Anti-E2F-1 (D426) Antibody (A25422)

Aberrant expression of microRNA (miRNA) has been previously demonstrated to play an important role in a wide range of cancer types and further elucidation of its role in the mechanisms underlying tumorigenesis, anticarcinogenesis and potential chemotherapeutics is warranted. We chose the anti-benzo[a]pyrene-7,8-diol-9,10-epoxide-transformed human bronchial epithelial cell line 16HBE-T to study miRNAs involved in anticarcinogenesis. In resveratrol-treated cells, we found that miR-622 was upregulated, whereas it was downregulated in 16HBE-T cells, suggesting that miR-622 potentially acts as a tumor suppressor. Increasing the level of miR-622 by transient transfection-induced inhibition of proliferation and G(0) arrest in 16HBE-T cells and the lung cancer cell line H460 as demonstrated by cell viability and cell cycle analysis. MiR-622 dramatically suppressed the ability of 16HBE-T cells to form colonies in vitro and to develop tumors in nude mice. According to bioinformatics analysis, K-Ras messenger RNA was predicted as a putative miR-622 target; this was confirmed by western blot and luciferase reporter assays. Cell growth retardation was inhibited upon knockdown of K-Ras and an increase in the level of miR-622 in 16HBE-T cells. Furthermore, miR-622 inhibitor partially impaired the growth of 16HBE-T cells as demonstrated by luciferase reporter activity and K-Ras protein expression in 16HBE-T cells. In summary, miR-622 functions as a tumor suppressor by targeting K-Ras and impacting the anticancer effect of resveratrol. Therefore, miR-622 is potentially useful as a clinical therapy. MiR-622 impacts the K-Ras signal pathway and the potentially anticarcinogenic or chemotherapeutic properties warrant further investigation.

Growth associated protein 43 (Gap43) is a neuron-specific phosphoprotein, which plays critical role in axon growth and synapses functions during neurogenesis. Here we identified two transcription start sites (TSSs) of the mouse Gap43 gene designated as a proximal site at +1, and a distal TSS at -414. RT-qPCR data reveal that the transcripts from +1 increase 10-fold on day-1 post-all-trans retinoic acid (RA) treatment, reached a peak value at day-4 and gradually reduced. By contrast, the distal TSS directs a late, remarkably sharp increase of the transcripts from the day-5 on. An intense signal of Gap43 at the neurites and neural network is determined by the efficient transcription of the distal promoter as shown in Northern blot and RT-qPCR assay. In addition, the targeting of p300 in combination with a differential enrichment of Brm to Brg1 change at the distal promoter region of the gene is induced under RA treatment. The over hundreds of GA rich stretches and the GAGAG elements located between the two TSSs may take parts in the differential transcription of the two TSSs of the Gap43. Our findings provide the first evidence on the identification and differential transcription of the two TSSs of the mouse Gap43 gene, and the preferential distribution of their protein products in the specific stages of RA induced P19 differentiation. These data suggest the efficient transcription of the distal promoter of Gap43 is an important mark for the transition of P19 cells from the progenitor stage into neuronal differentiation.

MicroRNAs are approximately 22nt non-coding RNAs that are present in a broad range of multicellular organisms. MicroRNAs play important roles in many biological or pathological processes by regulating the expression of their target genes. The fast and accurate identification of miRNA targets is a bottleneck in the clarification of the function of miRNAs. Here, we established a rapid and accurate strategy to identify miRNA functional target genes by combination of bioinformatic prediction with Cytoplasmic/Nuclear (C/N) ratios of mRNAs. The strategy comprises three steps: bioinformatic prediction, determination of mRNA C/N ratios, and confirmation by Western blotting, and might be suitable to most miRNAs. Our method will make a significant contribution to the study of the biological functions of miRNAs.