Maize edible‑legumes intercropping systems for enhancing agrobiodiversity and belowground ecosystem services

Abstract

Intensification of staple crops through conventional agricultural practices with chemical synthetic inputs has yielded positive outcomes in food security but with negative environmental impacts. Ecological intensification using cropping systems such as maize edible-legume intercropping (MLI) systems has the potential to enhance soil health, agrobiodiversity and significantly influence crop productivity. However, mechanisms underlying enhancement of biological soil health have not been well studied. This study investigated the shifts in rhizospheric soil and maize-root microbiomes and associated soil physico-chemical parameters in MLI systems of smallholder farms in comparison to maize-monoculture cropping systems (MMC). Maize-root and rhizospheric soil samples were collected from twenty-five farms each conditioned by MLI and MMC systems in eastern Kenya. Soil characteristics were assessed using Black oxidation and Walkley methods. High-throughput amplicon sequencing was employed to analyze fungal and bacterial communities, predicting their functional roles and diversity. The different MLI systems significantly impacted soil and maize-root microbial communities, resulting in distinct microbe sets. Specific fungal and bacterial genera and species were mainly influenced and enriched in the MLI systems (e.g., Bionectria solani, Sarocladium zeae, Fusarium algeriense, and Acremonium persicinum for fungi, and Bradyrhizobium elkanii, Enterobacter roggenkampii, Pantoea dispersa and Mitsuaria chitosanitabida for bacteria), which contribute to nutrient solubilization, decomposition, carbon utilization, plant protection, bio-insecticides/fertilizer production, and nitrogen fixation. Conversely, the MMC systems enriched phytopathogenic microbial species like Sphingomonas leidyi and Alternaria argroxiphii. Each MLI system exhibited a unique composition of fungal and bacterial communities that shape belowground biodiversity, notably affecting soil attributes, plant well-being, disease control, and agroecological services. Indeed, soil physico-chemical properties, including pH, nitrogen, organic carbon, phosphorus, and potassium were enriched in MLI compared to MMC cropping systems. Thus, diversification of agroecosystems with MLI systems enhances soil properties and shifts rhizosphere and maize-root microbiome in favor of ecologically important microbial communities.

Description

DATA AVAILABILITY : The unprocessed sequencing datasets generated during the current study have been deposited in GenBank, NCBI under BioProject PRJNA1056154. The 16S (V3-V4, bacteria) and ITS (ITS1-ITS2, fungi) metagenome data were registered as Biosamples SAMN39455314–SAMN39455397 and the sequences assigned SRA accessions SRR27606564–SRR27606647.

Keywords

Crop diversification, Soil health, Microbial communities, Fungal and bacterial activity, Metabarcoding, Sustainable agriculture, Maize edible-legume intercropping (MLI)

Sustainable Development Goals

SDG-15: Life on land
SDG-02: Zero Hunger

Citation

Jalloh, A.A., Mutyambai, D.M., Yusuf, A.A. et al. 2024, 'Maize edible‑legumes intercropping systems for enhancing agrobiodiversity and belowground ecosystem services', Scientific Reports, vol. 14, no. 14355, pp. 1-19. https://doi.org/10.1038/s41598-024-64138-w.