Arabidopsis HOOKLESS1 regulates responses to pathogens and abscisic acid through interaction with MED18 and acetylation of WRKY33 and ABI5 chromatin

Liao, Chao‐Jan; Lai, Zhibing; Lee, Sang-Hun; Yun, Dae‐Jin; Mengiste, Tesfaye

doi:10.1105/tpc.16.00105

Cited by 64 publications

(83 citation statements)

References 74 publications

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“…Genetic and biochemical studies have demonstrated that HLS1 is required for both ethylene‐ and light‐regulated ARF2 protein accumulation, but the underlying molecular mechanism is unclear (Li et al ., ). Consistent with the bioinformatic prediction that HLS1 shows sequence homology with N ‐acetyltransferases (Lehman et al ., ), a recent study has shown decreased levels of histone 3 acetylation at chromosome loci of WRKY33 and ABI5 ( ABA INSENSITIVE 5 ) in hls1 relative to that of the wild‐type (Liao et al ., ). However, direct evidence for the N ‐acetyltransferase activity of HLS1, either in vivo or in vitro , is missing (Liao et al ., ).…”

Section: Central Players Of Apical Hook Development: Auxin and Hookless1mentioning

confidence: 97%

“…Consistent with the bioinformatic prediction that HLS1 shows sequence homology with N ‐acetyltransferases (Lehman et al ., ), a recent study has shown decreased levels of histone 3 acetylation at chromosome loci of WRKY33 and ABI5 ( ABA INSENSITIVE 5 ) in hls1 relative to that of the wild‐type (Liao et al ., ). However, direct evidence for the N ‐acetyltransferase activity of HLS1, either in vivo or in vitro , is missing (Liao et al ., ). In the light of apical hook development, whether and how this putative N ‐acetyltransferase activity, if it exists, impinges on auxin distribution and signaling remains to be explored (Li et al ., ).…”

Section: Central Players Of Apical Hook Development: Auxin and Hookless1mentioning

confidence: 97%

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On hormonal regulation of the dynamic apical hook development

Wang

Guo

2018

New Phytologist

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Summary To deal with the ever‐changing environment, sessile plants adapt diverse and plastic organ structures during postembryonic development. Among these, the apical hook forms shortly after seed germination of most dicots, and protects the delicate shoot meristem from mechanical damage during soil emergence. For decades, this structure has been taken as an excellent model for the investigation of the mechanisms underlying the differential growth of plant tissues. Here, we summarize recent advances in the investigation of the hormonal regulation of apical hook development, focusing on the convergence to auxin and a central regulator HOOKLESS1 (HLS1). We propose the revisitation of hook curvature kinematics at suborgan and single‐cell resolution, and further pursuance of the mechanistics of apical hook development through combinatorial approaches of automated imaging and multidimensional modeling.

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Section: Central Players Of Apical Hook Development: Auxin and Hookless1mentioning

confidence: 97%

Section: Central Players Of Apical Hook Development: Auxin and Hookless1mentioning

confidence: 97%

On hormonal regulation of the dynamic apical hook development

Wang

Guo

2018

New Phytologist

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“…HLS1 and MED18 interact physically and probably are the part of the same complex. Using transgenic Arabidopsis plants it was proved that HLS1 and MED18 are engaged in ABA signaling and are tightly related to ABI5 action (Liao et al, 2016). …”

Section: Epigenetic Regulation Of the Abi5 Genementioning

confidence: 99%

The Role and Regulation of ABI5 (ABA-Insensitive 5) in Plant Development, Abiotic Stress Responses and Phytohormone Crosstalk

