THE LABELING OF CULTURED CELLS OF ACER WITH [14C]PROLINE AND ITS SIGNIFICANCE

The distribution of the radioactivity from [¹⁴C]proline that is bound in cultured cells of Acer has been determined by electron microscope autoradiography. In this way proline may be related to the cell wall as a morphological entity rather than as a fraction in a biochemical separation of a heterogeneous crop of cells. The cells in culture may vary greatly. Some are active growing, turgid cells, with thin protoplasts tightly pressed against their walls; in others the protoplasts may spontaneously withdraw from the wall; in still others the protoplasts disorganize, and walls thicken and become sculptured as the cells differentiate and even senesce. Different culturing practices may affect the status of the cells, and this, in turn, affects the distribution of radioactivity from proline in the cells. Cells which are actively growing, turgid, and nucleated have the highest grain density in their protoplasts and nuclei; as the protoplasts of such cells withdraw from their walls, they retain the bulk of the radioactivity. On the other hand, in cells which have thickened walls and sparse protoplast contents, the radioactivity is accumulated in their walls. A high content of proline and hydroxyproline-rich protein is, therefore, not a necessary or invariable feature of the cell walls of cultured Acer cells but depends on the state of development of these cells.     

Alternative modes of population growth inhibition in a human lymphoid cell line growing in suspension

Using a human lymphoid cell line grown under continuous culture conditions, two distinct plateau states were induced, either by lack of sufficient medium-supplied nutrient, or by other unknown mechanisms dependent on cell density. Flow microfluorometric measurements show that growth arrest due to nutritional insufficiency results in an accumulation of cells with G1 DNA content. In contrast, growth arrest due to high cell density is not associated with an altered distribution of cells with respect to DNA content as the population progresses from exponential to plateau state growth. Cell size decreases with progression of the plateau state induced by either type of growth arrest. Cells in a plateau state induced by high cell density utilize glucose and incorporate exogenous amino acid into protein at approximately the same rate as exponential cells. Proliferating, high cell density, plateau state cells have cell cycle phase durations similar to exponential cells. The stable, plateau state cell density is maintained by cell loss. No stable, unbound growth inhibitory factor was found in the medium of density-inhibited plateau state cultures.     

Electrolyte and non-electrolyte distribution in the ehrlich ascites tumor cells during the cell cycle

In a previous study, evidence was presented for changes in the state of water and osmotically active solutes during the cell cycle. Total water was constant at 82% (w/w), while the fraction of water that was osmotically active decreased from a maximum during S to a minimum at mitosis. Total Na⁺, K⁺, and C1^? in milliequivalents per liter of cell water remained constant. Therefore, electrolytes are sequestered in the osmotically inactive water. Evidence is now presented that Na⁺ exists primarily as one compartment, with a second, slower compartment appearing during S and disappearing during G2. Na⁺ is completely exchangeable during the entire cell cycle. The distribution of other penetrating solutes was also investigated. When placed in hyperosmotic ethylene glycol solutions, cells first shrink, then swell to their original volumes. ¹⁴C-ethylene glycol distributes in 89% of cell water throughout the cell cycle. However, ¹⁴C-urea distributes in anywhere from 86–100% of the cell water, depending on the stage in the cell cycle. Both solutes are at chemical equilibrium in water in which they are distributed, but they differ in their effects on cell volume. The final volume at which cells equilibrate in urea varies with the concentration of urea in the environment and with time into the cell cycle. Results suggest a loss of osmotically active particles or decreased osmotic activity of urea.     

The relationship between the growth characteristics of somatic cell hybrids and their level of camp and activities of adenylate cyclase and camp phosphodiesterase.

