Evidence for osmoregulation of cell growth and buoyant density in Escherichia coli.

The buoyant density of cells of Escherichia coli B/r NC32 increased with the osmolarity of the growth medium. Growth rate and its variability were also dependent upon the osmolarity of the medium. Maximum growth rates and minimum variability of these rates were obtained in Luria broth by addition of NaCl to a concentration of about 0.23 M.     

Independence of buoyant cell density and growth rate in Escherichia coli

The relationship between growth rate and buoyant density was determined for cells from exponential-phase cultures of Escherichia coli B/r NC32 by equilibrium centrifugation in Percoll gradients at growth rates ranging from 0.15 to 2.3 doublings per h. The mean buoyant density did not change significantly with growth rate in any of three sets of experiments in which different gradient conditions were used. In addition, when cultures were allowed to enter the stationary phase of growth, mean cell volumes and buoyant densities usually remained unchanged for extended periods. These and earlier results support the existence of a highly regulated, discrete state of buoyant density during steady-state growth of E. coli and other cells that divide by equatorial fission.     

Variation in buoyant density of whole cells and isolated cell walls of Streptococcus faecium (ATCC 9790).

The buoyant density of whole cells of Streptococcus faecium varies with growth rate and during the cell cycle. Two possible explanations for this were explored: (i) the density of cell walls may vary, and (ii) the proportions of wall and cytoplasm may vary. We tested the first possibility by isolating walls from chilled, unfixed populations of S. faecium cells and fractionating them on Percoll density gradients. Mean cell wall density averaged 4% less than whole-cell density and did not vary significantly with growth rate. In addition, walls isolated from heavy and light fractions of a population of cells did not differ significantly in density. Thus, variation in the density of isolated cell walls could not account for the observed variation in whole-cell density within or between populations. Using previously published measurements of the physical dimensions of S. faecium cells, we also found that the relative proportions of wall and cytoplasm (see the second possibility above) could not account for the observed changes in whole-cell buoyant density.     

A programmed cell death pathway activated in carrot cells cultured at low cell density

Programmed cell death (PCD) occurs in plants during development and defense, but the processes and mechanisms are not yet defined. Culture of carrot single cells at a cell density of <10⁴ cells ml⁻¹ activates a cell death process involving condensation and shrinkage of the cytoplasm and nucleus and fragmentation of the DNA. Modest abiotic stress treatments also cause cell condensation and shrinkage and the formation of DNA fragments, but the same abiotic stresses at high levels cause rapid necrosis with cell swelling and lysis. The common morphological features of cells dying at low cell density and following modest abiotic stress treatments suggest that these features reveal a PCD pathway in carrot. The addition of a cell-conditioned growth medium allows cells at low cell density to remain alive, demonstrating that cell-derived signal molecules suppress a pathway that is otherwise induced by default. Differences in the morphology of the dead cells suggest that proteolysis during PCD differs in detail in plants and animals; however, these findings show that plants, like animals, can control PCD by social signaling, and imply that the mechanism of PCD in plants and animals may be similar. Consistent with this, manipulation of signal pathway intermediates that regulate PCD in animals shows that Ca²⁺ and protein phosphorylation events are PCD pathway intermediates in carrot.     

Adherence column and buoyant density separation of bone marrow stem cells and more differentiated cells

Mouse bone marrow cells were separated by adherence column and albumin density gradient procedures, assaying for spleen colony forming units (in vivo CFU's), agar colony forming cells (in vitro CFC's) and cluster forming cells. Column filtrates were enriched for CFU's whereas in vitro CFC's and cluster-forming cells were enriched in adherent fractions. Gradient separation of these column fractions gave density distribution profiles indicating the non-identity and heterogeneity of CFU's and in vitro CFC's.     

Correlation of phenylalanine hydroxylase activity with cell density in cultured hepatoma cells.

We have found that the specific activity of phenylalanine hydroxylase varies over at least a forty-fold range during the growth cycle of Reuber hepatoma (H4) cells growing in monolayer culture. The variation has three phases: (1) a very rapid drop in specific activity upon subculturing to a low cell density; (2) a region of low specific activity and (3) after confluency, a rise to a high specific activity. All the results indicate that the cell density in the culture dish is primarily responsible for this fall and rise in activity. Neither conditioning of the growth medium, the rate of cell division, nor enzyme leakage from the cells appear to play a major role in the changes observed. Lactic dehydrogenase specific activity was determined in all experiments; a much smaller, but still cell density-dependent variation was observed for this enzyme.     

