The Plant Actin Cytoskeleton Responds to Signals from Microbe-Associated Molecular Patterns

Henty-Ridilla, Jessica L.; Shimono, Masaki; Li, Jiejie; Chang, Jeff H.; Day, Brad; Staiger, Christopher J.

doi:10.1371/journal.ppat.1003290

Cited by 157 publications

(268 citation statements)

References 70 publications

(127 reference statements)

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“…S14). Actin microfilaments regulate the movement of organelles, such as mitochondria (Henty-Ridilla et al, 2013). GFP-labeled mitochondria showed dynamic movement in ADF1-4Ri at a speed comparable with that of the wild type (Supplemental Movies S1 and S2).…”

Section: Af Organization Was Affected Only At Very Early Infection Timentioning

confidence: 96%

“…The organization and dynamics of AFs are regulated by a number of actin-binding proteins, among which actin-depolymerizing factors (ADFs) play a conserved role in actin destabilization by severing and depolymerizing microfilaments at the minus end in eukaryotes, including yeast, mammals, and plants (Maciver and Hussey, 2002;Henty-Ridilla et al, 2013). The Arabidopsis genome contains 11 members of the ADF gene family, which are classified into four subclasses (Ruzicka et al, 2007).…”

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confidence: 99%

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Nuclear Function of Subclass I Actin-Depolymerizing Factor Contributes to Susceptibility in Arabidopsis to an Adapted Powdery Mildew Fungus

2016

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Actin-depolymerizing factors (ADFs) are conserved proteins that function in regulating the structure and dynamics of actin microfilaments in eukaryotes. In this study, we present evidence that Arabidopsis (Arabidopsis thaliana) subclass I ADFs, particularly ADF4, functions as a susceptibility factor for an adapted powdery mildew fungus. The null mutant of ADF4 significantly increased resistance against the adapted powdery mildew fungus Golovinomyces orontii. The degree of resistance was further enhanced in transgenic plants in which the expression of all subclass I ADFs (i.e. ADF1-ADF4) was suppressed. Microscopic observations revealed that the enhanced resistance of adf4 and ADF1-4 knockdown plants (ADF1-4Ri) was associated with the accumulation of hydrogen peroxide and cell death specific to G. orontii-infected cells. The increased resistance and accumulation of hydrogen peroxide in ADF1-4Ri were suppressed by the introduction of mutations in the salicylic acid-and jasmonic acid-signaling pathways but not by a mutation in the ethylene-signaling pathway. Quantification by microscopic images detected an increase in the level of actin microfilament bundling in ADF1-4Ri but not in adf4 at early G. orontii infection time points. Interestingly, complementation analysis revealed that nuclear localization of ADF4 was crucial for susceptibility to G. orontii. Based on its G. orontii-infected-cell-specific phenotype, we suggest that subclass I ADFs are susceptibility factors that function in a direct interaction between the host plant and the powdery mildew fungus.Powdery mildew is an obligate biotrophic fungal pathogen that infects approximately 10,000 plant species, including crops, vegetables, and ornamental plants, thus causing extensive economic losses worldwide (Takamatsu, 2004). In an effort to understand the plant response to powdery mildew fungal infection and the mechanism of plant-powdery mildew fungus interactions, many mutants of host plants, particularly the model plant Arabidopsis (Arabidopsis thaliana), have been identified and analyzed.Genes for which loss causes increased resistance to a pathogen could encode factors involved in the suppression of plant immunity or susceptibility factors that function in support of the pathogenic infection. Previously identified Arabidopsis genes, the loss of whose expression causes enhanced resistance against adapted powdery mildew fungi, include POWDERY MILDEW RESISTANT1 (PMR1)

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Section: Af Organization Was Affected Only At Very Early Infection Timentioning

confidence: 96%

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confidence: 99%

Nuclear Function of Subclass I Actin-Depolymerizing Factor Contributes to Susceptibility in Arabidopsis to an Adapted Powdery Mildew Fungus

2016

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“…The creation and turnover of actin filaments, as well as their assembly into higherorder structures, are tightly regulated at spatial and temporal levels by a plethora of actin-binding proteins, which control nucleation, polymerization, capping, severing and crosslinking (dos Remedios et al, 2003;Higaki et al, 2007;Staiger and Blanchoin, 2006;Thomas et al, 2009;Winder and Ayscough, 2005). Recent live cell studies combining reliable fluorescent actin markers with novel high-resolution imaging techniques such as spinning-disc confocal microscopy and variable-angle epifluorescence microscopy (VAEM) have provided key insights into actin cytoskeleton dynamics at the cell cortex of plant cells (Augustine et al, 2011;Era et al, 2009;Henty et al, 2011;Henty-Ridilla et al, 2013;Khurana et al, 2010;Konopka and Bednarek, 2008;Li et al, 2012;Smertenko et al, 2010;Staiger et al, 2009;Tóth et al, 2012). In striking contrast to in vitro actin treadmilling (Bugyi and Carlier, 2010;Selve and Wegner, 1986), in vivo remodeling of plant cortical actin arrays was found to follow a socalled 'stochastic dynamics' process that is dominated by fast elongation and prolific severing of single filaments Okreglak and Drubin, 2010;Staiger et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

