Hemolytic Interaction of Newcastle Disease Virus and Chicken Erythrocytes. I. Quantitative Comparison Procedure

The extent to which erythrocytes are hemolyzed by Newcastle disease virus is a function of the relative concentrations of both virus and erythrocytes. Under proper conditions, the interaction of a single virus particle with an erythrocyte is sufficient to cause lysis. The extent of hemolysis is directly proportional to virus concentration only when the virus-erythrocyte ratio is very low. At the higher virus-erythrocyte ratios usually employed in hemolysis experiments, the extent of hemolysis is proportional to the logarithm of the virus concentration. Thus, quantitative comparisons of hemolytic activities of different virus preparations cannot be made by directly comparing the extent of hemolysis. Relative hemolytic activities must be determined by comparing virus concentrations which yield equivalent amounts of hemolysis (the quantitative comparison procedure).     

Hemolytic Activity of a Togavirus,Getah*

A purified toga-alphavirus, Getah (GET), showed optimal hemolytic activity for one-day-old chick red blood cells when incubated at 37 C for 120 min at pH 6.2. Experimental data obtained from various angles, such as pH dependency, inhibition by virus-specific antiserum and by concanavalin A, indicated that the hemolysis was a property of the virus particle itself. Although the mechanism of hemolysis by togaviruses has not been known, our results indicated that viral lipids may participate in this activity since the hemolytic activity was impaired by delipidation procedures.     

Lipid vesicle-cell interactions. I. Hemagglutination and hemolysis

The interaction of lipid vesicles (liposomes) of several different compositions with erythrocytes has been investigated. Lecithin liposomes, rendered positively charged with stearylamine, exhibit potent hemagglutination activity in media containing low concentrations of electrolytes. The hemagglutination titer is found to be a linear function of the zeta potential of the lipid vesicles. Hemagglutination is reduced when the surface potential of the cells is made more positive by pH adjustment or enzyme treatment. Similarly, hemagglutination is reduced by increasing concentrations of electrolytes. Hemagglutination is examined theoretically and is shown to be consistent with vesicle-cell interactions that are due to only electrostatic forces. Vesicles containing lysolecithin in addition to lecithin and stearylamine cause lysis of erythrocytes, provided the lipids of the vesicles are above the crystal-liquid crystal phase transition temperature. In addition, hemolysis requires close juxtaposition of the vesicle to the cell membrane; vesicles precoated with antibodies exhibit severely diminished hemolytic activities, only a small fraction of which can be attributed to a reduction in hemagglutination titer. Evidence is presented indicating that a single vesicle is sufficient to lyse one cell. With regard to hemagglutination and hemolysis, lipid vesicles of simple composition mimic paramyxoviruses such as Sendai virus.     

Enhancement of influenza virus hemolysis by physical and serological treatments

The mode of hemolysis by influenza A virus was compared with that of Sendai virus. The WSN strain of influenza virus grown in either eggs or MDCK cells expressed hardly any hemolytic activity by itself. Treatment of the MDCK cell-grown WSN virus with sonication or freezing and thawing moderately enhanced the hemolytic activity, but the maximum level attainable was considerably lower than that of Sendai virus. A high level of hemolytic activity comparable to that of Sendai virus was obtained only after treatment of the virus with antibody and complement. An electron microscopic study revealed that non- or low-hemolytic WSN virions were not permeable to uranyl acetate stain in contrast with the hemolytic virions obtained after treatment with antibody and complement, indicating that the hemolytic virions had sustained some injury to their envelopes. These phenomena were comparable to those found with Sendai virus, showing that damage to the envelope is also responsible for the hemolysis of influenza virus. The influenza viruses, however, remained spherical after every treatment and the stain did not penetrate into the core of the virion. These observations suggest that the envelope of influenza virus is more rigid than that of Sendai virus but that the hemolytic process of influenza virus is nevertheless mediated through envelope-membrane fusion as in the case of Sendai virus.     

