The molecular mechanisms underlying synaptic exocytosis in the hair cell, the auditory and vestibular receptor cell, are not well understood. Otoferlin, a C2 domain-containing Ca 2؉ -binding protein, has been implicated as having a role in vesicular release. Mutations in the OTOF gene cause nonsyndromic deafness in humans, and OTOF knock-out mice are deaf. In the present study, we generated otoferlin fusion proteins containing two of the same amino acid substitutions detected in DFNB9 patients (P1825A in C2F and L1011P in C2D). The native otoferlin C2F domain bound syntaxin 1A and SNAP-25 in a Ca 2؉ -dependent manner (with optimal 61 M free Ca 2؉ required for binding). These interactions were greatly diminished for C2F with the P1825A mutation, possibly because of a reduction in tertiary structural change, induced by Ca 2؉ , for the mutated C2F compared with the native C2F. The otoferlin C2D domain also bound syntaxin 1A, but with weaker affinity (K d ؍ 1.7 ؋ 10 ؊5 M) than for the C2F interaction (K d ؍ 2.6 ؋ 10 ؊9 M). In contrast, it was the otoferlin C2D domain that bound the Ca v 1.3 II-III loop, in a Ca 2؉ -dependent manner. The L1011P mutation in C2D rendered this binding insensitive to Ca 2؉ and considerably diminished. Overall, we demonstrated that otoferlin interacts with two main target-SNARE proteins of the hair-cell synaptic complex, syntaxin 1A and SNAP-25, as well as the calcium channel, with the otoferlin C2F and C2D domains of central importance for binding. Because mutations in the otoferlin C2 domains that cause deafness in humans impair the ability of otoferlin to bind syntaxin, SNAP-25, and the Ca v 1.3 calcium channel, it is these interactions that may mediate regulation by otoferlin of hair cell synaptic exocytosis critical to inner ear hair cell function.Calcium is a key regulator of synaptic vesicle fusion (reviewed in Ref. 1). In mechanosensory hair cells, calcium microdomains (2) and possibly nanodomains (3) are formed when voltage-gated calcium channels open upon depolarization. Calcium at these sites is thought to activate protein interactions, leading to vesicle fusion. Some of the key players in this process are the target-SNARE 2 proteins, syntaxin 1A and SNAP-25, and the vesicle-SNARE, synaptobrevin (4). Vesicle-SNARE synaptotagmin 1 plays a crucial role as a calcium sensor at the neuronal synapse, modulating calcium channels and vesicle release by a Ca 2ϩ -dependent interaction with other SNARE proteins in the presence of lipid molecules (4 -6). However, in vertebrate mechanosensory hair cells, synaptotagmin 1 is not detected (7). Instead, fast neurotransmitter release in auditory and vestibular hair cells, facilitated largely by an L-type voltagegated calcium channel, Ca v 1.3 (8, 9), is thought to be modulated by a newly discovered protein, otoferlin, acting as the Ca 2ϩ sensor and vesicle-binding protein. When mutated, otoferlin causes DFNB9 nonsyndromic deafness (10). Gene sequences of different deaf families show that the OTOF gene can undergo mutation at multiple locatio...
Transmitter release at synapses ensures faithful chemical coding of information that is transmitted in the sub-second time frame. The brain, the central unit of information processing, depends upon fast communication for decision making. Neuronal and neurosensory cells are equipped with the molecular machinery that responds reliably, and with high fidelity, to external stimuli. However, neuronal cells differ markedly from neurosensory cells in their signal transmission at synapses. The main difference rests in how the synaptic complex is organized, with active zones in neuronal cells and ribbon synapses in sensory cells (such as photoreceptors and hair cells). In exocytosis/neurosecretion, SNAREs (soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptors) and associated proteins play a critical role in vesicle docking, priming, fusion and synchronization of neurotransmitter release. Recent studies suggest differences between neuronal and sensory cells with respect to the molecular components of their synaptic complexes. In this review, we will cover current findings on neuronal and sensory-cell SNARE proteins and their modulators. We will also briefly discuss recent investigations on how deficits in the expression of SNARE proteins in humans impair function in brain and sense organs.
Surface plasmon resonance is an optical technique utilized for detecting molecular interactions. Binding of a mobile molecule (analyte) to a molecule immobilized on a thin metal film (ligand) changes the refractive index of the film. The angle of extinction of light, reflected after polarized light impinges upon the film, is altered, monitored as a change in detector position for the dip in reflected intensity (the surface plasmon resonance phenomenon). Because the method strictly detects mass, there is no need to label the interacting components, thus eliminating possible changes of their molecular properties. We have utilized surface plasmon resonance to study the interaction of proteins of hair cells.
