Carrier erythrocytes from cattle can be prepared from cells stored in a hypotonic, porous, dialyzed state

Hypotonic dialysis of bovine erythrocytes to 160-180 mosmol/kg produces cells with metastable pores. Cells stored for 3 weeks in a hypotonic dialyzed state can be used to prepare carrier erythrocytes. Pores generated by nonlytic hypotonic conditions are initially greater than 40 A in radius but shrink to less than 20 A with storage beyond 1 week. A metastable pore allows for hemoglobin isolation from hypotonically dialyzed cells.     

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.     

Macromolecular covalent binding of [14C]nitrobenzene in the erythrocyte and spleen of rats and mice

Nitrobenzene exposure is known to produce red blood cell damage as well as engorgement and sinusoidal congestion of the spleen in male Fischer-344 (F-344) rats but not in male B6C3F1 mice. These studies were conducted to investigate the species differences in the covalent binding of [¹⁴C]nitrobenzene in the erythrocyte and spleen and to assess the contribution of nitrobenzene-induced erythrocytic damage to the splenic effects. Total and covalently bound ¹⁴C concentrations in erythrocytes of rats were 6–13 times greater than those of mice following a single oral dose of 75, 150, 200 or 300 mg/kg [¹⁴C]nitrobenzene, suggesting that species differences in nitrobenzene-induced red blood cell toxicity may be related to differences in erythrocytic accumulation of nitrobenzene and its metabolites. Covalently bound ¹⁴C in erythrocytes of rats peaked 24 h following administration of 200 mg [¹⁴C]nitrobenzene/kg; in contrast, bound radio-label in erythrocytes from mice plateaued at 10 h. Splenic engorgement increased in a time-related manner in treated rats but not in mice. Species specificity was also observed in the accumulation of bound radiolabel in the spleen. Gel filtration and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of lysed, dialyzed erythrocytes from treated rats revealed that hemoglobin was the primary, if not the exclusive, site of macromolecular covalent binding following nitrobenzene treatment. SDS-PAGE of dialyzed rat spleens revealed that 82% of total bound ¹⁴C migrated identically to hemoglobin. These data indicate that covalent binding of [¹⁴C]nitrobenzene and its metabolites in the spleen is primarily derived from bound ¹⁴C from scavenged erythrocytes. Therefore, the species differences in splenic engorgement and accumulation of [¹⁴C]nitrobenzene may be related to differences in susceptibility to nitrobenzene-induced red blood cell damage.     

Some effects of the trypanocidal drug isometamidium on encapsulation in bovine carrier erythrocytes

Bovine erythrocyte exposure to isometamidium chloride causes increased osmotic fragility. Control cells tolerated up to 1 mg/ml drug with no effects. Carrier erythrocytes were highly susceptible to drug, with increased osmotic fragility and decreased encapsulation potential of sucrose and inulin. Scanning electron micrographs of control and carrier erythrocytes exposed to drug revealed the formation of enkephalocytes with carrier erythrocytes. Control erythrocytes showed greater tolerance to the drug. Apparently, access of the drug to the interior of the erythrocyte membrane allows the drug to be more interactive with the membrane.     

The molecular configuration of inulin: Implications for ultrafiltration theory and glomerular permeability

Summary A space-filling model of the inulin molecule, based solely on physico-chemical data in the literature, indicates that the gross shape of the solvated molecule is a cylinder having semi-length 25 Å and radius 10 Å. The axial dimensions of this model very nearly equal the equivalent estimates (25 and 10.5 Å) previously determined by studying restricted passage of inulin through artificial membranes of known pore size (E. Middleton,J. Membrane Biol. 20:347, 1975). The good agreement between these independentin-vitro studies-neither of which depends on ultrafiltration theory-strongly suggests that glomerular pore size is considerably greater than predicted by the theory.     

Passage of inulin and p-aminohippuric acid through artificial membranes: implications for measurement of renal function.

