Institute of Medical Microbiology, German Centre for Infection Research, Justus-Liebig-University, D-35392, Giessen, Germany.
BMC Genomics. 2013 Jan 22;14:47. doi: 10.1186/1471-2164-14-47.
Listeria monocytogenes is an important food-borne pathogen and model organism for host-pathogen interaction, thus representing an invaluable target considering research on the forces governing the evolution of such microbes. The diversity of this species has not been exhaustively explored yet, as previous efforts have focused on analyses of serotypes primarily implicated in human listeriosis. We conducted complete genome sequencing of 11 strains employing 454 GS FLX technology, thereby achieving full coverage of all serotypes including the first complete strains of serotypes 1/2b, 3c, 3b, 4c, 4d, and 4e. These were comparatively analyzed in conjunction with publicly available data and assessed for pathogenicity in the Galleria mellonella insect model.
The species pan-genome of L. monocytogenes is highly stable but open, suggesting an ability to adapt to new niches by generating or including new genetic information. The majority of gene-scale differences represented by the accessory genome resulted from nine hyper variable hotspots, a similar number of different prophages, three transposons (Tn916, Tn554, IS3-like), and two mobilizable islands. Only a subset of strains showed CRISPR/Cas bacteriophage resistance systems of different subtypes, suggesting a supplementary function in maintenance of chromosomal stability. Multiple phylogenetic branches of the genus Listeria imply long common histories of strains of each lineage as revealed by a SNP-based core genome tree highlighting the impact of small mutations for the evolution of species L. monocytogenes. Frequent loss or truncation of genes described to be vital for virulence or pathogenicity was confirmed as a recurring pattern, especially for strains belonging to lineages III and II. New candidate genes implicated in virulence function were predicted based on functional domains and phylogenetic distribution. A comparative analysis of small regulatory RNA candidates supports observations of a differential distribution of trans-encoded RNA, hinting at a diverse range of adaptations and regulatory impact.
This study determined commonly occurring hyper variable hotspots and mobile elements as primary effectors of quantitative gene-scale evolution of species L. monocytogenes, while gene decay and SNPs seem to represent major factors influencing long-term evolution. The discovery of common and disparately distributed genes considering lineages, serogroups, serotypes and strains of species L. monocytogenes will assist in diagnostic, phylogenetic and functional research, supported by the comparative genomic GECO-LisDB analysis server (http://bioinfo.mikrobio.med.uni-giessen.de/geco2lisdb).
单核细胞增生李斯特菌是一种重要的食源性病原体和宿主-病原体相互作用的模式生物,因此,考虑到研究控制此类微生物进化的力量,它是一个非常有价值的目标。该物种的多样性尚未得到详尽的探索,因为之前的研究主要集中在分析主要与人类李斯特菌病有关的血清型。我们使用 454 GS FLX 技术对 11 株菌株进行了全基因组测序,从而全面覆盖了所有血清型,包括 1/2b、3c、3b、4c、4d 和 4e 血清型的首个完整菌株。这些菌株与公开数据进行了比较分析,并在金龟子幼虫昆虫模型中评估了它们的致病性。
单核细胞增生李斯特菌的种泛基因组高度稳定但开放,表明它有能力通过产生或包含新的遗传信息来适应新的生态位。由辅助基因组代表的大多数基因尺度差异是由九个高变热点、数量相同的不同噬菌体、三个转座子(Tn916、Tn554、IS3 样)和两个可移动岛引起的。只有一部分菌株显示出不同亚型的 CRISPR/Cas 噬菌体抗性系统,这表明它们在维持染色体稳定性方面具有补充功能。李斯特菌属的多个进化枝表明,每个谱系的菌株都有很长的共同历史,这一点可以从 SNP 为基础的核心基因组树中得到证明,该树突出了小突变对物种单核细胞增生李斯特菌进化的影响。频繁的基因丢失或截断已被证实是一种常见的模式,特别是对于属于谱系 III 和 II 的菌株,这些基因被描述为对毒力或致病性至关重要。基于功能域和系统发育分布预测了新的与毒力功能相关的候选基因。对小调控 RNA 候选物的比较分析支持了转译 RNA 差异分布的观察结果,这表明存在广泛的适应性和调控影响。
本研究确定了常见的高变热点和移动元件作为单核细胞增生李斯特菌种基因尺度进化的主要效应因子,而基因衰减和单核苷酸多态性似乎是影响长期进化的主要因素。考虑到谱系、血清群、血清型和单核细胞增生李斯特菌种的菌株,共同和不同分布的基因的发现将有助于诊断、系统发生和功能研究,这一结果得到了比较基因组 GECO-LisDB 分析服务器(http://bioinfo.mikrobio.med.uni-giessen.de/geco2lisdb)的支持。
