Density distribution and cation composition of red blood cells in newborn puppies

The density distribution and cation composition of red blood cells from newborn puppies have been studied. The density distribution of red cells from a newborn puppy in a bovine serum albumin density gradient resembles a normal distribution with a peak density at a region less than that found for adult dog red cells. In two weeks the whole distribution shifts toward a more dense region, and a second cell peak appears so that the distribution becomes bimodal. This second cell peak is smaller than the original peak, and it appears at a region of lower density. In nine weeks the distribution becomes a normal one again, but the peak density corresponds to the peak density of the second cell peak which first appeared at two weeks. Evidence has been obtained to show that fetal red cells are located in the more dense cell peak and neonatal cells are in the less dense second peak. These results were obtained by labeling fetal cells with Cr⁵¹ and neonatal cells with Fe⁵⁹. The analysis of the cation content of these cells shows that fetal cells contain more K and Na and have a higher K/Na ratio than adult red cells. Furthermore, neonatal cells contain considerably less cation and hemoglobin than do fetal cells. From a study of the cation and hemoglobin content of red cells appearing in various density fractions it is concluded that fetal cells lose K and Na during the first two weeks after birth. Thus, the change in the density disribution of the erythrocytes is thought to be due to two factors: (1) An increase in the density of fetal cells due to the loss of K and Na and, hence, water during the first two weeks after birth, and (2) the entry of less dense neonatal cells into the circulation.     

Separation of Dictyostelium discoideum cells into density classes throughout their development and their relationship to the later cell types

This paper describes a fast, non-destructive method for the separation of large quantities of Dictyostelium discoideum cells into density classes at all stages of development. The cells were separated by low-speed centrifugation on preformed, linear Percoll density gradients. On these gradients, cells at all developmental stages showed a unimodal variation in density and this variation in density rapidly increased during the first hours of development. The density was affected by the amount of salt present in the gradient medium, which suggests that it is regulated by a permeability property of the cells. Slug cells showed a unimodal variation in density and did not form bands corresponding to the cell types. However, were able to isolate density fractions which showed a good enrichment of prespore and prestalk cells: 95% and 90%, respectively. Preaggregation cells separated on density gradients yielded fractions which contained different amounts of three developmentally regulated enzymes. Hence, cells at this stage are already heterogeneous in their enzymatic content. Sorting experiments showed a strong correlation between density and developmental fate; the least dense (light) cells preferentially became prestalk cells, and the dense (heavy) cells became prespore cells. This was found for cells at all developmental stages; even vegetative-stage cells showed considerable heterogeneity with regard to density, which was related to their developmental fate. The light cells become prestalk cells, and the heavy cells become prespore cells. Vegetative cells from the various density fractions differed in their DNA content and temporal onset of mitotic activity when resuspended in medium. Therefore, we suggest that the separation of vegetative cells on density gradients results in a separation of cells into cell-cycle phases. Hence, there appear to be cell-cycle-linked differences among vegetative cells, which bias their differentiation towards either the spore or stalk pathway.     

Interrelations among Na and K content,cell volume,and buoyant density in human red blood cell populations

Summary This study establishes a method for determining the concentration of Na and K in single red blood cells from electron probe microanalysis of a cell's Na and K content. To this end, red blood cells were separated into subpopulations according to their buoyant density by means of bovine serum density gradient centrifugation. Cell water and Na+K contents were then determined in each fraction by conventional analytic methods with cell volume estimated from measurements of hematocrits and cell number. It was found that an inverse relationship obtains between the mean cell volume and buoyant cell density since cells increased in size as density decreased. Although the amount of hemoglobin per cell was found to slightly increase as cell density decreased, hemoglobin concentration showed the inverse relationship, indicating that buoyant cell density differences are primarily the result of differences in hemoglobin concentration. In confirmation of Funder and Wieth (Funder, J., Wieth, J.O. 1966.Scand. J. Lab. Invest. 18:167–180) cell water and cell volume was found to vary directly with the summed content of Na+K. Finally, by means of electron probe microanalysis of single cells, the cellular concentration of hemoglobin was found to vary inversely with the Na+K content, providing a quantitative basis for directly estimating cell volume, and thus ionic concentration, with this technique.     

