UHRF2, a Ubiquitin E3 Ligase,Acts as a Small Ubiquitin-like Modifier E3 Ligase for Zinc Finger Protein 131

Small ubiquitin-like modifier (SUMO), a member of the ubiquitin-related protein family, is covalently conjugated to lysine residues of its substrates in a process referred to as SUMOylation. SUMOylation occurs through a series of enzymatic reactions analogous to that of the ubiquitination pathway, resulting in modification of the biochemical and functional properties of substrates. To date, four mammalian SUMO isoforms, a single heterodimeric SUMO-activating E1 enzyme SAE1/SAE2, a single SUMO-conjugating E2 enzyme ubiquitin-conjugating enzyme E2I (UBC9), and a few subgroups of SUMO E3 ligases have been identified. Several SUMO E3 ligases such as topoisomerase I binding, arginine/serine-rich (TOPORS), TNF receptor-associated factor 7 (TRAF7), and tripartite motif containing 27 (TRIM27) have dual functions as ubiquitin E3 ligases. Here, we demonstrate that the ubiquitin E3 ligase UHRF2 also acts as a SUMO E3 ligase. UHRF2 effectively enhances zinc finger protein 131 (ZNF131) SUMOylation but does not enhance ZNF131 ubiquitination. In addition, the SUMO E3 activity of UHRF2 on ZNF131 depends on the presence of SET and RING finger-associated and nuclear localization signal-containing region domains, whereas the critical ubiquitin E3 activity RING domain is dispensable. Our findings suggest that UHRF2 has independent functional domains and regulatory mechanisms for these two distinct enzymatic activities.     

黄体酮对3T3-L1脂肪前体细胞成脂分化后细胞中UCP2基因表达的影响

目的:观察体外培养条件下3T3-L1脂肪前体细胞诱导分化成的成熟脂肪细胞中解偶联蛋白2(UCP2)mRNA表达水平及黄体酮对其表达的影响。方法:体外培养3T3-L1脂肪细胞,在诱导3T3-L1脂肪细胞分化成熟后,经不同黄体酮浓度10μm/25μM/50μM/75μM/100μM刺激后,抽提总RNA,用RT-PCR检测UCP2 mRNA的表达。结果:黄体酮会促进成熟脂肪细胞中UCP2 mRNA的表达,(P<0.05)其中25μM浓度刺激下UCP2 mRNA表达量最高。结论:体外培养中,黄体酮对成熟脂肪细胞中UCP2 mRNA的表达与调控具有一定的影响。     

黄体酮对3T3-L1脂肪前体细胞成脂分化后细胞中UCP2基因表达的影响

目的：观察体外培养条件下3T3-L1脂肪前体细胞诱导分化成的成熟脂肪细胞中解偶联蛋白2（UCP2）mRNA表达水平及黄体酮对其表达的影响。方法：体外培养3T3-L1脂肪细胞,在诱导3T3．L1脂肪细胞分化成熟后,经不同黄体酮浓度10μm／25μM／50μM／75μM/100μM刺激后,抽提总RNA,用RT—PCR检测UCP2mRNA的表达。结果：黄体酮会促进成熟脂肪细胞中UCP2mRNA的表达,（P〈0．05）其中25μM浓度刺激下UCP2mRNA表达量最高。结论：体外培养中,黄体酮对成熟脂肪细胞中UCP2mRNA的表达与调控具有一定的影响。     

B波段紫外线照射对ＮＨ３Ｔ３细胞bcl—2、n—myc、c—fos三种基因表达的影响

用免疫组织化学SPTM试剂盒标记,用Quantimet520型图像分析仪定量分析B波段紫外线照射对NIH3T3细胞bcl-2,n-myc,c-fos三种基因表达的影响,结果发现Bcl-2(bcl-2表达的蛋白质）定位于细胞质,N-myc,c-Fos(分别为n-myc,c-fos表达的蛋白质）在细胞核中高表达,在细胞质中低表达,三种基因蛋白在对照组（未受紫外线照射的正常NIH3T3细胞中）均有表达,NIH3T3细胞经B波段紫外线照射后,9小时前Bcl-2无显变化。9小时后急剧增高,超过最初值;N-myc于照射后1小时前无显变化。1小时后降低,9小时后显剧增高,并超过最初值;c-Fos于照射后即下降,0.5小时后回升,逐渐达到最初值。     

