Doron Shkolnik scite author profile

Abscisic acid stress ripening 1 (ASR1) is a low molecular weight plant-specific protein encoded by an abiotic stress-regulated gene. Overexpression of ASR1 in transgenic plants increases their salt tolerance. The ASR1 protein possesses a zinc-dependent DNA-binding activity. The DNA-binding site was mapped to the central part of the polypeptide using truncated forms of the protein. Two additional zinc-binding sites were shown to be localized at the amino terminus of the polypeptide. ASR1 protein is presumed to be an intrinsically unstructured protein using a number of prediction algorithms. The degree of order of ASR1 was determined experimentally using nontagged recombinant protein expressed in Escherichia coli and purified to homogeneity. Purified ASR1 was shown to be unfolded using dynamic light scattering, gel filtration, microcalorimetry, circular dichroism, and Fourier transform infrared spectrometry. The protein was shown to be monomeric by analytical ultracentrifugation. Addition of zinc ions resulted in a global change in ASR1 structure from monomer to homodimer. Upon binding of zinc ions, the protein becomes ordered as shown by Fourier transform infrared spectrometry and microcalorimetry, concomitant with dimerization. Tomato (Solanum lycopersicum) leaf soluble ASR1 is unstructured in the absence of added zinc and gains structure upon binding of the metal ion. The effect of zinc binding on ASR1 folding and dimerization is discussed.

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Reactive oxygen species tune root tropic responses

Krieger

Shkolnik

Miller

et al. 2016

Plant Physiol.

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The default growth pattern of primary roots of land plants is directed by gravity. However, roots possess the ability to sense and respond directionally to other chemical and physical stimuli, separately and in combination. Therefore, these root tropic responses must be antagonistic to gravitropism. The role of reactive oxygen species (ROS) in gravitropism of maize and Arabidopsis (Arabidopsis thaliana) roots has been previously described. However, which cellular signals underlie the integration of the different environmental stimuli, which lead to an appropriate root tropic response, is currently unknown. In gravity-responding roots, we observed, by applying the ROS-sensitive fluorescent dye dihydrorhodamine-123 and confocal microscopy, a transient asymmetric ROS distribution, higher at the concave side of the root. The asymmetry, detected at the distal elongation zone, was built in the first 2 h of the gravitropic response and dissipated after another 2 h. In contrast, hydrotropically responding roots show no transient asymmetric distribution of ROS. Decreasing ROS levels by applying the antioxidant ascorbate, or the ROS-generation inhibitor diphenylene iodonium attenuated gravitropism while enhancing hydrotropism. Arabidopsis mutants deficient in Ascorbate Peroxidase 1 showed attenuated hydrotropic root bending. Mutants of the root-expressed NADPH oxidase RBOH C, but not rbohD, showed enhanced hydrotropism and less ROS in their roots apices (tested in tissue extracts with Amplex Red). Finally, hydrostimulation prior to gravistimulation attenuated the gravistimulated asymmetric ROS and auxin signals that are required for gravity-directed curvature. We suggest that ROS, presumably H 2 O 2 , function in tuning root tropic responses by promoting gravitropism and negatively regulating hydrotropism.

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MIZ1 regulates ECA1 to generate a slow, long-distance phloem-transmitted Ca²⁺signal essential for root water tracking inArabidopsis

Shkolnik

Nuriel

Bonza

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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SignificancePlant roots grow toward water, a phenomenon termed hydrotropism. The nature of the root signal that governs hydrotropism is elusive and remains to be elucidated. Here, we show that, in response to water potential differences across the root tip, a slow, asymmetric long-distance Ca2+ signal is transmitted via the phloem to the elongation zone, where it is asymmetrically distributed across the root to promote root curvature. Furthermore, we demonstrate that the hydrotropism-associated protein MIZ1 plays a role in generating the Ca2+ signal by its direct binding to and inhibition of ECA1, an endoplasmic reticulum Ca2+ pump, which resembles the animal sarco/endoplasmic reticulum Ca2+-ATPases (SERCAs). This study elucidates the mechanism underlying systemic Ca2+ signaling in plant roots, which is essential for water tracking.

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Hydrotropism: Root Bending Does Not Require Auxin Redistribution

et al. 2016

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Doron Shkolnik

Desiccation and Zinc Binding Induce Transition of Tomato Abscisic Acid Stress Ripening 1, a Water Stress- and Salt Stress-Regulated Plant-Specific Protein, from Unfolded to Folded State

Reactive oxygen species tune root tropic responses

MIZ1 regulates ECA1 to generate a slow, long-distance phloem-transmitted Ca²⁺signal essential for root water tracking inArabidopsis

Hydrotropism: Root Bending Does Not Require Auxin Redistribution

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Doron Shkolnik

Desiccation and Zinc Binding Induce Transition of Tomato Abscisic Acid Stress Ripening 1, a Water Stress- and Salt Stress-Regulated Plant-Specific Protein, from Unfolded to Folded State

Reactive oxygen species tune root tropic responses

MIZ1 regulates ECA1 to generate a slow, long-distance phloem-transmitted Ca2+signal essential for root water tracking inArabidopsis

Hydrotropism: Root Bending Does Not Require Auxin Redistribution

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Product

Resources

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MIZ1 regulates ECA1 to generate a slow, long-distance phloem-transmitted Ca²⁺signal essential for root water tracking inArabidopsis