Separation of Subclasses of Human Serum High Density Lipoproteins by Zonal Ultracentrifugation

An improved one-step method for the preparative separation of three subfraotions of high-density lipoproteins from normal human serum has been developed. It employs the method of rate zonal ultracentrifugation in a Z-60 rotor using a discontinuous NaBr gradient in the density range of 1.0 - 1.4. The density gradients were monitored directly by a flow-through density meter allowing the direct read-out of the actual densities in the process of filling and emptying the rotor. The separation of the three density fractions from 5 to 15 ml serum was achieved during a single 12 hours run at 59.000 rpm. The three fractions showed characteristically different patterns on polyacrylamide gel electrophoresis and differences in their lipid and protein composition.     

Separation of the main lipoprotein density classes from human plasma by rate-zonal ultracentrifugation

The major lipoprotein density classes (chylomicrons-VLDL, LDL, HDL(2) and HDL(3)) were isolated from human plasma in a two-step ultracentrifugal procedure using the Ti-14 zonal rotor. The isolation of the two major high density lipoprotein subclasses (HDL(2) and HDL(3)) was achieved in a 24-hr run using a nonlinear NaBr gradient in the density range of 1.00-1.40. The lipoproteins with a density < 1.063 found in the rotor's center were isolated in a second run of 140 min duration using a continuous linear NaBr gradient in the density range of 1.00-1.30. The isolated lipoproteins were analyzed for chemical composition and for electrophoretic mobility; purity of isolated fractions was checked by immunochemistry. The lipoproteins exhibited flotation rates, chemical compositions, and molecular weights similar to those found with the common sequential procedures in angle-head rotors. The amount of lipoprotein lipids in the bottom fraction of the zonal rotor was comparable to that of the angle-head rotor. The described method yields the main lipoprotein density classes free from albumin in a very short running time; compared with the rate-zonal techniques already in use, this method allows the quantitative separation of an additional lipoprotein density class (HDL(2)) without increasing the running time. Furthermore, this procedure proved to be suitable for isolation of plasma lipoproteins from subjects with various types and varying degrees of hyperlipoproteinemia.     

Rapid isolation of vesicular and micellar carriers of biliary lipids by ultracentrifugation

A simple, rapid, and new method has been developed to isolate and to quantitate the vesicular carrier of biliary lipids by isopycnic ultracentrifugation. The method combines the use of Metrizamide, as an inert centrifugation media to change the density of bile for isopycnic separation of vesicles, and a vertical rotor, to decrease both the time of centrifugation and the pressure of the hydrostatic column in the ultracentrifuge tube. Vesicles harvested from bile-Metrizamide density gradients were identified by negative staining electron microscopy. The buoyant densitites of biliary vesicles varied between 1.010 and 1.030 g/ml. The diameter of vesicles in fractions with d less than 1.020 g/ml was 82 +/- 10 nm and in fraction with d approximately 1.030 g/ml was 57 +/- 8 nm. Gel filtration chromatography with Ultrogel AcA 34 was used to validate the quantitive isolation of vesicles by the ultracentrifugal method. In experiments with bile-Metrizamide continuous preformed density gradients, greater than 93% of vesicular cholesterol was found in fractions with d less than 1.030 g/ml after 285 min of centrifugation at 50,000 rpm in a VTi vertical rotor (Beckman Instruments, Inc.). When 16% Metrizamide was dissolved in bile and centrifuged for 120 min, greater than 96% of total vesicular cholesterol was found in the top 0.4 ml of the 5-ml centrifuge tube, as assessed by gel filtration chromatography. This fraction contained less than 8% of cholesterol carried in micelles, as assessed by gel filtration chromatography. The variation coefficient of this short ultracentrifugal method to isolate biliary vesicles was 4.6%.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation of serum chylomicrons prior to density gradient ultracentrifugation of other serum lipoprotein classes

A method for the removal of serum chylomicrons before density gradient ultracentrifugation of the other serum lipoproteins using an SW 41 swinging bucket rotor is presented. In a preliminary spin, the chylomicrons with an Sf greater than 400 X 10(-13) s float to the top of the gradient, whereas the other lipoproteins are retained in the infranatant fraction. After removal of the chylomicrons, the other serum lipoproteins are subsequently fractionated by isopycnic density gradient ultracentrifugation. Analysis of the separated lipoprotein fractions suggested that this procedure permits isolation of a chylomicron fraction consisting solely of chylomicrons but that the very low density lipoprotein fraction subsequently isolated also contains chylomicrons or chylomicron remnants with an Sf less than 400 X 10(-13) s, and that there is considerable overlap in flotation rate and particle size of very low density lipoproteins and chylomicrons.     

