Reciprocal Responses in the Interaction between Arabidopsis and the Cell-Content-Feeding Chelicerate Herbivore Spider Mite

Zhurov, Vladimir; Navarro, Marie; Bruinsma, Kristie; Arbona, Vicent; Santamaría, M. Estrella; Cazaux, Marc; Wybouw, Nicky; Osborne, Edward J.; Ens, Cherise; Rioja, Cristina; Vermeirssen, Vanessa; Rubio‐Somoza, Ignacio; Krishna, Priti; Dı́az, Isabel; Schmid, Markus; Gómez-Cádenas, Aurelio; Peer, Yves Van de; Grbić, Miodrag; Clark, Richard M.; Leeuwen, Thomas Van; Grbić, Vojislava

doi:10.1104/pp.113.231555

Cited by 130 publications

(240 citation statements)

References 92 publications

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“…Particularly, ITCs derived from aliphatic glucosinolates have a deterrent activity against predating arthropods such as spider mites (Piasecka et al, 2015;Zhurov et al, 2014); those derived from indolic glucosinolates have antifeedant effects on aphids (Kim et al, 2008). In Arabidopsis thaliana, tryptophan-derived metabolites …”

Section: Phytoanticipinsmentioning

confidence: 99%

Metabolomics of Disease Resistance in Crops

Arbona

Gómez-Cádenas²

2016

Current Issues in Molecular Biology

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Plants are continuously exposed to the attack of invasive microorganisms, such as fungi or bacteria, and also viruses. To fight these attackers, plants develop different metabolic and genetic responses whose final outcome is the production of toxic compounds that kill the pathogen or deter its growth or semiotic molecules that alert other individuals of the same plant species. These molecules are derived from the secondary metabolism and their production is induced upon detection of a pathogen-associated molecular pattern (PAMP). These PAMPs are different molecules that are perceived by the host cell triggering defense responses. PAMP-elicited compounds are highly diverse and specific of every plant species and can be divided into preformed metabolites or phytoanticipins that are converted into toxic molecules upon pathogen perception, and toxic metabolites or phytoalexins that are produced only upon pathogen attack. Moreover, plant volatile emissions are also modified in response to pathogen attack to alert neighboring individuals or to make plants less attractive to pathogen vector arthropods. Plant metabolite profiling techniques have allowed the identification of novel antimicrobial molecules that are induced upon elicitation. However, more studies are required to assess the specific function of metabolites or metabolite blends on plant-microbe interactions.

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Section: Phytoanticipinsmentioning

confidence: 99%

Metabolomics of Disease Resistance in Crops

Arbona

Gómez-Cádenas²

2016

Current Issues in Molecular Biology

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“…Recently, several transcriptomic approaches allowed to establish molecular basis of its ability to adapt to different host plant species such as Arabidopsis, tomato and grapevine (Grbić et al 2011;Wybouw et al 2015;Díaz-Riquelme et al 2016;Rioja et al 2017). These thorough analyses often included monitoring of host plant transcriptional dynamics upon TSSM infestation and together with Arabidopsis and tomato focused research (Zhurov et al 2014;Martel et al 2015), gave an extensive overview on gene expression changes occurred starting from the early time points of infestation. However, there is a lack of data on how plants respond to TSSM in the presence of other stresses such as high light.…”

Section: Introductionmentioning

confidence: 99%

Cross-talk between high light stress and plant defence to the two-spotted spider mite in Arabidopsis thaliana

et al. 2017

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Little is known about how plants deal with arthropod herbivores under the fluctuating light intensity and spectra which occur in natural environments. Moreover, the role of simultaneous stress such as excess light (EL) in the regulation of plant responses to herbivores is poorly characterized. In the current study, we focused on a mite-herbivore, specifically, the two-spotted spider mite (TSSM), which is one of the major agricultural pests worldwide. Our results showed that TSSM-induced leaf damage (visualized by trypan blue staining) and oviposition rate (measured as daily female fecundity) decreased after EL pre-treatment in wild-type Arabidopsis plants, but the observed responses were not wavelength specific. Thus, we established that EL pre-treatment reduced Arabidopsis susceptibility to TSSM infestation. Due to the fact that a portion of EL energy is dissipated by plants as heat in the mechanism known as non-photochemical quenching (NPQ) of chlorophyll fluorescence, we tested an Arabidopsis npq4-1 mutant impaired in NPQ. We showed that npq4-1 plants are significantly less susceptible to TSSM feeding activity, and this result was not dependent on light pre-treatment. Therefore, our findings strongly support the role of light in plant defence against TSSM, pointing to a key role for a photoprotective mechanism such as NPQ in this regulation. We hypothesize that plants impaired in NPQ are constantly primed to mite attack, as this seems to be a universal evolutionarily conserved mechanism for herbivores.

