Both low and high concentrations of staurosporine induce G1 arrest through down-regulation of cyclin E and cdk2 expression

Staurosporine has been reported to cause arrest of cells in G1 phase at low concentration and in G2 phase at high concentration. This raises the question of why the effects of staurosporine on the cell cycle depend on the applied concentration. In order to verify these multiple functions of staurosporine in Meth-A cells, we used cyclin E as a landmark of G1/S transition, cyclin B as a landmark of G2/M transition and MPM2 as a hallmark of M phase. We found that staurosporine arrested cells in G1 phase at a low concentration (20 nM) and in G2/M phase at a high concentration (200 nM). However, 200 nM staurosporine increased the expression of cyclin B and cdc2 proteins, suggesting that the cells progressed through the G2/M transition, and increased the expression of MPM2 protein, indicating that the cells entered M phase. Moreover, 200 nM staurosporine increased the expression of p53 and p21 proteins and inhibited the expression of cyclin E and cdk2 proteins, suggesting that the cells were arrested in the G1 phase of the next cycle. Morphological observation showed similar results as well. These data suggest that the G2/M accumulation induced by 200 nM staurosporine does not reflect G2 arrest, but rather results from M phase arrest, followed by progression from M phase to the G1 phase of the next cycle without cytokinesis, and finally arrest of the cells in G1 phase.     

Improvement of a Potential Anthrax Therapeutic by Computational Protein Design

Past anthrax attacks in the United States have highlighted the need for improved measures against bioweapons. The virulence of anthrax stems from the shielding properties of the Bacillus anthracis poly-γ-d-glutamic acid capsule. In the presence of excess CapD, a B. anthracis γ-glutamyl transpeptidase, the protective capsule is degraded, and the immune system can successfully combat infection. Although CapD shows promise as a next generation protein therapeutic against anthrax, improvements in production, stability, and therapeutic formulation are needed. In this study, we addressed several of these problems through computational protein engineering techniques. We show that circular permutation of CapD improved production properties and dramatically increased kinetic thermostability. At 45 °C, CapD was completely inactive after 5 min, but circularly permuted CapD remained almost entirely active after 30 min. In addition, we identify an amino acid substitution that dramatically decreased transpeptidation activity but not hydrolysis. Subsequently, we show that this mutant had a diminished capsule degradation activity, suggesting that CapD catalyzes capsule degradation through a transpeptidation reaction with endogenous amino acids and peptides in serum rather than hydrolysis.     

Proteome dynamics and proteome function of cardiac 19S proteasomes

Myocardial proteasomes are comprised of 20S core particles and 19S regulatory particles, which together carry out targeted degradation of cardiac proteins. The 19S complex is unique among the regulators of proteasomes in that it affects both the capacity and specificity of protein degradation. However, a comprehensive molecular characterization of cardiac 19S complexes is lacking. In this investigation, we tailored a multidimensional chromatography-based purification strategy to isolate structurally intact and functionally viable 19S complexes from murine hearts. Two distinct subpopulations of 19S complexes were isolated based upon (1) potency of activating 20S proteolytic activity, and (2) molecular composition using a combination of immuno-detection, two-dimensional-differential gel electrophoresis, and MS-based approaches. Heat shock protein 90 (Hsp90) was identified to be characteristic to 19S subpopulation I. The physical interaction of Hsp90 with 19S complexes was demonstrated via multiple approaches. Inhibition of Hsp90 activity using geldanamycin or BIIB021 potentiated the ability of subpopulation I to activate 20S proteasomes in the murine heart, thus demonstrating functional specificity of Hsp90 in subpopulation I. This investigation has advanced our understanding of the molecular heterogeneity of cardiac proteasomes by identifying molecularly and functionally distinct cardiac 19S complexes. The preferential association of Hsp90 with 19S subpopulation I unveils novel targets for designing proteasome-based therapeutic interventions for combating cardiac disease.     

二核苷酸重复多态性的非同位素检测及其在基因诊断中的应用

本文报道了一种检测二核苷酸重复多态性的简便的非同位素法,利用重复序列两侧的特异引物进行ＰＣＲ扩增,产生的等位片段在薄层变性聚丙烯酰胺凝胶电泳上分离,再用灵敏的银染法显色。该方法不需要标记ＰＣＲ产物,简便、快速,分辨率可达１ｂｐ,并可用多对引物同时进行多重ＰＣＲ分析。用此方法对ＤＭＤ家系成员ｄｙｓｔｒｏｐｈｉｎ基因的５＇－脑型外显子止游区和３＇－非翻译区的两个（ＣＡ）。位点进行了扩增片段长度多态性分     

重力钝感的水稻突变体在重力和微重力条件下淀粉体的观察分析（简报）

植物向重性的研究一直受到关注,主要的研究集中在双子叶模式生物拟南芥中,而对单子叶植物的研究却很少。植物对重力感受的方式存在多种解释,但目前大量证据表明淀粉体一平衡石理论较为合理,它认为淀粉体作为平衡石在植物向重性反应中发挥了重要的作用。经过100多年的研究,现已从生理学与     

