Dextran sulfate inhibits fusion of influenza virus and cells expressing influenza hemagglutinin with red blood cells.

The influence of dextran sulfate with molecular weights of 500,000 and 8000 on binding and fusion of influenza virus (X31 strain) and of cells expressing influenza hemagglutinin (GP4F) with red blood cells (RBC) was investigated by spectrofluorimetry using virus and RBC labeled with the fluorescent dye octadecyl rhodamine B (R18). There was no significant inhibition of binding of virus and GP4F cells to red blood cells by dextran sulfate, but the polymer strongly inhibited the low pH induced fusion. Virus-RBC fusion was completely blocked by the high molecular weight dextran sulfate at concentrations as low as 0.5 mg/ml. Inhibition of RBC-GP4F cell fusion by dextran sulfate in the same concentration range was not as pronounced but the effect was potentiated by Ca2+. The polymer was only inhibitory when added at early steps of the fusion reaction, but the pH-induced conformational change of the hemagglutinin was not affected by dextran sulfate as measured by its susceptibility to proteolytic digestion. Removal of dextran sulfate after low pH-requiring steps allowed the system to fuse at neutral pH indicating that the inhibitory effect requires the continuous presence of dextran sulfate during the fusion reaction.     

Addition of oligosaccharide decreases the freezing lesions on human red blood cell membrane in the presence of dextran and glucose

Although incubation with glucose before freezing can increase the recovery of human red blood cells frozen with polymer, this method can also result in membrane lesions. This study will evaluate whether addition of oligosaccharide (trehalose, sucrose, maltose, or raffinose) can improve the quality of red blood cell membrane after freezing in the presence of glucose and dextran. Following incubation with glucose or the combinations of glucose and oligosaccharides for 3 h in a 37 °C water bath, red blood cells were frozen in liquid nitrogen for 24 h using 40% dextran (W/V) as the extracellular protective solution. The postthaw quality was assessed by percent hemolysis, osmotic fragility, mean corpuscle volume (MCV), distribution of phosphatidylserine, the postthaw 4 °C stability, and the integrity of membrane. The results indicated the loading efficiency of glucose or oligosaccharide was dependent on their concentrations. Moreover, addition of trehalose or sucrose could efficiently decrease osmotic fragility of red blood cells caused by incubation with glucose before freezing. The percentage of damaged cell following incubation with glucose was 38.04 ± 21.68% and significantly more than that of the unfrozen cells (0.95 ± 0.28%, P < 0.01). However, with the increase of the concentrations of trehalose, the percentages of damaged cells were decreased steadily. When the concentration of trehalose was 400 mM, the percentage of damaged cells was 1.97 ± 0.73% and similar to that of the unfrozen cells (P > 0.05). Moreover, similar to trehalose, raffinose can also efficiently prevent the osmotic injury caused by incubation with glucose. The microscopy results also indicated addition of trehalose could efficiently decrease the formation of ghosts caused by incubation with glucose. In addition, the gradient hemolysis study showed addition of oligosaccharide could significantly decrease the osmotic fragility of red blood cells caused by incubation with glucose. After freezing and thawing, when both glucose and trehalose, sucrose, or maltose were on the both sides of membrane, with increase of the concentrations of sugar, the percent hemolysis of frozen red blood cells was firstly decreased and then increased. When the total concentration of sugars was 400 mM, the percent hemolysis was significantly less than that of cells frozen in the presence of dextran and in the absence of glucose and various oligosaccharides (P < 0.01). However, when both glucose and trehalose were only on the outer side of membrane, with increase of the concentrations of sugars, the percent hemolysis was increased steadily. Furthermore, addition of oligosaccharides can efficiently decrease the osmotic fragility and exposure of phosphatidylserine of red blood cells frozen with glucose and dextran. In addition, trehalose or raffinose can also efficiently mitigate the malignant effect of glucose on the postthaw 4 °C stability of red blood cells frozen in the presence of dextran. Finally, addition of trehalose can efficiently protect the integrity of red blood cell membrane following freezing with dextran and glucose. In conclusion, addition of oligosaccharide can efficiently reduce lesions of freezing on red blood cell membrane in the presence of glucose and dextran.     

