Enhancement of altered-cell foci in baby mouse skin cultures by antitubulin treatment: Nuclear mechanisms

When primary baby mouse skin (BMS) cultures were subcultured for 48 hours into media containing 10^?6 to 10^?7 M colchicine or demecolcine, the number of altered cell foci appearing after 3–4 weeks' maintenance at 36°C was substantially enhanced over drug-free controls. This applied whether or not the primary cultures had been irradiated with white fluorescent light. The additional presence of cytochalasin D and 12-O-tetradecanoyl-phorbol-l3-acetate (TPA) sometimes improved and sometimes partly suppressed the enhancing effect of the antitubulin drugs, and these drugs were omitted for reproducible focus enhancement. The enhancement depended on passage through DNA synthesis in presence of colchicine, which did not prevent concurrent or subsequent DNA synthesis but induced a substantial proportion (>33%) to replicate in the tetraploid (4n to 8n) chromosome configuration. Another effect was to induce widespread asymmetric nuclear division, allowing the potential for chromosome loss. All these effects occurred within the first one or few cell cycles after removal of the antitubulin drugs. The results suggest that the generation of tetraploidy perhaps followed by chromosome loss may be an important factor in the rapid induction of altered cell foci. Pre-existing DNA damage is another important factor.     

Properties of cell lines derived from altered-cell foci in baby mouse skin cultures

Long-term cell lines were readily developed from a proportion of either baby mouse skin (BMS) cultures passing through colchicine-induced crisis or altered-cell foci selected from BMS cultures exposed to light and/or oxygen followed by colchicine. The developing cell lines behaved as though they passed through a continuing, profound genetic reshuffling process, which was usually lethal but which in some cases eventually yielded a gene set that favored long-term survival. Some cell lines have passed 120 cell doublings, and none has shown a second crisis or signs of senescence. As soon after isolation as measurement was possible (19–50 days) the cell lines were predominantly or entirely tetraploid or subtetraploid. Although BMS cells and all of the cell lines were density inhibited, the BMS, C14, C21 and C23 cells overgrew (formed colonies on) monolayers of the same cells in most combinations. The cell lines retained a variety of neoplastic morphological characters, although their morphology was more normal than in the original focus. No cell line, however, showed anchorage-independent growth or formed tumors in syngeneic hosts. The cell lines may all, therefore, be regarded as preneoplastic.     

Dexamethasone stimulates osteogenic differentiation in vertebral and femoral bone marrow cell cultures: Comparison of IGF-I gene expression

Osteoblast-like cell cultures have been established from the marrow of adult rat vertebrae. We have simultaneously examined the response to dexamethasone (dex) treatment in cultures of young adult female vertebral and femoral marrow cells. Alkaline phosphatase (AP) activity was analyzed as well as the expression of mRNAs for osteocalcin (OC) and insulin-like growth factor I (IGF-I). The vertebral and femoral marrow cells were maintained for 7 days in primary culture with or without 10⁻⁸ M dex and then 6 days in secondary culture without dex or with 10⁻⁸ M or 10⁻⁷ M dex. All cells were examined on day 6 of secondary culture. Vertebral and femoral cultures each expressed the highest AP enzyme levels when grown with dex in primary culture (10⁻⁸ M) and secondary culture (10⁻⁷ M). Under all experimental conditions, vertebral cultures had lower AP enzyme activity than femoral cultures. When dex was omitted from secondary culture, OC gene expression was not detected in either vertebral or femoral passaged cells even if dex was present in primary culture. For dex conditions where OC was expressed, vertebral cultures had higher OC mRNA steady-state levels than femoral cultures. IGF-I gene expression was detected by Northern analysis in both vertebral and femoral secondary cultures. However, vertebral marrow cultures had much higher IGF-I mRNA levels compared to femoral cultures whether or not dex was present in primary culture. These findings demonstrate that dex supports the differentiation of both vertebral and femoral adult marrow osteogenic cells into osteoblasts. Our results support the hypothesis that osteoblastic marrow cultures differ depending upon which location in the skeleton they are from and that there are skeletal site–dependent differences in the insulin-like growth factor system components. J. Cell. Biochem. 71:382–391, 1998. © 1998 Wiley-Liss, Inc.     

