Human KCC2a Protein Expression and Phosphorylation is Altered by Elimination of the Second Cryo-EM Identified Chloride Binding Site

Abstract

Background: Potassium-chloride cotransporters (KCCs) are responsible for the symport of Cl- with K+ in an electroneutral manner. They play important roles in numerous crucial physiological processes, from cell volume regulation to transepithelial solute transport, intracellular ion homeostasis and regulation of GABA neurotransmission. Under isotonicity, except for KCC2, KCCs remain inhibited due to phosphorylation of residues located in cytoplasmic domains, whereas in response to hypotonic cell swelling, dephosphorylation of these residues stimulates transport activity. After several decades of studies, new breakthroughs with the cryo-EM structural determination of KCCs have deepened our understanding of their molecular basis and transport function, including architecture, ion binding sites, and coupled ion transport. In the present study, we mutated and analyzed the two chloride-binding sites in human KCC2a recently reported by cryo-EM to determine whether the phosphorylation status is modified upon their removal. Methods: Xenopus laevis oocytes and HEK-293 cells were either microinjected or transfected with human KCC2a wild type (WT) or chloride-binding site mutants, G136/V137/I138A (S1-Cl), and G436/I437/M438/Y592A (S2-Cl). KCC2a phosphorylation status in response to isotonic and hypotonic conditions was evaluated by immunoblot analysis of regulatory phosphorylation sites pThr926 and pThr1030. In parallel, phosphorylation status of SPAK/OSR1 activating regulatory site pSer373/pSer325 was analyzed under the same conditions. Results: Elimination of either chloride-binding site induced changes in total expression of KCC2a. Removal of S1-Cl slightly increased total KCC2a expression, whereas lack of S2-Cl showed a significant reduction of total protein in Xenopus laevis oocytes and HEK-293 cells. Phosphorylation of regulatory Thr1030 in S2-Cl mutant is significatively decreased on both biological models, even under isotonic inhibitory (phosphorylated) conditions. pThr1030 on S1-Cl mutant behaves similarly to WT KCC2a. Phosphorylation of regulatory SPAK kinase is not affected on both mutants. Conclusions: Our results suggest that while both sites affect KCC2a total expression, only the S2-Cl appears to be affecting KCC2a activating response. It appears S2-Cl mutation dysregulates SPAK signaling pathway, since the kinase osmotic response remains unchanged on presence of KCC2a chloride binding mutants. AM INCar 22-1345 and PdlH UNAM Papiit IN222320 This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.