Secretome Analysis and In Planta Expression of Salivary Proteins Identify Candidate Effectors from the Brown Planthopper <i>Nilaparvata lugens</i>

Rao, Weiwei; Zheng, Xiaohui; Liu, Bingfang; Guo, Qin; Guo, Jianping; Wu, Yan; Shangguan, Xinxin; Wang, Huiying; Wu, Di; Wang, Zhizheng; Hu, Liang; Xu, Chunxue; Jiang, Weihua; Huang, Jin; Shi, Shaojie; He, Guangcun

doi:10.1094/mpmi-05-18-0122-r

Cited by 53 publications

(75 citation statements)

References 75 publications

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“…The C‐terminal region of this protein induces defense responses in plant cells, including cell death, the expression of pathogen‐responsive genes, and callose deposition (Shangguan et al, ). Salivary sheaths directly contact with plant cell after secretion and are easier sharped by natural selection (Rao et al, ). Because of their “forward” role in herbivore–plant interactions, salivary sheaths may undergo a higher evolution rate than other salivary components.…”

Section: Function Of Saliva In Planthopper–plant Interactionsmentioning

confidence: 99%

“…Suppression of ANX‐5 has negative effects on planthopper feeding (Huang et al, ). Interestingly, ANXs, which constitute the second largest protein family in N. lugens (Rao et al, ), do not possess typical annexin structure. These secretory ANX structures have so far been found only in planthopper species, indicating that ANXs were important in planthopper–plant coevolution.…”

Section: Function Of Saliva In Planthopper–plant Interactionsmentioning

confidence: 99%

“…Among 64 tested salivary proteins, 6 were identified as candidate effector proteins (Table ). The salivary proteins Nl12, Nl16, Nl28, and Nl43 induced cell death in N. benthamiana , whereas Nl40 induced chlorosis and Nl32 induced a dwarf phenotype (Rao et al, ). However, the exact function of these candidate effectors and recognizing mechanism in plants remain to be elucidated.…”

Section: Function Of Saliva In Planthopper–plant Interactionsmentioning

confidence: 99%

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How does saliva function in planthopper–host interactions?

Huang

Zhang

Hong

2019

Arch Insect Biochem Physiol

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Planthoppers are highly destructive pests that damage rice plants by feeding and transmitting viruses. They feed on phloem sap using specialized mouthparts and secrete saliva during feeding. Over the past decade, genomic, transcriptomic, and proteomic approaches have greatly improved our understanding of the complexity of planthopper saliva, and have provided a glimpse of planthopper-plant interactions. Here we focus on a few recent advances in planthopper saliva and discuss how salivary components influence planthopper performance. Understanding the molecular basis of saliva in planthopper-plant interactions will provide evolutionary insights, and promote the development of novel strategies for controlling agricultural pests. K E Y W O R D S host-plant relationship, planthopper, saliva

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Section: Function Of Saliva In Planthopper–plant Interactionsmentioning

confidence: 99%

Section: Function Of Saliva In Planthopper–plant Interactionsmentioning

confidence: 99%

Section: Function Of Saliva In Planthopper–plant Interactionsmentioning

confidence: 99%

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How does saliva function in planthopper–host interactions?

Huang

Zhang

Hong

2019

Arch Insect Biochem Physiol

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“…Many insect effectors have been described over the years as from saliva or salivary gland proteomic and transcriptomic data [27][28][29][30][31] . To unveil the actions of effector proteins on insect-hosts interactions, RNA interference (RNAi) has been applied.…”

mentioning

confidence: 99%

Gene silencing of Diaphorina citri candidate effectors promotes changes in feeding behaviors

