| In vitro Reconstitution Assays of Arabidopsis 20S Proteasome
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Author:
Date:
2021-04-05
[Abstract] The majority of cellular proteins are degraded by the 26S proteasome in eukaryotes. However, intrinsically disordered proteins (IDPs), which contain large portions of unstructured regions and are inherently unstable, are degraded via the ubiquitin-independent 20S proteasome. Emerging evidence indicates that plant IDP homeostasis may also be controlled by the 20S proteasome. Relatively little is known about the specific functions of the 20S proteasome and the regulatory mechanisms of IDP degradation in plants compared to other species because there is a lack of systematic protocols for in vitro assembly of this complex to perform in vitro degradation assays. Here, we present a detailed protocol of in vitro reconstitution assay of the 20S proteasome in Arabidopsis by modifying previously ...
[摘要] [摘要]大多数细胞蛋白的s的降解通过26S在真核生物蛋白酶。但是,内在无序的蛋白质(IDPs)包含大量的非结构化区域,并且内在地不稳定,因此很容易通过不依赖泛素的20S蛋白酶体降解。越来越多的证据最近显示ň植物境内流离失所者的平衡也可以通过20S蛋白酶控制。但是,由于缺乏用于体外分离20S蛋白酶体和降解测定的系统协议,因此我们对植物中IDP和20S蛋白酶体降解的功能和调控机制的研究和理解一直处于婴儿期与其他生物。在这里,我们通过采用和修改先前公开的方法,对拟南芥中20S蛋白酶体进行体外重组测定的详细方案。在此获得20S核心蛋白酶体的主要策略是从26S蛋白酶体中去除19S调节亚基。该协议包括两个主要部分:1)的来自表达表位标记的PAG1稳定的转基因品系20S蛋白酶体亲和纯化,的20S蛋白酶(程序AD)的基本组成部分; 2 )体外20S蛋白酶体降解测定法(方法E)。我们预计该协议将提供一种简单有效的方法来研究体外20S蛋白酶体降解,并促进植物中蛋白质代谢的研究。
[背景]蛋白质的降解通常是通过真核生物中的蛋白酶体来实现的。整合的26S蛋白酶体由两个亚颗粒组成:一个或两个末端的19S调节颗粒(RP),用作蛋白酶体激活剂;和20S核心蛋白酶体(CP),执行降解过程。大多数真核蛋白被多聚泛素化并导入26S蛋白酶体进行降解。然而,含有固有蛋白质无序已发现的区域直接通过破坏一个由20S蛋白酶的泛素依赖性降解(本日产等人,2014) ...
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| Modifying Styrene-maleic Acid Co-polymer for Studying Lipid Nanodiscs by Direct Fluorescent Labeling
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Author:
Date:
2018-08-20
[Abstract] This protocol was developed to functionalize styrene maleic acid (SMA) by direct fluorescent labeling in an easy way, accessible to biochemistry laboratories. This novel method is based on the coupling of carboxylic acids to primary amines using a carbodiimide, a reaction commonly used for protein chemistry. The procedure uses the hydrolyzed styrene-maleic acid copolymer and occurs entirely in aqueous solution with mild conditions compatible with many biomolecules.
[摘要] 该协议旨在通过直接荧光标记以简单的方式使苯乙烯马来酸(SMA)功能化,生物化学实验室可以使用。 该新方法基于使用碳二亚胺(一种常用于蛋白质化学的反应)将羧酸偶联到伯胺上。 该方法使用水解的苯乙烯 - 马来酸共聚物并且完全在水溶液中发生,具有与许多生物分子相容的温和条件。
【背景】膜蛋白体外的表征可能非常具有挑战性(Grisshammer和Tate,1995)。除了过度表达和膜分离的困难之外,还需要从其天然环境中提取膜蛋白。必需的溶解步骤通常需要使用去污剂来代替天然脂质环境,这通常会导致膜蛋白的结构和/或活性的丧失(Duquesne 等人,2016)。出于这个原因,已经开发了几种替代选择,例如amphipols(Popot,2010),以避免与洗涤剂相关的一些困难并保持膜蛋白的溶解度。几年前,苯乙烯马来酸(SMA)共聚物更常用作低分子量洗涤剂策略的替代品(Dorr et al。,2014; Jamshad et al。 ,2015; Prabudiansyah et al。,2015)。已经证明SMA能够自发地溶解生物膜并产生平均尺寸为10nm的圆盘形颗粒。这些纳米圆盘(称为SMALP)含有嵌入来自膜和SMA共聚物的脂质中的蛋白质混合物,将颗粒保持在溶液中(Knowles 等人,,2009)。 ...
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| Detecting the Interaction of Double-stranded RNA Binding Protein, Viral Protein and Primary miRNA Transcript by Co-immunoprecipitation in planta
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Author:
Date:
2018-05-05
[Abstract] MicroRNAs (miRNAs) play important roles in plant growth, development, and response to infection by microbes. Double-stranded RNA binding protein 1 (DRB1) facilitates the processing of primary miRNA transcripts into mature miRNAs. Recently, we found that NS3 protein encoded by rice stripe virus (RSV) associates with DRB1 and promotes miRNA biogenesis during RSV infection (Zheng et al., 2017). RNA co-immunoprecipitation (RIP) method was applied to identity association patterns among DRB1, NS3, and miRNA transcript.
[摘要] 微小RNA(miRNA)在植物生长,发育和微生物感染反应中发挥重要作用。 双链RNA结合蛋白1(DRB1)有助于将初级miRNA转录物加工成成熟的miRNA。 最近,我们发现水稻条纹病毒(RSV)编码的NS3蛋白与DRB1相关并促进RSV感染期间的miRNA生物合成(Zheng等人,2017)。 RNA共免疫沉淀(RIP)方法被用于鉴定DRB1,NS3和miRNA转录物之间的关联模式。
【背景】在双链RNA(dsRNA)结合蛋白HYPONASTIC LEAVES1(DRB1 / HYL1)的帮助下,通过RNA酶III酶DICER-LIKE1(DCL1)从其初级转录物(pri-miRNA) 锌指蛋白SERRATE(SE)。 水稻条纹病毒(RSV)感染广泛地干扰miRNA积累。 我们发现RSV编码的非结构蛋白3(NS3)通过与水稻中的DRB1相互作用下调pri-miRNAs来促进miRNA积累(Zheng等人,2017)。 为了揭示NS3如何增强pri-miRNA的加工,我们使用免疫共沉淀(Co-IP)来说明NS3,DRB1和pri-miRNA体内的关系。 该协议有助于了解两种蛋白质和一种RNA转录本之间的关联模式。
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