The Role of PIP2 in the Voltage-Dependent Activation of Kv7.1

Abstract

Phosphatidylinositol 4,5-bisphosphate (PIP2) is an important regulator of ion channel activity. While PIP2 modulation of voltage-independent Kir channels has been extensively studied, the mechanism of how PIP2 potentiates the activity of voltage-dependent ion channels remains uknown. In this work, we study PIP2 activation of a voltage-dependent potassium channel (Kv7.1). Kv7.1 channels have a canonical Kv structure with a central pore-gate domain (PGD) surrounded by four peripheral voltage-sensing domains (VSDs). Kv channel activation is thought to involve two general steps. First, membrane depolarization is sensed by gating charges in the VSDs resulting in conformational changes within the VSDs from the resting state to the activated state. After all four VSDs have been activated, the second general step in Kv activation involves a concerted motion during which the PGD opens to allow ion permeation. In this study we ask if PIP2 regulates activation of Kv7.1 by potentiating the early VSD conformational changes, the concerted opening of the PGD, or both. Using the voltage-clamp fluorometry (VCF) technique to assay local conformation changes in the VSDs and the PGD simultaneously, we are able to show that although depletion of PIP2 eliminates the ionic current, the early conformational changes in the VSD do not require PIP2. This result indicates that the later conformational changes that couple VSD activation to the opening of the PGD are eliminated by PIP2 depletion. We continue this work by dissecting the molecular details of why PIP2 is required for opening of the PGD in response to VSD activation. These results may provide insights on the common principle of how Kv channels are modulated by PIP2.