Babesia bovis: purification and concentration of merozoites and infected bovine erythrocytes

Babesia bovis merozoites, externalized by removal of infected erythrocytes from ordinary culture conditions, were completely separated from red blood cells and stroma by centrifugation in a Percoll gradient. A merozoite band formed at a point corresponding to about 1.087 g/ml specific density. Infected red blood cells were concentrated approximately fourfold to obtain greater than 49.0% parasitemia after centrifugation in Percoll. Most highly enriched fractions positioned between 1.121 and 1.123 g/ml specific density. Full parasite viability was retained.     

Separation of Non-filamentous Micro-organisms from Soil by Density Gradient Centrifugation in Percoll

Soil suspensions were homogenized, and desorbed non-filamentous micro-organisms were concentrated in a minimum volume of buffer by low speed centrifugation. The cells were separated from inanimate material by flotation at the interface between the buffer and a silica sol/polyvinyl pyrrolidone density gradient medium (Percoll). Cell suspensions were removed from the interface and fractionated according to density by high speed centrifugation on discriminating density gradients in Percoll.
Preliminary experiments indicated that most non-filamentous soil micro-organisms had densities in the range 1.081–1.123 g%sol;ml while Rhizobium isolated from crushed root nodules on Percoll was split into two bands of densities 1.081–1.110 and 1.041–1.073 g/ml. The lighter cells were the more pleomorphic.
The efficiency of extraction of cells from soil was governed by the extent of their desorption from inanimate particles. As rigorous desorption procedures damage cells, extraction efficiencies were low; 10–20% of cells counted microscopically in soil were recovered from density gradients. Electron microscopy of soil micro-organisms isolated by this method showed an unusual range of surface ornamentations on cell-like structures of bacterial dimensions.     

Percoll and Ficoll self-generated density gradients by low-speed osmocentrifugation

Percoll and Ficoll self-generated density gradients can be obtained by low-speed centrifugation of their solutions within dialysis cells. Useful Percoll density gradients can be obtained after 10-30 min centrifugation at 220-2010g, within dialysis cells. Ficoll density gradients, which are more difficult to self-generate, can be obtained by the same technique. Red cell band formation in a Percoll density gradient can be done in a single step by using dialysis cells as the centrifugation solution container.     

人卵巢颗粒细胞的体外培养方法探讨

目的建立人卵巢颗粒细胞分离纯化、体外培养的有效方法。方法收集体外受精—胚胎移植(IVF-ET)穿卵时的卵泡液,用胰蛋白酶消化法及密度梯度离心法分离纯化颗粒细胞并用不同培养基进行培养。结果用体积分数为50%的Percoll细胞分离液分离,DMEM/F12或McCoy’5a液体培养基进行培养,细胞纯度高,存活率高,后续生长良好。结论建立了人卵巢颗粒细胞体外培养的稳定模型,为颗粒细胞的体外研究奠定良好的基础。     

Leghaemoglobin within bacteroid-enclosing membrane envelopes from soybean root nodules

Methods are reported for the preparation from soybean (Glycine max (L.) Merr.) root nodules, of well-washed, intact membrane envelopes containing bacteroids. The intact envelopes are of much lower density than the bacteroids within and therefore only low speed centrifugation (approx. 150 g) may be used. The optimum osmotic strength is 600 mOsm/kg H₂O. The envelope contents were recovered following mild osmotic shock and-or hard centrifugal packing at >10,000 g. Extracts prepared in this way contained leghaemoglobin (identified spectrophotometrically), low-molecular-weight fluorescent materials and other components which are yet to be identified. Envelope leghaemoglobin did not react with specific antibody until the envelopes were ruptured. ¹³¹I-Labelled leghaemoglobin or bovine serum albumin, added during initial breakage of nodule cells, was not released when envelopes were ruptured to release leghaemoglobin. It is therefore concluded that this leghaemoglobin is located within the envelope space and did not arise from adhering or occluded cytosol leghaemoglobin. Based on the number and dimensions of microscopically intact envelopes in these preparations, the concentration within that space was in the range 178–523 M. Based on these estimates, leghaemoglobin within envelopes represented about one third of the total amount present in the nodule cells. Flat-bed isoelectric focusing of partially-purified envelope leghaemoglobin demonstrated that the latter contained all of the leghaemoglobin components previously reported for soybean nodules and an additional minor component focusing between leghaemoglobins a and b.     

