Flow cytometry combines the advantages of microscopy and biochemical analysis in a single highly sensitive technique for a rapid examination of numerous individual living cells. It has become a potent and essential tool in the studies of the physiology of the whole cell and its organelles. Rhodamine 123 is a vital fluorescent dye used in flow cytometry. As it is specifically concentrated in mitochondria because of the transmembrane potential that these organelles maintain in living cells, rhodamine 123 is thus a useful probe for monitoring the abundance and activity of mitochondria. A critical survey of the routine use of rhodamine 123 together with flow cytometry in mitochondrial research is presented.
The culture of rabbit tenocytes could be a useful model in the study of the physiopathology and pharmacotoxicology of tendons. This work was undertaken to examine the in vitro behavior of tenocytes form juvenile rabbit Achilles tendons. We report observations of the morphological and biological characteristics of primary culture and subsequent passages of rabbit tendon cells cultured in monolayer. Data obtained by electron microscopy and growth curves were complementary. After 36 passages, the generation time of tenocytes did not change and no sign of senescence could be seen. Primary culture and the first passages retained the expression of tenocyte differentiated functions, synthesis of type I collagen and decorin. Cell growth behavior was not modified upon passaging. However, when subcultured, tenocytes displayed a modulated phenotype.
Chondrocytes cultivated in monolayer rapidly divide and lose their morphological and biochemical characteristics, whereas they maintain their phenotype for long periods of time when they are cultivated in alginate beads. Because cartilage has a low cellularity and is difficult to obtain in large quantities, the number of available cells often becomes a limiting factor in studies of chondrocyte biology. Therefore, we explored the possibility of restoring the differentiated properties of chondrocytes by cultivating them in alginate beads after two multiplication passages in monolayer. This resulted in the reexpression of the two main markers of differentiated chondrocytes: Aggrecan and type II collagen gene expression was strongly reinduced from day 4 after alginate inclusion and paralleled protein expression. However, 2 weeks were necessary for total suppression of type I and III collagen synthesis, indicators of a modulated phenotype. Interleukin-1beta, a cytokine that is present in the synovial fluid of rheumatoid arthritis patients, induces many metabolic changes on the chondrocyte biology. Compared with cells in primary culture, the production of nitric oxide and 92-kDa gelatinase in response to interleukin-1beta was impaired in cells at passage 2 in monolayer but was fully recovered after their culture in alginate beads for 2 weeks. This suggests that the effects of interleukin-1beta on cartilage depend on the differentiation state of chondrocytes. This makes the culture in alginate beads a relevant model for the study of chondrocyte biology in the presence of interleukin-1beta and other mediators of cartilage destruction in rheumatoid arthritis and osteoarthrosis.
Articular chondrocytes from 2- to 3-month-old rabbits were cultured in serum-free medium supplemented with fibroblast growth factor. The effects were studied of GH, insulin-like growth factors (IGFs), and insulin on the production of IGF-I, IGF-II, and their binding proteins (BPs) and on cell multiplication. In the control culture medium, IGF-I levels were about one fifth those of IGF-II. Western blot analysis of the BPs revealed a predominant 30K form and 24K and 20K forms which appeared inconsistently and in small quantities. Ten to 100 ng/ml human GH had no mitogenic effect, and even had a slightly inhibitory effect. IGF-I at 10 ng/ml stimulated cell multiplication above the control level by 41% and at 50 ng/ml by 74%, whereas the mean increase obtained with IGF-II (10 and 50 ng/ml) was only 19%. At the same doses, insulin had no effect, but at 5 micrograms/ml it stimulated cell multiplication by a mean of 67%. There was a positive correlation between cell number and release into the medium of both IGF-I (r = 0.86) and IGF-II (r = 0.77). Neither IGF-I nor IGF-II production was affected by GH. Insulin (5 micrograms/ml) increased IGF-I production by a factor of 2.6, but increased IGF-II production by a factor of only 1.4. Under the various conditions of culture with different doses of GH and insulin, cell multiplication, relative to the control value was positively correlated to the IGF-I/IGF-II production ratio (r = 0.77). It would, therefore, seem that IGF-I secreted by the chondrocytes may stimulate their own proliferation. When IGFs or insulin were added to the culture medium, changes in the electrophoretic profiles of the BPs included an increase in the 30K form and an increase in or the appearance of the 24K and 20K forms. Ten and 50 ng/ml IGF-I or IGF-II had effects equal to or greater than those induced by 5 micrograms/ml insulin. These results indicate that the syntheses of BPs and IGFs are coordinated and that IGFs may be implicated in the control of the synthesis of their BPs.
