Rapid isolation of muscle-derived stem cells by discontinuous Percoll density gradient centrifugation

We investigated relationship between the maturity and density of muscle cells and developed a rapid isolation method to acquire stem cells from skeletal muscle. Mononuclear cells were isolated from the lower hind-limb muscles of 7-d-old male Sprague–Dawley rats and separated by Percoll density gradient centrifugation. After centrifugation, the cells were layered in the interfaces between each Percoll density layer. Flow cytometry was used to investigate the Sca-1, Pax7, CD34, CD45, M-cadherin, and myosin expression of the cells in each density layer. We found that CD45-positive cells were not present in freshly isolated muscle cells. CD34-, Pax7-positive cells were mainly observed at the interface between the 15% and 25% Percoll layers and had a density of 1.0235–1.0355 g/ml. Cells positive for M-cadherin were at the 25–35% Percoll density interface and had a density of 1.0355–1.0492 g/ml. We conclude that because there appears to be a correlation between maturity and density, muscle-derived stem cells may be isolated successfully from the 15–25% Percoll interface.     

Methods for growth of cultured cells in serum-free medium

Mitochondria prepared from skeletal muscle are typically contaminated with sarcoplasmic reticulum fragments and salt-soluble proteins. These contaminants can be removed by density-gradient centrifugation in Percoll. The resulting mitochondria retain both their original state three respiratory rates and their respiratory control ratios. The method has also been adapted to prepare mitochondria from very small tissue samples.     

Skeletal muscle cell populations. Separation and partial characterization of fibroblast-like cells from embryonic tissue using density centrifugation

Cell suspensions from the breast muscles of 10-day old chicken embryos were separated into non-myogenic, fibroblast-like cell fractions and a mononucleated, myogenic cell fraction by Percoll density centrifugation. Isolated populations were characterized by their morphology in both mass cultures and individual macroscopic clones and by the immunocytochemical detection of skeletal muscle- and smooth muscle-specific proteins in individual cells. Cell populations were also characterized by their protein patterns using sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The less dense, non-myogenic cells comprised 16% of the cells. In culture they were predominantly flattened, stellate cells and gave rise to clones lacking myotubes. These fibroblast-like cells were negative for skeletal muscle myosin or muscle type creatine phosphokinase. Less than 0.1% of these cells demonstrated strong fluorescence when stained with anti-desmin or anti-smooth muscle specific actin. This observation suggested that the vast majority of these cells were not related to vascular smooth muscle cells. Also, over 99% of the non-myogenic cells did not display characteristic properties of endothelial cells. The denser myogenic cell fraction comprised over 80% of the cells and in clonal cultures gave rise to about 70% myogenic clones. An additional 30% of clones from this fraction were non-myogenic indicating heterogeneity in this population. We conclude that Percoll centrifugation can be employed for the isolation of myogenic and non-myogenic cell populations directly from the embryonic muscle. Moreover, this procedure allows the direct analysis of cell-specific proteins (e.g., by gel electrophoresis) without the need for cell culturing. The results thus obtained closely reflect the status of the cells in the intact muscle.     

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.     

Isolation of skeletal muscle nuclei

A method for isolation of nuclei from rat skeletal muscle is described. The tissue is homogenized in the presence of Triton X-100, resulting in release of the nuclei from the muscle fibers. A crude nuclear pellet is prepared by differential centrifugation, and further purification is accomplished by centrifugation through dense sucrose. Bovine serum albumin is used to stabilize the nuclei during the isolation procedure. The isolated nuclei have been characterized microscopically and by chemical and enzymatic assay procedures.     