Localization of the membrane-associated CTP:phosphocholine cytidylyltransferase in Chinese hamster ovary cells with an altered membrane composition

The subcellular localization of the membrane-associated CTP:phosphocholine cytidylyltransferase was determined in Chinese hamster ovary cells in which the phospholipid composition had been altered by growth in the presence of N-methylethanolamine or treatment with phospholipase C. Cell homogenates were fractionated on Percoll density gradients, and marker enzyme activities were used to determine the location of the cellular membrane fractions. The peak of cytidylyltransferase activity occurred in the gradient at a density intermediate to that of the peaks of endoplasmic reticulum and plasma membrane markers. The profile of cytidylyltransferase activity most closely resembled that of the Golgi membrane marker; however, upon sucrose gradient centrifugation, the profile of the Golgi apparatus was very different from that of cytidylyltransferase. Differential centrifugation suggested a nuclear membrane association of the enzyme. Cytidylyltransferase was associated with a membrane fraction that sedimented when subjected to very low speed centrifugation (65 x g, 5 min). From Percoll gradient fractions, nuclei were identified by microscopy, and they migrated with cytidylyltransferase activity. The data are consistent with a localization of cytidylyltransferase in the nuclear membrane.     

Functional and physical characteristics of rat Leydig cell populations isolated by metrizamide and Percoll gradient centrifugation

The physical and functional properties of Leydig cell populations obtained by centrifugation of testicular cells in two different density gradient media, Percoll and Metrizamide, were compared. Percoll-gradient centrifugation yielded two Leydig cell bands (Peak I and Peak II) that were comparable, as to their density and testosterone-producing capacity, to the respective Leydig cell bands, Population I and Population II, isolated in a Metrizamide gradient. The denser Leydig cell band (II) had a greater capacity for testosterone production than the less dense band (I), regardless of the type of gradient used for its isolation. Metrizamide gradient centrifugation separated the majority of germ cells from the "light" (Population I) Leydig cells, whereas in the Percoll gradient, germ cells comigrated with Peak I Leydig cells. Leydig cell separation by Percoll gradients was highly dependent on the presence of Ca2+ and Mg2+ in the medium, while these cations had no effect on the separation of Leydig cells by Metrizamide. In conclusion, Metrizamide gradient centrifugation yielded two Leydig cell populations of similar functional and physical properties to the respective populations isolated in Percoll gradients.     

Separation of granule subpopulations in human polymorphonuclear leukocytes

Human polymorphonuclear leukocytes were isolated, disrupted by sonification and the nuclei and unbroken cells removed by centrifugation. The supernatant was applied on top of an optimised discontinuous Percoll gradient. After centrifugation we found nine gradient bands of distinct density. Both the nine bands and the whole fractionated gradient material were assayed for granule marker enzymes. Granule fractions of distinct density, enclosing different enzyme concentrations demonstrated the existence of granule subpopulations. There were three subpopulations of azurophil granules, about four subpopulations of specific granules, one granule fraction perhaps representing the C-particles, and a fraction of plasma membrane vesicles.     

Variation in Escherichia coli buoyant density measured in Percoll gradients.

Escherichia coli B/r cells, centrifuged to equilibrium in either self-generating or preformed gradients of Percoll, banded at an average density of 1.080 to 1.100 g/ml, depending on their growth rate and the temperature of centrifugation. Cells cultured in gradient material (70% Percoll) exhibited the same average density. At the various growth rates examined, the density of the individual cells in a steady-state population varied by less than 1% of the mean in E. coli strains B/r and B, as well as K-12. Electron microscope analysis of the density fractions of both fast- and slow-growing E. coli B/r populations suggested a small increase in density during cell constriction.     