Na+/H+ exchange is increased in sickle cell anemia and young normal red cells

Summary Red cell volume regulation is important in sickle cell anemia because the rate and extent of HbS polymerization are strongly dependent on initial hemoglobin concentration. We have demonstrated that volume-sensitive K:Cl cotransport is highly active in SS whole blood and is capable of increasing MCHC. We now report that Na⁺/H⁺ exchange (Na/H EXC), which is capable of decreasing the MCHC of erythrocytes with pH_i<7.2, is also very active in the blood of patients homozygous for HbS. The activity of Na/H EXC (maximum rate) was determined by measuring net Na⁺ influx (mmol/liter cell·hr=FU) driven by an outward H⁺ gradient in oxygenated, acidloaded (pH_i 6.0), DIDS-treated SS cells. The Na/H EXC activity was 33±3 FU (mean±se) (n=19) in AA whites, 37±8 FU (n=8) in AA blacks, and 85±15 FU (n=14) in SS patients (P<0.005). Separation of SS cells into four density-defined fractions by density gradient revealed mean values of Na/H EXC four to five times higher in reticulocytes (SS1), discocytes (SS2) and dense discocytes (SS3), than in the fraction containing irreversibly sickled cells and dense discocytes (SS4). In contrast to K:Cl cotransport, which dramatically decreases after reticulocyte maturation, Na/H EXC persists well after reticulocyte maturation. In density-defined, normal AA red cells, Na/H EXC decreased monotonically as cell density increased. In SS and AA red cells, the magnitude of stimulation of Na/H EXC by cell shrinkage varied from individual to individual. We conclude that Na/H EXC is highly expressed in SS and AA young red cells and decays slowly after reticulocyte maturation.     

Evaluation of density gradient separation methods

A new method for evaluating the effectiveness of isooynic separation processes is developed and explored. This technique is designed to measure the ability of a separation technique to attain the goals of a sorting process. The performance of a separation process is expressed in terms of an inconsistency number, I, whose values ranges from zero to unity. Processes which function perfectly are characterized by an I value of zero. Separation processes which subdivide a sample are characterized by an I value of unity. The validity of using I to measure the performance of separation processes was established by demonstrating that alterations in the performance of a well characterized separation technique were fully reflected by changes in the I value for the process. The capacity of four different techniques for ordering red cells with respect to their density was then shown to lie in a definite hierarchy. This hierarchy can be expressed as: Murphy technique (I = 0.21) > albumin density gradient (I = 0.43) > Stractan density gradient I = 0.53) > Percoll density gradient (I = 0.73). The performance of these techniques was found to be dependent on the exact operating conditions employed and the specific fraction of red cells isolated.     

Implications of small scale variation in ecological conditions for the diet and density of red colobus monkeys

In this 3-year investigation we documented patterns of density, diet, and activity of red colobus monkeys (Procolobus tephrosceles) in six areas in or near Kibale National Park, Uganda and related these patterns to availability of food resources. There were large differences in the density and behavior of the red colobus among the sites. For example, the red colobus at one site with a diverse plant community of more than 61 tree species, had a diet that included at least 42 species. In contrast, at a second site red colobus spent 92% of their feeding time eating from one species that dominated the tree community. The density of important red colobus food trees varied among sites from 32 trees/ha to 204 trees/ha, and red colobus density ranged from 0.70 groups/km² to 7.41 groups/km². Among sites, red colobus density was related to the cumulative DBH of important food trees, when one apparently anomalous site was excluded, and populations with more plant species in their diets tended to be those that were found at higher densities. Activity budgets of the red colobus populations varied markedly among sites. For example, feeding time ranged among sites from 29 to 55%, and traveling varied from 5 to 20%. When faced with increased foraging demands, red colobus reduced the time spent resting, while the time spent socializing remained fairly constant. Comparative socioecological studies typically contrast species separated by large geographical distances to ensure there is sufficient variation in the environment to detect behavioral responses. The marked differences in ecological conditions and red colobus behavior we documented over short geographical distances, suggests that small-scale contrasts are a useful tool to examine ecological determinants of behavior and community structure.     

