Correlation between phagocytic and membrane surface properties reflected by partitioning of human peripheral blood monocytes in two-polymer aqueous phases

Human peripheral blood monocyte-enriched fractions (identified by staining for peroxidase and by sizing) were obtained by velocity sedimentation at unit gravity of peripheral blood mononuclear cells. They were then fractionated by countercurrent distribution (a multiple-extraction procedure) in a charged Dextran/poly(ethylene glycol) aqueous phase system. The monocytes remained viable after the separation (order of 90%). Cells obtained from different cavities along the extraction train were tested for their ability to phagocytize latex particles. With increasing partition coefficient (presumably higher charge-associated membrane properties) the ratio of monocytes that phagocytized to monocytes that did not phagocytize increased appreciably. When, however, monocytes were permitted to phagocytize particles prior to countercurrent distribution, an increase in partition coefficient was associated with an appreciable decrease in the above-specified ratio. Control experiments indicate that the observed change in partitioning behavior cannot be ascribed to an alteration in size and/or density of the monocytes as a function of phagocytosis. It may be due to the internalization of charged surface groups during phagocytosis. We conclude that there is a correlation between the surface properties of monocytes (as reflected by partitiartitioning behavior cannot be ascribed to an alteration in size and/or density of the monocytes as a function of phagocytosis. It may be due to the internalization of charged surface groups during phagocytosis. We conclude that there is a correlation between the surface properties of monocytes (as reflected by partitioning) and their ability to ingest particles. Furthermore, an alteration in the surface charge-associated properties of monocytes as a consequence of phagocytosis is indicated by the cells' reduced partition coefficient.     

Fractionation of K-562 cells on the basis of their surface properties by partitioning in two-polymer aqueous-phase systems

The K-562 cell line is a culture of human leukemia stem cells originally derived from a patient with chronic myelogenous leukemia in blast crisis. We have subjected such cells, in the log phase of growth, to countercurrent distribution in a charge-sensitive dextran-polyethylene glycol aqueous-phase system, a method that fractionates cells on the basis of subtle differences in their surface properties, and found that: (1) The cell population is heterogeneous since it is composed of cells with different partition ratios. (2) There is a correlation between increasing cell partition ratios and increasing cell electrophoretic mobilities. (3) Cells under different parts of the distribution curve have dissimilar ratios of cells in different parts of the cell cycle, a phenomenon that may, at least partially, be the basis for the subfractionation of these cells. There is a clear tendency for cells in G₀+G₁+early S to decrease and for those in late S+G₂+M to increase with increasing partition ratios. (4) Sialic acid is a major surface charge component of the cells as evidenced by a dramatic drop in their partition ratios after treatment with neuraminidase.     

Fractionation of K-562 cells on the basis of their surface properties by partitioning in two-polymer aqueous-phase systems

The K-562 cell line is a culture of human leukemia stem cells originally derived from a patient with chronic myelogenous leukemia in blast crisis. We have subjected such cells, in the log phase of growth, to countercurrent distribution in a charge-sensitive dextran-polyethylene glycol aqueous-phase system, a method that fractionates cells on the basis of subtle differences in their surface properties, and found that: (1) The cell population is heterogeneous since it is composed of cells with different partition ratios. (2) There is a correlation between increasing cell partition ratios and increasing cell electrophoretic mobilities. (3) Cells under different parts of the distribution curve have dissimilar ratios of cells in different parts of the cell cycle, a phenomenon that may, at least partially, be the basis for the subfractionation of these cells. There is a clear tendency for cells in G0 + G1 + early S to decrease and for those in late S + G2 + M to increase with increasing partition ratios. (4) Sialic acid is a major surface charge component of the cells as evidenced by a dramatic drop in their partition ratios after treatment with neuraminidase.     

On the relation between surface area and partitioning of particulates in two-polymer aqueous phase systems

Partitioning in dextran-poly(ethylene glycol) aqueous two-phase systems is an established method for the separation of biomaterials. Size and surface properties are generally regarded as parameters which contribute to the determination of the materials' partition coefficients, K. While molecular weight or surface area can be one of the determinants of the K value of biomaterials in the size range of macromolecules to very small particulates (e.g. some viruses), partitioning liposomes of identical surface properties and different but distinct sizes indicate that surface areas greater than about 0.2 μm² do not affect the K value obtained. Analysis of available partitioning data of much larger particulates (i.e. cells) reveals that surface properties per unit area outweigh surface area per se in determining the K value in non-charge-sensitive, charge-sensitive and biospecific affinity phase systems.     

