| Biochemical Analysis of Dimethyl Suberimidate-crosslinked Yeast Nucleosomes
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Author:
Date:
2018-03-20
[Abstract] Nucleosomes are the fundamental unit of eukaryotic chromosome packaging, comprised of 147 bp of DNA wrapped around two molecules of each of the core histone proteins H2A, H2B, H3, and H4. Nucleosomes are symmetrical, with one axis of symmetry centered on the homodimeric interaction between the C-termini of the H3 molecules. To explore the functional consequences of nucleosome symmetry, we designed an obligate pair of H3 heterodimers, termed H3X and H3Y, allowing us to compare cells with single or double H3 alterations. Our biochemical validation of the heterodimeric X-Y interaction included intra-nucleosomal H3 crosslinking using dimethyl suberimidate (DMS). Here, we provide a detailed protocol for the use of DMS to analyze yeast nucleosomes.
[摘要] 核小体是真核染色体包装的基本单元,由围绕核心组蛋白H2A,H2B,H3和H4中的每一个的两个分子包裹的147bp DNA组成。 核小体是对称的,一个对称轴以H3分子的C-末端之间的同源二聚体相互作用为中心。 为了探索核小体对称性的功能性后果,我们设计了一对特异性H3异二聚体,称为H3X和H3Y,使我们能够比较具有单一或双重H3改变的细胞。 我们对异二聚体X-Y相互作用的生物化学验证包括使用二甲基琥珀三酸酯(DMS)进行的核内H3交联。 在这里,我们提供了使用DMS来分析酵母核小体的详细方案。
【背景】组蛋白的翻译后修饰影响染色体生物学的各个方面,包括转录,复制,修复和重组。因为核小体包含每个核心组蛋白的两个拷贝,所以修饰可以是对称的(在两个H3尾部上的相同修饰,例如,在核小体内的两个H3尾部上的K27me(Voigt等人
对于单个核小体内H3X-H3Y相互作用的生化验证,我们生成了表达细菌生物素连接酶BirA,N-末端V5-标记的H3X和N-末端生物素接受表位标记的H3Y的酵母菌株(Beckett等人, 1999)。 ...
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| Method for Multiplexing CRISPR/Cas9 in Saccharomyces cerevisiae Using Artificial Target DNA Sequences
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Author:
Date:
2017-09-20
[Abstract] Genome manipulation has become more accessible given the advent of the CRISPR (Clustered Regularly Interspaced Short Palindromic Repeats) editing technology. The Cas9 endonuclease binds a single stranded (single guide) RNA (sgRNA) fragment that recruits the complex to a corresponding genomic target sequence where it induces a double stranded break. Eukaryotic repair systems allow for the introduction of exogenous DNA, repair of existing mutations, or deletion of endogenous gene products. Targeting of Cas9 to multiple genomic positions (termed ‘multiplexing’) is achieved by the expression of multiple sgRNAs within the same nucleus. However, an ongoing concern of the CRISPR field has been the accidental targeting of Cas9 to alternative (‘off-target’) DNA locations within a genome. We ...
[摘要] 鉴于CRISPR(集群定期间隔短回归重复)编辑技术的出现,基因组操纵变得更加易于使用。 Cas9核酸内切酶将募集复合物的单链(单向导)RNA(sgRNA)片段结合到相应的基因组靶序列,引发双链断裂。真核修复系统允许引入外源DNA,修复现有突变或内源基因产物的缺失。通过在同一核内表达多个sgRNA来实现Cas9对多个基因组位置的定位(称为“多重”)。然而,CRISPR领域的持续关注是将Cas9意外地定位到基因组内的替代(“脱靶”)DNA位置。我们将安装的人造Cas9靶序列的使用(称为人造基因座上的Cas9复制)描述为允许(i)与单个sgRNA复用的酵母基因组中的用途; (ii)减少/消除可能的脱靶效应,以及(iii)精确控制预定目标序列的放置。
【背景】CRISPR(集群定期间隔回归重复)机制已经在原核生物中演变为具有很高精度编辑任何基因组的能力的原始适应性免疫系统(Jinek等,2012; Sorek等,2013)。这种生物技术需要使用来自化脓性链球菌(或othologous物种)的内切核酸酶(Cas9),单个RNA'引导'序列和外源供体DNA(如果需要)。仅在短短几年内,CRISPR / ...
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| Separation of Free and Bound cAMP in Mycobacteria
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Author:
Date:
2016-07-20
[Abstract] Mycobacterial genomes encode a plethora of genes that are involved in the synthesis, utilization and degradation of cAMP. The genome of M. tuberculosis H37Rv, for example, encodes 16 adenylyl cyclases and 10 genes harbouring the cyclic nucleotide-binding (CNB) domain (Shenoy and Visweswariah, 2006). Cyclic AMP is efficiently secreted by mycobacteria, and cytosolic as well as extracellular levels of cAMP can reach hundreds of micromolar. We have recently reported that an abundantly expressed universal stress protein (USP; Rv1636 in M. tuberculosis H37Rv and MSMEG_3811 in M. smegmatis, respectively) binds cAMP (Banerjee et al., 2015). Given the number of cAMP-binding proteins present in mycobacteria, it is expected that a significant fraction of ...
[摘要] 分枝杆菌基因组编码涉及cAMP的合成,利用和降解的大量基因。例如,结核分枝杆菌H37Rv的基因组编码16个腺苷酸环化酶和10个携带环核苷酸结合(CNB)结构域的基因(Shenoy和Visweswariah,2006)。循环AMP由分枝杆菌有效分泌,细胞溶质以及细胞外cAMP水平可达数百微摩尔。我们最近报道,大量表达的普遍应激蛋白(USP; Rv1636在结核分枝杆菌H37Rv和MSMEG_3811分别在耻垢分枝杆菌中)分别结合cAMP(Banerjee等,2015)。鉴于存在于分枝杆菌中的cAMP结合蛋白的数量,预期细胞内cAMP的显着部分可能与蛋白质结合。通常用于测量cAMP的方法是放射免疫测定(RIA)和ELISA。然而,这些方法包括将cAMP“结合”解离成蛋白质的样品的预先酸化,因此代表样品中存在的“总”cAMP。在本协议中,我们描述了一种将cAMP'结合'蛋白质与蛋白质“自由”分离或与蛋白质不相关的方法。这通过使细胞溶质级分或培养物上清液通过具有3kDa截止值的膜过滤来进行。只有'自由'cAMP才能通过膜。因此,滤液中的cAMP浓度代表样品中的“游离”cAMP。原始细胞溶质级分或培养上清液中的环AMP水平代表“总”cAMP浓度。从“总”中减去“自由”提供了与蛋白质结合的cAMP量。
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