Hemolysis of elasmobranch erythrocytes in urea solutions: effect of temperature

Skate and stingray cells were shown to hemolyze in isosmotic solutions containing urea as the sole solute. The rate of urea penetration into these cells as determined by the rate of hemolysis is highly temperature dependent with a Q₁₀ of 2.50–2.75. A reduced rate of methylurea penetration in the presence of urea was reconfirmed. The present results are consonant with the hypothesis of carrier mediated transport of urea in elasmobranch erythrocytes previously proposed by Murdaugh, Robin and Hearn.     

The tonicity-volume relations for systems containing human red cells and the chlorides of monovalent cations

1. Differences in the fragility of human red cells are observed in equimolar solutions of the chlorides of the monovalent cations. The cells are most fragile in LiCl and least fragile in NaCl, the salts falling in the order Li > K >== Rb > Cs > Na. 2. The difference between the tonicity-volume relations in systems containing LiCl and systems containing NaCl lies in the molarity of the solution of LiCl which is isotonic (isoplethechontic) with plasma being considerably greater (0.189 M) than the molarity of the solution of NaCl which is isotonic (isoplethechontic) with plasma (0.160 M). The difference cannot be stated meantime in any simpler terms than these; if the activity coefficients are taken into account, it becomes even greater. The tonicity-volume relations for the two systems are otherwise almost identical; the value of R for the two systems is almost the same, the critical volumes at which the cells of least resistance hemolyze are almost identical, and the critical volumes at which the cells of average resistance hemolyze are almost identical. 3. The LiCl effect on volume occurs as soon after the addition of the cells to 0.172 M LiCl as the hematocrit method allows one to measure it. It is reversible by washing with 0.172 M NaCl.     

Stability of membrane pores in hypotonically dialyzed erythrocytes: coencapsulation of different stokes radius probes can occur for at least 21 days in human erythrocytes

Hypotonic dialysis of human erythrocytes results in porous cell stability for several days. Hypotonic cells stored for 1 week are essentially normal with respect to the preparation of carrier erythrocytes. Afterward, cells begin to irreversibly hemolyze resulting in decreased cell recoveries and decreased encapsulation percentages of two probes, sucrose and inulin. The holes generated by controlled hypotonic dialysis (100 mOsm/kg) are unlike the single rupture hole generated by dialysis to 10-20 mOsm/kg. The minimum pore size of resealed, annealed carrier cells is confirmed to be less than 5.2 A.     

Use of vitamin E deficient red cells to detect a dialyzable hemolytic factor produced by peroxidizing rat liver microsomes.

The tendency of rat red blood cells to hemolyze in the presence of peroxidizing rat liver microsomes is greatly increased if the red cells are obtained from vitamin E deficient rats. Adequate dietary vitamin E supplementation imparts resistance against hemolysis. Dietary butylated hydroxytoluene or the level of erythrocyte glutathione or total thiols are relatively unimportant factors in determining red cell sensitivity to hemolysis induced by perixiziding microsomes. When separated from peroxidizing microsomes by a dialysis membrane, vitamin E deficient cells are completely hemolyzed. Hemolytically active material can be separated from peroxidized microsomes by dialysis at 0°C.     

THE PARACRYSTALLINE STATE OF THE RAT RED CELL

When washed rat red cells are kept in 3 per cent sodium citrate at low temperatures (4–9°C.), their resistance to osmotic hemolysis increases so that after several days they swell very little in hypotonic solutions (R = 0.15 to zero) and do not hemolyze even in distilled water. In this and in other respects they behave as if they were gelated or paracrystalline. The paracrystalline state is reversible, disappearing when the cells are warmed and rapidly reappearing when they are cooled, and the resistance to hypotonic hemolysis is not due to the cells reaching equilibrium with their environment by losing so much K that the concentrations become equal inside and out. The concentration of K remains about 25 times as great inside the cell as outside it in a hypotonic medium of T = 0.1, and the failure to swell and to hemolyze seems to be due to the activity of K in the interior of the paracrystalline cell approaching zero. The paracrystalline red cells are more resistant to saponin and digitonin hemolysis, and do not undergo the usual shape transformations, probably because they are too rigid. Hemolysis by saponin and similar lysins occurs without sphere formation, and after lysis is complete a granular debris is left behind. The paracrystalline cells show a diffuse birefringence with polarized light; on their being warmed, the birefringence disappears except at foci which are usually situated along the rim of the cell. The occurrence of the paracrystalline state accounts for the different amounts of swelling of red cells which have been observed in systems of the same degree of hypotonicity, and its relation to other metastable states of the red cell is discussed in connection with a tabulation of the metastable states of the mammalian red cell and their relation to one another. Changes in a membrane alone seem inadequate to account for the varied phenomena observed in connection with red cell behavior, the explanation of which appears to require a more detailed knowledge of the molecular architecture of the cell interior.     