Isolation of motile spermatozoa by density gradient centrifugation in Percoll®

A procedure using centrifugation in density gradients composed of Percoll was developed for isolation of spermatozoa from mammalian semen. To evaluate the technique, rabbit, human, or bovine semen was layered over continuous Percoll gradients ranging in density from 1.02 to 1.13 gm/ml and centrifuged at 1,500g for 45 min. After centrifugation, the seminal plasma remained above the gradient, whereas the spermatozoa and seminal particles were distributed within the gradient according to their buoyant densities. Unlike most washing techniques, no sperm pellet was formed; instead, the spermatozoa were concentrated into a compact band above the most dense layer of Percoll. The spermatozoa recovered from the gradient were easily resuspended by gentle techniques. Thus, the mechanical stress to the spermatozoa was minimized. Osmotic stress to the spermatozoa was also negligible as the Percoll gradients were isotonic throughout. Spermatozoa obtained by this technique possessed motility equivalent to that of spermatozoa in the unfractionated semen. Sperm suspensions recovered from the gradients contained less than 5% of the nonspermatozoal particles present in the original samples of unfractionated semen. Soluble seminal components were also efficiently removed from the spermatozoa. Thirty billion bovine spermatozoa could be fractionated on a single gradient without loss of effectiveness. Recovery of spermatozoa from these preparative separations averaged 80%. These results demonstrated that Percoll was a superior medium for efficient density gradient isolation of motile spermatozoa free of contamination by other seminal constituents.     

Prolamellar body and saponins: Avenacosides are not constituents of Avena etioplasts

Etiolated Avena leaf cells were homogenized, then fractionated into four fractions in the presence of salts by differential centrifugation, and intact etioplasts were prepared by Percoll or sucrose density gradient centrifugation. Using thin layer chromatography steroidal saponins, avenacoside A and B were found in the leaf cells and heavy cell fractions which were rich in other cell structures besides intact etioplasts, but not detected in the purified etioplasts. We concluded that saponins are not constituents of the prolamellar bodies in etioplasts.     

Is Urografin density gradient centrifugation suitable to separate nonculturable cells from <Emphasis Type="Italic">Escherichia coli</Emphasis> populations?

The ability of Urografin or Percoll density gradient centrifugations to separate nonculturable subpopulations from heterogeneous Escherichia coli populations was analysed. Bacterial counts (total, active and culturable cells) and flow cytometric analyses were carried out in all recovered bands. After Urografin centrifugation, and despite the different origin of E. coli populations, a common pattern was obtained. High-density bands were formed mainly by nonculturable cells. However, the increase in cell density would not be common to all nonculturable cells, since part of this subpopulations banded in low-density zones, mixed with culturable cells. Bands obtained after Percoll centrifugation were heterogeneous and culturable and nonculturable cells were recovered along the gradient. Thus, fractionation in Urografin cannot be only attributed to changes in buoyant densities during the transition from culturable to nonculturable state. Urografin density gradients allow us to obtain enriched fractions in nonculturable subpopulations from a heterogeneous population, but working conditions should be carefully chosen to avoid Urografin toxicity.     

Membrane Populations of Bovine Choroid Plexus: Separation by Density Gradient Centrifugation in Modified Colloidal Silica

Abstract: The choroid plexus is intimately involved in the production and regulation of the cerebrospinal fluid. Populations of surface membranes from this epithelial tissue were separated by density gradient centrifugation by use of modified colloidal silica (Percoll). A fraction of heavy microsomes (P₃) containing plasma membranes was prepared by differential centrifugation. Membranes in fraction P₃ were mixed with a given concentration of Percoll and density gradients generated during centrifugation. When fraction P₃ was mixed with 20% (v/v) Percoll and centrifuged at 20,000 r.p.m. for 1 h in a 50.2 Ti fixed-angle rotor, membranes containing alkaline phosphatase (AP) were found at a density of 1.037 g/cm³ while those containing NaK ATPase were found at 1.047 g/cm³. With more shallow density gradients using 12% and 14% Percoll, a broad shoulder of AP activity became manifest at densities greater than 1.060 g/cm³ suggesting multiple populations of membranes containing AP. Membranes containing AP could also be separated from membranes containing γ-glutamyl transpeptidase (γ-GTP); this separation was most pronounced in 12% Percoll. The activity of γ-GTP could not be separated from activity of NaK ATPase. Total protein was distributed broadly throughout the gradients. Studies have been undertaken to compare the behavior of choroidal membranes in Percoll gradients with that of renal membranes because the biochemical anatomy of the kidney has been extensively studied. In contrast to choroidal membranes, renal membranes with NaK ATPase activity were found to have densities lower than those membranes with AP. Thus, the distribution of membrane-bound enzymes from kidney in a Percoll gradient was exactly the opposite of that observed for these same enzymes from choroid plexus. In addition, unlike the γ-GTP activity of choroid plexus, γ-GTP from kidney could be separated from the activities of both alkaline phosphatase and NaK ATPase. These marked differences in membrane populations between choroid plexus and kidney as defined by Percoll density gradient centrifugation analyses are presumably reflective of differences in the functions of the two epithelial tissues.     

