[Atomic force microscope (AFM). A nanomanipulator for biophysical studies of stereocilia of the cochlear hair cells]. / Das Rasterkraftmikroskop (AFM). Ein Nanomanipulator für biophysikalische Untersuchungen an Stereozilien der Sinneszellen der Kochlea.

OBJECTIVES: Studies of the mechanoelectrical sensor system of the hair cell bundle in the cochlea require a manipulation device that enables controlled force application and movement of individual stereocilia in the nanometer range. METHODS: In our atomic force microscope (AFM) setup, the scan is directly controlled in an upright differential interference contrast (DIC) infrared video microscope with a water immersion objective and in the measured AFM image. Here we present studies on hair cells of the mammalian cochlea. RESULTS AND CONCLUSIONS: The resulting images revealed the tips of individual stereocilia of living sensory cells of the organ of Corti and the typical shape of the ciliary bundle. Scanning electron-microscopic (SEM) images of the identical hair bundles obtained after AFM investigation demonstrated that up to four AFM manipulations on the same cell did not cause obvious damage to the surface morphology of the stereocilia.

Expression of Ca(2+)-activated K(+) channel subunits and splice variants in the rat cochlea.

The recently manifested important role of the Ca(2+)-activated K(+) channels, especially of the Slo gene-coded channels, for the cochlea function of the chicken raised the question of homolog expression in mammalian inner ear tissue. Molecular biological methods were used to demonstrate the expression of Ca(2+)-activated K(+) channel subunits and splice variants of the Slo gene in the rat organ of Corti. RT-PCR experiments for the detection of rat Slo alpha subunit mRNA revealed the presence of several already known splice variants including variants which appeared to be typical for the organ of Corti (+58 aa) and for the brain (+61 aa). To detect the accessory beta subunit we used Southern blot hybridization. Our data support the hypothesis that Ca(2+)-activated K(+) channel subunits (i.e. Slo variants) are also involved in the hearing of mammals in the organ of Corti.

Molecular and functional characterization of acid-sensing ion channel (ASIC) 1b.

Acid-sensing ion channels (ASICs) are activated by extracellular protons and are involved in neurotransmission in the central nervous system, in pain perception, as well as in mechanotransduction. Six different ASIC subunits have been cloned to date, which are encoded by four genes (ASIC1-ASIC4). Proton-gated currents have been described in isolated neurons from sensory ganglia as well as from central nervous system. However, it is largely unclear which of the cloned ASIC subunits underlie these native proton-gated currents. Recently, a splice variant, ASIC-beta, has been described for ASIC1a. In this variant about one-third of the protein is exchanged at the N terminus. Here we show that ASIC-beta has a longer N terminus than previously reported, extending the sequence divergence between ASIC1a and this new variant (ASIC1b). We investigated in detail kinetic and selectivity properties of ASIC1b in comparison to ASIC1a. Kinetics is similar for ASIC1b and ASIC1a. Ca(2+) permeability of ASIC1a is low, whereas ASIC1b is impermeable to Ca(2+). Currents through ASIC1a resemble currents, which have been described in sensory and central neurons, whereas the significance of ASIC1b remains to be established. Moreover, we show that a pre-transmembrane 1 domain controls the permeability to divalent cations in ASIC1, contributing to our understanding of the pore structure of these channels.

Intracellular anions as the voltage sensor of prestin, the outer hair cell motor protein.

Outer hair cells (OHCs) of the mammalian cochlea actively change their cell length in response to changes in membrane potential. This electromotility, thought to be the basis of cochlear amplification, is mediated by a voltage-sensitive motor molecule recently identified as the membrane protein prestin. Here, we show that voltage sensitivity is conferred to prestin by the intracellular anions chloride and bicarbonate. Removal of these anions abolished fast voltage-dependent motility, as well as the characteristic nonlinear charge movement ("gating currents") driving the underlying structural rearrangements of the protein. The results support a model in which anions act as extrinsic voltage sensors, which bind to the prestin molecule and thus trigger the conformational changes required for motility of OHCs.

