A Novel Enhanced Green FluorescentProtein-Expressing NOG Mouse for Analyzingthe Microenvironment of Xenograft Tissues

The interaction between transplanted cells and host tissues is important for the growthand maintenance of transplanted cells. To analyze the mechanisms of these interactions, asystemic fluorescent protein-expressing mouse is a useful recipient. In this study, wegenerated a novel NOG strain, which strongly expresses enhanced green fluorescent protein(EGFP; PgkEGFP-NOG), especially in the liver, kidney, gastrointestinal tract, and testis.Because the host tissues expressed EGFP, xenotransplanted human cancer cells were clearlyidentified as EGFP-negative colonies in PgkEGFP-NOG mice. Immunohistochemical analysisrevealed that EGFP-expressing stromal tissues formed a complicated tumor microenvironmentwithin xenograft tissues. Moreover, a similar microenvironment was observed in human iPScell-derived teratomas. Collectively, these results indicated that a suitablemicroenvironment is essential for the growth and maintenance of xenotransplanted cells andthat PgkEGFP-NOG mice represent a useful animal model for analyzing the mechanisms ofmicroenvironment formation.     

Segmental differences in short-chain fatty acid transport in rabbit colon: Effect of pH and Na

Short-chain fatty acids (SCFAs) are the predominant luminal anion in the mammalian colon. Although they are rapidly absorbed in vivo, little is known about the mechanisms of transepithelial transport in vitro. Previous studies have suggested that SCFA transport may be linked to Na absorption or an anion exchange mechanism. We compared the transport of propionate under short-circuit conditions in rabbit proximal and distal colon to determine whether there were segmental differences, how SCFAs may be linked to either Na absorption or anion transport, and whether SCFAs, as weak electrolytes, may be affected by transepithelial pH gradients. In distal colon, propionate transport was not significantly altered by stimulation of electrogenic Na absorption, epinephrine or Cl removal. However, a modest transepithelial pH gradient (luminal 6.8/serosal 7.4) stimulated propionate absorption. In proximal colon, propionate transport was significantly altered by manuevers that either stimulated (lowered [Na] in the bathing media) or inhibited (theophylline) apical Na−H exchange. Neither Cl removal, nor the anion exchange inhibitor DIDS, nor a transepithelial bicarbonate gradient, altered propionate transport. A transepithelial pH gradient inhibited propionate secretion, but not in a manner entirely consistent with the effect of pH on the distribution of a weak electrolyte. These results suggest that there is significant segmental heterogeneity in colonic SCFA transport; that transepithelial propionate fluxes are altered by changes in pH or electroneutral Na absorption (Na−H exchange), but not by chloride removal, bicarbonate gradients or electrogenic Na absorption. Regulation of SCFA transport may be an important factor in the physiology of colonic fluid balance.     

The role of tumor necrosis factor-α for interleukin-10 production by murine dendritic cells

In the present study, we examined the role of tumor necrosis factor (TNF) in interleukin (IL)-10 production by dendritic cells (DCs) using bone-marrow derived DCs from wild type (WT) and TNF-α knockout (TNF-α^−/−) mice. Toll-like receptor (TLR) stimulation induced substantial level of IL-10 production by WT DCs, but significantly low level of IL-10 production by TNF-α^−/− DCs. In contrast, no significant difference was detected in IL-12 p40 production between WT and TNF-α^−/− DCs. Addition of TNF-α during TLR stimulation recovered the impaired ability of TNF-α^−/− DCs for IL-10 production. This recovery appeared to be associated with an activation of extracellular signal-regulated kinase, p38 mitogen-activated protein kinase, and phosphatidylinositol 3-kinase/Akt following the TNF-α addition. Blocking these kinases significantly inhibited IL-10 production by TNF-α^−/− DCs stimulated with TLR ligands plus TNF-α. Thus, TNF-α may be a key molecule to regulate the balance between anti-inflammatory versus inflammatory cytokine production in DCs.     

