| Tethered Chromosome Conformation Capture Sequencing in Triticeae: A Valuable Tool for Genome Assembly
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Author:
Date:
2018-08-05
[Abstract] Chromosome conformation capture sequencing (Hi-C) is a powerful method to comprehensively interrogate the three-dimensional positioning of chromatin in the nucleus. The development of Hi-C can be traced back to successive increases in the resolution and throughput of chromosome conformation capture (3C) (Dekker et al., 2002). The basic workflow of 3C consists of (i) fixation of intact chromatin, usually by formaldehyde, (ii) cutting the fixed chromatin with a restriction enzyme, (iii) religation of sticky ends under diluted conditions to favor ligations between cross-linked fragments or those between random fragments and (iv) quantifying the number of ligations events between pairs of genomic loci (de Wit and de Laat, 2012). In the original 3C protocol, ligation frequency was ...
[摘要] 染色体构象捕获测序(Hi-C)是一种全面询问细胞核中染色质三维定位的有效方法。 Hi-C的发展可以追溯到染色体构象捕获的分辨率和通量的连续增加(3C)(Dekker et al。,2002)。 3C的基本工作流程包括(i)通常用甲醛固定完整的染色质,(ii)用限制酶切割固定的染色质,(iii)在稀释条件下重新连接粘性末端,以促进交联片段之间的连接或随机片段之间的那些和(iv)量化基因组基因座对之间的连接事件的数量(de Wit和de Laat,2012)。在最初的3C方案中,通过半定量PCR扩增对应于少量基因组位点(“一对一”)的选定连接接头来测量连接频率(Dekker et al。,2002 )。然后,染色体构象捕获芯片(4C)和染色体构象捕获碳复制(5C)技术扩展3C以分别以“一对多”或“多对多”方式计算结扎事件。 Hi-C(Lieberman-Aiden et al。,2009)最终将3C与下一代测序相结合(Metzker,2010)。此处,在再连接之前,用生物素标记的核苷酸类似物填充粘性末端以在后续步骤中富集具有连接连接的片段。然后对Hi-C文库进行高通量测序,并将得到的读数映射到参考基因组,允许以“多对多”方式确定接触概率,其分辨率仅受限制性位点的分布限制和阅读深度。 Hi-C的首次应用是阐明人类基因组中的全球染色质折叠原理(Lieberman-Aiden et ...
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| Targeted Genome Editing of Virulent Phages Using CRISPR-Cas9
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Author:
Date:
2018-01-05
[Abstract] This protocol describes a straightforward method to generate specific mutations in the genome of strictly lytic phages. Briefly, a targeting CRISPR-Cas9 system and a repair template suited for homologous recombination are provided inside a bacterial host, here the Gram-positive model Lactococcus lactis MG1363. The CRISPR-Cas9 system is programmed to cleave a specific region present on the genome of the invading phage, but absent from the recombination template. The system either triggers the recombination event or exerts the selective pressure required to isolate recombinant phages. With this methodology, we generated multiple gene knockouts, a point mutation and an insertion in the genome of the virulent lactococcal phage p2. Considering the broad host range of the plasmids used ...
[摘要] 该协议描述了一个直接的方法来产生严格裂解噬菌体的基因组中的特定突变。 简而言之,在细菌宿主(此处为革兰氏阳性模型乳酸乳球菌MG1363)内提供靶向CRISPR-Cas9系统和适合于同源重组的修复模板。 CRISPR-Cas9系统被编程为切割入侵噬菌体的基因组上存在的特定区域,但是缺少重组模板。 该系统触发重组事件或施加分离重组噬菌体所需的选择性压力。 利用这种方法,我们在毒性乳酸球菌噬菌体p2的基因组中产生了多个基因敲除,点突变和插入。 考虑到本协议中使用的质粒的广泛宿主范围,后者可以外推到其他噬菌体 - 宿主对。
【背景】噬菌体是在每个生态系统中发现丰富的细菌病毒(Suttle,2005; Breitbart and Rohwer,2005),毫不奇怪,它们是牛奶的天然居民。噬菌体p2是乳品工业中发现的强毒乳球菌噬菌体的最普遍组( Sk1virus )的模型(Deveau等人,2006; Mahony等人。,2012),它感染革兰氏阳性细菌乳酸乳球菌MG1363,也是基础研究的模式菌株。尽管p2作为参照噬菌体的地位,但几乎一半的基因编码未表征的蛋白质。同样,由宏基因组学确定的绝大多数噬菌体基因在公共数据库中没有功能分配和同系物(Hurwitz等人,2016; Paez-Espino等人, 2016)。
研究基因的方法之一是通过修饰和随后观察所得到的表型。噬菌体基因组只能在宿主内以其生物活性形式进行修饰。强毒噬菌体严格裂解;因此,它们的基因组从未整合到细菌染色体中。这为DNA的体内修饰增加了一个时间限制,只能在短的感染周期内对其进行操作。 ...
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| Detection of Pathogens and Ampicillin-resistance Genes Using Multiplex Padlock Probes
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Author:
Date:
2017-08-20
[Abstract] Diagnostic assays for pathogen identification and characterization are limited either by the number of simultaneously detectable targets, which rely on multiplexing methods, or by time constraints due to cultivation-based techniques. We recently presented a 100-plex method for human pathogen characterization to identify 75 bacterial and fungal species as well as 33 clinically relevant β-lactamases (Barišić et al., 2016). By using 16S rRNA gene sequences as barcode elements in the padlock probes, and two different fluorescence channels for species and antibiotic resistance identification, we managed to cut the number of microarray probes needed by half. Consequently, we present here the protocol of an assay with a runtime of approx. 8 h and a detection limit of 105 cfu ...
[摘要] 用于病原体鉴定和表征的诊断测定法由依赖于多重方法的同时可检测目标的数量或由于基于培养的技术的时间限制来限制。 我们最近提出了一种用于人类病原体鉴定的100plex方法,以鉴定75种细菌和真菌物种以及33种临床相关β-内酰胺酶(Barišić等,2016)。 通过使用16S rRNA基因序列作为挂锁探针中的条形码元件,以及用于物种和抗生素抗性鉴定的两种不同的荧光通道,我们设法将需要的微阵列探针的数量减少一半。 因此,我们在这里介绍一个运行时间约为的测定方案。 8 h,检测限为105 cfu ml-1。 正确鉴定了89%的β-内酰胺酶和93.7%的物种。
【背景】β-内酰胺酶是一类提供抗β-内酰胺抗生素的抗生素抗性基因,其结构模拟D-丙氨酰-D-丙氨酸,细菌细胞壁的一个组分,从而抑制细菌细胞壁合成。 β-内酰胺酶能够水解β内酰胺抗生素β-内酰胺环的中心成分,并使其无效(Kong et al。,2010)。今天,描述了超过1000种β-内酰胺酶,并且存在巨大的潜在环境储层(Bush,2010; Brandt等,2017)。 ...
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