SummaryA primary cilium is a solitary slender non-motile protuberance of structured microtubules (9+0) enclosed by plasma membrane1. Housing components of the cell division apparatus between cell divisions, they also serve as specialized compartments for calcium signaling2 and Hedgehog (Hh) signaling pathways3. Specialized sensory cilia such as retinal photoreceptors and olfactory cilia employ diverse ion channels4-7. An ion current has been measured from primary cilia of kidney cells8 but the responsible genes have not been identified. The polycystin proteins (PC, PKD), identified in linkage studies of polycystic kidney disease9, are candidate channels divided into two structural classes: 11-transmembrane (TM) proteins (PKD1, PKD1-L1 and PKD1-L2) remarkable for a large extracellular N-terminus of putative cell adhesion domains and a GPCR proteolytic site, and the 6-TM channel proteins (PKD2, PKD2-L1, PKD2-L2; TRPPs). Evidence suggests that the PKD1s associate with the PKD2s via coiled-coil domains10-12. Here, we employ a transgenic mouse in which only cilia express a fluorophore and employ it to directly record from primary cilia and demonstrate that PKD1-L1 and PKD2-L1 form ion channels at high densities in several cell types. In conjunction with the companion manuscript2, we show that the PKD1-L1/PKD2-L1 heteromeric channel establishes the cilia as a unique calcium compartment within cells that modulates established Hedgehog pathways.
Mutations in the polycystin genes, PKD1 or PKD2, results in Autosomal Dominant Polycystic Kidney Disease (ADPKD). Although a genetic basis of ADPKD is established, we lack a clear understanding of polycystin proteins’ functions as ion channels. This question remains unsolved largely because polycystins localize to the primary cilium – a tiny, antenna-like organelle. Using a new ADPKD mouse model, we observe primary cilia that are abnormally long in cells associated with cysts after conditional ablation of Pkd1 or Pkd2. Using primary cultures of collecting duct cells, we show that polycystin-2, but not polycystin-1, is a required subunit for the ion channel in the primary cilium. The polycystin-2 channel preferentially conducts K+ and Na+; intraciliary Ca2+, enhances its open probability. We introduce a novel method for measuring heterologous polycystin-2 channels in cilia, which will have utility in characterizing PKD2 variants that cause ADPKD.
Neurosteroids are synthesized within the brain and act as endogenous anxiolytic, anticonvulsant, hypnotic, and sedative agents, actions that are principally mediated via their ability to potentiate phasic and tonic inhibitory neurotransmission mediated by γ-aminobutyric acid type A receptors (GABA A Rs). Although neurosteroids are accepted allosteric modulators of GABA A Rs, here we reveal they exert sustained effects on GABAergic inhibition by selectively enhancing the trafficking of GABA A Rs that mediate tonic inhibition. We demonstrate that neurosteroids potentiate the protein kinase C-dependent phosphorylation of S443 within α4 subunits, a component of GABA A R subtypes that mediate tonic inhibition in many brain regions. This process enhances insertion of α4 subunit-containing GABA A R subtypes into the membrane, resulting in a selective and sustained elevation in the efficacy of tonic inhibition. Therefore, the ability of neurosteroids to modulate the phosphorylation and membrane insertion of α4 subunit-containing GABA A Rs may underlie the profound effects these endogenous signaling molecules have on neuronal excitability and behavior.PKC | tonic current | receptor insertion | current rundown N eurosteroids are synthesized de novo in the brain from cholesterol, or steroid hormone precursors. Raising neurosteroid levels in the CNS causes anxiolysis, sedation/hypnosis, anticonvulsant action, and anesthesia and reduces depressivelike behaviors (1-3). Accordingly, dysregulation of neurosteroid signaling is associated with premenstrual dysphoric disorder, panic disorder, depression, schizophrenia, and bipolar disorder. Neurosteroids exert the majority of their actions via potentiating the activity of γ-aminobutyric acid receptors (GABA A Rs), which mediate the majority of fast synaptic inhibition in the adult brain. Accordingly, at low nanomolar concentrations they potentiate GABA-dependent currents, whereas at micromolar concentrations they directly activate GABA A Rs (4-8).GABA A Rs are Cl − -preferring pentameric ligand-gated ion channels that assemble from eight families of subunits: α(1-6), β(1-3), γ(1-3), δ, e, ө, π, and ρ(1-3) (9, 10). Receptor subtypes composed of α1-3βγ subunits largely mediate synaptic or phasic inhibition, whereas those constructed from α4-6β1-3, with or without γ/δ subunits, are principal determinants of tonic inhibition (11-13). Neurosteroids have been shown to bind GABA A Rs at an allosteric site distinct from that of GABA, benzodiazepines, or barbiturates (9, 14). Hosie et al. identified residues located within the transmembrane domain of GABA A R α and β subunits that are critical for the direct activation (α1-6; Threonine 236, β1-3; Tyrosine 284) and allosteric potentiation (α1-6 Asparagine 407, and α1-6 Glutamine 246) of neurosteroids (15-17). Accordingly, mutation of glutamine 241 (Q241) within the α1-6 subunits prevents allosteric potentiation of GABA A R composed of αβγ and αβδ subunits by neurosteroids (15,16).In addition to modulating channel gating, neurosteroids exert...