Skeletal muscle cell populations

Summary Cell suspensions from the breast muscles of 10-day old chicken embryos were separated into non-myogenic, fibroblast-like cell fractions and a mononucleated, myogenic cell fraction by Percoll^TM density centrifugation. lsolated populations were characterized by their morphology in both mass cultures and individual macroscopic clones and by the immunocytochemical detection of skeletal muscle-and smooth muscle-specific proteins in individual cells. Cell populations were also characterized by their protein patterns using sodium dodecyl sulfate/polyacrylamide gel electrophoresis. The less dense, non-myogenic cells comprised 16% of the cells. In culture they were predominantly flatiened, stellate cells and gave rise to clones lacking myotubes. These fibroblast-like cells were negative for skeletal muscle myosin or muscle type creatine phosphokinase. Less than 0.1% of these cells demonstrated strong fluorescence when stained with anti-desmin or anti-smooth muscle specific actin. This observation suggested that the vast majority of these cells were not related to vascular smooth muscle cells. Also, over 99% of the non-myogenic cells did not display characteristic properties of endothelial cells. The denser myogenic cell fraction comprised over 80% of the cells and in clonal cultures gave rise to about 70% myogenic clones. An additional 30% of clones from this fraction were non-myogenic indicating heterogeneity in this population. We conclude that Percoll centrifugation can be employed for the isolation of myogenic and non-myogenic cell populations directly from the embryonic muscle. Moreover, this procedure allows the direct analysis of cell-specific proteins (e.g., by gel electrophoresis) without the need for cell culturing. The results thus obtained closely reflect the status of the cells in the intact muscle.     

Biochemical and morphological differences between fibroblasts and myoblasts from embryonic chicken skeletal muscle

Summary Non-myogenic cells were isolated from the breast muscle of 10-day-old chicken embryos employing Percoll density centrifugation. In culture, these cells exhibited the spread out, stellate morphology of fibroblast-like cells. They also exhibited receptor-mediated binding of plateletderived growth factor (PDGF). Such binding was not detected in cultures of predominantly myogenic cells isolated by the Percoll density centrifugation from the same muscle. Percoll-isolated myogenic and fibrogenic cell populations were also analyzed by two-dimensional polyacrylamide gel electrophoresis immediately after removal from the muscle. This analysis revealed at least six polypeptides specific to the fibroblasts but not detected in the myogenic cell population. In addition, at least eight polypeptides found in the myogenic population were barely detectable, or lacking altogether from the fibroblast-like cells. Ultrastructural analysis of the freshly isolated cells demonstrated that the fibroblasts were larger than the myoblasts and that their cytoplasm contained many vesicles. We conclude that the fibrogenic and myogenic cells isolated by Percoll from embryonic muscle express cell type-specific characteristics. Moreover, based on the PDGF binding studies, the fibrogenic cells can be categorized as true fibroblasts.     

Purification of nuclei from a flagellate protozoan, Trypanosoma brucei

A simple and rapid technique is described for the isolation of nuclei from the flagellate protozoan Trypanosoma brucei. Cells were disrupted by nitrogen cavitation in the presence of hexylene glycol which enhances nuclear stability. Isolated nuclei were separated from nuclei trapped with cytoskeletal fragments and flagellae by Percoll density gradient centrifugation. Centrifugation in a medium with increased sucrose concentration greatly improved the separation of free nuclei from those trapped in cell debris. The isolation procedure resulted in the recovery of 34% of the nuclei present in the whole cell suspension. Electron microscopic and chemical analysis indicated that the recovered nuclei were in good condition and were highly purified.     

