Aggregation and disaggregation of red blood cells

The aggregation of red blood cells may be analyzed as an interaction of an adhesive surface energy and the elastic stored energy which results from deformation of the cell. The adhesive surface energy is the work required to separate a unit adhered area and is the resultant of adhesive forces due to the bridging molecules that bind the cells together and the electrostatic repulsion due to surface charge. The elastic strain energy in the case of the red blood is associated with the membrane elasticity only since the interior of the cell is liquid. The membrane elasticity is due both to bending stiffness and shear. The area expansion is small and may be neglected. These assumptions allow realistic computation of red cell shapes in rouleaux. The disaggregation of rouleaux requires an external force which must overcome the adhesive energy and also supply additional elastic energy of deformation. Depending on the geometry, the initial effect of elastic energy may tend to aid disaggregation. In a shear flow, the stresses on a suspended rouleau alternately tend to compress and to disaggregate the cells if they are free to rotate. This introduces a time dependence so that viscous effects due to the viscosity of the cell membrane, the cell cytoplasm and the external fluid may play a role in determining whether disaggregation proceeds to completion or not.     

Aggregation of red blood cells studied by ultrasound backscattering

The erythrocyte aggregation phenomenon is an important factor in capillary circulation. This phenomenon can be evaluated by a number of methods (microscopic observations, viscometry, light measurements) which cannot be applied simply to in vivo measurements. In contrast, ultrasound which propagates through soft tissues allows measurement of the mechanical properties of red blood cell (RBC) suspensions which depend on the aggregation phenomenon. We devised an apparatus in order to measure in vitro the ultrasonic backscattering intensity of RBC suspensions. First, with latex particles of different sizes, the ultrasonic backscattering coefficient has been measured in order to evaluate the apparatus response. Then, the ultrasonic backscattering coefficient of different aggregated erythrocyte suspensions has been measured and correlated with the erythrocyte sedimentation rate. Finally, the size of RBC aggregates of different suspensions has been evaluated.     

Membrane properties and aggregation of human red blood cells after endotoxin treatment in vitro

Endotoxin treatment of blood in vitro (10(-11) mg/RBC, 30 min at 30 degrees C) leads to a significant increase of the membrane elastic shear modulus mu and membrane viscosities as well as of the aggregation index AI and of the velocity of doublet formation.     

The specific heat and the heat of compression of human red cells,sickled red cells,and paracrystalline rat red cells

The investigation of two thermal properties of red cells throws some light on whether sickling is a process involving the crystallization of a relatively insoluble hemoglobin. These properties are the specific heat and the heat of compression, both of which would be expected to become numerically less if the hemoglobin of the red cell were to crystallize. In the case of paracrystalline rat red cells, which give spacings at 45 A and 58 A by x-ray diffraction, the specific heat is reduced to 85 per cent of that of the normal red cells, and the heat of compression is only about 75 per cent of that found for the normal red cell. In the case of the red cell sickled by a reduction of the O₂ tension, the specific heat and the heat of compression are substantially the same as found for the normal red cell. This is an argument against sickling being the result of a crystallization process, and supports the observation that sickled cells do not give x-ray spacings. The result is compatible, on the other hand, with sickling being the result of the formation of an oriented and birefringent gel.     

