A novel effector of Aphelenchoides besseyi, AbPFN3, interacts with multiple host proteins to assist parasitic nematode and maintain infection in rice

doi:10.1016/j.jia.2024.08.013

Advanced Online Publication | Current Issue | Archive | Adv Search

A novel effector of Aphelenchoides besseyi, AbPFN3, interacts with multiple host proteins to assist parasitic nematode and maintain infection in rice

Xin Huang^{1, 3}, Yuankai Chi¹, Wei Zhao¹, Wenkun Huang², Deliang Peng^2#, Rende Qi^1#

¹ Institute of Plant Protection and Agro-products Safety, Anhui Academy of Agricultural Sciences, Hefei 230031, China

² State Key Laboratory for Biology of Plant Diseases and Insect Pests, Institute of Plant Protection, Chinese Academy of Agricultural Sciences, Beijing 100193, China

³Institute of Plant Protection, Xinjiang Academy of Agricultural Sciences, Urumqi 830091, China

Abstract
References

Download: PDF in ScienceDirect
Export: BibTeX | EndNote (RIS)

摘要

水稻干尖线虫（Aphelenchoides besseyi）可侵染水稻、大豆、棉花等多种作物，给农业生产造成严重损失。目前水稻干尖线虫效应子的研究较少，该线虫的侵染分子机制仍不明确。研究水稻干尖线虫的致病分子机理，找到致病的关键靶标，对于水稻干尖线虫绿色防控技术的开发具有重要的意义。本研究使用原位杂交、qPCR、Co-IP/MS、BiFC、转基因过表达等技术对水稻干尖线虫分泌的一个关键致病效应子AbPFN3的功能进行了解析。AbPFN3基因全长381 bp，编码氨基酸长度126 aa。序列分析显示，AbPFN3与马铃薯白线虫的GpPFN3的序列相似性最高，为59.52%；AbPFN3具有典型的profilin蛋白结构域，但不具有信号肽和跨膜结构域。通过qPCR证实了AbPFN3在幼虫中高表达，使用原位杂交的方法得出AbPFN3是一个在食道腺特异表达的基因。亚细胞定位显示，AbPFN3被定位于内质网、叶绿体等多个细胞器上。使用Co-IP/MS、pull-down和BiFC等方法探究AbPFN3与寄主蛋白的互作，明确了水稻中与AbPFN3存在互作关系的蛋白有OsAAC1、OsBAP31和OsSAUR50，同时确定了这种互作发生在内质网、细胞质和质膜等多个细胞器中。在拟南芥中稳定表达AbPFN3基因后，植株的表型产生了明显变化，转基因拟南芥的株高显著高于野生型。在基因表达层面，转基因拟南芥中AAC1和BAP31基因的表达量显著上调，相反RGA2和SAUR50的表达量显著下调。综上所述，水稻干尖线虫AbPFN3是一个由食道腺分泌的效应子，与多个寄主蛋白存在互作关系，可能通过影响寄主的细胞发育、防卫反应、能量运输等过程促进水稻干尖线虫的侵染。本研究丰富了对水稻干尖线虫效应子分子互作模式的认识，证实了水稻干尖线虫的效应子可以通过与多个寄主蛋白的互作对寄主的多个生物学过程进行调控，进而促进线虫的侵染和寄生。

Abstract

The rice white tip nematode (RWTN) Aphelenchoides besseyi secretes effectors that manipulate the cells of its host plant and help the nematode to successfully parasitize and maintain infection in the host. The number of identified RWTN effectors is limited, and the mechanisms of RWTN effectors interacting with plants are largely unknown. Profilins (PFNs) function as hubs that control a complex network of molecular interactions. To gain full knowledge of PFN3 in plant parasitic nematodes, we identified an effector from A. besseyi named AbPFN3. AbPFN3 is transcriptionally upregulated in the juvenile stage of the nematode. In situ hybridization experiments showed that AbPFN3 transcribed in the nematode esophageal glands. Three AbPFN3-interacting proteins (OsAAC1, OsBAP31 and OsSAUR50) were found in the host plant, with interactions occurring in various locations such as the endoplasmic reticulum, cytoplasm, and plasma membrane. Transgenic analyses showed that the expression of AbPFN3 significantly increased plant height and upregulated the expression of AAC1 and BAP31 while downregulating RGA2 and SAUR50. This study describes a new effector protein, AbPFN3, secreted by A. besseyi, that interacts with multiple host proteins. These results suggest the important role of AbPFN3 in host defense response and cell development process.

Keywords: Aphelenchoides besseyi profilin 3 protein-protein interactions effector

Online: 22 August 2024

Fund:

This work was supported by the National Natural Science Foundation of China (32001881).

