| Bimolecular Fluorescence Complementation (BiFC) for Studying Sarcomeric Protein Interactions in Drosophila
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Author:
Date:
2020-04-05
[Abstract] Protein-protein interactions in Drosophila myofibrils are essential for their function and formation. Bimolecular Fluorescence Complementation (BiFC) is an effective method for studying protein interactions and localization. BiFC relies on the reconstitution of a monomeric fluorescent protein from two half-fragments when in proximity. Two proteins tagged with the different half-fragments emit a fluorescent signal when they are in physical contact, thus revealing a protein interaction and its spatial distribution. Because myofibrils are large networks of interconnected proteins, BIFC is an ideal method to study protein-protein interactions in myofibrils. Here we present a protocol for generating transgenic flies compatible with BiFC and a method for analyzing protein-protein ...
[摘要] [摘要] 果蝇肌原纤维中的蛋白质-蛋白质相互作用对其功能和形成至关重要。双分子荧光互补(BiFC )是研究蛋白质相互作用和定位的一种有效方法。BiFC 依赖于邻近时从两个半片段重构单体荧光蛋白。标记有不同半片段的两种蛋白质在物理接触时会发出荧光信号,从而揭示了蛋白质相互作用及其空间分布。因为肌原纤维相互连接的蛋白质的大型网络中,附设是一种理想的方法来 研究肌原纤维中蛋白质之间的相互作用。在这里,我们提出了一种生成与BiFC 兼容的转基因果蝇的协议,以及一种基于肌原纤维中荧光BiFC 信号的蛋白质-蛋白质相互作用分析方法。我们的方案适用于大多数果蝇蛋白,只需稍加修改即可用于研究任何组织。
[背景] 肉瘤是横纹肌中最小的收缩单位,并沿着肌原纤维的长度以重复的方式延伸(Reedy和Beall,1993)。肉瘤产生肌肉收缩的能力取决于两个肌原纤维成分:细丝和粗丝。肌球蛋白粗丝固定在肌节中心的M线,而肌动蛋白细丝固定在肌节两侧的Z盘上。因此,Z盘对于维持肌原纤维的结构和收缩至关重要,而Z盘无法形成可能导致各种人类肌病的严重缺陷性肌肉表型(Lemke和Schnorrer,2017年)。
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| Analysis of N-acetylmuramic acid-6-phosphate (MurNAc-6P) Accumulation by HPLC-MS
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Author:
Date:
2017-08-05
[Abstract] We describe here in detail a high-performance liquid chromatography-mass spectrometry (HPLC-MS)-based method to determine N-acetylmuramic acid-6-phosphate (MurNAc-6P) in bacterial cell extracts. The method can be applied to both Gram-negative and Gram-positive bacteria, and as an example we use Escherichia coli cells in this study. Wild type and mutant cells are grown for a defined time in a medium of choice and harvested by centrifugation. Then the cells are disintegrated and soluble cell extracts are generated. After removal of proteins by precipitation with acetone, the extracts are analyzed by HPLC-MS. Base peak chromatograms of wild type and mutant cell extracts are used to determine a differential ion spectrum that reveals differences in the MurNAc-6P content of ...
[摘要] 我们在这里详细描述了一种基于高效液相色谱 - 质谱(HPLC-MS)的方法,以确定细菌细胞提取物中的N-乙酰谷氨酸-6-磷酸(MurNAc-6P)。该方法可以应用于革兰氏阴性菌和革兰氏阳性菌,作为一个例子,我们在本研究中使用大肠杆菌细胞。野生型和突变型细胞在选择的培养基中生长一定时间并通过离心收获。然后细胞分解并产生可溶性细胞提取物。通过用丙酮沉淀除去蛋白质后,通过HPLC-MS分析提取物。野生型和突变型细胞提取物的基本峰图谱用于测定显示两种样品中MurNAc-6P含量差异的差异离子谱。确定阴离子模式下MurNAc-6P((MH)= 372.070m/z的提取色谱图的峰面积允许定量使用的MurNAc-6P水平计算消泡聚糖的MurNAc含量的回收率。
【背景】在细菌生长期间,大部分细菌的肽聚糖细胞壁稳定地翻转并可能回收(再循环)。 肽聚糖回收代谢的关键化合物是积聚在大肠杆菌的MurNAc-6P醚酶(MurQ)突变体中的N-乙酰谷氨酸-6-磷酸(MurNAc-6P) (Jaeger等人,2005; Uehara等人,2006)。 MurQ直向同源物被发现在许多细菌中,包括革兰氏阳性菌(Litzinger等人,2010; Reith和Mayer,2011)。 ...
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| CRISPR/Cas9 Editing of the Bacillus subtilis Genome
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Author:
Date:
2017-04-20
[Abstract] A fundamental procedure for most modern biologists is the genetic manipulation of the organism under study. Although many different methods for editing bacterial genomes have been used in laboratories for decades, the adaptation of CRISPR/Cas9 technology to bacterial genetics has allowed researchers to manipulate bacterial genomes with unparalleled facility. CRISPR/Cas9 has allowed for genome edits to be more precise, while also increasing the efficiency of transferring mutations into a variety of genetic backgrounds. As a result, the advantages are realized in tractable organisms and organisms that have been refractory to genetic manipulation. Here, we describe our method for editing the genome of the bacterium Bacillus subtilis. Our method is highly efficient, resulting in ...
[摘要] 大多数现代生物学家的基本过程是研究生物体的遗传操作。尽管许多不同的方法用于编辑细菌基因组已经在实验室中使用了数十年,但CRISPR / Cas9技术对细菌遗传学的适应使得研究人员能够以无与伦比的设施来操纵细菌基因组。 CRISPR / Cas9允许基因组编辑更精确,同时也提高将突变转移到各种遗传背景的效率。因此,在遗传操作难以处理的易处理生物和生物体中实现了这些优点。在这里,我们描述了我们编辑枯草芽孢杆菌细菌基因组的方法。我们的方法是高效的,导致精确,无标记的突变。此外,在产生编辑质粒之后,可以将突变快速导入几个遗传背景,大大增加可进行遗传分析的速度。
枯草芽孢杆菌是高度易处理的革兰氏阳性菌。遗传研究适用于使用多种载体通过同源重组快速有效地引入突变。尽管有许多不同的方法来引入B突变。 subtilis,每种方法都有其局限性。一种简单而简单的方法,用于在B中进行突变。枯草芽孢杆菌是基因破坏,其中将质粒整合到感兴趣的基因内(Vagner等人,1998)。主要的局限性包括:1)扰乱操纵子的极地作用的潜力; 2)引进和保留外来DNA; 3)一旦使用抗生素耐药性盒,如果在其他突变的背景下研究给定的突变,则研究者必须使用不同的盒;和4)该方法限于靶向整个基因,并且不能产生更精确的点突变。 ...
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