Fluorescence properties of rhodamine 800 in whole blood and plasma

We have characterized the fluorescence spectral properties of rhodamine 800 (Rh800) in plasma and blood in order to test the possibility of making clinical fluorescence measurements in whole blood without separation steps. Rh800 was used because of its absorption at red/near-infrared wavelengths away from the absorption bands of hemoglobin. We utilized the front-face illumination and detection to minimize the effects of absorption and/or scatter during measurements. The presence of Rh800 was detected in plasma and blood using steady-state fluorescence measurements. Absorption due to hemoglobin reduced the Rh800 intensity from the blood. Fluorescence lifetime measurements in plasma and blood showed that it is possible to recover lifetime parameters of Rh800 in these media. We obtained mean lifetimes of 1.90 and 1.86 ns for Rh800 in plasma and blood, respectively. Using the recently described modulation sensing method, we quantified the concentrations of Rh800 in plasma and blood. Rh800 was detected at a concentration of as low as 2 microM in both media. High anisotropy values were obtained for Rh800 in plasma and blood using steady-state and anisotropy decay measurements, implying the tight binding of this probe to the contents of these media. This binding can be exploited to monitor the concentrations of different blood components using already existing or new red-emitting probes that will be specially designed to bind to these components with high specificity. To test this possibility of direct measurements in blood, we used Rh800 to monitor albumin in the presence of red blood cells. Increase in the polarization of Rh800 as the concentration of albumin was increased in the presence of the red cells showed the feasibility of such measurements.     

Rheological discrimination between native, rigid and aggregated red blood cells in oscillatory flow

The viscoelastic behaviour of hardened or aggregated red blood cells is compared with the flow pattern of native red blood cells, all suspended in buffer solution at a hematocrit of 45%. The rheological properties are investigated under oscillatory shear at the constant frequency of 2Hz. Variation of the amplitude covers a range of shear-rates from 0.5/s to 200/s. It can be seen that rigidification of the red cells by treatment with glutardialdehyde leads to changes of the flow properties in the range of shear-rates above 10/s, whereas aggregate formation due to addition of dextran distinctly alters the flow properties in the range of shear-rates below 10/s.     

Study of structural changes of contractile muscle proteins with the aid of polarization ultraviolet fluorescence microscopy. 1. Conformational changes of F-actin in the muscle fiber caused by ATP and its analogs]

Increase of anisotropy of F-actin fluorescence of balanus and rabbit muscle fibers under the influence of ATP, AMP and pyrophosphate in EGTA presence was detected by means of the polarized ultraviolet (UV) fluorescent microscopy methods. The fluorescence anisotropy changes are assumed to be associated with the conformational changes in the actin. ATP cause more noticeable changes of actin structure, than pyrophosphate and AMP. The conformational changes in the actin of balanus and rabbit muscle fibres were similar. ATP and its analogs induced also decrease of UV fluorescence anisotropy of A-band which appears to be associated with conformational changes in myosin. It was siggested that the changes in fluorescence of anisotropy of A-bands are due to structural changes in both HMM and LMM parts of myosin molecule.     

Effect of Dextran 500 on Radial Migration of Erythrocytes in Postcapillary Venules at Low Flow Rates

Recently, we reported that collision efficiency (fraction of total collisions that result in the formation of aggregates) between red blood cells was an important factor in the formation of aggregates in postcapillary venules. In the present study, we focus on how high molecular weight dextran influences the overall radial migration trend of red blood cells in the postcapillary venule along a longitudinal distance of 50 μm from the bifurcation which would in turn affect collision behavior of these cells. A radial migration index, which defines the extent of radial migration of individual cells relative to the vessel center, was found to have a larger magnitude after infusion of dextran (1.9 ± 2.73) compared to that before dextran infusion (1.48 ± 3.89). This implied that dextran-induced aggregation might provide an external force to actively move cells towards the centerline of the vessel, which could contribute to the greater number of red blood cells participating in collision (16% increase) and aggregate formation. Further analysis of the collision behavior of individual red blood cells revealed that collision frequencies of individual cells decreased from a wide range (1 to 14) to a narrow range (1 to 5) after dextran treatment, indicating the alteration of collision behavior of red blood cells by the presence of aggregates along the flow stream.     