When avian tendon cells are transferred from an in vivo environment to an in vitro environment, they lose their ability to synthesize large amounts of collagen relative to other cell proteins and thereby forgo the hallmark of their differentiated state. This research has systematically investigated the role of various components in the standard cell culture medium in order to decipher why it is an inadequate environment for maintaining differentiated function. The results show that serum levels in excess of 0.5% can be detrimental to a high production of collagen synthesis. The magnitude of this serum effect was also found to be a function of cell density. High cell densities, apparently acting through an increase in the CO₂ concentration, reverse the inhibitory effect of serum. In addition, if the lactate ion concentration is raised to 30 mM (the highest concentration tested), the level of collagen synthesis relative to total cellular protein is restored to its initial level of 30%. Thus, the major differentiated function of avian tendon cells can be retained in cell culture. Moreover, the results appear to implicate high cell density as the normal stabilizing factor in maintaining differentiation in ovo. A high concentration of cells tend to switch the cell metabolism to one which is more anaerobic, thereby favoring high collagen synthesis. Reduction in the cell division rate, which also occurs at high cell densities, does not appear to effect the ratio of collagen to other cell proteins synthesized.     

Control of lens epithelial cell survival

We have studied the survival requirements of developing lens epithelial cells to test the hypothesis that most cells are programmed to kill themselves unless they are continuously signaled by other cells not to do so. The lens cells survived for weeks in both explant cultures and high-density dissociated cell cultures in the absence of other cells or added serum or protein, suggesting that they do not require signals from other cell types to survive. When cultured at low density, however, they died by apoptosis, suggesting that they depend on other lens epithelial cells for their survival. Lens epithelial cells cultured at high density in agarose gels also survived for weeks, even though they were not in direct contact with one another, suggesting that they can promote one another's survival in the absence of cell- cell contact. Conditioned medium from high density cultures promoted the survival of cells cultured at low density, suggesting that lens epithelial cells support one another's survival by secreting survival factors. We show for the first time that normal cell death occurs within the anterior epithelium in the mature lens, but this death is strictly confined to the region of the anterior suture.     

ELECTRON MICROSCOPE STUDY OF MYCOBACTERIUM LEPRAE AND ITS ENVIRONMENT IN A VESICULAR LEPROUS LESION.

Imaeda, Tamotsu (Instituto Venezolano de Investigaciones Cientificas, Caracas, Venezuela) and Jacinto Convit. Electron microscope study of Mycobacterium leprae and its environment in a vesicular leprous lesion. J. Bacteriol. 83:43-52. 1962.-Biopsied specimens of a borderline leprosy lesion were observed with the electron microscope. In this lesion, the majority of Mycobacterium leprae were laden with cytoplasmic components. The bacilli were separated from the cytoplasm of host cells by an enclosing membrane, thus differing from the environment of well-developed lepra cells in lepromatous lesions.The cell wall is composed of a moderately dense layer. A diffuse layer is discernible outside the cell wall, separated from it by a low density space. It is suggested that the cell wall is further coated by a low density layer, although the nature of the outermost diffuse layer has not yet been determined.The plasma membrane consists of a double layer, i.e., dense inner and outer layers separated by a low density space. The outer layer is closely adjacent to the cell wall. In the region where the outer layer of the plasma membrane enters the cytoplasm and is transformed into a complex membranous structure, the inner layer encloses this membranous configuration. Together they form the intracytoplasmic membrane system.In the bacterial cytoplasm, moderately dense, presumably polyphosphate bodies are apparent. As neither these bodies nor the intracytoplasmic membrane system are visible in the degenerating bacilli, it seems probable that these two components represent indicators of the state of bacillary activity.     