Alterations in the efficacy of neuronal inhibition mediated by GABA A receptors (GABA A Rs) containing β3 subunits are continually implicated in autism spectrum disorders (ASDs). In vitro, the plasma membrane stability of GABA A Rs is potentiated via phosphorylation of serine residues 408 and 409 (S408/9) in the β3 subunit, an effect that is mimicked by their mutation to alanines. To assess if modifications in β3 subunit expression contribute to ASDs, we have created a mouse in which S408/9 have been mutated to alanines (S408/9A). S408/9A homozygotes exhibited increased phasic, but decreased tonic, inhibition, events that correlated with alterations in the membrane stability and synaptic accumulation of the receptor subtypes that mediate these distinct forms of inhibition. S408/9A mice exhibited alterations in dendritic spine structure, increased repetitive behavior, and decreased social interaction, hallmarks of ASDs. ASDs are frequently comorbid with epilepsy, and consistent with this comorbidity, S408/9A mice exhibited a marked increase in sensitivity to seizures induced by the convulsant kainic acid. To assess the relevance of our studies using S408/9A mice for the pathophysiology of ASDs, we measured S408/9 phosphorylation in Fmr1 KO mice, a model of fragile X syndrome, the most common monogenetic cause of ASDs. Phosphorylation of S408/9 was selectively and significantly enhanced in Fmr1 KO mice. Collectively, our results suggest that alterations in phosphorylation and/or activity of β3-containing GABA A Rs may directly contribute to the pathophysiology of ASDs.GABA receptor | phosphorylation | autism spectrum disorder | tonic inhibition | phasic inhibition
The behavioral and anatomical deficits seen in fragile X syndrome (FXS) are widely believed to result from imbalances in the relative strengths of excitatory and inhibitory neurotransmission. Although modified neuronal excitability is thought to be of significance, the contribution that alterations in GABAergic inhibition play in the pathophysiology of FXS are ill defined. Slow sustained neuronal inhibition is mediated by γ-aminobutyric acid type B (GABA) receptors, which are heterodimeric G-protein-coupled receptors constructed from R1a and R2 or R1b and R2 subunits. Via the activation of G, they limit cAMP accumulation, diminish neurotransmitter release, and induce neuronal hyperpolarization. Here we reveal that selective deficits in R1a subunit expression are seen in Fmr1 knock-out mice (KO) mice, a widely used animal model of FXS, but the levels of the respective mRNAs were unaffected. Similar trends of R1a expression were seen in a subset of FXS patients. GABA receptors (GABARs) exert powerful pre- and postsynaptic inhibitory effects on neurotransmission. R1a-containing GABARs are believed to mediate presynaptic inhibition in principal neurons. In accordance with this result, deficits in the ability of GABARs to suppress glutamate release were seen in Fmr1-KO mice. In contrast, the ability of GABARs to suppress GABA release and induce postsynaptic hyperpolarization was unaffected. Significantly, this deficit contributes to the pathophysiology of FXS as the GABAR agonist ()-baclofen rescued the imbalances between excitatory and inhibitory neurotransmission evident in Fmr1-KO mice. Collectively, our results provided evidence that selective deficits in the activity of presynaptic GABARs contribute to the pathophysiology of FXS.
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