Differential antimitogenic effectiveness of atrial natriuretic peptides in primary versus subcultured rat aortic smooth muscle cells: Relationship to expression of ANF-C receptors

Previous studies have shown that atrial natriuretic peptides inhibit mitogenesis in subcultured aortic smooth muscle cells by a mechanism that appears to be mediated via the C-type or “clearance” receptor. In the current study, we have compared the antimitogenic effect of these peptides in serum-stimulated primary aortic smooth muscle cell cultures and in subcultured cells. A series of atrial peptides, including rANF_99–126, rANF_103–126, and rANF_103–125, were only poorly antimitogenic in serum-stimulated primary cultures, whereas des[Cys¹⁰⁵, Cys¹²¹] rANF_104–126 which binds selectively to the ANF-C receptors had no antimitogenic activity. In contrast, in subcultured cells (between subcultures 3 and 25), rANF_99–126, rANF_103–126, rANF_103–126, Cys¹¹⁶rANF_102–116, and des[Cys¹⁰⁵, Cys¹²¹]rANF_104–126 inhibited serum-induced [³H]thymidine incorporation (IC₅₀ in the range of 10–50 nM), with maximal inhibition of 40–70%. The lack of antimitogenic activity in primary cultures did not appear to be related to the lack of cGMP elevation elicited by atrial peptides or to an inherent insensitivity to the action of antimitogens, because primary cultures were responsive to the cGMP-elevating effect of atrial peptides and the cells were more rather than less sensitive to the antimitogenic effect of the nitric-oxide-vasodilator, SNAP, as compared to subcultured cells. Analysis of the affinity and binding capacity of freshly isolated aortic membranes, and primary or secondary cultures for [¹²⁵I]rANF_99–126, revealed that the number of ANF receptors increased by tenfold, following subculture. Moreover, subcultured cells contained receptors with increased binding affinity for peptide analogues selective for the ANF-C-type type receptor. Covalent cross-linking studies with (¹²⁵I)rANF_99–126 confirmed that membranes prepared from fresh aortae predominantly expressed the ANF-A/guanylate cyclase receptor, whereas in subcultured cells the predominantly cross-linked protein was the ANF-C-type receptor, with receptors in primary cultures occupying an intermediate position. These results suggest that the binding and antimitogenic activity of atrial peptides in aortic smooth muscle cells depends on the phenotypic state of these cells. Moreover, the increased antimitogenic potency of atrial peptides in secondary cultures may reflect increased expression of the ANF-C-type receptors. © 1993 Wiley-Liss, Inc.     

Density dependent inhibition of cell growth in cultures of primary and established lines of cells

The effect of cell crowding on DNA synthesis (incorporation of ³HTdR and ³²PO₄) was studied by an improved method in monolayers of secondary cells and established cell lines, either normal or transformed by viruses or carcinogens. The method was based mainly on pulse labeling of cultures of cells a few hours after their seeding in equal numbers onto areas of different size in identical dishes, a condition which ensured equal physiological conditions and different degrees of crowding of cells. DNA synthesis was hardly inhibited in crowded monolayers of secondary chick, mouse and hamster embryo cells. The incorporation of radioactive thymidine and phosphate into DNA of cell lines such as BHK 21, 3T3/SV40 and L929 was strongly inhibited. An SV40-transformed line of hamster kidney cells (HKT7) synthetized DNA equally well in sparse as in crowded monolayers. In lines of human amnion (FL) and BHK 21 cells which were more extensively studied the degree of inhibition of DNA synthesis was inversely proportional to their density. Autoradiography after ³HTdR pulse-labeling indicated that the same proportion of cell nuclei were labeled in sparse and in crowded cultures. The extent of labeling (number of grains per nucleus) was lower in crowded cultures of those cells that also showed inhibition of incorporation of this label as measured by scintillation. The inhibition is thus expressed in retardation of DNA synthesis in cells in S phase rather than arresting it in a larger percentage of cells.     

