Functional and compositional responses in soil microbial communities along two metal pollution gradients: does the level of historical pollution affect resistance against secondary stress?

Hamed Azarbad,Karolina Nikiel,Maria Niklińska,Nico M Van Straalen,Wilfred F M Röling

doi:10.1007/s00374-015-1033-0

Hamed Azarbad, Karolina Nikiel + Show 3 more

Open Access

https://doi.org/10.1007/s00374-015-1033-0

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Abstract

We examined how the exposure to secondary stressors affected the functional and compositional responses of microbial communities along two metal pollution gradients in Polish forests and whether responses were influenced by the level of metal pollution. Basal respiration rate and community composition, as determined by 16S rRNA gene-based denaturing gradient analysis, were studied in laboratory-incubated microcosms, containing soil samples taken from different locations in the field gradients, and subjected to secondary stress factors (arsenic, salt, benzo[a]pyrene or flooding). Soils adapted to higher metal contamination levels were more resistant to arsenic and salt stress compared to less polluted soils, indicating that functional and compositional responses to these stresses were related to the level of historical pollution in the long-term contaminated forest soils. However, community composition and functioning in soils along the two gradients were resistant to benzo[a]pyrene and flooding stress. Changes in respiration were significantly related to changes in community composition. Knowledge on the functional gene capabilities prior to adding the secondary stressor benefitted understanding the functional responses toward additional stressors. Our study highlights that microbial communities selected for metal resistance in the field might also become more resistant against some secondary stress factors; however, the type of stress and the level of historical pollution play a decisive role in community-level responses toward secondary stressors.

Highlights

Microbial communities can adapt to metal contamination by overexpressing genes conferring metal tolerance, by acquiring tolerance through horizontal gene transfer or via selective growth of metal-tolerant microorganisms (Turpeinen et al 2004)
Regression analysis revealed that the arsenic-induced decrease of Basal respiration (BR) on day 1 along the Miasteczko Śląskie gradient was negatively affected by TItot (β=2.7, p=0.014); in other words, the largest effects of arsenic were observed in the lesser polluted soils
Using two separate gradients, polluted by different smelters, the present study demonstrates that, overall, functional and compositional responses to arsenic and salt stress were clearly related to the level of pollution in the long-term contaminated soils

Summary

Introduction

Microbial communities can adapt to metal contamination by overexpressing genes conferring metal tolerance, by acquiring tolerance through horizontal gene transfer or via selective growth of metal-tolerant microorganisms (Turpeinen et al 2004). Adaptation usually results in changes of community composition and the maintenance of soil functionality up to high concentrations of metals in soil (Frostegård et al 1996; Bååth et al 1998; Witter et al 2000). Dealing with potentially toxic stress is energy-demanding for microorganisms due to the maintenance of metal resistance mechanisms. It has been hypothesized that adapted communities will be increasingly susceptible to additional stressors (Degens et al 2001).

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