Conditional expression of the transformed phenotype in an epithelial-like cell line.

A subclone of ts 14/MNU/2, derived from a heteroploid (epithelial) monkey kidney cell line of BSC-1 and transformed in vitro by methylnitrosourea, expressed the transformed phenotype only at the elevated temperature of 39.5(0)C. Compared to the growth characteristics at 33(0)C, the transformed property was exhibited in the (1) high efficiency of plating at low cell densities, (2) colony morphology, (3) growth in absence of serum and (4) alterations in the quality and the quantity of chromosomal proteins in presence of low concentrations of serum. Such experimental systems may provide an effective control for studying molecular mechanisms related to transformation and neoplasia.     

Cardiomyocyte marker expression in a human lymphocyte cell line using mouse cardiomyocyte extract

Cell transplantation shows potential for the treatment of cardiac diseases. Embryonic stem cells, cord blood and mesenchymal stem cells have been suggested as sources for transplantation therapy. Because of some technical limitations with the use of stem cells, transdifferentiation of fully differentiated cells is a potentially useful alternative. We investigated whether human peripheral blood cells could transdifferentiate into cardiomyocyte. Transdifferentiation was induced in a human B lymphocyte cell line (Raji). Cardiomyocyte extract was prepared from adult mouse cardiomyocytes. The cells were treated with 5-aza-2-deoxycytidine and trichostatin A, permeabilized with streptolysin O, and exposed to the mouse cardiomyocyte extract. They were cultured for 10 days, 3 weeks and 4 weeks. Cardiomyocyte markers were detected with immunohistochemistry and flow cytometry. Immunocytochemistry revealed that some cells expressed myosin heavy chain, α-actinin and cardiac troponin T after 3 and 4 weeks. Flow cytometry confirmed these data. In cells exposed to trichostatin A and 5-aza-2-deoxycytidine and permeabilized in the presence of the cardiomyocyte extract, troponin T expression was seen in 3.53% of the cells and 3.11% of them expressed α-actinin. After exposure to the cardiomyocyte extract, some permeabilized cells adhered to the plate loosely; however, the morphology did not change significantly, and they continued to show a rounded shape after 4 weeks. Our treated lymphocytes expressed cardiomyocyte markers. Our results suggest that lymphocytes may be useful in future research as a source of cells for reprogramming procedures.     

Absence of gamma-actin expression in the mouse fibroblast cell line, L

Cytoplasmic isoactins of mouse fibroblast L-cells were examined by two-dimensional gel electrophoresis. In contrast to other cultured cell lines, which contain both beta- and gamma-actin, L-cells contained only beta-actin species. This unique phenomenon was due neither to the transformed status of this cell line nor to the characteristic nature of adipose tissue fibroblasts of C3H mice. When RNA of L-cells was translated in a nuclease-treated reticulocyte lysate system, actin synthesized in vitro also appeared as only one species, beta-actin. Therefore, the genetic information for gamma-actin is absent at the level of translatable mRNA in L-cells.     

A mouse kidney cell line with a G:C --> C:G transversion mutator phenotype

We report the identification of a mouse kidney epithelial cell line (K435) in which G:C-->C:G transversion mutations occur at an elevated rate and are the predominant spontaneous events observed at the selectable Aprt locus. Of three genotoxins tested, ultraviolet radiation (UV), ionizing radiation, and hydrogen peroxide, only UV exposure was able to alter the spectrum of small mutational events. To determine if the G:C-->C:G mutator phenotype was due to a deficiency in the mismatch repair pathway, the K435 cells were tested for resistance to 6-thioguanine, cisplatin, and MNNG. Although the K435 cells were as resistant to 6-thioguanine and cisplatin as Pms2 and Mlh1 null kidney cells, they were hypersensitive to MNNG. Moreover, the K435 cells do not exhibit microsatellite instability, a hallmark of mismatch repair deficiency. These results suggest that a novel mechanism, which does not include a classical deficiency in mismatch repair, accounts for the G:C-->C:G mutator phenotype.     

Early insulin signaling cascade in a model of oxidative skeletal muscle: mouse Sol8 cell line

