[Clinical utility of real-time fluorescent PCR for combined detection of anaplastic lymphoma kinase and c-ros oncogene 1 receptor tyrosine kinase in non-small cell lung cancer].

Objective: To investigate the clinical application value of combined detection of ALK fusion gene and c-ros oncogene 1 receptor tyrosine kinase (ROS1) fusion gene in non-small cell lung cancer (NSCLC) using real-time fluorescent PCR. Methods: A kit for combined detection of ALK fusion gene and ROS1 fusion gene based on fluorescent PCR was used to simultaneously detect the two fusion genes in 302 cases of NSCLC specimens. The results were validated through Sanger sequencing. The consistency of the two detection methods was analyzed. Results: All 302 cases of NSCLC specimens were successfully analyzed through fluorescent PCR (302/302). 12 cases (4.0%) were found to contain ALK fusion gene, including 3 cases with ALK-M1, 3 with ALK-M2, 3 with ALK-M3, 1 with ALK-M4, and 2 with ALK-M6 fusion gene.12 cases (4.0%) were found to contain ROS1 fusion gene, including 1 case with ROS1-M7, 8 cases with ROS1-M8, 1 case with ROS1-M12, 1 case with ROS1-M14, and 1 case with double-positive ROS1-M3 and ROS1-M8 fusion genes. The total detection rate of ALK fusion gene and ROS1 fusion gene was 7.9% (24/302) and 278 cases showed to be negative for ALK fusion gene and ROS1 fusion gene. The successful detection rates for Sanger DNA sequencing were also 100%. The positive, negative and total coincidence rates obtained by real-time fluorescent PCR and by Sanger DNA sequencing were all 100%. Conclusions: The results of Sanger DNA sequencing demonstrate that the real-time fluorescent PCR assay is equally effective in detecting ALK and ROS1 fusion genes in NSCLC tissues. Furthermore, real-time fluorescent PCR assay can be used to detect trace ALK and ROS1 fusion gene simultaneously in tiny samples, and can save time and avoid repeated sampling. It is worthy of recommendation as a rapid and reliable detection technique.

N-stearoyltyrosine protects primary neurons from Aß-induced apoptosis through modulating mitogen-activated protein kinase activity.

N-stearoyltyrosine (NsTyr), an anandamide (AEA) analogue is similar to AEA not only structurally but also in terms of biological activity. Since A beta-induced neuronal injury triggers the activation of mitogen-activated protein kinase (MAPK) pathways and the induction or activation of pro- and anti-apoptotic proteins, in the present study we aimed to assess the protective effect of NsTyr against A beta induced neuronal apoptosis. Cell viability and neuronal injury were respectively measured by 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyl tetrazolium bromide (MTT) assay and lactate dehydrogenase (LDH) assay. Hoechst staining and flow cytometric assessment were used to evaluate cell apoptosis. The anti-apoptotic mechanism involved MAPK phosphorylation and Bcl-2/Bax expression was investigated. The best neuroprotective effect on A beta 25-35-induced neuronal apoptosis was observed in the presence of NsTyr (1 microM). NsTyr exerted anti-apoptotic effect at least partly via activating p-ERK-Bcl-2 but suppressing p-p38-Bax pathways. Moreover a dynamic balance between p-ERK and p-p38 MAPK pathways in NsTyr-induced neuronal protection suggested an interaction between them. Our results indicated the neuroprotective effect of NsTyr on A beta 25-35-induced neuronal injury was at least partly due to anti-apoptosis and raised the possibility that NsTyr might reduce neurodegenerative disorders.

Induction of anion exchanger-1 translation and its opposite roles in the carcinogenesis of gastric cancer cells and differentiation of K562 cells.

Anion exchanger-1 (AE1), an erythroid-specific membrane protein, mediates the Cl(-)/HCO(-)(3) exchange across the plasma membrane and regulates intracellular pH. We have found that AE1 was unexpectedly expressed in gastric cancer cells and participated in the tumorigenesis of the cancer. Here, we focus on the induction of AE1 expression and its role in gastric carcinogenesis as well as in the differentiation of K562 cells. The results show that expression of AE1 is not related to genetic mutation or the mRNA level, but rather, that it is modulated by miR-24. miR-24 decreases the expression of AE1 through binding to the 3'UTR of AE1 mRNA. Transfection of an miR-24 into gastric cancer cells reduced the elevation of the AE1 protein, which resulted in return of AE1-sequestrated p16 to the nucleus, thereby inhibiting proliferation of the cells. Furthermore, the miR-24 inhibitor cooperated with hemin to induce the expression of AE1 in K562 cells and differentiation of the cells, which is consistent with results obtained from the cells cultured at pH 7.6 or from forced stable expression of AE1. These findings establish a novel regulation of miR-24-related AE1 expression in gastric carcinogenesis and erythropoiesis.