Carbonic anhydrase in guinea pig skeletal muscle mitochondria

The presence of carbonic anhydrase activity was demonstrated in guinea pig skeletal muscle mitochondria purified by Percoll gradient centrifugation such that contamination by sarcoplasmic reticulum vesicles was less than 5%. Assay of purified heavy sarcoplasmic reticulum vesicles for carbonic anhydrase activity showed these to have somewhat less activity than the mitochondria, so that any contribution by sarcoplasmic reticulum vesicles to mitochondrial activity would be negligible. In agreement with this observation, rabbit skeletal muscle mitochondria prepared by the Percoll method had no detectable activity. Assay of the guinea pig muscle mitochondrial enzyme activity in the presence of Triton X-100 showed a sixfold greater activity than in its absence, indicating a matrix location for the carbonic anhydrase. The enzyme is highly sensitive to the sulfonamide inhibitor ethoxzolamide, with Ki = 8.7 nM. The activation energy obtained from the rate constant for CO2 hydration, kenz with units (mg/ml)-1 s-1, over the range 4 to 37 degrees C was 12.8 kcal/mol. These properties are those expected for a carbonic anhydrase of the CA II class of isozymes, rather than for CA I, CA III, and the liver mitochondrial enzyme CA V.     

Fractionation of cells and subcellular particles with Percoll

At present, centrifugation is the most common method for separation and isolation of cells and subcellular particles. The technique can be used for a wide range of applications. During latter years it has become obvious what a powerful method density gradient centrifugation is, especially when used in conjunction with sensitive assays or clinical treatments. The most active areas for use of density gradient centrifugation include purification for in vitro fertilization of sperm of both human and bovine origin, isolation of cells for cell therapy of patients receiving chemo- and radiation therapy and basic research both on cellular and subcellular levels. These treatments and investigations require homogeneous populations of cells and cell organelles, which are undamaged after the separation procedure. Percoll, once introduced to reduce convection during centrifugation, has proved to be the density gradient medium of choice since it fulfills almost all criteria of an ideal density gradient medium. Recently good results have also been obtained after silanization of colloidal silica particles, e.g. BactXtractor. The latter medium has proved to be useful in recovery of microorganisms from food samples free of inhibitors to the Polymer Chain Reaction (PCR). The separation procedures described for Percoll in this review seem to be applicable to any cells or organelles in suspension for which differences in size or bouyant density exist. Furthermore, since Percoll media are inert, they are well suited for the separation of fragile elements like enveloped viruses.     

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.     

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.     

Fractionation of Different Life Cycle Stages of Microsporidia Nosema grylli from Crickets Gryllus bimaculatus by Centrifugation in Percoll Density Gradient for Biochemical Research

ABSTRACT. A new method of fractionation and purification of different life cycle stages of microsporidia Nosema grylli , parasitizing the fat body of cricket Gryllus bimaculatus , by centrifugation in Percoll density gradient is elaborated. The whole procedure can be summarized as: 1) infected fat body preparation, 2) homogenization in buffer and filtration through cotton wad and filter paper, 3) first centrifuging, resulting in the separation of the pellet into three layers containing different life cycle stages, 4) second centrifuging of the chosen layer in Percoll density gradient, 5) washing out the Percoll from the fraction under study. After centrifugation in Percoll density gradient, meronts and early sporonts form a band in the area corresponding to density 1.016 g/ml. Mature spores form the pellet at the bottom of centrifuge tube, while immature spores are distributed throughout the layer of 1.016 g/ml up to the bottom of the centrifuge tube, according to their buoyant densities. The offered technique is simple, it takes about one hour and may become a routine procedure for biochemical studies on microsporidia.     

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.     

Separation of human endothelial cells from fibroblasts by centrifugation in Percoll gradients

Human endothelial cells from the umbilical vein and skin fibroblasts can be separated by means of centrifugation in a density gradient of Percoll. Cells show a good recovery in culture. Viability is not impaired.     

Nuclear buoyant density determination and the purification and characterization of wild-type neurospora nuclei using percoll density gradients

A procedure has been developed using Percoll density gradients for the isolation and purification of nuclei from germinated conidia of wild-type Neurospora crassa St. Lawrence strain 74A. Crude nuclei were purified isopycnically in gradients of Percoll, which is silica coated with polyvinylpyrrolidone. A DNA:RNA:protein ratio of 1:3.5:6.5 was found in purified nuclei. Cytoplasmic contamination was found to be negligible in the nuclear preparations, as determined by electron microscopy and by following a radioactively-labeled ribosome tag during the isolation procedure. A small amount of endogenous ribonuclease activity was detected in the crude nuclear preparations, but not in suspensions of nuclei purified in the Percoll gradients. Ribosomal RNA was extracted from the nuclei in good yields, and electrophoretic analysis indicated the presence of precursor rRNA molecules, as well as the mature 17S and 25S rRNA species. Using the Percoll gradient system, the buoyant density of purified Neurospora nuclei was determined to be 1.08 grams per milliliter based on refractive index measurements.     

