NEK2 plays an active role in Tumorigenesis and Tumor Microenvironment in Non-Small Cell Lung Cancer

Abnormal expression and dysfunction of Never-in-mitosis-A-related kinase 2 (NEK2) result in tumorigenesis. High levels of NEK2 are related to malignant progression, drug resistance, and poor prognosis. However, the relationship between NEK2 levels and the occurrence of non-small cell lung cancer (NSCLC) remains unknown. This study aimed to explore the impacts of NEK2 on the oncogenesis of NSCLC and the tumor microenvironment. Downregulation of NEK2 inhibited A549 and H1299 cell proliferation, migration, and invasion, blocking cell cycle at the G0/G1 phase. Loss of NEK2 inhibited the release of IL-10 from tumor cells, M2-like polarization of macrophages, angiogenesis, and vascular endothelial cell migration. Furthermore, NEK2 deficiency inhibited tumor growth in vivo. Taken together, NEK2 knockdown inhibited the occurrence and development of NSCLC, M2 polarization of macrophages, and angiogenesis. The abnormal expression of NEK2 might not only indicate tumor progression and patient prognosis but also serve as a potential molecular therapeutic target with great development prospects.     

Translational regulation in the brain by TDP-43 phase separation

The in vivo physiological function of liquid–liquid phase separation (LLPS) that governs non–membrane-bound structures remains elusive. Among LLPS-prone proteins, TAR DNA-binding protein of 43 kD (TDP-43) is under intense investigation because of its close association with neurological disorders. Here, we generated mice expressing endogenous LLPS-deficient murine TDP-43. LLPS-deficient TDP-43 mice demonstrate impaired neuronal function and behavioral abnormalities specifically related to brain function. Brain neurons of these mice, however, did not show TDP-43 proteinopathy or neurodegeneration. Instead, the global rate of protein synthesis was found to be greatly enhanced by TDP-43 LLPS loss. Mechanistically, TDP-43 LLPS ablation increased its association with PABPC4, RPS6, RPL7, and other translational factors. The physical interactions between TDP-43 and translational factors relies on a motif, the deletion of which abolished the impact of LLPS-deficient TDP-43 on translation. Our findings show a specific physiological role for TDP-43 LLPS in the regulation of brain function and uncover an intriguing novel molecular mechanism of translational control by LLPS.     

RAD51AP1 promotes progression of ovarian cancer via TGF-β/Smad signalling pathway

Ovarian cancer (OC) is one of the leading causes of female deaths. However, the molecular pathogenesis of OC has still remained elusive. This study aimed to explore the potential genes associated with the progression of OC. In the current study, 3 data sets of OC were downloaded from the GEO database to identify hub gene. Somatic mutation data obtained from TCGA were used to analyse the mutation. Immune cells were used to estimate effect of the hub gene to the tumour microenvironment. RNA-seq and clinical data of OC patients retrieved from TCGA were used to investigate the diagnostic and prognostic values of hub gene. A series of in vitro assays were performed to indicate the function of hub gene and its possible mechanisms in OC. As a result, RAD51AP1 was found as a hub gene, which expression higher was mainly associated with poor survival in OC patients. Up-regulation of RAD51AP1 was closely associated with mutations. RAD51AP1 up-regulation accompanied by accumulated Th2 cells, but reduced CD4 + T cells and CD8 + T cells. Nomogram demonstrated RAD51AP1 increased the accuracy of the model. Down-regulation of RAD51AP1 suppressed proliferation, migration and invasion capabilities of OC cells in vitro. Additionally, scatter plots showed that RAD51AP1 was positively correlated with genes in TGF-β/Smad pathway. The above-mentioned results were validated by RT-qPCR and Western blotting. In conclusion, up-regulation of RAD51AP1 was closely associated with mutations in OC. RAD51AP1 might represent an indicator for predicting OS of OC patients. Besides, RAD51AP1 might accelerate progression of OC by TGF-β/Smad signalling pathway.     

不同微生物大鼠腹腔注射模型尿液蛋白组学的比较

不同的微生物都可以引起腹腔感染,文中尝试利用尿液来区分不同的微生物感染.通过在大鼠腹腔内分别注射大肠杆菌、金黄色葡萄球菌和白色念球菌建立3种模型,收集感染后0、12、36、72h的尿液,并使用液相色谱串联质谱技术(LC-MS/MS)对尿蛋白进行分析.与感染前相比,在大肠杆菌腹腔注射模型中共鉴定到69个差异蛋白,在金黄色...     

林蛙受精卵的表面收缩波和卵裂起动收缩

林蛙受精卵表面的大豆凝集素结合位点没有侧向运动,联在结合位点上的标记物在卵表面位置的改变应该可以反映卵表面运动。本文利用近景摄影测量术和侧向摄影法观测卵表面标记点位置的变化,得到下面的结果:1.卵裂前30—40min,整个卵表面都向预定分裂沟中心移动,表示卵表面在收缩。卵裂前15min左右,沟中心附近的卵表面开始松弛,随之是离沟较远处的卵表面松弛,显示卵表面有一个从预定分裂沟中心向四周传播的收缩波(图2—5)。如果以相邻标记点之间的距离变化作图(图6),则出现两个波,一个是松弛波,一个是收缩波。本文对卵表面究竟出现一个波还是两个波的问题进行了讨论。2.分裂沟中心附近收缩时,高程逐渐下降,基部两侧逐渐加宽(图7和图8);卵松弛时,高程增加,基部收缩。所以卵高程的变化也是从预定分裂沟中心波浪形地向四周传播的。3.卵裂沟出现前3—5 min,预定分裂沟两端开始向沟中心收缩,这是卵裂起动收缩。以后收缩范围逐渐扩大,强度亦增加,但预定分裂沟两侧的卵表面没有向预定分裂沟两端移动。这一结果支持了赤道区收缩的假说。     

A non-structural protein encoded by Rice Dwarf Virus targets to the nucleus and chloroplast and inhibits local RNA silencing

RNA silencing is a potent antiviral mechanism in plants and animals. As a counter-defense, many viruses studied to date encode one or more viral suppressors of RNA silencing (VSR). In the latter case, how different VSRs encoded by a virus function in silencing remains to be fully understood. We previously showed that the nonstructural protein Pns10 of a Phytoreovirus, Rice dwarf virus (RDV), functions as a VSR. Here we present evidence that another nonstructural protein, Pns11, also functions as a VSR. While Pns10 was localized in the cytoplasm, Pns11 was localized both in the nucleus and chloroplasts. Pns11 has two bipartite nuclear localization signals (NLSs), which were required for nuclear as well as chloroplastic localization. The NLSs were also required for the silencing activities of Pns11. This is the first report that multiple VSRs encoded by a virus are localized in different subcellular compartments, and that a viral protein can be targeted to both the nucleus and chloroplast. These findings may have broad significance in studying the subcellular targeting of VSRs and other viral proteins in viral-host interactions.

     

Activation of the bitter taste sensor TRPM5 prevents high salt-induced cardiovascular dysfunction

Science China Life Sciences - High salt intake is a known risk factor of cardiovascular diseases. Our recent study demonstrated that long-term high salt intake impairs transient receptor potential...