A rapid one-step method for the isolation of bacteroids from root nodules of soybean plants, utilizing self-generating Percoll gradients

Bacteroids were isolated from the nodules of soybean plants by means of self-generating Percoll density gradients. The entire procedure can be performed in less than 1 h using an ordinary refrigerated centrifuge and angle head rotor. All of the markers for cytosol and bacteroid fractions behaved in accord with other reports in the literature. Asparaginase, beta-hydroxybutyrate dehydrogenase, and alanine dehydrogenase were all localized in the bacteroid fraction. Invertase, phosphoenolpyruvate carboxylase, and leghaemoglobin were all found in the cytosol fraction. Very little (less than 7%) cross contamination between the fractions was observed. The isolated bacteroids were viable, and based on electron micrographs, were free from contaminating plant material. Since the entire procedure is performed isosmotically, very little damage to the bacteroids is likely to occur. No organic compounds, except Percoll, were added to the isolating media, thus aiding in the analysis of bacteroid and cytosol metabolites.     

Isolation and culture of somatotrophs from the pituitary of the rainbow trout: Immunological and physiological characterization

Summary The aim of the present paper was to obtain somatotroph- and gonadotroph-enriched populations from collagenase dispersed pituitaries of male rainbow trout. Inasmuch as the percentage of immunoreactive gonadotrophs and somatotrophs present in pituitaries was higher at spermiation than at the beginning of spermatogenesis, we tried such a cell separation with fish at this stage of spermatogenesis. Cells were fractionated using their differences in buoyant density with centrifugation in Percoll solutions. The use of Percoll linear gradients (1.110 to 1.027 g/ml) showed that somatotroph cells have a density of between 1.102 and 1.064 g/ml whereas gonadotrophs are spread over the range of the gradient. It was thus possible, by using linear or discontinuous Percoll gradients, to obtain 95 to 67% (mean 80%) enriched somatotropic cell fractions while no enriched gonadotropic cell fractions were collected. The fractionated cells kept their ability to be cultured and to be responsive to specific secretagogues. Somatostatine induced a 80 to 85% decrease in growth hormone release per somatotroph in the initial cell suspension as well as in the different cell fractions. On the other hand, the basal growth hormone release per cell was lower in the fractions containing cells with a density lower than 1.062 g/ml. Inversely, the gonadotrophs have a basal release per cell independent of their density, and this is also available for their responsiveness to salmon gonadotropin-releasing hormone.     

A small-scale method for the isolation of insulin-containing secretory granules from islets of Langerhans

A method has been developed which uses small-scale (400 microliter) Percoll gradients and an inexpensive bench-top microcentrifuge for the rapid isolation of insulin-containing secretory granules from islets of Langerhans available from a single rat pancreas. Granule fractions were prepared from homogenates of isolated rat islets by a differential centrifugation step (10 min) to produce a granule-enriched membrane pellet, followed by a further centrifugation (10 min) on a discontinuous Percoll gradient to produce a granule fraction. Measurement of membrane-marker enzyme activities suggested that the yield and purity of granule fractions prepared by this method were comparable to those reported for other methods involving longer centrifugation times in ultracentrifuges. Further purification of the granule fractions by removing lysosomal contamination was achieved by an additional centrifugation (10 min) on another small-scale gradient of higher Percoll concentration. The method proved useful for isolating biosynthetically labeled secretory granule membranes and contents from islets of Langerhans which had been cultured in the presence of 35S-labeled amino acids. The speed and simplicity of this method suggest that it will prove useful in studies requiring the rapid isolation of insulin-containing secretory granules from isolated islets.     

