Dynamics of L-929 cell spreading after mitosis

Changes in the cell shape of L-929 (NCTC, clone 929) during the cell cycle were analyzed with time-lapse microscopy. It was found that the cells pass through three spreading stages. The maximal cell spreading was observed during the first 1.5 h after mitosis. In this period, the cell area increases in correspondence with the sigmoid dependence and enlarges by approximately 3.0–3.5 times. After a short plateau, the cell area begins to increase, also correspondence with the sigmoid dependence. This period is longer (up to 6 h after the beginning of cell division), with an additional 1.5-fold increase in the cell size. Later, cell area enlargement continues linearly up to the beginning of the next mitosis.     

Analysis of the cell cycle duration of cells of permanent line L-929

The direct measurement of the cell cycle duration in L-929 cells was performed using time-lapse photography. The cell cycle duration was 15.77 +/- 0.08 h with a standard deviation of 1.54 +/- 0.06 h. The experimental value fit to a normal distribution with a correlation coefficient 0.999. High homogeneity of this parameter and a wide range of variability of the karyotype (58-66 chromosomes) indicate that there is no correlation between these characteristics of L-929 cells. It is also shown that the difference between cell cycle durations of daughter cells tent to zero and fits by an exponent.     

Respiration of mengovirus-infected L-929 cells

Iglewski, W. J. (The Pennsylvania State University, University Park), and E. H. Ludwig. Respiration of mengovirus-infected L-929 cells. J. Bacteriol. 92:733-738. 1966.-Polarographic techniques were employed to study the oxidative metabolism of L-929 cells during a one-step mengovirus growth cycle. Virus maturation began 3.5 hr after infection and was complete with 7 hr. Virus maturation was accompanied by a decreased rate of endogenous respiration and an increased rate of oxidation of succinate and alpha-glycerophosphate by L-929 cells. The rate of glucose uptake was the same for mengovirus-infected and control L-929 cells. However, there was a decreased oxidation of glucose to carbon dioxide and a decreased production of lactic acid by L cells infected with mengovirus under aerobic conditions. Mengovirus was produced equally well under aerobic and anaerobic conditions. The implications of the alterations in metabolism with respect to virus synthesis are discussed.     

L-929 cells under hyperosmotic conditions

Changes in cell water content resulting from sorbitol addition to the environment of L-929 cells were evaluated gravimetrically using¹⁴C-labeled polyethylene glycol as a probe of extracellular space. Reductions in cell water were proportional to sorbitol supplements up to 0.6 molal, above which no further measurable decrease occurred. No volume regulation occurred for at least 1 h but the percentage of cell water lost was quickly regained when physiological conditions were restored. The amount of cell water lost because of a given hyperosmotic exposure was found to exceed the loss of cell volume. That discrepancy could be the result of an overestimation of extracellular space and/or an underestimation of cell volume reduction as a result of infolding of the cell surface. Na⁺ and K⁺ were also measured in cells of variable water content and volume: no significant change occurred in the amounts of these ions per cell, but large increases in total cell concentration resulted from hyperosmotic exposure. The sum of Na⁺ and K⁺ concentrations exceeds the total osmotic pressure of the medium indicating that an appreciable fraction of Na⁺ and K⁺ must be bound to fixed charges within the cells. The results are evaluated in the context of intracellular organization.     

Glycolysis in permeabilized L-929 cells.

Mouse L-929 cells permeabilized with dextran sulphate (DSP cells) carry out glycolysis when supplemented with glucose, ATP and NAD+ in a suitable incubation buffer. Glycolytic rates were linear and generally independent of cell density over the range examined (1 x 10(6)-10 x 10(6) cells/ml). Electron microscopy revealed characteristic changes in DSP cell ultrastructure, notably for nuclei and mitochondria. Some cells lacked plasma membranes, while others appeared intact. In the latter case, estimates of the lesion size in plasma membranes were obtained from volume of distribution studies using 14C-labelled proteins, and infiltration of fluorescein isothiocyanate dextran. The results indicated the presence of lesions large enough to allow globular proteins of about 400 kDa to cross the cell surface. In spite of that, only about 10% of total cell protein exited from DSP cells during a 30 min incubation period. We propose that none of the glycolytic enzymes in DSP cells can exist completely in solution in the 'cytosol', suggesting extensive enzyme organization. The results are interpreted within the broader picture of metabolic organization in animal cells and the nature of the 'cytosol'.     