Cell lines were established from rabbit articular chondrocytes following transfection with a plasmid encoding SV40 early function genes. This resulted in cell immortalization (130 passages have been completed for the oldest cell line) with acquisition of characteristics of partial transformation such as reduced serum requirements for normal and clonal growth. The immortalized chondrocytes, called SVRAC, did not form multilayer foci when maintained in postconfluent culture. Their ability to form colonies in soft agar was not increased in comparison with normal chondrocytes, but they were weakly tumorigenic in nude mice. SVRAC lost the ability to synthesize type II collagen and Alcian blue-stainable matrix, which are markers of the differentiated chondrocyte phenotype, and synthesized predominantly type I collagen. Studies of collagen gene expression showed that pro alpha 1 (II) mRNA was undetectable, whereas pro alpha 1 (I) collagen mRNA was expressed even in late passage cultures. Unlike normal dedifferentiated chondrocytes, SVRAC were unable to re-express the differentiated phenotype in response to tridimensional culture or microfilament depolymerization. Cell lines obtained from chondrocytes transfected either in primary culture or just after release of cells from cartilage displayed the same behaviour. Thus SV40 early genes were able to immortalize rabbit articular chondrocytes, but the resulting cell lines displayed an apparently irreversibly dedifferentiated phenotype. These cell lines can be used as models to identify regulatory pathways that are required for the maintenance or reexpression of differentiated function in chondrocytes.
The effect of the switch to aerobic growth conditions was examined in rabbit articular chondrocytes transferred to culture. Spectroscopic analysis of the cytochromes of the respiratory chain shows that only cytochrome b is present in chondrocytes from cartilage, cytochromes c, c1, and a.a3 being undetectable as compared with the typical spectrum found in a primary cell culture on day 4. Steady state levels of RNA transcripts of nuclear (cytochrome c) and mitochondrial genes (cytochrome b and cytochrome oxidase subunits II and III) involved in the oxidative metabolism were determined relative to the RNA transcripts of the nuclear gene for glyceraldehyde phosphate dehydrogenase involved in the glycolytic pathway and to mitochondrial ribosomal RNAs. Chondrocytes transferred to culture showed a general increase in the levels of all transcripts, but the effect on mitochondrial transcripts was much greater (x 20) than the effect on nuclear transcripts (x 3-4). These results show the absence of a coordinate regulation of the expression of mitochondrial and nuclear genes coding for components of the respiratory chain. The increase in mitochondrial DNA triggered by culture conditions does not appear to be sufficient to account for the enhanced transcription. Concomitant with these mitochondrial changes, the level of transcripts for the collagen II gene involved in the differentiation function decreases dramatically (3% of the control on day 3).
Flow cytometry has been widely used to quantify fluorescent probes in cell culture. However, FCM is not adapted to toxicological screenings due to the cost, the length and the poor reproducibility of this technique. Moreover, several multicenter studies have preferred microtitration methodologies for drug screening. A new fluorimetric technology has been designed that is sensitive and adapted to direct screening in 96-well microplates. This fluorimeter uses cold light technology (CLF) with chemical and physical modifications of the lighting system (Rat et al., 1995). CLF allows reading of UV, visible and near infrared fluorescence by increasing light energy (from 1000 to 2300 lumens) and reducing the calorific part of light (IR > 900 nm, Joule effect). It induces a decrease in background and a 500- to 1000-fold improvement of detection limit of probes in comparison with classical fluorimeters and permits detection of pg/ml to fg/ml. CLF allows easy evaluation of cell injury induced by physical agents (UVA) or chemical toxins (CCl4). Four biological endpoints for cytotoxicity evaluation have been tested with several probes: proliferation (H33258); viability (fluorescent Neutral Red); cell-cell adhesion (calcein-AM); and mitochondrial metabolic effects (Rhodamine 123). Rh123 assay appeared more sensitive than fluorimetric or photometric detection of Neutral Red assay. Cold light fluorimetry (CLF) permits direct detection of low concentrations of probes (pg/ml to fg/ml). CLF is shown to improve classical cytotoxicity assays and, owing to its adaptability to microtitration (in 6-, 12- or 96-well plates and in Petri dishes), it is thus a promising alternative to flow cytometry for drug cytotoxicity screening.
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