Abstract
In our former research, we succeeded in using agar, alginate, and perlite as immobilization materials to maintain long-term survival of the inoculant, Ensifer fredii LP2/20, in a controlled glasshouse. Therefore the information on the establishment and activity of the inoculant to promote plant growth under field conditions, the effects of the inoculant on the soil microbial communities and specific microbial taxa, and the association between the inoculant and soil elements merit further studies. Here, we found that agar was the most suitable material that supported the establishment of the inoculant under field conditions. RNA-based analysis showed that E. fredii LP2/20 immobilized in agar was still metabolically active at day 50 after being introduced into soil. Inoculation of E. fredii LP2/20 immobilized in agar conferred the highest plant dry weight (up to 89.94%) and all plant elements including total N (9.55%), P (17.94%), K (68.42%), Ca (39.77%), Mg (30.76%), Fe (29.85%), and Zn (22.44%). Inoculation of E. fredii LP2/20 immobilized in agar increased soil chemicals including soil organic matter (99.02%), total N (272.48%), P (31.75%), K (52.74%), Fe (51.06%), and Zn (63.10%). High-throughput next-generation sequencing of bacterial 16S rRNA amplicons showed that the Proteobacteria, Acidobacteria, Bacteroidetes, and Firmicutes were dominant phyla in Chinese kale field soil. Inoculation of E. fredii LP2/20 significantly affected the soil bacterial community structure by decreasing total bacterial richness and diversity. The numbers of alpha- and gamma-Proteobacteria were significantly increased while the number of delta-Proteobacteria was significantly decreased due to E. fredii LP2/20 establishment. Soil total P, K, and Ca and soil pH were the important factors that shaped the soil bacterial community composition.
Highlights
Nowadays, modern agricultural practices focus on the use of biofertilizers to move towards agricultural and environmental sustainability
We conducted the experiment to examine: (1) the potential of using E. fredii LP2/20 immobilized in agar, alginate, and perlite to promote plant growth under field conditions, (2) the influence of E. fredii LP2/20 immobilized in agar, alginate, and perlite on plant nutrients and soil elements, (3) the effect of using E. fredii LP2/20 immobilized in agar, alginate, and perlite on the soil bacterial community structure assessed by highthroughput sequencing of 16S rRNA gene amplicons as well as (4) the changes in the abundance and associations of bacterial taxa in response to soil environmental factors
Our results show the new potential use of E. fredii LP2/20 immobilized in agar as a bacterial biofertilizer to promote plant growth and increase plant nutrition and soil fertility in the field
Summary
Modern agricultural practices focus on the use of biofertilizers to move towards agricultural and environmental sustainability. Our former research had been conducted to determine the potential of using agar and alginate compared with perlite, which is currently used in biofertilizer production, as cell immobilization materials for maintaining longterm survival of the inoculants strain in a controlled glasshouse and reducing the production cost. In a former research we succeeded in using agar, alginate, and perlite as cell immobilization materials to maintain long-term survival of E. fredii LP2/20 that produced high amounts of plant stimulants including indole acetic acid (IAA) (42.71 ± 0.85 μg/ml) and ammonia (0.79 ± 0.01 mM) in a controlled glasshouse. Our experiments were carried out with the expectation of moving towards an environmentally friendly manner for sustainable development
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