Your search keyword '"Jiazhu Jiang"' showing total 2 results

1. Isolation, identification, and mechanism analysis of plant growth-promoting rhizobacteria in tobacco

Author

Chuandong Jiang, Fuyu Peng, Li Zhang, Yuqin Zhang, Jie Wang, Junmin Li, Binghui Cui, Changdai Cao, Chengqiang Wang, Yunlei Qin, Ran Wang, Zongpeng Zhao, Jiazhu Jiang, Mingfeng Yang, Mingming Sun, Long Yang, and Qiang Zhang

Subjects

growth and development, microbiome and metagenomic analysis, plant growth-promoting rhizobacteria, tobacco, soil improvement, Microbiology, QR1-502

Abstract

Plant growth, crop yield, and pest and disease control are enhanced by PGPR (Plant growth promoting rhizobacteria), which are beneficial microorganisms found in a close symbiosis with plant roots. Phytohormones are secreted, nutrient uptake is improved, and soil properties along with the microbiological environment are regulated by these microorganisms, making them a significant focus in agricultural research. In this study, the efficient PGPR strain T1 was isolated and screened from tobacco inter-root soil, and identified and confirmed by ITS sequencing technology. Tobacco growth indicators and soil property changes were observed and recorded through potting experiments. The activities of key enzymes (e.g., sucrase, catalase, urease) in soil were further determined. High-throughput sequencing technology was utilized to sequence the soil microbial community, and combined with macro-genomics analysis, the effects of T1 strain on soil microbial diversity and metabolic pathways were explored. Following the application of T1, significant improvements were observed in the height, leaf length, and width of tobacco plants. Furthermore, the physical and chemical properties of the soil were notably enhanced, including a 26.26% increase in phosphorus availability. Additionally, the activities of key soil enzymes such as sucrase, catalase, and urease were significantly increased, indicating improved soil health and fertility. Comprehensive joint microbiomics and macrogenomics analyses revealed a substantial rise in the populations of beneficial soil microorganisms and an enhancement in metabolic pathways, including amino acid metabolism, synthesis, and production of secondary metabolites. These increase in beneficial microorganisms and the enhancement of their metabolic functions are crucial for plant growth and soil fertility. This study provides valuable references for the development of innovative microbial fertilizers and offers programs for the sustainable development of modern agriculture.

Published

2024

2. Degradation and mechanism analysis of protein macromolecules by functional bacteria in tobacco leaves

Author

Chuandong Jiang, Decai Kong, Yangyang Li, Jingguo Sun, Zhenguo Chen, Mingfeng Yang, Shoutao Cao, Cunfeng Yu, Zengyu Wang, Jiazhu Jiang, Chengguang Zhu, Nan Zhang, Guangwei Sun, and Qiang Zhang

Subjects

tobacco, protein degradation, functional bacteria, mechanism analysis, curing, Microbiology, QR1-502

Abstract

Tobacco, a crop of significant economic importance, was greatly influenced in leaf quality by protein content. However, current processing parameters fail to adequately meet the requirements for protein degradation. Microorganisms possess potential advantages for degrading proteins and enhancing the quality of tobacco leaves, and hold substantial potential in the process of curing. To effectively reduce the protein content in tobacco leaves, thereby improving the quality and safety of the tobacco leaves. In this study, tobacco leaf were used as experimental material. From these, the BSP1 strain capable of effectively degrading proteins was isolated and identified as Bacillus subtilis by 16S rDNA analysis. Furthermore, the mechanisms were analyzed by integrating microbiome, transcriptome, and metabolome. Before curing, BSP1 was applied to the surface of tobacco leaves. The results indicated that BSP1 effectively improves the activity of key enzymes and the content of related substances, thereby enhancing protein degradation. Additionally, protein degradation was achieved by regulating the diversity of the microbial community on the surface of the tobacco leaves and the ubiquitin-proteasome pathway. This study provided new strategies for extracting and utilizing functional strains from tobacco leaves, opening new avenues for enhancing the quality of tobacco leaves.

Published

2024