Study of the relationship between shape and aggregation change in human erythrocytes

The relationship between shape and spontaneous and fibrinogen-induced aggregation change in human erythrocytes was studied. Spontaneous and fibrinogen-induced erythrocyte aggregation was investigated using a rheoscope designed according to the method of H. Schmid-Schonbein et al. (1973). The erythrocyte shape was studied by means of light microscopy. It was shown that plasma enriched with lysophosphatidic acid and ATP depletion of erythrocytes led to the change of erythrocyte shape: discocytes transformed into echinocytes. It was found that spontaneous aggregation of such cells was considerably decreased. Aggregation of erythrocytes, treated with lysophosphatidic acid, was diminished more markedly. Fibrinogen-induced aggregation of echinocytes, obtained after treatment with lysophosphatidic acid and produced by ATP depletion, was also greatly reduced.     

A study of the aggregation of human red blood cells induced by picric acid

The effect of picric acid on the aggregation of human erythrocytes was studied. It was shown that the addition of picric acid to a suspension of washed erythrocytes leads to a decrease in pH of medium to 1.5-2 and the formation of echinocytes. Stirring the suspension of echinocytes at low pH values results in a strong aggregation of cells. Increasing the pH value to 7.4 leads to a desaggregation of echinocytes. It was found that picric acid does not induce the aggregation of cells fixed by glutaraldehyde. A substantial decrease in the aggegation of spheric erythrocytes obtained after heating the cells at 50 degrees C was observed.     

Changes in erythrocyte and thrombocyte aggregation after ultraviolet irradiation

Lipid peroxidation which occurs in blood serum under ultraviolet irradiation was studied. The products of these reaction suppress ADP-induced aggregation of native platelets. The rouleaux-forming capacity increased after UV-irradiation of plasma and serum albumin. Under UV-irradiation the aggregates of albumin molecules are supposed to form the aggregates of albumin molecules which bind the erythrocytes in rouleaux.     

Effect of adenosine on the shape,aggregates morphology and aggregability of ATP-depleted erythrocytes

The effect of adenosine on the shape, aggregate morphology and aggregability of ATP-depleted erythrocytes was studied. It is shown that the ATP-depletion of erythrocyte leads to the change in their shape: diskocytes transform to echinocytes. It is found that the aggregability of such cells in autologous plasma significantly decreased. Incubation of echinocytes with adenosine largely restored discoid shape and erythrocyte aggregability.     

The RBC morphological dependence of the RBC disaggregability

The aim of this study was to determine the red blood cell (RBC) disaggregability dependence upon the RBC shape. The study concentrated on stored blood during bank storage and on suspensions of artificially induced echinocytes. Measurements was performed in autologous plasma of hematocrit 0.45 and at constant plasmatic content. Rheological studies using stationary viscometry, nonstationary viscometry and rheoscopy were made in order to assess different stages of the disaggregability process. Whatever the method of measurement used, the morphological interpretation of the results reveal that beyond 75% of echinocytes within the sample, the disaggregation process is altered. The shear stresses required to dissociate the echinocyte aggregates are significantly higher than those required to disaggregate normal RBC rouleaux.     

The interaction of β2-glycoprotein I with lysophosphatidic acid in platelet aggregation and blood clotting

β₂-Glycoprotein I (β₂-GPI) is a plasma protein that binds to oxidized low-density lipoprotein (LDL) and negatively charged substances, and inhibits platelet activation and blood coagulation. In this study, we investigated the interaction of β₂-GPI with a negatively charged lysophosphatidic acid (LPA) in platelet aggregation and blood clotting. Two negatively charged lysophospholipids, LPA and lysophosphatidylserine, specifically inhibited the binding of β₂-GPI to oxidized LDL in a concentration-dependent manner. Intrinsic tryptophan fluorescence studies demonstrated that emission intensity of β₂-GPI decreases in an LPA-concentration-dependent manner without a shift in wavelength maxima. LPA specifically induced the aggregation of β₂-GPI in phosphate-buffered saline, and in incubated plasma and serum, both of which are known to accumulate LPA by the action of lecithin-cholesterol acyltransferase and lysophospholipase D/autotaxin. β₂-GPI aggregated by LPA did not inhibit activated von Willebrand factor-induced aggregation, and did not prolong the activated partial thromboplastin time in blood plasma, in contrast to non-aggregated β₂-GPI. These results suggest that β₂-GPI aggregated by the binding to LPA fails to inhibit platelet aggregation and blood clotting in contrast to non-aggregated β₂-GPI.     

