果蝇Mad蛋白MH2结构域的晶体结构

Decapentaplegic（Dpp）属于转化生长因子β（Transforming growth factor β,TGF-β）超家族,在果蝇（Drosophila）发育过程中起着调节细胞增殖、分化和胚胎模式化等重要作用.Smad蛋白家族的成员能够特异性地介导TGF-β信号在细胞内的传递.Mother Against Dpp（Mad）是第一个发现的Smad蛋白,本研究解析了其MH2（mad homology2）结构域（Mad-MH2）的晶体结构,分辨率为2.80,该结构和已知的哺乳动物Smad蛋白的MH2结构具有较高的相似性.未磷酸化的Mad-MH2在结晶过程中形成了同源三聚体,而且在溶液中表现出浓度依赖的寡聚趋势.结构分析显示,Mad-MH2同源三聚体的形成主要由C末端的SSVS序列介导;进一步体外生化实验表明,最后两个Ser残基的磷酸化可以大大增强Mad-MH2的聚合能力.有意思的是,一个不对称单位中的同源三聚体中,只有两个Mad-MH2分子的C末端具有稳定的空间构象;通过和R-Smad/Smad4异源三聚体结构的比较,本研究认为Mad-MH2同源三聚体中带有柔性SSVS末端序列的分子比较容易被Co-Smad替代,进而形成具有生理功能的异源三聚体.     

胰岛素受体底物PH结构域相互作用蛋白结构和功能研究进展

PHIP是一种与胰腺β细胞中胰岛素受体底物（IRS）的PH结构域相互作用的蛋白。根据小鼠PHIP（mPHIP）mRNA翻译的不同起始位点,除全长的PHIP1外,mPHIP基因还编码其他3种不同变异体。在胰岛素诱导的信号途径中,主要分布于细胞核的PHIP1和IRS-1的PH结构域相互作用,介导IRS蛋白酪氨酸的磷酸化。IRS-2和PHIP1的共表达能诱导IRS在细胞膜上的定位,促进葡萄糖转运蛋白4（GLUT4）向细胞质膜的转移。PHIP1的表达能提高β-细胞内细胞周期蛋白D2的表达,促进β细胞的生长。PHIP1的表达活化蛋白激酶B（PKB）,活化的PKB能明显抑制β细胞的凋亡。PHIP与胰岛素信号传导途径中其他信号分子的相互作用机制尚不明确。     

PH结构域的结构和功能研究进展

PH结构域是一种存在于多种信号转导蛋白和细胞骨架蛋白中的大约由120个氨基酸组成的功能性区域.不同蛋白质中的PH结构域在一级结构上的同源性并不很高,但其空间结构中肽链主链的折叠方式基本相同,而主要差别存在于其中的三个可变环上,含有这些环的侧面带有正电荷,被认为可能是其配体的结合部位.目前已知的配体有G蛋白βγ亚单位（Gβγ）、蛋白激酶C（PKC）和磷脂酰肌醇衍生物（PIP₂或IP₃）,所以PH 结构域可能介导信号蛋白与这些分子间的相互作用,参与细胞信号转导网络的构成.     

溴结构域蛋白4的结构和功能及其抑制剂在肿瘤研究中的应用

溴结构域和超末端结构域(bromodomain and extraterminal domain, Bet)家族是表观基因组的调节因子,也是肿瘤细胞生存所依赖的肿瘤相关基因表达的关键驱动因子。溴结构域蛋白4 (bromodomain-containing protein 4, Brd4)是溴域和端外蛋白家族中的一员,通常识别乙酰化组蛋白,并定位于目的基因的启动子或增强子区域,启动并维持肿瘤相关基因的表达。Brd4与多种转录因子调控和染色质修饰密切相关,并参与DNA损伤修复、维持端粒功能,从而维持肿瘤细胞的存活。本文围绕Brd4蛋白的结构、功能及其抑制剂在肿瘤研究中的应用进行综述。     

含有补体控制蛋白结构域的蛋白质的结构和功能

补体控制蛋白(CCP)结构域分布广泛,含有CCP结构域的蛋白质在补体调节、机体排异和抵御微生物侵袭,甚至肿瘤发生发展等方面具有重要的功能。现在发现的含CCP结构域的蛋白质大约有100多种。我们综述了CCP结构域的基本特征,简要介绍了有代表性的含CCP结构域的蛋白质的功能。     

Toll样受体与核苷酸结合寡聚化结构域蛋白在防御反应中的相互作用

哺乳动物具有两个微生物识别系统,一个系统是由Toll样受体（TLRs）的膜结合受体家族组成;另一个系统是由位于胞浆的核苷酸结合寡聚化结构域（NOD）蛋白家族组成。入侵机体的微生物可能通过不同抗原激活多个模式识别受体,导致免疫反应的产生。本文将对TLRs及NODs信号通路在防御反应中的相互作用进行综述。     

