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.     

Only multimeric hensin located in the extracellular matrix can induce apical endocytosis and reverse the polarity of intercalated cells.

When an intercalated epithelial cell line was seeded at low density and allowed to reach confluence, it located the anion exchanger band 3 in the apical membrane and an H+-ATPase in the basolateral membrane. The same clonal cells seeded at high density targeted these proteins to the reverse location. Furthermore, high density cells had vigorous apical endocytosis, and low density cells had none. The extracellular matrix of high density cells was capable of inducing apical endocytosis and relocation of band 3 to the basolateral membrane in low density cells. A 230-kDa extracellular matrix (ECM) protein termed hensin, when purified to near-homogeneity, was able to reverse the phenotype of the low density cells. Antibodies to hensin prevented this effect, indicating that hensin is necessary for conversion of polarity. We show here that hensin was synthesized by both low density and high density cells. Whereas both phenotypes secreted soluble hensin into their media, only high density cells localized it in their ECM. Analysis of soluble hensin by sucrose density gradients showed that low density cells secreted monomeric hensin, and high density cells secreted higher order multimers. When 35S-labeled monomeric hensin was added to high density cells, they induced its aggregation suggesting that the multimerization was catalyzed by surface events in the high density cells. Soluble monomeric or multimeric hensin did not induce apical endocytosis in low density cells, whereas the more polymerized hensin isolated from insoluble ECM readily induced it. These multimers could be disaggregated by sulfhydryl reagents and by dimethylmaleic anhydride, and treatment of high density ECM by these reagents prevented the induction of endocytosis. These results demonstrate that hensin, like several ECM proteins, needs to be precipitated in the ECM to be functional.     

Eight types of endocrine cells in the abomasum of sheep

In the ovine abomasum, 8 types of endocrine cells were classified at ultrastructural level. The gastric-type EC cells contained oval and pleomorphic granules with high electron density. The intestinal-type EC cells were filled with oval, irregular and highly dense granules. ECL cells contained irregular granules with high density and wide clear spaces. D cells were filled with round granules showing low to moderate density and finely granular matrix D1 cells contained round or oval granules with variable, low to moderate density and finely granular content. G cells showed round and oval granules with moderate density, densely packed or flocculent content. F cells were filled with oval or elliptic granules showing low density with a finely granular and flocculent matrix. X cells contained round granules with high density and homogeneous material. Gastric-type EC cells, intestinal-type EC cells, D cells, and D1 cells were represented in the cardiac, fundic and pyloric gland areas of the ovine abomasum. ECL cells and F cells were confined to the fundic glands, G cells and X cells to the pyloric glands.     

Buoyant density of Escherichia coli is determined solely by the osmolarity of the culture medium

In previous studies, we had shown that the buoyant density ofEscherichia coli is determined by the osmolarity of the growth medium by varying the osmolarity of the medium with NaCl or sucrose. However, the buoyant density of the cells always exceeded that of the growth medium. Here we determined the effect of medium with a buoyant density greater than the expected buoyant density of cells by adding Nycodenz to Luria broth. Percoll gradients of cells were analyzed by laser light scattering. The buoyant density for 125- and 375-mOsM-grown cells was 0.002 g/ml and 0.003 g/ml more, respectively, for cells grown in the presence of Nycodenz than those grown without Nycodenz, while the buoyant density of 250-mOsM-grown cells was 0.005 g/ml less for cells grown in the presence of Nycodenz than those grown without Nycodenz. Cells grown in 500-mOsM medium with or without Nycodenz had the same buoyant density. the buoyant density of cultures grown in defined medium was the same as those grown in rich medium, with only the medium osmolarity correlating to buoyant density. We conclude from these experiments that neither buoyant density nor chemical make-up of the medium determines the buoyant density of cells grown in that medium. Only the medium osmolarity determines cell buoyant density, suggesting thatE. coli has no mechanisms to sense buoyant density.     

