Dominik Oliver

Gating of Ca2+-Activated K+ Channels Controls Fast Inhibitory Synaptic Transmission at Auditory Outer Hair Cells

Fast inhibitory synaptic transmission in the central nervous system is mediated by ionotropic GABA or glycine receptors. Auditory outer hair cells present a unique inhibitory synapse that uses a Ca2+-permeable excitatory acetylcholine receptor to activate a hyperpolarizing potassium current mediated by small conductance calcium-activated potassium (SK) channels. It is shown here that unitary inhibitory postsynaptic currents at this synapse are mediated by SK2 channels and occur rapidly, with rise and decay time constants of approximately 6 ms and approximately 30 ms, respectively. This time course is determined by the Ca2+ gating of SK channels rather than by the changes in intracellular Ca2+. The results demonstrate fast coupling between an excitatory ionotropic neurotransmitter receptor and an inhibitory ion channel and imply rapid, localized changes in subsynaptic calcium levels.

Protein Kinase CK2 Is Coassembled with Small Conductance Ca2+-Activated K+ Channels and Regulates Channel Gating

Small conductance Ca(2+)-activated K+ channels (SK channels) couple the membrane potential to fluctuations in intracellular Ca2+ concentration in many types of cells. SK channels are gated by Ca2+ ions via calmodulin that is constitutively bound to the intracellular C terminus of the channels and serves as the Ca2+ sensor. Here we show that, in addition, the cytoplasmic N and C termini of the channel protein form a polyprotein complex with the catalytic and regulatory subunits of protein kinase CK2 and protein phosphatase 2A. Within this complex, CK2 phosphorylates calmodulin at threonine 80, reducing by 5-fold the apparent Ca2+ sensitivity and accelerating channel deactivation. The results show that native SK channels are polyprotein complexes and demonstrate that the balance between kinase and phosphatase activities within the protein complex shapes the hyperpolarizing response mediated by SK channels.

Expression density and functional characteristics of the outer hair cell motor protein are regulated during postnatal development in rat

1 The non‐linear capacitance (Cnon‐lin) of postnatal outer hair cells (OHCs) of the rat was measured by a patch‐clamp lock‐in technique. Cnon‐lin is thought to result from a membrane protein that provides the molecular basis for the unique electromotility of OHCs by undergoing conformational changes in response to changes in membrane potential (Vm). Protein conformation is coupled to Vm by a charged voltage sensor, which imposes Cnon‐lin on the OHC. Cnon‐lin was investigated in order to characterize the surface expression and voltage dependence of this motor protein during postnatal development. 2 On the day of birth (P0), Cnon‐lin was not detected in OHCs of the basal turn of the cochlea, whilst it was 89 fF in apical OHCs. Cnon‐lin increased gradually during postnatal development and reached 2.3 pF (basal turn, P9) and 7.5 pF (apical turn, P14) at the oldest developmental stages covered by our measurements. The density of the protein in the plasma membrane, deduced from non‐linear charge movement per membrane area, increased steeply between P6 and P11 and reached steady state (4200 e−μm−2) at about P12. 3 Voltage at peak capacitance (V½) shifted with development from hyperpolarized potentials shortly after birth (‐88.3 mV, P2) to the depolarized potential characteristic of mature OHCs (‐40.8 mV, P14). This developmental difference in V½ was also observed in outside‐out patches immediately after patch excision. During subsequent wash‐out V½ shifted towards the depolarized value found in the adult state, suggesting a direct modulation of the molecular motor. 4 Thus, the density of the motor protein in the plasma membrane and also its voltage dependence change concomitantly in the postnatal period and reach adult characteristics right at the onset of hearing.

Ci-VSP Is a Depolarization-activated Phosphatidylinositol-4,5-bisphosphate and Phosphatidylinositol-3,4,5-trisphosphate 5′-Phosphatase

