Subcellular distribution of glucocorticoid receptors in mouse fibroblasts.

Mouse fibroblasts contain a macromolecular binding component (receptor) which binds glucocorticoids specifically and with high affinity. This study shows that there are three different cellular forms of bound receptor and that it is experimentally possible to markedly alter the subcellular distribution of these three forms. Cells incubated with (3H)triamcinolone acetonide were broken after hypotonic shock and a 7000g hypotonic supernatant was obtained; the pellet was extracted with 0.3 M KCl, yielding a nuclear extract; the remaining pellet was resuspended in water, sonicated, and assayed for "nuclear residual" (i.e., nonextractable) radioactivity. If whole cells are incubated at 0 degrees in a growth medium, almost all of the bound steroid is located in the hypotonic supernatant fraction. Incubation at 37 degrees produces a shift of the steroid-bound macromolecule into the nuclear extractable form, while omission of glucose and addition of KCN at 37 degrees markedly increase the nuclear residual form at the expense of both the nuclear-extractable and supernatant forms. Since DNase treatment of chromatin liberates a soluble steroid-receptor complex, we believe that the nuclear residual form may be steroid-receptor complex tightly bound to chromatin. We propose a model suggesting that an energy-requiring process is required to generate free receptor from the chromatin complex to complete the normal cellular recycling system.     

The effects of epidermal growth factor on gene expression in human fibroblasts

A better understanding of the molecular effects of epidermal growth factor (EGF) on target cell can help to reveal important aspects of cellular proliferation, transformation, and apoptosis, as well as embryonic and fetal development. In this study, we examined the differences in gene expression of cultured fibroblasts with EGF stimulation for 48 h by using high-density complementary deoxyribonucleic acid (cDNA) arrays. We found that EGF could cause widespread alteration in gene expression. Eight hundred and fifty-five genes, more than 20% of those assayed, showed changed expression, which are involved in various cellular processes, such as energetic metabolism, biosynthesis, the progress of cell cycle, and the signaling pathways of receptor tyrosine kinase (RTKs) and G protein-coupled receptors (GPCRs). The most striking finding is that long-term EGF treatment on cultured fibroblasts resulted in down-regulation of the genes encoding membrane receptors and ion channels and desensitized RTKs and GPCRs to their physiological and nonphysiological stimuli, which seems to be a slow-acting, but permanent, effect of EGF on RTK and GPCR signaling pathways and to play important roles in embryonic and fetal development.     

Androgen sensitivity and gene expression in ras + myc-induced mouse prostate carcinomas.

We established an androgen-sensitive cell line (BR31-5) from a ras + myc-induced mouse prostate carcinoma and used this cell line together with a previously reported transplantable androgen-independent mouse prostate carcinoma to investigate patterns of expression for apoptosis-related genes in an androgen-deprived environment. Single cell suspensions derived from the BR31-5 cell line were inoculated into the flank of intact or castrated adult male C57BL/6 mice and tumors were harvested 12 days post-inoculation for Northern blotting. A transplantable androgen-independent prostate cancer was also inoculated into intact or castrated mice and tumors harvested 21 days later. Tumor volume analyses showed that BR31-5 carcinomas were androgen-sensitive. Northern blotting showed that mRNA levels for two apoptosis-related genes, transforming growth factor-beta 1 and c-myc, were significantly elevated to a similar extent in carcinomas grown in castrated hosts compared to intact hosts for both the androgen-sensitive BR31-5 and androgen-independent carcinomas. Levels of mRNA for tissue type plasminogen activator, shown previously to be elevated in androgen-independent carcinomas following growth in castrates, were also increased in BR31-5 carcinomas under similar androgen-deprived conditions but to a lesser extent. Interestingly, testosterone repressed prostate mRNA No. 2 levels shown previously to be similar in both the intact and castrated groups for androgen-independent carcinomas were significantly increased in the castrated group compared to the intact group for BR31-5 carcinomas. Therefore, specific patterns of expression for apoptosis-related genes may be able to discriminate androgen-sensitive and androgen-independent prostate cancer under androgen-deprived conditions.     

