Nutrient limitations to bacterial and fungal growth during cellulose decomposition in tropical forest soils

Lettice C Hicks,Norma Salinas,Andrew T Nottingham,Erland Bååth,Patrick Meir,Adan J Q Ccahuana

doi:10.1007/s00374-017-1247-4

Abstract

Nutrients constrain the soil carbon cycle in tropical forests, but we lack knowledge on how these constraints vary within the soil microbial community. Here, we used in situ fertilization in a montane tropical forest and in two lowland tropical forests on contrasting soil types to test the principal hypothesis that there are different nutrient constraints to different groups of microorganisms during the decomposition of cellulose. We also tested the hypotheses that decomposers shift from nitrogen to phosphorus constraints from montane to lowland forests, respectively, and are further constrained by potassium and sodium deficiency in the western Amazon. Cellulose and nutrients (nitrogen, phosphorus, potassium, sodium, and combined) were added to soils in situ, and microbial growth on cellulose (phospholipid fatty acids and ergosterol) and respiration were measured. Microbial growth on cellulose after single nutrient additions was highest following nitrogen addition for fungi, suggesting nitrogen as the primary limiting nutrient for cellulose decomposition. This was observed at all sites, with no clear shift in nutrient constraints to decomposition between lowland and montane sites. We also observed positive respiration and fungal growth responses to sodium and potassium addition at one of the lowland sites. However, when phosphorus was added, and especially when added in combination with other nutrients, bacterial growth was highest, suggesting that bacteria out-compete fungi for nitrogen where phosphorus is abundant. In summary, nitrogen constrains fungal growth and cellulose decomposition in both lowland and montane tropical forest soils, but additional nutrients may also be of critical importance in determining the balance between fungal and bacterial decomposition of cellulose.

Highlights

The terrestrial carbon (C) cycle is regulated by the supply and demand of several crucial elements within organisms
We addressed the following questions: do different nutrients limit cellulose decomposition in montane and lowland tropical forest sites, and are fungi or bacteria the main decomposers of cellulose under different nutrient availabilities? Our experimental objective was to control the abundance of C and other nutrients added to soil; we added a cellulose C-substrate in combination with different nutrients
We tested whether microbial C metabolism during cellulose degradation was predominantly constrained by P and

Summary

Introduction

The terrestrial carbon (C) cycle is regulated by the supply and demand of several crucial elements within organisms The study of these elemental constraints has been framed within theories of ecological stoichiometry, which identify important ‘limiting nutrients’ for growth or metabolism (Sterner and Elser 2002; von Liebig 1855) and have advanced our understanding of primary production and decomposition in global ecosystems (Elser et al 2009, Zechmeister-Boltenstern et al 2015). Fertilization and decomposition experiments have shown that phosphorus (P), nitrogen (N), sodium (Na) and potassium (K) all may limit soil microbial processes to some extent (Kaspari et al 2008, 2009; Waring 2012) It remains unclear whether these variable responses to nutrient addition reflect different nutrient constraints to different groups of belowground organisms, different nutrient constraints to the decomposition of different organic matter substrates and/ or different environmental drivers of decomposition among sites. This problem is challenging given our lack of understanding of whether and how different soil organisms regulate soil processes in general (Fierer 2017)

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