Memantine inhibits efferent cholinergic transmission in the cochlea by blocking nicotinic acetylcholine receptors of outer hair cells.

Memantine is a blocker of Ca(2+)-permeable glutamate and nicotinic acetylcholine receptors (nAChR). We investigated the action of memantine on cholinergic synaptic transmission at cochlear outer hair cells (OHCs). At this inhibitory synapse, hyperpolarization of the postsynaptic cell results from opening of SK-type Ca(2+)-activated K(+) channels via a highly Ca(2+)-permeable nAChR containing the alpha 9 subunit. We show that inhibitory postsynaptic currents recorded from OHCs were reversibly blocked by memantine with an IC(50) value of 16 microM. RT-PCR revealed that a newly cloned nAChR subunit, alpha 10, is expressed in OHCs. In contrast to homomeric expression, coexpression of alpha 9 and alpha 10 subunits in Xenopus laevis oocytes resulted in robust acetylcholine-induced currents, indicating that the OHC nAChR may be an alpha 9/alpha 10 heteromer. Accordingly, nAChR currents evoked by application of the ligand to OHCs and currents through alpha 9/alpha 10 were blocked by memantine with a similar IC(50) value of about 1 microM. Memantine block of alpha 9/alpha 10 was moderately voltage dependent. The lower efficacy of memantine for inhibition of inhibitory postsynaptic currents (IPSCs) most probably results from a blocking rate that is slow with respect to the short open time of the receptor channels during an IPSC. Thus, synaptic transmission in OHCs is inhibited by memantine block of Ca(2+) influx through nAChRs. Importantly, prolonged receptor activation and consequently massive Ca(2+) influx, as might occur under pathological conditions, is blocked at low micromolar concentrations, whereas the fast IPSCs initiated by short receptor activation are only blocked at concentrations above 10 microM.

Lateral mechanical coupling of stereocilia in cochlear hair bundles.

For understanding the gating process of transduction channels in the inner ear it is essential to characterize and examine the functional properties of the ultrastructure of stereociliary bundles. There is strong evidence that transduction channels in hair cells are gated by directly pulling at the so-called tip links. In addition to these tip links a second class of filamentous structures was identified in the scanning and transmission electron microscope: the side-to-side links. These links laterally connect stereocilia of the same row of a hair bundle. This study concentrates on mechanical coupling of stereocilia of the tallest row connected by side-to-side links. Atomic Force microscopy (AFM) was used to investigate hair bundles of outer hair cells (OHCs) from postnatal rats (day 4). Although hair bundles of postnatal rats are still immature at day 4 and interconnecting cross-links do not show preferential direction yet, hair bundles of investigated OHCs already showed the characteristic V-shape of mature hair cells. In a first experiment, the stiffness of stereocilia was investigated scanning individual stereocilia with an AFM tip. The spring constant for the excitatory direction was 2.5 +/- 0.6 x 10(-3) N/m whereas a higher spring constant (3.1 +/- 1.5 x 10(-3) N/m) was observed in the inhibitory direction. In a second set of experiments, the force transmission between stereocilia of the tallest row was measured using AFM in combination with a thin glass fiber. This fiber locally displaced a stereocilium while the force laterally transmitted to the neighboring untouched taller stereocilia was measured by AFM. The results show a weak force interaction between tallest stereocilia of postnatal rats. The force exerted to an individual stereocilium declines to 36% at the nearest adjacent stereocilium of the same row not touched with the fiber. It is suggested that the amount of force transmitted from a taller stereocilium to an adjacent one of the same row depends on the orientation of links. Maximum force transmission is expected to appear along the axis of interconnecting side links. In our studies it is suggested that transmitted forces are small because connecting side links are oriented very close to an angle of 90 degrees with respect of the scan direction (excitatory-inhibitory direction).

