处理与蜱虫相关的微生物复杂性

A. Cabezas-Cruz, T. Pollet, A. Estrada-Peña, Eléonore Allain, S. Bonnet, S. Moutailler
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引用次数: 20

摘要

蜱及其传播的病原体对世界各地的人类和动物健康构成越来越大的负担。在过去的几年里,高通量检测和测序技术(HTT)揭示了蜱个体携带高度多样性的微生物,包括致病性和非致病性细菌。尽管有几项研究有助于获得与不同蜱虫物种相关的微生物目录,但HTT研究仍然存在主要限制和挑战,以获得与蜱虫相关的微生物复杂性的进一步见解。目前,使用下一代测序(NGS),可以记录细菌属(或更高的分类水平);然而,物种鉴定仍然存在问题,这反过来影响了使用NGS进行病原体检测。微流控PCR是一种高通量检测技术,可以检测多达96种不同的病原体,它与NGS的结合可能会对病原体-微生物共生模式提供有趣的见解。然而,由于尚未实施病原体菌株的检测,微流控PCR也受到限制,因此,细菌基因型之间的推定关联目前尚不清楚。结合NGS和微流控PCR数据可能是具有挑战性的。在此,我们回顾了HTT在蜱微生物学研究中的应用,并提出了网络分析作为综合数据分析的基准,以揭示不同生态系统中与蜱相关的微生物群落的结构和意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Handling the Microbial Complexity Associated to Ticks
Ticks and the pathogens they transmit constitute a growing burden for human and animal health worldwide. In the last years, high-throughput detection and sequencing technologies (HTT) have revealed that individual ticks carry a high diversity of microorganisms, including pathogenic and non-pathogenic bacteria. Despite several studies have contributed to the availability of a catalog of microorganisms associated to different tick species, major limitations and challenges remain ahead HTT studies to acquire further insights on the microbial complexity associated to ticks. Currently, using next generation sequencing (NGS), bacteria genera (or higher taxonomic levels) can be recorded; however, species identification remains problematic which in turn affects pathogen detection using NGS. Microfluidic PCR, a high-throughput detection technology, can detect up to 96 different pathogen species, and its combination with NGS might render interesting insights into pathogen-microbiota co-occurrence patterns. Microfluidic PCR, however, is also limited because detection of pathogen strains has not been implemented, and therefore, putative associations among bacterial genotypes are currently unknown. Combining NGS and microfluidic PCR data may prove challenging. Here, we review the impact of some HTT applied to tick microbiology research and propose network analysis as an integrative data analysis benchmark to unravel the structure and significance of microbial communities associated to ticks in different ecosystems.
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