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Autori principali: Zhang, Zhi-Feng, Hou, Jun-Jie, Lin, Jing-Wei, Li, Meng
Natura: Artículo científico
Lingua:en
Pubblicazione: Applied microbiology and biotechnology 2026
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Accesso online:https://pubmed.ncbi.nlm.nih.gov/41761001/
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author Zhang, Zhi-Feng
Hou, Jun-Jie
Lin, Jing-Wei
Li, Meng
author_facet Zhang, Zhi-Feng
Hou, Jun-Jie
Lin, Jing-Wei
Li, Meng
Zhang, Zhi-Feng
Hou, Jun-Jie
Lin, Jing-Wei
Li, Meng
collection PubMed - marine biology
contents Fusarium enrichment alters the soil microbial community and network structure of Brassica crops. Zhang, Zhi-Feng Hou, Jun-Jie Lin, Jing-Wei Li, Meng Fusarium Soil Microbiology Brassica Plant Diseases Crops, Agricultural RNA, Ribosomal, 16S China Soil Fungi DNA, Ribosomal Spacer High-Throughput Nucleotide Sequencing Microbiota Bacteria Sequence Analysis, DNA Soil-borne microbial diseases constitute a significant constraint on crop production, causing substantial annual economic losses estimated at 40%-60% in agricultural sectors. This study aimed to identify the principal plant pathogens causing diseases in Brassica crops in Ningxia, China, and the factors and mechanisms of infection. Employing ITS and 16S rRNA gene high-throughput sequencing, we investigated the soil microbial community associated with both healthy and diseased Brassica crops, as well as other main crops. We detected significant abundances of the soil-borne pathogenic fungi Fusarium and Olpidium, with Fusarium markedly enriched in diseased soils, suggesting its potential role in pathogenesis. Furthermore, the disease presence induced substantial disturbance in the soil fungal community, whereas the prokaryotic community structure remained relatively unaffected. Spatial and environmental factors exerted a more pronounced influence on fungal communities than on prokaryotic communities, with disease incidence attenuating the impact of environmental variables on fungal assemblages. Further analysis revealed that soil properties positively drove Fusarium abundance, and this proliferation synergized with soil factors to reduce fungal evenness. This evenness loss, coupled with the pathogen's direct effect, ultimately led to network simplification and a vulnerable "low evenness-high complexity" state. Network analyses confirmed this vulnerability, showing heightened complexity but diminished stability in fungal networks within diseased soils. Collectively, our findings provide a theoretical and technical framework for the rapid identification and effective management of pathogens affecting Brassica crops. KEY POINTS: Fusarium is significantly and highly enriched in diseased Brassica soil. Fungal community exhibits distinct patterns in diseased Brassica soil. Diseased soil exhibits more complex, less stable fungal networks.
format Artículo científico
id pubmed_41761001
institution PubMed
language en
publishDate 2026
publisher Applied microbiology and biotechnology
record_format pubmed
spellingShingle Fusarium enrichment alters the soil microbial community and network structure of Brassica crops.
Zhang, Zhi-Feng
Hou, Jun-Jie
Lin, Jing-Wei
Li, Meng
Fusarium
Soil Microbiology
Brassica
Plant Diseases
Crops, Agricultural
RNA, Ribosomal, 16S
China
Soil
Fungi
DNA, Ribosomal Spacer
High-Throughput Nucleotide Sequencing
Microbiota
Bacteria
Sequence Analysis, DNA
Fusarium enrichment alters the soil microbial community and network structure of Brassica crops. Zhang, Zhi-Feng Hou, Jun-Jie Lin, Jing-Wei Li, Meng Fusarium Soil Microbiology Brassica Plant Diseases Crops, Agricultural RNA, Ribosomal, 16S China Soil Fungi DNA, Ribosomal Spacer High-Throughput Nucleotide Sequencing Microbiota Bacteria Sequence Analysis, DNA Soil-borne microbial diseases constitute a significant constraint on crop production, causing substantial annual economic losses estimated at 40%-60% in agricultural sectors. This study aimed to identify the principal plant pathogens causing diseases in Brassica crops in Ningxia, China, and the factors and mechanisms of infection. Employing ITS and 16S rRNA gene high-throughput sequencing, we investigated the soil microbial community associated with both healthy and diseased Brassica crops, as well as other main crops. We detected significant abundances of the soil-borne pathogenic fungi Fusarium and Olpidium, with Fusarium markedly enriched in diseased soils, suggesting its potential role in pathogenesis. Furthermore, the disease presence induced substantial disturbance in the soil fungal community, whereas the prokaryotic community structure remained relatively unaffected. Spatial and environmental factors exerted a more pronounced influence on fungal communities than on prokaryotic communities, with disease incidence attenuating the impact of environmental variables on fungal assemblages. Further analysis revealed that soil properties positively drove Fusarium abundance, and this proliferation synergized with soil factors to reduce fungal evenness. This evenness loss, coupled with the pathogen's direct effect, ultimately led to network simplification and a vulnerable "low evenness-high complexity" state. Network analyses confirmed this vulnerability, showing heightened complexity but diminished stability in fungal networks within diseased soils. Collectively, our findings provide a theoretical and technical framework for the rapid identification and effective management of pathogens affecting Brassica crops. KEY POINTS: Fusarium is significantly and highly enriched in diseased Brassica soil. Fungal community exhibits distinct patterns in diseased Brassica soil. Diseased soil exhibits more complex, less stable fungal networks.
title Fusarium enrichment alters the soil microbial community and network structure of Brassica crops.
topic Fusarium
Soil Microbiology
Brassica
Plant Diseases
Crops, Agricultural
RNA, Ribosomal, 16S
China
Soil
Fungi
DNA, Ribosomal Spacer
High-Throughput Nucleotide Sequencing
Microbiota
Bacteria
Sequence Analysis, DNA
url https://pubmed.ncbi.nlm.nih.gov/41761001/