Phospholipids as modulators of K(ATP) channels: distinct mechanisms for control of sensitivity to sulphonylureas, K(+) channel openers, and ATP.

Recent work has established membrane phospholipids such as phosphatidylinositol-4,5-bisphosphate (PIP(2)) as potent regulators of K(ATP) channels controlling open probability and ATP sensitivity. We here investigated the effects of phospholipids on the pharmacological properties of cardiac type K(ATP) (Kir6.2/SUR2A) channels. In excised membrane patches K(ATP) channels showed considerable variability in sensitivity to glibenclamide and ATP. Application of the phosphatidylinositol phosphates (PIPs) phosphatidylinositiol-4-phosphate, PIP(2), and phosphatidylinositol-3,4,5-trisphosphate reduced sensitivity to ATP and glibenclamide closely resembling the native variability. Insertion of the patch back into the oocyte (patch-cramming) restored high ATP and glibenclamide sensitivity, indicating reversible modulation of K(ATP) channels via endogenous PIPs-degrading enzymes. Thus, the observed variability seemed to result from differences in the membrane phospholipid content. PIP(2) also diminished activation of K(ATP) channels by the K(+) channel openers (KCOs) cromakalim and P1075. The properties mediated by the sulphonylurea receptor (sensitivity to sulfonylureas and KCOs) seemed to be modulated by PIPs via a different mechanism than ATP inhibition mediated by the Kir6.2 subunits. First, polycations abolished the effect of PIP(2) on ATP inhibition consistent with an electrostatic mechanism but only weakly affected glibenclamide inhibition and activation by KCOs. Second, PIP(2) had clearly distinct effects on the concentration-response curves for ATP and glibenclamide. However, PIPs seemed to mediate the different effects via the Kir6.2 subunits because a mutation in Kir6.2 (R176A) attenuated simultaneously the effects of PIP(2) on ATP and glibenclamide inhibition. Finally, experiments with various lipids revealed structural features necessary to modulate K(ATP) channel properties and an artificial lipid (dioleoylglycerol-succinyl-nitriloacetic acid) that mimicked the effects of PIPs on K(ATP) channels.

A sequence motif responsible for ER export and surface expression of Kir2.0 inward rectifier K(+) channels.

Integral membrane proteins are sorted via the secretory pathway. It was proposed that this pathway is non-selective provided that the cargo protein is properly assembled and lacks an endoplasmic reticulum (ER) retention signal. However, recent experimental evidence suggests that efficient export of proteins from the ER to the Golgi complex is not simply a default pathway. Here we demonstrate a novel sequence motif (FxYENEV) in the cytoplasmic C-terminus of mammalian inward rectifier potassium (Kir) channels which determines ER export. This motif is found to be both necessary and sufficient for efficient export from the ER that eventually leads to efficient surface expression of Kir2.1 channels.

Inflammatory mediators potentiate ATP-gated channels through the P2X(3) subunit.

The P2X(3) receptor is an ATP-gated ion channel predominantly expressed in nociceptive neurons from the dorsal root ganglion. P2X(3) receptor channels are highly expressed in sensory neurons and probably contribute to the sensation of pain. Kinetics of P2X(3) currents are characterized by rapid desensitization (<100 ms) and slow recovery (>20 s). Thus, any mechanism modulating rate of desensitization and/or recovery may have profound effect on susceptibility of nociceptive neurons expressing P2X(3) to ATP. Here we show that currents mediated by P2X(3) receptor channels and the heteromeric channel P2X(2/3) composed of P2X(2) and P2X(3) subunits are potentiated by the neuropeptides substance P and bradykinin, which are known to modulate pain perception. The effect is mediated by the respective neuropeptide receptors, can be mimicked by phorbol ester and blocked by inhibitors of protein kinases. Together with data from site-directed mutagenesis our results suggest that inflammatory mediators sensitize nociceptors through phosphorylation of P2X(3) and P2X(2/3) ion channels or associated proteins.