Diffusion of inulin and p-aminohippuric acid (PAH) in combined aqueous solution through artificial membranes was measured at room temperature and atmospheric pressure. The membranes had pore diameters of 26, 50, 100, 200, 250, 350, 510 or 990 A. The diffusion of PAH was only restricted with a pore size of 26 A, but inulin diffusion was restricted at 100 A. When diffusion of both solutes was unrestricted (pore diameter greater than or equal to 200 A), PAH diffused four times faster than inulin, and in restricted situations this ratio was even greater. The results of these diffusion studies allow the major and minor molecular dimensions of the solutes to be estimated. Filtration of the two solutes was studied in slowly flowing situations and also with increased temperature and pressure. Pore sizes required for unrestricted filtration were the same as for unrestricted diffusion but the passage ratio was reduced from 4 to 2. These results suggest strongly that two conditions are necessary if the glomerular filtration rate (GFR) of inulin is to equal the true GFR: membrane pore size must be at least 200 A and passage through the membranes must be by bulk transport.     

Gel chromatography on a Sepharose 4B column: earlier elution of protein-sodium dodecyl sulfate complexes of low Stokes radii

A procedure is described for the determination of the Stokes radius of a detergent micelle by gel chromatography. It was observed that different lots of Sepharose 4B can exhibit a wide variation in the permeation of their gel pores. It is shown that this variation is due to differences in their pore size distribution. It has been observed that protein-sodium dodecyl sulfate (SDS) complexes of high Stokes radii eluted on a Sepharose 4B column with Stokes radii lower than the theoretical, as it has been previously reported but that protein-SDS complexes of low Stokes radii (less than 70 A), contrary to what might have been expected, eluted with Stokes radii higher than the theoretical. Evidence was obtained that their anomalous elution is due to an interaction of the detergent SDS with the gel pores of small diameter.     

Effect of moderately low temperatures (-30 C to -70 C) on the permeability of erythrocyte membranes

The barrier properties of reconstituted and native erythrocyte membranes frozen to -30, -40 or -70 degrees C and stored for a month were studied. The release of markers, namely haemoglobin molecules, [14C] sucrose and K+ ions from cells and membrane structures was measured. The main changes in the barrier function of ghosts and cells have been found to be due to freeze-thawing rather than to storage conditions. Glycerol, a cryoprotectant, appeared to stabilize the barrier properties of erythrocyte membranes for haemoglobin molecules, [14C] sucrose and to a lesser extent for K+ ions. The cryoprotective effect of glycerol has been shown to be considerably greater towards erythrocytes ghosts than to native erythrocytes.     

对地贫红细胞的显微激光散射和图象分析

应用显微准弹性激光散射(MQLS)技术与显微生物医学图象分析技术对地中海贫血红细胞及胞内血红蛋白动态特性进行了研究.在实验中,比较了正常人及地贫患者红细胞胞内血红蛋白聚集体的平均流体力学半径、平均平动扩散系数及红细胞膜的搏动频率等动态特性参数,以及细胞的截面积、规化形状因子、长径、短径、灰度等图象分析数据,发现地贫红细胞的血红蛋白聚合物平均流体力学半径远远大于正常人红细胞的,其大小变异亦较正常人大,且其膜搏动频率也较为缓慢,细胞的截面积也变小.这反映了地贫红细胞内有较大的蛋白质聚合物存在和红细胞变形能力差的特性.研究还表明,显微准弹性激光散射技术结合图象分析技术,可使测量的可比性和准确性大大提高,预期可广泛适用于各种活细胞动态特性的研究.     

Filtration,diffusion, and molecular sieving through porous cellulose membranes

1. A study has been made of the diffusion and filtration of a graded series of molecules (including tritium-labelled water, urea, glucose, antipyrine, sucrose, raffinose, and hemoglobin) in aqueous solution through porous cellulose membranes of three degrees of porosity. 2. Experimental results were in close agreement with predictions based on the membrane pore theory of Pappenheimer et al. (1,2). Restriction to molecular diffusion is a function of pore radius and molecular radius described by equation (11) in the text. Molecular sieving during ultrafiltration is a function of total pore area per unit path length, pore radius, molecular radius, and filtration rate given by equations (16) and (19). 3. Estimates of average pore radius made by means of this theory were considerably larger than estimates made by the method of Elford and Ferry (3) (Table II). Sources of error in the latter method are discussed and a new method of membrane calibration is proposed in which the total cross-sectional area of the pores is measured by direct diffusion of isotope-labelled water. 4. Steady-state osmotic pressures of solutions of sucrose and raffinose measured during molecular sieving through cellulose membranes were found to be close to the "ideal" osmotic pressures calculated by van't Hoff's law. Thus the present experimental data support the methods used by Pappenheimer et al. in their studies on living capillary walls as well as their theory of membrane pore permeability.     