HUMAN VASCULAR ENDOTHELIAL CELLS IN CULTURE : Growth and DNA Synthesis

Human endothelial cells, obtained by collagenase treatment of term umbilical cord veins, were cultured using Medium 199 supplemented with 20% fetal calf serum. Small clusters of cells initially spread on plastic or glass, coalesced and grew to form confluent monolayers of polygonal cells by 7 days. Cells in primary and subcultures were identified as endothelium by the presence of Weibel-Palade bodies by electron microscopy. A morphologically distinct subpopulation of cells contaminating some primary endothelial cultures was selectively subcultured, and identified by ultrastructural criteria as vascular smooth muscle. Autoradiography of endothelial cells after exposure to [³H]thymidine showed progressive increases in labeling in growing cultures beginning at 24 h. In recently confluent cultures, labeling indices were 2.4% in central closely packed regions, and 53.2% in peripheral growing regions. 3 days after confluence, labeling was uniform, being 3.5 and 3.9% in central and peripheral areas, respectively. When small areas of confluent cultures were experimentally "denuded," there were localized increases in [³H]thymidine labeling and eventual reconstitution of the monolayer. Liquid scintillation measurements of [³H]thymidine incorporation in primary and secondary endothelial cultures in microwell trays showed a similar correlation of DNA synthesis with cell density. These data indicate that endothelial cell cultures may provide a useful in vitro model for studying pathophysiologic factors in endothelial regeneration.     

Secondary association of exogenous polynucleotides with cells and nuclei in uptake experiments

Manipulation of [³H]polynucleotide-treated cells to remove them from the substrate or to isolate nuclei has been shown to result in secondary association of the exogenous polynucleotide with the cells or nuclei. Experiments have shown untreated (control) cultures, when processed with supernatants from [³H]polynucleotide-treated cell monolayers, exhibited a significant amount of radioactive label associated with the nuclei from control cells. In spite of thorough washing of polynucleotide-treated cell monolayers prior to the manipulation, the association was extensive. It is likely to overshadow the association resulting solely from the exposure of monolayer cells to the polynucleotide.     

Effect of trypsinization on susceptibility of primary human amniotic cells toChlamydia trachomatis TW-3 strain

The effect of trypsinization of human amnion membranes on the susceptibility of amnion cells toChlamydia trachomatis TW-3 infection was examined by infectivity titrations using standard procedures of chlamydial inoculation, and detection of chlamydial inclusions. Epithelial cells derived from freshly trypsinized membranes as well as primary and secondary cultured cells that were freshly removed from monolayers by trypsin treatment were not susceptible to infection at 30 min and at 2 and 6 h after trypsinization. Monolayers grown 18 h and up to 5 or more days after trypsinization were susceptible to infection. Primary 5-day monolayers derived from each of nine placentas inoculated with chlamydiae showed a range of titers from 10⁻³ to 10^−6.5 (SD=1.2 logarithm). Primary monolayers supported the multiplication of chlamydiae to consistently higher titers than secondary and tertiary monolayers from the same amnion.     

Splenic cultures from rainbow trout,Oncorhynchus mykiss: establishment and characterisation

This study describes the culture conditions and the phenotypic features of different types of splenic cultures established from explants. Using the same culture technique it was possible to grow splenic explants from which monolayers of reticular origin, long-term haematopoietic cultures, and subcultures were obtained. The cultures were characterised by light and electron microscopy, cytochemical and immuno-cytochemical analyses, phagocytic activity and susceptibility to virus. The cultures comprised multilayers of epithelioid and fibroblastoid cells with haemopoietic foci, melanomacrophages and eosinophilic granular cells. The cytochemical and immuno-cytochemical analyses revealed that the stromal cells were always positive for ANAE activity. The stromal cells in primary cultures were negatively or weakly stained by antibodies directed against cytokeratins and S-100, but in the subcultures they were strongly stained by these antibodies. The stromal cells had very poor phagocytic activity and were susceptible to VHS virus.     