Pacheco

Galdeano

Maluta

et al. 2020

Sci Rep

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Insect effectors are mainly secreted by salivary glands, modulate plant physiology and favor the establishment and transmission of pathogens. Feeding is the principal vehicle of transmission of Candidatus Liberibacter asiaticus (Ca. Las) by the Asian citrus psyllid (ACP), Diaphorina citri. This study aimed to predict putative ACP effectors that may act on the Huanglongbing (HLB) pathosystem. Bioinformatics analysis led to the identification of 131 candidate effectors. Gene expression investigations were performed to select genes that were overexpressed in the ACP head and modulated by Ca. Las. To evaluate the actions of candidate effectors on D. citri feeding, six effectors were selected for gene silencing bioassays. Double-stranded RNAs (dsRNAs) of the target genes were delivered to D. citri adults via artificial diets for five days. RNAi silencing caused a reduction in the ACP lifespan and decreased the salivary sheath size and honeydew production. Moreover, after dsRNA delivery of the target genes using artificial diet, the feeding behaviors of the insects were evaluated on young leaves from citrus seedlings. These analyses proved that knockdown of D. citri effectors also interfered with ACP feeding abilities in planta, causing a decrease in honeydew production and reducing ACP survival. Electrical penetration graph (EPG) analysis confirmed the actions of the effectors on D. citri feeding behaviors. These results indicate that gene silencing of D. citri effectors may cause changes in D. citri feeding behaviors and could potentially be used for ACP control. Insect pests are one of the main factors that reduce agricultural plant productivity. Global losses caused by these animals reach 220 billion dollars annually 1. In addition to the damage caused by their actions, problems caused by insects can be increased by the transmission of several plant pathogens 2. Asian citrus psyllid (ACP), Diaphorina citri Kuwayama (Hemiptera: Liviidae), stands out as the most important agricultural pest among citrus crops 3. ACP is a vector for the bacteria Candidatus Liberibacter asiaticus (Ca. Las), the causal agent of Huanglongbing (HLB). This disease affects all commercial citrus varieties by promoting plant decline and reducing fruit quality 4,5. In the last fifteen years, HLB has spread quickly across the American continent and the citrus production in the USA declined 58% 4. In Brazil, 34 million citrus trees have been removed since the first detection of HLB in 2004 6. So far, no efficient control for HLB has been found. Disease management consists of producing seedlings using Ca Las-free nursery stock, removal of infected trees and insecticide applications for vector control 7,8. However, the extensive application of insecticides could select for ACP-resistant populations 9-11. Diaphorina citri acquire Ca. Las via a circulative-persistent manner during feeding 12,13. The efficiency of Ca. Las transmission is affected by the duration of phloem ingestion by ACP 14. Studies have been developed to understand the interactions ...

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“…S4c). This suggested that the salivary DNase II may function differently from other salivary effectors such as Nl12, Nl40, Nl16, Nl28 and Nl43 (Rao et al, 2019).…”

Section: Researchmentioning

confidence: 99%

Salivary DNase II from Laodelphax striatellus acts as an effector that suppresses plant defence

et al. 2019

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Summary Extracellular DNA, released by damaged plant cells, acts as a damage‐associated molecular pattern (DAMP). We demonstrated previously that the small brown planthopper (Laodelphax striatellus, SBPH) secreted DNase II when feeding on artificial diets. However, the function of DNase II in insect feeding remained elusive. The influences of DNase II on SBPHs and rice plants were investigated by suppressing expression of DNase II or by application of heterogeneously expressed DNase II. We demonstrated that DNase II is mainly expressed in the salivary gland and is responsible for DNA‐degrading activity of saliva. Knocking down the expression of DNase II resulted in decreased performance of SBPH reared on rice plants. The dsDNase II‐treated SBPH did not influenced jasmonic acid (JA), salicylic acid (SA), ethylene (ET) pathways, but elicited a higher level of H2O2 and callose accumulation. Application of heterogeneously expressed DNase II in DNase II‐deficient saliva slightly reduced the wound‐induced defence response. We propose a DNase II‐based invading model for SBPH feeding on host plants, and provide a potential target for pest management.

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Secretome Analysis and In Planta Expression of Salivary Proteins Identify Candidate Effectors from the Brown Planthopper Nilaparvata lugens

Cited by 53 publications

References 75 publications

How does saliva function in planthopper–host interactions?

How does saliva function in planthopper–host interactions?

Gene silencing of Diaphorina citri candidate effectors promotes changes in feeding behaviors

Salivary DNase II from Laodelphax striatellus acts as an effector that suppresses plant defence

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