| Visualization of RNA 3’ ends in Escherichia coli Using 3’ RACE Combined with Primer Extension
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Author:
Date:
2018-03-05
[Abstract] In this assay, 3’ RACE (Rapid Amplification of cDNA 3’ Ends) followed by PE (primer extension), abbreviated as 3’ RACE-PE is used to identify the mRNA 3’ ends. The following protocol describes the amplification of the mRNA 3’ ends at the galactose operon in E. coli and the corresponding visualization of the PCR products through PE. In PE, the definite primer is 5’ end-labeled using [γ-(32) P] ATP and T4 polynucleotide kinase, which anneals to the specific DNA molecules within the PCR product of the 3’ RACE. The conventional PE can only be used to locate the 5’ end of an mRNA transcript since reverse transcriptase (RTase) polymerizes only in the 5’ → 3’ direction. Thus, Taq polymerase is used instead of RTase, PCR is performed. Therefore, we are able to locate the 3’ end of the ...
[摘要] 在该测定中,使用缩写为3'RACE-PE的3'RACE(cDNA3'末端快速扩增),随后是PE(引物延伸),以鉴定mRNA3'末端。以下方案描述E中半乳糖操纵子的mRNA 3'末端的扩增。并通过PE对相应的PCR产物进行可视化。在PE中,使用[γ-(32)P] ATP和T4多核苷酸激酶对确定的引物进行5'末端标记,其退火至3'RACE的PCR产物内的特定DNA分子。由于逆转录酶(RTase)仅在5'→3'方向聚合,常规PE只能用于定位mRNA转录物的5'末端。因此,使用Taq聚合酶代替RTase,进行PCR。因此,我们能够使用此测定法定位mRNA的3'末端。通过在变性8%尿素-PAGE(聚丙烯酰胺凝胶电泳)凝胶中分离DNA产物,可以直接显示和定量3'末端的相对量。 3'末端的确切位置可以通过比较这些最终的DNA产物与相应的DNA测序阶梯进行测序。
【背景】mRNA 3'末端的合成是E中的重要步骤。产生稳定的信使RNA(mRNA)的大肠杆菌。在真核细胞中,mRNA 3'末端形成是通过从内部磷酸二酯键切割,然后加入聚(A)尾;而在原核细胞中,通过终止转录或通过加工初级转录产生mRNA的3'末端(Altman和Robertson,1973; Nudler和Gottesman,2002; Zhao等人,1999年)。因此,分析mRNA ...
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| A Small RNA Isolation and Sequencing Protocol and Its Application to Assay CRISPR RNA Biogenesis in Bacteria
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Author:
Date:
2018-02-20
[Abstract] Next generation high-throughput sequencing has enabled sensitive and unambiguous analysis of RNA populations in cells. Here, we describe a method for isolation and strand-specific sequencing of small RNA pools from bacteria that can be multiplexed to accommodate multiple biological samples in a single experiment. Small RNAs are isolated by polyacrylamide gel electrophoresis and treated with T4 polynucleotide kinase. This allows for 3’ adapter ligation to CRISPR RNAs, which don’t have pre-existing 3’-OH ends. Pre-adenylated adapters are then ligated using T4 RNA ligase 1 in the absence of ATP and with a high concentration of polyethylene glycol (PEG). The 3’ capture step enables precise determination of the 3’ ends of diverse RNA molecules. Additionally, a random hexamer in the ligated ...
[摘要] 新一代高通量测序技术能够对细胞中的RNA群体进行敏感和明确的分析。在这里,我们描述了一种从细菌中分离和链特异性测序小RNA池的方法,所述细菌可以在单个实验中多路复用以容纳多个生物样品。小RNA通过聚丙烯酰胺凝胶电泳分离并用T4多核苷酸激酶处理。这允许3'衔接头连接至CRISPR RNA,其不具有预先存在的3'-OH末端。然后使用T4 RNA连接酶1在不存在ATP和高浓度聚乙二醇(PEG)的情况下将前腺苷酸化的衔接子连接。 3'捕获步骤能够精确测定不同RNA分子的3'末端。此外,连接适配器中的随机六聚体有助于控制潜在的下游扩增偏差。逆转录后,将cDNA产物环化并通过PCR制备文库。我们显示扩增的文库不需要通过凝胶电泳可见,以期望产物的有效测序。使用这种方法,我们通常从少量纯化的小RNA制备RNA测序文库。该协议适合于通过对成熟的CRISPR RNA进行测序来测定细菌中的CRISPR RNA生物合成,但可以用于测序不同类型的小RNA。我们还提供了一个完整的数据处理管道示例,并提供了运行所提供脚本的说明。
【背景】与聚集的经常散布的短回文重复序列(CRISPR)相关的遗传模块赋予不同的原核宿主适应性免疫(Barrangou et ...
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| Oral Microbiome Characterization in Murine Models
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Author:
Date:
2017-12-20
[Abstract] The oral microbiome has been implicated as a trigger for immune responsiveness in the oral cavity, particularly in the setting of the inflammatory disease periodontitis. The protocol presented here is aimed at characterizing the oral microbiome in murine models at steady state and during perturbations of immunity or physiology. Herein, we describe murine oral microbiome sampling procedures, processing of low biomass samples and subsequent microbiome characterization based on 16S rRNA gene sequencing.
[摘要] 口腔微生物组被认为是口腔免疫应答的触发因素,特别是在炎性疾病牙周炎的形成中。 这里提出的协议旨在描述在稳定状态和扰动免疫或生理学的小鼠模型中的口腔微生物群。 在此,我们描述了鼠类口腔微生物群落取样程序,低生物量样品的处理和随后的基于16S rRNA基因测序的微生物群鉴定。
【背景】微生物组在调节组织特异性免疫应答(特别是在屏障部位)中起关键作用(Belkaid和Harrison,2017)。在这些屏障环境中,例如胃肠道和皮肤,选择的共生物显示能够驱动特定免疫细胞群体的发育(Ivanov等人,2009; Naik等人。,2012)。我们的工作最近开始探索口腔微生物组在剪裁组织免疫力方面的影响,尤其是在牙龈处,一个脆弱的口腔屏障部位(Abusleme和Moutsopoulos,2016; Dutzan等人,2017)。
在人类中,众所周知口腔中含有丰富多样的微生物(Human Microbiome Project,2012)。口腔微生物群落的改变与常见的口腔疾病,牙周炎(一种影响牙龈组织并导致组织损伤的炎症)有关(Griffen等人,2012; Abusleme等人。,2013; Moutsopoulos et al 。,2015)。迄今为止,动物模型已经有助于解决微生物组在各种生理和病理条件中的作用(Turnbaugh等人,2006; ...
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