动物细胞核内miRNA的加工过程

microRNA(miRNA)是存在于真核生物中的一类大的基因家族,与其靶mRNA分子一起形成了生物体内复杂的调控网络。miRNA在基因表达调节过程中的关键性作用涉及到发育时序的控制、造血细胞的分化、细胞凋亡、细胞增殖以及器官的形成等方面。其中最值得探讨的问题是miRNA的生物发生过程及其调控机制。近年来,miRNA在动物细胞核中加工机制的研究取得了较大的进展。在细胞核中,RNA多聚酶II指导的miRNA基因的转录,微处理器作用下的pri-miRNA的剪切及exportin-5协助下的pre-miRNA的输出过程彼此协调,共同而有序的完成miRNA在细胞核中的加工过程。     

Structural Differences between Pri-miRNA Paralogs Promote Alternative Drosha Cleavage and Expand Target Repertoires

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Editing independent effects of ADARs on the miRNA/siRNA pathways

Adenosine deaminases acting on RNA (ADARs) are best known for altering the coding sequences of mRNA through RNA editing, as in the GluR‐B Q/R site. ADARs have also been shown to affect RNA interference (RNAi) and microRNA processing by deamination of specific adenosines to inosine. Here, we show that ADAR proteins can affect RNA processing independently of their enzymatic activity. We show that ADAR2 can modulate the processing of mir‐376a2 independently of catalytic RNA editing activity. In addition, in a Drosophila assay for RNAi deaminase‐inactive ADAR1 inhibits RNAi through the siRNA pathway. These results imply that ADAR1 and ADAR2 have biological functions as RNA‐binding proteins that extend beyond editing per se and that even genomically encoded ADARs that are catalytically inactive may have such functions.     

PLEKHA7 defines an apical junctional complex with cytoskeletal associations and miRNA-mediated growth implications

E-cadherin-p120 catenin complexes are essential for adherens junction (AJ) formation and for the maintenance of the normal epithelial phenotype. PLEKHA7 was originally identified as a member of this complex that tethers microtubules to the AJs and supports their overall integrity. Recently, we revealed that PLEKHA7 regulates cellular behavior via miRNAs by associating with the microprocessor complex at the apical zonula adherens (ZA). We have also identified a new set of PLEKHA7 interacting partners at the apical ZA, via proteomics. Our analysis shows that the main groups of proteins associating with PLEKHA7 are cytoskeletal-related and RNA-binding proteins. Here, we provide extended evidence for association of PLEKHA7 with several of these proteins. We also show that PLEKHA7 loss activates the actin regulator cofilin in a p120-dependent manner, providing an explanation for the effects of PLEKHA7 on the cortical actin ring. Interestingly, PLEKHA7 regulates the levels and associates with PP1α, a phosphatase responsible for cofilin activation. Finally, we clarify the mode of regulation of the oncogenic miR-19a by PLEKHA7. Overall, our findings support a multi-layered role of PLEKHA7 in converging cytoskeletal dynamics and miRNA-mediated growth regulation at the ZA, with potentially critical implications in cancer that warrant further investigation.     

一种心肌细胞电参数微机实时分析系统

本文介绍了一种分析心肌细胞膜电位参数的微机系统。该系统能用两种采样间隔(50μs和1ms)自动地把动作电位的0至4相转换为数字量,并测量和打印出静息电位、最大上升速率、振幅、时程以及波形面积。同时,还能转换并测量心肌收缩张力信号。该系统配备有心肌细胞膜电位的概率密度函数分析软件以及基于 FFT 的功率谱分析软件。     

Fabrication of a low-cost on-stage cell incubator with full automation

In recent years the possibility of observing by microscopy the dynamic activity of living cells has been largely pursued. We have developed a low-cost (~ 260 euros) on-stage cell incubator for inverted optical microscopes. This device allows to keep cells in good conditions for their survival and proliferation. The device is based on the use of the Arduino microprocessor interfaced with LabView. It can be connected to a computer via USB port allowing to monitor and register all the useful parameters of the measurements: temperature, CO₂ concentration and relative humidity. It consists of a closed metallic and plastic (PMMA) chassis which provides optical transparency to the petri dish in order to use interference contrast imaging techniques. The system exploits also a second Arduino microprocessor to perform autofocus of the images and to automatically acquire images at defined time intervals. Cell biology laboratories could easily construct this device to allow also students to follow dynamic processes of living cells and to practice with the DIY (Do-It-Yourself) approach to biology. At the same time, students could become familiar with the use of low-cost microprocessors like Arduino.