The chemical composition of native organic matter influences the response of bacterial community to input of biochar and fresh plant material

Wang, Congying; Anderson, Craig; Suárez-Abelenda, Manuel; Wang, Tao; Arbestain, Marta Camps; Ahmad, Riaz; Herath, H.M.S.K.

doi:10.1007/s11104-015-2621-3

Cited by 20 publications

(6 citation statements)

References 65 publications

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“…The reason for the biochar-induced increase in microbial diversity is mostly unknown. However, as mentioned in other studies, it seems likely that organic compounds attached to the biochar particles 58 , 59 , the high pH of biochar-amended soils 35 , or other biochar properties (surface area, pore space) promoted the formation of specific niches, which supported the growth and activity of a diverse range of taxa 33 , 35 , 57 , 60 .…”

Section: Discussionmentioning

confidence: 69%

Soil biochar amendment affects the diversity of nosZ transcripts: Implications for N2O formation

Harter

El-Hadidi

Huson

et al. 2017

Sci Rep

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Microbial nitrogen transformation processes such as denitrification represent major sources of the potent greenhouse gas nitrous oxide (N2O). Soil biochar amendment has been shown to significantly decrease N2O emissions in various soils. However, the effect of biochar on the structure and function of microbial communities that actively perform nitrogen redox transformations has not been studied in detail yet. To analyse the community composition of actively denitrifying and N2O-reducing microbial communities, we collected RNA samples at different time points from a soil microcosm experiment conducted under denitrifying conditions and performed Illumina amplicon sequencing targeting nirK, typical nosZ and atypical nosZ mRNA transcripts. Within 10 days, biochar significantly increased the diversity of nirK and typical nosZ transcripts and resulted in taxonomic shifts among the typical nosZ-expressing microbial community. Furthermore, biochar addition led to a significant increase in transcript production among microbial species that are specialized on direct N2O reduction from the environment. Our results point towards a potential coupling of biochar-induced N2O emission reduction and an increase in microbial N2O reduction activity among specific groups of typical and atypical N2O reducers. However, experiments with other soils and biochars will be required to verify the transferability of these findings to other soil-biochar systems.

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Section: Discussionmentioning

confidence: 69%

Soil biochar amendment affects the diversity of nosZ transcripts: Implications for N2O formation

Harter

El-Hadidi

Huson

et al. 2017

Sci Rep

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“…Additionally, purpose-made biochars hold promises in improving soil physical properties (Herath et al 2013), reducing soil fertility constraints (Mia et al 2014) and stimulating soil biological processes (Wang et al 2015), and thereby enhance crop performance. Several studies have been undertaken to understand how P availability to plants can be directly or indirectly influenced by biochar addition and these are described below.…”

Section: Introductionmentioning

confidence: 99%

Can biochar increase the bioavailability of phosphorus?

Shen

Hedley

Arbestain

et al. 2016

J. Soil Sci. Plant Nutr.

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A large proportion of phosphate (P) fertilizer applied to Andosols reacts with reactive aluminum (Al) and iron (Fe) to become unavailable for plant uptake. We investigated whether biochar could enhance plant growth by (i) mobilizing soil P through changing soil pH or facilitating the growth of arbuscular mycorrhizal fungi (AMF), and/or (ii) introducing additional P. We grew Lotus pedunculatus cv barsille in two Andosols of contrasting P status amended with three biochars (with distinct porosity, nutrient and liming properties) at a dose of 10 t ha-1 for 32 weeks. The growth medium was divided into a root and a hyphal zone through a nylon mesh and a tephra layer that allowed the P in the hyphal zone to be transferred only by AMF hyphae. The addition of a relative nutrient-rich biochar (e.g. made from willow woodchips) with liming properties to the root zone of the P-deficient soil increased plant growth by 59% and P uptake by 73%. Pine-based biochar provided no extra nutrient acquisition and no plant-growth stimulation when added to the root zone of the Pdeficient soil. However, when hyphae of those plants had access to a P-rich soil patch, the presence of pine biochar in the soil patch greatly enhanced P uptake and plant growth (e.g., by 76% and 40% when using biochar produced at 450 o C compared to the absence of it). None of the tested biochars conferred advantages in the root zone of a high-P soil. We concluded that the benefits from biochar addition to nutrient uptake and plant growth are biochar-and soil-specific. Thus, biochars need to be tailored-made for certain soils by optimizing feedstock and pyrolysis conditions before application.

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“…For example, the fact that in the Cambisol, but not in the Andosol, roots have a direct impact on both measured enzymes involved in the C cycle, could be related to the existence of a more plant-derived OM in the Cambisol, and a more microbial-derived SOM in the Andosol (Herath et al 2015) due to differences in clay mineralogy and prevalence of microaggregates in the latter (Angst et al 2021). The increase in root biomass reported by Garbuz et al (2021) would have caused a direct increase in microbial-derived SOM in both soil types, but this increase would have been diluted in the Andosol where this SOM fraction is already more abundant as suggested by Wang et al (2015b).…”

Section: Enzymes Of the C Cyclementioning

confidence: 84%

Biochar increases soil enzyme activities in two contrasting pastoral soils under different grazing management

Garbuz

Mackay

Camps‐Arbestain

et al. 2022

Crop & Pasture Science

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Context. Soil enzyme activities are key regulators of carbon and nutrient cycling in grazed pastures. Aims. We investigated the effect of biochar addition on the activity of seven enzymes involved in the carbon, nitrogen and phosphorus cycles in a Sil-andic Andosol and a Dystric Cambisol under permanent pastures. Methods. The study consisted of a one-year field-based mesocosm experiment involving four pastures under different nutrient and livestock practices: with and without effluent under dairy cow grazing on the Andosol, and with either nil or high phosphorus fertiliser input under sheep grazing on the Cambisol. Soil treatments were: (1) willow biochar added at 1% w/w; (2) lime added at the liming equivalence of biochar (positive control); (3) no amendments (negative control). Key results. Compared with the Cambisol, the Andosol had higher dehydrogenase, urease, alkaline and acid phosphatase and, especially, nitrate-reductase activities, aligning with its higher pH and fertility. In both soils, biochar addition increased the activity of all enzymes, except for acid phosphatase and peroxidase; lime addition increased peroxidase and nitrate-reductase activity. Conclusions. The increased enzyme activity was strongly positively correlated with soil biological activity following biochar addition. Biochar caused a 40-45% increase in cellulase activity, attributed to increased root biomass following biochar addition. The response in acid and alkaline phosphatase activity can be attributed to the impact of biochar and lime addition on soil pH. Implications. The results provide more insights in realising the potential benefits of biochar to the provision of ecosystem services for grazed pastures.

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The chemical composition of native organic matter influences the response of bacterial community to input of biochar and fresh plant material

Cited by 20 publications

References 65 publications

Soil biochar amendment affects the diversity of nosZ transcripts: Implications for N2O formation

Soil biochar amendment affects the diversity of nosZ transcripts: Implications for N2O formation

Can biochar increase the bioavailability of phosphorus?

Biochar increases soil enzyme activities in two contrasting pastoral soils under different grazing management

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