Aging of erythrocytes results in altered red cell surface properties in the rat, but not in the human. Studies by partitioning in two-polymer aqueous phase systems

Aqueous solutions of dextran and of poly(ethylene glycol) when mixed give rise to two-phase systems useful in separating cells, on the basis of their surface properties, by partitioning. Depending on whether salts with unequal or equal affinity for the two phases are chosen, phases with or without an electrostatic potential difference between the phases are obtained. At appropriate polymer concentrations the former yield cell partition coefficients (i.e., the quantity of cells in the top phase as a percentage of total cells added) based on charge-associated surface properties while the latter reflect membrane lipid-related parameters. With increasing cell age, rat erythrocytes have diminishing partition coefficients in both charged and uncharged phases. Using the elevated aspartate aminotransferase levels of younger red cells as a marker, we have not found that young mature erythrocytes of human do not have the highest partition coefficient in the red cell population as they do in rat. Experiments with isotopically labeled dog red cells yield results similar to those found with human erythrocytes. Furthermore, density-separated young and old red cells from human give overlapping countercurrent distribution curves. Finally, countercurrent distribution of human red blood cells followed by pooling of cells from the left and right ends of the distribution and subjection of these cells to a redistribution gives curves that overlap with each other and with the original countercurrent distribution. This indicates that not only are human red cells not subfractionated based on possible age-related surface alterations, but also that they are not subfractionated by partitioning based on any surface parameter. These results are consistent with our previous findings that membrane sialic acid/hemoglobin absorbance is essentially constant through the extraction train after countercurrent distribution of human erythrocytes in a charged phase system; and with the recent reports of others that there is no difference in electrophoretic mobility between human young and old red cells.     

Aging of erythrocytes results in altered red cell surface properties in the rat,but not in the human Studies by partitioning in two-polymer aqueous phase systems

Aqueous solutions of dextran and of poly(ethylene glycol) when mixed give rise to two-phase systems useful in separating cells, on the basis of their surface properties, by partitioning. Depending on whether salts with unequal or equal affinity for the two phases are chosen, phases with or without an electrostatic potential difference between the phases are obtained. At appropriate polymer concentrations the former yield cell partition coefficients (i.e., the quantity of cells in the top phase as a percentage of total cells added) based on charge-associated surface properties while the latter reflect membrane lipid-related parameters. With increasing cell age, rat erythrocytes have diminishing partition coefficients in both charged and uncharged phases. Using the elevated aspartate aminotransferase levels of younger red cells as a marker, we have now found that young mature erythrocytes of human do not have the highest partition coefficient in the red cell population as they do in rat. Experiments with isotopically labeled dog red cells yield results similar to those found with human erythrocytes. Furthermore, density-separated young and old red cells from human give overlapping countercurrent distribution curves. Finally, counter-current distribution of human red blood cells followed by pooling of cells from the left and right ends of the distribution and subjection of these cells to a redistribution gives curves that overlap with each other and with the original countercurrent distribution. This indicates that not only are human red cells not subfractionated based on possible age-related surface alterations, but also that they are not subfractionated by partitioning based on any surface parameter.These results are consistent with our previous findings that membrane sialic acid/hemoglobin absorbance is essentially constant through the extraction train after countercurrent distribution of human erythrocytes in a charged phase system; and with the recent reports of others that there is no difference in electrophoretic mobility between human young and old red cells.     

Membrane surface properties of normal and malignant cells: partition in aqueous two-polymer phase systems

The partition of normal and malignantly transformed fibroblast lines and cell lines initiated from malignant human astrocytomas and a benign ganglioneuroma has been examined in aqueous dextran-polyethylene glycol phase system containing phosphate buffer with a low phosphate/sodium chloride ratio. The malignant astrocytomas showed a significantly lower partition coefficient as compared with the benign ganglioneuroma. Treatment of astrocytoma cells with dexamethasone caused an increase in the partitioning of the cell population. No differences were found in the partition behaviour of normal BHK-21 cells and their malignant transformants, the TRES fibrosarcoma cells. Polyoma and simian virus-transformed 3T3 fibroblasts showed partition ratios similar to the untransformed cells. Dexamethasone pre-treatment had no effect on the partition behaviour of these cells. The significance of these observations has been discussed in relation to the surface hydrophobicity and the neoplastic state.     