Separation of the microvillous (maternal) from the basal (fetal) plasma membrane of human term placenta: methods and physiological significance of marker enzyme distribution.

Plasma membranes from normal, full-term human placental trophoblast have been isolated by a new procedure. The method depends upon isopycnic zonal centrifugation using linear sucrose/Ficoll density gradients. Enrichment of plasma membrane marker enzymes with respect to trophoblast homogenate is found in two distinct peaks (designated B and D) of the fractionated effluent recovered from the rotor. Fraction B is enriched with membrane-bound alkaline phosphatase and 5'-nucleotidase, but not with (Na+, K+)-ATPase of F(-)-stimulated adenylate cyclase. It is suggested that this material is derived from the maternal-facing microvillous plasma membrane. Fraction D, enriched with (Na+, K+)-ATPase, F(-)-stimulated adenylate cyclase and, to a smaller extent, with 5'-nucleotidase and alkaline phosphatase is, by exclusion, proposed to be derived from the fetal-facing basal plasma membrane. Both plasma membrane fractions are shown to be free of appreciable contamination, using specific markers for endoplasmic reticulum, mitochondria, nuclei and lysosomes. The separation of the two membrane fractions is shown to depend both upon these membranes forming closed vesicles during homogenization and upon the buoyant densities of such vesicles differing in such a way that microvillous plasma membranes band at a lower density than basal plasma membranes. No separation of the membranes is achieved in gradients in which the vesicles are collapsed.     

Characterization of the separation properties of the Beckman elutriator system

The role of fluid flow in the elutriation process was visualized by pumping dye solution through the Beckman JE-6 elutriator rotor. Three major fluid flow disturbances were observed in the separation chambers, namely; jet-streaming, ripple flow, and whirl flow. In order to evaluate the effects of these non-ideal fluid flow patterns on the separation of homogeneous populations of particles or cells, 12--35 micron diameter latex spheres and 9L rat brain tumor cells were fractionated with the Beckman elutriator system. The elutriator system was evaluated on the basis of: (1) recovery, (2) elution loss during loading, (3) homogeneity of the size distributions, and (4) the relationship of the median volume of eluted particles or cells to the rotor speed and the collection fluid velocity. Both a conventional collection method (two 40-mL fractions at ech collection rotor speed) and a long collection method (10--15 40-mL fractions at several collection rotor speeds) were compared to determine if collection procedures could compensate for some of the difficulties caused by the non-ideal fluid flow patterns. Although more than 90% of the particles or cells were always recovered, about 5% eluted during the loading procedure. Neither collection method altered this phenomenon. The long collection method significantly improved the homogeneity of the collected populations, but this was accompanied by a reduction in cell yield. The median particle or cell volume of each fraction agreed with that expected under ideal fluid flow conditions except at high and low rotor speeds when the conventional collection method was used.     

Characterization of the separation properties of the beckman elutriator system

The role of fluid flow in the elutriation process was visualized by pumping dye solution through the Beckman JE-6 elutriator rotor. Three major fluid flow disturbances were observed in the separation chambers, namely; jet-streaming, ripple flow, and whirl flow. In order to evaluate the effects of these non-ideal fluid flow patterns on the separation of homogeneous populations of particles or cells, 12–35 μm diameter latex spheres and 9L rat brain tumor cells were fractionated with the Beckman elutriator system. The elutriator system was evaluated on the basis of: (1) recovery, (2) elution loss during loading, (3) homogeneity of the size distributions, and (4) the relationship of the median volume of eluted particles or cells to the rotor speed and the collection fluid velocity. Both a conventional collection method (two 40-mL fractions at each collection rotor speed) and a long collection method (10–15 40-mL fractions at several collection rotor speeds) were compared to determine if collection procedures could compensate for some of the difficulties caused by the non-ideal fluid flow patterns. Although more than 90% of the particles or cells were always recovered, about 5% eluted during the loading procedure. Neither collection method altered this phenomenon. The collected populations, but this was accompanied by a reduction in cell yield. The median particle or cell volume of each fraction agreed with that expected under ideal fluid flow conditions except at high and low rotor speeds when the conventional collection method was used.     