Developmental expression of the small-conductance Ca(2+)-activated potassium channel SK2 in the rat retina.

Small-conductance Ca(2+)-activated potassium (SK) channels are present in most central neurons, where they mediate the afterhyperpolarizations (AHPs) following action potentials. SK channels integrate changes in intracellular Ca(2+) concentration with membrane potential and thus play an important role in controlling firing pattern and excitability. Here, we characterize the expression pattern of the apamin-sensitive SK subunits, SK2 and SK3, in the developing and adult rat retina using in situ hybridization and immunohistochemistry. The SK2 subunit showed a distinct and developmentally regulated pattern of expression. It appeared during the first postnatal week and located to retinal ganglion cells and to subpopulations of neurons in the inner nuclear layer. These neurons were identified as horizontal cells and dopaminergic amacrine cells by specific markers. In contrast to SK2, the SK3 subunit was detected neither in the developing nor in the adult retina. These results show cell-specific expression of the SK2 subunit in the retina and suggest that this channel underlies the apamin-sensitive AHP currents described in retinal ganglion cells.

Developmental and cellular expression pattern of epithelial sodium channel alpha, beta and gamma subunits in the inner ear of the rat.

Endolymphatic ion composition in the adult inner ear is characterized by high K(+) and low Na(+) concentration. This unique ion composition is essential for proper functioning of sensory processing. Although a lot has been learned in recent years about molecules involved in K(+) transport in inner ear, the molecules involved in Na(+) transport are only beginning to emerge. The epithelial Na(+) channel (ENaC) is a highly selective Na(+) channel that is expressed in many Na(+)-reabsorbing tissues. The aim of our study was to investigate whether ENaC is expressed in inner ear of rats and could account for Na(+) reabsorption from endolymph. We detected mRNA for the three channel-forming subunits (alpha, beta and gamma ENaC) in cochlea, vestibular system and endolymphatic sac. mRNA abundance increased during the first 12 days of life in cochlea and vestibular system, coinciding with decreasing Na(+) concentration in endolymph. Expression was strongest in epithelial cells lining scala media, most notably Claudius' cells. As these cells are characterized by a very negative resting potential they would be ideally suited for reabsorption of Na(+). mRNA abundance in endolymphatic sac decreased during the first 6 days of life, suggesting that ENaC might be implicated in reabsorption of endolymph in the endolymphatic sac of neonatal animals. Together, our results suggest that the epithelial Na+ channel is a good candidate for a molecule involved in Na(+) homeostasis in inner ear.

Expression of AMPA receptor subunit flip/flop splice variants in the rat auditory brainstem and inferior colliculus.

The expression of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) receptor subunit mRNAs and their flip/flop splice variants was evaluated in the rat auditory brainstem and inferior colliculus employing in situ hybridization with radiolabeled oligonucleotide probes. A differential expression of AMPA receptor subunits in auditory nuclei was observed. In general, neurons in all nuclei of the auditory brainstem express high levels of GluR-C flop and GluR-D flop mRNA, but low to very low levels of GluR-A and GluR-B mRNA. The strongest GluR-C and -D flop expression is found in the ventral and medial part of the anteroventral cochlear nucleus, the posteroventral cochlear nucleus, and the medial and the lateral superior olive. These nuclei are part of the binaural auditory pathway which is important for sound localization in space. In contrast, neurons in the central nucleus of the inferior colliculus express high levels of GluR-B flip but only low levels of the other AMPA receptor subunits. From our data, we conclude that neurons of nuclei involved in binaural processing exhibit a specific "auditory AMPA receptor" which consists primarily of GluR-C flop and -D flop and often lacks GluR-B subunits; this indicates fast kinetics and high Ca(2+) permeability of AMPA receptor currents. In contrast, neurons in the central nucleus of the inferior colliculus contain large amounts of GluR-B flip subunits resulting in Ca(2+) impermeable AMPA receptors with slow kinetics.

