Microbial Keystone Taxa Identification in Global Wastewater Treatment Plants Based on Deep Learning

Microbial Keystone Taxa Identification in Global Wastewater Treatment Plants Based on Deep Learning

Microorganisms play a vital role in maintaining the stability of the activated sludge (AS) ecosystem. Recent studies indicate that certain keystone taxa impact both composition and function, but independent of their abundance. However, an effective framework for identifying these taxa from numerous...

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Bibliographic Details
Main Author: Sen Wang (135167) (author)
Other Authors: Yong-Chao Wang (6931529) (author), Can Wang (157994) (author)
Published: 2025
Subjects:
Microbiology
Ecology
Sociology
Space Science
Environmental Sciences not elsewhere classified
Biological Sciences not elsewhere classified
wastewater treatment systems
wastewater treatment process
recent studies indicate
primary factors influencing
bypassing network reconstruction
algorithm effectively avoids
throughput sequencing data
deep learning framework
throughput sequencing
various samples
various environmental
tricky issue
study introduces
still lacking
particularly without
increased connectivity
expeditious framework
effective framework
dissolved oxygen
climatic conditions
challenging task
assemblage samples
activated sludge
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Summary:Microorganisms play a vital role in maintaining the stability of the activated sludge (AS) ecosystem. Recent studies indicate that certain keystone taxa impact both composition and function, but independent of their abundance. However, an effective framework for identifying these taxa from numerous high-throughput sequencing data is still lacking, particularly without the challenging task of reconstructing the detailed microbial correlation network. We developed a deep learning framework that quantifies microbial impact values across samples, bypassing network reconstruction. This algorithm effectively avoids the tricky issue of differing keystoneness across species in various samples, making it applicable to AS assemblage samples from various environmental and climatic conditions. In this work, we applied this framework to the high-throughput sequencing of the global wastewater treatment sample and identified 61 candidate taxa as the keystones for the wastewater treatment process. We found that the temperature and dissolved oxygen are the primary factors influencing the keystone taxa. Moreover, we found that the increased connectivity of keystone taxa with other members promotes tighter integration within the activated sludge microbial community. In summary, this study introduces an expeditious framework for efficient keystone taxa identification and reveals their role in enhancing microbial community integration in wastewater treatment systems.

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