Phosphoinositides are membrane-delimited regulators of protein function and control many different cellular targets. The differentially phosphorylated isoforms have distinct concentrations in various subcellular membranes, which can change dynamically in response to cellular signaling events. Maintenance and dynamics of phosphoinositide levels involve a complex set of enzymes, among them phospholipases and lipid kinases and phosphatases. Recently, a novel type of phosphoinositide-converting protein (termed Ci-VSP) that contains a voltage sensor domain was isolated. It was already shown that Ci-VSP can alter phosphoinositide levels in a voltage-dependent manner. However, the exact enzymatic reaction catalyzed by Ci-VSP is not known. We used fluorescent phosphoinositide-binding probes and total internal reflection microscopy together with patch-clamp measurements from living cells to delineate substrates and products of Ci-VSP. Upon activation of Ci-VSP by membrane depolarization, membrane association of phosphatidylinositol (PI) (4,5)P2- and PI(3,4,5)P3-specific binding domains decreased, revealing consumption of these phosphoinositides by Ci-VSP. Depletion of PI(4,5)P2 was coincident with an increase in membrane PI(4)P. Similarly, PI(3,4)P2 was generated during depletion of PI(3,4,5)P3. These results suggest that Ci-VSP acts as a 5′-phosphatase of PI(4,5)P2 and PI(3,4,5)P3.

Nonmammalian orthologs of prestin (SLC26A5) are electrogenic divalent/chloride anion exchangers

Individual members of the mammalian SLC26 anion transporter family serve two fundamentally distinct functions. Whereas most members transport different anion substrates across a variety of epithelia, prestin (SLC26A5) is special, functioning as a membrane-localized motor protein that generates electrically induced motions (electromotility) in auditory sensory hair cells of the mammalian inner ear. The transport mechanism of SLC26 proteins is not well understood, and a mechanistic relation between anion transport and electromotility has been suggested but not firmly established so far. To address these questions, we have cloned prestin orthologs from chicken and zebrafish, nonmammalian vertebrates that presumably lack electromotility in their auditory systems. Using patch-clamp recordings, we show that these prestin orthologs, but not mammalian prestin, generate robust transport currents in the presence of the divalent anions sulfate or oxalate. Transport is blocked by salicylate, an inhibitor of electromotility generated by mammalian prestin. The dependence of transport equilibrium potentials on sulfate and chloride concentration gradients shows that the prestin orthologs are electrogenic antiporters, exchanging sulfate or oxalate for chloride in a strictly coupled manner with a 1:1 stoichiometry. These data identify transport mode and stoichiometry of electrogenic divalent/monovalent anion exchange and establish a reliable and simple method for the quantitative determination of the various transport modes that have been proposed for other SLC26 transport proteins. Moreover, the sequence conservation between mammalian and nonmammalian prestin together with a common pharmacology of electromotility and divalent antiport suggest that the molecular mechanism behind electromotility is closely related to an anion transport cycle.

Prestin, the Motor Protein of Outer Hair Cells

Prestin is a gene recently cloned from mammalian cochlear outer hair cells (OHC) using a single cell type, outer minus inner hair cell, specific suppressive subtractive hybridization procedure. The localization and gene expression profile of the prestin protein fits the pattern of OHC’s development of electromotility. When prestin is abundantly expressed in normally nonmotile kidney cells, nonlinear capacitance and motility that are normally only seen in OHCs can be recorded. Furthermore, both nonlinear capacitance and motility can be reduced by salicylate, a well-known inhibitor of electromotility. These data suggest that prestin is the motor protein of OHCs. Amino acid sequence and gene structure analysis indicate that prestin is the fifth member of a newly discovered anion transport family (SLC26) that includes PDS, DRA and DTDST, which are chloride-iodide transporters, Cl–/HCO–3 exchangers or sulfate transporters. Prestin shares overall structure similarity with this anion transporter family. Recently, intracellular anions (chloride or bicarbonate) were found to be essential for OHC electromotility and prestin’s function.

The Role of BKCa Channels in Electrical Signal Encoding in the Mammalian Auditory Periphery