Primary cultured murine hepatocytes but not hepatoma cells regulate the cell number through density-dependent cell death

The mechanisms by which hepatocytes regulate their cell numbers in culture have been examined. We found that when murine hepatocytes were cultured at an overconfluent stage, the number of viable cells were reduced to that of the confluent stage 48 h later by cell death. Cell death was accompanied by LDH release, and it was observed only in primary cultured hepatocytes but not in hepatoma cells. Genomic DNA analysis using electrophoresis showed that DNA fragmentation, a biochemical hallmark of apoptosis, was induced in superconfluent cultures of hepatocytes in a cell-density-dependent fashion, but not in pre-confluent cells. DNA fragmentation was rapidly induced 2 h after the beginning of the in vitro culture and continued up to 24 h later. Flow cytometry analysis demonstrated that the nuclei from the hepatocytes in a high density culture were condensed and that the DNA content was reduced. These data suggest that the mechanism of cell death is apoptosis. The DNA fragmentation seen in the high density hepatocyte culture was not observed in hepatoma cell lines. Moreover, apoptosis was induced in hepatocytes of MRL/lpr mice, suggesting that the Fas antigen was not involved in the apoptotic process. Apoptosis was inhibited by a protein synthesis inhibitor, cycloheximide, and by a calmodulin antagonist, W-7. Taken together, the results indicate that high density culture of murine hepatocytes though not hepatoma cells regulate their cell numbers by an apoptotic mechanism. The apoptosis is dependent on de novo protein synthesis and intracellular calcium metabolism.     

Cell cycle changes in the buoyant density of exponential-phase cells of Streptococcus faecium.

Cell buoyant densities were determined by centrifugation in Percoll gradients containing exponential-phase cells of Streptococcus faecium ATCC 9790 grown at a mass doubling time of about 33 min. This bacterium showed the highest average density values (1.13 g/ml) measured to date for any eucaryotic or procaryotic organism. Fractions having the highest densities were enriched with cells that were in the process of dividing or had just divided. These high-density fractions were also enriched with cells that had newly initiated sites of cell wall growth. It appears that S. faecium shows minimum cell densities in the midportion of its cycle.     

Variations in cell size and buoyant density of Escherichia coli K12 during glycogen accumulation

The effect of glycogen accumulation on buoyant density and volume of Escherichia coli K12 was studied. A procedure consisting of three linear equations is presented. This requires measurement only of three parameters: cell buoyant density, cell volume and specific content of the polymer. Experimental values are then used to calculate intercepts and slopes of the equations by linear regression. From the estimated values of such parameters the in vivo values of several variables of interest can be calculated. These include in vivo density and volume of the glycogen inclusion, as well as density and volume of the structural material in the cell. The results are consistent with the glycogen inclusions being hydrated.     

Immunocytochemical localization of ornithine decarboxylase in cultured murine cells

Summary Antiserum elicited to ornithine decarboxylase (ODC) purified from murine RAW 264 macrophage-like cells has been employed to localize ODC in cultured murine cells. The antiserum immunoprecipitated 100% of the ODC activity from the cultured cells. The specificity of the antiserum was demonstrated by the immunoprecipitation from ³⁵S-methionine metabolically-labeled cell extracts of a single protein which migrated upon SDS-gel electrophoresis coincident with authentic ODC. Indirect immunofluorescence experiments were performed on paraformaldehyde-fixed RAW 264 cells and JB6 epidermal cells using the rabbit anti-ODC antiserum and FITC-conjugated goat anti-rabbit IgG. Little immunofluorescence was apparent in non-stimulated cells. Intense immunofluorescence was detectable in stimulated cells at times of peak cellular ODC activity. Antigenically-reactive ODC was localized diffusely in the cytoplasm and was absent in the nuclei of RAW 264 cells, whereas in the JB6 cells the immunodetectable enzyme protein was localized in a punctate pattern in both the cytoplasm and nucleoplasm and was absent in the nucleolus. The appearance and disappearance of immunoreactive ODC in both cell types after stimulation was consistent with the alterations in ODC activity.     