Evaluation of L-929 postmitotic daughter cell spreading during their migration on a substrate

Spreading of postmitotic daughter cells was examined using time-lapse microscopy. The work was performed on unsynchronized cells of a permanent L-929 cell line. The study aimed at formalizing the comparison of the moving cell area and estimating whether the area of migrating cells was changed randomly or nonrandomly. Two new parameters are proposed for comparison of cell morphology: the identity indicator and the synchronism indicator. To calculate these parameters, time-dependent changes of the area in cell pairs were measured. The first indicator shows the degree of coincidence between the absolute area values in the cell pairs, whereas the second indicator shows synchronism in the changes of cell areas and does not depend on their absolute values. The low indicators were a high similarity in the time-dependent changes of the cell area. The indicators were shown to be approximately 1.5-fold lower for the pairs of the postmitotic daughter cells than those for any other pair of the cells. The results point to a nonrandom character of the changes of cultured cell morphology.     

Continuous production of human erythropoietin by immobilized recombinant L-929 cells

Recombinant L-929 cells transfected with the human erythropoietin (EPO) gene were immobilized in a macroporous cellulosic support and its derivatives in which charged groups or cell attachment factors were introduced. The immobilized cells were cultured in serum-containing and serum-free media. Comparable production of EPO was observed even in the serum-free medium when a support modified by polyethyleneimine was used for immobilization. The cells immobilized on the supports were cultured in fluidized-bed and inner-loop type air-lift bioreactors for continuous production of EPO. A high cell density of more than 2 × 10⁷ cells/cm³-support and high EPO productivity were achieved and maintained for 50 d through the use of the inner-loop type air-lift bioreactor. The productivity was 13.4-fold higher than that of conventional static cultures in petri-dishes.     

Mouse transcobalamin II: Biosynthesis and uptake by L-929 cells

Mouse fibroblast (L-929) cells, in culture, synthesized and secreted into the growth medium a vitamin B₁₂-binding substance which was identical to mouse transcobalamin II (TC II) as judged by the following criteria: (i) gel filtration on Sephadex G-200, (ii) ion-exchange chromatography on DEAE-cellulose and CM-cellulose, and (iii) the ability to facilitate cellular B₁₂ uptake by L-929 cells. The secretion of mouse fibroblast binder was blocked by cycloheximide and puromycin; and in both cases the cells' ability to secrete this binder was partially restored when the inhibitor was removed. Within 30 h after the cells were exposed to [⁵⁷Co]B₁₂ bound to mouse serum TC II (M_r ~ 38,000) the [⁵⁷Co]B₁₂ was bound to a large molecular weight intracellular binder (M_r ~ 120,000) which was not released into the culture medium. During this same incubation period, the cells released free [⁵⁷Co]B₁₂ and [⁵⁷Co]B₁₂ bound to a protein which had the same elution volume as mouse serum TC II on Sephadex G-200.     

Glucose metabolism and the channeling of glycolytic intermediates in permeabilized L-929 cells