Production and Release of Acetylcholinesterase by a Primary Cell Culture of Bovine Adrenal Medullary Chromaffin Cells

Abstract: Bovine adrenal chromaffin cells were isolated and maintained as primary culture monolayers. Total acetylcholinesterase (AChE) activity in the cells increased during the culture period, and AChE activity appeared in the culture medium. We have examined the role of the AChE synthesized by the cells on ACh-evoked release of catecholamine from the cells. A progressive decrease in the efficacy of ACh (5 × 10-⁵m ) to evoke release of [³H] norepinephrine from day 3–15 cultures suggests that exogenously applied ACh is hydrolyzed by the nascent AChE synthesized by the cells. These findings provide evidence that chromaffin cells produce AChE and release it into their immediate environment.     

The chronic effects of db-cAMP on cell cycle parameters and cell size in asynchronous culture of Chinese hamster ovary cells

N⁶,O^2′-dibutyryl adenosine 3′,5′-cyclic-phosphate (db-cAMP) has been shown to convert Chinese hamster cells of ovarian origin (CHO-K₁) from compact, randomly oriented cells growing in multilayers to elongated fibroblast-like cells which grow in monolayers. This compound also has been reported to have a variety of effects on the cell cycle. Most such studies have employed synchronized cells to determine cell cycle effects, and consequently have been limited to the short-term effects of the compound. We have looked for chronic effects on the cell cycle in cultures exposed continuously to db-cAMP from the initiation of the cultures until they had reached or approached the plateau phase. This was done by combined autoradiography and Feulgen microspectrophotometry plus measurements of the protein content of mitotic cells to detect any influence on cell size. The overall results were that continuous exposure to db-cAMP had at most only minor effects on the cell cycle and cell size when the culture medium was renewed daily. Somewhat greater effects were found on plateau-phase cells in cultures in which the medium was not renewed. In this case fewer cells appeared to remain in the cell cycle in the cultures with db-cAMP. Comparison with our earlier results with Chinese hamster V79 cells led to the conclusions that cell cycle parameters and cell size at mitosis were less altered during culture growth in CHO cells, but that CHO cells seemed to be less able to maintain cells in the cell cycle in crowded cultures.     

Interactions between Marek's Disease Herpesvirus and Avian Leucosis Virus in Tissue Culture

A GROUP B herpesvirus is important in the aetiology of Marek's disease, a highly contagious lymphoproliferative disease of chickens^1,2. Chicks inoculated with enveloped Marek's disease herpesvirus (MDHV), extracted from feather follicle epithelium of chickens with the disease, developed tumour-like aggregates of lymphoid cells in the viscera and frequently in the peripheral nerves^3,4. Cultures of chicken embryo fibroblast (CEF) cells infected with MDHV develop discrete foci of altered cells⁵. Our data show that MDHV infection of cultures of CEF cells, previously infected with an avian leucosis virus (RAV-2), results in both a reduction in the number of MDHV foci and an increase in the complement fixing avian leucosis antigen (COFAL)⁶ titre.     

Differential chromosomal fluorescence with 33258 Hoechst

In order to initiate studies on chemical carcinogenesis in an in vitro system analogous to mouse epidermis, primary epidermal cell cultures from perinatal mouse skin were established. A standardized method for the large-scale isolation of epidermal cells from late embryonic or newborn mouse dorsal skin has been developed. The epidermal cells were separated from fibroblasts by two series of discontinuous Ficoll density gradients. Using 80 to 100 animals/experiment, an average yield of 3×10⁶ viable epidermal cells/animal was obtained. The viability of the purified cell suspension exceeded 85%, and the plating efficiency, representing the growing cell fraction 24 h after plating, was about 43%.The cultures started as epithelial monolayers without fibroblast contamination. Their epidermal nature and origin was proved immunologically by an in vivo absorbed rabbit anti-mouse epidermis antiserum. The purity of the epidermal cells was quantitatively determined in trypsinized suspensions by the indirect immunofluorescence test yielding more than 95% epidermal antigen-positive cells. About half of the remaining antigen-negative cells could be identified as melanocytes. These highly purified epidermal cells grew in vitro for 2–3 weeks without dermal constituents or diffusible mesenchymal factors. The monolayers differentiated in culture giving rise to keratinizing cell sheets on top of the proliferating basal layer. By morphological, histochemical and physical methods, it could be evidenced that the differentiation processes in vitro are quite similar to keratinization in vivo.     

