Noa Wigoda scite author profile

SummaryNumerous GAST-like genes have been identified in various plant species. All code for small proteins with a conserved C-terminal region in which 12 cysteines are located in exactly the same positions. We have previously identified five gibberellin (GA)-induced GAST1-like genes in petunia, GIP1-5. GIP2 is expressed in elongating zones, and its suppression in transgenic petunia plants inhibits stem elongation, suggesting a role for the protein in GA-induced cell growth. However, nothing is known about the biochemical activity of GIP2 or any other GAST-like protein. As all contain putative catalytic disulfide bonds (putative redox-active cysteines), we speculated that they might be involved in redox regulation. Expression analysis of GIP2, GIP4 and GIP5 revealed that they are induced by H 2 O 2 . To study whether GIP2 modulates H 2 O 2 levels, we generated transgenic petunia plants expressing GIP2 under the regulation of the ubiquitous CaMV 35S promoter. The transgene reduced H 2 O 2 levels in leaves following wounding. It also reduced the levels of H 2 O 2 in guard cells following osmotic stress and ABA treatments, leading to the suppression of stomatal closure. In addition, the transgene promoted stem and corolla elongation. As reactive oxygen species (ROS) are involved in cell elongation, we suggest that GIP2 affects growth by regulating the levels of ROS. As all known GAST-like proteins contain putative redox-active cysteines, they may all act as antioxidants.

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Differential gene expression and transport functionality in the bundle sheath versus mesophyll – a potential role in leaf mineral homeostasis

Wigoda

Pasmanik‐Chor

Yang

et al. 2017

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Arabidopsis leaf hydraulic conductance is regulated by xylem sap pH, controlled, in turn, by a P‐type H⁺‐ATPase of vascular bundle sheath cells

et al. 2021

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The leaf vascular bundle sheath cells (BSCs) that tightly envelop the leaf veins, are a selective and dynamic barrier to xylem sap water and solutes radially entering the mesophyll cells. Under normal conditions, xylem sap pH below 6 is presumably important for driving and regulating the transmembranal solute transport. Having discovered recently a differentially high expression of a BSC proton pump, AHA2, we now test the hypothesis that it regulates the xylem sap pH and leaf radial water fluxes. We monitored the xylem sap pH in the veins of detached leaves of wild-type Arabidopsis, AHA mutants and aha2 mutants complemented with AHA2 gene solely in BSCs. We tested an AHA inhibitor (vanadate) and stimulator (fusicoccin), and different pH buffers. We monitored their impact on the xylem sap pH and the leaf hydraulic conductance (K leaf ), and the effect of pH on the water osmotic permeability (P f ) of isolated BSCs protoplasts. We found that AHA2 is necessary for xylem sap acidification, and in turn, for elevating K leaf . Conversely, AHA2 knockdown, which alkalinized the xylem sap, or, buffering its pH to 7.5, reduced K leaf , and elevating external pH to 7.5 decreased the BSCs P f . All these showed a causative link between AHA2 activity in BSCs and leaf radial hydraulic water conductance.

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Arabidopsis leaf hydraulic conductance is regulated by xylem-sap pH, controlled, in turn, by a P-type H⁺-ATPase of vascular bundle sheath cells

Grunwald

Wigoda

Sade

et al. 2017

Preprint

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The leaf vascular bundle sheath cells (BSCs) that tightly envelop the leaf veins, are a selective and dynamic barrier to xylem-sap water and solutes radially entering the mesophyll cells. Under normal conditions, xylem-sap pH of <6 is presumably important for driving and regulating the transmembranal solute transport. Having discovered recently a differentially high expression of a BSC proton pump, AHA2, we now test the hypothesis that it regulates this pH and leaf radial water fluxes.We monitored the xylem-sap pH using the ratiometric fluorescent probe FITC-dextran fed into veins of detached leaves of WT Arabidopsis, AHA mutants, and aha2 mutants complemented with AHA2 gene solely in BSCs. We tested an AHA inhibitor and stimulator, and different pH buffers. We monitored their impact on the xylem-sap pH, the whole leaf hydraulic conductance (Kleaf) and the water osmotic permeability of isolated BSCs protoplasts (Pf).Our results demonstrated AHA2 indispensability for xylem-sap acidification, necessary, in turn, for elevating Pf and Kleaf. Conversely, elevating xylem-sap pH to 7.5, reduced significantly both Pf and Kleaf.All these demonstrate a causative link between AHA2 activity in BSCs and leaf water influx. This positions the BSCs as a pH-controlled transpiration valve in series with the stomata.One-sentence summaryBundle-sheath cells can control the leaf hydraulic conductance by proton-pump-regulated xylem sap pH

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Noa Wigoda

The gibberellin‐induced, cysteine‐rich protein GIP2 from Petunia hybrida exhibits in planta antioxidant activity

Differential gene expression and transport functionality in the bundle sheath versus mesophyll – a potential role in leaf mineral homeostasis

Arabidopsis leaf hydraulic conductance is regulated by xylem sap pH, controlled, in turn, by a P‐type H⁺‐ATPase of vascular bundle sheath cells

Arabidopsis leaf hydraulic conductance is regulated by xylem-sap pH, controlled, in turn, by a P-type H⁺-ATPase of vascular bundle sheath cells

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Noa Wigoda

The gibberellin‐induced, cysteine‐rich protein GIP2 from Petunia hybrida exhibits in planta antioxidant activity

Differential gene expression and transport functionality in the bundle sheath versus mesophyll – a potential role in leaf mineral homeostasis

Arabidopsis leaf hydraulic conductance is regulated by xylem sap pH, controlled, in turn, by a P‐type H+‐ATPase of vascular bundle sheath cells

Arabidopsis leaf hydraulic conductance is regulated by xylem-sap pH, controlled, in turn, by a P-type H+-ATPase of vascular bundle sheath cells

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Arabidopsis leaf hydraulic conductance is regulated by xylem sap pH, controlled, in turn, by a P‐type H⁺‐ATPase of vascular bundle sheath cells

Arabidopsis leaf hydraulic conductance is regulated by xylem-sap pH, controlled, in turn, by a P-type H⁺-ATPase of vascular bundle sheath cells