About author: #Correspondence Deliang Peng, E-mail: pengdeliang@caas.cn; Rende Qi, E-mail: rende7@126.com

	Service
	E-mail this article
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors

Cite this article:

Xin Huang, Yuankai Chi, Wei Zhao, Wenkun Huang, Deliang Peng, Rende Qi. 2024. A novel effector of Aphelenchoides besseyi, AbPFN3, interacts with multiple host proteins to assist parasitic nematode and maintain infection in rice. Journal of Integrative Agriculture, Doi:10.1016/j.jia.2024.08.013

An L, Zhang S, Guo P, Song L, Xie C, Guo H, Fang R, Jia Y. 2022. RIR1 represses plant immunity by interacting with mitochondrial complex I subunit in rice. Molecular Plant Pathology, 23, 92-103.

Atabekova A K, Pankratenko A V, Makarova S S, Lazareva E A, Owens R A, Solovyev A G, Morozov S Y. 2017. Phylogenetic and functional analyses of a plant protein related to human B-cell receptor-associated proteins. Biochimie, 132, 28-37.

Bobay B G, DiGennaro P, Scholl E, Imin N, Djordjevic M A, Bird D Mck. 2013. Solution NMR studies of the plant peptide hormone CEP inform function. FEBS Letters, 587, 3979-3985.

Chen J, Lin B, Huang Q, Hu L, Zhuo K, Liao J. 2017. A novel Meloidogyne graminicola effector, MgGPP, is secreted into host cells and undergoes glycosylation in concert with proteolysis to suppress plant defenses and promote parasitism. PLoS Pathogens, 13, e1006301.

Chen J, Hu L, Sun L, Lin B, Huang K, Zhuo K, Liao J. 2018. A novel Meloidogyne graminicola effector, MgMO237, interacts with multiple host defence‐related proteins to manipulate plant basal immunity and promote parasitism. Molecular Plant Pathology, 19, 1942-1955.

De Almeida Engler J, Van Poucke K, Karimi M, Groodt R D, Gheysen G, Engler G, Gheysen G. 2004. Dynamic cytoskeleton rearrangements in giant cells and syncytia of nematode‐infected roots. The Plant Journal, 38, 12-26.

De Boer J M, Yan Y, Smant G, Davis E L, Baum T J. 1998. In-situ hybridization to messenger RNA in Heterodera glycines. Journal of Nematology, 30, 309–312.

Diedrich G, Spahn C M T, Stelzl U, Schäfer M A, Wooten T, Bochkariov D E, Cooperman B S, Traut R R, Nierhaus K H. 2000. Ribosomal protein L2 is involved in the association of the ribosomal subunits, tRNA binding to A and P sites and peptidyl transfer. The EMBO Journal, 19, 5241-5250.

Dubreuil, G., Deleury, E., Magliano, M., Jaouannet M, Abad P, Rosso M N. 2011. Peroxiredoxins from the plant parasitic root-knot nematode, Meloidogyne incognita, are required for successful development within the host. International Journal for Parasitology, 41, 385–396.

Dubreuil G, Magliano M, Deleury E, Abad P, Rosso M N. 2007. Transcriptome analysis of root-knot nematode functions induced in the early stages of parasitism. New Phytologist, 176, 426-436.

Espada M, Eves-van den Akker S, Maier T, Vijayapalani P, Baum T, Mota M, Jones J T. 2018. STATAWAARS: a promoter motif associated with spatial expression in the major effector-producing tissues of the plant-parasitic nematode Bursaphelenchus xylophilus. BMC Genomics, 19, 1-13.

Eves-van den Akker S, Lilley C J, Jones J T, Urwin P E. 2014. Identification and characterisation of a hyper-variable apoplastic effector gene family of the potato cyst nematodes. PLoS Pathogens, 10, e1004391.

Eves-van den Akker S, Birch P R J. 2016. Opening the effector protein toolbox for plant–parasitic cyst nematode interactions. Molecular Plant, 9, 1451-1453.

Favoreto L, Faleiro V O, Freitas M A, Brauwers L R, Galbieri R, Homiak J A, Lopes-Caitar V S, Marcelino-Guimarães F C, Meye M C. 2018. First report of Aphelenchoides besseyi infecting the aerial part of cotton plants in Brazil. Plant Disease, 102, 2662.

Fiore C, Trezeguet V, Le Saux A, Roux P, Schwimmer C, Dianoux A C, Noel F, Lauquin GJ-M, Brandolin G, Vignais PV. 1998. The mitochondrial ADP/ATP carrier: structural, physiological and pathological aspects. Biochemie, 80, 137-150.

