of bovine semen and its effect on fresh and freeze-thawed spermatozoa

The effect of the removal of the low-molecular-weight fraction (LMWF, less than 12,000-14,000 Da) from the seminal plasma present in extended semen by dialysis and by centrifugation (1,376g for 20 min at 5 degrees C) were compared with the current methods of freezing bovine semen. Significantly higher sperm post-thaw motility (P less than 0.05) was obtained in the dialyzed samples than with the other two methods. The appropriate time and temperature for dialysis of semen was also studied. Semen aliquots were dialyzed (1:50, retentate:dialysate) for 30 min, 1 or 2 hr at 5 degrees C, and during the cooling process from 37 to 5 degrees C over a 2-hr period. Superior sperm motility (P less than 0.05) in prefreeze and post-thawed samples was observed when semen was dialyzed for 1 or 2 hr during the cooling process as compared with that of semen dialyzed at 5 degrees C. A third experiment was conducted to establish the effect of the use of dialysis bags of different molecular weight cutoffs (MWCO) on sperm motility. Semen samples were dialyzed (1:50) during the cooling process in dialysis bags of 1,000, 3,500, 6,000-8,000, 12,000-14,000, 25,000, and 50,000 MWCO. No statistical differences (P greater than 0.05) in sperm post-thaw motility were found after evaluation of the number of cells that passed through the Sephadex filter and all the dialyzed values obtained were significantly (P less than 0.05) superior to the results obtained with no dialysis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Physicochemical characterization and phylogenetic comparison of fish lens proteins.

The composition of soluble eye lens proteins from four chondropterygiian and fourteen teleostean fishes were analyzed for heterogeneity in MW and pI. Lens proteins from all the fish species studies are distributed in the pI range 4.3-9.0 with polypeptides in the range 17,500-31,000 Da. Phylogenetic trees are constructed based on the observations.     

Erythrocyte hemolysis by radiofrequency fields

A field-strength-dependent hemolytic effect of continuous-wave radiofrequency (RF) exposure in vitro has been demonstrated. Erythrocytes in whole heparinized rabbit blood were hemolyzed by a 2-h exposure to 50- or 100-MHz RF fields at field strengths of greater than 4 V/cm. An effect of comparable magnitude resulted from exposure to 10-MHz RF at a field strength of 9 V/cm. Sample temperatures were maintained at 22.5 degrees +/- 0.2 degrees C. There was no apparent involvement of heating or temperature gradients, nor were there any RF exposure effects on cellular K+ or Na+ concentration, nor on pH. The mechanism of the hemolytic effect is not known. Since the percentage of lysed erythrocytes was less than 1% and there was an absence of effects on cellular cation concentrations, RF radiation may have irreversibly altered the plasma membrane permeability of a sensitive subpopulation of red cells (possibly aged cells) leading to osmotic lysis. RF radiation at these frequencies appears to affect red cells in a manner that is qualitatively and quantitatively different from microwave radiation.     

Heat-modifiable outer membrane proteins of Neisseria meningitidis and their organization within the membrane.

Neisseria meningitidis group B serotype 2 strain M986 contains two predominant outer membrane proteins, with apparent molecular weights of 41,000 (protein b) and 28,000 (protein e). Heating of outer membrane vesicles at 56 degrees C for 20 min caused much of b** to disaggregate and denature into b (41,000 daltons). In contrast, protein e could be rapidly solubilized by SDS at room temperature into its monomeric state (e*), but it was not converted to its final higher apparent molecular weight of 28,000 (e) unless heated at 100 degrees C for 2 min. We propose that protein b exists in the membrane as trimers or tetramers in a transmembrane configuration and that protein e exists as subunits on the exterior surface of the outer membrane and has a highly ordered tertiary structure.     

Protein-catalyzed exchange of phosphatidylinositol between rat brain microsomes and myelin.

Exchange of phosphatidylinositol and phosphatidylcholine between microsomal and myelin membranes has been demonstrated. This exchange is reversible and catalyzed by soluble proteins from the brain homogenate precipitated at pH 5.1. The extent of exchange of phosphatidylinositol from microsomal membrane to myelin is dependent upon pH and temperature, with an optimum around pH 7 and at 50 degrees C. Maximum exchange was observed at approximately equal amounts of microsomal, myelin, and supernatant proteins. The extent of the catalyzed exchange increases 4- to 8-fold upon using sonicated or heat-treated myelin as an acceptor membrane. Heating of microsomal membranes results in no change. The extent of catalyzed exchange of phosphatidylcholine is less than that of the phosphatidylinositol. The exchange of other phospholipids and glycolipids between microsomal and myelin membranes cannot be demonstrated. The catalytic activity of the pH 5.1 supernatant proteins in rat brain for the exchange of phosphatidylinositol increases with age after birth and reaches a maximum around 21 days of age analogous to the process of myelination. The pH 5.1 supernatant proteins from quaking and jimpy mutant mice has normal catalytic activity.     

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).