基因组
生物
系统发育多样性
门
克莱德
微生物生态学
微生物种群生物学
环境DNA
生态学
系统发育树
计算生物学
生物多样性
遗传学
基因
细菌
作者
Lauren Alteio,Frederik Schulz,R. Seshadri,Neha Varghese,William Rodriguez-Reillo,Elizabeth M. Ryan,Danielle Goudeau,Stephanie A. Eichorst,Rex R. Malmstrom,Robert M. Bowers,Laura A. Katz,Jeffrey L. Blanchard,Tanja Woyke
出处
期刊:MSystems
[American Society for Microbiology]
日期:2020-03-09
卷期号:5 (2)
被引量:72
标识
DOI:10.1128/msystems.00768-19
摘要
Microbial ecologists have historically used cultivation-based approaches as well as amplicon sequencing and shotgun metagenomics to characterize microbial diversity in soil. However, challenges persist in the study of microbial diversity, including the recalcitrance of the majority of microorganisms to laboratory cultivation and limited sequence assembly from highly complex samples. The uncultivated majority thus remains a reservoir of untapped genetic diversity. To address some of the challenges associated with bulk metagenomics as well as low throughput of single-cell genomics, we applied flow cytometry-enabled mini-metagenomics to capture expanded microbial diversity from forest soil and compare it to soil bulk metagenomics. Our resulting data from this pooled-cell sorting approach combined with bulk metagenomics revealed increased phylogenetic diversity through novel soil taxa and rare biosphere members. In-depth analysis of genomes within the highly represented Bacteroidetes phylum provided insights into conserved and clade-specific patterns of carbon metabolism.
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