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“…However, when the whole tomato genome transcriptional response to T. urticae was analyzed, none of the genes encoding SA signaling proteins, nor commonly used SA markers, were differentially expressed . Furthermore, SA-deficient mutants increased the performance of T. urticae on tomato but had no effect on Arabidopsis (Zhurov et al, 2014).…”

Section: Induced Defense: Phytohormone Signallingmentioning

confidence: 99%

“…Furthermore, the importance of the JA pathway for plant resistance to mites was proven by the use of JA-deficient mutants of Arabidopsis that show a higher susceptibility to T. urticae (Zhurov et al, 2014) and of tomato to A. lycopersici .…”

Section: Induced Defense: Phytohormone Signallingmentioning

confidence: 99%

Drought-stressed tomato plants trigger bottom-up effects on key mite pests

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de Madrid, gracias a la concesión de la beca predoctoral de la Junta de Ampliación de Estudios Toca ahora recapitular toda la gente que ha formado parte de manera directa o indirecta de esta aventura que es el doctorado. Sé que, dado que son muchos años y muchas experiencias, alguno quedará sin mencionar, igualmente gracias, no me lo tengáis en cuenta.En primer lugar, quiero dar las gracias a mis dos directores de tesis, Pedro y Felix, por darme la oportunidad de hacer la tesis con vosotros. Porque siempre habéis confiado en mí, realizando la tesis en un tema que nos era lejano a los tres y que hemos sabido llevar a buen puerto. Gracias por todo lo que he aprendido de vosotros tanto a nivel personal como de vuestra amplia experiencia en investigación. Por guiarme estos años, evitando que me dispersara y por vuestra paciencia, dado que reconozco que muchas veces soy un poco caótico.A Matilde Barón que nos asesoró en el desarrollo de un protocolo de inducción de sequía.A toda la gente del consorcio Genomite marco en el que se desarrolló esta tesis. En especial a María, Alain y Philipe del CBGP (el de Francia) por facilitarnos la población de T. evansi, sus consejos en la cría de ácaros y su acogida en Montpellier, pasamos buenos momentos recolectando ácaros. A Cristina y Vava, por sus consejos y los momentos vividos en Montpellier. A Jerry y Mike por coordinar el proyecto y por sus comentarios como evaluadores externos que han contribuido de manera significativa a mejorar la tesis.Al laboratorio de Isabel Díaz del CBGP (el de la UPM) por su ayuda en los protocolos de inhibidores de proteasas y qPCR. A Isabel, ya son unos cuantos años que nos conocemos desde las clases de agrónomos, pasando por Chile, gracias por tu dedicación y tu ayuda todos estos años. A Ana y Blanca por su ayuda y por acogerme en el laboratorio como si fuera el mío.A Estrella, la que nunca para, muchas gracias por todo lo que me has enseñado, has sido una gran maestra y una muy buena compañera, nos queda pendiente coincidir en un congreso.Gracias también por toda tu ayuda en la recta final de la tesis.Al servicio de química de proteínas, a Emilia y a Javier, siempre dispuestos a ayudar, incluso cuando algún análisis corría prisa.A la maravillosa gente del laboratorio, a la que daba gusto ver cada mañana, voy a echar de menos las conversaciones durante las comidas, los cafés del 201 … A Esteban que me pasó el testigo de la cría de ácaros. Al otro Miguel, gracias por tu apoyo en todo lo referente a sequía y que me reafirmó en lo que estaba haciendo, gracias por tus comentarios que han mejorado esta tesis. A Gema y Pedro, por echarme una mano cuando lo necesitaba y alegrar los cafés. A la gente del 201, laboratorio en el que resistí los 5 años. A Matías, fuente de sabiduría en lo personal y laboral; Nuria, siempre con optimismo y con imaginación; Carolina, rodeada de sus animalillos dispuesta siempre a echar una mano; Gabriela, la dj del labo, siempre nos quedará Juan Luis Guerra bailado junto a la poyata; María, que me cedió el testigo, siempre r...

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Reciprocal Responses in the Interaction between Arabidopsis and the Cell-Content-Feeding Chelicerate Herbivore Spider Mite

Cited by 130 publications

References 92 publications

Metabolomics of Disease Resistance in Crops

Metabolomics of Disease Resistance in Crops

Cross-talk between high light stress and plant defence to the two-spotted spider mite in Arabidopsis thaliana

Drought-stressed tomato plants trigger bottom-up effects on key mite pests

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