Romanian Language, Literature and Educational System under the Sign of “the Sociological Concept of Language”

AbstractWithin the Romanian cultural milieu, the Communist ideology generates a special type of literary, linguistic and educational discourse enhancing the newly-occurred paradigm. The political traits turn into an “aesthetic canon” converting the discourses into politically-oriented texts. The writing pattern brings forward its own ideology, subjecting literature to the contemporary political values and functions. Our study focuses on these aspects, trying to emphasize the shift of values and points of view concerning the discourse itself, be it literary, linguistic or educational

Identification of FDA-approved drugs targeting the Farnesoid X Receptor

The farnesoid X receptor (FXR) belongs to the nuclear receptor family and is activated by bile acids. Multiple, chemically rather diverse, FXR agonists have been developed and several of these compounds are currently tested in clinical trials for NAFLD and cholestasis. Here, we investigated possible FXR-agonism or antagonism of existing FDA/EMA-approved drugs. By using our recently developed FRET-sensor, containing the ligand binding domain of FXR (FXR-LBD), 1280 FDA-approved drugs were screened for their ability to activate FXR in living cells using flow cytometry. Fifteen compounds induced the sensor for more than twenty percent above background. Real-time confocal microscopy confirmed that avermectin B1a, gliquidone, nicardipine, bepridil and triclosan activated the FRET sensor within two minutes. These compounds, including fluticasone, increased mRNA expression of FXR target genes OSTα and OSTβ in Huh7 cells, and in most cases also of MRP2, SHP and FGF19. Finally, avermectin B1a, gliquidone, nicardipine and bepridil significantly increased IBABP promoter activity in a luciferase reporter assay in a dose-dependent manner. In conclusion, six FDA/EMA-approved drugs currently used in the clinical practice exhibit moderate agonistic FXR activity. This may on the one hand explain (undesired) side-effects, but on the other hand may form an opportunity for polypharmacology

Monitoring bile acid transport in single living cells using a genetically encoded Förster resonance energy transfer sensor

Bile acids are pivotal for the absorption of dietary lipids and vitamins and function as important signaling molecules in metabolism. Here, we describe a genetically encoded fluorescent bile acid sensor (BAS) that allows for spatiotemporal monitoring of bile acid transport in single living cells. Changes in concentration of multiple physiological and pathophysiological bile acid species were detected as robust changes in Förster resonance energy transfer (FRET) in a range of cell types. Specific subcellular targeting of the sensor demonstrated rapid influx of bile acids into the cytoplasm and nucleus, but no FRET changes were observed in the peroxisomes. Furthermore, expression of the liver fatty acid binding protein reduced the availability of bile acids in the nucleus. The sensor allows for single cell visualization of uptake and accumulation of conjugated bile acids, mediated by the Na(+)-taurocholate cotransporting protein (NTCP). In addition, cyprinol sulphate uptake, mediated by the putative zebrafish homologue of the apical sodium bile acid transporter, was visualized using a sensor based on the zebrafish farnesoid X receptor. The reversible nature of the sensor also enabled measurements of bile acid efflux in living cells, and expression of the organic solute transporter αβ (OSTαβ) resulted in influx and efflux of conjugated chenodeoxycholic acid. Finally, combined visualization of bile acid uptake and fluorescent labeling of several NTCP variants indicated that the sensor can also be used to study the functional effect of patient mutations in genes affecting bile acid homeostasis. CONCLUSION: A genetically encoded fluorescent BAS was developed that allows intracellular imaging of bile acid homeostasis in single living cells in real tim

The glucocorticoid mometasone furoate is a novel FXR ligand that decreases inflammatory but not metabolic gene expression

The Farnesoid X receptor (FXR) regulates bile salt, glucose and cholesterol homeostasis by binding to DNA response elements, thereby activating gene expression (direct transactivation). FXR also inhibits the immune response via tethering to NF-κ B (tethering transrepression). FXR activation therefore has therapeutic potential for liver and intestinal inflammatory diseases. We aim to identify and develop gene-selective FXR modulators, which repress inflammation, but do not interfere with its metabolic capacity. In a high-throughput reporter-based screen, mometasone furoate (MF) was identified as a compound that reduced NF-κ B reporter activity in an FXR-dependent manner. MF reduced mRNA expression of pro-inflammatory cytokines, and induction of direct FXR target genes in HepG2-GFP-FXR cells and intestinal organoids was minor. Computational studies disclosed three putative binding modes of the compound within the ligand binding domain of the receptor. Interestingly, mutation of W469A residue within the FXR ligand binding domain abrogated the decrease in NF-κ B activity. Finally, we show that MF-bound FXR inhibits NF-κ B subunit p65 recruitment to the DNA of pro-inflammatory genes CXCL2 and IL8. Although MF is not suitable as selective anti-inflammatory FXR ligand due to nanomolar affinity for the glucocorticoid receptor, we show that separation between metabolic and anti-inflammatory functions of FXR can be achieved

Loss of SerpinA5 protein expression is associated with advanced-stage serous ovarian tumors

Epithelial ovarian cancer, the most lethal neoplasm of the female genital tract, is usually diagnosed at an advanced stage as obvious symptoms are absent at early stages. This disease is believed to originate from malignant transformation of the ovarian surface epithelium or fallopian tube. Histologically, several subtypes are being recognized, with serous histology accounting for the majority of cases. Serous tumors include serous borderline tumors and serous carcinomas. A better understanding of the tumor biology and molecular mechanisms involved in these tumors is needed, as both patient management and prognosis differ substantially. Previous microarray analysis identified SerpinA5, a uPA inhibitor, as key regulator for indolent borderline behavior. As carcinomas are characterized by loss of SerpinA5 mRNA expression, we hypothesized that SerpinA5 protein expression is reduced or lost in carcinomas when compared with borderline tumors. We performed SerpinA5 immunohistochemical staining on 32 serous borderline tumors, 187 primary serous carcinomas and 62 serous omental metastases. Reduced or absent SerpinA5 protein staining was observed in carcinomas when compared with borderline tumors (P <0.001). SerpinA5 protein expression was significantly lowered in the omental metastases (P <0.001) when compared with the matching primary carcinoma. Interestingly, SerpinA5 protein expression was reduced in advanced-stage borderline tumors, often characterized by micropapillary growth and/or microinvasion, when compared with early-stage borderline tumors (P=0.015). In conclusion, SerpinA5 expression is significantly reduced in advanced-stage serous borderline tumors and serous carcinomas when compared with the early-stage counterparts, and reduction of expression is linked to more aggressive features of borderline tumors. Modern Pathology (2011) 24, 463-470; doi:10.1038/modpathol.2010.214; published online 19 November 201

Frequent Inactivation of Cysteine Dioxygenase Type 1 Contributes to Survival of Breast Cancer Cells and Resistance to Anthracyclines

Genome-wide DNA methylation analyses have identified hundreds of candidate DNA-hypermethylated genes in cancer. Comprehensive functional analyses provide an understanding of the biologic significance of this vast amount of DNA methylation data that may allow the determination of key epigenetic events associated with tumorigenesis.info:eu-repo/semantics/publishe