10. Purification of Viruses by Cenlrifugation in Gradients of Inert Substances

ABSTRACT

By using a reorienting gradient centrifuge rotor cut from a block of Nylon and fitted with eight septae, it was possible to separate the components of the haemolymph of the mollusc Turbo sarmaticus into three fractions in a sucrose gradient held in the bowl of the rotor. The fractions were (108 and 98)S, 44S and 16-22S. The success of the experiment was due to the large differences in the sedimentation coefficients of the components. When the rotor was applied to the natural mixture of the five viruses of the caterpillars of Nudaurelia cytheria only the main component could be isolated in a pure state. The viruses were separated by isopycnic centrifugation in “self formed” caesium chloride gradients, using a Beckman Model E analytical centrifuge in which a separation cell fitted with a centerpiece with two perforated partitions was used.

Centrifugation in gradients of inert substances is useful for the separation of components in a mixture¹. There are two principles involved in this type of separation. One, termed reorienting gradient centrifugation (reograd) relies on the differences in masses or, better still on the sedimentation coefficients of the different components in the mixture and the second, termed isopycnic centrifugation², on the densities or specific gravities of the different entities.     

Purification and characterization of bovine lipoproteins: resolution of high density and low density lipoproteins using heparin-Sepharose chromatography

The selective and reversible adsorption of bovine low density lipoproteins (LDL) by heparin-Sepharose has been exploited as the critical step in a procedure for the preparative isolation of very low density lipoproteins (VLDL)/chylomicrons, LDL, and high density lipoproteins (HDL) from bovine plasma. Molecular size exclusion chromatography and isopycnic density gradient separation steps are also involved in the method described. The resulting HDL and LDL fractions are free from contamination by one another as judged by electrophoretic mobility in agarose gels. The major lipid and apolipoprotein compositions of the three resolved lipoprotein classes have been determined.     

Particle size and protein content of six fractions of the Sf 20 plasma lipoproteins isolated by density gradient centrifugation

A procedure is described for the separation of plasma S(f) > 400 and S(f) 20-400 lipoproteins each into three fractions. Serum samples are overlayered with a sodium chloride density gradient in a preparative ultracentrifuge tube and thin layers are removed at the top of the tube after successive centrifugations at different speeds in a swinging bucket rotor. The procedure was evaluated by electron microscopy of the S(f) > 400 lipoprotein fractions and schlieren analysis of the S(f) 20-400 lipoprotein fractions. Protein content of each fraction was measured by elemental N, C, H, and lipid-P analysis. Protein coverage was calculated for all fractions on the assumption that there is a surface layer 20 A thick. For the entire S(f) > 400 lipoprotein spectrum and for a part of the S(f) 20-400 lipoprotein distribution the proportion of surface covered by protein was constant (approximately 20% coverage). Therefore, for these portions of the lipoprotein spectrum, the increase in surface: volume ratio as particle size decreases is approximately compensated for by an increase in the weight percentage of protein.     

Ultrastructural studies of peripheral blood lymphocytes in T cell-depleted rabbits

Summary Density separation of purified peripheral blood leucocytes from T-cell depleted rabbits on a linear Ficoll-metrizoate gradient has been applied to obtain different leucocyte fractions. Two lymphocyte fractions separated on density seem to have different characteristics, both morphologically and immunologically. In this study these two fractions have been characterized ultrastructurally by using scanning electron microscopy (SEM) and transmission electron microscopy (TEM), and a relationship has been established between the surface architecture (SEM), the cell size (SEM/TEM) and surface-Ig/C₃-receptors (LM, light microscopy). Finally three types of lymphocytes have been described in the two lymphocyte fractions separated on density. Morphometric information such as cell size, cell shape, eu-/heterochromatin ratio in the nucleus and the nucleus-/cell ratio have been correlated to the stage of activation of the B lymphocyte in a representative density separation.     

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.     

A new method for the rapid separation of cell organelles

A rapid procedure is described for the separation of plant cell organelles from castor bean endosperm (Ricinus communis). This method is based on the reorientation of sucrose density gradients during centrifugation in a vertical rotor, thus resulting in a shorter path length and drastically reduced run times. Comparison to a separation by a standard procedure shows that, by using this method, equal resolution is possible in less than 10% spin time.     