Murine mesenchymal stem cell isolated and expanded in low and high density culture system: surface antigen expression and osteogenic culture mineralization

Marrow culture from mice has been reported to be overgrown by non-mesenchymal cells. In almost all protocols for isolation of murine mesenchymal stem cells (MSCs), high density culture systems have been employed. Since MSCs are colonogenic cells, the initiating cell seeding density may have significant impact on their cultures. This subject was explored in this study. For this purpose, the bone marrow cells from NMRI mice were plated at 2.5 × 10⁶ cells/cm² and upon confluency were reseeded as either low density (50 cells/cm²) or high density (8 × 10⁴ cells/cm²) cultures. The cells were expanded through an additional subculture and the passage 2 cells as a product of two culture systems were statistically compared with respect to their surface antigen profiles and osteogenic culture mineralization. While low density culture grew with multiple colony formation, there were no distinct colonies in high density cultures. In contrast to high density cultures, passage 2 cells from low density system possessed typical homogenous fibroblastic morphology. Some cells from high density system but not the low density cultures expressed hematopoietic and endothelial cell markers including CD135, CD34, CD31, and Vcam surface antigens. Furthermore, osteogenic cultures from low density system displayed significantly more mineralization than those from high density system. Taken together, it seems that low density culture system resulted in more purified MSC culture than its counterpart as high density culture system.     

Contact-mediated changes in cytoagglutination.

Cytoagglutination with Concanavalin A was studied in SV3T3 cells as a function of cell density. Agglutinability was low in subconfluent cultures (midpoint concentration 200 μg/ml) buth high in multilayered cultures (midpoint concentration 10–15 μg/ml). Normal 3T3 cells retained low agglutinability (midpoint concentration 1000 μg/ml) even when seeded at superconfluent density. By growing SV3T3 cells at low and at high density in the same culture dish it could be excluded that density modulation of cytoagglutination was caused by differences in pH or nutrient supply. Changes in the density of ConA binding sites or in ATP concentration could not account for the 20-fold difference in agglutinability between cells from high and low density regions. Cell kinetic studies demonstrated that all cells in high and low density cultures were in log phase of growth, differing only in the amount of intercellular contact. In Py-BHK cells, density modulation of agglutinability was much less demonstrated. Unlike SV3T3 cells, these cells rearranged on the substrate when seeded at low density to form clusters of cells with intensive overlapping contact. The results suggest that in transformed cells, cell-to-cell contact is a major determinant of high agglutinability which therefore seems the result, rather than the cause, of uncontrolled growth.     

Density dependent growth of corneal endothelial cells cultured in vitro

Using the cornea of macaque monkey, we demonstrated the relationship between cell density and growth of endothelial cells in vitro. Corneal endothelial cells in a cell sheet grow most actively in regions with cell density of 1000 to 1800 cells/mm2, in explant cultures and cell sheets and in concentrated inocula dissociated cells. Cell morphology was well sustained in these cultures. Cells cultured at a higher cell density retained their potential to proliferate actively, showing clear contrast to cells cultured at a density lower than 200 cells/mm2. When dissociated cells were cultured at a low density and maintained for more than 4 weeks, they gradually lost their growth potential, altered into polymorphonuclear giant cells and eventually dedifferentiated. In addition, cells with no contact with each other did not express growth potential. Density dependent growth was confirmed by measuring the mitotic index against the cell density per square mm from the center to the peripheral regions in cultured explants. It is concluded that the growth pattern of corneal endothelial cells is closely related to cell density, and that growth of these cells might be regulated through intercellular communications.     

Purification of Competent Cells in the Bacillus subtilis Transformation System

Transformed cells have been separated from nontransformed cells by centrifugation on a density gradient of Renografin-76. Separation was achieved both on a linear gradient and on a discontinuous gradient. Under optimal conditions, all of the cells in one band (median density, 1.110 g/ml) were transformants, whereas virtually all cells in the other (median density, 1.131) were nontransformants. In some instances, recentrifugation of the transformant band further enriched the transformant population. The transformed population can also be enriched by zonal centrifugation in a linear gradient of Ficoll. However, this technique is far less efficient than centrifugation in Renografin-76. Since the density of competent cells is identical to that of transformants, we conclude that the low density is a property of competent cells. The significance of this low density to the physiology of competent cells is discussed.     