Direct measurement of the internal viscosity of sickle erythrocytes as a function of cell density

The rotational dynamics of TEMPAMINE can be used to study directly the intracellular environment. The extracellular signal from TEMPAMINE is broadened away by the use of potassium ferricyanide which does not enter the cell. The EPR signal which results when 1 mM TEMPAMINE, 120 mM ferricyanide, and erythrocytes are mixed together arises from TEMPAMINE only in the intracellular aqueous space. The relative viscosity measured by the motion of TEMPAMINE in various control environments is: water at 37 degrees C = 1; human plasma at 37 degrees C = 1.1; internal aqueous environment of washed erythrocytes or whole blood at 37 degrees C = 4.92 +/- 0.32. Erythrocytes can be fractionated by density. In sickle-cell anemia (SS), the percentage of cells we find with density greater than 1.128 g/ml is 15-40%, in normals (AA) and sickle trait (AS) 1%. By direct spin-label measurements with TEMPAMINE we show, for the first time, that the relative internal viscosity (eta mu) of these dense erythrocytes is markedly elevated and density-dependent. Our results show that (1) eta mu increases with increasing cell density; (2) eta mu obtained from sickle cells is higher than eta mu obtained from normal cells at a given density, and this effect is greater at 37 degrees C than at 20 degrees C; (3) eta mu is proportional to MCHC, but eta mu in erythrocytes is higher than eta mu obtained from in vitro preparations of hemoglobin S at equivalent concentrations. We conclude that the relative internal viscosity of erythrocytes is affected by three factors: the state of cell hydration, the amount of hemoglobin polymer present, and the potential interactions of the cell membrane with intracellular hemoglobin.     

Comparative study of production of dextransucrase and dextran by cells of Leuconostoc mesenteroides immobilized on Celite and in calcium alginate beads

In fed-batch fermentation, cells of L. mesenteroides immobilized on three types of Celite were used to produce dextransucrase (DS) followed by production of dextran. A layer of calcium alginate on the porous Celite R630 particles improved their mechanical stability, increased the amount of soluble DS produced and decreased the cell leakage from the highly porous support. Enzyme production with the immobilized cell cultures was significantly affected by both pore and particle size. Immobilized cultures using Celite R648 (average particle radius of 200 mum and pore size of 0.14 mum) produced the highest total enzymatic activity, followed by Celite R633, alginate-coated Celite R630, Celite R630, and then calcium alginate beads. Culture of free cells produced about 18% more total enzymatic activity than immobilized cells in calcium alginate beads, but about 64% less than immobilized cells on Celite R630. It is expected that larger amounts of enzymatic activity than measured are immobilized inside the alginate-coated Celite R630 and calcium alginate beads due to the mass transfer limitation conferred by the dextran product formed therein. The dextran yield from conversion of sucrose to dextran and fructose with all such enzyme-enriched, immobilized-cell cultures was higher than that obtained from free-cell culture under similar conditions.     

Biochemical properties of inulosucrase from Leuconostoc citreum CW28 used for inulin synthesis

Biochemical properties of inulosucrase from Leuconostoc citreum CW28, a potential biocatalyst for inulin synthesis, were determined in order to select optimal reaction conditions. The hydrolysis reaction was about 3.5 times more efficient than the transferase reaction. It was found that high sucrose concentrations (≈250 g L^-1) were required for maximum fructose transferase yields. High molecular weight inulin distributions were obtained with cell associated inulosucrase, while lower size products were associated to the activity of the free enzyme in solution. When using whole cells, mannitol was found as a by-product of the reaction resulting from the reduction of fructose released by sucrose hydrolysis. A 30 L pilot plant synthesis with 250 g L^-1 of sucrose was carried out using the cell associated inulosucrase resulting in 76% of the substrate being transformed to inulin.     

