Autophagy contributes to regulation of the hypoxia response during submergence in <i>Arabidopsis thaliana</i>

Chen, Liang; Liao, Bin; Hua, Qi; Xie, Lei; Huang, Li; Tan, Wei‐Juan; Zhai, Ning; Yuan, Li‐Bing; Zhou, Ying; Yu, Lujun; Chen, Qinfang; Shu, Wen‐Sheng; Xiao, Shi

doi:10.1080/15548627.2015.1112483

Cited by 157 publications

(184 citation statements)

References 69 publications

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“…These proteins modulate the autophagy pathway and thereby enhance Arabidopsis tolerance to nutrient starvation (Qi et al, 2017). In fact, autophagy responses are also activated during hypoxia and contribute to plant submergence tolerance (Chen et al, 2015(Chen et al, , 2017a(Chen et al, and 2017b. This evidence suggests that an additional tier of regulation might connect the ERF-VIIs to submergence responses, through the SINAT factors.…”

mentioning

confidence: 99%

Group VII Ethylene Response Factors in Arabidopsis: Regulation and Physiological Roles

Giuntoli

Perata

2017

Plant Physiol.

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confidence: 99%

Group VII Ethylene Response Factors in Arabidopsis: Regulation and Physiological Roles

Giuntoli

Perata

2017

Plant Physiol.

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“…Arabidopsis mutants defective in autophagy are highly sensitive to submergence (Chen et al, 2015). Several of these genes involved in fatty acid and amino acid breakdown are crucial to maintain energy status and performance during stress conditions or in nonphotosynthetic developmental stages.…”

Section: Alternative Metabolic Reserve Mobilization As a Coordinated mentioning

confidence: 99%

Transcriptomes of eight Arabidopsis thaliana accessions reveal core conserved, genotype- and organ-specific responses to flooding stress

et al. 2016

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ORCID IDs: 0000-0002-6709-6436 (S.H.); 0000-0001-6777-6565 (M.E.S.); 0000-0002-8568-7125 (J.B.-S.); 0000-0002-6940-0657 (R.S.).Climate change has increased the frequency and severity of flooding events, with significant negative impact on agricultural productivity. These events often submerge plant aerial organs and roots, limiting growth and survival due to a severe reduction in light reactions and gas exchange necessary for photosynthesis and respiration, respectively. To distinguish molecular responses to the compound stress imposed by submergence, we investigated transcriptomic adjustments to darkness in air and under submerged conditions using eight Arabidopsis (Arabidopsis thaliana) accessions differing significantly in sensitivity to submergence. Evaluation of root and rosette transcriptomes revealed an early transcriptional and posttranscriptional response signature that was conserved primarily across genotypes, although flooding susceptibility-associated and genotype-specific responses also were uncovered. Posttranscriptional regulation encompassed darkness-and submergence-induced alternative splicing of transcripts from pathways involved in the alternative mobilization of energy reserves. The organ-specific transcriptome adjustments reflected the distinct physiological status of roots and shoots. Root-specific transcriptome changes included marked up-regulation of chloroplast-encoded photosynthesis and redox-related genes, whereas those of the rosette were related to the regulation of development and growth processes. We identified a novel set of tolerance genes, recognized mainly by quantitative differences. These included a transcriptome signature of more pronounced gluconeogenesis in tolerant accessions, a response that included stress-induced alternative splicing. This study provides organ-specific molecular resolution of genetic variation in submergence responses involving interactions between darkness and low-oxygen constraints of flooding stress and demonstrates that early transcriptome plasticity, including alternative splicing, is associated with the ability to cope with a compound environmental stress.

