Mitomycin C-induced effects on aerobic methanotrophs in a landfill cover soil; implications of a viral shunt?

Mitomycin C can potentially induce a viral shunt, impacting soil microbial respiration and methane uptake, and modifies the active bacterial community composition, including the methanotrophs. A viral shunt can occur when phages going through a lytic cycle, including lysogenic phages triggered by inducing agents (e.g. mitomycin C), results in host lysis and the release of cell constituents and virions. The impact of a viral shunt on the carbon, including methane cycle in soil systems is poorly understood. Here, we determined the effects of mitomycin C on the aerobic methanotrophs in a landfill cover soil. To an extent, our results support a mitomycin C-induced viral shunt, as indicated by the significantly higher viral-like particle (VLP) counts relative to bacteria, elevated nutrient concentrations (ammonium, succinate), and initially impaired microbial activities (methane uptake and microbial respiration) after mitomycin C addition. The trend in microbial activities at <2 days largely corresponded to the expression of the pmoA and 16S rRNA genes. Thereafter (>11 days), the active bacterial community composition significantly diverged in the mitomycin C-supplemented incubations, suggesting the differential impact of mitomycin C on the bacterial community. Collectively, we provide insight on the effects of mitomycin C, and potentially a viral shunt, on the bacteria in the soil environment.

Automated summary

Mitomycin C can induce a viral shunt, affecting soil microbial respiration and methane uptake, and alter the composition of active bacterial community, including methanotrophs. The impact of a viral shunt on the carbon cycle, including methane cycle, in soil systems is not well understood. This study provides insights into the effects of Mitomycin C and potentially a viral shunt on bacteria in the soil environment.