Trypsin Action on the Growth of Sendai Virus in Tissue Culture Cells II. Restoration of the Hemolytic Activity of L Cell-Borne Sendai Virus by Trypsin

Sendai virus grown in L cells (L Sendai) caused little hemolysis, whereas the one grown in fertile eggs (egg Sendai) induced distinct hemolysis. Enzymatic treatment with trypsin at low concentrations markedly enhanced the hemolytic activity of L Sendai but not that of egg Sendai. Both sonic treatment and freezing and thawing greatly enhanced the hemolytic activity of egg Sendai, but they gave little enhancing effect on that of L Sendai which could, however, be greatly increased by successive treatment with trypsin. Dose response and kinetic experiments on the trypsin effect have suggested that a similarity exists in the inhibitory mechanism of infectivity for L cells and hemolytic activity of L Sendai. Treatment of L cells with trypsin at later stages of infection released a highly hemolytic L Sendai from those cells. The present study, by reference to the density centrifugation studies in a previous report (4), has shown that a variation in infectivity for L cells and in the hemolytic activity of L Sendai is a type of host-controlled modification distinguishable from the density variation.     

Biologically active peptides of the vesicular stomatitis virus glycoprotein.

A peptide corresponding to the amino-terminal 25 amino acids of the mature vesicular stomatitis virus glycoprotein has recently been shown to be a pH-dependent hemolysin. In the present study, we analyzed smaller constituent peptides and found that the hemolytic domain resides within the six amino-terminal amino acids. Synthesis of variant peptides indicates that the amino-terminal lysine can be replaced by another positively charged amino acid (arginine) but that substitution with glutamic acid results in the total loss of the hemolytic function. Peptide-induced hemolysis was dependent upon buffer conditions and was inhibited when isotonicity was maintained with mannitol, sucrose, or raffinose. In sucrose, all hemolytic peptides were also observed to mediate hemagglutination. The large 25-amino acid peptide is also a pH-dependent cytotoxin for mammalian cells and appears to effect gross changes in cell permeability. Conservation of the amino terminus of vesicular stomatitis virus and rabies virus suggests that the membrane-destabilizing properties of this domain may be important for glycoprotein function.     

Relationship between the hemolytic action of heavy metals and lipid peroxidation

It is well known that some of the heavy metals have a hemolytic action, but the mechanisms responsible for this effect are not well established. In order to elucidate whether or not the hemolytic action of heavy metal ions is associated with the peroxidation of membrane lipids, the relationship between metal-induced hemolysis and the generation of malonaldehyde has been studied.The results obtained show that metal-induced hemolysis is associated with the development of peroxidative processes in erythrocyte membranes. The peroxidation is caused by metals with and without pro-oxidant catalytic action. The level of the malonaldehyde products rises before the appearance of hemolysis which proves that the development of peroxidative processes precedes but does not result from hemolysis.The suggestion has been made that the peroxidation of membrane lipids is a possible mechanism of damage to the red cell membrane in metal-induced hemolysis.     

Trifluoperazine inhibits Sendai virus-induced hemolysis

Sendai virus-induced hemolysis, a manifestation of virus-red cell fusion, is inhibited by exposure of the virus to 50 microM and higher concentrations of trifluoperazine. Trifluoperazine does not disrupt the virus, since trifluoperazine-treated virus with no hemolytic activity sediments slightly faster than untreated virus on sucrose density gradients and contains viral proteins in proportions characteristic of untreated virus. Trifluoperazine affects the fusion protein to a greater extent than the hemagglutinin, since trifluoperazine-treated virus with no hemolytic activity is as active or nearly as active in agglutinating red cells. The partition coefficient of trifluoperazine between the virus membrane and buffer is lower at 4 degrees C than, but the same at 37 degrees C, as that between the red cell membrane and buffer. Nevertheless, virus-independent red cell lysis and inactivation of virus-mediated hemolysis occur when the red cell and viral membranes, respectively, contain similar concentrations of trifluoperazine. Furthermore, 13-28% more trifluoperazine is necessary to achieve either effect at 4 degrees C or at 25 degrees C than at 37 degrees C. Changes in the surface activity of trifluoperazine do not explain these results, insofar as the critical micellar concentration of (0.75 mM) and maximal reduction in surface tension by (40 dyn/cm) trifluoperazine are the same at 25 degrees C and 37 degrees C. The fluorescence of viral tryptophan decreases by approx. 25% when viral hemolysis is inactivated by trifluoperazine, by trypsin treatment or by heating at 100 degrees C for 5 min.     