Release of cell-free ice nuclei from Halomonas elongata expressing the ice nucleation gene inaZ of Pseudomonas syringae

Release of ice nuclei in the growth medium of recombinant Halomonas elongata cells expressing the inaZ gene of Pseudomonas syringae was studied in an attempt to produce cell-free active ice nuclei for biotechnological applications. Cell-free ice nuclei were not retained by cellulose acetate filters of 0.2 microm pore size. Highest activity of cell-free ice nuclei was obtained when cells were grown in low salinity (0.5-5% NaCl, w/v). Freezing temperature threshold, estimated to be below -7 degrees C indicating class C nuclei, was not affected by medium salinity. Their density, as estimated by Percoll density centrifugation, was 1.018 +/- 0.002 gml(-1) and they were found to be free of lipids. Ice nuclei are released in the growth medium of recombinant H. elongata cells probably because of inefficient anchoring of the ice-nucleation protein aggregates in the outer membrane. The ice+ recombinant H. elongata cells could be useful for future use as a source of active cell-free ice nucleation protein.     

Rapid Isolation of Rat Brain Nuclei on Percoll Gradients

A rapid isotonic method for fractionation of nuclei from rat brain is described. This procedure is based on the use of discontinuous colloidal silica gel (Percoll) gradients. We start from a 63,000-g purified nuclear pellet (fraction P3) isolated from gray matter and white matter separately. This is followed by fractionation of fraction P3 in an initial differential centrifugation step on five-step Percoll gradients producing six nuclear fractions designated 1, 2, 3 (gray matter) and 4, 5, 6 (white matter). Fractions 2, 4, and 5 obtained from this centrifugation are heterogeneous. These fractions are subfractionated further under isopycnic conditions using five-step Percoll gradients to yield subfractions 2b, 4b, and 5c. Three methods were used to characterize the nuclear types. First, light and electron microscopic examination was used to identify the nuclei in each preparation and to assess the purity of each preparation. Second, the activities of RNA polymerase I and II were monitored. Third, the protein/DNA ratios of the nuclear fractions were determined. Fraction 1 was enriched in neuronal nuclei; fractions 2b and 4b in astrocytic nuclei; and fractions 3, 5c, and 6 in nuclei of oligodendrocytes. RNA polymerase I and II activity was highest in fraction 1, which also displayed the highest protein/DNA ratio. Electron microscopy showed that the various classes of nuclei are congruent to 90% pure. Therefore, the procedure described here is suitable for obtaining highly purified neuronal and three types of glial nuclei from rat brain.     

Electron cytochemistry of oxalate-stimulated calcium uptake in microsomes from the smooth muscle of the pig stomach

Summary A microsomal fraction was isolated from the smooth muscle of the antrum of the pig stomach by differential centrifugation. Electron microscopy of the negatively stained material showed that this fraction is heterogeneous in composition. The microsomes accumulated calcium in the presence of ATP, magnesium and oxalate. The amount of calcium taken up per mg protein was in the same range as observed for other smooth muscle microsomal preparations. Although this amount is much smaller than that in the microsomal fraction of skeletal muscle, calcium oxalate crystals were formed in some vesicles, as occurs in the skeletal muscle fragmented sarcoplasmic reticulum. Through the presence of the calcium oxalate crystals, many of these vesicles acquired sufficient mass and density to allow them to be isolated by centrifugation. A purification of about 40 fold in terms of calcium content was reached.     

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.