Kinetics of linear rouleaux formation studied by visual monitoring of red cell dynamic organization

Red blood cells (RBCs) in the presence of plasma proteins or other macromolecules may form aggregates, normally in rouleaux formations, which are dispersed with increasing blood flow. Experimental observations have suggested that the spontaneous aggregation process involves the formation of linear rouleaux (FLR) followed by formation of branched rouleaux networks. Theoretical models for the spontaneous rouleaux formation were formulated, taking into consideration that FLR may involve both "polymerization," i.e., interaction between two single RBCs (e + e) and the addition of a single RBC to the end of an existing rouleau (e + r), as well as "condensation" between two rouleaux by end-to-end addition (r + r). The present study was undertaken to experimentally examine the theoretical models and their assumptions, by visual monitoring of the spontaneous FLR (from singly dispersed RBC) in plasma, in a narrow gap flow chamber. The results validate the theoretical model, showing that FLR involves both polymerization and condensation, and that the kinetic constants for the above three types of intercellular interactions are the same, i.e., k(ee) = k(er) = k(rr) = k, and for all tested hematocrits (0.625-6%) k < 0.13 +/- 0.03 s(-1).     

Segregation into separate rouleaux of erythrocytes from different species. Evidence against the agglomerin hypothesis of rouleaux formation.

Erythrocytes from one species were labelled with fluorescein isothiocyanate and mixed with unlabelled erythrocytes from another species. Albumin polymers were added to generate rouleaux. The species of origin of erythrocytes in rouleaux was determined by fluorescence microscopy. Erythrocytes from different species segregated into independent rouleaux. However, fluorescent and non-fluorescent erythrocytes from one individual were mixed randomly in rouleaux. These results confirm, using a novel experimental approach, previous observations of Sewchand & Canham [(1976) Can. J. Physiol. Pharmacol. 54, 437-442]. Since rouleaugenic agents are not species-specific, under the 'agglomerin' hypothesis of rouleau formation they would be expected to form bridges between cells from different species. It follows that either the agglomerin hypothesis is incorrect, or additional species-specific surface components are involved in the aggregation of agglomerin-cross-bridged cells.     

Changes of RBC aggregation in oxygenation-deoxygenation: pH dependency and cell morphology

The effects of the oxygenation-deoxygenation process on red blood cell (RBC) aggregation were examined in relation to morphological changes in RBCs and the contribution of CO(2). A low-shear rheoscope was used to measure the rate of rouleaux (one-dimensional aggregate) formation in diluted autologous plasma exposed to gas mixtures with different Po(2) and Pco(2). RBC indexes and RBC suspension pH were measured for the oxygenated or the deoxygenated condition, and the cell shape was observed with a scanning electron microscope. In the oxygenation-deoxygenation process, the rate of rouleaux formation increased with rising pH of the RBC suspension, which was lowered in the presence of CO(2). The rate increased with increasing mean corpuscular hemoglobin concentration (thus the cells shrank), which increased with rising pH and decreased in the presence of CO(2). With rising pH, cell diameter increased and cell thickness decreased (thus the cell flattened). In addition, slight echinocytosis was induced in the presence of CO(2), and the aggregation was reduced by the morphological change. In conclusion, RBC aggregation in the oxygenation-deoxygenation process is mainly influenced by the pH-dependent change in the surface area-to-volume ratio of the cells, and the aggregation is modified by CO(2)-induced acidification and the accompanying changes in mean corpuscular hemoglobin concentration and cell shape.     