The cytoplasmic amino terminus of HCN1, the primary full-length HCN isoform expressed in trout saccular hair cells, was found by yeast two-hybrid protocols to bind the cytoplasmic carboxyl-terminal domain of a protocadherin 15a-like protein. HCN1 was immunolocalized to discrete sites on saccular hair cell stereocilia, consistent with gradated distribution expected for tip link sites of protocadherin 15a. HCN1 message was also detected in cDNA libraries of rat cochlear inner and outer hair cells, and HCN1 protein was immunolocalized to cochlear hair cell stereocilia. As predicted by the trout hair cell model, the amino terminus of rat organ of Corti HCN1 was found by yeast two-hybrid analysis to bind the carboxyl terminus of protocadherin 15 CD3, a tip link protein implicated in mechanosensory transduction. Specific binding between HCN1 and protocadherin 15 CD3 was confirmed with pull-down assays and surface plasmon resonance analysis, both predicting dependence on Ca HCN12 is the primary full-length HCN isoform underlying I h (hyperpolarization-activated, cyclic nucleotide-gated, nonselective cation channel current) in a model hair cell preparation from the trout sacccule (1). cAMP-gated I h , possibly in addition to the mechanosensory-transduction current, sets the membrane potential for a subpopulation of saccular hair cells (2, 3). The membrane potential in the saccular hair cell subpopulation is sufficiently depolarized to activate voltage-gated calcium channels, permitting influx of calcium and secretion of hair cell transmitter (2). Given that saccular hair cells expressing I K1 in addition to I h are more hyperpolarized, not supporting activation of the voltage-gated calcium channels, we predicted that spontaneous release of transmitter from the subpopulation of hair cells would constitute hair cell-generated spontaneous activity for the saccule (1). However, little has been previously reported on the morphological localization of the HCN1 isoform in hair cells or possible links to structural proteins that mechanistically would localize HCN1 in hair cells (for preliminary report, see Ref. 4). In general, little is known about proteinprotein interactions for the HCN isoforms that would modulate I h and/or the associated instantaneous current (5).Protocadherin 15 is a proposed tip link protein involved in connecting shorter stereocilia to adjacent taller stereocilia in the stereociliary array of inner ear hair cells, facilitating the opening of the mechanosensory transduction channel in response to auditory and vestibular stimuli. The active tip link protein in Danio rerio is protocadherin 15a (6), characterized by splice variants in its carboxyl terminus. In the mammal, protocadherin 15 CD3 is hypothesized to be a tip link protein at insertion sites in the tips of the shorter stereocilia of the stereociliary array (7,8). EXPERIMENTAL PROCEDURES Acquisition of a Model Hair Cell Preparation from the Trout Saccule and an Organ of Corti Subfraction from theRat Cochlea-Hair cell layers were isolated from the t...
Adenylyl cyclase signaling pathways have been identified in a model hair cell preparation from the trout saccule, for which the hair cell is the only intact cell type. The use of degenerate primers targeting cDNA sequence conserved across adenylyl cyclase (AC) isoforms, and RT-PCR, coupled with cloning of amplification products, indicated expression of AC9, AC7 and AC5/6, with cloning efficiencies of 11:5:2. AC9 and AC5/6 are inhibited by Ca2+, the former in conjunction with calcineurin, and message for calcineurin has also been identified in the trout saccular hair cell layer. AC7 is independent of Ca2+. Given the lack of detection of calcium/calmodulin-activated isoforms previously suggested to mediate adenylyl cyclase activation in the absence of Gαs in mammalian cochlear hair cells, the issue of hair-cell Gαs mRNA expression was re-examined in the teleost vestibular hair cell model. Two full-length coding sequences were obtained for Gαs/olf in the vestibular type II-like hair cells of the trout saccule. Two messages for Gαi have also been detected in the hair cell layer, one with homology to Gαi1 and the second with homology to Gαi3 of higher vertebrates. Both Gαs/olf protein and Gαi1/Gαi3 protein were immunolocalized to stereocilia and to the base of the hair cell, the latter consistent with sites of efferent input. While a signaling event coupling to Gαs/olf and Gαi1/Gαi3 in the stereocilia is currently unknown, signaling with Gαs/olf, Gαi3, and AC5/6 at the base of the hair cell would be consistent with transduction pathways activated by dopaminergic efferent input. mRNA for dopamine receptors D1A4 and five forms of dopamine D2 were found to be expressed in the teleost saccular hair cell layer, representing information on vestibular hair cell expression not directly available for higher vertebrates. Dopamine D1A receptor would couple to Gαolf and activation of AC5/6. Co-expression with dopamine D2 receptor, which itself couples to Gαi3 and AC5/6, will down-modulate levels of cAMP, thus fine-tuning and gradating the hair-cell response to dopamine D1A. As predicted by the trout saccular hair cell model, evidence has been obtained for the first time that hair cells of mammalian otolithic vestibular end organs (rat/mouse saccule/utricle) express dopamine D1A and D2L receptors, and each receptor co-localizes with AC5/6, with a marked presence of all three proteins in subcuticular regions of type I vestibular hair cells. A putative efferent, presynaptic source of dopamine was identified in tyrosine hydroxylase-positive nerve fibers which passed from underlying connective tissue to the sensory epithelia, ending on type I and type II vestibular hair cells and on afferent calyces.
Messages for subunits of voltage-gated calcium channels were examined in the cochlea of the CBAm ouse by PCR analysis. Total RNA was extracted from the auditory organs of 16-18-day-old animals. After reverse transcription, resulting cDNA was amplified by PCR with primers targeted to nucleotide sequences corresponding to 12 different calcium channel subunits. PCR products representing subunit gene expression were strongly and consistently amplified for aic, a 10, alE, /3~,/33, and /3~but not for alA, aiB, ais, /32, or y. The chosen primers amplified cochlear cDNA to yield an overall pattern of bands different from that of any tissue studied thus far, in particular with respect to the a25 and /3s ubunits; the a26 product was found to be significantly shorter than the corresponding brain and skeletal muscle isoforms. Nucleotide sequencing confirmed the identity of mouse cochlear subunit cDNAs. The results suggest that L-type and presumptive R-type calcium channels are expressed in the mammalian cochlea and that the a25 subunits may be coded by a characteristic splice-variant mRNA.
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