In Vitro最新文献

The growth and differentiation of L6 myoblasts are subject to control by two proteins secreted by cells of the Buffalo rat liver line. The first of these, rat insulinlike growth factor-II (formerly designated multiplication stimulating activity) is a potent stimulator of myoblast proliferation and differentiation, as well as associated processes such as amino acid uptake and incorporation into protein, RNA synthesis, and thymidine incorporation into DNA. In addition, this hormone causes a significant decrease in the rate of protein degradation. All of these actions seem to be attributable to a single molecular species, although their time courses and sensitivity to the hormone differ substantially. The second protein, the differentiation inhibitor (DI), is a nonmitogenic inhibitor of all tested aspects of myoblast differentiation, including fusion and the elevation of creatine kinase. Indirect immunofluorescence experiments demonstrated that DI also blocks accumulation of myosin heavy chain and myomesin. Upon removal of DI after 72 h incubation, all of these effects were reversed and normal myotubes containing the usual complement of muscle-specific proteins were formed. Thus, this system makes it possible to achieve specific stimulation or inhibition of muscle cell differentiation by addition of purified proteins to cloned cells in serum-free medium.

The phorbol ester, 12-0-tetradecanoyl-phorbol-13-acetate (TPA) was used as a comitogen with the plant lectins phytohemagglutinin (PHA) and concanavalin A (ConA) in short-term cultures of whole blood from nonmammalian vertebrates. Stimulation with TPA in addition to standard mitogens resulted in a synergistic effect, consistently yielding more metaphases than cultures stimulated with either PHA, ConA, or TPA alone and is successful with blood samples as small as 0.1 ml. The increased mitotic index makes it possible to use different banding procedures for systematic studies. Also, because the amount of blood needed is so small, this procedure, unlike other published techniques, does not require the destruction of smaller animals to do chromosome studies.

Postnatal rat heart cells in culture enriched with respect to muscle cells were obtained by either high density seeding or by the replating technique. [3H]Thymidine incorporation to DNA and the enzymatic pattern of cytoplasmic and lysosomal enzymes have been studied as a function of the culture's age, of seeding density, and replating. It was shown that replating maintains predominance of myocyte population for at least 2 wk in culture; heavy seeding density allows homogeneous myocyte population for the 1st wk in culture; and the enzyme profile of the culture may serve as an indicator for the type of cell population in culture and its state of differentiation.

It was observed previously that primordia of fetal rat testes when explanted in vitro in a synthetic medium at the outset of sexual differentiation differentiate seminiferous cords during the following days, but that the addition of 15% fetal bovine serum prevents this morphogenesis. In the present study, human, horse, bovine calf, and rat sera were shown to exert the same effect. Very low concentrations of human or fetal bovine serum (0.5 or 1%) were sufficient to produce the serum effect, which was only slightly reduced when the serum was heated. The serum activity was not removed by dialysis (membrane cut-off 15 000), but it disappeared after treatment with trichloroacetic or perchloric acids or after trypsin digestion. Partial purification of the active factor(s) from human serum was achieved by successive gel filtration, affinity chromatography, and ion exchange chromatography. Analysis of the active fractions by electrofocusing and immunoelectrophoresis placed the activity within the alpha globulin group. Among a series of purified serum proteins tested, alpha 2-HS-glycoprotein was found to exhibit the serum effect, though this activity was heat labile.

Six different techniques were evaluated to define better those technical factors that are most critical for obtaining prometaphase cells for banding analysis. Our results demonstrate: colcemid exposures of 30 min or less have no effect on increasing the yield of prometaphase cells, colcemid exposures of greater than 0.1 microgram/ml can be toxic, methotrexate depresses the mitotic index significantly and seems to increase the incidence of prometaphase cells only because it suppresses later forms; and (d) the optimum number of cytogenetically satisfactory prometaphase cells can be obtained with a 4-h exposure to a combination of low concentration actinomycin D (0.5 microgram/ml) and colcemid (0.1 microgram/ml). This technique inhibits chromosome condensation while permitting prometaphase cells to accumulate for 4 h.

