Suvra Das, JérÔme Delamare-Deboutteville, Andrew C. Barnes, Oleksandra Rudenko
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引用次数: 0
摘要
牛津纳米孔技术公司(Oxford Nanopore Technologies)开发的长线程测序平台 MinION 可在资源有限的环境中(如野外条件或中低收入国家)对细菌基因组进行测序。为此,需要使用无害、廉价的试剂和设备来提取高分子量 DNA,目前已经开发出了一些针对革兰氏阴性菌的方法。然而,我们发现,如果不进行修改,这些方法不适合革兰氏阳性链球菌属,而这种细菌是中低收入国家养鱼业和食品安全的主要威胁。我们对多种方法进行了评估,其中最有效的是使用溶菌酶、十二烷基硫酸钠和蛋白酶 K 来裂解细菌细胞,并使用磁珠来回收 DNA 的提取方法。我们对该方法进行了优化,使其能够以最少的试剂和时间获得足够纯度的高分子量 DNA。该方法的适用性已通过 MinION 测序和组装 12 个流行病学上不同的鱼类致病性链球菌和无乳链球菌分离物的基因组得到验证。通过有效的高分子量 DNA 提取和 MinION 测序,我们在伊氏链球菌中发现了一个天然存在的 15 kb 低拷贝数可移动质粒,我们将其命名为 pSI1。我们预计,在资源有限的情况下,我们的高分子量 DNA 提取方案可成功用于类似的难以溶解的革兰氏阳性菌,它是中低收入国家基于 MinION 的疾病诊断的首选方法。
Extraction of high-molecular-weight DNA from Streptococcus spp. for nanopore sequencing in resource-limited settings
The long-read sequencing platform MinION, developed by Oxford Nanopore Technologies, enables the sequencing of bacterial genomes in resource-limited settings, such as field conditions or low- and middle-income countries. For this purpose, protocols for extracting high-molecular-weight DNA using nonhazardous, inexpensive reagents and equipment are needed, and some methods have been developed for gram-negative bacteria. However, we found that without modification, these protocols are unsuitable for gram-positive Streptococcus spp., a major threat to fish farming and food security in low- and middle-income countries. Multiple approaches were evaluated, and the most effective was an extraction method using lysozyme, sodium dodecyl sulfate, and proteinase K for lysis of bacterial cells and magnetic beads for DNA recovery. We optimized the method to consistently achieve sufficient yields of pure high-molecular-weight DNA with minimal reagents and time and developed a version of the protocol which can be performed without a centrifuge or electrical power. The suitability of the method was verified by MinION sequencing and assembly of 12 genomes of epidemiologically diverse fish-pathogenic Streptococcus iniae and Streptococcus agalactiae isolates. The combination of effective high-molecular-weight DNA extraction and MinION sequencing enabled the discovery of a naturally occurring 15 kb low-copy number mobilizable plasmid in S. iniae, which we name pSI1. We expect that our resource-limited settings-adapted protocol for high-molecular-weight DNA extraction could be implemented successfully for similarly recalcitrant-to-lysis gram-positive bacteria, and it represents a method of choice for MinION-based disease diagnostics in low- and middle-income countries.
期刊介绍:
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