Ultra-deep long-read metagenomics captures diverse taxonomic and biosynthetic potential of soil microbes
Abstract
Background
Soil ecosystems have long been recognized as hotspots of microbial diversity, but most estimates of their complexity remain speculative, relying on limited data and extrapolation from shallow sequencing. Here, we revisit this question using one of the deepest metagenomic sequencing efforts to date, applying 148 Gbp of Nanopore long-read and 122 Gbp of Illumina short-read data to a single forest soil sample.
Results
Our hybrid assembly reconstructed 837 metagenome-assembled genomes (MAGs), including 466 high- and medium-quality genomes, nearly all lacking close relatives among cultivated taxa. Rarefaction and k-mer analyses reveal that, even at this depth, we capture only a fraction of the extant diversity: nonparametric models project that over 10 Tbp would be required to approach saturation. These findings offer a quantitative, technology-enabled update to long-standing diversity estimates and demonstrate that conventional metagenomic sequencing efforts likely miss the majority of microbial and biosynthetic potential in soil. We further identify over 11,000 biosynthetic gene clusters (BGCs), >99% of which have no match in current databases, underscoring the breadth of unexplored metabolic capacity.
Conclusions
Taken together, our results emphasize both the power and the present limitations of metagenomics in resolving natural microbial complexity, and they provide a new baseline for evaluating future advances in microbial genome recovery, taxonomic classification, and natural product discovery.
Related articles
Related articles are currently not available for this article.