Timmers Peer H A, Widjaja-Greefkes H C Aura, Plugge Caroline M, Stams Alfons J M
Laboratory of Microbiology, Wageningen University, Stippeneng 4, 6708 WE, Wageningen, the Netherlands.
Centre of Excellence for Sustainable Water Technology, Wetsus, Oostergoweg 9, 8911 MA, Leeuwarden, the Netherlands.
Appl Microbiol Biotechnol. 2017 Jul;101(14):5847-5859. doi: 10.1007/s00253-017-8338-x. Epub 2017 Jun 15.
Since the discovery that anaerobic methanotrophic archaea (ANME) are involved in the anaerobic oxidation of methane coupled to sulfate reduction in marine sediments, different primers and probes specifically targeting the 16S rRNA gene of these archaea have been developed. Microbial investigation of the different ANME subtypes (ANME-1; ANME-2a, b, and c; and ANME-3) was mainly done in sediments where specific subtypes of ANME were highly enriched and methanogenic cell numbers were low. In different sediments with higher archaeal diversity and abundance, it is important that primers and probes targeting different ANME subtypes are very specific and do not detect other ANME subtypes or methanogens that are also present. In this study, primers and probes that were regularly used in AOM studies were tested in silico on coverage and specificity. Most of the previously developed primers and probes were not specific for the ANME subtypes, thereby not reflecting the actual ANME population in complex samples. Selected primers that showed good coverage and high specificity for the subclades ANME-1, ANME-2a/b, and ANME-2c were thoroughly validated using quantitative polymerase chain reaction (qPCR). From these qPCR tests, only certain combinations seemed suitable for selective amplification. After optimization of these primer sets, we obtained valid primer combinations for the selective detection and quantification of ANME-1, ANME-2a/b, and ANME-2c in samples where different ANME subtypes and possibly methanogens could be present. As a result of this work, we propose a standard workflow to facilitate selection of suitable primers for qPCR experiments on novel environmental samples.
自从发现厌氧甲烷氧化古菌(ANME)参与海洋沉积物中与硫酸盐还原耦合的甲烷厌氧氧化过程以来,已经开发出了专门针对这些古菌16S rRNA基因的不同引物和探针。对不同ANME亚型(ANME-1;ANME-2a、b和c;以及ANME-3)的微生物研究主要是在特定ANME亚型高度富集且产甲烷细胞数量较低的沉积物中进行的。在古菌多样性和丰度较高的不同沉积物中,针对不同ANME亚型的引物和探针必须具有高度特异性,且不能检测到其他同时存在的ANME亚型或产甲烷菌,这一点很重要。在本研究中,对AOM研究中常用的引物和探针进行了计算机模拟测试,评估其覆盖范围和特异性。大多数先前开发的引物和探针并非ANME亚型特异性的,因此无法反映复杂样品中实际的ANME种群情况。对显示出对ANME-1、ANME-2a/b和ANME-2c亚分支具有良好覆盖范围和高特异性的选定引物,使用定量聚合酶链反应(qPCR)进行了全面验证。从这些qPCR测试中发现,只有某些组合似乎适合选择性扩增。对这些引物组进行优化后,我们获得了有效的引物组合,可用于在可能存在不同ANME亚型以及可能存在产甲烷菌的样品中选择性检测和定量ANME-1、ANME-2a/b和ANME-2c。这项工作的结果是,我们提出了一个标准工作流程,以方便为新环境样品的qPCR实验选择合适的引物。