SEPARATION OF HELA CELLS BY COLLOIDAL SILICA DENSITY GRADIENT CENTRIFUGATION : I. Separation and Partial Synchrony of Mitotic Cells

Using a colloidal silica density gradient, HeLa cells in mitosis were found to have a density of 1.040–1.046 g/cc, lighter than the remaining interphase cells. The mitotic cells could be harvested and cultured after centrifugation, showing growth synchrony by measurement of a peak in mitotic index 21 hr after establishing the culture. By using Colcemid or vinblastine sulfate, HeLa cells were arrested in metaphase and centrifuged on the colloidal silica density gradient. The blocked metaphase cells were lighter in density than the interphase cells but somewhat more dense than untreated cells selected by the density gradient centrifugation. Near-equilibrium conditions were established during the centrifugation of cells so that cell density measurements could be made, and the gradient medium employed was not measurably toxic to those cells tested.     

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

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

白条草蜥消化道内分泌细胞的免疫组织化学

应用6种胃肠激素抗血清和免疫组织化学ABC法(avidin-biotin complex method),对白条草蜥(Takydromus wolteri)消化道内分泌细胞进行了免疫组织化学定位研究和形态学观察。结果表明,5-羟色胺细胞较其他5种内分泌细胞的分布更为广泛,整个消化道中(即从食管到直肠)均有分布,其分布密度高峰位于幽门。食管、回肠和直肠未检测到生长抑素细胞,生长抑素细胞在幽门部分布密度最高,总体来说生长抑素细胞的分布在胃部较高而在小肠部较低。胃泌素细胞和胰多肽细胞分布在小肠,均在十二指肠分布密度最高。胰高血糖素细胞在胃幽门部分布密度最高,十二指肠、空肠次之,回肠分布密度最低。P-物质细胞仅分布于幽门部。6种内分泌细胞以圆形和锥体形为主,它们广泛分布于消化道黏膜之间、腺泡上皮细胞之间及上皮细胞基部。内分泌细胞的密度分布与其食性、食物组成和生活环境有关,它们的形态与其内、外分泌功能是相适应的。     

Regulation of concanavalin A agglutination by the extracellular matrix

The agglutinability of rat C₆ glioma cells by concanavalin A (Con A) depends upon cell density. From sparse density to near confluency agglutinability increases as cell density rises. Both the half-maximal concentration and the maximum amplitude of agglutination by Con A are functions of cell density, but are separate cell parameters differing in the extent to which they are affected by density and the point at which they become insensitive to further density increases. Both trypsin and EDTA reduce cell agglutinability. The similarity in recovery kinetics between low density cells and cells dissociated with EDTA or trypsin suggests that low density cells may lose the same surface agglutination component(s) removed by trypsin and EDTA. Density-dependent regulation of Con A agglutinability is anchorage dependent; cells grown in suspension display no such phenomenon. The cooperative cell regulation of agglutinability is mediated by the extracellular matrix, or micro-exudate. The matrix contains two activities: low density cultures produce a matrix inhibitor of Con A agglutinability, while high density cultures produce a matrix promotor.     

Buoyant density studies of several mecillinam-resistant and division mutants of Escherichia coli.

The buoyant density of wild-type Escherichia coli cells has previously been reported not to vary with growth rate and cell size or age. In the present report we confirm these findings, using Percoll gradients, and analyze the recently described lov mutant, which was selected for its resistance to mecillinam and has been suggested to be affected in the coordination between mass growth and envelope synthesis. The average buoyant density of lov mutant cells was significantly lower than that of wild-type cells. Similarly, the buoyant density of wild-type cells decreased in the presence of mecillinam. The density of the lov mutant, like that of the wild type, was invariant over a 2.8-fold range in growth rate. In this range, however, the average cell volume was also constant. Analysis of buoyant density as a function of cell volume in individual cultures revealed that smaller (newborn) lov mutant cells had higher density than larger (old) cells; however, the density of the small cells never approached that of the wild-type cells, whose density was independent of cell size (age). A pattern similar to that of lov mutant cells was observed in cells carrying the mecillinam-resistant mutations pbpA(Ts) and rodA(Ts) and the division mutation ftsI(Ts) at nonpermissive temperatures as well as in wild-type cells treated with mecillinam, but not in mecillinam-resistant crp or cya mutants.     