Regulation of GIRK channel deactivation by Galpha(q) and Galpha(i/o) pathways.

G protein regulated inward rectifying potassium channels (GIRKs) are activated by G protein coupled receptors (GPCRs) via the G protein betagamma subunits. However, little is known about the effects of different GPCRs on the deactivation kinetics of transmitter-mediated GIRK currents. In the present study we investigated the influence of different GPCRs in the presence and absence of RGS proteins on the deactivation kinetics of GIRK channels by coexpressing the recombinant protein subunits in Xenopus oocytes. The stimulation of both G(i/o)- and G(q)-coupled pathways accelerated GIRK deactivation. GIRK currents deactivated faster upon stimulation of G(i/o)- and G(q)-coupled pathways by P(2)Y(2) receptors (P(2)Y(2)Rs) than upon activation of the G(i/o)-coupled pathway alone via muscarinic acetylcholine receptor M2 (M(2) mAChRs). This acceleration was found to be dependent on phospholipase C (PLC) and protein kinase C (PKC) activities and intracellular calcium. With the assumption that RGS2 has a higher affinity for Galpha(q) than Galpha(i/o), we demonstrated that the deactivation kinetics of GIRK channels can be differentially regulated by the relative amount of RGS proteins. These data indicate that transmitter-mediated deactivation of GIRK currents is modulated by crosstalk between G(i/o)- and G(q)-coupled pathways.

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.

A new member of acid-sensing ion channels from pituitary gland.

Acid-sensing ion channels (ASICs) constitute a branch of the super-gene family of amiloride-sensitive sodium channels. So far five different ASICs have been cloned from mammalian tissues. They are activated by a drop of extracellular pH but differ with respect to effective agonist concentration, desensitization and mRNA expression pattern. Here we report cloning of ASIC4, a new protein showing about 45% identity to other ASICs. ASIC4 is 97% identical between rat and human and shows strongest expression in pituitary gland. Moreover, we detected expression throughout the brain, in spinal cord, and inner ear. ASIC4 cannot be activated by a drop of extracellular pH in Xenopus oocytes, suggesting association with other subunits or activation by a ligand different from protons. Our results suggest a role for ASICs also in endocrine glands.

Mechanical stimulation of individual stereocilia of living cochlear hair cells by atomic force microscopy.

This paper describes the investigation of elastical properties and imaging of living cochlear hair bundles of inner (IHC) and outer hair cells (OHC) on the level of individual stereocilia. A custom-made AFM-setup was used, allowing to scan the mechano-sensitive structures of the inner ear under direct control of an upright differential interference contrast (DIC) microscope with a water-immersion objective. Scanning electron microscopy (SEM) images of the identical hair bundles obtained after AFM investigation demonstrated that forces up to 1.5 nanonewton (nN) did not cause obvious damage of the surface morphology of the stereocilia. These are the first images of hair bundles of living sensory cells of the organ of Corti by AFM. They display the tips of individual stereocilia and the typical V-shape of ciliary bundles. Since line scans clearly show that slope and force interaction depend on the elastical properties of stereocilia, quantitative stiffness measurements and stimulation of single transduction channels are suggested.

Intracellular regulation of inward rectifier K+ channels.

Inward rectifier potassium (Kir) channels comprise a relatively young gene family of ion channels whose first member was isolated in 1993. A common property its members share is a strong dependence on intracellular regulators such as polyamines, nucleotides, phospholipids, kinases, pH and guanosine-triphosphate-binding proteins (G-proteins). The physiological role of Kir channels is to modulate the excitability and secretion of potassium (K+) to maintain K+ homeostasis, under the control of various intracellular second messengers. Structurally, Kir channels are assembled from four alpha-subunits each carrying the prototypic K+-channel pore region lined by two transmembrane segments with intracellular N- and C-termini. The exact molecular mechanism of Kir channel gating by intracellular second messengers is of considerable biophysical interest. Recent studies have gained significant insight into the molecular mechanism of intracellular regulation by pH. This review illustrates the various modes of regulation of this class of ion channel and the present knowledge of the underlying molecular mechanisms.

pH gating of ROMK (K(ir)1.1) channels: control by an Arg-Lys-Arg triad disrupted in antenatal Bartter syndrome.