Cellular phenotype-dependent and -independent effects of vitamin C on the renewal and gene expression of mouse embryonic fibroblasts

Vitamin C has been shown to delay the cellular senescence and was considered a candidate for chemoprevention and cancer therapy. To understand the reported contrasting roles of vitamin C: growth-promoting in the primary cells and growth-inhibiting in cancer cells, primary mouse embryonic fibroblasts (MEF) and their isogenic spontaneously immortalized fibroblasts with unlimited cell division potential were used as the model pair. We used microarray gene expression profiling to show that the immortalized MEF possess human cancer gene expression fingerprints including a pattern of up-regulation of inflammatory response-related genes. Using the MEF model, we found that a physiological treatment level of vitamin C (10(-5) M), but not other unrelated antioxidants, enhanced cell growth. The growth-promoting effect was associated with a pattern of enhanced expression of cell cycle- and cell division-related genes in both primary and immortalized cells. In the immortalized MEF, physiological treatment levels of vitamin C also enhanced the expression of immortalization-associated genes including a down-regulation of genes in the extracellular matrix functional category. In contrast, confocal immunofluorescence imaging of the primary MEF suggested an increase in collagen IV protein upon vitamin C treatment. Similar to the cancer cells, the growth-inhibitory effect of the redox-active form of vitamin C was preferentially observed in immortalized MEF. All effects of vitamin C required its intracellular presence since the transporter-deficient SVCT2-/- MEF did not respond to vitamin C. SVCT2-/- MEF divided and became immortalized readily indicating little dependence on vitamin C for the cell division. Immortalized SVCT2-/- MEF required higher concentration of vitamin C for the growth inhibition compared to the immortalized wildtype MEF suggesting an intracellular vitamin C toxicity. The relevance of our observation in aging and human cancer prevention was discussed.     

Effect of cycloheximide and growth factors on gene expression in quiescent mouse embryo fibroblasts

Gene expression in quiescent mouse embryo fibroblasts was studied by labelling the cells with [14C] amino acids and analysing the proteins by electrophoresis in polyacrylamide gradient gels containing sodium dodecyl sulfate. Cycloheximide (CH) pretreatment of the cells was found to induce the synthesis of four proteins of molecular weights 72,000, 68,000, 42,000, and 29,000. These proteins were induced by CH both in serum-arrested and serum-stimulated cells. Addition of platelet-derived growth factor to serum-arrested quiescent cells also induced the synthesis of these proteins. Addition of CH and fetal calf serum (20%) to quiescent cells resulted in a dramatic increase in the synthesis of actin and another protein of molecular weight 29,000. The 29,000-dalton protein was present in higher quantities in the nuclei of induced cells. This protein appeared to be an early protein whose synthesis was transiently induced in quiescent cells within 3 hours of addition of 20% fetal calf serum (FCS). The synthesis of this protein was virtually turned off at 5-6 hours after the addition of serum. However, if CH or a combination of CH and FCS was present, a continuous synthesis of the 29 K protein was observed.     

The effects of glucocorticoid hormone on the expression of c-jun

The effects of glucocorticoid hormone on the expression of c-jun in the fibroblasts were studied. The expression of c-jun was repressed by dexamethasone in the NIH3T3 cells, but not in the transformed B104-1 or EJ-Ras cells. The repression was not relieved by the addition of cycloheximide.     

Down-regulation of glucocorticoid receptors in mouse lymphoma cell variants.

The mouse thymoma-derived cell line W7 is sensitive to the cytolytic action of glucocorticoids. We have isolated a novel class of cell variant that apparently overcomes its inherent sensitivity to glucocorticoids by reversibly down-regulating the level of glucocorticoid receptors. This phenotype is stable during subcloning in the presence and in the absence of glucocorticoids and is dominant in somatic cell hybrids with wild-type cells. Fusion of this variant with wild-type cells produces hybrids that down-regulate and are less sensitive to glucocorticoids than hybrids of receptor-negative and wild-type cells. This is the first demonstration of a phenotypic change which correlates with down-regulation of the glucocorticoid receptor.     

Recycling and desensitization of glucocorticoid receptors in v-mos transformed cells depend on the ability of nuclear receptors to modulate gene expression