L-929 cells (mouse fibroblasts) permeabilized with dextran sulfate (DSP cells) carry out vigorous and linear rates of glycolysis when supplied with a suitable incubation medium. Glycolysis in DSP cells is pH dependent, being strongly inhibited at pH 6.5. Compared to their nonpermeabilized counterparts, DSP cells exhibit faster glycolytic rates, but tend to convert a smaller proportion of the glucose utilized to lactate. [14C]Glucose is converted to lactate by DSP cells without dilution from endogenous substrates. When exogenous 12C-labeled glycolytic intermediates (12C-I) are added to glycolyzing DSP cells the [14C]lactate produced from [14C]glucose is diluted to varying extents, depending on the intermediate. However, the extent of that dilution (reduced specific activity) is not that expected from the complete mixing of exogenous 12C-I with their corresponding 14C-labeled intermediates coming from [14C]-glucose. DSP cells also respire and convert glucose to CO2. The amount of 14CO2 produced from [14C]glucose is also reduced by addition of most 12C-I, an interesting exception being pyruvate, which had no measurable effect on 14CO2 production and caused only a modest stimulation of respiration in glycolyzing DSP cells. These results suggest that channeling, or some other form of coupling, takes place between the glycolytic production of pyruvate and its further oxidation. These observations confirm previously published data and add further support to the proposition that channeling of glycolytic intermediates occurs in DSP cells but is of the "leaky" type. Although abundant evidence in the literature indicates that various glycolytic enzymes associate with F-actin, as well as other elements of the cytomatrix, we observed no effect of cytochalasin D on lactate production even at very high concentrations of this compound. Our results are compared with those from other laboratories and discussed in the context of metabolic organization.     

Evidence for intermediate channelling in the glycolytic pathway of permeabilized L-929 cells

L-929 cells permeabilized by dextran sulfate (DSP cells) carry out vigorous and linear rates of glycolysis when supplied with a suitable incubation medium. Unlabeled 3-phosphoglycerate (PGA) added to DSP cells reduces the specific activity of lactate coming from [14C]glucose but the extent of this reduction can not be accounted for on the basis of free diffusion of PGA coming from [14C]glucose. Studies on other glycolytic intermediates, although preliminary, yield similar results. PGA also inhibits the production of lactate from glucose; however, this effect, like that of the reduction of lactate specific activity, becomes apparent only at concentrations of PGA well in excess of those considered to be physiological. We conclude that channelling of PGA, and probably other intermediates, occurs but is of the "leaky" type.     

Cellular RNA synthesis in normal and mengovirus-infected L-929 cells.

Cellular RNA synthesis was studied in mouse L-929 cells and in these cells infected with mengovirus. RNA polymerases I, II, and III were partially purified and their chromatographic properties were analyzed by DEAE-Sephadex A-25 chromatography. RNA polymerase II was purified from mouse liver and its subunit structure was compared to that of normal and virus-infected L-929 cells by two-dimensional gel electrophoresis. By these criteria, the enzymes from all three sources were identical. The RNA synthetic activities and capacities of chromatins from normal and virus-infected cells were compared under a variety of conditions. The endogenous activity in chromatin from infected cells was inhibited relative to controls but the residual activity responded normally to stimulation by ammonium sulfate, heparin, and Sarkosyl. The template capacity of the chromatins was compared with added RNA polymerase II and by a rifampicin challenge assay utilizing Escherichia coli RNA polymerase. Identical results were obtained in each case. The number of growing RNA chains and the rates of their elongations were determined. The results showed that nuclei and chromatin from infected cells have a smaller number of RNA polymerase II molecules engaged in RNA synthesis than normal cells do but that the active molecules elongate RNA chains at the same rate.     

Fatty conversion of mouse fibroblasts of the L-929 line induced by cysticerci of the cat tapeworm

Effect of exometabolites of cysticerci of H. taeniaeformis on morphological features of transformed fibroblasts was investigated using L-929 cells. Studies on histochemistry and ultrastructure of L-929 cells treated with the cysticercal exometabolites induced a fatty conversion of these cells. It is proposed that the exometabolites in question may exert their influence on differentiation degree in the in vitro long-term cultivated fibroblasts-like cells.     

Density dependent regulation of growth in suspension cultures of L-929 cells

Suspension cultures of L-929 fibroblasts grown to densities of 6 to 10 × 10⁶ cells/ml through daily centrifugation and resuspension in fresh media, have been maintained for periods up to five months without change in viability or cell size. DNA synthesis and mitosis in these cultures is limited to 5% of the cells per day, a fraction very nearly equal to the fraction of cells rendered nonviable, most likely during the manipulations associated with medium renewal. The kinetics of the flow of cells into the S and M periods following (a) renewal of the medium and (b) dilution of the high density cultures, suggest that the large majority of the cells are in a G₀ or early G₁ phase, resuming growth readily in response to decreased cell density. This is further indicated by the sequence of the marked shifts occurring in the cell volume distribution spectrum of the high density cultures after dilution. Long term, steady state regulation of growth with retention of intact viability was thus demonstrated in the case of a long established aneuploid cell line. The fact that this occurs in suspension but not in attached cultures, supports the concept that impairment of growth control in such cells affects predominantly regulatory mechanisms located at the cell surface rather than those concerned with intracellular synthesis and metabolism.     

