Divergent Changes in Bacterial Functionality as Affected by Root-Zone Ecological Restoration in an Aged Peach Orchard

Soil restoration is a crucial approach to improving plant productivity in orchards with soil degradation, yield reduction, and fruit quality declination in China. A self-invented root-zone ecological restoration practice (RERP) with soil conditioner, or organic fertilizer, was employed in a degraded...

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Bibliographic Details
Published in:Microorganisms (Basel) 2022-10, Vol.10 (11), p.2127
Main Authors: Sun, Na, Zhang, Weiwei, Liao, Shangqiang, Li, Hong
Format: Article
Language:English
Subjects:
Abundance
Acidic soils
Agricultural production
Agricultural research
alpha diversity
Amino acids
Bacteria
bacterial community
Biological diversity
Composition
Correlation analysis
Crop yield
Crop yields
Declination
Ecological restoration
Ecosystem services
Ecosystems
Environmental aspects
Environmental restoration
Fertilizers
Fruits
Gene amplification
Genera
Management
Methods
Microenvironments
Nutrients
orchard ecosystem
Orchards
Organic fertilizers
Organic soils
Peach
Potassium
Production processes
Productivity
Restoration
Root zone
Soil amendments
Soil analysis
Soil bacteria
soil conditioner
Soil conditioners
Soil conditions
Soil degradation
Soil depth
Soil layers
Soil microbiology
Soil microorganisms
Soil properties
soil property
Soil surfaces
Soils
Taxonomy
Trees
Water supply
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Summary:Soil restoration is a crucial approach to improving plant productivity in orchards with soil degradation, yield reduction, and fruit quality declination in China. A self-invented root-zone ecological restoration practice (RERP) with soil conditioner, or organic fertilizer, was employed in a degraded peach orchard in Beijing in 2020 to investigate the consequent impacts on soil bacterial composition and functionality at soil depths of 0–20 cm and 20–40 cm. Bacterial diversity was sensitive to RERP, especially in subsurface soil. RERP with soil conditioner significantly increased bacterial diversity, and affected abundances of certain genera, such as a significantly increased amount of Bacillus in surface soil and Blastococcus, Microvirga, Nocardioides, and Sphingomonas in subsurface soil. It also significantly affected abundances of bacterial functions related to metabolism in subsurface soil, particularly those with low abundance such as decreased transcription abundance and increased amino acid metabolism abundance. Soil bacterial functions were observably affected by bacterial diversity and composition, particularly in the deep soil layer. RERP affected bacterial functionality via responses of soil bacteria and bacteria-mediated alterations to the changed soil property. Correlation analysis between soil properties, bacterial taxonomy, and bacterial functions revealed that RERP affected bacterial functionality by altering the soil microenvironment with ample nutrients and water supply in root zone. Consequently, shifted bacterial functionality could have a potential in orchard ecosystem services in view of fruit yield and quality. Taken together, RERP had notably positive impacts on soil bacterial diversity and functions, and a prospect of increased plant productivity in the degrade orchard ecosystem.
ISSN:2076-2607
2076-2607
DOI:10.3390/microorganisms10112127