Hypertonic cryohemolysis of human red blood cells

Summary Hypertonic cryohemolysis of human erythrocytes is caused by incubation of the cells in hypertonic medium at a temperature of 20–50°C (stage 1), with subsequent cooling to 0°C (stage 2). In 0.86m sucrose hemolysis increases, with increasing stage 1 temperature, whereas in 1m NaCl cryohemolysis has a temperature optimum at a stage 1 temperature of about 30°C.Cryohemolysis is inhibited by preceding ATP depletion of the cells and bypreincubation of the cells in hypertonic medium at 0°C. In general, anesthetics inhibit cryohemolysis strongly. Only in 1m NaCl at stage 1 temperatures in the range of 40–50°C is cryohemolysis stimulated by these drugs, if present during the entire incubation period. This effect is abolished, however, when the anesthetic is added after piror incubation of the cells at 40–50°C in 1m NaCl.Ghost-bound ANS fluorescence indicates complicated conformation changes in the membrane structure during the various experimental stages leading to cryohemolysis.Some of the experimental results can be considered as examples of molecular hysteresis, thus indicating several different metastable structures of the membrane, under various experimental conditions.The described results support the working hypothesis of Green and Jung that the experimental procedure results in membrane protein damage, preventing normal adaptation of the membrane during cooling.     

Shape memory of human red blood cells

The human red cell can be deformed by external forces but returns to the biconcave resting shape after removal of the forces. If after such shape excursions the rim is always formed by the same part of the membrane, the cell is said to have a memory of its biconcave shape. If the rim can form anywhere on the membrane, the cell would have no shape memory. The shape memory was probed by an experiment called go-and-stop. Locations on the membrane were marked by spontaneously adhering latex spheres. Shape excursions were induced by shear flow. In virtually all red cells, a shape memory was found. After stop of flow and during the return of the latex spheres to the original location, the red cell shape was biconcave. The return occurred by a tank-tread motion of the membrane. The memory could not be eliminated by deforming the red cells in shear flow up to 4 h at room temperature as well as at 37 degrees C. It is suggested that 1). the characteristic time of stress relaxation is >80 min and 2). red cells in vivo also have a shape memory.     

Potassium-activated phosphatase from human red blood cells

Summary The cell membrane K⁺-activated phosphatase activity was measured in reconstituted ghosts of human red cells having different ionic contents and incubated in solutions of varying ionic composition. When K⁺-free ghosts are suspended in K⁺-rich media, full activation of the phosphatase is obtained. Conversely, very little ouabainsensitive activity is detected in K⁺-rich ghosts suspended in K⁺-free media. These results, together with the fact that Na⁺ competitively inhibits the effects of K⁺ only when present externally, show that the K⁺ site of the membrane phosphatase is located at the outer surface of the cell membrane. The Mg⁺⁺ requirements for K⁺ activation of the membrane phosphatase are fulfilled by internal Mg⁺⁺. Addition of intracellular Na⁺ to ATP-containing ghosts raises the apparent affinity of the enzyme for K⁺, suggesting that the sites where ATP and Na⁺ produce this effect are located at the inner surface of the cell membrane. The asymmetrical features of the membrane phosphatase are those expected from the proposed role of this enzyme in the Na⁺–K⁺-ATPase system.The authors are established investigators of the Consejo Nacional de Investigaciones Científicas y Técnicas, Argentina.     

Aggregation behavior and electrophoretic mobility of red blood cells in various mammalian species

Differences of red blood cell (RBC) aggregation among various mammalian species has been previously reported for whole blood, for RBC in autologous plasma, and for washed RBC re-suspended in polymer solutions. The latter observation implies the role of cellular factors, yet comparative studies of such factors are relatively limited. The present study thus investigated RBC aggregation and RBC electrophoretic mobility (EPM) for guinea pigs, rabbits, rats, humans and horses; RBC were re-suspended in isotonic 500 kDa dextran solutions for the EPM and aggregation measurements, with aggregation studies also done in autologous plasma. Salient results included: (1) species-specific RBC aggregation in both plasma and dextran (horse > human > rat > rabbit approximately = guinea pig) with a significant correlation between aggregation in the two media; (2) similar EPM values in PBS for rat, human and horse, a lower value for guinea pig, and a markedly reduced EPM for rabbit RBC; (3) EPM values in dextran with a rank order identical to that for cells in PBS; (4) relative EPM results indicating formation of a polymer-poor, low viscosity depletion layer at the RBC surface (greatest depletion for horse RBC). EPM-aggregation correlations were evident and generally consistent with the Depletion Model for aggregation, yet did not fully explain differences between species; additional studies at various ionic strengths and with various dextran fractions thus seem warranted.     