Studies on antiviral glycosides. II. Chemical modifications of the envelope of Sendai virus

Treatment of Sendai virus with p-azidophenyl-6-chloro-6-deoxy-beta-D-glucopyranoside (APG) caused chemical modification of the viral envelope under UV irradiation, which did not affect the hemagglutinin activity of the virus but inhibited the hemolytic activity. Also, the transfer of phospholipid from the viral envelope to chicken erythrocytes was measured using a spinlabel technique by electron spin resonance (ESR). In this experiment, the phospholipid transfer was depressed by the treatment with APG under the conditions which inhibited the hemolytic activity of the virus. These results suggest that APG bound covalently to lipid may disturb the specific interaction between the protein and the lipid of the viral envelope, resulting in the inhibition of the hemolytic activity. The effects of APG on the hemolysis and phospholipid transfer were compared with the results for the concanavalin A- and amphotericin B-treated viruses.     

Monoclonal anti-hemagglutinin antibodies detect irreversible antigenic alterations that coincide with the acid activation of influenza virus A/PR/834-mediated hemolysis.

Exposure of influenza virus to an acidic environment, which is known to be required for viral fusion and hemolysis, has recently been shown to induce a conformational change in the hemagglutinin molecule. In the present study, we examined the effects of acid incubation on the antigenicity, biological activity, and morphology of influenza virus A/PR/8/34 (H1N1). Incubation of PR8 virus at pH 5 in the absence of erythrocytes resulted in a rapid and irreversible loss of viral hemolytic activity and infectivity. Apart from a less distinct appearance of the viral surface projections and slight damage to the envelope structure, acid incubation did not result in gross morphological changes in the viral architecture. The acid-induced change could be detected in the form of greatly increased or decreased binding of many monoclonal antibodies directed to each of the four major antigenic regions of the hemagglutinin. Triggering of viral hemolytic activity and antigenic alterations was similarly pH dependent. In addition, the different pH dependencies of egg-grown and trypsin-treated MDCK-grown viruses coincided with an analogous pH dependence of the antigenic alterations that were observed with these viruses. These observations are compatible with the idea that some of the anti-hemagglutinin antibodies detect conformational changes in the hemagglutinin which are required for the initiation of fusion and hemolysis.     

Effect of Alcohol on Bacterial Hemolysis

Hemolysis of blood agar is broadly used as a diagnostic tool for identifying and studying pathogenic microorganisms. We have recently shown that alcohol vapors can confer hemolytic properties on otherwise nonhemolytic fungi (microbial alcohol-conferred hemolysis; MACH). Until now, this phenomenon has been found in various yeast strains and other fungi, but only in a few bacterial species (e.g., staphylococci). In the current study we (1) determined the extent of the above phenomenon in various Gram-positive and Gram-negative laboratory bacterial strains and in clinical bacterial isolates, (2) validated the observed hemolysis using a quantitative technique, and (3) provided evidence that the observed alcohol-mediated hemolysis may, at least in part, be related to synthesis of hemolytic lipids.     

Factors influencing variable oxidative hemolysis of inbred mouse erythrocytes

The hemolysis of erythrocytes from certain inbred mouse strains (e.g., BALB/c) in response to hydrogen peroxide stress has been shown to be correlated with the type of hemoglobin beta chain (Kruckeberg, W.C., et al. (1987) Blood 70, 909-914). The characteristic hemolytic response of BALB/c red cells to oxidative stress resembles that of human red cells in that carbon monoxide and iron chelators inhibit hemolysis of both. Gross hemoglobin oxidation rates were similar in hemolytic (BALB/c) and nonhemolytic (C57BL/6) strains. The rate and degree of in vitro catalase inhibition by sodium azide was also the same for the two strains. Even in the presence of this catalase inhibitor the assayable hydrogen peroxide disappeared within seconds of its addition, yet hemolysis was not observed for about 15 min. The mechanism underlying this delay between hydrogen peroxide addition and disappearance and subsequent hemolysis is under investigation.     