Effect of pH on the velocity of erythrocyte aggregation

The effect of pH on the velocity of aggregation of human erythrocytes was quantitatively examined with a rheoscope combined with a video-camera, an image analyzer and a computer, in relation to the morphological changes of erythrocytes and their aggregates. (i) With increasing pH of the medium, the velocity of erythrocyte aggregation increased. (ii) The rouleaux formed at high pH were longer in shape and more stable against the increase of shear rate than those formed at low pH. (iii) With increasing pH, the diameter of erythrocyte increased, the (maximum) thickness decreased, and the cell volume decreased. The pH dependency of erythrocyte aggregation may be mainly due to the morphological change of erythrocytes, and partly due to the changes of erythrocyte deformability and of interaction with macromolecules.     

Effect of lysophosphatidic acid on motility, polarisation and metabolic burst of human neutrophils

Abstract The effect of lysophosphatidic acid (LPA) on human neutrophil activation was examined by a combination of automated tracking assays, cell shape measurements and assays of the metabolic burst by means of 7-dimethylamino-naphthalene-1,2-dicarbonic acid hydrazide (DNDH)-dependent chemiluminescence. LPA powerfully stimulated polarisation and motility. Polarisation became detectable at 2 μM LPA and virtually 100% of cells were polarised at 20 μM LPA. Cell motility increased with the degree of polarisation, and was diminished at high LPA concentration, but this decrease was reversed by albumin. LPA also inhibited the metabolic burst response to both n -formyl-methionyl-leucyl-phenylalanine (fMLP) and phorbol 12-myristate 13-acetate (PMA). Inhibition of the PMA-induced metabolic burst by LPA was not affected by pertussis toxin, showing that the effect was not mediated by the pertussis toxin-sensitive heterotrimeric G protein, and that inhibition of the PMA-stimulated metabolic burst by LPA could result from a direct action of LPA on the small cytosolic GTP-binding proteins. These results indicate that lysophosphatidic acid production by thrombin-activated platelets could play a significant role in the regulation of the inflammatory response.     

Effect of temperature on the velocity of erythrocyte aggregation

The velocity of the aggregation of human erythrocytes was examined in the range of 5-43 degrees C with a rheoscope combined with a video camera, an image analyzer and a computer. (1) With increasing temperature, the velocity of erythrocyte aggregation induced by fibrinogen, immunoglobulin G and artificial macromolecules (dextran of 70 kDa and poly(glutamic acid) of 50 kDa) increased. However, the relationship between the velocity of erythrocyte aggregation and the temperature was different among these macromolecules. (2) In 70% autologous plasma, the velocity of erythrocyte aggregation was minimum at 15-18 degrees C, and increased at both higher and lower temperatures. (3) The shape of erythrocyte aggregates in 12 mumol/l fibrinogen (containing 770 mumol/l albumin) and in 70% autologous plasma was dependent on temperature: three-dimensional below 15-18 degrees C and one-dimensional (mainly rouleaux) above 15-18 degrees C. However, the shape of aggregates in 27 mumol/l immunoglobulin G (containing 770 mumol/l albumin) was three-dimensional in all temperature ranges. (4) The temperature dependency of erythrocyte aggregation was discussed in terms of the changes of medium viscosity, of erythrocyte properties and of bridging macromolecules.     

Suppression of lysophosphatidic acid and lysophosphatidylcholine formation in the plasma in vitro: proposal of a plasma sample preparation method for laboratory testing of these lipids

It is now established that lysophosphatidic acid (LPA) and lysophosphatidylcholine (LPC) play important roles in a variety of biological responses, especially in the area of vascular biology, and determination of their concentrations in the plasma is believed to be clinically relevant. Preparation of the measurement samples is a difficult task, however, because the blood levels of these lipids can be easily increased by in vitro manipulation after venepuncture. In this study, we examined the optimal conditions for the preparation of plasma samples for the measurement of LPA and LPC. It appears that regulation of platelet activation and the enzymatic activity of lysophospholipase D/autotaxin and lecithin-cholesterol acyltransferase is important to suppress the undesirable formation of LPA and LPC after venepuncture. We found that in vitro formation of LPA and LPC was negligible when whole blood samples were mixed with 7.5 mM EDTA plus 10% (v/v) citrate-theophylline-adenosine-dipyridamole (CTAD) and when all of the procedures, including the plasma preparation and preservation until measurement, were performed at 4 degrees C. Thus, although the plasma levels of LPA and LPC can be easily altered, laboratory testing of these important bioactive lipids for clinical purposes may be conducted reliably if the samples are prepared under stringent conditions.     