“…Additional, more specific, roles have been assigned to actin bundling during guard cell and chloroplast movements (Higaki et al, 2010b), cell growth and morphogenesis (Baluska et al, 2001;Higaki et al, 2010a;Nick, 2010;Nick et al, 2009;Smith and Oppenheimer, 2005) and the set-up of plant defense responses against pathogens (Clément et al, 2009;Day et al, 2011;Hardham et al, 2007;Henty-Ridilla et al, 2013;Opalski et al, 2005;Schmidt and Panstruga, 2007;Takemoto et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Live cell imaging approaches reveal actin cytoskeleton-induced self-association of the actin-bundling protein WLIM1

Hoffmann

Moes

Dieterle

et al. 2013

Journal of Cell Science

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Crosslinking of actin filaments into bundles is critical for the assembly/stabilization of specific cytoskeletal structures. Relatively little is known about the molecular mechanisms underlying actin bundle formation. The two LIM domain-containing (LIM) proteins define a novel and evolutionary-conserved family of actin bundlers whose actin-binding and -crosslinking activities primarily rely on their LIM domains. Using TIRF microscopy, we describe real-time formation of actin bundles induced by tobacco NtWLIM1 in vitro. We show that NtWLIM1 binds to single filaments and subsequently promotes their interaction and zippering into tight bundles of mixed polarity. NtWLIM1-induced bundles grew by both elongation of internal filaments and addition of preformed fragments at their extremities. Importantly, these data are highly consistent with the modes of bundle formation and growth observed in transgenic Arabidopsis plants expressing a GFP fused Arabidopsis AtWLIM1 protein. Using two complementary live cell imaging approaches, a close relationship between NtWLIM1 subcellular localization and self-association was established. Indeed, both BiFC and FLIM-FRET data revealed that, although unstable NtWLIM1 complexes can sporadically form in the cytosol, stable complexes concentrate along the actin cytoskeleton. Remarkably, the disruption of the actin cytoskeleton significantly impaired NtWLIM1 self-association. In addition, biochemical analyses support that F-actin facilitates the switch of purified recombinant NtWLIM1 from a monomeric to a di/oligomeric state. Based on our data we propose a model in which actin binding promotes the formation/stabilization of NtWLIM1 complexes, which in turn might drive the crosslinking of actin filaments.

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“…In Arabidopsis epidermal cells, the density of cortical actin filament arrays increases within minutes after infection with pathogenic and nonpathogenic bacteria as well as elicitation by diverse MAMPs (Henty-Ridilla et al, 2013bLi et al, 2015b). This actin remodeling is required for defense responses such as callose deposition in the cell wall, transcriptional reprogramming of defense genes, and subsequently contributes to plant resistance against virulent and avirulent microbes (Henty-Ridilla et al, 2013bLi et al, 2015b). Quantitative analyses of actin dynamics in live cells have uncovered the potential molecular mechanisms that contribute to increased filament abundance.…”

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confidence: 99%

Capping Protein Modulates Actin Remodeling in Response to Reactive Oxygen Species during Plant Innate Immunity

Cao

Staiger

2016

Plant Physiol.

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Plants perceive microbe-associated molecular patterns and damage-associated molecular patterns to activate innate immune signaling events, such as bursts of reactive oxygen species (ROS). The actin cytoskeleton remodels during the first 5 min of innate immune signaling in Arabidopsis (Arabidopsis thaliana) epidermal cells; however, the immune signals that impinge on actin cytoskeleton and its response regulators remain largely unknown. Here, we demonstrate that rapid actin remodeling upon elicitation with diverse microbe-associated molecular patterns and damage-associated molecular patterns represent a conserved plant immune response. Actin remodeling requires ROS generated by the defense-associated NADPH oxidase, RBOHD. Moreover, perception of flg22 by its cognate receptor complex triggers actin remodeling through the activation of RBOHDdependent ROS production. Our genetic studies reveal that the ubiquitous heterodimeric capping protein transduces ROS signaling to the actin cytoskeleton during innate immunity. Additionally, we uncover a negative feedback loop between actin remodeling and flg22-induced ROS production.

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The Plant Actin Cytoskeleton Responds to Signals from Microbe-Associated Molecular Patterns

Cited by 157 publications

References 70 publications

Nuclear Function of Subclass I Actin-Depolymerizing Factor Contributes to Susceptibility in Arabidopsis to an Adapted Powdery Mildew Fungus

Nuclear Function of Subclass I Actin-Depolymerizing Factor Contributes to Susceptibility in Arabidopsis to an Adapted Powdery Mildew Fungus

Live cell imaging approaches reveal actin cytoskeleton-induced self-association of the actin-bundling protein WLIM1

Capping Protein Modulates Actin Remodeling in Response to Reactive Oxygen Species during Plant Innate Immunity

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