In v-mos transformed cells, glucocorticoid receptor (GR) proteins that bind hormone agonist are not efficiently retained within nuclei and redistribute to the cytoplasmic compartment. These cytoplasmic desensitized receptors cannot be reutilized and may represent trapped intermediates derived from GR recycling. We have used the glucocorticoid antagonist RU486 to examine whether v-mos effects can be exerted on any ligand-bound GR. In the rat 6m2 cell line that expresses a temperature-sensitive p85gag-mos oncoprotein, RU486 is a complete antagonist and suppresses dexamethasone induction of metallothionein-1 mRNA at equimolar concentrations. Using indirect immunofluorescence, we observe efficient nuclear translocation of GR in response to RU486 treatment in either the presence or absence of v-mos oncoproteins. However, in contrast to the redistribution of agonist-bound nuclear receptors to the cytoplasm of v-mos-transformed cells, RU486-bound GRs are efficiently retained within nuclei. Interestingly, withdrawal of RU486 does not lead to efficient depletion of nuclear GR in either nontransformed or v-mos transformed cells. It is only after the addition of hormone agonist to RU486 withdrawn v-mos-transformed cells that GRs are depleted from nuclei and subsequently redistributed to the cytoplasm. Thus, only nuclear GRs that are agonist-bound and capable of modulating gene activity can be subsequently processed and recycled into the cytoplasm.     

Effect of the growth conditions on the expression of cell-surface-associated platelet-derived growth factor receptors in mouse fibroblasts

The conditions affecting the appearance and disappearance of platelet-derived growth factor (PDGF) receptors from the pool of active cell surface-associated receptors were studied. Receptor molecules were revealed in intact Swiss 3T3 fibroblasts by their ability to bind 125I-labeled PDGF and, due to their property to become phosphorylated in tyrosine following ligand binding, by antibodies to phosphotyrosine. PDGF receptor molecules were found to be quite scarce in exponentially growing fibroblasts as compared to quiescent cells. When growing cells were either shifted to a medium containing plasma or received suramin in the culture medium, cell surface-associated PDGF receptors largely increased. This process required about 12 h. Incubation of quiescent cells in serum, but not in plasma, induced a slow decrement of ligand-activatable receptors. In the presence of PDGF the rate of receptor removal from the cell surface was very rapid and was a function of the PDGF concentration. Quiescent cells deprived of cell-surface receptors by incubation with PDGF reexpressed PDGF receptors in about 14 h.     

Regulation of thymidylate synthase gene expression in mouse fibroblasts synchronized by mitotic selection

Previous studies have shown that thymidylate synthase gene expression is regulated over a wide range in response to growth stimulation in cultured mouse fibroblasts. In the present study we show that the gene is also regulated during the cell cycle in continuously growing cells. Our analyses were conducted with a fluorodeoxyuridine-resistant mouse 3T6 cell line that overproduces thymidylate synthase and its mRNA by a factor of 50 due to gene amplification. Cells were synchronized by mitotic selection. RNA blot analyses showed that the amount of thymidylate synthase mRNA increased 5- to 10-fold as cells progressed from G1 through the middle of S phase. S1 nuclease protection assays showed that the pattern of 5' termini of thymidylate synthase mRNA was the same in G1 and S phase. Despite the large increase in thymidylate synthase mRNA content, the level of the enzyme increased only by a factor of 2 as cells progressed from G1 to mid S phase. This apparent discrepancy can be explained by the fact that the enzyme is highly stable.     

Posttranscriptional control of human gamma interferon gene expression in transfected mouse fibroblasts.

Human gamma interferon genomic DNA was introduced into NIH 3T3 fibroblasts by calcium phosphate precipitation and was not expressed in these cells at the cytoplasmic mRNA or protein level. Treatment of the transfected cells with cycloheximide (1 microgram/ml) induced the accumulation of cytoplasmic gamma interferon mRNA and biologically active human gamma interferon. Analysis of the nuclear enriched RNA from untreated cells indicated that human gamma interferon mRNA was present, suggesting that cycloheximide may act by inhibiting a specific nuclease or may enhance the processing or transport of the RNA from the nucleus to the cytoplasm.     

Mechanoregulation of gene expression in fibroblasts

Mechanical loads placed on connective tissues alter gene expression in fibroblasts through mechanotransduction mechanisms by which cells convert mechanical signals into cellular biological events, such as gene expression of extracellular matrix components (e.g., collagen). This mechanical regulation of ECM gene expression affords maintenance of connective tissue homeostasis. However, mechanical loads can also interfere with homeostatic cellular gene expression and consequently cause the pathogenesis of connective tissue diseases such as tendinopathy and osteoarthritis. Therefore, the regulation of gene expression by mechanical loads is closely related to connective tissue physiology and pathology. This article reviews the effects of various mechanical loading conditions on gene regulation in fibroblasts and discusses several mechanotransduction mechanisms. Future research directions in mechanoregulation of gene expression are also suggested.