Partition of ribosomes in two-polymer aqueous phase systems

Two-polymer aqueous phase systems are described in which ribosomes selectively partition into one of the phases. One of the phase systems is used to determine rapidly and conveniently binding of thiostrepton and erythromycin to Escherichia coli ribosomes under equilibrium conditions.     

The dynamics of phase partition. A study of parameters affecting rat liver organelle partitioning in aqueous two-polymer phase systems.

Separation of subcellular organelles by two-phase partition is thought to reflect differential partition of the organelles between the two phases or between one of the phases and the interface. Studies by Fisher and colleagues [Fisher & Walter (1984) Biochim. Biophys. Acta 801, 106-110] suggest that cell separation by phase partition is a dynamic process in which the partition changes with time. This is mainly due to association of the cells with sedimenting droplets of one phase in the bulk of the other. Rat liver organelle partition was studied to determine whether the same dynamic behaviour is observed. Partition was clearly time-dependent during 24 h at unit gravity, and was also affected by altering the volume ratio of the two phases and the duration of phase mixing. These results indicate that, as with cells, the partition of organelles between phases is a dynamic process, and is consistent with the demonstration that organelles adhere to the phase droplet surfaces. Optimization of the volume ratio between phases may lead to significant processing economies. Organelle sedimentation in the upper phase was significantly faster than in the isoosmotic sucrose. Theoretical modelling of apparent organelle sizes indicates that aggregation occurs in the poly(ethylene glycol)-rich upper phase. This phenomenon is likely to limit the use of this technique in organelle separations unless means can be found to decrease aggregation.     

Differential effect of neuraminidase-treatment on the surface charge-associated properties of rat reticulocytes and erythrocytes. Studies by partitioning in two-polymer aqueous phases

Rat reticulocytes undergo charge-associated surface changes, detectable by cell partitioning in charged dextran-poly(ethylene glycol) aqueous phase systems, as they become mature erythrocytes. Young reticulocytes have a lower partition coefficient, i.e., quantity of cells in the top phase as a percentage of total cells added, than do mature erythrocytes. Sialic acid is the main charge-bearing group on red blood cells and, in the case of the rat, most of the sialic acid can be removed by treatment of the cells with neuraminidase (Vibrio cholerae). By combining isotopic 59Fe-labeling of reticulocytes with countercurrent distribution of the entire red blood cell population in charged dextran-poly(ethylene glycol) aqueous phases we have now studied the relative effect of neuraminidase-treatment on rat reticulocytes and mature erythrocytes. It was found that neuraminidase-treatment (a) does not eliminate surface differences, detectable by partitioning, between rat reticulocytes and erythrocytes and (b) reduces the partition coefficient of mature erythrocytes to a greater extent than the partition coefficient of reticulocytes indicating a differential effect of this enzyme on the two cell populations.     

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

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

Effect of surface modification of rat erythrocytes of different ages on their partitioning behavior in charge-sensitive two-polymer aqueous phases

Partitioning differences between cells in two-polymer aqueous phase systems originate from subtle differences between the surface properties of cells. Because of the exponential relation between the parameters affecting the partition ratio (P) and the P itself, differences in membrane components suspected of effecting the differential partitioning of closely related cell populations cannot be directly established by conventional chemical assay techniques. In order to study the chemical nature of the components responsible for the age-related changes in surface properties of rat red cells we have devised an approach which uses a combination of isotopic labeling of erythrocyte subpopulations of distinct cell age with different enzyme and/or chemical treatments followed by countercurrent distribution in charge-sensitive two-polymer aqueous phase systems. These studies show that: neuraminidase-susceptible sialic acid is not responsible for the cell age-related surface differences detected by partitioning; the component(s) responsible for the cell age-related surface differences can be extracted (from aldehyde-fixed red cells) with ethanol or cleaved with dilute sulfuric acid. Our data are consistent with the hypothesis that ganglioside-linked sialic acid is the chemical moiety responsible for the cell charge-associated surface differences among rat red blood cells of different ages.     

