SUMMARY Epithelial-neuronal signaling is essential for sensory encoding in touch, itch and nociception; however, little is known about the release mechanisms and neurotransmitter receptors through which skin cells govern neuronal excitability. Merkel cells are mechanosensory epidermal cells that have long been proposed to activate neuronal afferents through chemical synaptic transmission. We employed a set of classical criteria for chemical neurotransmission as framework to test this hypothesis. RNA sequencing of adult mouse Merkel cells demonstrated that they express presynaptic molecules and biosynthetic machinery for adrenergic transmission. Moreover, live-cell imaging directly demonstrated that Merkel cells mediate activity- and VMAT-dependent release of fluorescent catecholamine neurotransmitter analogues. Touch-evoked firing in Merkel-cell afferents was inhibited either by pre-synaptic silencing of SNARE-mediated vesicle release from Merkel cells or by neuronal deletion of β2-adrenergic receptors. Together, these results identify both pre- and postsynaptic mechanisms through which Merkel cells excite mechanosensory afferents to encode gentle touch.
St. John's Wort (SJW) has been used medicinally for over 5,000 years. Relatively recently, one of its phloroglucinol derivatives, hyperforin, has emerged as a compound of interest. Hyperforin first gained attention as the constituent of SJW responsible for its antidepressant effects. Since then, several of its neurobiological effects have been described, including neurotransmitter re-uptake inhibition, the ability to increase intracellular sodium and calcium levels, canonical transient receptor potential 6 (TRPC6) activation, N-methyl-D-aspartic acid (NMDA) receptor antagonism as well as antioxidant and anti-inflammatory properties. Until recently, its pharmacological actions outside of depression had not been investigated. However, hyperforin has been shown to have cognitive enhancing and memory facilitating properties. Importantly, it has been shown to have neuroprotective effects against Alzheimer's disease (AD) neuropathology, including the ability to disassemble amyloid-beta (Abeta) aggregates in vitro, decrease astrogliosis and microglia activation, as well as improve spatial memory in vivo. This review will examine some of the early studies involving hyperforin and its effects in the central nervous system (CNS), with an emphasis on its potential use in AD therapy. With further investigation, hyperforin could emerge to be a likely therapeutical candidate in the treatment of this disease.
Alzheimer's disease (AD) is a neurodegenerative disorder characterized by a progressive deterioration of cognitive abilities, amyloid-β peptide (Aβ) accumulation and synaptic alterations. Previous studies indicated that hyperforin, a component of the St John's Wort, prevents Aβ neurotoxicity and some behavioral impairments in a rat model of AD. In this study we examined the ability of tetrahydrohyperforin (IDN5607), a stable hyperforin derivative, to prevent the cognitive deficit and synaptic impairment in an in vivo model of AD. In double transgenic APPswe/PSEN1ΔE9 mice, IDN5706 improves memory and prevents the impairment of synaptic plasticity in a dose-dependent manner, inducing a recovery of long-term potentiation. In agreement with these findings, IDN5706 prevented the decrease in synaptic proteins in hippocampus and cortex. In addition, decreased levels of tau hyperphosphorylation, astrogliosis, and total fibrillar and oligomeric forms of Aβ were determined in double transgenic mice treated with IDN5706. In cultured cells, IDN5706 decreased the proteolytic processing of the amyloid precursor protein that leads to Aβ peptide generation. These findings indicate that IDN5706 ameliorates AD neuropathology and could be considered of therapeutic relevance in AD treatment.
Background: Coordinated synaptic and nuclear signaling is required for long lasting changes in neuronal morphology. Results: Afadin undergoes activity-dependent bi-directional shuttling to synapses and the nucleus resulting in dendritic spine remodeling and histone modifications. Conclusion: Afadin is required for coordinated signaling at synapses and the nucleus. Significance: Bi-directional trafficking of afadin is required for coordinated synaptic and nuclear signaling in response to activity-dependent stimulation.