Endocytic pathway of recombinant murine tumor necrosis factor in L-929 cells

The fate of TNF after binding to the surface of L-929 cells was followed by using murine rTNF coupled to colloidal gold as a probe. A time-course study using electron microscopy was performed. Our results confirm previous indications obtained from biochemical studies suggesting that TNF is internalized by this cell type. They further directly show that internalization proceeds through the classical receptor-mediated endocytosis pathway, i.e., via clathrin-coated structures and endosomes before accumulation in secondary lysosomes.     

Optimization of reovirus production from mouse L-929 cells in suspension culture

Reovirus serotype 3 Dearing (T3D) has shown potential as a novel cancer therapy. To support the increasing demand for reovirus, a two-stage perfusion mode scheme is proposed for cell growth and reovirus production. Mouse L-929 cells were used as the host for reovirus infection due to their ability to grow well in suspension culture. Several L-929 cell growth and reovirus infection characteristics were investigated and optimized in spinner flask batch cultures. For the growth of L-929 cells, a balanced nutrient-fortification of SMEM medium increased the maximum cell density by 30%, compared to normal SMEM; however, ammonia and lactate accumulations were found to inhibit further cell growth. For the production of reovirus, approximately 90% increase in viral yield resulted when the infection temperature was reduced from 37 to 33 degrees C. Infectious reovirus particles were shown to be stable in conditioned medium at 37 and 33 degrees C. The final virus titer was dependent on the multiplicity of infection (MOI) and the host cell density at the time of infection. A combination of an MOI of 0.1 pfu/cell and an initial host cell density of 1.0 x 10(6) cells/mL in fortified medium resulted in a maximum virus titer of (4.59 +/- 0.16) x 10(9) pfu/mL and a specific yield of (2.34 +/- 0.08) x 10(3) pfu/cell. At an optimal harvest time of the infection process, 99% of the virus was associated with the cellular debris. Finally, the presence of 5.0 mM ammonia in the culture medium was shown to seriously inhibit the reovirus yield, whereas lactate concentrations up to 20 mM had no effect.     

Respiratory metabolism of L-929 cells at different water contents and volumes

Oxygen consumption was measured in mouse L-929 cells whose volumes and water contents were reduced by adding sorbitol to the medium. The volume of water lost due to a given sorbitol supplement exceeded the loss in apparent cell volume. An explanation is given for this discrepancy. The rate of oxygen uptake in the absence of exogenous respiratory substrate was essentially the same in cells whose total volume was reduced by 45%, amounting to a loss of about 70% of the total cell water, compared to controls at 'physiological' volume and water content. Cells under these same conditions responded to added substrates (pyruvate, glucose, and glutamine) and inhibitors (iodoacetate and 2-deoxyglucose) in nearly the same way as control cells. These observations are in accord with and add to previous work showing that very large fluctuations in cell volume and water content have only modest effects on the rates and directions of a variety of metabolic processes. The results are interpreted in terms of current views on the composition and organization of the aqueous compartments of eucaryotic cells.     

An RNA fraction in chromatin of L-929 cells associated with DNA

Isopycnic gradient centrifugation of L-929 cell chromatin in a 38% (W/V) metrizamide solution yields two distinct fractions. The fraction banding at a density of 1.24 gm/cm² (H chromatin) contains about 10% of the DNA present in the fraction banding at a density of 1.18 gm/cm² (L chromatin). Both fractions contain the same proportions of satellite to main band DNA's. Some differences can be seen in the DNA: protein ratios and types of proteins present in the H and L chromatin fractions.