Capacity for tumor cell implantation as a function of in vitro cell density

Implantation properties of two melanoma cell lines, line 26 (low rate of implantation) and line 37 (high rate of implantation) were studied as a function of the cell density of the cells grown in monolayer in vitro. Sparse cultures (collected at a density of 0.8 × 10³ cells cm^?2) of line 37 produced 7.7 times as many lung tumor foci as those of line 26. Confluent cultures (collected at a density of 40 × 10³ cells cm^?2) resulted in greater numbers of tumor foci for both cell lines, but line 37 produced only 3.1 times as many tumor foci as did line 26 cells. Thus the high implantation line (37) has a much greater ability to implant when grown in the sparse state and injected than the low implantation line (26), but both lines have high implantation rates when injected as confluent cells.     

Altered differentiation in rat and rabbit limb bud micromass cultures by glutathione modulating agents

Glutathione (GSH) is the primary source of reducing equivalents in most cells, contributes significantly to the cellular redox potential and can control differentiation, proliferation, and apoptosis. Using limb bud micromass cultures from Sprague Dawley rats and New Zealand White rabbits, GSH modulating agents, L-buthionine-S,R-sulfoximine (BSO) and diethyl maleate (DEM) altered the formation of Alcian blue positive chondrogenic foci. Limb bud micromass cultures were treated for 5 d with BSO (50 or 100 μM) or DEM (5–25 μM). GSH content was determined by HPLC analysis. In rat cultures, BSO treatment did not affect differentiation but did show GSH depletion. In rabbit cultures, BSO completely inhibited differentiation and significantly depleted GSH. Treatment of rat cultures with DEM resulted in the dose-dependent decrease of chondrogenic foci, which correlated with a dose-dependent depletion of GSH. DEM completely inhibited rabbit limb bud cell differentiation and depleted GSH by 44%. Inhibition of differentiation was confirmed in rabbit cultures by the reduction in BMP-4 content. Addition of N-acetylcysteine to rabbit micromass cultures restored chondrogenic foci differentiation seen following treatment with both DEM and BSO. These results show species differences in GSH depletion in rat vs. rabbit limb bud cells and implicate GSH and cysteine in affecting pathways involved in chondrocyte differentiation.     

Neuronal and non-neuronal properties of neuroblastoma cells.

Three different mouse neuroblastoma cell lines (S20Y, N2CL10, N115) were examined for acetylcholinesterase activity, ganglioside composition, cell processes, and affinity for protargol silver (i.e., argyrophilia). Assays were made on cloned cells, corresponding tumors which developed after subcutaneous injection of $\text{A}\text{J}$ strain male mice with 2 × 10⁶ cells, and primary and secondary cultures. Acetylcholinesterase activity was present in all cells assayed, with maximal activity noted in cloned cells. Ganglioside patterns of neuroblastoma cells differed from those of neural cells, but remained qualitatively unchanged for a given cell line grown in vivo or in vitro. Some cells were stained with protargol silver in primary cultures, but few cells in cloned or secondary cultures, or those in in vivo tissues, were impregnated with protargol silver. These findings show that while neuroblastoma cell lines maintain some neuronal characteristics (i.e., high acetylcholinesterase levels, cell processes), they do not express other accepted neuronal properties (i.e., ganglioside patterns, argyrophilia), and suggest that direct analogies between normal neurons and “differentiated” neuroblastoma cells should be made with caution.     

