The plant hormone cytokinin is perceived by membrane-located sensor histidine kinases. Arabidopsis (Arabidopsis thaliana) possesses three cytokinin receptors: ARABIDOPSIS HISTIDINE KINASE2 (AHK2), AHK3, and CYTOKININ RESPONSE1/ AHK4. The current model predicts perception of the cytokinin signal at the plasma membrane. However, cytokinin-binding studies with membrane fractions separated by two-phase partitioning showed that in the wild type, as well as in mutants retaining only single cytokinin receptors, the major part of specific cytokinin binding was associated with endomembranes. Leaf epidermal cells of tobacco (Nicotiana benthamiana) expressing receptor-green fluorescent protein fusion proteins and bimolecular fluorescence complementation analysis showed strong fluorescence of the endoplasmic reticulum (ER) network for all three receptors. Furthermore, separation of the microsomal fraction of Arabidopsis plants expressing Myc-tagged AHK2 and AHK3 receptors by sucrose gradient centrifugation followed by immunoblotting displayed the Mg 2+ -dependent density shift typical of ER membrane proteins. Cytokinin-binding assays, fluorescent fusion proteins, and biochemical fractionation all showed that the large majority of cytokinin receptors are localized to the ER, suggesting a central role of this compartment in cytokinin signaling. A modified model for cytokinin signaling is proposed.
SummaryPlant outward-rectifying K þ channels mediate K þ efflux from guard cells during stomatal closure and from root cells into the xylem for root-shoot allocation of potassium (K). Intriguingly, the gating of these channels depends on the extracellular K þ concentration, although the ions carrying the current are derived from inside the cell. This K þ dependence confers a sensitivity to the extracellular] prevailing outside. We investigated the mechanism of K þ -dependent gating of the K þ channel SKOR of Arabidopsis by site-directed mutagenesis. Mutations affecting the intrinsic K þ dependence of gating were found to cluster in the pore and within the sixth transmembrane helix (S6), identifying an 'S6 gating domain' deep within the membrane. Mapping the SKOR sequence to the crystal structure of the voltage-dependent K þ channel KvAP from Aeropyrum pernix suggested interaction between the S6 gating domain and the base of the pore helix, a prediction supported by mutations at this site. These results offer a unique insight into the molecular basis for a physiologically important K þ -sensory process in plants.
Background: In plants the hormone cytokinin is perceived by members of a small cytokinin receptor family, which are hybrid sensor histidine kinases. While the immediate downstream signaling pathway is well characterized, the domain of the receptor responsible for ligand binding and which residues are involved in this process has not been determined experimentally.
The plant hormone cytokinin is implicated in a large number of developmental and physiological processes. In the model plant Arabidopsis thaliana cytokinin is perceived by a class of membrane-bound receptor histidine kinases with three members, namely AHK2, AHK3, and CRE1/AHK4. These receptors possess an N-terminally located putative extracellular cyclases/histidine kinases associated sensor extracellular (CHASE) domain, which is responsible for hormone recognition. This hydrophilic domain and the two flanking transmembrane regions (CHASE-TM) were expressed using a cell-free protein expression system based on a bacterial ribosomal extract. To obtain soluble CHASE-TM protein, different detergents were directly added to the cell-free reaction and their effect on the yield of soluble protein was studied. After optimising the experimental set-up and employing Brij 58 as a detergent more than 3 mg/ml soluble protein of the CHASE-TM domain were obtained. Affinity purification via a C-terminally fused His-tag resulted in greater than 90% purity. The identity of the purified domain was confirmed by matrix-assisted laser desorption/ionization mass spectrometry (MALDI-MS) analysis. Circular dichroism spectroscopy was used and a predominantly α-helical folding pattern was shown, which is in good accordance with secondary structure prediction. A newly developed cytokinin binding assay confirmed the functionality of the thus expressed and purified CHASE-TM domain. The work presented clearly demonstrates the feasibility of producing high amounts of a plant membrane protein using a cell-free protein expression system. This opens the possibility of further biochemical and pharmacological analysis, as well as structural studies on this type of receptor protein.
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