G蛋白Rab3a协同神经生长抑制因子(GIF)抑制神经元的生长

为了研究G蛋白Rab3a与神经生长抑制因子 (growthinhibitoryfactor,GIF ,原称金属硫蛋白 3,MT 3)相互作用对神经元细胞生长的影响 ,以嗜铬细胞瘤株 (pheochromocytoma)PC1 2充当神经元模型 .将hMT 3(humanMT 3)和Rab3a基因分别克隆至真核表达载体pFlag CMV 2和pSV HA中 ,质粒共同转染PC1 2细胞 ,观察转染后细胞的生长状态 .以共转染pFlag CMV 2 hMT 1和pSV HA Rab3a的细胞组作为对照 ,验证hMT 3与Rab3a相互作用对PC1 2影响的特异性 .结果发现 ,共转染pFlag CMV 2 hMT 3和pSV HA Rab3a的PC1 2细胞生长明显受到抑制 ,细胞生长抑制率与GIF在脑提取物存在F的神经元生长抑制作用接近 ,但转染两基因中的任何单个基因以及共转染pFlag CMV 2 hMT 1和pSV HA Rab3a对PC1 2细胞生长无影响 .进一步构建重组表达质粒pGEX 4T 1 Rab3a和pGEX 4T 1 hMT 3,转化大肠杆菌BL2 1 ,经谷胱甘肽 Sepharose 4B亲和层析、凝血酶酶切和SephacrylS 1 0 0纯化 ,得到纯度 95 %以上的Rab3a和hMT 3蛋白 .体外细胞生物学活性检测表明 ,表达的Rab3a蛋白与重组hMT 3蛋白共培养PC1 2 ,对细胞的生长产生了明显的特异性协同抑制作用 ,抑制曲线与GIF在脑提取物存在下的神经元生长抑制曲线极为相似     

水稻蜡质基因第一内含子中g片段上核蛋白因子结合位点的确定

水稻蜡质基因 5’非翻译区中的第一内含子具有增强基因表达的作用 ,本实验室曾检测到该内含子中的一段 171bp长的g片段与水稻未成熟种子核蛋白存在特异性结合。本文进一步用凝胶滞后实验和足印实验确定了该核蛋白在g片段上的结合位点位于蜡质基因转录起始点下游 783～ 818bp处 ,该结合位点富含AT碱基 ;Southwesternblot实验测出该蛋白的分子量约为 2 0kD。用硫酸铵分步沉淀和肝素 Sepharose柱层析的方法对这一蛋白进行了初步纯化。还初步检测了此蛋白DNA结合活性对温度的耐受性。以上特征提示它可能属于HMG类DNA结合蛋白     

RACK1 and CIS mediate the degradation of BimEL in cancer cells

RACK1 is a 7-WD motif-containing protein with numerous downstream effectors regulating various cellular functions. Using a yeast two-hybrid screen, we identified dynein light chain 1 as a novel interacting partner of RACK1. Additionally, we demonstrated that RACK1 formed a complex with DLC1 and Bim, specifically BimEL, in the presence of apoptotic agents. Upon paclitaxel treatment, RACK1, DLC1, and CIS mediated the degradation of BimEL through the ElonginB/C-Cullin2-CIS ubiquitin-protein isopeptide ligase complex. We further showed that RACK1 conferred paclitaxel resistance to breast cancer cells in vitro and in vivo. Finally, we observed an inverse correlation between CIS and BimEL levels in both ovarian and breast cancer cell lines and specimens. Our study suggests a role of RACK1 in protecting cancer cells from apoptosis by regulating the degradation of BimEL, which together with CIS could play an important role of drug resistance in chemotherapy.     

Constitutive β-catenin activation in osteoblasts impairs terminal osteoblast differentiation and bone quality

Accumulating evidence suggests that Wnt/β-catenin signaling plays a central role in controlling bone mass. We previously reported that constitutive activation of β-catenin (CA-β-catenin) in osteoblasts potentially has side effects on the bone growth and bone remodeling process, although it could increase bone mass. The present study aimed to observe the effects of osteoblastic CA-β-catenin on bone quality and to investigate possible mechanisms of these effects. It was found that CA-β-catenin mice exhibited lower mineralization levels and disorganized collagen in long bones as confirmed by von Kossa staining and sirius red staining, respectively. Also, bone strength decreased significantly in CA-β-catenin mice. Then the effect of CA-β-catenin on biological functions of osteoblasts were investigated and it was found that the expression levels of osteocalcin, a marker for the late differentiation of osteoblasts, decreased in CA-β-catenin mice, while the expression levels of osterix and alkaline phosphatase, two markers for the early differentiation of osteoblasts, increased in CA-β-catenin mice. Furthermore, higher proliferation rate were revealed in osteoblasts that were isolated from CA-β-catenin mice. The Real-time PCR and western blot examination found that the expression level of c-myc and cyclin D1, two G1 progression-related molecules, increased in osteoblasts that were isolated from the CA-β-catenin mice, and the expression levels of CDK14 and cyclin Y, two mitotic-related molecules that can accelerate cells entering into S and G2/M phases, increased in osteoblasts that were isolated from the CA-β-catenin mice. In summary, osteoblastic CA-β-catenin kept osteoblasts in high proliferative state and impaired the terminal osteoblast differentiation, and this led to changed bone structure and decreased bone strength.