Lorentsenbaun8103

Salvianolic acid B (Sal B) is a potential cytotoxic polyphenol against cancer. In the present study the effect of Sal B and its molecular mechanism were investigated in the non‑small cell lung cancer (NSCLC) A549 cell line. The TGF‑β/MAPK/Smad signaling axis was explored. A549 cells were co‑cultured with and without different concentrations of Sal B (25, 50 and 100 µM respectively) and TGF‑β1 (9 pM) for 24 h. Cell epithelial‑mesenchymal transition (EMT), cell migration, cell cycle distribution, autophagy and apoptosis were assessed by western blotting (WB), wound healing assay and flow cytometry, respectively. Moreover, activation of MAPK, Smad2/3 and the downstream target, plasminogen activator inhibitor 1 (PAI‑1), were assessed by WB. The results demonstrated that Sal B inhibited TGF‑β1‑induced EMT and migration of A549 cells, hampered cell cycle progression and induced cell autophagy and apoptosis. Furthermore, Sal B inactivated MAPK signaling pathways and the phosphorylation of Smad2/3, especially the phosphorylation of Smad3 at the linker region, which resulted in decreased protein expression levels of PAI‑1 in TGF‑β1‑stimulated A549 cells. Overall, these results demonstrated that Sal B may have a potential therapeutic effect against NSCLC in vitro. The results of the present study indicated that the underlying active mechanism of Sal B in NSCLC may be closely related to the impeded activation of the MAPK and Smad2/3 signaling pathways. Therefore, Sal B may be a potential candidate NSCLC therapeutic agent.Behavioral assessment is the dominant approach for evaluating whether animal models of brain diseases can successfully mimic the clinical characteristics of diseases. At present, most research regarding brain diseases involves the use of rodent models. While studies have reported numerous methods of behavioral assessments in rodent models of brain diseases, each with different principles, procedures, and assessment criteria, only few reviews have focused on characterizing and differentiating these methods based on applications for which they are most appropriate. Therefore, in the present review, the representative behavioral tests in rodent models of brain diseases were compared and differentiated, aiming to provide convenience for researchers in selecting the optimal methods for their studies.MicroRNAs (miRNAs) are small non‑coding RNAs that control patterns of gene expression by inducing the degradation of mRNAs. In addition, miRNAs are known to serve an important role in the pathogenesis of atrial fibrillation (AF). In general, AF is diagnosed using electrocardiography. However, the present study investigated whether specific miRNAs derived from microarray analysis of human urine could regulate AF through the inhibition of calcium handling protein phosphorylation in an AF model. Microarray analysis of the transcriptome in the human urine of patients with paroxysmal supraventricular tachycardia and AF revealed that 7 differentially expressed miRNAs were significantly downregulated (miR‑3613, 6763, 423, 3162, 1180, 6511, 3197) in patients with AF. In addition, quantitative PCR results demonstrated that collagen I, collagen III, fibronectin and TGF‑β, which are fibrosis‑related genes, were upregulated in patients with AF. Furthermore, fibrosis‑related genes were upregulated in angiotensin II‑induced atrial myocytes, which demonstrated that these genes may be targets of miR‑423. In the AF cell model transfected with miR‑423, the expression of calcium handling proteins, including phosphorylated calmodulin‑dependent protein kinase II, was reduced. The transfection of miR‑423 attenuated damage to cardiac cells caused by calcium handling proteins. The findings highlight the importance of calcium handling protein phosphorylation changes in fibrosis‑induced AF and support miR‑423 detection in human urine as a potential novel approach of AF diagnosis.TP53 mutation is one of the most frequent gene mutations in head and neck squamous cell carcinoma (HNSCC) and could be a potential therapeutic target. Recently, the WEE1 G2 checkpoint kinase (WEE1) inhibitor adavosertib (Adv) has attracted attention because of its selective cytotoxicity against TP53‑mutated cells and has shown promising activity in early phase clinical trials. In the present study, it was demonstrated that combined treatment with Adv and a selective histone deacetylase 6 (HDAC6) inhibitor, ricolinostat (RCS), synergistically enhanced cell death induction in four out of five HNSCC cell lines with TP53 mutation (CAL27, SAS, HSC‑3, and OSC‑19), one HNSCC cell line with impaired TP53 function by HPV‑infection (UPCI‑SCC154), and TP53‑knockout human lung cancer cell line (A549 TP53‑KO), but not in TP53 wild‑type A549 cells. Time‑lapse imaging showed that RCS enhanced the Adv‑induced mitotic catastrophe. selleck inhibitor Consistent with this, RCS treatment suppressed checkpoint kinase 1 (Chk1) (Ser345) phosphorylation and co‑administration of RCS with Adv suppressed cyclin‑dependent kinase 1 (Tyr15) phosphorylation along with increased expression of γ‑H2A.X, a marker of DNA double‑strand breaks in CAL27 cells. These data showed that RCS enhanced Adv‑induced premature mitotic entry and cell death induction in the mitotic phase. However, although HDAC6 knockdown enhanced Adv‑induced cell death with γ‑H2A.X elevation, HDAC6 knockdown did not repress Chk1 phosphorylation in CAL27 cells. Our data demonstrated that the co‑administration of RCS with Adv in HNSCC cells resulted in the suppression of Chk1 activity, leading to synergistically