Large-conductance voltage- and Ca2+-activated K+ channels (BKCa) are involved in shaping spiking patterns in many neurons. Less is known about their role in mammalian inner hair cells (IHCs), mechanosensory cells with unusually large BKCa currents. These currents may be involved in shaping the receptor potential, implying crucial importance for the properties of afferent auditory signals. We addressed the function of BKCa by recording sound-induced responses of afferent auditory nerve (AN) fibers from mice with a targeted deletion of the pore-forming α-subunit of BKCa (BKα−/−) and comparing these with voltage responses of current-clamped IHCs. BKCa-mediated currents in IHCs were selectively abolished in BKα−/−, whereas cochlear physiology was essentially normal with respect to cochlear sensitivity and frequency tuning. BKα−/− AN fibers showed deteriorated precision of spike timing, measured as an increased variance of first spike latency in response to tone bursts. This impairment could be explained by a slowed voltage response in the presynaptic IHC resulting from the reduced K+ conductance in the absence of BKCa. Maximum spike rates of AN fibers were reduced nearly twofold in BKα−/−, contrasting with increased voltage responses of IHCs. In addition to presynaptic changes, which may be secondary to a modest depolarization of BKα−/− IHCs, this reduction in AN rates suggests a role of BKCa in postsynaptic AN neurons, which was supported by increased refractory periods. In summary, our results indicate an essential role of IHC BKCa channels for precise timing of high-frequency cochlear signaling as well as a function of BKCa in the primary afferent neuron.

Interaction of Permeant and Blocking Ions in Cloned Inward-Rectifier K+ Channels

Blocking cloned inward-rectifier potassium (Kir) channels from the cytoplasmic side was analyzed with a rapid application system exchanging the intracellular solution on giant inside-out patches from Xenopus oocytes in <2 ms. Dependence of the pore-block on interaction of the blocking molecule with permeant and impermeant ions on either side of the membrane was investigated in Kir1.1 (ROMK1) channels blocked by ammonium derivatives and in Kir4.1 (BIR10) channels blocked by spermine. The blocking reaction in both systems showed first-order kinetics and allowed separate determination of on- and off-rates. The off-rates of block were strongly dependent on the concentration of internal and external bulk ions, but almost independent of the ion species at the cytoplasmic side of the membrane. With K+ as the only cation on both sides of the membrane, off-rates exhibited strong coupling to the K+ reversal potential (E(K)) and increased and decreased with reduction in intra and extracellular K+ concentration, respectively. The on-rates showed significant dependence on concentration and species of internal bulk ions. This control of rate-constants by interaction of permeant and impermeant internal and external ions governs the steady-state current-voltage relation (I-V) of Kir channels and determines their physiological function under various conditions.

Probing the regulation of TASK potassium channels by PI(4,5)P2 with switchable phosphoinositide phosphatases

Non‐technical summary  The electrical activity of nerve cells is produced by the flux of ions through specialized membrane proteins called ion channels. Some ion channels can be regulated by the signalling lipid PIP2, a component of the channels’ membrane environment. Here we examine the relevance of PIP2 for the regulation of one specific channel type, termed TASK. Many chemical transmitters in the brain change neural activity by shutting off TASK channels and it has been suggested that this results from reduction of PIP2. By using novel techniques to alter the concentration of PIP2 in living cells, we find that the activity of TASK is independent of PIP2. Besides demonstrating that another signalling mechanism must control the activity of nerve cells via TASK inhibition, we delineate a general approach for clarifying the relevance of PIP2 in many cell types and organs.

Sodium current expression during postnatal development of rat outer hair cells

Abstract Outer hair cells of the cultured organ of Corti from newborn rats (0–11 days after birth) were studied in the whole-cell patch-clamp configuration. A voltage-activated sodium current was detected in 97% (n = 109) of the cells at 0–9 days after birth. The properties of this current were: (1) its activation and inactivation kinetics were fast and voltage-dependent, (2) the voltage at half-maximum activation was –45.0 mV, (3) its steady-state inactivation was temperature-sensitive (the half-inactivating voltage was –92.6 mV at 23°C and –84.8 mV at 37°C), (4) the reversal potential (80 mV) was close to the sodium equilibrium potential and currents could be abolished by the removal of extracellular sodium, and (5) tetrodotoxin blocked the current with a Kd of 474 nmol/l. Current amplitudes were up to 1.7 nA at room temperature. Mean current amplitudes showed a developmental time course with a maximum at postnatal days 3 and 7 for outer hair cells from the basal and apical part of the cochlea, respectively. In current-clamp mode cells had membrane potentials of –59.7 ± 11.7 mV (n = 9). When cells were hyperpolarized by constant current injection, depolarizing currents were able to trigger action potentials. At 18 days after birth, sodium currents were greatly reduced and barely detectable. The results show that, unlike adult outer hair cells, immature outer hair cells regularly express voltage-gated sodium channels. However, due to mismatching of the sodium current inactivation range and membrane potential in vitro, a physiological function appears questionable.