Abstract
Chronic acid deposition affects many temperate hardwood forests of the northeastern United States, reduces soil pH and phosphorus (P) availability, and can alter the structure and function of soil microbial communities. The strategies that microorganisms possess for survival in acidic, low P soil come at a carbon (C) cost. Thus, how microbial communities respond to soil acidification in forests may be influenced by plant phenological stage as C allocation belowground varies; however, this remains largely unexplored. In this study, we examined microbial communities in an ecosystem level manipulative experiment where pH and/or P availability were elevated in three separate forests in Northeastern Ohio. Tag-encoded pyrosequencing was used to examine bacterial and fungal community structure at five time points across one year corresponding to plant phenological stages. We found significant effects of pH treatment and time on fungal and bacterial communities in soil. However, we found no interaction between pH treatment and time of sampling for fungal communities and only a weak interaction between pH elevation and time for bacterial communities, suggesting that microbial community responses to soil pH are largely independent of plant phenological stage. In addition, fungal communities were structured largely by site, suggesting that fungi were responding to differences between the forests, such as plant community differences.
Highlights
Forests are an important terrestrial biome, covering 30% of Earth’s surface and harboring a large percentage of the planet’s plant and animal species [1]
This study found little evidence to support our hypothesis that the microbial community response to soil pH and Pi limitation would be altered by changes in plant phenological stage and the potential availability of labile C
Acidobacteria subgroups were more abundant at low pH, others were more abundant at elevated pH, including subgroup 2. This could explain the higher relative abundance at elevated soil pH we found of the operational taxonomic unit (OTU) matching with the Acidobacteria order Ellin6513, which is an undescribed taxa in subdivision
Summary
Forests are an important terrestrial biome, covering 30% of Earth’s surface and harboring a large percentage of the planet’s plant and animal species [1]. In addition to providing 49% of terrestrial primary productivity [1], forests provide important ecosystem services and sequester large amounts of carbon (C) in living biomass [2,3], which can offset the effects of anthropogenic emissions on global atmospheric CO2 levels and impact global climate change. Despite their importance, forest function is affected by human disturbance, such as landscape fragmentation, overharvesting, and atmospheric air pollution, including acid deposition [4,5,6,7]. Forest acidification is of particular interest as it Microorganisms 2020, 8, 1; doi:10.3390/microorganisms8010001 www.mdpi.com/journal/microorganisms
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