Details

Autor(en) / Beteiligte

• Graham, Emily B.
• Wieder, William R.
• Leff, Jonathan W.
• Weintraub, Samantha R.
• Townsend, Alan R.
• Cleveland, Cory C.
• Philippot, Laurent
• Nemergut, Diana R.

Titel

Do we need to understand microbial communities to predict ecosystem function? A comparison of statistical models of nitrogen cycling processes

Ist Teil von

• Soil biology & biochemistry, 2014-01, Vol.68, p.279-282

Ort / Verlag

Amsterdam: Elsevier Ltd

Erscheinungsjahr

2014

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• Despite the central role of microorganisms in biogeochemistry, process models rarely explicitly account for variation in communities. Here, we use statistical models to address a fundamental question in ecosystem ecology: do we need to better understand microbial communities to accurately predict ecosystem function? Nitrogen (N) cycle process rates and associated gene abundances were measured in tropical rainforest soil samples collected in May (early wet season) and October (late wet season). We used stepwise linear regressions to examine the explanatory power of edaphic factors and functional gene relative abundances alone and in combination for N-cycle processes, using both our full dataset and seasonal subsets of the data. In our full dataset, no models using gene abundance data explained more variation in process rates than models based on edaphic factors alone, and models that contained both edaphic factors and community data did not explain significantly more variation in process rates than edaphic factor models. However, when seasonal datasets were examined separately, microbial predictors enhanced the explanatory power of edaphic predictors on dissimilatory nitrate reduction to ammonium and N2O efflux rates during October. Because there was little variation in the explanatory power of microbial predictors alone between seasonal datasets, our results suggest that environmental factors we did not measure may be more important in structuring communities and regulating processes in October than in May. Thus, temporal dynamics are key to understanding the relationships between edaphic factors, microbial communities and ecosystem function in this system. The simple statistical method presented here can accommodate a variety of data types and should help prioritize what forms of data may be most useful in ecosystem model development. •A method is presented to explore the utility of edaphic and microbial data in explaining biogeochemical process rates.•In general, edaphic factors structured communities involved in N-cycling.•The value of gene relative abundance data for explaining function over edaphic factors alone varied by process and by season.