Quantification of phosphatidic acid and lysophosphatidic acid by HPLC with evaporative light-scattering detection

Phosphatidic acid (PA) and lysophosphatidic acid (LPA) are lipids that regulate cellular processes. PA stimulates kinases and may play a role in exocytosis and membrane fusion. LPA can induce cell proliferation, platelet aggregation, and microfilament formation. Due to the growing interest in these lipids, rapid purification and quantification of these lipids is desirable. We now describe a method that utilizes one HPLC run to separate trace amounts of PA and LPA from large amounts of lipids found in cellular extracts. A two-pump HPLC with a solvent system consisting of chloroform, methanol, water, and ammonium hydroxide was employed to produce a reliable, efficient purification of the two lipids. Lipid mass was quantified by a sensitive evaporative light-scattering detector. Using this new method, insulin addition increased both PA (87%) and LPA (217%) mass in Xenopus laevis oocytes.     

Autotaxin stabilizes blood vessels and is required for embryonic vasculature by producing lysophosphatidic acid

Autotaxin (ATX) is a cancer-associated motogen that has multiple biological activities in vitro through the production of bioactive small lipids, lysophosphatidic acid (LPA). ATX and LPA are abundantly present in circulating blood. However, their roles in circulation remain to be solved. To uncover the physiological role of ATX we analyzed ATX knock-out mice. In ATX-null embryos, early blood vessels appeared to form properly, but they failed to develop into mature vessels. As a result ATX-null mice are lethal around embryonic day 10.5. The phenotype is much more severe than those of LPA receptor knock-out mice reported so far. In cultured allantois explants, neither ATX nor LPA was angiogenic. However, both of them helped to maintain preformed vessels by preventing disassembly of the vessels that was not antagonized by Ki16425, an LPA receptor antagonist. In serum from heterozygous mice both lysophospholipase D activity and LPA level were about half of those from wild-type mice, showing that ATX is responsible for the bulk of LPA production in serum. The present study revealed a previously unassigned role of ATX in stabilizing vessels through novel LPA signaling pathways.     

Cytospectrophotometric research on hemoglobin in human erythrocytes. I. The methemoglobin content in intact erythrocytes and its alteration under the influence of chromosmon, ascorbic acid, riboflavin and glutathione

The blood of healthy men and patients with methemoglobinemia of different genesis was incubated with chromosmon, ascorbic acid, riboflavin and glutathione, the percentage of erythrocytes with thorn-shaped protuberances-echinocytes being subsequently determined in the blood smears. The absorbtion spectra at the range 400-650 nm were investigated both in the smooth erythrocytes and in echinocytes. A correlation was found between the percentage of echinocytes and the methemoglobin content in the blood. The methemoglobin amount in the echinocytes was determined to be higher than in the smooth erythrocytes. It is discovered that effects of chromosmon, glutathione and riboflavin on production of methemoglobin depend on the dose, individual peculiarities of erythrocytes and on the illness that caused methemoglobinemia. The calculation of echinocyte percentage may be used as an express-diagnostics of methemoglobinemia and for purposes of studying the effect of methemoglobin-producing substances and drugs.     

Dielectric approach to investigation of erythrocyte aggregation. II. Kinetics of erythrocyte aggregation-disaggregation in quiescent and flowing blood

A method based on dielectric properties of dispersed systems was applied to investigate the kinetics of RBC aggregation and the break-up of the aggregates. Experimentally, this method consists of measuring the capacitance at a frequency in the beginning of the beta-dispersion. Two experimental protocols were used to investigate the aggregation process. In the first case, blood samples were fully dispersed and then the flow was decreased or stopped to promote RBC aggregation. It was found that the initial phases of RBC aggregation are not affected by the shear rate. This finding indicates that RBC aggregation is a slow coagulation process. In the second case, RBCs aggregated under flow conditions at different shear rates and after the capacitance reached plateau levels, the flow was ceased. The steady-state capacitance of the quiescent blood and the kinetics of RBC aggregation after stoppage of shearing depend on the prior shear rate. To clarify the reasons for this effect, the kinetics of the disaggregation process was studied. In these experiments, time courses of the capacitance were recorded under different flow conditions and then a higher shear stress was applied to break up RBC aggregates. It was found that the kinetics of the disaggregation process depend on both the prior and current shear stresses. Results obtained in this study and their analysis show that the kinetics of RBC aggregation in stasis consists of two consecutive phases: At the onset, red blood cells interact face-to-face to form linear aggregates and then, after an accumulation of an appropriate concentration of these aggregates, branched rouleaux are formed via reactions of ends of the linear rouleaux with sides of other rouleaux (face-to-side interactions). Branching points are broken by low shear stresses whereas dispersion of the linear rouleaux requires significantly higher energy.     

