Ectopic activation of the rice <scp>NLR</scp> heteropair <scp>RGA</scp>4/<scp>RGA</scp>5 confers resistance to bacterial blight and bacterial leaf streak diseases

Hutin, M.; Césari, Stella; Chalvon, Véronique; Michel, Corinne; Tran, Tuan Hiep; Boch, Jens; Koebnik, Ralf; Szurek, Boris; Kroj, Thomas

doi:10.1111/tpj.13231

Cited by 29 publications

(20 citation statements)

References 59 publications

(90 reference statements)

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“…For example, scientists generated transgenic rice ( Oryza sativa ) plants harboring the AVR1‐CO39 effector gene of rice blast fungus M. oryzae or the NLR gene RGA4 , under the control of a TALE‐inducible promoter. Both transgenic lines exhibited enhanced resistance when challenged with pathogen strains carrying the corresponding TAL effectors (Hutin et al, 2016). Furthermore, both rice and pepper have evolved “executor” genes with TAL effector binding sites in their promoters, such as Xa27 from rice and Bs3 and Bs4c from pepper, the products of which induce hypersensitive cell death to confine pathogen proliferation (Dangl et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

Pathogen‐informed breeding for crop disease resistance

et al. 2021

JIPB

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The development of durable and broad-spectrum resistance is an economical and eco-friendly approach to control crop diseases for sustainable agricultural production. Emerging knowledge of the molecular basis of pathogenesis and plant-pathogen interactions has contributed to the development of novel pathogen-informed breeding strategies beyond the limits imposed by conventional breeding. Here, we review the current status of pathogen-assisted resistance-related gene cloning. We also describe how pathogen effector proteins can be used to identify resistance resources and to inform cultivar deployment. Finally, we summarize the main approaches for pathogen-directed plant improvement, including transgenesis and genome editing. Thus, we describe the emerging role of pathogen-related studies in the breeding of disease-resistant varieties, and propose innovative pathogen-informed strategies for future applications.

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Section: Introductionmentioning

confidence: 99%

Pathogen‐informed breeding for crop disease resistance

et al. 2021

JIPB

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“…Research has shown that modifying the expression of defense-related ( DR ) genes alters the resistance of rice to Xoc . For example, the overexpression of the broad-spectrum disease resistance gene OsMPK6 , an indole-3-acetic acid amido synthetase ( GH3–2 ), a nucleotide binding and leucine-rich repeat domain (NLR) protein heteropairs RGA4/RGA5 , OsPGIP4 , OsMAPK10.2 , the small heat shock protein gene OsHSP18.0-CI and the phytosulfokine receptor 1 ( OsPSKR1 ) enhanced the resistance of rice to BLS (Shen et al 2010; Fu et al 2011; Feng et al 2016; Hutin et al 2016; Ma et al 2017; Ju et al 2017; Yang et al 2019). The repression of OsWRKY45–1 , a receptor-like cytoplasmic kinase ( NRRB ), OsImpα1a and OsImpα1b also enhanced the resistance of rice to Xoc (Tao et al 2009; Guo et al 2014; Hui et al 2019).…”

Section: Introductionmentioning

confidence: 99%

OsPGIP1-Mediated Resistance to Bacterial Leaf Streak in Rice is Beyond Responsive to the Polygalacturonase of Xanthomonas oryzae pv. oryzicola

Peng

et al. 2019

Rice

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Polygalacturonase-inhibiting proteins (PGIPs) have been shown to recognize fungal polygalacturonases (PGs), which initiate innate immunity in various plant species. Notably, the connection between rice OsPGIPs and PGs in Xanthomonas oryzae pv. oryzicola (Xoc), which causes bacterial leaf streak (BLS), remains unclear. Here, we show that OsPGIP1 was strongly induced after inoculating rice with the Xoc strain RS105. Furthermore, OsPGIP1-overexpressing (OV) and RNA interference (RNAi) rice lines increased and decreased, respectively, the resistance of rice to RS105, indicating that OsPGIP1 contributes to BLS resistance. Subsequently, we generated the unique PG mutant RS105Δpg, the virulence of which is attenuated compared to that of RS105. Surprisingly, the lesion lengths caused by RS105Δpg were similar to those caused by RS105 in the OV lines compared with wild-type ZH11 with reduced Xoc susceptibility. However, the lesion lengths caused by RS105Δpg were still significantly shorter in the OV lines than in ZH11, implying that OsPGIP1-mediated BLS resistance could respond to other virulence factors in addition to PGs. To explore the OsPGIP1-mediated resistance, RNA-seq analysis were performed and showed that many plant cell wall-associated genes and several MYB transcription factor genes were specifically expressed or more highly induced in the OV lines compared to ZH11 postinoculation with RS105. Consistent with the expression of the differentially expressed genes, the OV plants accumulated a higher content of jasmonic acid (JA) than ZH11 postinoculation with RS105, suggesting that the OsPGIP1-mediated resistance to BLS is mainly dependent on the plant cell wall-associated immunity and the JA signaling pathway.

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“…R gene promoters have been modified to include a concatemer of EBE sites for TALes from multiple strains of a pathogen 60, 61 . TAL EBEs can also be added to promoters to recruit TALe-mediated expression of autonomous R genes or avirulence proteins leading to resistance reactions 62, 63 .…”

mentioning

confidence: 99%

Recent advances in developing disease resistance in plants

2019

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Approaches to manipulating disease resistance in plants is expanding exponentially due to advances in our understanding of plant defense mechanisms and new tools for manipulating the plant genome. The application of effective strategies is only limited now by adoption of rapid classical genetic techniques and the acceptance of genetically engineered traits for some problems. The use of genome editing and cis-genetics, where possible, may facilitate applications that otherwise require considerable time or genetic engineering, depending on settling legal definitions of the products. Nonetheless, the variety of approaches to developing disease resistance has never been greater.

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Ectopic activation of the rice NLR heteropair RGA4/RGA5 confers resistance to bacterial blight and bacterial leaf streak diseases

Cited by 29 publications

References 59 publications

Pathogen‐informed breeding for crop disease resistance

Pathogen‐informed breeding for crop disease resistance

OsPGIP1-Mediated Resistance to Bacterial Leaf Streak in Rice is Beyond Responsive to the Polygalacturonase of Xanthomonas oryzae pv. oryzicola

Recent advances in developing disease resistance in plants

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