Mechanism of polymer-induced hemolysis: nanosized pore formation and osmotic lysis

Hemolysis induced by antimicrobial polymers was examined to gain an understanding of the mechanism of polymer toxicity to human cells. A series of cationic amphiphilic methacrylate random copolymers containing primary ammonium groups as the cationic functionality and either butyl or methyl groups as hydrophobic side chains have been prepared by radical copolymerization. Polymers with 0-47 mol % methyl groups in the side chains, relative to the total number of monomeric units, showed antimicrobial activity but no hemolysis. The polymers with 65 mol % methyl groups or 27 mol % butyl groups displayed both antimicrobial and hemolytic activity. These polymers induced leakage of the fluorescent dye calcein trapped in human red blood cells (RBCs), exhibiting the same dose-response curves as for hemoglobin leakage. The percentage of disappeared RBCs after hemolysis increased in direct proportion to the hemolysis percentage, indicating complete release of hemoglobin from fractions of RBCs (all-or-none leakage) rather than partial release from all cells (graded leakage). An osmoprotection assay using poly(ethylene glycol)s (PEGs) as osmolytes indicated that the PEGs with MW > 600 provided protection against hemolysis while low molecular weight PEGs and sucrose had no significant effect on the hemolytic activity of polymers. Accordingly, we propose the mechanism of polymer-induced hemolysis is that the polymers produce nanosized pores in the cell membranes of RBCs, causing an influx of small solutes into the cells and leading to colloid-osmotic lysis.     

Effect of ethanol on the hemolytic stability of erythrocytes

The stability of rabbit erythrocytes to hemolysis induced by different compounds in the presence or absence of ethanol or acetaldehyde has been analyzed. Ethanol slightly reduced erythrocyte stability against acidic hemolysis only after long-term preincubation, but the effect of ethanol on stability to oxidative hemolysis manifested itself immediately after its addition to the cells. Ethanol decreased both stability of cells to oxidative damage and dispersion of the hemolytic curve. Comparison of the effects of ethanol and acetaldehyde showed that the destabilizing effect of ethanol might be caused by either its direct action or the effect of its metabolites formed during preincubation of ethanol with erythrocytes. Possible mechanisms of ethanol and acetaldehyde effects on erythrocyte stability are discussed.     

Exploration of the correlation between the structure, hemolytic activity, and cytotoxicity of steroid saponins

The hemolytic activity of a collection of 63 steroid saponins was determined. The correlations between these structures and their hemolytic and cytotoxic activities are discussed. It has been demonstrated that the hemolytic activity of steroid saponins is highly dependent on their structures, that is, the sugar length, the sugar linkage, the substitutes on the sugar, as well as the aglycone. It has also been disclosed that the hemolytic activity and cytotoxicity of steroid saponins are not correlated. These results suggest that steroid saponins execute hemolysis and cytotoxic activity in different mechanisms, and encourage to develop steroid saponins into potent antitumor agents devoid of the detrimental effect of hemolysis.     

Quantitation of erythrocyte photohemolysis by light microscopy.

In a solution of erythrocytes and a photo-active compound, light activation of the compound produces hemolysis of the cells. This study describes a new assay in which focused light through a microscope is used to induce a circumscribed hemolysis of erythrocytes that have been mixed with fluorescein isothiocyanate-dextran 150,000 (FITC-DEX) and placed in a hemacytometer. The hemolytic response was monitored by detecting transmitted light intensity in the area (1.8 x 10(-4) cm2) of activation. Only cells within the specific microscopic field of activation hemolyze. This allows for multiple sites of activation within one sample. The hemolytic response was dependent on the concentration of FITC-DEX (0.5-4 mg/ml) and on light intensity (53-210 J/cm2) but not on small changes in hematocrit (3%-5%) or on the presence of platelets and leukocytes. Rabbit erythrocytes, however, were almost twice as sensitive as those from guinea pigs. Since the photohemolytic response will depend on the composition and strength of the erythrocyte membrane and presence of oxidant defense mechanisms, we suggest that this assay could be used to detect drug- or disease-induced changes in the red blood cell membrane.     

The mechanism of bile salt-induced hemolysis.