A separation chamber to sort cells and cell organelles by weak physical forces: III. Preparative electrophoresis of cells in stationary density gradients at low electric field strength

An apparatus was designed for preparative density gradient electrophoresis of mammalian cells. In a low conductivity isotonic Ficoll density gradient of 1.5 cm length, human erythrocytes treated with neuraminidase were separated from untreated erythrocytes at an electric field strength of approximately 2.7 v/cm. Within 5 min two bands of erythrocytes were visible. Electrophoretic separation was completed within 25 min. The fractionation is performed in a design consisting of three Perspex circular plates, bottom and top plates of which can be displaced simultaneously relative to the stationary middle plate by a worm-gear mechanism. The middle plate contains a cylindrical separation chamber of 50 cm² and 1.5 cm high. Top and bottom plates contain cones and flow deflectors for the undisturbed thin layering of cell suspensions and for introduction of the density gradient. Also present in top and bottom plates are electrode compartments containing a large platinum electrode and a cellophane membrane that isolates the separation chamber hydrodynamically but not electrically from the electrode compartment. The electrode compartments were flushed with electrophoresis buffer to remove products of electrophoresis as well as the (low) generated Joule heat.     

Melittin lysis of red cells

Summary This paper describes experiments designed to explore interactions between human red blood cell membranes and melittin, the main component of bee venom. We found that melittin binds to human red cell membranes suspended in isotonic NaCl at room temperature, with an apparent dissociation constant of 3×10^–8 m and maximum binding capacity of 1.8×10⁷ molecules/cell. When about 1% of the melittin binding sites are occupied, cell lysis can be observed, and progressive, further increases in the fraction of the total sites occupied lead to progressively greater lysis in a graded manner. 50% lysis occurs when there are about 2×10⁶ molecules bound to the cell membrane. For any particular extent of melittin binding, lysis proceeds rapidly during the first few minutes but then slows and stops so that no further lysis occurs after one hour of exposure of cells to melittin. The graded lysis of erythrocytes by melittin is due to complete lysis of some of the cells, since both the density and the hemoglobin content of surviving, intact cells in a suspension that has undergone graded melittin lysis are similar to the values observed in the same cells prior to the addition of melittin. The cells surviving graded melittin lysis have an increased Na and reduced K, proportional to the extent of occupation of the melittin binding sites. Like lysis, Na accumulation and K loss proceed rapidly during the first few minutes of exposure to melittin but then stops so that Na, K and hemoglobin content of the cells remain constant after the first hour. These kinetic characteristics of both lysis and cation movements suggest that melittin modifies the permeability of the red cell membrane only for the first few minutes after the start of the interaction. Direct observation of cells by Nomarsky optics revealed that they crenate, become swollen and lyse within 10 to 30 sec after these changes in morphology are first seen. Taken together, these results are consistent with the idea that melittin produces lysis of human red cells at room temperature by a colloid osmotic mechanism.     

Separation of mouse testis cells by equilibrium density centrifugation in Renografin gradients

Mouse testis cells have been separated by equilibrium density centrifugation in gradients of Renografin. Intact testis cells were not damaged by the separation procedure provided that, following separation, the osmolarity was reduced gradually. The various cell types were identified microscopically and by ³H-thymidine labelling with similar results. The present technique has demonstrated that significant variations in cell density occur during spermatogenesis. Approximately ten-fold enrichments of nearly all testis cell types were achieved by equilibrium density separation of testis cell suspensions. More homogeneous cell populations were prepared by density gradient centrifugation of cell fractions obtained from velocity sedimentation separations. Overall enrichments of spermatogonia, by 29-fold; pachytene spermatocytes, 45-fold; dividing meiotic cells, 170-fold; round spermatids, 30-fold; step 11–13 elongating spermatids, 12-fold; Leydig cells, 70-fold; and cytoplasmic fragments, 55-fold, were obtained. In this study, a method for preparation of cell suspensions was also developed to produce higher yields of spermatogonia and young primary spermatocytes; however, the density distribution of these cells was altered.     

