Abstract
The rigorous environmental stress of the severely eroded Loess Plateau may have promoted specific soil bacterial communities in comparison to other eco-environmental regions. In order to unmask the bacterial diversity and most influential environmental parameters, Illumina MiSeq high throughput sequencing of 16S rRNA from 24 representative soil samples collected across south-east to north-west transect of the Loess Plateau in northern Shaanxi, China was conducted. This high-throughput sequencing revealed a total of 1,411,001 high quality sequences that classified into 38 phyla, 127 classes, >240 orders, and over 650 genera, suggesting a high bacterial richness across the Loess Plateau soils. The seven dominant groups were: Proteobacteria, Actinobacteria, Acidobacteria, Planctomycetes, Gemmatimonadetes, Chloroflexi, and Verrucomicrobi (relative abundance of >5%). Increasing/decreasing soil pH and geographic longitudinal distance correlated significantly with increasing/decreasing bacterial richness and diversity indices. Pairwise correlation analysis showed higher bacterial diversity at longitudinal gradients across 107°39′-109°15′ (south-east to north-west) in our studied Chinese loess zone. Variation partitioning analysis indicated significant influence of soil characteristics (~40.4%) than geographical distance (at a landscape scale of ~400 km) that was responsible for 13.6% of variation in bacterial community structure from these soils. Overall, contemporary soil characteristics structure the bacterial community in Loess Plateau soil to a greater extent than the spatial distances along the loess transect.
Highlights
Soil microorganisms from terrestrial habitats are key drivers of critical ecosystem services, such as nutrients cycling (Madsen, 2005), soil organic matter (SOM) stabilization and C sequestration (Grandy and Neff, 2008; Plaza et al, 2013)
Our results demonstrate that, soil nutrients exhibited varying ranges of Soil organic carbon (SOC)-3.4 times, total nitrogen (TN)-7.4 times and Total phosphorus (TP)-4.5 times across different ecosystems than soil pH ∼
We report that bacterial community structure in these soils is strongly manipulated by soil pH and TP contents
Summary
Soil microorganisms from terrestrial habitats are key drivers of critical ecosystem services, such as nutrients cycling (Madsen, 2005), soil organic matter (SOM) stabilization and C sequestration (Grandy and Neff, 2008; Plaza et al, 2013). With the country’s ambitious “payment for ecosystem services” (such as soil carbon storage, biodiversity conservation and climate regulation) program (Bennett, 2008), the Chinese government has invested ∼28 billion USD in GTGP during its first implementation period from 1999 to 2008 (Lü et al, 2012). This substantially resulted in land-use conversions from former agricultural lands to re-vegetating forests and/or natural-recovering grasslands (Deng et al, 2014; Fazhu et al, 2015). Biogeographic distribution patterns of bacterial communities across Loess Plateau soils still lack in-depth exploration
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