Soil nutrient management influences diversity, community association and functional structure of rhizosphere bacteriome under vegetable crop production

Adekunle R Raimi; Obinna T Ezeokoli; Rasheed A Adeleke

doi:10.3389/fmicb.2023.1229873

Soil nutrient management influences diversity, community association and functional structure of rhizosphere bacteriome under vegetable crop production

Front Microbiol. 2023 Sep 28:14:1229873. doi: 10.3389/fmicb.2023.1229873. eCollection 2023.

Authors

Adekunle R Raimi¹, Obinna T Ezeokoli¹, Rasheed A Adeleke¹

Affiliation

¹ Unit for Environmental Sciences and Management, North-West University, Potchefstroom, South Africa.

Abstract

Introduction: Rhizosphere bacterial communities play a crucial role in promoting plant and soil ecosystem health and productivity. They also have great potential as key indicators of soil health in agroecosystems. Various environmental factors affect soil parameters, which have been demonstrated to influence soil microbial growth and activities. Thus, this study investigated how rhizosphere bacterial community structure and functions are affected by agronomic practices such as organic and conventional fertiliser application and plant species types.

Methods: Rhizosphere soil of vegetable crops cultivated under organic and conventional fertilisers in different farms was analysed using high-throughput sequencing of the 16S rRNA gene and co-occurrence network pattern among bacterial species. The functional structure was analysed with PICRUSt2 pipeline.

Results: Overall, rhizosphere bacterial communities varied in response to fertiliser type, with soil physicochemical parameters, including NH_4, PO₄, pH and moisture content largely driving the variations across the farms. Organic farms had a higher diversity richness and more unique amplicon sequence variants than conventional farms. Bacterial community structure in multivariate space was highly differentiated across the farms and between organic and conventional farms. Co-occurrence network patterns showed community segmentation for both farms, with keystone taxa more prevalent in organic than conventional farms.

Discussion: Module hub composition and identity varied, signifying differences in keystone taxa across the farms and positive correlations between changes in microbial composition and ecosystem functions. The organic farms comprised functionally versatile communities characterised by plant growth-promoting keystone genera, such as Agromyces, Bacillus and Nocardioides. The results revealed that organic fertilisers support high functional diversity and stronger interactions within the rhizosphere bacterial community. This study provided useful information about the overall changes in soil microbial dynamics and how the changes influence ecosystem functioning under different soil nutrient management and agronomic practices.

Keywords: 16S rRNA gene sequencing; agroecosystem; fertilizers; microbial networks; plant-soil ecology; soil-plant-microbe interactions.