Theory and practice of centrifugal elutriation (CE). Factors influencing the separation of human blood cells

Centrifugal elutriation (CE) is currently a widely used preparative cell separation technique. In order to optimize the separation of cells that show only small differences in sedimentation velocity, several conditions that might influence the resolution capacity, such as rotor speed, counterflow, jetstream, cell load, density, and viscosity of the elutriation medium, were analyzed. Experiments carried out with human red blood cells (rbc) indicated that selective losses of rbc from the rotor caused by the jetstream, could be prevented if the separations were carried out at high rotor speeds, as predicted by the theory. In addition, high cell loads (5 X 10(8) rbc) resulted in better separations than low cell loads (5 X 10(7) rbc). Human monocytes were separated into subpopulations that differed only about 0.003 g/mL in density, but have virtually the same size. The separation was carried out either by increasing the density or viscosity of the elutriation medium or by decreasing the rotor speed. In all cases similar results were obtained. These results indicated that under optimal conditions CE can be applied for the separation of cells that differ only slightly in sedimentation velocity.     

Isolation of plasma lipoproteins by zonal ultracentrifugation in the B14 and B15 titanium rotors

Lipoproteins were isolated from plasma of man, dog, rabbit, rat, and chicken by ultracentrifugation in continuous density gradients using the B14 titanium and B15 titanium zonal rotors. Both the VLDL and the LDL of human plasma were separated easily from the HDL and from the other more plentiful plasma proteins by centrifugation for only 1 or 2 hr in the B14 or B15 rotor, respectively. Satisfactory separation of the HDL from the more dense plasma proteins was not achieved with these rotors. The human LDL achieved isopycnic equilibrium (d 1.04) on prolonged periods (> 24 hr) of centrifugation in a sucrose-KBr density gradient. The pattern of distribution of cholesterol and phospholipid throughout the density gradient coincided with the pattern of distribution of the lipoprotein-protein measured spectrophotometrically or chemically. The concentration of cholesterol and phospholipid in the lipoproteins isolated by zonal ultracentrifugation agreed with analyses reported for lipoproteins isolated by sequential centrifugation in solutions of increasing density. The lipoproteins isolated by zonal ultracentrifugation were characterized further by their electrophoretic behavior. The fractions which were identified as the LDL (d 1.04-1.05) from all species migrated on paper as a beta-globulin; the LDL from plasma of dogs contained an additional component which has been designated as an alpha(2)-globulin. The fractions which were identified as the HDL from all species migrated as an alpha(1)-globulin. Reaction of human LDL with either rabbit antihuman beta-lipoprotein or rabbit antihuman serum resulted in a single immunodiffusion band. The S(f, 1.063) of the human LDL was calculated to be 6.0. When plasma from humans or rabbits was centrifuged in the B15 rotor, the HDL was not visible as a distinct peak and was not separable from the bulk of the more dense plasma proteins; when plasma from dogs or chickens was centrifuged under identical conditions, the HDL was clearly detectable. Even though the mean density of the HDL from dogs or chickens was not different from that of man or rabbits, the visibility of this lipoprotein in dogs and chickens was probably due to its high concentration in the plasma of these species. When plasma from the rat was centrifuged under similar conditions, the HDL was also clearly in evidence. Although rat plasma contained a relatively small concentration of HDL, the lipoprotein had a lower mean density than did the HDL of the other species and was therefore more easily separable from the dense plasma proteins. The procedure of zonal ultracentrifugation for the isolation of lipoproteins by flotation is simultaneously preparative and analytical and should find useful application in the investigation of the soluble lipoproteins from plasma and tissues.     

A Zonal Density Gradient Centrifuge for Separating Cytoplasmic Granules from Trypanosoma brucei

SYNOPSIS. A small zonal density gradient centrifuge has been designed and constructed for the separation of cell granules from Trypanosoma brucei. Two distinct bands were obtained on a simple sucrose density gradient of the following granules which were found in corresponding fractions of the effluent by electron microscopy: Type I granules (lysosomes) which formed a clear-cut band toward the periphery of the rotor, and Type II (endoplasmic reticular) granules which formed a more diffuse band and showed great diversity of size, shape and state of aggregation. This aggregation is related to the structure of these granules which are formed in the endoplasmic reticular tubules and are therefore not easily dispersed during rupture of the cell body.     