Autocrine signals enable chondrocytes to survive in culture

We recently proposed that most mammalian cells other than blastomeres may be programmed to kill themselves unless continuously signaled by other cells not to. Many observations indicate that some mammalian cells are programmed in this way, but is it the case for most mammalian cells? As it is impractical to test all of the hundreds of types of mammalian cells, we have focused on two tissues--lens and cartilage-- which each contain only a single cell type: if there are cells that do not require signals from other cells to avoid programmed cell death (PCD), lens epithelial cells and cartilage cells (chondrocytes) might be expected to be among them. We have previously shown that rat lens epithelial cells can survive in serum-free culture without signals from other cell types but seem to require signals from other lens epithelial cells to survive: without such signals they undergo PCD. We show here that the same is true for rat (and chick) chondrocytes. They can survive for weeks in culture at high cell density in the absence of other cell types, serum, or exogenous proteins or signaling molecules, but they die with the morphological features of apoptosis in these conditions at low cell density. Medium from high density cultures, FCS, or a combination of known growth factors, all support prolonged chondrocyte survival in low density cultures, as long as antioxidants are also present. Moreover, medium from high density chondrocyte cultures promotes the survival of lens epithelial cells in low density cultures and vice versa. Chondrocytes isolated from adult rats behave similarly to those isolated from developing rats. These findings support the hypothesis that most mammalian cells require signals from other cells to avoid PCD, although the signals can sometimes be provided by cells of the same type, at least in tissues that contain only one cell type.     

Osmotic properties of ehrlich ascites tumor cells during the cell cycle

Ehrlich ascites tumor cells were grown and maintained in continuous spinner culture. The population of dividing cells was synchronized by a double thymidine block technique. Cell cycle phases were determined graphically by plotting mitotic index, cell number, and DNA synthesis against time. Changes in the osmotic properties of Ehrlich ascites tumor cells during the cell cycle are described. Permeability to water is highest at the initiation of S and progressively decreases to its lowest value just after mitosis. Heats of activation for water permeability vary during the cell cycle, ranging from 9–14 kcal/mole. Results may imply changes in the state of water in the membrane during the cycle. The volume of osmotically active cell water is highest during S and early G2 and decreases during the mitotic phase, as cells undergo division. Total water content remains stable at 82% (w/w) during the cycle. Total concentration of the three major ions (Na, K, Cl), expressed as mEq/liter total cell volume, does not change. The fraction of total cell water which is osmotically active (Ponder's R) decreased gradually from 0.75 at S to about 0.56 following mitosis. Findings suggest that a fraction of the total water within the cell exists in a “bound” form and is, therefore, incapable of being shifted under the driving force of osmotic pressure. This fraction of bound water increases during the cell cycle. Possible alterations in membrane fluidity and the state of water in the cell are discussed.     

The application of kinematic equations for the study of cell turnover

Cell turnover in renewing populations is accompanied by cell displacement from a site where cells are formed to a location where they are eliminated. Cell displacement reflects genuine streaming, proceeding along a trajectory denominated as tissue radius. In the sagittally sectioned gastro-intestinal crypt the radius extends along one of its cell columns. In each column the cell locations are numbered so that the crypt origin resides at location 1. Since the cell proceeds from the first location and outward, given two locations i and j such that j greater than i, the cell at j is older or more differentiated than the cell at location i, or more generally, state j represents the future state of i while state i represents a past stage for j. Cell displacement on the radius depends solely upon cell production and the acceleration of a cell through location i equals the cell production rate there. Its velocity may be represented by kinematic equations which in the present context acquire dual meaning: either describing cell displacement, or cell production associated with cell displacement. Cell velocities may be derived by following a labelled cell with time or from density distributions of labelled cells along the tissue radius. The first approach is essentially kinematic, while the second regards the density distribution as an analog of mechanical work and since work involves displacement, velocity (and cell production) is derivable from the density distribution. The two estimates are denominated here as time and space estimates. The second approach is essentially morphological, and may be applied during routine examination of histopathological slide and even be computerized.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cell proliferation on hydrogels