Insulin receptors on cultured murine lymphoid tumor cell lines

Summary Eight murine lymphoid tumor cell lines have been examined for the presence of high-affinity insulin receptors. The eight cell lines included two Abelson murine leukemia virus-transformed pre-B cell lines, three plasmacytoma cell lines, and three spontaneous T-cell lymphomas from AKR mice. All of the cell lines in the B-cell series had high-affinity insulin binding sites. The apparent equilibrium association constant (K_a) for the high-affinity binding sites on these cells was 1.3–3.3 × 109 M^–1. Two of the T-cell lymphomas had high-affinity receptor levels so low as to be undetectable in the whole cell binding assay under the conditions used for assaying the other cell lines, although in binding assays performed at very high cell densities, these two cell lines did appear to have a small number of high-affinity insulin binding sites. These results indicate that the growth stimulus provided by the tumor virus in neoplastic transformation of the AKR thymic lymphocytes differs from that provided by lectins in blast transformation of lymphocytes in that the neoplastic transforming event does not always result in the emergence of large numbers of high-affinity insulin receptors. In addition, the existence of cell lines such as the T-cell lymphomas that have nearly exclusively low-affinity binding sites suggests that the low-affinity sites may represent a distinct receptor that is not freely interconvertible with the high-affinity receptor.     

Interleukin 2 receptors on cultured murine epidermal Langerhans cells

Rat monoclonal antibodies 3C7 and 7D4 detect two distinct functional regions of the murine interleukin 2 (IL 2) receptor. When studying the emergence kinetics of IL 2 receptors in mixed epidermal cell (EC)-lymphocyte cultures by using 3C7 and 7D4 in an indirect immunofluorescence assay, we regularly encountered a distinctive membrane fluorescence not only on lymphocytes, but also on a subpopulation of cells exhibiting a dendritic morphology. Reasoning that these 3C7/7D4-reactive dendritic cells might represent a subpopulation of epidermal dendritic cells, we studied mouse EC for the presence of 3C7/7D4- reactive cells. Although 3C7/7D4 reactivity was never detected on freshly isolated EC or on epidermal sheets, a small number of 3C7/7D4+ cells was encountered after 24 to 48 hr of culture. These cells exhibited a dendritic shape, expressed Ia antigens, lacked Thy-1 antigens, and displayed the ultrastructural features of Langerhans cells (LC) with the notable exception of Birbeck granules. Although after 24 hr, only 20% of Ia+ EC were 3C7/7D4+, the vast majority of LC displayed 3C7/7D4 binding sites after 4 to 5 days of culture. Preincubation of cultured LC-enriched EC with recombinant human IL 2 prevented subsequent 3C7-but not 7D4-binding to these cells. Western blot analysis of 7D4-reactive material of detergent extracts from LC-enriched EC revealed three bands in the same m.w. range as reported for CTLL cells. These results demonstrate that cultured LC express IL 2 receptors and may bear important implications for a better understanding of growth regulation, differentiation, and immunologic functions of LC.     

Effects of cell density on the neutral glycolipid composition of cultured human brain and glioma cells

Density dependent chain elongation of neutral glycosphingolipids (NGSL) is associated with contact inhibition of mitosis in several normal cultured cell lines. Transformed non-neural cell lines which have impaired contact inhibition frequently lose this biochemical response. To determine if either of these phenomena occur in human neural cells we determined NGSL compositions of cultured glioblastoma multiforme and normal fetal brain cells. Fetal cells generally had more total NGSL than the tumor cells. As a percentage of total NGSL, both cell lines at higher cell densities had larger proportions of ceramide trihexoside and globoside, but smaller proportions of cerebroside. This decrease was mainly in nonhydroxy fatty acid cerebroside of glioma cells, but in hydroxy fatty acid cerebroside of normal fetal brain cells. These results demonstrate that although glioblastoma multiforme cells have markedly impaired growth control, they still preserve density dependent chain elongation of NGSL. A role for this phenomenon in normal cellular growth control has yet to be established.