Capsulation of in vitro and in vivo grown Bacteroides species

By centrifugation on a four step Percoll density gradient cells of Bacteroides species could be separated according to the size of extracellular structure. The difference in size was visible by both light and electron microscopy. Two structures were observed on Bacteroides fragilis by electron microscopy, namely a fibrous network and an electron dense layer. An electron dense layer was visible on Bacteroides ovatus only when stained with ruthenium red. B. fragilis cells grown in the mouse peritoneal cavity did not produce a large fibrous network. An electron dense layer was observed on some cells in the presence of ruthenium red stain and cells possessing this layer were phagocytosed in vivo.     

A separation chamber to sort cells,nuclei, and chromosomes at moderate g forces. II. Studies on velocity sedimentation and equilibrium density centrifugation of mammalian cells

A separation chamber having a surface of 50 cm² and a height of 2 cm is described for the rapid separation of cells and cell organelles at acceleration forces from 10 to 90g. To eliminate wall sedimentation artifacts, the chamber was positioned 20 cm from the rotor axis in a speed-controlled centrifuge. The chamber has flow deflectors for the undisturbed introduction of the sample layer and the gradient; an antivortex cross prevents swirling upon acceleration and deceleration. To illustrate the use of the separation chamber, examples of velocity sedimentation and of equilibrium density centrifugation are given: (i) human monocytes (70% were 90% pure) are separated from lymphocytes in 10 min at 20g; (ii) nonparenchymal rat liver cells are separated in 10 min at 16g in 97% pure endothelial cells and 99% pure Kupffer cells; (iii) equilibrium density centrifugation of human peripheral blood cells at about 90g permits the separation of erythrocytes, monocytes, lymphocytes, neutrophils, eosinophils, and basophils in one run. B cells are separated from T cells. The movement of swinging buckets is analyzed in mathematical terms and a simple method is offered to determine the position of cells in density gradients with the use of a small programmable calculator.     

Density of red alder (Alnus rubra) in headwaters influences invertebrate and detritus subsidies to downstream fish habitats in Alaska

We investigated the influence of red alder (Alnus rubra) stand density in upland, riparian forests on invertebrate and detritus transport from fishless headwater streams to downstream, salmonid habitats in southeastern Alaska. Red alder commonly regenerates after soil disturbance (such as from natural landsliding or timber harvesting), and is common along streams in varying densities, but its effect on food delivery from headwater channels to downstream salmonid habitats is not clear. Fluvial transport of invertebrates and detritus was measured at 13 sites in spring, summer and fall during two years (2000–2001). The 13 streams encompassed a riparian red alder density gradient (1–82% canopy cover or 0–53% basal area) growing amongst young-growth conifer (45-yr-old stands that regenerated after forest clearcutting). Sites with more riparian red alder exported significantly more invertebrates than did sites with little alder (mean range across 1–82% alder gradient was about 1–4 invertebrates m^?3 water, and 0.1–1 mg invertebrates m^?3 water, respectively). Three-quarters of the invertebrates were of aquatic origin; the remainder was of terrestrial origin. Aquatic taxa were positively related to the alder density gradient, while terrestrially-derived taxa were not. Streams with more riparian alder also exported significantly more detritus than streams with less alder (mean range across 1–82% alder gradient was 0.01–0.06 g detritus m^?3 water). Based on these data, we predict that headwater streams with more riparian alder will provide more invertebrates and support more downstream fish biomass than those basins with little or no riparian alder, provided these downstream food webs fully utilize this resource subsidy.     

Inhibition of development of transformation by Rous sarcoma virus in cultures of high cell density

The effect of cell density on morphological transformation of chick embryo cells by Rous Sarcoma Virus (RSV) was examined in this study, and a cell density optimum for transformation was found. Less than 10% of the transformed foci appearing at the optimum density (2.5 × 10⁴ cells per cm²) developed at high cell densities, and the diameters of the foci (an indication of the number of cells per focus) decreased with increasing cell density. No correlation was found between the decrease in transformation at high cell densities and the effect of cell density on the initial rate of cell proliferation, although dissociation of transformation from incorporation of radioactive precursors into nucleic acids could not be established. Redistribution of cells infected at high density showed that only a small proportion of successfully infected cells developed into foci. The results indicate that transformation of cells containing the RSV genome can be suppressed by physiological factors accompanying high cell density.     