Fu J, Momčilović I, Prasad P V. 2012. Roles of protein synthesis elongation factor EF-Tu in heat tolerance in plants. Journal of Botany, 2012, 835836.

Halperin T, Zheng B, Itzhaki H, Clarke A K, Adam Z. 2001. Plant mitochondria contain proteolytic and regulatory subunits of the ATP-dependent Clp protease. Plant Molecular Biology, 45, 461-468.

Hamamouch N, Li C, Hewezi T, Baum T J, Mitchum M G, Hussey R S, Vodkin L O, Davis E L. 2012. The interaction of the novel 30C02 cyst nematode effector protein with a plant b-1,3-endoglucanase may suppress host defence to promote parasitism. Journal of Experimental Botany, 63, 3683-3695.

He F, Chen S, Ning Y, Wang G L. 2016. Rice (Oryza sativa) protoplast isolation and its application for transient expression analysis. Current Protocols in Plant Biology, 1, 373-383.

Hewezi T, Howe P J, Maier T R, Hussey R S, Mitchum M G, Davis E L, Baum T J. 2010. Arabidopsis spermidine synthase is targeted by an effector protein of the cyst nematode Heterodera schachtii. Plant Physiology, 152, 968-984.

Huang X, Xu C L, Yang S H, Li J Y, Wang H L, Zhang Z X, Chen C, Xie H. 2019. Life-stage specifc transcriptomes of a migratory endoparasitic plant nematode, Radopholus similis elucidate a diferent parasitic and life strategy of plant parasitic nematodes. Scientific Reports, 9: 6277.

Huang X, Chi Y K, Birhan A A, Zhao W, Qi R D, Peng D L. 2022. The new effector AbSCP1 of foliar nematode (Aphelenchoides besseyi) is required for parasitism rice. Journal of Integrative Agriculture, 21, 1084-1093.

Jaouannet M, Magliano M, Arguel M J, Gourgues M, Evangelisti E, Abad P, Rosso M N. 2013. The root-knot nematode calreticulin Mi-CRT is a key effector in plant defense suppression. Molecular Plant-Microbe Interactions, 26, 97-105.

Jaubert S, Laffaire J B, Ledger T N, Escoubas P, Amri E Z, Abad P, Rosso M N. 2004. Comparative analysis of two 14-3-3 homologues and their expression pattern in the root-knot nematode Meloidogyne incognita. International Journal for Parasitology, 34, 873-880.

Ji H, Xie J, Han Z. Yang F, Yu W, Peng Y, Qing Xue. 2023. Complete genome sequencing of nematode Aphelenchoides besseyi, an economically important pest causing rice white-tip disease. Phytopathology Research, 5, 1-13.

Jones J., Reavy B., Smant G., Prior A E. 2003. Glutathione peroxidases of the potato cyst nematode Globodera Rostochiensis. Gene, 324, 47-54.

Kandasamy M K, Gilliland L U, McKinney E C, Meagher R B. 2001. One plant actin isovariant, ACT7, is induced by auxin and required for normal callus formation. The Plant Cell, 13, 1541-1554.

Kim J, Yang R, Chang C, Park Y, Tucker M L. 2018. The root-knot nematode Meloidogyne incognita produces a functional mimic of the Arabidopsis INFLORESCENCE DEFICIENT IN ABSCISSION signaling peptide. Journal of Experimental Botany, 69, 3009-3021.

Lambert K N, Allen K D, Sussex I M. 1999. Cloning and characterization of an esophageal-gland-specific chorismate mutase from the phytoparasitic nematode Meloidogyne javanica. Molecular Plant-Microbe Interactions, 12, 328-336.

Lee C, Chronis D, Kenning C, Peret B, Hewezi T, Davis E L, Baum T J, Hussey R, Bennett M, Mitchum M G. 2011. The novel cyst nematode effector protein 19C07 interacts with the Arabidopsis auxin influx transporter LAX3 to control feeding site development. Physiology, 155, 866–880.

Leelarasamee N, Zhang L, Gleason C. 2018. The root-knot nematode effector MiPFN3 disrupts plant actin filaments and promotes parasitism. PLoS Pathogens, 14, e1006947.

Lilley C J, Maqbool A, Wu D, Yusup H B, Jones L M, Birch P R J, Banfield M J, Urwin P E, Eves-van den Akker S. 2018. Effector gene birth in plant parasitic nematodes: Neofunctionalization of a housekeeping glutathione synthetase gene. PLoS Genetics, 14, e1007310.