Phosphoglycolate phosphatase from human red blood cells

The nucleotide profile of rat liver Golgi vesicles isolated using sucrose gradients has been determined by high-pressure liquid chromatography. The nucleotide composition of this Golgi preparation, probably modified by osmotic shock, differs from that of liver supernatant fraction and from isolated rough microsomes. The major nucleotides present in the Golgi have been tentatively identified as uridine diphosphate and a peak containing uridine monophosphate plus cytidine monophosphate at 1.6 and 0.5 nmol/mg protein, respectively. In order to minimize osmotic shock, we have modified the isolation of Golgi using D₂O-sucrose gradients. Intact Golgi from these gradients were extracted directly and analyzed. Higher levels of nucleotides were found in the unshocked preparation, and the profile was also altered, although it was still distinct from that of liver supernatant. Four major peaks were found, tentatively identified as uridine monophosphate plus cytidine monophosphate, adenosine monophosphate, UDP, and uridine diphosphogalactose plus uridine diphosphoglucose, at 6.4, 6.4, 6.1, and 3.3 nmol/mg protein. These results indicate that the membrane of the Golgi apparatus is not freely permeable to nucleotides but that selective mechanisms exist for the uptake or exclusion of specific nucleotides from this organelle. The fact that UDP is selectively retained in shocked Golgi vesicles may indicate the presence of a binding protein which would prevent interference of Golgi function by UDP, a highly inhibitory product of galactosyltransferase.     

The isolation of reticulocyte-free human red blood cells

We depleted reticulocytes from erythrocytes of both sickle cell disease (SCD) subjects and healthy controls by four methods: fluorescence-activated cell sorting (FACS), Miltenyi immunomagnetic depletion (MACS), a combination of these methods (FACS + MACS) and Percoll density separation. The efficiency of these methods was assessed by new methylene blue staining and manual enumeration of the reticulocytes. FACS sorted erythrocytes from reticulocytes based on size and granularity, as well as the absence of dsDNA staining. MACS depleted reticulocytes from erythrocytes based on the immunoaffinity to CD36 and CD71. Reticulocytes from healthy controls were depleted to 相似文献   

ATP and integrity of human red blood cells

In spite of the well known significance of ATP in the energy dependent life processes, the role of ATP in maintaining cellular integrity is poorly understood. A possible model for studying ATP dependent life processes is to monitor the kinetics of changes seen intra/extracellularly during ATP depletion. In our model system anticoagulated human whole blood was incubated at different temperatures to reduce intracellular ATP without addition of any chemicals. The red blood cells in their own plasma were incubated for several days at 4 degrees C or at 37 degrees C, and ATP, glucose, K+, Na+, hemoglobin, water content, mean corpuscular volume (MCV), pH and Ca2+ were analyzed in time-sequences. All the examined parameters remained practically unchanged at 4 degrees C, while at 37 degrees C total ATP and glucose decreased parallel and after a transient increase of MCV, the water content of red blood cells decreased. As the actual ATP fell below 10% of the initial ATP content (at 48 h), the release of potassium sharply increased. Release of hemoglobin started only after 96 hours of incubation. Maximums of changes of the examined parameters were found at different time intervals. The maximal speed of concentration changes for glucose was found at 12-24 hours of incubation and at 24-36 hours for ATP, at 48-60 hours for K+(-)Na+ and after 96 hours for hemoglobin.     

