Viral and parasitic cell ratios per free-living microbe across ecosystems

ABSTRACT

It is generally assumed that viruses outnumber cells on Earth by at least tenfold^1–4. Virus-to-microbe ratios (VMR) are largely based on fluorescently-labelled viral-like particles (VLPs) counts. However, these exclude cell-infecting lytic and lysogenic viruses and potentially include many false positives, e.g. DNA-containing membrane vesicles, genetransfer agents or inert particles. Here, we develop a metagenome-based VMR estimate (mVRM) accounting for all viral stages (virion-lytic-lysogenic) using normalised counts of viral DNA-polymerases and cellular universal single-copy genes as proxies for individuals. To properly estimate mVMR in aquatic ecosystems, we generated metagenomes from co-occurring cellular and viral fractions (>50 kDa-200 μm size range) in freshwater, seawater and 6-14-32% salt solar-saltern ponds. Viruses outnumbered cells in non-blooming freshwater and marine plankton by around twofold. However, mVMR in 133 uniformly-analysed metagenomes from diverse ecosystems showed that free-living cells largely exceeded viruses and epibiont DPANN archaea and/or CPR bacteria in compact environments (sediments, soils, microbial mats, host-associated microbiomes). Along the Piggyback-the-winner model⁵ lines, lysogenic genes significantly correlated with cell, but not necessarily biotope, density. While viruses likely are the most diverse biological entities on Earth^6,7, our results suggest that cells are the most abundant and that cellular parasites may exert population-size control in some high-density ecosystems.