A study of nucleated erythrocytes by density-gradient centrifugation in a zonal rotor

1. Several substances of high molecular weight were examined for their suitability as suspension media in the formation of density gradients for the zonal centrifugation of avian erythrocytes. None proved satisfactory. 2. The behaviour of pigeon erythrocytes in rate-sedimentation experiments in a type A zonal rotor with density gradients of sucrose was examined. The mature cells sediment more rapidly than the younger cells and have a lower RNA/DNA ratio. Maturation is accompanied by a greater loss of RNA from the nucleus than from the cytoplasm. 3. The base composition of the nuclear RNA and of the two species of cytoplasmic ribosomal RNA is reported. 4. The RNA of erythrocytes may be labelled in vivo by injection of inorganic [(32)P]phosphate. The cells most active in the synthesis of RNA sediment less rapidly than the bulk of the cells. 5. Reticulocyte nuclei sediment more slowly than those from erythrocytes. Reticulocyte nuclei have a mean volume of 35mu(3) and are isopycnic with sucrose of density 1.2871 (measured at 20 degrees ). Maturation of the nuclei causes them to shrink to a volume of 25mu(3) and the density to increase to 1.2944.     

Glomerular and postglomerular transcapillary exchange in dog kidney

The multiple-indicator dilution technique (MIDT) was used to study glomerular and postglomerular permselectivity to neutral dextran molecular weight markers in anesthetized dogs undergoing mannitol diuresis. Renal vein and urine outflow curves were obtained after an intraarterial pulse injection of 125I-labeled albumin (plasma reference), creatinine (extracellular reference), [14C]inulin, and chromatographically homogeneous 3H-labeled neutral dextrans. The urine recovery data reflect solute losses across the glomerulus. The renal vein outflow curves contain information about both glomerular and postglomerular extraction. For dextrans less than 13,500 daltons the urine transit pattern was superimposed on the glomerular markers creatinine and inulin. Relative to 125I-labeled albumin, the renal vein recoveries for creatinine, inulin, and dextrans (less than 13,500 daltons) were all equal. The renal vein mean transit time (tdextran) was greater than talbumin and less than tcreatinine. With increasing dextran size, tdextran progressively decreased. Eventually for dextrans greater than 15,500 daltons, tdextran became equal to talbumin in the renal vein, whereas urine recovery relative to inulin decreased with increasing size. Urine recovery of 3H-labeled dextran (ED) relative to inulin (Ei) provided a measure of unidirectional fractional glomerular extraction (ED/Ei). Constant infusion fractional clearance measurement of the same dextrans [U/P)D/(U/P)i) was found to equal ED/Ei obtained from the MIDT. Within the autoregulatory range of glomerular filtration, ED/Ei was invariant with reduction in renal plasma flow. Therefore, under the experimental conditions employed in the present study, diffusion across the glomerulus was negligible relative to convection. This permitted estimation of the reflection coefficients for the series of neutral dextrans. Postglomerular extraction was markedly flow dependent, which implies a major diffusion limitation. Application of a barrier-limited distributed model permitted quantitation of postglomerular capillary permeability coefficients for neutral markers of less than 5000 daltons.     

Interaction of liposomes with erythrocytes in the process of their lysis]

Interaction of phosphatidyl choline liposomes with erythrocytes during spontaneous lysis of the latter has been studied. It is shown that hemoglobin which is released during the lysis of erythrocytes is found by liposomes which in their turn are absorbed on the external erythrocyte surface. In this case the binding of hemoglobin by liposomes takes place with a greater speed than its release during erythrocyte lysis and is accompanied by a change in its conformation. Possibilities of the microcalorimetry methods for studying the interaction of liposomes with erythrocytes under the conditions mentioned above are considered.     

Localization of inulinase and invertase in Kluyveromyces species

In vivo hydrolysis of inulin and sucrose was examined in selected yeasts of the genus Kluyveromyces. Cells, grown in sucrose-limited chemostat cultures, were subjected to treatments for the removal of inulinase, the enzyme responsible for the hydrolysis of both inulin and sucrose. The effects of these treatments were studied by measurement of inulin-dependent and sucrose-dependent oxygen consumption by cell suspensions. In Kluyveromyces marxianus var. marxianus, inulinase was partially secreted into the culture fluid. Removal of culture fluid inulinase by washing had no effect on sucrose-dependent oxygen consumption by this yeast. However, this treatment drastically reduced inulin-dependent oxygen consumption. Treatment of washed cells with sulfhydryls removed part of the cell wall-retained inulinase and reduced inulin-dependent oxygen consumption by another 80%. Sucrose-dependent oxygen consumption was less affected, decreasing by 40%. Cell suspensions of K. marxianus var. drosophilarum, K. marxianus var. vanudenii, and Saccharomyces kluyveri rapidly utilized sucrose but not inulin. This is in accordance with the classification of these yeasts as inulin negative. Supernatants of cultures grown at pH 5.5 did not catalyze the hydrolysis of inulin and sucrose. This suggested that these yeasts contained a strictly cell-bound invertase, an enzyme not capable of inulin hydrolysis. However, upon washing, cells became able to utilize inulin. The inulin-dependent oxygen consumption further increased after treatment of the cells with sulfhydryls. These treatments did not affect the sucrose-dependent oxygen consumption of the cells. Apparently, these treatments removed a permeability barrier for inulin that does not exist for sucrose.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on a beta-fructosidase (inulinase) produced bySaccharomyces fragilis