The M-antigen in HK and LK sheep red cell membranes

Summary Red cells of all high-potassium-type (HK) sheep and of more than one half of all low-potassium-type (LK) sheep contained the M-antigen and were hemolyzed by iso-immune anti-M antiserum in presence of a guinea pig serum complement. It was characteristic for the hemolysis of HK red cells by the M-antiserum the all HK cells were ultimately hemolyzed at suboptimal antibody concentrations, provided the time of incubation at 37 °C was sufficiently long. Thus, the M-antigen appears to be expressed on all red cells of an individual HK sheep. The M-antibody was absorbed by HK red cells and their membranes with a high affinity, whereas M-negative LK red cells and their membranes did not bind the antibody. The ratio of the number of antibody units absorbed per cell or membrane to the number of antibody units required for lysis approached unity. The amount of antibody absorbed per membrane was unaffected by ouabain in the presence of ATP, Mg⁺⁺, Na⁺, and K⁺. The M-antigen activity depends on the integrity of the red cell membrane and was not detectable after lyophilization of HK membranes or in the membrane protein solubilized by n-butanol. The major M-antibody activity was found among the high molecular weight plasma proteins and may be attributed to the ₂ M globulins. Heterogeneity within the antibody fraction cannot be excluded since some hemolytic activity was detected in a chromatographic fraction containing predominantly -globulin. The relationship between the M-antigen and the Na⁺–K⁺ transport system in sheep red cell membranes is discussed.This work was presented in part at the 53rd annual meeting of the Federation of American Societies for Experimental Biology, Atlantic City, N. J. 1969.     

Plasmodium lophurae: membrane proteins of erythrocyte-free plasmodia and malaria-infected red cells

Plasma membranes of normal duckling erythrocytes were prepared by blender homogenization and nitro-en decompression. Surface membrane vesicles of red cells infected with the avian malaria Plasmodium lophurae were produced by nitrogen decompression. Membranes of erythrocyte-free malaria parasites were removed from cytoplasmic constituents by Dounce homogenization. These membranes were collected by centrifugation in a sucrose step gradient and purified on a linear sucrose gradient. Red cell membranes had a buoyant density of 1.159 g/cm3, whereas plasmodial membranes banded at 2 densities: 1.110 g/cm3 and 1.158 g/cm3. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the isolated red cell membranes revealed 7 major protein bands with molecular weights (MW) ranging from 230, 000 to 22,000, and 3 glycoprotein bands with MW of 160,000, 88,000 and 37,000. Parasite membranes also had 7 major bands with MW ranging from 100,000 to 22,000. No glycoproteins were identifiable in these membranes. The proteins of the surface membranes from infected red cells had MW similar to those from normal red cells; however, there was some evidence of a reduction in the amount of the high MW polypeptides. The red cell membrane contained 79 nmoles sialic acid/mg membrane protein, whereas plasmodial membranes had 8 nmoles sialic acid/mg membrane protein. The sialic acid content of the surface membranes of infected red cells was significantly smaller than that of normal cells. Lactoperoxidase-glucose oxidase-catalyzed iodination of intact normal and malaria-infected erythrocytes labeled 7 surface components. Although no observable differences in iodinatable proteins were seen in these preparations, there was a striking reduction in the iodinatability of erythrocytic membranes obtained from P. lophurae-infected cells. Erythrocyte-free plasmodia bound very little radioactive iodine; the small amount of radioactivity was distributed among 3 major bands with MW of 42,000, 32,000 and 28,000. It is suggested that the alterations of the surface of the P. lophurae-infected erythrocyte do not occur by a wholesale insertion of plasmodial membrane proteins into the red cell plasma membrane, but rather that there are parasite-mediated modifications of existing membrane polypeptides.     

