Impact of <i>Ectropis grisescens</i> Warren (Lepidoptera: Geometridae) Infestation on the Tea Plant Rhizosphere Microbiome and Its Potential for Enhanced Biocontrol and Plant Health Management

Impact of <i>Ectropis grisescens</i> Warren (Lepidoptera: Geometridae) Infestation on the Tea Plant Rhizosphere Microbiome and Its Potential for Enhanced Biocontrol and Plant Health Management

The root-associated microbiome significantly influences plant health and pest resistance, yet the temporal dynamics of its compositional and functional change in response to <i>Ectropis grisescens</i> Warren (Lepidoptera: Geometridae) infestation remain largely unexplored. The study took...

Full description

Saved in:
Bibliographic Details
Main Authors: He Liu, Wei Chen, Xiaohong Fang, Dongliang Li, Yulin Xiong, Wei Xie, Qiulian Chen, Yingying You, Chenchen Lin, Zhong Wang, Jizhou Wang, Danni Chen, Yanyan Li, Pumo Cai, Chuanpeng Nie, Yongcong Hong
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Insects
Subjects:
<i>Camellia sinensis</i>
<i>Ectropis grisescens</i> Warren
rhizosphere microbiome
<i>Burkholderia</i>
transcriptomic analysis
metagenomic analysis
Online Access:https://www.mdpi.com/2075-4450/16/4/412
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The root-associated microbiome significantly influences plant health and pest resistance, yet the temporal dynamics of its compositional and functional change in response to <i>Ectropis grisescens</i> Warren (Lepidoptera: Geometridae) infestation remain largely unexplored. The study took samples of leaves, roots, and rhizosphere soil at different times after the plants were attacked by <i>E. grisescens</i>. These samples were analyzed using transcriptomic and high-throughput sequencing of 16S rRNA techniques. The goal was to understand how the plant’s defense mechanisms and the microbial community around the roots changed after the attack. Additionally, bacterial feedback assays were conducted to evaluate the effects of selected microbial strains on plant growth and pest defense responses. By conducting 16S rRNA sequencing on the collected soil samples, we found significant shifts in bacterial communities by the seventh day, suggesting a lag in community adaptation. Transcriptomic analysis revealed that <i>E. grisescens</i> attack induced reprogramming of the tea root transcriptome, upregulating genes related to defensive pathways such as phenylpropanoid and flavonoid biosynthesis. Metagenomic data indicated functional changes in the rhizosphere microbiome, with enrichment in genes linked to metabolic pathways and nitrogen cycling. Network analysis showed a reorganization of core microbial members, favoring nitrogen-fixing bacteria like <i>Burkholderia</i> species. Bacterial feedback assays confirmed that selected strains, notably <i>Burkholderia cepacia</i> strain ABC4 (T1) and a nine-strain consortium (T5), enhanced plant growth and defense responses, including elevated levels of flavonoids, polyphenols, caffeine, jasmonic acid, and increased peroxidase (POD) and superoxide dismutase (SOD) activities. This study emphasizes the potential of utilizing root-associated microbial communities for sustainable pest management in tea cultivation, thereby enhancing resilience in tea crops while maintaining ecosystem balance.
ISSN:2075-4450

Similar Items