Prebiotics: A Solution for Improving Plant Growth, Soil Health, and Carbon Sequestration?

Alahmad, Abdelrahman; Edelman, Lucas; Castel, Lisa; Bernardon-Mery, Aude; Laval, Karine; Trinsoutrot-Gattin, Isabelle; Thioye, Babacar

doi:10.1007/s42729-023-01517-8

Cited by 3 publications

(1 citation statement)

References 145 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Nevertheless, we did find that some associated bacteria are highly correlated with soil and plant nutrient characteristics. Among them, the abundance of Caulobacter [66], Peniophora [67,68], Nocardia [69], Lysinibacillus [70], and Brevundimonas [71] were significantly correlated with C, K, Ca, Mg, Fe, and Mn contents of plant roots, all of which are important microorganisms involved in respiratory metabolism and energy decomposition processes. Based on the differences in the abundance of element-related microbial communities among different provenances, N-related bacteria communities were significantly higher in JXSY than in other bacterial communities and provenances, indicating that F. hodginsii from JXSY may prioritize meeting its own N element requirements through root-associated bacteria.…”

Section: Discussionmentioning

confidence: 99%

Chemical and Microbial Differences of Root and Rhizosphere Soil among Different Provenances of Fokienia hodginsii

Liu,

Zhu,

Wen

et al. 2024

Forests

View full text Add to dashboard Cite

Aims: Fokienia hodginsii is a threatened conifer tree species, known as the dominant nursery-grown species capable of colonizing the challenging woodland environments in southern China due to its strong root penetrating ability. The ecological phenotype of Fokienia hodginsii is not well documented during its breeding process, which limits the potential planting area and its ecological function. This study aims to understand how Fokienia hodginsii associates with microbes to conduct its key ecological function and provide a theoretical basis for further improving the forest nursery management of Fokienia hodginsii. Methods: This study explored the ecological traits of 11 main Fokienia hodginsii provenances in a homogeneous garden experiment by analyzing their nutrient utilization strategies and associated microbial features in the rhizosphere soil and roots. Results: The study found that the paramount difference in the rhizosphere soil among provenances is in Ca and Fe content. Some microbial communities, namely Crenarchaeota, Verrucomicrobiota, and Desulfobacterota, were positively correlated with the amounts of the soil nutrient elements, whereas Abditibacteriota and Dependentiae were negatively correlated. The abundance of N- and Fe-related bacteria in the Fu Jian Chang Ting (FJCT) provenance was significantly higher than that in other provenances, while the C-, P-, K-, and Mg-related fungal communities, respectively, had higher abundances in the FJCT, Fu Jian Long Yan (FJLY), Fu Jian Gu Tian (FJGT), and Fu Jian Xian You (FJXY) provenances than the others. The impacts of the Gui Zhou Li Ping (GZLP), Hu Nan Dao Xian (HNDX), Jiang Xi Shang Yao (JXSY), and Guang Dong Shi Xing (GDSX) provenances on the rhizosphere soil are similar, but the differences in nutrient utilization arise from the plant itself. Conversely, the root nutrient contents of the FJCT, Fu Jian You Xi (FJYX), Fu Jian An Xi (FJAX), FJLY, Fu Jian De Hua (FJDH), FJGT, and FJXY provenances are highly correlated with soil nutrient features. Conclusions: For the native provenances, their economic traits are better than the exotic provenances. The native provenances are more sensitive to local soil conditions, so they should benefit more from human interventions, rendering them more suitable for artificial cultivation. The growth of the exotic provenances is less affected by the soil environment, making them better suited for the ecological transformation of forest stands and soil improvement.

show abstract

Section: Discussionmentioning

confidence: 99%

Chemical and Microbial Differences of Root and Rhizosphere Soil among Different Provenances of Fokienia hodginsii

Liu,

Zhu,

Wen

et al. 2024

Forests

View full text Add to dashboard Cite

show abstract

Engineering agricultural soil microbiomes and predicting plant phenotypes

Berruto,

Demirer

2024

Trends in Microbiology

View full text Add to dashboard Cite

Unveiling the Impact of Soil Prebiotics on Rhizospheric Microbial Functionality in Zea mays L.

Alahmad,

Edelman,

Bouteiller

et al. 2024

Agriculture

View full text Add to dashboard Cite

Prebiotics, a subset of biostimulants, have garnered attention for their potential to enhance soil conditions and promote plant growth, offering a promising alternative to conventional agricultural inputs. This study explores how two commercial prebiotics, K1® and NUTRIGEO L® (SPK and SPN), impact soil functions compared to a control (SP). The experiment involved agricultural soil amended with organic wheat straws and cultivated with Zea mays L. Previous research demonstrated substantial effects of these prebiotics on plant biomass, soil parameters, and microbial community ten weeks after application. The present study delves deeper, focusing on soil microbial abundance, enzyme activities, and metabolic diversity. Analysis revealed that SPN notably increased the fungi-to-bacteria ratio, and both prebiotics elevated the activity of several key enzymes. SPN enhanced α-glucosidase and β-galactosidase activities, while SPK increased arylsulfatase, phosphatase, alkaline phosphatase, and urease activities. Enzymatic indexes confirmed the positive impact on soil functional diversity and fertility. Additionally, prebiotic treatments showed distinct metabolic profiles, with SPK degrading eleven carbon sources more rapidly across five groups and SPN accelerating the decomposition rate of four carbon sources from three groups. These findings highlight the ability of prebiotics to shape microbial communities and enhance soil fertility by modulating their functional activity and diversity.

show abstract

Prebiotics: A Solution for Improving Plant Growth, Soil Health, and Carbon Sequestration?

Cited by 3 publications

References 145 publications

Chemical and Microbial Differences of Root and Rhizosphere Soil among Different Provenances of Fokienia hodginsii

Chemical and Microbial Differences of Root and Rhizosphere Soil among Different Provenances of Fokienia hodginsii

Engineering agricultural soil microbiomes and predicting plant phenotypes

Unveiling the Impact of Soil Prebiotics on Rhizospheric Microbial Functionality in Zea mays L.

Contact Info

Product

Resources

About