Differential effects of interleukin 2 vs B cell growth factor on human B cells

The effects of recombinant interleukin 2 (IL-2) and high m.w. (HMW) B cell growth factor (BCGF) were examined on normal human peripheral blood B cells activated with Staphylococcus aureus Cowan I (SAC). When SAC-activated B cells were separated into Tac-antigen (Tac-Ag)+ and Tac-Ag- fractions by a cell sorter, recombinant IL-2 induced only the Tac-Ag+ cells to proliferate, whereas both Tac-Ag+ and Tac-Ag- cells responded to HMW-BCGF (m.w. 60,000). Alternatively, SAC-activated B cells were separated according to density into three fractions: low density (large) cells (82 +/- 15% Tac-Ag+), intermediate density (medium) cells (45 +/- 13% Tac-Ag+), and high density (small) cells (less than 5% Tac-Ag+). Recombinant IL-2 enhanced proliferation of low density cells the most, intermediate density cells less, and high density cells not at all. HMW-BCGF induced all three fractions to proliferate to approximately the same degree. Finally, the effects of IL-2 and BCGF on the DNA and RNA content of the various fractions of B cells was examined. RNA content was greater in IL-2-stimulated B cells than BCGF-stimulated B cells, whereas DNA content was the same in both cell populations. IL-2 and BCGF may preferentially interact with different subpopulations of B cells. The interaction of IL-2 or BCGF with normal activated B cells may induce both similar and different intracellular events.     

Hensin remodels the apical cytoskeleton and induces columnarization of intercalated epithelial cells: processes that resemble terminal differentiation

Intercalated epithelial cells exist in a spectrum of phenotypes; at one extreme, beta cells secrete HCO3 by an apical Cl/HCO3 exchanger and a basolateral H+ ATPase. When an immortalized beta cell line is seeded at high density it deposits in its extracellular matrix (ECM) a new protein, hensin, which can reverse the polarity of several proteins including the Cl/HCO3 exchanger (an alternately spliced form of band 3) and the proton translocating ATPase. When seeded at low density and allowed to form monolayers these polarized epithelial cells maintain the original distribution of these two proteins. Although these cells synthesize and secrete hensin, it is not retained in the ECM, but rather, hensin is present in a large number of intracellular vesicles. The apical cytoplasm of low density cells is devoid of actin, villin, and cytokeratin19. Scanning electron microscopy shows that these cells have sparse microvilli, whereas high density cells have exuberant apical surface infolding and microvilli. The apical cytoplasm of high density cells contains high levels of actin, cytokeratin19, and villin. The cell shape of these two phenotypes is different with high density cells being tall with a small cross-sectional area, whereas low density cells are low and flat. This columnarization and the remodeling of the apical cytoplasm is hensin-dependent; it can be induced by seeding low density cells on filters conditioned by high density cells and prevented by an antibody to hensin. The changes in cell shape and apical cytoskeleton are reminiscent of the processes that occur in terminal differentiation of the intestine and other epithelia. Hensin is highly expressed in the intestine and prostate (two organs where there is a continuous process of differentiation). The expression of hensin in the less differentiated crypt cells of the intestine and the basal cells of the prostate is similar to that of low density cells; i.e., abundant intracellular vesicles but no localization in the ECM. On the other hand, as in high density cells hensin is located exclusively in the ECM of the terminally differentiated absorptive villus cells and the prostatic luminal cell. These studies suggest that hensin is a critical new molecule in the terminal differentiation of intercalated cell and perhaps other epithelial cells.     

Observations consistent with autocrine stimulation of hybridoma cell growth and implications for large-scale antibody production

Existence of autocrine growth factors (aGFs) may influence the serum requirement for growth of hybridoma cells and thus significantly influence process economics. For the murine hybridoma cell line S3H5/2bA2, critical inoculum density (cID) and serum requirement for growth were inversely related for cultivation in both T flasks and spinner flasks. In spinner flasks, an inoculum density of 10⁶ cells/ml was necessary for the cells to grow in RPMI 1640 medium without serum supplement, and an inoculum density of 10³ cell/ml was necessary in RPMI 1640 medium with 10% serum. In T flasks, where the local cell density is higher than in spinner flasks, an inoculum density of 10⁶ cells/ml was necessary for the cells to grow in RPMI 1640 medium without serum supplement, and an inoculum density of 1 cell/ml was also necessary in RPMI 1640 medium with 10% serum. Further, immobilized cells at high local cell density could grow under conditions where cells in T flasks at corresponding overall cell density could not grow. The cells at high inoculum density were less sensitive to shear induced by mechanical agitation than the cells at low inoculum density. Taken together these observations support the existence of secreted aGF(s) by the hybridoma cell line used. Since the specific MAb production rate was independent of cultivation method and inoculum density, the existence of autocrine growth factors would suggest that the use of immobilized cells should improve the economics of MAb production.     

