Air Monitoring by Nanopore Sequencing

Overview

Journal ISME Commun

Publisher Oxford University Press

Date 2024 Jul 31

PMID 39081363

Authors

Tim Reska

Sofya Pozdniakova

Silvia Borras

Albert Perlas

Ela Sauerborn

Lidia Canas

Michael Schloter

Xavier Rodo

Yuanyuan Wang

Barbro Winkler

Jorg-Peter Schnitzler

Lara Urban

Affiliations

Soon will be listed here.

Abstract

While the air microbiome and its diversity are essential for human health and ecosystem resilience, comprehensive air microbial diversity monitoring has remained rare, so that little is known about the air microbiome's composition, distribution, or functionality. Here we show that nanopore sequencing-based metagenomics can robustly assess the air microbiome in combination with active air sampling through liquid impingement and tailored computational analysis. We provide fast and portable laboratory and computational approaches for air microbiome profiling, which we leverage to robustly assess the taxonomic composition of the core air microbiome of a controlled greenhouse environment and of a natural outdoor environment. We show that long-read sequencing can resolve species-level annotations and specific ecosystem functions through de novo metagenomic assemblies despite the low amount of fragmented DNA used as an input for nanopore sequencing. We then apply our pipeline to assess the diversity and variability of an urban air microbiome, using Barcelona, Spain, as an example; this randomized experiment gives first insights into the presence of highly stable location-specific air microbiomes within the city's boundaries, and showcases the robust microbial assessments that can be achieved through automatable, fast, and portable nanopore sequencing technology.

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