Reproducible subculture of adult human prostatic epithelial cells from normal, benign hyperplastic and malignant tissue has been achieved. Cholera toxin is the key component in the culture system, but use of an optimal basal medium (PFMR-4) supplemented with a high level of serum in collagen-coated dishes also improves growth and serial propagation.

In this report, we present evidence that estrogen-dependent rat mammary tumor cells produce autostimulatory (autocrine) growth factors in response to estrogens, and that hormone autonomous cells produce autocrine activities that are no longer under estrogen regulation. Confirmation of the in vivo significance of autostimulatory factors was sought by inoculating rats with mixed populations of estrogen-dependent, responsive, and autonomous MTW9/PL mammary tumor cells, and showing that after 16 weeks growth in castrated male rats, the estrogen-dependent and responsive mammary tumor cells not only survived, but continued to grow. Three out of seven of the clones derived from apparently autonomous tumors were shown to be estrogen-dependent or responsive. These are the first data establishing that estrogen-dependent (responsive) mammary tumor cells are able to grow in the absence of physiological concentrations of sex steroid hormones in vivo, and that autocrine factors secreted from adjacent autonomous cells are able to substitute for the steroid hormone requirement.

When Drosophila cell lines are exposed to physiological doses of the steroid molting hormone, ecdysterone, they enter mitotic arrest and differentiate morphologically. These responses are accompanied by specific changes in gene expression. Several enzyme activities (acetylcholinesterase, beta-galactosidase, dopa decarboxylase, and catalase) are induced and the synthesis of a cytoplasmic actin and the four small heat-shock proteins is initiated. Several of these ecdysterone inducible genes have been physically isolated and characterized, in several cases by DNA sequencing. Current studies focus on introducing cloned ecdysterone inducible genes into responsive cells by DNA mediated transfection. Once it is clear that these introduced genes acquire the normal pattern of hormone-regulated gene expression in the cell, in vitro mutagenesis can be used before transfection to modify their structure. Transient expression, then, can become a functional assay to define regions of DNA flanking the coding region of inducible genes that are needed for proper gene expression and regulation in cultured cells.

Human lung epithelial cells have been isolated and maintained in pure culture and characterized during their time in culture. Any residual fibroblasts were removed by selective trypsinization within the first 48 h in culture and the residual epithelial cells from the primary culture grew to confluent density. The epithelial cells at Passage 2 or greater were serially subpassaged when cultures reached ca. 80% confluency. This procedure permitted us to conduct biochemical and structural studies of starting materials and subsequent population doublings. Electron microscope evaluation of both initial monolayers and cell suspensions showed cultures to be composed of a single cell type. These cells had microvilli on their free or apical surface. Subsequent population doubling level 1 up to 5 exhibited the same structures. They contained lamellar inclusions, which are typical of Type II alveolar epithelial cells. Fetal lung (age 18 to 20 wk) cell suspensions processed for electron microscopy before culturing showed cells to be undifferentiated, epithelial-like with small microvilli along cell borders, and with desmosomes at cell junctions. Lamellar inclusions were not observed in these cells. Ultrastructural studies of the cultured epithelial cells demonstrated that the lamellar inclusions had a slightly positive reaction when tested for acid phosphatase. Phospholipid analysis of these lung epithelial cells showed a phospholipid composition consistent with that found in surfactant-containing Type II cells. Cultured epithelial cells stained with phosphine 3-R demonstrated a green fluorescent cytoplasm and nucleus with brightly fluorescent yellow-orange perinuclear particles. The preceding characterization of these cells leads us to conclude that they exhibit structural and biochemical features commensurate with Type II epithelial cells from human lung. Moreover, these selection techniques applied to the isolation of human lung Type II cells from the tissue permit us to study the differentiative function of these cells routinely under conditions of growth in vitro.

Liver parenchymal cells cultured in serum-free medium may retain their ability to synthesize glycogen in response to insulin. Specific hormone requirements are needed by hepatocytes to retain the biochemical pattern of mature cells. Insulin supplementation of culture medium seems to be essential to maintain the glycogen synthesis rate of cultured hepatocytes. The continuous presence of dexamethasone amplified the insulin-induced glycogen synthesis. Cytophotometric analysis showed differences in the way that individual cells accumulate glycogen in response to insulin stimulus, which indicates that liver parenchymal cells in culture are functionally heterogeneous.