Modulation of cell surface fibronectin assembly sites by lysophosphatidic acid

Lysophosphatidic acid is a product of activated platelets and has diverse actions on cells. We have characterized the effect of lysophosphatidic acid on cell-mediated binding and assembly of fibronectin, an extracellular matrix protein. Serum made from whole blood, but neither platelet-poor plasma nor serum made from platelet- poor plasma, caused enhanced binding of fibronectin to cultured fibroblastic cells. The ability of whole blood serum to enhance binding of fibronectin was abolished by phospholipase B. These results indicate that lysophosphatidic acid derived from platelets is the principal component in whole blood serum that is active in the fibronectin binding assay. 1-oleoyl lysophosphatidic acid, 20-200 nM, was as active as 0.1-0.2% whole blood serum. The stimulatory effect of lysophosphatidic acid on the binding of fibronectin or the amino- terminal 70-kD fragment of fibronectin was rapid, sustained, and lost upon removal of lysophosphatidic acid. The stimulatory effect on binding could not be duplicated by bradykinin, platelet-activating factor, bombesin, or a peptide agonist of the thrombin receptor. Enhanced binding of the 70-kD fragment was due to increases in both the number and affinity of binding sites. Enhanced binding and assembly of fibronectin correlated with changes in cell shape and actin-containing cytoskeleton. The binding sites for fibronectin on lysophosphatidic acid-stimulated cells, as assessed by fluorescence, video, and scanning electron microscopy, were on areas of cell membrane containing numerous filopodia that extended between cells or between cells and substratum. These observations suggest that lysophosphatidic acid functions as a powerful and specific modulator of cell shape and early matrix assembly during wound healing.     

Dependence of dielectrophoretic force on the size of cylindrical particles by the example of a suspension of erythrocytes

For the modeling of erythrocyte rouleaux (linear cell aggregations), we propose an approximation procedure for the dipole moment in short cylinders, which contains the case of ellipsoidal bodies only as a first approximation. The method allows one to introduce corrections that are more representative for these particles. Depending on the number of erythrocytes forming an aggregation, i.e., on different but discrete measures of rouleaux lengths, the dielectrophoretic force is calculated and represented against the frequency of the applied a.c. field. As a result, frequency regions in the upper MHz range appear in which the strength and direction of DEP forces are different for different rouleaux sizes. This property is suitable for the detection and spatial separation of rouleaux populations of different length in blood samples by means of a microelectronic array.     

Production of lysophosphatidic acid by lysophospholipase D in incubated plasma of spontaneously hypertensive rats and Wistar Kyoto rats.

Lysophosphatidic acid has been identified as a vasopressor principle in incubated mammalian plasma and sera, and shown to be generated extracellulary by lysophospholipase D-like activity. In this study, we monitored the time course of changes in the major phospholipid fractions during incubation of plasma, and found that polyunsaturated lysophosphatidic acids accumulate more rapidly than saturated lysophosphatidic acids at expense of the corresponding lysophosphatidylcholines. We compared the phospholipase activities for producing bioactive LPA in age-matched spontaneously hypertensive rats and Wistar Kyoto rats. The lysophospholipase D activity in rat plasma was found to be independent of strain and age. We suggest that lysophospholipase D functions in rat for persistent production of bioactive LPA in the circulation throughout life. However, our finding that production of LPA in spontaneously hypertensive rats was not greater than that in Wistar Kyoto rats does not seem to support the idea that increased production of LPA is involved in the pathogenesis of hypertension.