Cell models provide important tools to investigate the mechanisms modulating the insulin-signaling cascade. Insulin interaction and subsequent signaling of cells is complex and regulated at multiple levels: receptor abundance, binding dynamics, phosphorylation/dephosphorylation of tyrosine and serine/threonine residues, and subsequent interactions of key intracellular messengers. We report early insulin signaling events in the mouse Sol8 myogenic cell line. Sol8 cells responded to insulin by increasing total IRS-1, p85 PI3-kinase and tyrosine phosphorylated IRS-1 (pY-IRS-1) at 10 min (P<0.05), but not at 1 min of insulin stimulation. The dose-response relationships at 10-min insulin (10 to 300 nM) stimulation showed that IRS-1 and pY-IRS-1 responded to 100 and 300 nM insulin, and the p85 PI3-kinase response peaked at 30 nM insulin. PI3-kinase appeared to be present in high abundance and, in response to insulin, recruitment to the insulin receptor tyrosine kinase (IR) of IRS-1 and PI3-kinase was observed. The increase in IRS-1 detected in IR immunoprecipitates was twofold, while the corresponding increase in PI3-kinase was threefold, suggesting direct recruitment of PI3-kinase to the IR. PI3-kinase detected in IRS-1 immunoprecipitates in response to insulin increased 1.7-fold. An ultimate target of this pathway, GLUT4 recruitment to the PM, was delayed (30 min), the increase in GLUT4 being of similar magnitude (1.6-fold) to the early signaling events. Saturation binding analysis indicated that IR in the plasma membrane was not down-regulated in response to insulin. The present study suggests that early signaling events in the insulin cascade are invoked in Sol8 myogenic cells and that this cell line provides a useful model to study insulin signaling.     

Characterization of a nickel resistant mouse cell line

Nickel is a potent carcinogen and, at high concentrations, is toxic to mammalian cells. The effects associated with nickel exposure are well-documented but its mechanism of action in the cell has not yet been fully described. In order to understand the metabolic fate of nickel in mammalian cells, a variant cell population has been selected that continues to grow and divide in the presence of nickel chloride concentrations that are toxic to the parental cell line (Balb/c-3T3 mouse fibroblasts). Nickel resistance is not caused by altered uptake of nickel from the medium or increased clearance from the cells and is not associated with changes in metallothionein expression. Compared to the normal cells, the nickel resistant cells have a decreased number of chromosomes and numerous centromeric fusions. The expression of some proteins and the distribution of nickel bound by various proteins are altered in the nickel resistant cells. Preliminary results indicate that the nickel resistant phenotype may be transferred by genomic DNA-mediated transfection into a recipient NIH-3T3 cell line. Current investigations are directed at identifying a gene responsible for nickel resistance.     

A mouse hybrid cell line that supports gene expression from a variety of promoters in amplifiable vectors

Summary A hybrid cell line was constructed by fusion of mouse L-cells with an NIH3T3 cell line derivative containing a hybrid gene consisting of the mouse immunoglobulin kappa (IgK) variable gene promoter linked to theEscherichia coli gpt gene. Such hybrids grew to a much higher density compared to either of the parental cell lines. The utility of this cell line as a host to express foreign genes was tested by the expression of TGF-β cDNA using the cytomegalovirus promoter. The vector also contained the human dihydrofolate reductase (DHFR) gene driven by SV40 early promoter, to allow for the amplification of the transfected gene. Initial transformants, selected at 100 nM methotrexate (MTX), were subsequently selected for resistance to a higher concentration of MTX (2 μM). Such clones expressed an increased level of TGF-β when compared to the initial transformants. Both the initial transformants and the clones with the amplified DHFR gene produced TGF-β in an acid-activatable precursor form. This mouse hybrid host cell line also allowed the expression of foreign genes cloned in an eukaryotic expression vector with the mouse IgK variable region promoter and human growth hormone as the reporter gene, whereas such vectors did not function in CHO cells. The mouse hybrid cell line was also found to be capable of being used with a broad range of promoters.     

Induction of K-channel expression in a neuroblastoma cell line

Whole-cell currents were examined in mouse neuroblastoma cells of the N2AB-1 line. In standard culture medium, N2AB-1 cells exhibited large voltage-dependent Na currents but no discernible K currents. Treatment of N2AB-1 cells with either dimethylsulfoxide (DMSO) in low-serum medium or with retinoic acid (RA) caused the expression of delayed rectifier K currents. Currents from two types of K channel with single channel slope conductances of 15.0 pS and 6.4 pS were observed in outside-out patches from cells of both treatment groups. Thus, while N2AB-1 cells did not exhibit K currents under standard culture conditions, they did possess the gene(s) encoding K channels. The treatments caused other changes that were not directly linked to K-channel expression. RA treatment caused neurite extension in most, but not all, N2AB-1 cells; however, all RA-treated cells, including those without neurites, expressed K currents. RA treatment did not suppress cell division or cause hypertrophy. In contrast, treatment with DMSO/low serum suppressed cell division and caused cellular hypertrophy, but did not cause long neurites to form. Thus, the regulation of K channels was not coupled in a simple fashion to properties that have been associated with a differentiated neuronal phenotype: neurite elaboration, changes in cell size, and inhibition of cell division. These results suggest that N2AB-1 cells may be a good model system for investigating the processes regulating K-channel expression.     