Summary The adhesion and proliferation of mammalian fibroblasts (Flow 7000) on the surface of hydrophilic (copolymer ofN-vinyl-2-pyrrolidone and methyl methacrylate) and hydrophobic [polymethylmethacrylate (PMMA) stereocomplex] hydrogels with a wide range in water content were studied morphologically and quantitatively. It was demonstrated that cell proliferation on hydrogels by a static culture method decreased as the water content of the gels increased. However, it is remarkable that the cell proliferation on PMMA hydrogels with a high water content is equivalent to that on glass Petri dishes. The results obtained in the proliferation of cells on the surface of these hydrogels closely correspond to the state of cell adhesion. When fresh medium or air was perfused from the popposite side of the PMMA hydrogel membrane on which the cells were proliferating (perfusion method), the cells continued to grow into a higher density than with the conventional static culture method. In the case of fresh medium perfusion, the amount of proliferated cell was dependent on both the permeability of the membrane and the density of the membrane “scaffolding”. Virus multiplication in the cultured cells increased in proportion to the cell density, whereas the cell function was similar in both culture methods.     

Differential mitogenic effects of methyl isobutyl xanthine and a tumor growth factor on G1-arrested 3T3 T proadipocytes at the predifferentiation GD state and the growth-factor deficiency GS state

Two growth-states exist in the G1 phase of the 3T3 T proadipocyte cell cycle. GD is the arrest state at which proadipocytes must growth-arrest prior to differentiation. GS is the arrest state at which proadipocytes growth-arrest following deprivation of serum or growth factors. In an attempt to further distinguish these arrest states, we have compared the relative ability of a variety of mitogens to induce GD- and GS-arrested cells to initiate DNA synthesis. The data show that GD-arrested cells at both high and low densities can be induced to proliferate by methyl-isobutyl-xanthine (MIX), whereas high and low density GS-arrested cells are not. The data also show that a tumor growth factor can stimulate the proliferation of both high and low density GD- and GS-arrested cells, whereas other agents are poor mitogens for high density GD-arrested cells. We conclude that MIX and a tumor growth factor (TUGF) can serve as probes to study the characteristics of the GD arrest state.     

Metabolic shift analysis at high cell densities

Abstract: In high cell density cultures it is virtually inevitable that the environment to which the cells are exposed is heterogeneous. Thus, with suspended cultures, individual cells are subject to temporal changes in their environment whereas with aggregated or immobilized cells, the culture can be considered as being formed by a number of subpopulations, each with its own environmental characteristics. In addition, in a high cell density environment, high concentrations of end products may negatively influence the growth rate. This may result in the selection of organisms with an altered metabolic behaviour or with a decreased sensitivity to the adverse effects of the product. We discuss the consequences of this heterogeneity with regard to carbon source metabolism in view of the ability of many bacterial species to adapt to environmental conditions. Selection of variant organisms was found to occur with Clostridium butyricum when grown for a prolonged time in a medium containing approx. I-50 mM glucose. In contrast to the original strain, these variants could sustain a high maximal growth rate in the presence of butyric acid. In addition, they had acquired the capacity to spontaneously form aggregates and were able to carry out a completely solventogenic fermentation. Heterogeneous metabolic activity in aggregated cells is demonstrated with cultures of Lactobacillus laevolacticus , an aggregateforming lactic acid bacterium that converts glucose completely to o-lactate. By using microelectrodes, we show that the fraction of metabolically active cells decreases with increasing aggregate size: in larger aggregates steep pH gradients occur with the effect that only the outer layer of the aggregate is metabolically active, i.e. contributes to lactic acid formation, whereas with smaller aggregates all cells remain active. As a result, the net specific lactic acid production rate of the population as a whole is not invariably increased with increased aggregate size.     