Differential effect of neuraminidase-treatment on the surface charge-associated properties of rat reticulocytes and erythrocytes: Studies by partitioning in two-polymer aqueous phases

Rat reticulocytes undergo charge-associated surface changes, detectable by cell partitioning in charged dextran-poly(ethylene glycol) aqueous phase systems, as they become mature erythrocytes. Young reticulocytes have a lower partition coefficient, i.e., quantity of cells in the top phase as a percentage of total cells added, than do mature erythrocytes. Sialic acid is the main charge-bearing group on red blood cells and, in the case of the rat, most of the sialic acid can be removed by treatment of the cells with neuraminidase (Vibrio cholerae). By combining isotopic ⁵⁹Fe-labeling of reticulocytes with countercurrent distribution of the entire red blood cell population in charged dextran-poly(ethylene glycol) aqueous phases we have now studied the relative effect of neuraminidase-treatment on rat reticulocytes and mature erythrocytes. It was found that neuraminidase-treatment (a) does not eliminate surface differences, detectable by partitioning, between rat reticulocytes and erythrocytes and (b) reduces the partition coefficient of mature erythrocytes to a greater extent than the partition coefficient of reticulocytes indicating a differential effect of this enzyme on the two cell populations.     

Various topochemical arrangements of sialic acids on human erythrocytes as detected by partition in aqueous two-polymer phase systems

Human and rabbit red blood cells were subjected to partition in an aqueous, buffered Ficoll-Dextran two-phase system. The effect of neuraminidase treatment on the cell partition behaviour was examined and compared with the amount of sialic acids released from the cell surface and with the change in the electrophoretic mobility of the cells. The data obtained in the study indicate that there are two main groups of sialic acids differing in their topochemical arrangement on the human erythrocyte surface, and their relative hydrophobicity was evaluated. The results obtained in the case of rabbit red cells seem to indicate that sialic acids present on the cell surface are not the only major ionogenic surface components as is the case for human red cells. The data obtained support the assumption that the membrane surface charge is the determinant of cell partition only as a factor affecting the relative hydrophobicity of the cell surface.     

Alterations in membrane surface properties during cell differentiation as measured by partition in aqueous two-polymer phase systems: Rat intestinal epithelial cells

Membrane surface properties of rat intestinal epithelial cells (crypt base to villus tips) were studied by cell partition in a two-polymer aqueous phase system. A higher partition generally reflects higher cell surface charge (or charge-associated properties) which is not necessarily the same as the charge determined by cell electrophoresis since the latter reflects only the charge at the plane of shear while the former gauges it deeper into the membrane [10]. Cells were prepared by the method of Weiser [22] which sequentially yields cell fractions from villus tips to crypt base. The isolated cells were subjected to countercurrent distribution in a dextran-polyethylene glycol aqueous two-phase system. Countercurrent distribution on the first fractions obtained by Weiser's method have a peak to the left and a smaller peak to the right indicating a surface membrane heterogeneity of upper villus cells; last fractions have a peak only to the right. When all fractions are pooled before countercurrent distribution two well-separated peaks are obtained with the right peak sometimes showing additional heterogeneities. Experiments combining isotope labeling of cells with countercurrent distribution lead us to conclude that the membrane charge (or charge-associated properties) of crypt base cells increases during differentiation and that the charge of the villus cells to which they give rise then diminishes during maturation. The charge of the bulk of the upper villus cells is the lowest of any in the intestinal cell population. The basis for the alteration in charge has not been established but the phenomenon of changing membrane surface charge (or charge-associated properties) as a function of cell differentiation, maturation and aging appears to be a general phenomenon having been found and traced in different cell populations [14, 16, 17, 28].     

The molecular basis of partitioning in aqueous two-phase systems.

Protein purification based on partition in aqueous two-phase systems has attracted interest for many years. This approach has been advocated as a primary-stage unit operation in downstream processing. In reality, application has been strictly limited through inadequate understanding of the complex molecular forces involved in partitioning processes.