The biogenesis, maintenance, and function of primary cilia are controlled through intraflagellar transport (IFT) driven by two kinesin-2 family members, the heterotrimeric KIF3A/KIF3B/KAP complex and the homodimeric KIF17 motor1,2. How these motors and their cargoes gain access to the ciliary compartment is poorly understood. We identify a ciliary localization signal (CLS) in the KIF17 tail domain that is necessary and sufficient for ciliary targeting. Similarities between the CLS and classic nuclear localization signals (NLS) suggests that similar mechanisms regulate nuclear and ciliary import. We hypothesize that ciliary targeting of KIF17 is regulated by a Ran-GTP gradient across the ciliary base. Consistent with this, cytoplasmic expression of GTP-locked Ran(G19V) disrupts the gradient and abolishes ciliary entry of KIF17. Furthermore, KIF17 interacts with importin-β2 in a manner dependent on the CLS and inhibited by Ran-GTP. We propose that Ran plays a global role in regulating cellular compartmentalization by controlling the shuttling of cytoplasmic proteins into nuclear and ciliary compartments.
Anosmia and hyposmia, the inability or decreased ability to smell, is estimated to afflict 3-20% of the population. Risk of olfactory dysfunction increases with old age and may also result from chronic sinonasal diseases, severe head trauma, and upper respiratory infections, or neurodegenerative diseases. These disorders impair the ability to sense warning odors in foods and the environment, as well as hinder the quality of life related to social interactions, eating, and feelings of well-being. This article reports and extends on a clinical update commencing at the 2016 Association for Chemoreception Sciences annual meeting. Included were reports from: a patient perspective on losing the sense of smell with information on Fifth Sense, a nonprofit advocacy organization for patients with olfactory disorders; an otolaryngologist's review of clinical evaluation, diagnosis, and management/treatment of anosmia; and researchers' review of recent advances in potential anosmia treatments from fundamental science, in animal, cellular, or genetic models. As limited evidence-based treatments exist for anosmia, dissemination of information on anosmia-related health risks is needed. This could include feasible and useful screening measures for olfactory dysfunction, appropriate clinical evaluation, and patient counseling to avoid harm as well as manage health and quality of life with anosmia.
Ion channel targeting within neuronal and muscle membranes is an important determinant of electrical excitability. Recent evidence suggests that there exists within the membrane specialized microdomains commonly referred to as lipid rafts. These domains are enriched in cholesterol and sphingolipids and concentrate a number of signal transduction proteins such as nitricoxide synthase, ligand-gated receptors, and multiple protein kinases. Here, we demonstrate that the voltagegated K ؉ channel Kv2.1, but not Kv4.2, targets to lipid rafts in both heterologous expression systems and rat brain. The Kv2.1 association with lipid rafts does not appear to involve caveolin. Depletion of cellular cholesterol alters the buoyancy of the Kv2.1 associated rafts and shifts the midpoint of Kv2.1 inactivation by nearly 40 mV without affecting peak current density or channel activation. The differential targeting of Kv channels to lipid rafts represents a novel mechanism both for the subcellular sorting of K ؉ channels to regions of the membrane rich in signaling complexes and for modulating channel properties via alterations in lipid content.The subcellular localization of ion channels is necessary for proper electrical signaling. In cardiac and skeletal myocytes, ion channels show a differential surface distribution (1, 2). Within the brain, voltage-gated K ϩ (Kv) channels often show not only polarized sorting to either axons or dendrites, but also isoform-specific localization within dendrites alone. Thus, there exists specific sorting mechanisms for restricting lateral distribution within a given membrane domain (3). One physiological consequence for such specific localization is that it places various signal transduction molecules near their ion channel substrates (4). Several families of intracellular proteins, PDZs and AKAPs, have been shown to cluster both ion channels and modulatory signaling enzymes. Indeed, great emphasis has been placed on the role of PDZ proteins such as PSD-95 in the targeting and localization of ion channels and neurotransmitter receptors (5). In contrast, the role of membrane lipids in differential targeting and integration of ion channels within the plane of the plasma membrane has not been addressed.Recent advances in the study of cell membrane structure have led to the emerging idea that microdomains exist within the fluid bilayer of the plasma membrane. These dynamic structures, termed lipid rafts, are rich in tightly packed sphingolipids and cholesterol (6). The rafts, which are present in both excitable and non-excitable cells, localize a number of membrane proteins, including multiple signal transduction molecules, while excluding others (7). Different types of rafts are likely to exist based on the presence of specific marker proteins and ultrastructure data (8). Caveolae represent one well studied subpopulation of lipid raft having an invaginated morphology and containing the scaffolding protein, caveolin, which interacts directly with several intracellular proteins (7, 9 -12). Here, we de...
Nonmotile cilia on olfactory sensory neurons (OSNs) compartmentalize signaling molecules, including odorant receptors and cyclic nucleotide-gated (CNG) channels, allowing for efficient, spatially confined responses to sensory stimuli . Little is known about the mechanisms of the ciliary targeting of olfactory CNG channels, composed of three subunits: CNGA2, CNGA4, and CNGB1b . Recent reports suggest that subunit composition of the retinal CNG channel influences localization, leading to disease . However, the mechanistic role of subunits in properly targeting native olfactory CNG channels remains unclear. Here, we show that heteromeric assembly with CNGB1b, containing a critical carboxy-terminal motif (RVxP), is required for ciliary trafficking of olfactory CNG channels. Movement of proteins within the cilia is governed by intraflagellar transport (IFT), a process that facilitates bidirectional movement of cargo along microtubules. Work in C. elegans has established that heterotrimeric and homodimeric kinesin-2 family members play a critical role in anterograde transport . In mammalian systems, the heterotrimeric KIF3a/KIF3b/KAP-3 complex plays a clear role in IFT; however, no role has been established for KIF17, the mammalian homolog of OSM-3 . Here, we demonstrate that KIF17 is required for olfactory CNG channel targeting, providing novel insights into mechanisms of mammalian ciliary transport.
The precise subcellular localization of ion channels is often necessary to ensure rapid and efficient integration of both intracellular and extracellular signaling events. Recently, we have identified lipid raft association as a novel mechanism for the subcellular sorting of specific voltage-gated K ؉ channels to regions of the membrane rich in signaling complexes. Here, we demonstrate isoform-specific targeting of voltage-gated K ؉ (Kv) channels to distinct lipid raft populations with the finding that Kv1.5 specifically targets to caveolae. Multiple lines of evidence indicate that Kv1.5 and Kv2.1 exist in distinct raft domains: 1) channel/raft association shows differential sensitivity to increasing concentrations of Triton X-100; 2) unlike Kv2.1, Kv1.5 colocalizes with caveolin on the cell surface and redistributes with caveolin following microtubule disruption; and 3) immunoisolation of caveolae copurifies Kv1.5 channel. Both depletion of cellular cholesterol and inhibition of sphingolipid synthesis alter Kv1.5 channel function by inducing a hyperpolarizing shift in the voltage dependence of activation and inactivation. The differential targeting of Kv channel subtypes to caveolar and noncaveolar rafts within a single membrane represents a unique mechanism of compartmentalization, which may permit isoform-specific modulation of K ؉ channel function.
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