Elucidation of the phenotypic change on the surface of Had-1 cell, a mutant cell line of mouse FM3A carcinoma cells selected by resistance to Newcastle disease virus infection

Had-1, which was isolated from mouse FM3A carcinoma cells, was a non-permissive mutant cell line to Newcastle disease virus infection. Comparative study of the asparagine-linked sugar chains of the surface glycoproteins of the mutant and its parental cells revealed that galactosylation of the complex-type sugar chains is extensively reduced in the mutant. Assay of galactosyltransferase in the two cell lines, however, showed that the enzymatic activity in Had-1 cells is virtually identical to that in FM3A cells. Somatic cell hybridization analysis indicated that the mutant has the same defect as Chinese hamster ovary cell mutant Lec 8, which is deficient in UDP-galactose transport into Golgi vesicles.     

Cross-generational effects of climate change on expression of a sexually selected trait

Sexually selected traits and early breeding are often correlated with quality in birds: individuals that breed earlier in the season have more elaborate traits and raise more surviving offspring [1, 2]. As global climate warms, breeding date for many temperate birds is advancing [3, 4], but we lack corresponding information on climate-induced variation in sexual selection. Here, we investigated influences of climate on a sexually selected plumage trait in a Himalayan warbler (Phylloscopus humei). We found that when spring is warm, birds breed early. Subsequent to an early-breeding year, adults express relatively large sexually selected traits and rear offspring that also develop large traits. The positive effects of early breeding, plus the across-year correlation between parent and offspring cohorts, predict that warmer climates should lead to increases in trait size. However, trait size has not increased over the past 25 years, even though mean breeding date has advanced. We show that whereas warm springs have positive effects on trait size, warm summers have negative effects due to increased feather wear. Apparent stasis in the size of a sexually selected trait thus masks large, conflicting influences of climate change. Continued climate warming has the potential to affect the honesty of sexual signals, as trait expression and condition become increasingly disassociated.     

Frizzled-7 receptor ectodomain expression in a colon cancer cell line induces morphological change and attenuates tumor growth

Frizzled (FZD) receptors have a conserved N-terminal extracellular cysteine-rich domain that interacts with Wnts and co-expression of the receptor ectodomain can antagonize FZD-mediated signalling. Using the ectodomain as an antagonist we have modulated endogenous FZD7 signalling in the moderately differentiated colon adenocarcinoma cell line, SK-CO-1. Unlike the parental cell line, which grows as tightly associated adherent cell clusters, the FZD7 ectodomain expressing cells display a spread out morphology and grow as a monolayer in tissue culture. This transition in morphology was associated with decreased levels of plasma membrane-associated E-cadherin and beta-catenin, localized increased levels of vimentin and redistribution of alpha6 integrin to cellular processes in the FZD7 ectodomain expressing cells. The morphological and phenotype changes induced by FZD7 ectodomain expression in SK-CO-1 cells is thus consistent with the cells undergoing an epithelial-to-mesenchymal-like transition. Furthermore, initiation of tumor formation in a xenograft tumor growth assay was attenuated in the FZD7 ectodomain expressing cells. Our results indicate a pivotal role for endogenous FZD7 in morphology transitions that are associated with colon tumor initiation and progression.     

GREG cells, a dysferlin-deficient myogenic mouse cell line

The dysferlinopathies (e.g. LGMD2b, Myoshi myopathy) are progressive, adult-onset muscle wasting syndromes caused by mutations in the gene coding for dysferlin. Dysferlin is a large (~200kDa) membrane-anchored protein, required for maintenance of plasmalemmal integrity in muscle fibers. To facilitate analysis of dysferlin function in muscle cells, we have established a dysferlin-deficient myogenic cell line (GREG cells) from the A/J mouse, a genetic model for dysferlinopathy. GREG cells have no detectable dysferlin expression, but proliferate normally in growth medium and fuse into functional myotubes in differentiation medium. GREG myotubes exhibit deficiencies in plasma membrane repair, as measured by laser wounding in the presence of FM1-43 dye. Under the wounding conditions used, the majority (~66%) of GREG myotubes lack membrane repair capacity, while no membrane repair deficiency was observed in dysferlin-normal C2C12 myotubes, assayed under the same conditions. We discuss the possibility that the observed heterogeneity in membrane resealing represents genetic compensation for dysferlin deficiency.     

New cell line of mouse ependymoblastoma

A new cell line derived from transplanted mouse ependimoblastoma consists of typical fibroblast-like cells with well-defined pleomorphism. The line is characterized by a rapid increase and decrease of proliferative activity, by a short stationary phase and early degeneration. The average time of themitotic cycle was determined as being 22-24, tG1-11-12, ts-8-9, tG2-3 and tM-near 0.9 hours. The cytophotometrical evaluation of DNA content revealed two cell subpopulations with different ploidy, both in culture and in tumor in vivo. As compared to the original tumor cells, the cultured cells differ in wider variability of DNA content and a higher average ploidy per nucleus.