Characterization of the near infrared absorption spectra of cytochrome aa3 and haemoglobin for the non-invasive monitoring of cerebral oxygenation

Near infrared (IR) spectroscopy can give continuous, direct information about cerebral oxygenation in vivo by providing signals from oxygenated and deoxygenated haemoglobin and cytochrome aa3. Due to a lack of precise spectral information and uncertainties about optical path length it has previously been impossible to quantify the data. We have therefore obtained the cytochrome aa3 spectrum in vivo from the brains of rats after replacing the blood with a fluorocarbon substitute. Near infrared haemoglobin spectra were also obtained, at various oxygenation levels, from cuvette studies of lysed human red blood cells. Estimates of optical path length have been obtained. The data were used to construct an algorithm for calculating the changes in oxygenated and deoxygenated haemoglobin and oxygenated cytochrome aa3 in tissue from changes in near IR absorption.     

The influence of 2-mercaptoethanol (2-ME) treatment of IgG antibody on its ability to induce cytotoxicity in nonsensitized lymphocytes

Administering dextran 2 hr before giving antigen (sheep red blood cells) to X-irradiated mice repopulated with B and T cells caused alterations in antibody synthesis. Besides a slight increase in the number of cells making IgM antibodies, cells producing IgG antibodies were detected at a time when none are usually present in untreated control animals.Repopulating X-irradiated mice with B cells treated with dextran either in vivo or in vitro and immunizing with sheep red blood cells resulted in twice the background number of sheep red blood cell-specific IgM-plaque-forming cells at 4.5 days of immunization as well as a small number of IgG-plaque-forming cells at 8.5 days. At these times, control animals given only B cells and sheep red blood cells possessed a background number of IgM-plaque forming cells and no IgG plaque-forming cells.Incubating B cells with θ-specific antiserum and complement to remove residual T cells prior to transplantation obliterated dextran's stimulus. Dextran's alterations of immunological responses towards unrelated antigens therefore appears to be manifested through T cells. The latter must be in company with B cells at the time of exposure to dextran. Thus, T cells upon contact with dextran apparently release B cell stimulatory factor (s) responsible for increasing the number of IgM-forming cells and for triggering IgG-forming cells.     

A note on osmotic pressure measured with ionophore treated red blood cells

A method is described by which the osmotic pressure of macromolecules or many low molecular weight substances can be measured relative to the known osmotic pressure of a reference substance. Measurements can also be made in the presence of univalent electrolytes. The method involves the use of ionophore treated mammalian red blood cells as osmometers. Details are given for the establishment of the isosmotic identity line for dextran M_w = 9 400, M_n = 5 500 and sucrose using nystatin treated human red blood cells. The sucrose concentrations used were from 20 to 33 mOsm (50–80 kPa).     

Studies with dextran 40 in cryopreservation of blood

Whole blood from healthy donors was washed twice with phosphate-buffered saline (PBS) and then resuspended in sufficient PBS to give a final concentration of 2 × 10⁹/cells/ml. Aliquots were combined with equal volumes of the required diluents to give final dextran 40 concentrations of 0, 5, 10, 15, and 20% in PBS. Fifty-lambda samples in 50-lambda Micropets (Clay Adams) were frozen in alcohol baths at temperatures ranging from ?10 to ?80 °C. The specimens were frozen either for 1 min or 16 min, rapidly thawed, and resuspended in PBS or PBS plus dextran. Percentage of hemolysis was determined colorimetrically. Results indicate that concentraitons as low as 5% dextran exert a cryoprotective effect. Increased dextran concentration increases cryoprotection at high subzero bath temperatures (?10 ° and ?20 °C). Dextran concentrations beyond 12% have a damaging effect at low subzero bath temperatures (below ?30 °C). Based on this a two-factor hypothesis for cryopreservation is proposed. Apparent partial recovery of red blood cells without dextran or with 5% dextran during subzero storage was demonstrated.     

Influence of prolonged physical exercise on the erythropoietin concentration in blood

Erythropoietin (EPO) and red blood cells were studied in 15 well-trained men before and several times after a marathon run. Changes in red blood cells reflected changes of plasma volume. Immediately after the run, red blood cells were increased due to haemoconcentration, whereas 31 h later the values were decreased due to haemodilution. The EPO concentration was increased 3 h, and more impressive 31 h, after the run. This long-lasting increase in EPO concentration after the marathon run would seem to be responsible for the increased red blood cell mass in long distance runners.     