Fusion of chicken erythrocytes by phospholipase C (Clostridium perfringens): The requirement for hemolytic and hydrolytic factors for fusion

Phospholipase C (Clostridium perfringens) preparations are able to induce fusion of chicken erythrocytes only in the presence of low concentrations (0.6 mM) of Mn²⁺. Anti-phospholipase C serum inhibits hemolysis and fusion of the cells only when added during the first 20 min of the incubation time. Heated phospholipase C preparations which fail to hemolyze chicken erythrocytes are able to induce fusion only in the presence of another hemolytic reagent such as prymnesin (an hemolytic toxin from Prymnesium parvum).     

Tissue hemolysins as lysin-inhibitor complexes

1. Lytic substances are enzymatically produced at 37°C. from tissue slices or homogenates (mouse liver, kidney, etc.) and appear in the medium in which the tissue fragments are suspended. Their concentration increases with the time during which the tissue is kept at 37°C. (preincubation), and is accompanied by pH changes, so that the lytic activity as finally measured is a function of both the time of preincubation and of the pH. The optimum pH for lysin production is above 7.0, but the lysins, once produced, hemolyze red cells more rapidly at low pH's than at high ones. The enzyme system which produces the lysins is inactivated by heating to 100°C. for 5 minutes. Sodium iodoacetate and fluoride interfere with lysin production principally by reducing the concomitant pH shift; KCN accelerates the production of lytic material in mouse liver homogenates. 2. Comparison of the lytic activity of the supernatant fluid of a preincubated homogenate with the much greater lytic activity of the substances which can be extracted from the same supernatant fluid by alcohol and ether points to these extractable substances existing in the supernatant fluid as lysin-inhibitor complexes of relatively low lytic activity. These complexes are formed enzymatically during preincubation from non-lytic complexes in the tissue. The latter may be lipoproteins, and the highly lytic ether-extractable substances may be fatty acids or their soaps. 3. The diffusibility of the lysin-inhibitor complexes is small. 4. Lytic substances which are ether-insoluble can be extracted with alcohol from tissues as well as from serum. These "lysolecithin-like" substances exist in the supernatant fluids of homogenates as lysin-inhibitor complexes. 5. Lysis of mouse red cells by substances contained in mouse tissue (liver and kidney) is often accompanied by the formation of methemoglobin and choleglobin. Mouse red cells containing choleglobin are abnormally fragile both osmotically and mechanically, and it is possible that a process involving the production of choleglobin, accompanied or followed by globin denaturation, is one which contributes towards the hemolysis which occurs in systems containing tissue slices or homogenates.     

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.     

Superoxide anion as a mediator of drug-induced oxidative hemolysis.

The superoxide dismutase inhibitor diethyldithiocarbamate (DDC) was utilized to study the toxic effect of 1,4-naphthoquinone 2-sulfonate (NQ), a structural analog of the hemolytic drug, menadione, on red cells. NQ was shown to react with hemoglobin and result in the generation of superoxide anion (O2-). Red cells treated with NQ were found to undergo a gradual disappearance of their oxyhemoglobin and also hemolyze. Red cells pretreated with DDC to inhibit cellular superoxide dismutase were found to be markedly sensitive to oxyhemoglobin destruction and hemolysis in the presence of NQ. Superoxide dismutase-inhibited red cells were also found to undergo a slow autohemolysis in the absence of NQ. No evidence for lipid peroxidation was obtained for red cells treated with NQ either in the presence or the absence of DDC. Ghosts prepared from superoxide dismutase-inhibited red cells exposed to NQ were found to retain a green hemoglobin-derived pigment.     

Effect of potassium chloride on the uptake and storage of phosphate by Saccharomyces mellis

The inorganic and polyphosphate pools of Saccharomyces mellis, grown in a medium containing excess phosphate, remain associated with the cells when the cells are suspended in a saline medium. If the cells are incubated in a medium containing 2 m KCl, the cells are altered in some manner which permits most of the orthophosphate and approximately one-third of the polyphosphate to be subsequently eluted by osmotic shock. At lower salt concentrations, beta-mercaptoethanol enhances this salt effect but is inactive by itself in this respect. At equivalent ionic strengths, the sodium salt of ethylenediaminetetraacetic acid behaves exactly like KCl or any other monovalent ionic compound in altering the cell to susceptibility to osmotic shock. No special effect of this anion at either high or low concentration could be detected. Resting cells are refractory to being altered in this manner by salts if an energy source, such as glucose, is included in the reaction mixture. Cells which are depleted of phosphate reserves will immediately incorporate phosphate when suspended in a medium containing inorganic phosphate and an energy source. These cells exhibit the phenomenon of "überkompensation." In resting cells, the inclusion of KCl in the reaction mixture prevents the conversion of orthophosphate into polyphosphate and, also, gradually decreases the ability of the organism even to assimilate orthophosphate. This effect is reversible, however, since the cells will incorporate phosphate in a normal manner if the cells are transferred to a non-salinized medium, or if a nitrogen source is included in the salinized reaction mixture so that the cells are now in a medium adequate for growth.     