Theory and practice of centrifugal elutriation (CE)

Centrifugal elutriation (CE) is currently a widely used preparative cell separation technique. In order to optimize the separation of cells that show only small differences in sedimentation velocity, several conditions that might influence the resolution capacity, such as rotor speed, counterflow, jetstream, cell load, density, and viscosity of the elutriation medium, were analyzed. Experiments carried out with human red blood cells (rbc) indicated that aselective losses of rbc from the rotor caused by the jetstream, could be prevented if the separations were carried out at high rotor speeds, as predicted by the theory. In addition, high cell loads (5×10⁸ rbc) resulted in better separations than low cell loads (5×10⁷ rbc). Human monocytes were separated into subpopulations that differed only about 0.003 g/mL in density, but have virtually the same size. The separation was carried out either by increasing the density or viscosity of the elutriation medium or by decreasing the rotor speed. In all cases similar results were obtained. These results indicated that under optimal conditions CE can be applied for the separation of cells that differ only slightly in sedimentation velocity.     

Purification of very high density lipoproteins by differential density gradient ultracentrifugation

Differential density gradient ultracentrifugation procedures, utilizing a vertical rotor, were developed for the preparative purification of very high density lipoproteins (VHDL, density greater than 1.21 g/ml). The VHDLs of several insect species were purified as follows. An initial density gradient ultracentrifugation step removed lipoproteins of lower density from the VHDL-fraction, which partially separated from the nonlipoproteins present in the infranatant. A complete separation was achieved by a second centrifugation step employing a modified gradient system. The use of a vertical rotor and specially designed discontinuous gradients allows a relatively fast, efficient, and economical isolation of the class of very high density lipoproteins. Similar gradient systems should be useful for the detection and purification of VHDLs from other sources.     

Advantages and limitations of density gradient ultracentrifugation in the fractionation of human serum lipoproteins: role of salts and sucrose

Two density gradient ultracentrifugation methods, Redgrave et al. (1975. Anal. Biochem. 65: 42-49) and Nilsson et al. (1981. Anal. Biochem. 110: 342-348), currently used for the separation and analysis of plasma lipoproteins were compared with respect to their resolving power and capacity to obtain pure products as a function of time of ultracentrifugation using the same rotor (Beckman SW-40), speed (150,000 g), and temperature (14 degrees C). The effects of sucrose and salts were also investigated. The Redgrave gradient insured the separation of the major classes of plasma lipoproteins after 24 hr of centrifugation; however, equilibrium conditions were only reached after 48 hr, at which time the lipoproteins were contaminated by albumin. When the effluents from each rotor tube were continuously monitored at 280 nm, each lipoprotein band gave values that were higher than those from mass analyses. This was due to a light scattering effect, the extent of which was dependent on the concentration of lipoproteins and salts. Sucrose prevented the scattering effect and was found to bind irreversibly to the apolipoproteins. In contrast, after 66 hr centrifugation, the lipoproteins obtained from the Nilsson gradient exhibited a close correspondence between protein mass and absorbance values at 280 nm, had no scattering effect, and were uncontaminated by albumin. The difference in spectroscopic behavior between the Redgrave and the Nilsson procedures was attributed to three factors: 1) the presence of sucrose in the latter gradient and incorporation of this sugar into lipoproteins as assessed by mass and radioactivity measurements; 2), the salt density to which the serum samples were exposed to at the beginning of the ultracentrifugation; and 3) the final lipoprotein concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Centrifugal separation of carcinoma or atypical cells in voided urine

A simple density gradient method was used to separate atypical and cancer cells from non-cancer cells in voided urine from patients with transitional cell atypia (moderate and grave atypia) and bladder cancer (squamous cell carcinoma and transitional cell carcinoma). Prior to cell separation, the Saccomanno preserved cells were dispersed by homogenization. After cell separation (5 min x 1400 rpm), atypical and cancer cells were enriched up to 20-fold. Also, most of the leucocytes (68-98%) and squamous cells (47-82%) were absent from density gradient specimen fractions containing the largest percentages of atypical and cancer cells. Peak purity ranges of atypical or cancer cells from different sample classes showed a large degree of overlap. This permitted the pooling of density gradient fractions enriched for atypical or cancer cells, thus increasing the efficiency of the method. Also, following centrifugation, the Papanicolaou-stained specimen fractions showed less background staining than the unprocessed controls, and the cells retained diagnostic morphologic features. We infer that this method may be a useful, low-cost approach for the morphologic study of developing cancers, not only from the urinary bladder, but also from the respiratory tract.