Multiple components of the spliceosome regulate Mcl1 activity in neuroblastoma

Cancer treatments induce cell stress to trigger apoptosis in tumor cells. Many cancers repress these apoptotic signals through alterations in the Bcl2 proteins that regulate this process. Therapeutics that target these specific survival biases are in development, and drugs that inhibit Bcl2 activities have shown clinical activity for some cancers. Mcl1 is a survival factor for which no effective antagonists have been developed, so it remains a principal mediator of therapy resistance, including to Bcl2 inhibitors. We used a synthetic-lethal screening strategy to identify genes that regulate Mcl1 survival activity using the pediatric tumor neuroblastoma (NB) as a model, as a large subset are functionally verified to be Mcl1 dependent and Bcl2 inhibitor resistant. A targeted siRNA screen identified genes whose knockdown restores sensitivity of Mcl1-dependent NBs to ABT-737, a small molecule inhibitor of Bcl2, BclXL and BclW. Three target genes that shifted the ABT-737 IC50 >1 log were identified and validated: PSMD14, UBL5 and PRPF8. The latter two are members of a recently characterized subcomplex of the spliceosome that along with SART1 is responsible for non-canonical 5′-splice sequence recognition in yeast. We showed that SART1 knockdown similarly sensitized Mcl1-dependent NB to ABT-737 and that triple knockdown of UBL5/PRPF8/SART1 phenocopied direct MCL1 knockdown, whereas having no effect on Bcl2-dependent NBs. Both genetic spliceosome knockdown or treatment with SF3b-interacting spliceosome inhibitors like spliceostatin A led to preferential pro-apoptotic Mcl1-S splicing and reduced translation and abundance of Mcl1 protein. In contrast, BN82865, which inhibits the second transesterification step in terminal spliceosome processing, did not have this effect. These findings demonstrate a prominent role for the spliceosome in mediating Mcl1 activity and suggest that drugs that target either the specific UBL5/PRPF8/SART1 subcomplex or SF3b functions may have a role as cancer therapeutics by attenuating the Mcl1 survival bias present in numerous cancers.     

53BP1与DNA双链断裂损伤修复

DNA的精确复制和遗传对维持基因组稳定性有重要作用。DNA双链断裂损伤可能诱导细胞凋亡和染色质重排,在肿瘤的发生发展过程中发挥作用。53BP1是DNA双链断裂修复中的重要调节蛋白质之一,对调控损伤修复平衡和维持基因组稳定性起着重要作用。本文主要对53BP1的结构、生物学功能、信号通路、分子机制和翻译后修饰做一浅显的总结和展望,希望能为53BP1的深入研究提供一些理论基础。     

量子点应用于人骨肉瘤HOS细胞系研究的生物毒性评价

目的:将合成的两种量子点应用于研究人骨肉瘤HOS细胞系,初步检测其生物毒性,以确定本研究所制备量子点可否应用于骨肉瘤的基础研究。方法:将生长良好的HOS细胞与制备的两种量子点分别共培养,使用MTT试剂盒检测不同时间点细胞活性,实验进行三次,取其平均值,分析所得数据,并绘制出量子点浓度-细胞活性曲线,分析得出两者之间的量效关系。结果:1.4μM的CdTe/ZnS QDs和0.275μM的Cd Te/Cd S QDs分别是本实验中对HOS细胞的最高毒性浓度。较短时间(30 min)的暴露分别导致了48.6±0.9%和31.9±0.8%的细胞死亡,3 h后分别有33.7±2.3%和49.4±1.1%的细胞存活。而在孵育了18 h之后,只有28.0±1.6%和15.3±1.6%的细胞存活。我们可以观察到均为典型的时间/浓度曲线。结论:选用适宜浓度以及共培养时间,本实验制备的量子点完全可以满足纳米量子点粒子使用于HOS细胞研究的基本生物学条件,可以进行人骨肉瘤HOS细胞测温等的一些列实验操作。由于量子点自身优越的光学性能以及可接受的生物安全性,在肿瘤研究领域具有很大的潜力,将会成为肿瘤示踪、检测、以及靶向治疗新的有力工具。