IADS, a decomposition product of DIDS activates a cation conductance in Xenopus oocytes and human erythrocytes: new compound for the diagnosis of cystic fibrosis.

DIDS (4,4'-diisothiocyanato-stilbene-2,2'-disulfonic acid) is a commonly used blocker of plasma membrane anion channels and transporters. We observed that DIDS undergoes decomposition while stored in DMSO (dimethyl sulfoxide) forming a biologically active compound. One decomposition product, called IADS, was identified and synthesized. Voltage-clamp and patch clamp experiments on Xenopus laevis oocytes and human erythrocytes revealed that IADS is able to activate a plasma membrane cation conductance in both cell types. Furthermore, we found that IADS induces hemolysis in red blood cells of healthy donors but fails to hemolyze erythrocytes of donors with cystic fibrosis. Thus, IADS stimulated activation of a cation conductance could form the basis for a novel diagnostic test of cystic fibrosis.     

The dielectric permittivity at radio frequencies and the bruggeman probe: novel techniques for the on-line determination of biomass concentrations in plant cell cultures

A novel technique is described for the measurement of the volume fraction of biomass in a suspension by the simultaneous measurement of the conductivity of a suspension containing cells and of the medium in which the cells are suspended. The presence of non-conducting particulate matter in a suspension will cause the conductivity of a suspension to be decreased relative to that of the medium in which the particles are suspended. A simple equation (the Bruggeman equation) describes the relationship between the volume fraction of non-conducting particulate matter and the decrease in conductivity. The accuracy of this method for the determination of the biomass concentration of plant cells (Festuca arundinacea) in culture was shown. The method was successfully applied to the on-line determination of biomass concentrations during the growth of F. arundinacea cultures, and gave good agreement with biomass levels as determined from measurements of the radio-frequency dielectric permittivity of such cultures.     

Synthesis of immunoglobulin by substrate attached mouse myeloma cells

Cultured mouse myeloma cells grow in suspension and synthesize and secrete large amounts of immunoglobulin. Mouse myeloma cells which attach to a plastic substratum have been obtained by mutagenesis and subsequent selection. Normal mouse myeloma cells will also attach to plastic tissue culture dishes pre-treated with poly-L-lysine. The attached cells synthesize and secrete the same large amounts of immunoglobulin as the suspended cells.     

Survivals of mouse oocytes approach 100% after vitrification in 3-fold diluted media and ultra-rapid warming by an IR laser pulse

Vitrification is the most sought after route to the cryopreservation of animal embryos and oocytes and other cells of medical, genetic, and agricultural importance. Current thinking is that successful vitrification requires that cells be suspended in and permeated by high concentrations of protective solutes and that they be cooled at very high rates to below −100 °C. We report here that neither of these beliefs holds for mouse oocytes. Rather, we find that if mouse oocytes are suspended in media that produce considerable osmotic dehydration before vitrification and are subsequently warmed at ultra high rates (10,000,000 °C/min) achieved by a laser pulse, nearly 100% will survive even when cooled rather slowly and when the concentration of solutes in the medium is only 1/3rd of standard.     

Perfusion culture apparatus for suspended mammalian cells

A variety of processes have been proposed for mammalian cell culture in the commercial production of useful substances (e.g., monoclonal antibodies, therapeutic and diagnostics proteins). Among them, the perfusion culture of suspended non-immobilized cells is the most advantageous. Perfusion culture can be classified by the separation process of suspended cells from the culture mixture into three types, namely filtration, gravitational settling and centrifugation. From a commercial point of view, the present situation and technical problems of suspended-cell perfusion culture will be reviewed based on the three types, The recent development of perfusion culture has been carried out mainly on the filtration separation process, but the centrifugation process seems to have a promising future because of operation stability and scale-up feasibility. The reasons will be explained in details.     

基于AFM单细胞力谱技术的淋巴瘤细胞黏附力测量

细胞黏附在细胞生理功能中起着重要的调控作用,对细胞黏附行为进行定量研究有助于理解生命活动内在机制.原子力显微镜（AFM）的出现为研究溶液环境下微纳尺度生物系统的生物物理特性提供了强大工具,特别是AFM单细胞力谱（SCFS）技术可以对单细胞黏附力进行测量.但目前利用SCFS技术进行的研究主要集中在贴壁细胞,对于动物悬浮细胞黏附行为进行的研究还较为缺乏.本文利用AFM单细胞力谱技术（SCFS）对淋巴瘤细胞黏附行为进行了定量测量.研究了淋巴瘤细胞与其单克隆抗体药物利妥昔（利妥昔单抗与淋巴瘤细胞表面的CD20结合后激活免疫攻击）之间的黏附力,分析了利妥昔浓度及SCFS测量参数对黏附力的影响,并对淋巴瘤细胞之间的黏附力进行了测量.实验结果证明了SCFS技术探测动物悬浮细胞黏附行为的能力,加深了对淋巴瘤细胞黏附作用的认识,为单细胞尺度下生物力学探测提供了新的可能.     