Summary A study was made of a β-fructosidase, which is produced extracellularly and intracellularly bySaccharomyces fragilis. The enzyme catalyzes the hydrolysis of inulin, bacterial levans, sucrose, and the fructose portion of raffinose, by splitting off terminal fructosyl units. It attacks β-2,1 as well as β-2,6 linkages. The enzyme content of inulin-grown cells is sufficient to allow fermentation of inulin at the same rate as glucose. The ratio of hydrolysis rates with sucrose and inulin was about 25 for the β-fructosidase ofS. fragilis and about 14,000 for invertase.S. fragilis does not contain significant amounts of invertase and it ferments inulin, sucrose and raffinose with the aid of a related, but different enzyme, inulinase. Conditions of growth were established which favor inulinase synthesis. Highest yields were obtained with inulin as the carbon source, and somewhat lower yields with raffinose. Glucose, fructose and sucrose were poor inducers of inulinase. The pH of the medium during growth on inulin had to be in the range where inulinase could act, otherwise growth was tardy and poor. In an inulin containing medium aeration favored enzyme production as a result of stimulation of growth. The inulinase content of the cells in a unit volume was generally greater than that in the culture medium. The intracellular inulinase could be solubilized quantitatively by autolysis. The intra-and extracellular inulinases were concentrated and purified to the same extent. Comparison of the two preparations with respect to substrate specificity, rate of inactivation by heat, pH optima with sucrose (4.2) and with inulin (5.0), and elution patterns from a column of diethylaminoethyl cellulose, indicated that the intra-and extracellular enzymes were identical.     

Bufferless lysis of erythrocytes for isolation of hemoglobin using modified cellulose acetate membranes

This paper presents a modified cellulose acetate membrane prepared using a dry casting technique that can be used to perform lysis of erythrocytes and isolation of hemoglobin. Isolation of hemoglobin is thus achieved without the use of lysis buffers. Cellulose acetate (CA) membranes are embedded with ammonium chloride (NH₄Cl) and potassium bicarbonate (KHCO₃), which act as lysing agents. The presence of embedded salts is confirmed using EDS analysis. The pores in the CA membrane act as filters. The average pore size in these membranes is designed to be 1.5 μM, as characterized by SEM analysis, so that they allow hemoglobin to pass through and block all other cells and unlysed erythrocytes present in blood. When a drop of blood is added to the membrane, the NH₄Cl and KHCO₃ embedded in the membrane dissolve in plasma and lyse the erythrocytes. The filtered hemoglobin is characterized using UV-Vis Spectroscopy. The results indicate extraction of higher concentration of hemoglobin compared with conventional methods.     

Effects of an inhomogeneous magnetic field on flowing erythrocytes

Effects of an inhomogeneous magnetic field on narrow erythrocyte streams in a wide and transparent laminar buffer flow were studied. The stream line of erythrocytes containing paramagnetic hemoglobin showed distinct displacement toward the stronger magnetic field. The displacement increased in the order, oxygenated erythrocytes (no displacement), erythrocytes containing cyanomethemoglobin, deoxygenated erythrocytes, erythrocytes containing methemoglobin in the high spin state; more precisely the displacement was proportional to the square of the paramagnetic moment of hemoglobin contained in the erythrocytes. In addition, the displacement was proportional to the product of the magnetic flux density and its gradient, and approximately proportional to the hematocrit of the flowing-erythrocyte suspension, and was much larger than that calculated for a single erythrocyte. These phenomena could be successfully interpreted by the interaction of paramagnetic erythrocytes with the inhomogeneous magnetic field, the resistance force (Stokes Law) from the bulk water, and the hydrodynamic interaction between erythrocytes.