The hemolytic activities of sodium deoxycholate (DChol) and its tauro-conjugate (TDChol) and glyco-conjugate (GDChol) were analysed. 50 % hemolysis occurred in 30 min at pH 7.3, at the concentrations of these detergents equal to 0.044, 0.042 and 0.040 % respectively. These values are below their critical micellar concentrations. Based on its kinetics, this hemolysis is classified as being of permeability type. The detergents increase the permeability of erythrocyte membranes to KCl, and colloid osmotic hemolysis occurs. The minimum of hemolytic activity of the three cholates is at about pH 7.5. A very high increase in hemolytic activity occurs at pHs below 6.8, 6.5 and 6.2 for DChol, TDChol, and GDChol, respectively. These values are close to the pK(a) for DChol (6.2), but much higher than the pK(a) for TDChol (1.9) and GDChol (4.8). It is therefore suggested that the increase in hemolytic activity is not a result of the protonation of the anionic groups of the cholates. At acidification below pH 6, the kinetics of DChol induced hemolysis change to the damage type characterised by nonselective membrane permeability. Such a transition is not observed in TDChol and GDChol induced hemolysis. It is therefore suggested that the change in the type of hemolysis depends on protonation of the anionic group of cholates.     

pH-dependent hemolysis and cell fusion of rhabdoviruses

Human erythrocytes pretreated with fungal semialkali protease or trypsin became susceptible to hemagglutination by vesicular stomatitis virus (VSV) and rabies virus. Both viruses exhibited extensive hemolytic and fusion activities against erythrocytes pretreated with these enzymes. The hemolysis and fusion were pH dependent and the activities were most apparent at pH 5.0 and decreased with increase in pH. However, VSV still exhibited slight hemolytic activity at neutral pH. Hemolysis was also dependent on the dose of virus and was inhibited by treatment of the viruses with antiviral antibody. Results of sodium dodecyl sulfate polyacrylamide gel electrophoresis of erythrocyte membranes suggested that most of the carbohydrates were removed from the membrane proteins by the treatment with proteolytic enzymes.     

Hemolysis by aliphatic alcohols and saponin measured by the coil planet centrifugation method

Using the coil planet centrifugation method, the mechanism of hemolysis by alcohols and saponin was investigated. With this technique, erythrocytes are introduced into a gradient of hemolytic agents in saline, which is prepared in a long coiled polyethylene tube. The tube is centrifuged so that the cells move from a low to a high concentration of hemolytic agent. When the cells lyse, they release hemoglobin which remains stationary, and therefore hemolytic potency can be determined spectrophotometrically by the distance the cells move before lysing. We found that alcohols caused hemolysis at a particular concentration, whereas saponin-induced hemolysis was dependent on the amount of saponin accumulated in the environment of the cell. In addition, alcohols with longer carbon chains were more potent hemolytic agents than those with shorter chains, but each additional carbon group produced less of an increase in hemolysis per mole of alcohol. This chain-length dependency is consistent with a previous study on in vivo alcohol-induced hemolysis. The coil planet centrifugation method is also adaptable to comparative studies on the mechanism of other types of hemolysis, such as immune or drug-induced lysis, and to toxicological studies.     

Reconstitution of functional influenza virus envelopes and fusion with membranes and liposomes lacking virus receptors.

Reconstituted influenza virus envelopes were obtained following solubilization of intact virions with Triton X-100. Quantitative determination revealed that the hemolytic and fusogenic activities of the envelopes prepared by the present method were close or identical to those expressed by intact virions. Hemolysis as well as virus-membrane fusion occurred only at low pH values, while both activities were negligible at neutral pH values. Fusion of intact virions as well as reconstituted envelopes with erythrocyte membranes--and also with liposomes--was determined by the use of fluorescently labeled viral envelopes and fluorescence dequenching measurements. Fusion with liposomes did not require the presence of specific virus receptors, namely sialoglycolipids. Under hypotonic conditions, influenza virions or their reconstituted envelopes were able to fuse with erythrocyte membranes from which virus receptors had been removed by treatment with neuraminidase and pronase. Inactivated intact virions or reconstituted envelopes, namely, envelopes treated with hydroxylamine or glutaraldehyde or incubated at low pH or 85 degrees C, neither caused hemolysis nor possessed fusogenic activity. Fluorescence dequenching measurements showed that only fusion with liposomes composed of neutral phospholipids and containing cholesterol reflected the viral fusogenic activity needed for infection.