人死亡结构域相关蛋白干扰载体的构建与鉴定

[目的]构建人死亡结构域相关蛋白(hDaxx)的干扰载体,为研究hDaxx在HPV致宫颈癌发生与发展过程中的作用提供实验基础。[方法]以hDaxx全基因序列为模板,设计hDaxx RNA干扰引物并扩增干扰片段,将其连接到pGPU6/GFP/Neo真核表达载体,构建pGPU6/GFP/Neo-SiDaxx干扰载体,转染至HeLa细胞,利用荧光显微镜观察转染效率以及通过RT-PCR、Western Blot检测siRNA对HeLa细胞中hDaxx表达的影响。[结果]在转染了pGPU6/GFP/Neo-Si Daxx载体的HeLa细胞中,其hDaxx mRNA和蛋白的表达水平与空载体对照组比较明显降低。[结论]成功构建了hDaxx的干扰载体pGPU6/GFP/Neo-Si Daxx,该干扰载体能抑制HeLa细胞中hDaxx mRNA基因和蛋白的表达。     

果蝇钙调蛋白和肌球蛋白NINAC相互作用分析

果蝇的视觉信号转导途径是已知的最快的G 蛋白偶联信号通路。这其中涉及到TRP/TRPL通道的开放以及钙离子的内流等一系列反应的形成。NINAC（neither inactivation nor afterpotential C）是一种特异性存在于果蝇感光细胞中的第3类肌球蛋白（Myosin III）,其在终止果蝇的视觉信号转导通路中起着非常重要的作用。NINAC蛋白具有两种亚型：一种是132 kD的蛋白亚型 (p132),另一种则是174 kD的蛋白亚型(p174)。这两种不同的蛋白亚型都具有相同的激酶催化结构域(kinase domain),以及与肌球蛋白相似的马达结构域(motor domain)。但是,它们在C末端却存在着非常大的差异,这其中包括了钙调蛋白结合基序(IQ motif)。NINAC的这两种蛋白亚型在果蝇的感光细胞中的定位以及作用有很大不同,尤其是在与钙调蛋白的相互作用方面。钙调蛋白结合基序与钙调蛋白（CaM）之间的相互作用对于果蝇的视觉信号通路具有重要的意义：NINAC结合钙调蛋白能力的缺失将导致果蝇的视觉传导缺陷。本文通过蛋白共表达的方法,成功表达并纯化得到了不同版本的NINAC与钙调蛋白的蛋白复合物。静态光散射的结果表明,在Ca2+存在情况下,p174蛋白可以结合2个Ca2+-CaM,而p132只结合1个Ca2+-CaM。通过分析型凝胶过滤以及等温量热滴定技术,进一步鉴定了p174及p132的IQ2（第2个钙调蛋白结合基序）序列与Ca2+ CaM的相互作用。通过序列分析及进一步的突变实验发现,p174 IQ2中的3个疏水氨基酸（F1083,F1086 和 L1092）对于钙调蛋白的结合非常重要,并导致了p174与p132蛋白和Ca2+ CaM结合能力的差异。本文的研究提供了NINAC与Ca2+-CaM相互作用的生化机制,将为进一步在果蝇视觉信号通路中深入研究CaM是如何调节NINAC的体内功能实验打下基础。     

G蛋白信号调节因子的结构分类和功能

G蛋白信号调节因子是能够直接与激活的Gα亚基结合,显著刺激Gα亚基上的GTP酶活性,加速GTP水解,从而灭活或终止G蛋白信号的一组分子大小各异的多功能蛋白质家族。它们都共同拥有一个130个氨基酸的保守的RGS结构域,其功能是结合激活的Gα亚基,负调节G蛋白信号。许多RGS蛋白还拥有非RGS结构域,能够结合其它信号蛋白,从而整合和调节G蛋白信号之间以及G蛋白和其它信号系统之间的关系。     

Deafl的功能结构域分析和预测

目的分析转录因子Deafl的功能结构域并预测其功能。方法利用现有的数据库和软件对Deafl的转录因子结构域,核定位信号及和输出信号进行分析和预测。结果Deafl含有一个保守的SAND结构域及一个能介导蛋白质一蛋白质相互作用的MYND结构域;有核定位信号和核输出信号;在其N端还有一个富含丙氨酸结构域。结论Deafl除有典型转录因子必需的功能结构域之外,可能还有不止一个结构域能介导与其它蛋白质因子的相互作用,这对Deafl调控外周组织抗原表达至关重要。     

