Abstract
AbstractSoil bacteria play a key role in regulating terrestrial biogeochemical cycling and greenhouse gas fluxes across the soil‐atmosphere continuum. Despite their importance to ecosystem functioning, we lack a general understanding of how bacterial communities respond to climate change, especially in relatively understudied ecosystems like tropical montane wet forests. We used a well‐studied and highly constrained 5.2°C mean annual temperature (MAT) gradient in tropical montane wet forests on the Island of Hawaii to test the hypothesis that long‐term, whole‐ecosystem warming and the accompanying increase in belowground carbon flux increase the diversity and alter the composition of soil bacterial communities. Across this MAT gradient, dominant vegetation, substrate type and age, soil moisture, and disturbance history are constant, allowing us to effectively isolate the influence of rising MAT on soil bacterial community structure. Contrary to our hypothesis, we found that the richness, evenness, and phylogenetic diversity of the soil bacterial community remained remarkably stable with MAT and that MAT did not predict variation in bacterial community composition despite a substantial increase in belowground soil carbon fluxes across the gradient. Our results suggest that other factors that are constant across this gradient—such as soil pH, water availability and plant species composition—may be more important than warming in influencing soil bacterial community composition and diversity, at least within the temperature range studied here (~13–18°C MAT). Ours is the first study to demonstrate stability of soil bacterial community structure with rising MAT and increased belowground carbon flux in a tropical wet forest ecosystem. Moreover, our results add to growing evidence that the diversity and composition of soil bacterial communities dominated by Proteobacteria and Acidobacteria in low‐pH forest soils may be insensitive to the direct effect of climate warming.
Highlights
Climate warming may have both direct and indirect effects on soil bacterial communities, but the magnitude and direction of these effects remain poorly resolved (Allison and Martiny 2008, Shade et al 2012, Cregger et al 2014)
Similar to trends for diversity, we found no support for our hypothesis that temperature influences bacterial community composition in tropical montane wet forest soils
Increasing carbon fluxes with temperature, along with evidence from other studies indicating that bacterial diversity and community composition are sensitive to increasing carbon inputs (Carney et al 2007, Nemergut et al 2010, Landa et al 2013), led us to hypothesize that rising mean annual temperature (MAT) and the concurrent increase in belowground carbon availability would drive substantial shifts in the diversity and composition of soil bacteria
Summary
Climate warming may have both direct and indirect effects on soil bacterial communities, but the magnitude and direction of these effects remain poorly resolved (Allison and Martiny 2008, Shade et al 2012, Cregger et al 2014). Several studies have reported significant relationships between elevation and soil bacterial community structure (Bryant et al 2008, Singh et al 2011, 2014b, Shen et al 2015), including one in tropical wet forests (Fierer et al 2011), changes in temperature along all of these elevation gradients have been con founded with changes in soil pH or plant species composition.
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