enhanced apoptosis via mitotic catastrophe in a p53‑dependent manner. This enhanced cell death appeared to be partially mediated by the inhibition of HDAC6 activity by RCS.Gentamicin is an important aminoglycoside antibiotic used in the treatment of gram‑negative bacterial infections, but nephrotoxicity and ototoxicity reduce its utility. The autophagy pathway is involved in damage of auditory hair cells. With the aim of developing new strategies for attenuating gentamicin ototoxicity, the present study investigated the otoprotective mechanism of 2,3,4',5‑tetrahydroxystilbene‑2‑O‑β‑D-glucoside (THSG) in vitro using the mouse cochlear cell line UB/OC‑2. MTT assay demonstrated that gentamicin reduced UB/OC‑2 cell viability and western blotting showed that gentamicin upregulated autophagy‑related proteins, such as Beclin, autophagy related 5 and LC3‑II. THSG significantly attenuated gentamicin‑induced cytotoxicity, clearly reduced LDH release observed by LDH assay and decreased the expression of autophagy‑related proteins. Reverse‑transcription‑quantitative (RT‑q) PCR and western blotting showed that THSG against gentamicin‑induced autophagy via suppressing the expression of Sesn2, at both the mRNA and protein level and a possible involvement of AMP‑activated protein kinase (AMPK)/mTOR signaling response. Collectively, the present study demonstrated that THSG decreased gentamicin‑induced ototoxicity in UB/OC‑2 cochlear cells via the autophagic signaling in regulating Sesn2/AMPK/mTOR pathway. These results suggested that THSG might be a new therapeutic agent with the potential to attenuate gentamicin ototoxicity.The expression of the nuclear receptor transcription factor (TF) COUP‑TFII is broadly associated with cell differentiation and cancer development, including of pancreatic ductal adenocarcinoma (PDAC), a devastating disease with one of the poorest prognoses among cancers worldwide. Recent studies have started to investigate the pathological and physiological roles of a novel COUP‑TFII isoform (COUP‑TFII_V2) that lacks the DNA‑binding domain. As the role of the canonical COUP‑TFII in PDAC was previously demonstrated, the present study evaluated whether COUP‑TFII_V2 may have a functional role in PDAC. It was demonstrated that COUP‑TFII_V2 naturally occurs in PDAC cells and in primary samples, where its expression is consistent with shorter overall survival and peripheral invasion. Of note, COUP‑TFII_V2, exhibiting nuclear and cytosolic expression, is linked to epithelial to mesenchymal transition (EMT) and cancer progression, as confirmed by nude mouse experiments. The present results demonstrated that COUP‑TFII_V2 distinctively regulates the EMT of PDAC and, similarly to its sibling, it is associated with tumor aggressiveness. The two isoforms have both overlapping and exclusive functions that cooperate with cancer growth and dissemination. By studying how PDAC cells switch from one isoform to the other, novel insight into cancer biology was gained, indicating that this receptor may serve as a novel possible target for PDAC management.Following the publication of the above paper, a concerned reader drew to the Editor's attention that one of the fluorescence microscopic images featured in Fig. 4A had previously appeared in a different form (a portion of data in a different orientation) in another article published by the same authors [Yu J, Zhao L, Li Y, Li N, He M, Bai H, Yu Z, Zheng Z, Mi X, Wang E and We M Silencing of Fanconi anemia complementation group F exhibits potent chemosensitization of mitomycin C activity in breast cancer cells. J Breast Cancer 16 291‑299, 2013]. Furthermore, the data panel shown for the 'MDA‑MB‑231/untreated' experiment in Fig. 4A in the above paper appeared to be duplicated as the 'MDA‑MB‑231/MMC + control shRNA' experiment, albeit stained differently. After having received a request from the authors to publish a corrigendum in view of the errors identified in Fig. 4 of the above paper, the Editor of International Journal of Oncology has conducted an independent investigation of the matter and determined that this article should be retracted from the Journal on account of a lack of confidence in the presented data. Upon receiving this decision, the authors were not in agreement that the paper should be retracted. The Editor regrets any inconvenience that has been caused to the readership of the Journal. [the original article was published in International Journal of Oncology 45 129‑138, 2014; DOI 10.3892/ijo.2014.2400].Following the publication of the above article, an interested reader drew to the authors' attention that the 'NB‑4' and 'NB‑2' panels for the invasion and migration assays shown in Fig. 3B and C on p. 113 appeared to contain overlapping data, such that the data may have been derived from the same original source, even though the panels were intending to have shown results obtained under different experimental conditions. The authors have re‑examined their raw data and realized that these data were inadvertently mixed up when Fig. 3B and C were assembled. A corrected version of Fig. 3, showing the data as they should have appeared for the 'NB‑4' and 'NB‑2' invasion and migration assay experiments in Fig. 3B and C, is shown on the next page. The authors sincerely apologize for the errors that were introduced into Fig. 3 of the published article, and thank the Editor of Oncology Reports for allowing them the opportunity to publish a Corrigendum. All the authors agree to the publication of the authors, and they apologize to the readership for any inconvenience caused.