Inward-rectifier K(+) channels of the ROMK (K(ir)1.1) subtype are responsible for K(+) secretion and control of NaCl absorption in the kidney. A hallmark of these channels is their gating by intracellular pH in the neutral range. Here we show that a lysine residue close to TM1, identified previously as a structural element required for pH-induced gating, is protonated at neutral pH and that this protonation drives pH gating in ROMK and other K(ir) channels. Such anomalous titration of this lysine residue (Lys-80 in K(ir)1.1) is accomplished by the tertiary structure of the K(ir) protein: two arginines in the distant N and C termini of the same subunit (Arg-41 and Arg-311 in K(ir)1.1) are located in close spatial proximity to the lysine allowing for electrostatic interactions that shift its pK(a) into the neutral pH range. Structural disturbance of this triad as a result from a number of point mutations found in patients with antenatal Bartter syndrome shifts the pK(a) of the lysine residue off the neutral pH range and results in channels permanently inactivated under physiological conditions. Thus, the results provide molecular understanding for normal pH gating of K(ir) channels as well as for the channel defects found in patients with antenatal Bartter syndrome.

NMR structure and functional characteristics of the hydrophilic N terminus of the potassium channel beta-subunit Kvbeta1.1.

Rapid N-type inactivation of voltage-dependent potassium (Kv) channels controls membrane excitability and signal propagation in central neurons and is mediated by protein domains (inactivation gates) occluding the open channel pore from the cytoplasmic side. Inactivation domains (ID) are donated either by the pore-forming alpha-subunit or certain auxiliary beta-subunits. Upon coexpression, Kvbeta1.1 was found to endow non-inactivating members of the Kv1alpha family with fast inactivation via its unique N terminus. Here we investigated structure and functional properties of the Kvbeta1.1 N terminus (amino acids 1-62, betaN-(1-62)) using NMR spectroscopy and patch clamp recordings. betaN-(1-62) showed all hallmarks of N-type inactivation: it inactivated non-inactivating Kv1.1 channels when applied to the cytoplasmic side as a synthetic peptide, and its interaction with the alpha-subunit was competed with tetraethylammonium and displayed an affinity in the lower micromolar range. In aequous and physiological salt solution, betaN-(1-62) showed no well defined three-dimensional structure, it rather existed in a fast equilibrium of multiple weakly structured states. These structural and functional properties of betaN-(1-62) closely resemble those of the "unstructured" ID from Shaker B, but differ markedly from those of the compactly folded ID of the Kv3.4 alpha-subunit.

Gene expression of P2X-receptors in the developing inner ear of the rat.

Reverse transcription-polymerase chain reaction (RT-PCR) was used to characterize the expression of P2X receptor subunits (P2X1-P2X7) in different inner ear tissues. The present study revealed the presence of P2X2, P2X3, P2X4 and P2X7-mRNA in rat organ of Corti, vestibular organ and spiral ganglion at different postnatal developmental stages (PD1-PD16), with slight differences in the onset of expression. Expression of P2X1, P2X5 and P2X6-mRNA was not detectable in the inner ear tissues. In addition, single cell RT-PCR experiments with outer hair cells (OHC) revealed the expression of either the P2X2 or the P2X2-2 splice variant or coexpression of both isoforms in individual cells. Our data suggest that extracellular adenosine-5'-triphosphate (ATP) may play an important role in signal transduction in the inner ear.