Phosphate amendment drives bloom of RNA viruses after soil wet-up
Phosphate amendment drives bloom of RNA viruses after soil wet-up
Sieradzki, E. T.; Allen, G. M.; Kimbrel, J. A.; Nicol, G. W.; Hazard, C.; Nuccio, E. E.; Blazewicz, S. J.; Pett-Ridge, J.; Trubl, G.
AbstractSoil rewetting after a dry period results in a surge of activity and succession in both microbial and DNA virus communities. Less is known about the response of RNA viruses to soil rewetting--while they are highly diverse and widely distributed in soil, they remain understudied. We hypothesized that RNA viruses would show temporal succession following rewetting and that phosphate amendment would influence their trajectory, as viral proliferation may cause phosphorus limitation. Using 39 time-resolved metatranscriptomes and amplicon data, 2,190 RNA viral populations were identified across five phyla, with 37% of these predicted to infect bacteria (26%) or fungi (11%). Only 1.2% of viral populations had annotated capsid genes, suggesting most persist via intracellular replication without a free virion phase. Phosphate amendment altered RNA viral community composition within the first week and amended vs. unamended communities remained distinguishable for up to three weeks. While the overall host community remained stable, certain bacterial populations showed reduced abundance in phosphate-amended soils, likely due to increased viral lysis, as RNA bacteriophages, particularly Leviviricetes, proliferated significantly. Notably, 60% of the viruses with increased abundance under phosphate amendment belonged to basal Lenarviricota clades rather than well-known groups like Leviviricetes. We estimate RNA bacteriophage infections may affect 107-109 bacteria per gram of soil, aligning with the total bacterial population (107-1010 -1 soil), suggesting that RNA phages significantly influence bacterial communities post-wet-up, with phosphorus availability modulating this effect.