Lin B, Zhuo K, Wu P, Cui R, Zhang L, Liao J. 2013. A novel effector protein, MJ-NULG1a, targeted to giant cell nuclei plays a role in Meloidogyne javanica parasitism. Molecular Plant-Microbe Interactions, 26, 55-66.

Lin B, Zhuo K, Chen S, Hu L, Sun L, Wang X, Zhang L, Liao J. 2016. A novel nematode effector suppresses plant immunity by activating host reactive oxygen species-scavenging system. New Phytologist, 209, 1159-1173.

Masonbrink R, Maier T R, Muppirala U, Seetharam A S, Lord E, Juvale P S, Schmutz J, Johnson N T, Korkin D, Mitchum M G, Mimee B, Eves-van den Akker S, Hudson M, Severin A J,Baum T J. 2019. The genome of the soybean cyst nematode (Heterodera glycines) reveals complex patterns of duplications involved in the evolution of parasitism genes. BMC Genomics, 20, 1-14.

Meyer M C, Favoreto L, Klepker D, Marcelino-Guimarães F C. 2017. Soybean green stem and foliar retention syndrome caused by Aphelenchoides besseyi. Tropical Plant Pathology, 42, 403-409.

Mishal R, Luna-Arias J P. 2022. Role of the TATA-box binding protein (TBP) and associated family members in transcription regulation. Gene, 833, 146581.

Mitchum M G, Wang X, Wang J, Davis E L. 2012. Role of nematode peptides and other small molecules in plant parasitism. Annual Review of Phytopathology, 50, 175-195.

Mravec J, Skůpa P, Bailly A, Hoyerová K, Křeček P, Bielach A, Petrášek J, Zhang J, Gaykova V, Stierhof Y D, Dobrev P , Schwarzerová K, Rolčík J, Seifertová D, Luschnig C, Benková E, Zažímalová E, Geisler M, Friml J. 2009. Subcellular homeostasis of phytohormone auxin is mediated by the ER-localized PIN5 transporter. Nature, 459, 1136-1140.

Noon J B, Qi M, Sill D N, Muppirala U, Eves-van den Akker S, Maier T R, Dobbs D, Mitchum M G, Hewezi T, Baum T J. 2016. A Plasmodium-like virulence effector of the soybean cyst nematode suppresses plant innate immunity. New Phytologist, 212, 444-460.

Pankratenko A V, Atabekova A K, Lazareva E A, Baksheeva V E, Zhironkina O A, Zernii E Y, Owens R A, Solovyev A G, Morozov S Y. 2017. Plant-specific 4/1 polypeptide interacts with an endoplasmic reticulum protein related to human BAP31. Planta, 245, 193-205.

Pogorelko G, Juvale P S, Rutter W B, Hewezi T, Hussey R, Davis E L, Mitchum M G, Baum T J. 2016. A cyst nematode effector binds to diverse plant proteins, increases nematode susceptibility and affects root morphology. Molecular Plant Pathology, 17, 832-844.

Postma W J, Slootweg E J, Rehman S, Finkers-Tomczak A, Tytgat T O G, van Gelderen K, Lozano-Torres J L, Roosien J, Pomp R, van Schaik C, Bakker J, Goverse A, Smant G. 2012. The effector SPRYSEC-19 of Globodera rostochiensis suppresses CC-NB-LRR-mediated disease resistance in plants. Plant physiology, 160, 944-954.

Quistgaard E M. 2021. BAP31: Physiological functions and roles in disease. Biochimie, 186, 105-129.

Rosso M N, Favery B, Piotte C, Arthaud L, De Boer J M, Hussey R S, Bakker J, Baum T J, Abad P. 1999. Isolation of a cDNA encoding a β-1, 4-endoglucanase in the root-knot nematode Meloidogyne incognita and expression analysis during plant parasitism. Molecular Plant-Microbe Interactions, 12, 585-591.

Rutter W B, Hewezi T, Maier T R, Mitchum M G.Davis E L. Hussey R S. Baum T J. 2014. Members of the Meloidogyne avirulence protein family contain multiple plant ligand-like motifs. Phytopathology, 104, 879-885.

Siddique S, Radakovic Z S, De La Torre C M, Chronis D, Novák O, Ramireddy E, Holbein J, Matera C, Hütten M, Gutbrod P, Anjam M S, Rozanska E, Habash S, Elashry A, Sobczak M, Kakimoto T, Strnad M, Schmülling T, Mitchum M G, Grundler F M W. 2015. A parasitic nematode releases cytokinin that controls cell division and orchestrates feeding site formation in host plants. Proceedings of the National Academy of Sciences of the United States of America, 112, 12669-12674.