Cellular effects of ornithine decarboxylase induction in cells maintained with a salts/glucose medium

Cultures preincubated in a growth restricted salts/glucose medium in the presence and absence of ornithine decarboxylase (ODC) activating factors were then incubated under ideal growth conditions to study the influence of these factors on cell growth. Incubation of confluent cultures in a salts/glucose medium alone did not induce ODC or change the other biochemical parameters investigated. However, if cultures were incubated in the salts/glucose medium supplemented with asparagine (ASN) and agents that increase cellular cAMP levels then ODC was induced after 6–8 h. This primary induction in the salts/glucose medium resulted in altered and delayed ODC induction during growth stimulation and also caused a delay in (³H) thymidine incorporation without affecting (³H) uridine and (³H) leucine incorporation. These results demonstrate that incubation of cultures in a salts/glucose media with ASN and dibutyryl cAMP (dBcAMP) causes refractory ODC induction and altered (³H) thymidine incorporation upon growth challenge with complete medium. These effects were not observed when cells were preincubated in a salts/glucose medium alone.     

cAMP-dependent protein kinase and proliferation differ in normal and polycystic kidney epithelia

Developmental control of cellproliferation is crucial, and abnormal principal cell proliferation maycontribute to cystogenesis in polycystic kidney disease. This studyinvestigates roles of cAMP and its primary effector, cAMP-dependentprotein kinase (protein kinase A; PKA), in control of cellproliferation in filter-grown noncystic (NC) and cystic (CY)-derivedprincipal cell cultures. These cultures had similar cAMP pathwaycharacteristics upstream of PKA subunit distribution but differed inpredicted PKA subtype distribution. Functionally, cultures wereproliferative before polarization, with constitutively higherproliferation in CY cultures. NC cultures achieved levels similar tothose of CY cultures on pharmacological manipulation of cAMP productionor PKA activation or inhibition of PKA subtype I activity. Inhibitionof overall PKA activity, or of PKA subtype II anchoring, diminishedcAMP/PKA-mediated proliferation in NC cultures but had no effect on CYcultures. Polarized CY monolayers remained proliferative, but NCmonolayers lost responsiveness. No large proliferation changes resultedfrom treatments of polarized cultures; however, polarized NC and CY cultures differed in poststimulation handling of PKA catalytic and typeII regulatory subunits. Our results support PKA subtype regulationof prepolarization proliferation in NC principal cells and alteredregulation of PKA in CY cells and suggest that differences at ordownstream of PKA can contribute to altered proliferation in adevelopmental renal disease.

     

DNA synthesis and cell proliferation in C6 glioma and primary glial cells exposed to a 836.55 MHz modulated radiofrequency field

We have tested the hypothesis that modulated radiofrequency (RF) fields may act as a tumor-promoting agent by altering DNA synthesis, leading to increased cell proliferation. In vitro tissue cultures of transformed and normal rat glial cells were exposed to an 836.55 MHz, packet-modulated RF field at three power densities: 0.09, 0.9, and 9 mW/cm², resulting in specific absorption rates (SARs) ranging from 0.15 to 59 μW/g. TEM-mode transmission-line cells were powered by a prototype time-domain multiple-access (TDMA) transmitter that conforms to the North American digital cellular telephone standard. One sham and one energized TEM cell were placed in standard incubators maintained at 37 °C and 5% CO₂. DNA synthesis experiments at 0.59–59 μW/g SAR were performed on log-phase and serum-starved semiquiescent cultures after 24 h exposure. Cell growth at 0.15–15 μW/g SAR was determined by cell counts of log-phase cultures on days 0, 1, 5, 7, 9, 12, and 14 of a 2 week protocol. Results from the DNA synthesis assays differed for the two cell types. Sham-exposed and RF-exposed cultures of primary rat glial cells showed no significant differences for either log-phase or serum-starved condition. C₆ glioma cells exposed to RF at 5.9 μW/g SAR (0.9 mW/cm²) exhibited small (20–40%) significant increases in 38% of [³H]thymidine incorporation experiments. Growth curves of sham and RF-exposed cultures showed no differences in either normal or transformed glial cells at any of the power densities tested. Cell doubling times of C₆ glioma cells [sham (21.9 ± 1.4 h) vs. field (22.7 ± 3.2 h)] also demonstrated no significant differences that could be attributed to altered DNA synthesis rates. Under these conditions, this modulated RF field did not increase cell proliferation of normal or transformed cultures of glial origin. Bioelectromagnetics 18:230–236, 1997. © 1997 Wiley-Liss, Inc.