Transcriptome Profiling Revealed Potentially Critical Roles for Digestion and Defense-Related Genes in Insects' Use of Resistant Host Plants: A Case Study with Sitobion Avenae.

Da Wang,Xiaoqin Shi,Deguang Liu,Zheming Shang,Yujing Yang

doi:10.3390/insects11020090

Da Wang, Xiaoqin Shi + Show 3 more

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https://doi.org/10.3390/insects11020090

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Journal: Insects	Publication Date: Jan 30, 2020
Citations: 6	License type: CC BY 4.0

Affiliation: North West Agriculture and Forestry University

Abstract

Using host plant resistance (HPR) in management of insect pests is often environmentally friendly and suitable for sustainable development of agricultural industries. However, this strategy can be limited by rapid evolution of insect populations that overcome HPR, for which the underlying molecular factors and mechanisms are not well understood. To address this issue, we analyzed transcriptomes of two distinct biotypes of the grain aphid, Sitobion avenae (Fabricius), on wheat and barley. This analysis revealed a large number of differentially expressed genes (DEGs) between biotypes 1 and 3 on wheat and barley. The majority of them were common DEGs occurring on both wheat and barley. GO and KEGG enrichment analyses for these common DEGs demonstrated significant expression divergence between both biotypes in genes associated with digestion and defense. Top defense-related common DEGs with the most significant expression changes included three peroxidases, two UGTs (UDP-glycosyltransferase), two cuticle proteins, one glutathione S-transferases (GST), one superoxide dismutase, and one esterase, suggesting their potentially critical roles in the divergence of S. avenae biotypes. A relatively high number of specific DEGs on wheat were identified for peroxidases (9) and P450s (8), indicating that phenolic compounds and hydroxamic acids may play key roles in resistance of wheat against S. avenae. Enrichment of specific DEGs on barley for P450s and ABC transporters suggested their key roles in this aphid’s detoxification against secondary metabolites (e.g., alkaloids) in barley. Our results can provide insights into the molecular factors and functions that explain biotype adaptation in insects and their use of resistant plants. This study also has significant implications for developing new resistant cultivars, developing strategies that limit rapid development of insect biotypes, and extending resistant crop cultivars’ durability and sustainability in integrated management programs.

Highlights

In the constantly changing agricultural landscape, effective management of various insect pests often presents huge challenges
We identified 16 common differentially expressed genes (DEGs) related to digestion, and 40 to defense that could be involved in the biotype divergence process in S. avenae
Our study revealed a large number of digestive and defensive DEGs between S. avenae biotypes on both wheat and barley, suggesting that digestive and defensive enzymes could facilitate adaptations of S. avenae populations to changes in host plant chemistry

Summary

Introduction

In the constantly changing agricultural landscape, effective management of various insect pests often presents huge challenges. Insects 2020, 11, 90 host plant resistance can provide many benefits, such as economic savings, promotions of natural and biological control, and a decrease in potentially hazardous insecticide applications [1,2]. This pest management strategy developed from naturally evolved plant defenses is often environmentally friendly and suitable for sustainable development of agricultural industries, and it can be very valuable in the integrated management of insect pests for various agricultural crops [1,3]. One of the most serious challenges to the use of resistant crops against various insect pests is the rapid development of new biotypes [5]

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