Identification and characterization of monolayer cultures of sheep trophoblast cells maintained in bicameral culture chambers

Enriched epithelial cell and fibroblast fractions were isolated from ovine placentomes by isopycnic centrifugation of collagenase/DNAse-dispersed cells through a density gradient of 45% Percoll. The epithelial cells formed confluent monolayers when plated onto filters impregnated with a 50-microns layer of Matrigel in medium containing 10% fetal bovine serum. These cells were maintained in dual environment culture chambers in serum-free medium for at least 12 days. The epithelium had a polarized appearance similar to that found in vivo only when cells were plated at high density (10(7)/cells/cm2). The epithelial monolayer consisted predominantly of a single population of uninucleate cells with intracellular features similar to those previously described for ovine trophoblast both in vivo and in vitro. These cells stained positively with an antiserum to alpha-keratin, a marker specific to epithelial cells, and no staining was observed with antisera raised against binucleate cells or leucocyte-common antigen. Binucleate cells were detected by microscopy and immunostaining in the pellet of cells obtained from the Percoll gradient but were rarely seen in the epithelium. The epithelial monolayer excluded 3H-inulin, added to the basal chamber, from the apical chamber, thus demonstrating the formation of a permeability barrier similar to that found in vivo. The maintenance of a monolayer of pure ovine trophoblast cells in vitro, which retain the characteristics of the epithelium in vivo, will enable the study of many cellular functions of the trophoblast.     

Enriched populations of rat retinal ganglion cells: Studies using a cell-type specific surface marker

Cells dissociated from adult and neonatal rat retinas were separated by density gradient centrifugation. Previous work had shown that rat retinal cells labelled by an immunofluorescence assay for the Thy-1 antigen were chiefly or exclusively ganglion cells, and so the proportion of Thy-1 positive cells in the density gradient fractions was used as an index of the enrichment of ganglion cells. The proportion of Thy-1 positive neonatal cells was increased from about 0.4% in the initial dissociate to about 8% in the most enriched fraction of a Percoll step gradient. Amongst adult cells the initial 0.7% Thy-1 positive cells were increased to roughly 2% in the best fraction of a metrizamide step gradient.

The presence of relatively large numbers of Thy-1 positive cells in other fractions suggested that it would be difficult to further increase the proportion of rat ganglion cells by methods based on their sedimentation properties. These results demonstrate the importance of cell-type specific markers in attempts to purify cells from the central nervous system.     

Cell fractions from rat rib growth cartilage. Biochemical characterization of matrix molecules

In an attempt to isolate and characterize the putative target cells for growth hormone, chondrocytes were isolated from rat rib growth cartilage and fractionated by centrifugation in a discontinuous Percoll gradient. This resulted in three cell fractions with differing properties. The fraction with the lowest density consisted mainly of large, lipid-containing cells which became flattened in subsequent culture. The cells in this fraction were fair collagen producers but synthesized only minor amounts of proteoglycans and apparently no proteoglycan aggregates. These cells probably originate in the hypertrophy zone of the growth plate. The fraction with highest density, on the other hand, consisted of small cells which upon cell culture became polygonal and surrounded with refractile matrix. They synthesized less collagen, but more proteoglycans than the low-density fraction. The proportion of proteoglycan aggregates was rather low (10-20%) but otherwise the proteoglycans were similar to those synthesized by other chondrocytes. This cell fraction was tentatively identified as cells from the upper part of the growth plate. Finally, the middle fraction was heterogeneous, consisting of cells of varying shape. This fraction synthesized large amounts of both collagen and proteoglycans. In all three cell fractions, type II collagen predominated. There were also minor amounts of (1a, 2a, 3a) collagen, and, in the two denser fractions, of type I collagen.     

Demonstration of an intact complex of epidermal growth factor and its receptor in the endosomes of A-431 cells

The compartmentalization of the epidermal growth factor (EGF) receptors in A-431 cells was studied using centrifugation of the microsomal fraction of these cells in continuous Percoll gradient. The existence of an intact (non-degraded) EGF receptor in plasma membrane and endosome fraction was demonstrated by electrophoretic analysis of in vitro phosphorylated Percoll fractions. No phosphorylated receptor was revealed in lysosomal fraction by this method. The existence of non dissociated EGF-receptor complexes in intracellular compartments 30 minutes after the start of internalization was proven using a synthesized photoreactive labeled EGF derivative (125I-EGF-SANAH). The removing of pH gradient in organellar membranes by 10 mkM of monensin did not affect dissociation from its receptor. The data obtained proved the existence of non-dissociated and non-degraded EGF-receptor complexes in the endosomal compartment of A-431 cells.