2016

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ABA Insensitive 5 (ABI5) is a basic leucine zipper transcription factor that plays a key role in the regulation of seed germination and early seedling growth in the presence of ABA and abiotic stresses. ABI5 functions in the core ABA signaling, which is composed of PYR/PYL/RCAR receptors, PP2C phosphatases and SnRK2 kinases, through the regulation of the expression of genes that contain the ABSCISIC ACID RESPONSE ELEMENT (ABRE) motif within their promoter region. The regulated targets include stress adaptation genes, e.g., LEA proteins. However, the expression and activation of ABI5 is not only dependent on the core ABA signaling. Many transcription factors such as ABI3, ABI4, MYB7 and WRKYs play either a positive or a negative role in the regulation of ABI5 expression. Additionally, the stability and activity of ABI5 are also regulated by other proteins through post-translational modifications such as phosphorylation, ubiquitination, sumoylation and S-nitrosylation. Moreover, ABI5 also acts as an ABA and other phytohormone signaling integrator. Components of auxin, cytokinin, gibberellic acid, jasmonate and brassinosteroid signaling and metabolism pathways were shown to take part in ABI5 regulation and/or to be regulated by ABI5. Monocot orthologs of AtABI5 have been identified. Although their roles in the molecular and physiological adaptations during abiotic stress have been elucidated, knowledge about their detailed action still remains elusive. Here, we describe the recent advances in understanding the action of ABI5 in early developmental processes and the adaptation of plants to unfavorable environmental conditions. We also focus on ABI5 relation to other phytohormones in the abiotic stress response of plants.

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“…This ABA-induced weakening of ROS production should be part of a larger defensive network where ABA acts as a moderating signal. Indeed, transcriptomic and epigenetic studies revealed that ABA down-regulates the expression of many defensive genes (de Torres-Zabala et al, 2007; Cheng et al, 2016; Liao et al, 2016). All these additive effects would explain the extremely susceptible phenotype of the ABA-overproducing plants, even more pronounced than the AtrbohD mutant’s one even if this mutant does not exhibit any oxidative stress response to infection ( Figures 5 , 6 ).…”

Section: Discussionmentioning

confidence: 99%

“…Recent studies highlighted the major involvement of ABA in the regulation network of plant defense. It induces the accumulation of HLS1, an histone acetyltransferase that regulates epigenetically defense responses (Liao et al, 2016), enhances expression of defense genes through the down-regulation of many miRNAs (Cheng et al, 2016) and its effects on cell wall composition and structure influence resistance to pathogens (Curvers et al, 2010; Sánchez-Vallet et al, 2012). All these data would explain the negative impact of ABA on pathogen defense in some pathosystems (Asselbergh et al, 2008b).…”

Section: Introductionmentioning

confidence: 99%

Manipulation of ABA Content in Arabidopsis thaliana Modifies Sensitivity and Oxidative Stress Response to Dickeya dadantii and Influences Peroxidase Activity

et al. 2017

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The production of reactive oxygen species (ROS) is one of the first defense reactions induced in Arabidopsis in response to infection by the pectinolytic enterobacterium Dickeya dadantii. Previous results also suggest that abscisic acid (ABA) favors D. dadantii multiplication and spread into its hosts. Here, we confirm this hypothesis using ABA-deficient and ABA-overproducer Arabidopsis plants. We investigated the relationships between ABA status and ROS production in Arabidopsis after D. dadantii infection and showed that ABA status modulates the capacity of the plant to produce ROS in response to infection by decreasing the production of class III peroxidases. This mechanism takes place independently of the well-described oxidative stress related to the RBOHD NADPH oxidase. In addition to this weakening of plant defense, ABA content in the plant correlates positively with the production of some bacterial virulence factors during the first stages of infection. Both processes should enhance disease progression in presence of high ABA content. Given that infection increases transcript abundance for the ABA biosynthesis genes AAO3 and ABA3 and triggers ABA accumulation in leaves, we propose that D. dadantii manipulates ABA homeostasis as part of its virulence strategy.

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Arabidopsis HOOKLESS1 regulates responses to pathogens and abscisic acid through interaction with MED18 and acetylation of WRKY33 and ABI5 chromatin

Cited by 64 publications

References 74 publications

On hormonal regulation of the dynamic apical hook development

On hormonal regulation of the dynamic apical hook development

The Role and Regulation of ABI5 (ABA-Insensitive 5) in Plant Development, Abiotic Stress Responses and Phytohormone Crosstalk

Manipulation of ABA Content in Arabidopsis thaliana Modifies Sensitivity and Oxidative Stress Response to Dickeya dadantii and Influences Peroxidase Activity

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