The Drosophila Toll signaling pathway

The identification of the Drosophila melanogaster Toll pathway cascade and the subsequent characterization of TLRs have reshaped our understanding of the immune system. Ever since, Drosophila NF-κB signaling has been actively studied. In flies, the Toll receptors are essential for embryonic development and immunity. In total, nine Toll receptors are encoded in the Drosophila genome, including the Toll pathway receptor Toll. The induction of the Toll pathway by gram-positive bacteria or fungi leads to the activation of cellular immunity as well as the systemic production of certain antimicrobial peptides. The Toll receptor is activated when the proteolytically cleaved ligand Spatzle binds to the receptor, eventually leading to the activation of the NF-κB factors Dorsal-related immunity factor or Dorsal. In this study, we review the current literature on the Toll pathway and compare the Drosophila and mammalian NF-κB pathways.     

Pelle kinase is activated by autophosphorylation during Toll signaling in Drosophila

The Drosophila Pelle kinase plays a key role in the evolutionarily conserved Toll signaling pathway, but the mechanism responsible for its activation has been unknown. We present in vivo and in vitro evidence establishing an important role for concentration-dependent autophosphorylation in the signaling process. We first show that Pelle phosphorylation can be detected transiently in early embryos, concomitant with activation of signaling. Importantly, Pelle phosphorylation is enhanced in a gain-of-function Toll mutant (Toll(10b)), but decreased by loss-of-function Toll alleles. Next we found that Pelle is phosphorylated in transfected Schneider L2 cells in a concentration-dependent manner such that significant modification is observed only at high Pelle concentrations, which coincide with levels required for phosphorylation and activation of the downstream target, Dorsal. Pelle phosphorylation is also enhanced in L2 cells co-expressing Toll(10b), and is dependent on Pelle kinase activity. In vitro kinase assays revealed that recombinant, autophosphorylated Pelle is far more active than unphosphorylated Pelle. Importantly, unphosphorylated Pelle becomes autophosphorylated, and activated, by incubation at high concentrations. We discuss these results in the context of Toll-like receptor mediated signaling in both flies and mammals.     

Toll/IMD signal pathways mediate cellular immune responses via induction of intracellular PLA 2 expression

Phospholipase A₂ (PLA₂) hydrolyzes fatty acids from phospholipids at the sn‐2 position. Two intracellular PLA₂s, iPLA₂A and iPLA₂B, have been found in Spodoptera exigua. Both are calcium‐independent cellular PLA₂. Their orthologs have been found in other insects. These two iPLA₂s are different in ankyrin motif of N terminal region. The objective of this study was to determine whether Toll/immune deficiency (IMD) signal pathways could mediate cellular immune responses via induction of iPLA₂ expression. Both iPLA ₂s were expressed in all developmental stages of S. exigua, showing the highest expression in the adult stage. During larval stage, hemocyte is the main tissue showing expression of these iPLA₂s. Both iPLA₂s exhibited similar expression patterns after immune challenge with different microbial pathogens such as virus, bacteria, and fungi. Promoter component analysis of orthologs encoded in S. frugiperda indicated nuclear factor‐κB‐ and Relish‐responsible elements on their promoters, suggesting their expression in S. exigua under Toll/IMD immune signaling pathways. RNA interference (RNAi) of MyD88 or Pelle under Toll pathway suppressed inducible expression levels of both iPLA₂s in response to Gram‐positive bacteria containing Lys‐type peptidoglycan or fungal infection. In contrast, RNAi against Relish under IMD pathway suppressed both iPLA₂s in response to infection with Gram‐negative bacteria. Under RNAi conditions, hemocytes significantly lost cellular immune response measured by nodule formation. However, addition of arachidonic acid (a catalytic product of PLA₂) rescued such immunosuppression. These results suggest that Toll/IMD signal pathways can mediate cellular immune responses via eicosanoid signaling by inducing iPLA₂ expression.     

Drosophila melanogaster myotropins have unique functions and signaling pathways

Drosophila melanogaster TDVDHVFLRFamide (DMS), SDNFMRFamide, and pEVRFRQCYFNPISCF (FLT) represent three structurally distinct peptide families. Each peptide decreases heart rate albeit with different magnitudes and time-dependent responses. DMS and FLT are expressed in the crop and decrease crop motility; however, SDNFMRFamide expression and effect on the crop has not been reported. These data suggest the peptides have different physiological roles. The peptides have non-overlapping expression patterns in neural tissue, which suggests different mechanisms regulate their synthesis and release. The structures, expression patterns, and activities of the myotropins suggest they have important but different roles in biology and different signaling pathways.