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“…Given that autophagy contributes to the regulation of plant responses to both biotic (e.g., bacterial and fungal pathogens) and abiotic (e.g., hypoxia) stress in Arabidopsis (Lenz et al, 2011;Chen et al, 2015), we investigated whether the deletion of TRAF1a and TRAF1b would affect plant stress resistance. To this end, we inoculated wild-type, traf1a/b-1, traf1a/b-2, and traf1a/b-3 plants with the virulent bacteria Pseudomonas syringae pv tomato DC3000 and the necrotrophic fungi Botrytis cinerea, which are widely used to evaluate plant defense responses (Lenz et al, 2011;Xiao and Chye, 2011).…”

Section: The Traf1a/b Mutants Show Altered Sensitivity To Biotic and mentioning

confidence: 99%

“…Loss of TRAF1a and TRAF1b Constitutively Increases Salicylic Acid Levels, Activates PR Gene Expression, and Enhances Cell Death and Hydrogen Peroxide Production Autophagy is a protective mechanism that is essential for the disposal of damaged organelles and for the maintenance of cellular reactive oxygen species (ROS) homeostasis in plants under stress conditions, a process likely controlled by the salicylic acid (SA) signaling pathway (Liu and Bassham, 2012;Chen et al, 2015). Given that SA, jasmonates (JAs), and ROS accumulate in Arabidopsis atg mutants (Yoshimoto et al, 2009), we examined the SA, JA, and ROS levels in the TRAF1a-and TRAF1b-knockout lines using liquid chromatographymass spectrometry.…”

Section: Plants Lacking Traf1a and Traf1b Are Hypersensitive To Nutrimentioning

confidence: 99%

“…In Arabidopsis thaliana, deletion of ATG genes causes hypersensitivity to nutrient deprivation, premature leaf senescence, shortened life span, alteration of the cellular metabolome, activated innate immunity, and impaired biotic and abiotic stress tolerance (Doelling et al, 2002;Hanaoka et al, 2002;Yoshimoto et al, 2004;Liu et al, 2005;Thompson et al, 2005;Xiong et al, 2005;Phillips et al, 2008;Chung et al, 2010;Minina et al, 2013;Li et al, 2014;Chen et al, 2015;Avin-Wittenberg et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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TRAF Family Proteins Regulate Autophagy Dynamics by Modulating AUTOPHAGY PROTEIN6 Stability in Arabidopsis

et al. 2017

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Eukaryotic cells use autophagy to recycle cellular components. During autophagy, autophagosomes deliver cytoplasmic contents to the vacuole or lysosome for breakdown. Mammalian cells regulate the dynamics of autophagy via ubiquitinmediated proteolysis of autophagy proteins. Here, we show that the Arabidopsis thaliana Tumor necrosis factor ReceptorAssociated Factor (TRAF) family proteins TRAF1a and TRAF1b (previously named MUSE14 and MUSE13, respectively) help regulate autophagy via ubiquitination. Upon starvation, cytoplasmic TRAF1a and TRAF1b translocated to autophagosomes. Knockout traf1a/b lines showed reduced tolerance to nutrient deficiency, increased salicylic acid and reactive oxygen species levels, and constitutive cell death in rosettes, resembling the phenotypes of autophagy-defective mutants. Starvation-activated autophagosome accumulation decreased in traf1a/b root cells, indicating that TRAF1a and TRAF1b function redundantly in regulating autophagosome formation. TRAF1a and TRAF1b interacted in planta with ATG6 and the RING finger E3 ligases SINAT1, SINAT2, and SINAT6 (with a truncated RING-finger domain). SINAT1 and SINAT2 require the presence of TRAF1a and TRAF1b to ubiquitinate and destabilize AUTOPHAGY PROTEIN6 (ATG6) in vivo. Conversely, starvation-induced SINAT6 reduced SINAT1-and SINAT2-mediated ubiquitination and degradation of ATG6. Consistently, SINAT1/SINAT2 and SINAT6 knockout mutants exhibited increased tolerance and sensitivity, respectively, to nutrient starvation. Therefore, TRAF1a and TRAF1b function as molecular adaptors that help regulate autophagy by modulating ATG6 stability in Arabidopsis.

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Autophagy contributes to regulation of the hypoxia response during submergence in Arabidopsis thaliana

Cited by 157 publications

References 69 publications

Group VII Ethylene Response Factors in Arabidopsis: Regulation and Physiological Roles

Group VII Ethylene Response Factors in Arabidopsis: Regulation and Physiological Roles

Transcriptomes of eight Arabidopsis thaliana accessions reveal core conserved, genotype- and organ-specific responses to flooding stress

TRAF Family Proteins Regulate Autophagy Dynamics by Modulating AUTOPHAGY PROTEIN6 Stability in Arabidopsis

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