Changes in monoclonal antibody productivity of recombinant BHK cells immobilized in collagen gel particles

Animal cell perfusion high density culture is often adopted for the production of biologicals in industry. In high density culture sometimes the productivity of biologicals has been found to be enhanced. Especially in immobilized animal cell culture, significant increase in the productivity has been reported. We have found that the specific monoclonal antibody (MAb) productivity of an immobilized hybridoma cell is enhanced more than double. Several examples of enhancing productivities have been also shown by collagen immobilized cells. Immobilized cells involve some different points from non-immobilized cells in high density culture: In immobilized culture, some cells are contacted together, resulting in locally much higher cell concentration more than 10⁸ cells/ml. Information originating from a cell can be easily transduced to the others in immobilized culture because the distance between cells is much nearer. Here we have performed collagen gel immobilized culture of recombinant BHK cells which produce a human IgG monoclonal antibody in a protein-free medium for more than three months. In this high density culture a stabilized monoclonal antibody production was found with around 8 times higher specific monoclonal antibody productivity compared with that in a batch serum containing culture. No higher MAb productivity was observed using a conditioned medium which was obtained from the high density culture, indicating that no components secreted from the immobilized cells work for enhancing monoclonal antibody production. The MAb productivity by the non-immobilized cells obtained by dissolving collagen using a collagenase gradually decreased and returned to the original level in the batch culture using a fresh medium. This suggests that the direct contact of the cells or a very close distance between the cells has something to do with the enhancement of the MAb productivity, and the higher productivity is kept for a while in each cell after they are drawn apart.     

CELL DEATH,SURVIVAL AND PROLIFERATION IN TETRAHYMENA THERMOPHILA. EFFECTS OF INSULIN,SODIUM NITROPRUSSIDE, 8-BROMO CYCLIC GMP,NG-METHYL-L-ARGININE AND METHYLENE BLUE

Cells of the ciliate Tetrahymena thermophila produce compounds that act as autocrine (paracrine) survival and/or growth factors. 8-Bromo cyclic GMP, sodium nitroprusside, hemin, protoporphyrin IX, human recombinant and bovine insulin were tested for their ability to substitute for the cell-produced factors and stimulate cell survival and proliferation. The cells were inoculated into conical flasks in a nutritionally complete, chemically defined medium at known cell densities from 5 to 5000cells/ml. In unsupplemented medium cells at 5 to 500cells/ml (‘low initial cell density cultures’) died within 8h, whereas cells at 1000 and 5000cells/ml (‘high initial cell density cultures’) proliferated with lag phases lasting for up to 4h. In the presence of insulin compounds, hemin, protoporphyrin IX, or 8-bromo cyclic GMP, cells also proliferated at all low initial cell densities. Sodium nitroprusside was effective over two separate concentration ranges: at the nanomolar levels as well at low pico- to femtomolar levels. At initial population densities of up to 50cells/ml the cells at both concentrations of sodium nitroprusside survived about 4-fold longer than the controls. At 500 initial cells/ml, cells at thehigh concentrations of sodium nitroprusside survived about 4-fold longer than those of the control cultures; they proliferated in the low concentrations of sodium nitroprusside. Concentrations of hemin, too low to have any effects on their own, had synergistic effects with sodium nitroprusside. N^G-methyl-L-arginine inhibited proliferation at high initial cell densities. This inhibitory action was reduced by high concentrations of L-arginine, protoporphyrin IX, sodium nitroprusside, or 8-bromo cGMP, but not by insulin. Methylene blue inhibited cell proliferation at high initial cell densities. This inhibition was circumvented by addition of 8-bromo cGMP. The findings that insulin-related material may be released from Tetrahymena and that insulin and sodium nitroprusside increase intracellular cGMP in these cells are discussed in relation to the presented results. Together these observations suggest that cGMP is responsible for supporting cell survival in Tetrahymena and switching the cells into their proliferative mode, and that cell-produced signal molecules and insulin stimulate an NO-dependent guanylate cyclase into producing cGMP.     

Specific suppression of the immune response by HGG tolerant spleen cells. I. Parameters affecting the level of suppression.