Preliminary characterization of accessory cells in the nonadherent fraction of human blood mononuclear cells

We investigated why peripheral blood mononuclear cells rigorously depleted of adherent cells by sequential incubation on plastic and nylon wool remained fully responsive to both antigenic and mitogenic signals. Nylon wool nonadherent cells (NWNA) depleted of cells expressing HLA-DR by monoclonal antibody and complement lysis did not respond to tetanus toxoid (TT) or suboptimal concentrations of phytohemagglutinin (PHA). Addition of adherent accessory cells to these NWNA HLA-DR- cells reconstituted the response to stimuli. NWNA, fractionated by discontinuous density gradient centrifugation, contained high density cells which were unresponsive alone to optimal concentrations of both TT and PHA. All the lower density fractions contained cells which were accessory for higher density cell responses to stimuli. The lowest density fraction was approximately 30% monocytes (esterase and peroxidase positive) and less than or equal to 3% B lymphocytes (surface IgG bearing). The other low density fractions contained large granular lymphocytes but rarely monocytes and no B lymphocytes. Depletion of OKT3+, OKM1+, and Leu-11+ cells from lower density cells by monoclonal antibody and complement lysis did not abolish their accessory activity, but depletion of HLA-DR+ cells or gamma irradiation of these cells decreased their accessory activity for PHA and eradicated accessory activity for TT. Thus, the responsiveness of NWNA to soluble antigenic and mitogenic signals is due, in part, to the presence of low density cells which are radiosensitive and phenotypically HLA-DR+ OKT3-OKM1-Leu-11-. Accessory activity in NWNA seems to reside, therefore, in a cell which is not a typical monocyte, natural killer cell, nor B or T lymphocyte.     

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.     

Differences in intramembrane particle distribution in young and old human erythrocytes

The distribution of intramembrane particles in human erythrocytes was studied by freeze-fracture on young and old cells and compared to that obtained after ATP depletion or following addition of a clustering agent. It was shown that intramembrane particles became aggregated and the mean particle density increased as the cells aged. Likewise, both particle aggregation and increased density were found in young cells after moderate ATP depletion. In contrast, mean particle density was markedly reduced in both cell types after exhaustive depletion. Paradoxically, Zn treatment led to decreased particle density in young cells, whilst producing the opposite effect in aged cells. The results suggest that their low ATP content may account for the increased particle density of senescent cells.     

Role of serum components in density-dependent inhibition of growth of cells in culture. Platelet-derived growth factor is the major serum determinant of saturation density

The effects of platelet-derived growth factor and plasma components on saturation density in cultures of 3T3 cells were investigated. Both of these components of whole blood serum affect saturation density; however, when 3T3 cells become quiescent at high density in medium containing whole blood serum, only platelet-derived growth factor and fresh whole blood serum are capable of stimulating proliferation. Addition of fresh plasma- derived serum has little effect on cell growth. These results suggest that the platelet factor is the major determinant of saturation density in cultures of 3T3 cells maintained in medium supplemented with whole blood serum. Experiments were performed to investigate the mechanism by which platelet-derived growth factor regulates saturation density. We investigated the possibilities of inactivation of growth factors by proliferating cells, and the effects of cell density on the response of 3T3 cells to platelet-derived growth factor. The amount of platelet- derived growth factor required to initiated DNA synthesis increases with increasing cell density. Some inactivation of growth factors by growing cells was detected, but this depletion was only evident at high cell density. We propose that density-dependent inhibition in cultured 3T3 cells is the result both of an increased requirement for the platelet- derived growth factor as the cultures become more crowded and of inactivation of growth factor activity by growing cells.