Interaction of PIP2 with the XIP region of the cardiac Na/Ca exchanger

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Interaction of PIP₂ with the XIP region of the cardiac Na/Ca exchanger

Zhaoping He¹, Siyi Feng², Qiusheng Tong², Donald W. Hilgemann², and Kenneth D. Philipson¹

¹ Departments of Physiology and Medicine and the Cardiovascular Research Laboratories, University of California, Los Angeles, School of Medicine, Los Angeles, California 90095-1760; and ² Department of Physiology, University of Texas, Southwestern Medical Center, Dallas, Texas 75235-9040

The sarcolemmal Na/Ca exchanger undergoes an inactivation process in which exchange activity decays over several seconds followingactivation by the application of Na to the intracellular surfaceof the protein. Inactivation is eliminated by an increase in membranephosphatidylinositol 4,5-bisphosphate (PIP₂). Inactivation isalso strongly affected by mutations to a basic 20-amino acid segmentof the exchanger known as the endogenous XIP region. The hypothesisthat PIP₂ directly interacts with the XIP region of the exchangerwas tested. First, we investigated the ability of a peptide withthe same sequence as the XIP region to bind to immobilized phospholipidvesicles. ¹²⁵I-labeled XIP bound avidly to vesicles containing only a low concentration(<3%) of PIP₂. The binding was specific, in that binding was notdisplaced by other basic peptides. The effects of altering thesequence of XIP peptides also indicated binding specificity. Second,we examined the functional response to PIP₂ of exchangers withmutated XIP regions. Outward Na/Ca exchange currents were measuredusing the giant excised patch technique. The mutated exchangerseither had no inactivation or accelerated inactivation. In bothcases, the exchangers no longer responded to PIP₂ or to PIP₂ antibodies.Overall, the data indicate that the affinity of the endogenousXIP region for PIP₂ is an important determinant of the inactivationprocess.

NCX1.1; calcium transport; inactivation; regulation

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