Effect of osmotic compression on the force-velocity properties of glycerinated rabbit skeletal muscle cells

The force-velocity relations of single glycerinated rabbit psoas muscle fibers at 5 degrees C were studied at maximum and half-maximum activation in the presence of 0 (control) and 39-145 g/liter dextran T-70. Resting fiber diameter decreased progressively to approximately 70% of the nondextran control as the dextran concentration was increased. Isometric force at full activation increased to a maximum of 136% of control at 111 g/liter dextran and then fell to 80% of control in 145 g/liter dextran. Maximum velocity, which fell to 49% of the control value in the highest concentration of dextran, was nearly constant at approximately 65% control over the range of 58-111 g/liter dextran. Relative maximum power, which gives an estimate of changes in intermediate velocity, was not significantly reduced by dextran concentrations up to 76 g/liter, but then fell progressively to 62% of control in the highest concentration of dextran. At half-maximum activation, maximum velocity and relative maximum power were not significantly different from the values at full activation. The results obtained at partial activation indicate that the decline of velocity seen in the presence of dextran is not due to a passive internal load and that the dextran does not cause a viscous resistance to shortening. The increased velocity in the absence of dextran can be explained by the reduced ability of cross-bridges to resist shortening, as proposed by Goldman (1987. Biophys. J. 51:57).     

Effects of dextran molecular weight on red blood cell aggregation

The reversible aggregation of human red blood cells (RBC) by proteins or polymers continues to be of biologic and biophysical interest, yet the mechanistic details governing the process are still being explored. Although a depletion model with osmotic attractive forces due to polymer depletion near the RBC surface has been proposed for aggregation by the neutral polyglucose dextran, its applicability at high molecular mass has not been established. In this study, RBC aggregation was measured over a wide range of dextran molecular mass (70 kDa to 28 MDa) at concentrations ≤2 g/dL. Our results indicate that aggregation does not monotonically increase with polymer size; instead, it demonstrates an optimum dextran molecular mass around 200-500 kDa. We used a model for depletion-mediated RBC aggregation to calculate the expected depletion energies. This model was found to be consistent with the experimental results and thus provides new insight into polymer-RBC interactions.     

Depletion interactions in polymer solutions promote red blood cell adhesion to albumin-coated surfaces

The effects of concentration and molecular weight of neutral dextrans on the adhesion of human red blood cells (RBC) to albumin-coated glass have been investigated using a parallel-plate flow chamber. Results indicate that the adhesion is markedly increased in the presence of 70 kDa and 500 kDa dextran, with this increase reflected by both the number of cells adhering and the strength of the adhesion. This increased adhesiveness is attributed to reduced surface concentrations of the large polymers and hence attractive forces due to depletion interaction. Depletion interaction brings the adjacent surfaces closer, leading to an increased number of binding sites available to the cell and thus more efficient and stronger adhesion of single cells. Our results suggest that depletion might play a role in other specific cell-cell or cell-surface interactions via initiating close contacts to allow specific binding.     

Cell-cell affinity probed by countercurrent distribution in two-polymer aqueous phase systems

Aqueous solutions of dextran and of polyethylene glycol when mixed form immiscible liquid two-phase systems with a polyethylene glycol-rich top and a dextran-rich bottom. Such phases can be buffered and rendered isotonic and are suitable for the partition of cells. The partition coefficient of cells (i.e., their relative affinity for the top or bottom phase or their adsorption at the interface) depends on the polymer concentrations, on the ionic composition and concentration and, most sensitively, on their membrane surface properties. When two cell populations are mixed the partition coefficient of each is unaffected by the presence of the other population unless an interaction takes place between them. By countercurrent distribution of two cell populations, in a phase system selected such that the partition coefficient of one population is high (i.e., more cells in the top phase) and of the other low, one should be able to detect subtle interactions between cells in the two populations should they occur. Results of experiments with a model system consisting of human peripheral blood mononuclear cells and sheep red blood cells bear out the feasibility of this approach. At low ratios of sheep erythrocytes to mononuclear cells no interaction is apparent. With increasing ratios there is an increasing shift in the distribution curve of subpopulations of mononuclear cells (i.e., T-lymphocytes) as they interact with the sheep red cells. Substitution of rabbit red cells for sheep erythrocytes (at high ratios) reveals a small yet significant shift of a subpopulation of mononuclear cells as well. Distribution of human peripheral blood lymphocytes from patients with chronic lymphocytic leukemia (all B-lymphocytes) are essentially unaffected by the presence of sheep red cells. This sensitive new method, still in its infancy, holds out the hope for the detection of previously unknown cell-cell affinities and for probing suspected cell-cell interactions.     