Membrane and intracellular modes of sugar-dependent increments in red cell stability

Sugar-dependent increments in red cell stability under osmotic stress can be ascribed to changes either in the membrane or in the intracellular matrix. These two possible modes of action have been tested and characterized.Rheological investigation of membrane-free haemoglobin solutions has shown that D-glucose, but not D-fructose, promotes the formation of a visco-plastic gel structure. gel strength is a function of glucose concentration, haemoglobin concentration and temperature. The ability of various sugars to promote gel formation correlates with their solution properties. The existence of gel structure reduces K⁺ and haemoglobin leak from red cells whose membranes were partially destroyed by γ- radiation. Reduced osmotic swelling in the presence of glucose is also due to gel formation since the glucose effect is lost in resealed red cell ghost.D-Fructose does not protect red cells against radiation damage; its mode of action in increasing red cell stability under osmotic stress is a membrane effect. Cell sizing using the Coulter Counter has shown that fructose, but not glucose, can increase the maximal volume at lysis. At 50 mM., D-fructose expands the red cell ghost voloume by 11.2%; this represents a 7.2% increase in membrane area. Ghost expansion by fructose is fructose concentration dependent (0–100 mM) and is insensitive to temperature variation (0–37 °C).     

The in vivo reproductive potential of density separated cells

Murine ascites cells (L1210, L5178Y, Ehrlich ascites) were labelled with ¹³¹I-iododeoxyuridine and subjected to buoyant density centrifugation on a continuous, linear Ficoll gradient. Cell losses sustained during density centrifugation were evaluated by recording the amount of ¹³¹I recovered in the final cell fractions. The viability and proliferative capacity of the density separated cells were tested by monitoring the rate of ¹³¹I excretion following inoculation of the recovered cells into new, non-radioactive hosts.Density separation in Ficoll appeared to cause few, if any, adverse effects. Cell recovery under properly regulated experimental conditions was virtually complete (97% or higher). The reproductive potential of density-separated cells was identical to that of control cells. However, considerable cell mortality could be induced by permitting cellular aggregation in medium free of antiagglutinin or by exposure of excessive quantities of cells to a density gradient.Viability indices obtained with trypan blue proved unsuitable for predicting long-term survival. In some experiments the trypan blue data provided a 90–100% viability reading when in fact the entire cell population had been inactivated by irradiation or heat incubation. Since the trypan blue test also did not reveal the full extent of mortality among aggregated cells or cells recovered from overloaded gradients, it was concluded that the dye exclusion test, in spite of its utility for monitoring immediate cell death and membrane destruction, was of limited value for evaluating the reproductive potential of mammalian cells.     

Red blood cell [14C]cholesterol exchange and plasma cholesterol esterifying activity of normal and sickle cell blood

The present study performed on density fractions of sickle and normal erythrocytes prepared on Stractan density gradient shows that dense erythrocytes have consistently decreased uptake of [¹⁴C]cholesterol from plasma in comparison to young, less dense erythrocytes. Plasma of sickle cell patients also shows a reduction in cholesterol-esterifying activity in comparison to normal controls. A possible effect of these processes in the increased cholesterol to phospholipid molar ratio of irreversibly sickled cells has been suggested.     

Binding of thrombin to normal and transformed fibroblasts depends on cell density

Binding of biologically active [¹²⁵I]thrombin to several normal and transformed human and chicken cell lines was found to depend on cell density; more [¹²⁵I]thrombin per cell was bound to sparse than to dense cultures. When normal and transformed cells were compared at equal densities the previously reported difference in [¹²⁵I]thrombin binding was not evident.     

Differentiation of acidophilic thiobacilli by cell density in renografin gradients

Thiobacillus acidophilus andT. ferrooxidans were separated by centrifugation on the basis of their cell density in Renografin gradients. For both species, growth history was the largest factor influencing cell density. Density was greatest forT. acidophilus andT. ferrooxidans grown with tetrathionate, followed byT. acidophilus grown with glucose.T. ferrooxidans grown with ferrous sulfate was the least dense.T. acidophilus was isolated from iron-grownT. ferrooxidans by separation in a Renografin gradient. Plasmid patterns ofT. acidophilus andT. ferrooxidans were used to confirm the separation of the two species in mixed gradients.