A New Role for SAG12 Cysteine Protease in Roots of Arabidopsis thaliana

James, Maxence; Masclaux-Daubresse, Céline; Marmagne, Anne; Azzopardi, Marianne; Laîné, Philippe; Goux, Didier; Étienne, Philippe; Trouverie, Jacques

doi:10.3389/fpls.2018.01998

Cited by 26 publications

(17 citation statements)

References 48 publications

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“…The nWHY1 plant, which accumulated approximately 4-fold higher WHY1 transcripts over WT plants, had apparently lower expression levels for its repressed targets WRKY53 and WRKY33, as well as SEN4. But on the other hand, this line expressed significantly higher SAG12 and SAG29 (Figure 2), which encoded, respectively, a cysteine protease and a sucrose transporter and functioned in remobilization of nitrogen and carbon in senescent organs as well as in normal organs under stress conditions [45][46][47]. This line showed more or less delayed leaf senescence as compared to the why1 mutant or WT (Figure 1).…”

Section: Ectopic Expression Of a Plastid Isoform Why1 Causes A Strongmentioning

confidence: 91%

H2O2 as a Feedback Signal on Dual-Located WHIRLY1 Associates with Leaf Senescence in Arabidopsis

Lin

Huang

Shi

et al. 2019

Cells

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Leaf senescence, either as a natural stage of development or as an induced process under stress conditions, incorporates multiple intricate signaling pathways. At the cellular level, retrograde signals have been considered as important players during the initiation and progression of senescence in both animals and plants. The plant-specific single-strand DNA-binding protein WHIRLY1 (WHY1), a repressor of leaf natural senescence, is dually located in both nucleus and plastids. Despite many years of studies, the myth about its dual location and the underlying functional implications remain elusive. Here, we provide further evidence in Arabidopsis showing that alteration in WHY1 allocation between the nucleus and chloroplast causes perturbation in H2O2 homeostasis, resulting in adverse plant senescence phenotypes. The knockout of WHY1 increased H2O2 content at 37 days post-germination, coincident with an early leaf senescence phenotype, which can be rescued by ectopic expression of the nuclear isoform (nWHY1), but not by the plastid isoform (pWHY1). Instead, accumulated pWHY1 greatly provoked H2O2 in cells. On the other hand, exogenous H2O2 treatment induced a substantial plastid accumulation of WHY1 proteins and at the same time reduced the nuclear isoforms. This H2O2-induced loss of nucleus WHY1 isoform was accompanied by enhanced enrichments of histone H3 lysine 9 acetylation (H3K9ac) and recruitment of RNA polymerase II (RNAP II) globally, and specifically at the promoter of the senescence-related transcription factor WRKY53, which in turn activated WRKY53 transcription and led to a senescence phenotype. Thus, the distribution of WHY1 organelle isoforms and the feedback of H2O2 intervene in a circularly integrated regulatory network during plant senescence in Arabidopsis.

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Section: Ectopic Expression Of a Plastid Isoform Why1 Causes A Strongmentioning

confidence: 91%

H2O2 as a Feedback Signal on Dual-Located WHIRLY1 Associates with Leaf Senescence in Arabidopsis

Lin

Huang

Shi

et al. 2019

Cells

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“…Although both autophagy and cysteine proteases are key players during leaf senescence, protein proteolysis, and nutrient recycling, as shown by recent publications from James et al [86,87], the relationship between them remains largely unknown. It is admitted that proteins are not degraded inside the autophagosomes but rather transported by them to the lytic vacuoles where proteases and hydrolases operate.…”

Section: Cross-talk Between Autophagy and Senescence-related Cystementioning

confidence: 99%

Autophagy and Nutrients Management in Plants

Chen

Shinozaki

Luo

et al. 2019

Cells

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Nutrient recycling and mobilization from organ to organ all along the plant lifespan is essential for plant survival under changing environments. Nutrient remobilization to the seeds is also essential for good seed production. In this review, we summarize the recent advances made to understand how plants manage nutrient remobilization from senescing organs to sink tissues and what is the contribution of autophagy in this process. Plant engineering manipulating autophagy for better yield and plant tolerance to stresses will be presented.

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“…Plant proteases have been described to accomplish multiple roles in different physiological processes along the plant life cycle, such as programmed cell death, senescence, abscission, fruit ripening, plant growth, and N homeostasis (Grudkowska and Zagdańska, 2004; van der Hoorn, 2008; Liu et al, 2018; Tornkvist et al, 2019). In response to abiotic and biotic stresses, proteases are also involved in nutrient remobilization associated with leaf and root proteins degradation to ensure yield (Diaz-Mendoza et al, 2014; Velasco-Arroyo et al, 2016, 2018; Gomez-Sanchez et al, 2019; James et al, 2019), or in triggering the response of the plant to pathogens and phytophagous insects and acari (van der Hoorn and Jones, 2004; Shindo and van der Hoorn, 2008; Misas-Villamil et al, 2016; Diaz-Mendoza et al, 2017). Moreover, plant proteases play a crucial role in the plant seed germination, through the mobilization of other proteins accumulated in seeds and cereal grains (Grudkowska and Zagdańska, 2004; Cambra et al, 2012; Diaz-Mendoza et al, 2016; Szewinska et al, 2016; Liu et al, 2018; Radchuk et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Plant Proteases: From Key Enzymes in Germination to Allies for Fighting Human Gluten-Related Disorders

et al. 2019

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Plant proteases play a crucial role in many different biological processes along the plant life cycle. One of the most determinant stages in which proteases are key protagonists is the plant germination through the hydrolysis and mobilization of other proteins accumulated in seeds and cereal grains. The most represented proteases in charge of this are the cysteine proteases group, including the C1A family known as papain-like and the C13 family also called legumains. In cereal species such as wheat, oat or rye, gluten is a very complex mixture of grain storage proteins, which may affect the health of sensitive consumers like celiac patients. Since gluten proteins are suitable targets for plant proteases, the knowledge of the proteases involved in storage protein mobilization could be employed to manipulate the amount of gluten in the grain. Some proteases have been previously found to exhibit promising properties for their application in the degradation of known toxic peptides from gluten. To explore the variability in gluten-degrading capacities, we have now analyzed the degradation of gluten from different wheat cultivars using several cysteine proteases from barley. The wide variability showed highlights the possibility to select the protease with the highest potential to alter grain composition reducing the gluten content. Consequently, new avenues could be explored combining genetic manipulation of proteolytic processes with silencing techniques to be used as biotechnological tools against gluten-related disorders.

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A New Role for SAG12 Cysteine Protease in Roots of Arabidopsis thaliana

Cited by 26 publications

References 48 publications

H2O2 as a Feedback Signal on Dual-Located WHIRLY1 Associates with Leaf Senescence in Arabidopsis

H2O2 as a Feedback Signal on Dual-Located WHIRLY1 Associates with Leaf Senescence in Arabidopsis

Autophagy and Nutrients Management in Plants

Plant Proteases: From Key Enzymes in Germination to Allies for Fighting Human Gluten-Related Disorders

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