Silverstone A L, Jung H S, Dill A, Kawaide H, Kamiya Y, Sun T P. 2011. Repressing a repressor: gibberellin-induced rapid reduction of the RGA protein in Arabidopsis. The Plant Cell, 13, 1555-1566.

Song H, Lin B, Huang Q, Sun L, Chen J, Hu L, Zhuo K, Liao J. 2021. The Meloidogyne graminicola effector MgMO289 targets a novel copper metallochaperone to suppress immunity in rice. Journal of Experimental Botany, 72, 5638-5655.

Sukarta O C A, Zheng Q, Slootweg E J, Mekken M, Mendel M, Putker V, Bertran A, Brand A, Overmars H, Pomp R, Roosien J, Boeren S, Smant G, Goverse A. 2022. GLYCINE-RICH RNA-BINDING PROTEIN 7 potentiates effector-triggered immunity through an RNA recognition motif. Plant Physiology, 189, 972-987.

Sun N, Wang J, Gao Z, Dong J, He H, Terzaghi W, Wei N, Deng X W, Chen H. 2016. Arabidopsis SAURs are critical for differential light regulation of the development of various organs. Proceedings of the National Academy of Sciences of the United States of America, 113, 6071-6076.

Tang J, Xia H, Cao M, Zhang X, Zeng W, Hu S, Tong W, Wang J, Wang J, Yu J, Yang H, Zhu L. 2004. A comparison of rice chloroplast genomes. Plant Physiology, 135, 412-420.

Tucker M L, Yang R. 2013. A gene encoding a peptide with similarity to the plant IDA signaling peptide (AtIDA) is expressed most abundantly in the root-knot nematode (Meloidogyne incognita) soon after root infection. Experimental Parasitology, 134, 165-170.

Tulek A, Kepenekci I, Cobanoglu S, Hekimhan H, Devran Z, Melik B, Elekcioglu H I. 2009. A new culturing method for the rice white tip nematode, Aphelenchoides besseyi Christie, 1942, on carrot discs. Russian Journal of Nematology, 17, 135-136.

van Mourik H, van Dijk A D J, Stortenbeker N, Angenent G C, Bemer M. 2017. Divergent regulation of Arabidopsis SAUR genes: a focus on the SAUR10-clade. BMC Plant Biology, 17, 1-14.

Vieira P, Danchin E G J, Neveu C, Crozat C, Jaubert S, Hussey R S, Engler G, Abad P, de Almeida-Engler J, Castagnone-Sereno P, Rosso M. 2011. The plant apoplasm is an important recipient compartment for nematode secreted proteins. Journal of Experimental Botany, 62, 1241-1253.

Wang D W, Xu C L, Ding S W, Huang X, Cheng X, Zhang C, Chen C, Xie H. 2018. Identification and function of FAR protein family genes from a transcriptome analysis of Aphelenchoides besseyi. Bioinformatics, 34, 2936-2943.

Wei H, Wang X, He Y, Xu H, Wang L. 2021. Clock component OsPRR73 positively regulates rice salt tolerance by modulating OsHKT2;1‐mediated sodium homeostasis. The EMBO Journal, 40, e105086.

Witke W. 2004. The role of profilin complexes in cell motility and other cellular processes. Trends in Cell Biology, 14, 461-469.

Yang S, Li J, Yang S, Tang S, Wang H, Xu C, Xie H. 2024. A chorismate mutase from Radopholus similis plays an essential role in pathogenicity. Journal of Integrative Agriculture, 23, 923-937.

Zhang H, Yu Z, Yao X, Chen J, Chen X, Zhou H, Lou Y, Ming Feng, Jin Y. 2021. Genome-wide identification and characterization of small auxin-up RNA (SAUR) gene family in plants: evolution and expression profiles during normal growth and stress response. BMC Plant Biology, 21, 1-14.

Zhang X, Peng H, Zhu S, Xing J, Li X, Zhu Z, Zheng J, Wang L, Wang B, Chen J, Ming Z, Yao K, Jian J, Luan S, Coleman-Derr D, Liao H, Peng Y, Peng D, Yu F. 2020. Nematode-encoded RALF peptide mimics facilitate parasitism of plants through the FERONIA receptor kinase. Molecular Plant, 13, 1434-1454.

Zhao J, Duan Y, Kong L A, Huang W K, Peng D L, Liu S M. 2022. Opposite Beet Cyst Nematode-Infection Phenotypes of Transgenic Arabidopsis between Overexpressing GmSNAP18 and AtSNAP2 and between Overexpressing GmSHMT08 and AtSHMT4. Phytopathology, 112, 2383-2390.

No related articles found!

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Shared

Discussed

Cite this article:

About JIA

Editorial board

For authors