Cytodifferentiation and tissue phenotype change during transformation of embryonic lens epithelium to mesenchyme-like cells in vitro

A number of adult and embryonic epithelia, when suspended within native type I collagen gels, give rise to elongate bipolar cells that migrate freely within the three-dimensional matrix. The morphology of these newly formed mesenchyme-like cells is indistinguishable from "true" mesenchymal cells at the light and ultrastructural level. In this report, we extend previous observations on the transformation of embryonic avian lens epithelium to mesenchyme-like cells. Lens epithelia, dissected from 12-day chick embryos, were cultured either within a collagen matrix or on a two-dimensional surface. Cells derived from explants on the surface of type I collagen express the epithelial phenotype. The cells form new basal lamina, continue to express delta-crystallin protein and secrete both type IV collagen and laminin. In contrast, epithelia suspended within collagen gels lose epithelial morphology, phenotype, and cytodifferentiation. The newly formed mesenchyme-like cells lack the ability to synthesize lens-specific delta-crystallin protein, type IV collagen, and laminin. They do, however, express type I collagen de novo, a characteristic of mesenchymal cells. The changes in cytodifferentiation and tissue phenotype which occur during the transformation are stable under the conditions studied here. When mesenchyme-like cells are removed from the gel and replated onto two-dimensional surfaces, they remain bipolar, will invade collagen matrices, and are unable to synthesize delta-crystallin protein.     

Crystal structure determination of basic phospholipase A_2 from venom of Agkistrodon halys pallas by molecular replacement method

Basic phospholipase A2 (BPLA2) from the venom of Agkistrodon halys pallas has a strong ability to hemolyze erythrocytes. The asymmetrical unit of P212121 crystal of BPLA2 contains two molecules. Self-rotation function was used to study the orientation relationship of these two molecules. Cross-rotation and translation functions were then used to determine the orientations and positions of the two molecules in the unit cell. The model building and preliminary structure refinement were carried out. The result shows that the two molecules in the asymmetrical unit of orthorhombic crystal are related by a non-crystallographic 2-fold symmetry axis.     

Epithelial cells fluidize upon adhesion but display mechanical homeostasis in the adherent state

Atomic force microscopy is used to study the viscoelastic properties of epithelial cells in three different states. Force relaxation data are acquired from cells in suspension, adhered but single cells, and polarized cells in a confluent monolayer using different indenter geometries comprising flat bars, pyramidal cones, and spheres. We found that the fluidity of cells increased substantially from the suspended to the adherent state. Along this line, the prestress of suspended cells generated by cortical contractility is also greater than that of cells adhering to a surface. Polarized cells that are part of a confluent monolayer form an apical cap that is soft and fluid enough to respond rapidly to mechanical challenges from wounding, changes in the extracellular matrix, osmotic stress, and external deformation. In contrast to adherent cells, cells in the suspended state show a pronounced dependence of fluidity on the external areal strain. With increasing areal strain, the suspended cells become softer and more fluid. We interpret the results in terms of cytoskeletal remodeling that softens cells in the adherent state to facilitate adhesion and spreading by relieving internal active stress. However, once the cells spread on the surface they maintain their mechanical phenotype displaying viscoelastic homeostasis.     

Glycolysis of red cells suspended in solutions of impermeable solutes. Intracellular pH and glycolysis.

The glycolytic rate human red cells suspended in a sucrose medium of low or physiological pH was higher than that of the cells suspended in Ringer's medium of the same. pH. The medium pHP-glycolytic rate curve of red cells suspended in soucrose media shifted to the acidic side by about one unit compared with that of cells suspended in Ringer's medium. Similarly, the pattern of glycolytic intermediates in red cells suspended in a sucrose medium resembled that in cells suspended in Ringer's solution of about one unit higher pH. These phenomena could be ascribed to the change of intracellular pH, which was measured by the 5,5'-dimethyl-oxazolidine-2,4-dione method. A similar stimulation of glycolysis was observed when sodium citrate was added to red cells suspended in Ringer's solution at constant pH. These observations indicate that membrane-impermeable non-electrolytes or anions stimulate glycolysis of red cells by elevation ofthe intracellular pH. Red cell glycolysis is influenced mainly by the intracellular pH rather than by the pH of the suspending medium.