After adoptive transfer, the spleen cells from mice made tolerant to human gamma-globulin (HGG) specifically suppress the immune response of normal spleen cells. However, this suppressive activity in the spleen cells of tolerant mice is only present for a brief period after treatment with tolerogen. Spleen cells from animals injected 10 days earlier with tolerogen reduce the immune response of an equal number of normal spleen cells by 75%. Spleen cells from mice made tolerant 40 days previously are, however, no longer suppressive, even though they remain completely unresponsive. These data suggest that active suppression of antigen-reactive cells is not the mechanism responsible for maintaining tolerance to HGG, but rather is only transiently associated with the tolerant state. Further evidence in favor of the separation of the tolerant state from suppressive activity is that complete suppression of the normal spleen cell response requires either a high ratio of tolerant to immune competent cells or a delay in the antigenic challenge of the reconstituted recipients. By contrast, such manipulations are not required to demonstrate the complete unresponsiveness of the tolerant cells after adoptive transfer.     

Regulation of active and quiescent somatic stem cells by Notch signaling

Somatic stem/progenitor cells actively proliferate and give rise to different types of mature cells (active state) in embryonic tissues while they are mostly dormant (quiescent state) in many adult tissues. Notch signaling is known to regulate both active and quiescent states of somatic stem cells, but how it regulates these different states is unknown. Recent studies revealed that the Notch effector Hes1 is expressed differently during the active and quiescent states during neurogenesis and myogenesis: high in the quiescent state and oscillatory in the active state. When the Hes1 expression level is high, both Ascl1 and MyoD expression are continuously suppressed. By contrast, when Hes1 expression oscillates, it periodically represses expression of the neurogenic factor Ascl1 and the myogenic factor MyoD, thereby driving Ascl1 and MyoD oscillations. High levels of Hes1 and the resultant Ascl1 suppression promote the quiescent state of neural stem cells, while Hes1 oscillation-dependent Ascl1 oscillations regulate their active state. Similarly, in satellite cells of muscles, known adult muscle stem cells, high levels of Hes1 and the resultant MyoD suppression seem to promote their quiescent state, while Hes1 oscillation-dependent MyoD oscillations activate their proliferation and differentiation. Therefore, the expression dynamics of Hes1 is a key regulatory mechanism of generating and maintaining active/quiescent stem cell states.     

微囊藻毒素与自然水体中细菌VIVIFORM状态的相关性

细菌VIVIFORM状态是直接关系到自然水体水质评价和环境保护的生态现象 ,其形成机理相当复杂 ,但环境胁迫是主要诱因。通过人为改变湖水中的微囊藻毒素 (MC LR)水平 ,对水体中蓝藻毒素与细菌VIVIFORM状态之间的相关性进行了分析。结果表明 ,较高的毒素水平对水体中细菌种群总量没有明显的影响 ,但能刺激VIVIFORM细菌转化成可培养状态 ,从而证实了自然水体中蓝藻毒素与水细菌VIVIFORM状态之间存在直接的相关性。     

Transport of 6-deoxy-D-glucose and D-xylose by untransformed and SV40-transformed 3T3 cells

Transport rates of the nonphosphorylated D-glucose analogs 6-deoxy-D-glucose and D-xylose were measured in quiescent and serum-stimulated cultures of mouse 3T3 cells, in SV40-transformed 3T3 cells (SV101), and in a density revertant cell line derived from SV101 (Fl-SV101). Initial rates of both entry and exit of 6-deoxy-D-glucose and D-xylose were more than threefold higher in serum-stimulated 3T3 and in SV101 cells than they were in quiescent 3T3 cells, but transport rates were not higher in the transformed cells (SV101) than they were in serum-stimulated 3T3. Confluent cultures of Fl-SV101 showed lower rates of transport than serum-stimulated Fl-SV101, but not as low as quiescent 3T3 cells. These data confirm previous findings of others with other analogs that glucose transport is one of the cell functions that is depressed when 3T3 cells enter the quiescent G₀ state, but emphasize that SV40-transformed 3T3 cells do not show higher activity of the D-glucose carrier than do actively growing 3T3 cells. Thus, enhanced glucose transport appears not to be a specific consequence of transformation, but a reflection of the active growth state of the cell.