Alterations in reactivity of the blood factors of cattle red cells after pronase treatment

Pronase treatment of cattle red cells produced various effects: (a) an increase in reactivity of the J factor and evolution of a specific cryptoantigen; (b) decrease in the A-B, G₂, K, I₂ O₂, O₃, P, Q, T_1; Y₂, A, B', E'₂, E'₃, I', K', O'-L'-V-L and M, factors, but (c) no change in the specifity or in the titre of the remaining 16 different blood factors. Most of the pronase-affectable blood factors were destroyed in a rather narrow but characteristic range of pronase treatment intensities. However, at like intensities, variations were demonstrable due to the fact that the blood factor occurred (a) in red cells from different individuals, and (b) in different phenogroups or subgroups of the B locus.     

Glucose transport kinetics in human red blood cells

D-[14C]Glucose self exchange and unidirectional efflux from human red blood cells were studied at 20 degrees C (pH 7.2) by means of the Millipore-Swinnex filtering technique whose time resolution is greater than 1 s and the continuous flow-tube method with a time resolution of greater than 2 ms. The unidirectional efflux data were analyzed using both the method of initial rates and the integrated rate equation. Simple Michaelis-Menten kinetics apply to the results obtained under both experimental conditions. In self-exchange mode, the half-saturation constant, K1/2ex, was 10 (S.E. +/- 1) mM. In unidirectional efflux mode K1/2ue was 6.6 (S.E. +/- 0.5) mM (initial rates) or by the method of integrated rates 7.7 mM, with a range of 2.7-12.1 mM, K1/2ue increasing with an increased initial intracellular glucose concentration. Our results of K1/2ex oppose previous published values of 32 mM for self exchange (Eilam and Stein (1972) Biochim. Biophys. Acta 266, 161-173) and 25 mM for unidirectional efflux (Karlish et al. (1972) Biochim. Biophys. Acta 255, 126-132) that have been used extensively in kinetic considerations of glucose transport models. Under self-exchange conditions Jmaxex was 1.8 x 10(-10) mol cm-2s-1, and in unidirectional efflux mode Jmaxue was 8.3 x 10(-11) mol cm-2s-1 (initial rates) and 8.6 x 10(-11) mol cm-2s-1 (integrated rates). We suggest that the previous high values of Jmax and in particular K1/2 are due to the use of methods with insufficient time resolution. Our results indicate that the transport system is less asymmetric than was generally accepted, and that complicated transport models developed to account for the great difference between the determined K1/2 and J max values are redundant.     

Calcium extrusion by high-density human red blood cells

Normal human red blood cells were separated on arabinogalactan density gradients to provide cell populations comprising a very small percentage of the cells (0.4%-1.8%). These very high-density cells were compared to a low-density, mature reference cell population with respect to their ATP content and their capacity to extrude Ca that had been loaded into the cells using the ionophore A23187. Assay of ATP content of freshly drawn and separated cells suggested a decrease of approximately 40% in the ATP concentration of the most dense 0.5%-1% of the cells, but the second most dense percent or so of the cells showed no ATP deficit. When the cells were loaded with millimolar amounts of 45Ca, high and low-density cell populations extruded Ca at the same rate. It appears that even stringently selected cells comprising the highest-density portion of the total cell population have an intact Ca transport system that can rapidly export Ca from the cell when adequate metabolic support is available.     

NMR water-proton spin-lattice relaxation time of human red blood cells and red blood cell suspensions

NMR water-proton spin-lattice relaxation times were studied as probes of water structure in human red blood cells and red blood cell suspensions. Normal saline had a relaxation time of about 3000 ms while packed red blood cells had a relaxation time of about 500 ms. The relaxation time of a red cell suspension at 50% hematocrit was about 750 ms showing that surface charges and polar groups of the red cell membrane effectively structure extracellular water. Incubation of red cells in hypotonic saline increases relaxation time whereas hypertonic saline decreases relaxation time. Relaxation times varied independently of mean corpuscular volume and mean corpuscular hemoglobin concentration in a sample population. Studies with lysates and resealed membrane ghosts show that hemoglobin is very effective in lowering water-proton relaxation time whereas resealed membrane ghosts in the absence of hemoglobin are less effective than intact red cells.