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High-throughput single-cell sequencing of activated sludge microbiome

Yulin Zhang, Bingjie Xue, Yanping Mao, Xi Chen, Weifu Yan, Yan-Ren Wang, Yulin Wang, Lei Liu, Jiale Yu, Xiaojin Zhang, Chao Shan, Edward Topp, Wenshan Zheng, Tong Zhang

2024Environmental Science and Ecotechnology12 citationsDOIOpen Access PDF

Abstract

Wastewater treatment plants (WWTPs) represent one of biotechnology's largest and most critical applications, playing a pivotal role in environmental protection and public health. In WWTPs, activated sludge (AS) plays a major role in removing contaminants and pathogens from wastewater. While metagenomics has advanced our understanding of microbial communities, it still faces challenges in revealing the genomic heterogeneity of cells, uncovering the microbial dark matter, and establishing precise links between genetic elements and their host cells as a bulk method. These issues could be largely resolved by single-cell sequencing, which can offer unprecedented resolution to show the unique genetic information. Here we show the high-throughput single-cell sequencing to the AS microbiome. The single-amplified genomes (SAGs) of 15,110 individual cells were clustered into 2,454 SAG bins. We find that 27.5% of the genomes in the AS microbial community represent potential novel species, highlighting the presence of microbial dark matter. Furthermore, we identified 1,137 antibiotic resistance genes (ARGs), 10,450 plasmid fragments, and 1,343 phage contigs, with shared plasmid and phage groups broadly distributed among hosts, indicating a high frequency of horizontal gene transfer (HGT) within the AS microbiome. Complementary analysis using 1,529 metagenome-assembled genomes from the AS samples allowed for the taxonomic classification of 98 SAG bins, which were previously unclassified. Our study establishes the feasibility of single-cell sequencing in characterizing the AS microbiome, providing novel insights into its ecological dynamics, and deepening our understanding of HGT processes, particularly those involving ARGs. Additionally, this valuable tool could monitor the distribution, spread, and pathogenic hosts of ARGs both within AS environments and between AS and other environments, which will ultimately contribute to developing a health risk evaluation system for diverse environments within a One Health framework. • This study marks the first application of high-throughput single-cell sequencing to activated sludge (AS) microbiome. • A total of 15,110 single cells were sequenced, resulting in 2,454 single-amplified genome bins. • The analysis detected 1,137 antibiotic resistance genes, 10,450 plasmid fragments, and 1,343 phage contigs. • The shared relationships for plasmid (12,819) and phage (184) hosts indicate a high frequency of horizontal gene transfer. • A set of 1,529 metagenome-assembled genomes was used to further classify 98 previously unclassified SAG bins.

Topics & Concepts

Activated sludgeThroughputMicrobiomeComputational biologyDNA sequencingBiologyComputer scienceEnvironmental scienceGeneticsGeneSewage treatmentTelecommunicationsEnvironmental engineeringWirelessMicrobial Community Ecology and PhysiologyGut microbiota and healthBacteriophages and microbial interactions
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