Physical properties of flowing blood

The changes of viscosity, optical reflection and electrical resistivity of blood due to flow are dependent on the orientation and deformation of red cells. From electrical point of view, it can be assumed that blood is suspension of small insulating particles (red cells) in conductive fluid (plasma) when the frequency of supplied voltage is lower than several hundreds KHz. When blood flows, red cells deform and orient in flow direction. Therefore, flowing blood shows anisotropic electrical and optical properties. In steady flow, blood resistivity longitudinal to flow decrease with flow rate, and transverse one increases. Blood flow in living body is not steady but pulsatile. We measured both longitudinal and transverse resistivity changes, optical reflection change and viscosity change of sinusoidally flowing blood in a rectangular conduit. The results are 1) during one period of sinusoidal flow the longitudinal resistivity change is opposite to that of transverse one, 2) the waveform of reflection light change is similar to that of resistance change, and 3) minimum points of both longitudinal resistivity and viscosity changes do not appear at the moment when flow is zero but are delayed. When the amplitude of sinusoidal flow is small and oscillation frequency is high, the phase difference between the zero crossing period of flow and the period of minimum change in resistivity, increases up to 90 degrees. Viscosity of blood decreases with increase of amplitude and frequency of sinusoidal flow.     

Cell-cell affinity of senescent human erythrocytes

During their 120-day life span, human red blood cells (RBC) undergo several physicochemical changes, including an increased tendency to aggregate in plasma or polymer solutions. This study was designed to examine potential associations between age-related differences in RBC mobility, aggregation, and membrane glycocalyx properties for cells suspended in buffer and in 3 g/dl solutions of 70.3 kDa dextran. A recent model for depletion-mediated RBC aggregation was employed to calculate the changes of glycocalyx properties that were consistent with experimental electrophoretic mobility (EPM) and aggregation data. Young and old cells were obtained by density separation, after which aggregation and EPM were determined versus ionic strength; old cells exhibited a two- to threefold greater aggregation in dextran. EPM of old cells was identical to young cells in polymer-free media yet was 4% greater in dextran. The greater EPM for old RBC indicates a larger polymer depletion layer, which could be explained either by a 10-15% decrease of their glycocalyx thickness or a similar percentage decrease of polymer penetration into their glycocalyx. The larger depletion layer leads to markedly elevated cell-cell affinities for old cells, with the computed affinity increases consistent with enhanced old RBC aggregation. These results provide a rational explanation for the aggregation and EPM behavior of old RBC, and raise the possibility of depletion-mediated interactions contributing to senescent cell removal from the circulation.     

Effect of dextran on protein stability and conformation attributed to macromolecular crowding

Thermally induced transition curves of hen egg-white lysozyme were measured in the presence of several concentrations of dextran at pH 2.0 by near-UV and far-UV CD. The transition curves were fitted to a two-state model by a non-linear, least-squares method to obtain the transition temperature (T(m)), enthalpy change (deltaH(u)(T(m))), and free energy change (deltaG(u)(T)) of the unfolding transition. An increase in T(m) and almost constant deltaH(u)(T(m)) values were observed in the presence of added dextran at concentrations exceeding ca 100 g l(-1). In addition, dextran-induced conformational changes of fully unfolded protein were investigated by CD spectroscopy. Addition of high concentrations of dextran to solutions of acid-unfolded cytochrome c at pH 2.0 results in a shift of the CD spectrum from that characteristic of the fully unfolded polypeptide to that characteristic of the more compact, salt-induced molten globule state, a result suggesting that the molten globule-like state is stabilized relative to the fully unfolded form in crowded environments. Both observations are in qualitative accord with predictions of a previously proposed model for the effect of intermolecular excluded volume (macromolecular crowding) on protein stability and conformation.