Affiliation:
1. Centre for Environmental and Marine Studies (CESAM), Department of Biology, University of Aveiro, 3810-193 Aveiro, Portugal
2. Tecniferti®, Rua de Ourém, Lote 14, 2º I, Almoinha Grande, 2416-903 Leiria, Portugal
Abstract
Advances in soil microbial communities are driving agricultural practices towards ecological sustainability and productivity, with engineering microbial communities significantly contributing to sustainable agriculture. This study explored the combined effects of two white-rot fungi (Trametes sp. and Pleurotus sp.) and six rhizobacterial strains belonging to four genera (Acinetobacter sp., Enterobacter sp., Flavobacterium sp., and Pseudomonas sp.) on maize growth and soil enzymatic activity over a 14-day period. At the plant level, germination, fresh and dry mass of the aerial and root parts, length, and stage of development of the stem, as well as the chlorophyll content, were evaluated. Furthermore, soil dehydrogenase, acid and alkaline phosphatases, pH, and electrical conductivity were evaluated. Rot fungi induced distinct effects on maize germination, with Pleurotus sp. strongly suppressing maize germination by 40% relative to that of the control. The isolated bacterial strains, except Enterobacter sp. O8, and 8 of the 12 fungus + bacterial strain combinations induced germination rates higher than those of the control (≥40%). Combinations of Flavobacterium sp. I57 and Pseudomonas sp. O81 with the rot fungus Pleurotus sp. significantly improved plant shoot length (from 28.0 to 37.0 cm) and developmental stage (fourth leaf length increase from 10.0 to 16.8 cm), respectively, compared with the same bacteria alone or in combination with the rot fungus Trametes sp. In the soil, the presence of both fungi appeared to stabilize phosphatase activity compared to their activity when only bacteria were present, while also promoting overall dehydrogenase enzymatic activity in the soil. Integrating all parameters, Trametes sp. rot fungus + Enterobacter sp. O8 may be a potential combination to be explored in the context of agricultural production, and future studies should focus on the consistency of this combination’s performance over time and its effectiveness in the field.
Funder
MIRACLE project
Foundation for Science and Technology
FCT/MCTES
Reference49 articles.
1. European Commission (2024, May 13). Questions and Answers on a Directive on Soil Monitoring and Resilience. Available online: https://ec.europa.eu/commission/presscorner/detail/en/qanda_23_3637.
2. The soil crisis: The need to treat as a global health problem and the pivotal role of microbes in prophylaxis and therapy;Timmis;Microb. Biotechnol.,2021
3. Targeting the soil quality and soil health concepts when aiming for the United Nations Sustainable Development Goals and the EU Green Deal;Bonfante;Soil Discuss.,2020
4. Forward-looking on new microbial consortia: Combination of rot fungi and rhizobacteria on plant growth-promoting abilities;Carneiro;Appl. Soil Ecol.,2023
5. Khan, A., Singh, A.V., Gautam, S.S., Agarwal, A., Punetha, A., Upadhayay, V.K., Kukreti, B., Bundela, V., Jugran, A.K., and Goel, R. (2023). Microbial bioformulation: A microbial assisted biostimulating fertilization technique for sustainable agriculture. Front. Plant Sci., 14.