T3SS1和T3SS2影响副溶血弧菌生物学特性及细胞致病性的比较

【目的】探究两套Ⅲ型分泌系统T3SS1和T3SS2影响副溶血弧菌生物学特性及细胞致病性的差异和相关性。【方法】以T3SS1和T3SS2主要结构基因vcrD1和vcrD2为研究对象,利用同源重组技术分别构建单基因和双基因缺失株ΔvcrD1、ΔvcrD2、ΔvcrD1-vcrD2,以及互补株CΔvcrD1和CΔvcrD2;分析各菌株的生长特性、生物被膜形成能力、运动性的差异;比较各菌株对细胞毒性以及对细胞炎性因子转录水平的影响。【结果】与野生株相比,各缺失株的生长速度无显著差异。缺失株ΔvcrD1生物被膜形成能力、运动性和细胞毒性均极显著下降;缺失株ΔvcrD2主要表现为细胞炎性因子IL-1β和IL-6转录水平的显著上调,同时对细胞毒性作用下降。双基因缺失株ΔvcrD1-vcrD2在缺失株ΔvcrD1的基础上,生物被膜形成能力、运动性、细胞毒性均进一步显著下降,但在细胞炎性因子的转录水平上,则与ΔvcrD1一致,与野生株相比均无显著差异。【结论】T3SS1和T3SS2对副溶血弧菌生物学特性和细胞致病性的影响存在差异。T3SS1主要影响细菌的生物被膜形成、运动性及细胞毒性作用;T3SS2不影响生物被膜形成、运动性等生物学特性,参与细菌对细胞炎性反应中的负调控作用,同时具有一定的细胞毒性作用。T3SS1有助于副溶血弧菌在环境中的生存,而T3SS2可有利于细菌在宿主体内免疫逃避的过程。T3SS1和T3SS2对副溶血弧菌生物学特性和细胞致病性的影响可能存在一定的相关作用,具体机制有待进一步研究。     

PKCeta associates with cyclin E/Cdk2 complex in serum-starved MCF-7 and NIH-3T3 cells

Protein kinase C (PKC) encodes a family of enzymes implicated in cellular differentiation, growth control, and tumor promotion. However, very little is known with respect to the molecular mechanisms that link protein kinase C to cell cycle control. Here we report that PKCeta associates with the cyclin E/Cdk2 complex. This is shown for the ectopically overexpressed PKCeta in NIH-3T3 cells, the inducibly expressed PKCeta in MCF-7 cells (under control of the tetracycline-responsive promoter), and the endogenously expressed PKCeta in mouse mammary epithelial HC11 cells. Subcellular cell fractionation experiments revealed that the complex with cyclin E is formed mostly in the nuclear fractions, although in these cells PKCeta is predominantly expressed in the cytosolic fractions. The complex of PKCeta and cyclin E was studied at various phases of the cell cycle, in serum-starved quiescent cells and in cells stimulated with serum to reenter the cell cycle. Interestingly, the interaction between PKCeta and cyclin E was most prominent in serum-starved cells and was disintegrated when cells entered the cells cycle. Immunofluorescence staining demonstrated that in serum-starved cells PKCeta is concentrated at the perinuclear zone, which is also the site of its colocalization with cyclin E. Colocalization of PKCeta and cyclin E in the perinuclear region was observed in serum-starved cells, and less in proliferating cells. These experiments suggest that the interaction between PKCeta and cyclin E is carefully regulated, and is correlated with the inactivated form of the cyclin E/Cdk2 complex. Thus, our studies support an important link between PKC and cell cycle control.