Small-diameter vesicular glutamate transporter 3-lineage (Vglut3 lineage) dorsal root ganglion (DRG) neurons play an important role in mechanosensation and thermal hypersensitivity; however, little is known about their intrinsic electrical properties. We therefore set out to investigate mechanisms of excitability within this population. Calcium microfluorimetry analysis of male and female mouse DRG neurons demonstrated that the cooling compound menthol selectively activates a subset of Vglut3 lineage neurons. Whole-cell recordings showed that small-diameter Vglut3 lineage DRG neurons fire menthol-evoked action potentials and exhibited robust, transient receptor potential melastatin 8 (TRPM8)-dependent discharges at room temperature. This heightened excitability was confirmed by currentclamp and action potential phase-plot analyses, which showed menthol-sensitive Vglut3 lineage neurons to have more depolarized membrane potentials, lower firing thresholds, and higher evoked firing frequencies compared with menthol-insensitive Vglut3 lineage neurons. A biophysical analysis revealed voltage-gated sodium channel (Na V) currents in menthol-sensitive Vglut3 lineage neurons were resistant to entry into slow inactivation compared with menthol-insensitive neurons. Multiplex in situ hybridization showed similar distributions of tetrodotoxin (TTX)-sensitive Na V transcripts between TRPM8-positive and-negative Vglut3 lineage neurons; however, Na V 1.8 transcripts, which encode TTX-resistant channels, were more prevalent in TRPM8-negative neurons. Conversely, pharmacological analyses identified distinct functional contributions of Na V subunits, with Na V 1.1 driving firing in menthol-sensitive neurons, whereas other small-diameter Vglut3 lineage neurons rely primarily on TTX-resistant Na V channels. Additionally, when Na V 1.1 channels were blocked, the remaining Na V current readily entered into slow inactivation in menthol-sensitive Vglut3 lineage neurons. Thus, these data demonstrate that TTX-sensitive Na V s drive action potential firing in menthol-sensitive sensory neurons and contribute to their heightened excitability.
Key pointsr Kainate receptors (KARs) are ionotropic glutamate receptors (iGluRs) that modulate synaptic transmission and intrinsic neuronal excitability.r KARs associate with the auxiliary proteins neuropilin-and tolloid-like 1 and 2 (Neto1 and Neto2), which act as allosteric modulators of receptor function impacting all biophysical properties of these receptors studied to date. r M3-S2 linkers play a critical role in KAR gating; we found that individual residues in these linkers bidirectionally influence Neto2 modulation of KAR desensitization in an agonist specific manner.r We also identify the D1 dimer interface as a novel site of Neto2 modulation and functionally correlate the actions of Neto2 modulation of desensitization with modulation of cation sensitivity.r We identify these domains as determinants of Neto2 modulation. Thus, our work contributes to the understanding of auxiliary subunit modulation of KAR function and could aid the development of KAR-specific modulators to alter receptor function.Abstract Kainate receptors (KARs) are important modulators of synaptic transmission and intrinsic neuronal excitability in the CNS. Their activity is shaped by the auxiliary proteins Neto1 and Neto2, which impact KAR gating in a receptor subunit-and Neto isoform-specific manner. The structural basis for Neto modulation of KAR gating is unknown. Here we identify the M3-S2 gating linker as a critical determinant contributing to Neto2 modulation of KARs. M3-S2 linkers control both the valence and magnitude of Neto2 modulation of homomeric GluK2 receptors. Furthermore, a single mutation in this domain abolishes Neto2 modulation of heteromeric receptor desensitization. Additionally, we found that cation sensitivity of KAR gating is altered by Neto2 association, suggesting that stability of the D1 dimer interface in the ligand-binding domain (LBD) is an important determinant of Neto2 actions. Moreover, modulation of cation sensitivity was eliminated by mutations in the M3-S2 linkers, thereby correlating the action of Neto2 at these structurally discrete sites on receptor subunits. These results demonstrate that the KAR M3-S2 linkers and LBD dimer interface are critical determinants for Neto2 modulation of receptor function and identify these domains as potential sites of action for the targeted development of KAR-specific modulators that alter the function of auxiliary proteins in native receptors. Abbreviations ATD, amino terminal domain; AMPAR, AMPA receptor; CUB, C1r/C1s-Uegf-BMP; eGFP, enhanced green florescent protein; iGluR, ionotropic glutamate receptor; KAR, kainate receptor; LBD, ligand binding domain; NMDAR, NMDA receptor; Neto, neuropilin-and tolloid-like; TARP, transmembrane AMPA receptor regulatory protein.
The voltage-gated sodium channel (NaV), NaV1.1, is well-studied in the central nervous system; conversely, its contribution to peripheral sensory neuron function is more enigmatic. Here, we identify a new role for NaV1.1 in mammalian proprioception. RNAscope analysis and in vitro patch clamp recordings in genetically identified mouse proprioceptors show ubiquitous channel expression and significant contributions to intrinsic excitability. Notably, genetic deletion of NaV1.1 in sensory neurons caused profound and visible motor coordination deficits in conditional knockout mice of both sexes, similar to conditional Piezo2-knockout animals, suggesting this channel is a major contributor to sensory proprioceptive transmission. Ex vivo muscle afferent recordings from conditional knockout mice found that loss of NaV1.1 leads to inconsistent and unreliable proprioceptor firing characterized by action potential failures during static muscle stretch; conversely, afferent responses to dynamic vibrations were unaffected. This suggests that while a combination of Piezo2 and other NaV isoforms are sufficient to elicit activity in response to transient stimuli, NaV1.1 is required for transmission of receptor potentials generated during sustained muscle stretch. Impressively, recordings from afferents of heterozygous conditional knockout animals were similarly impaired, and heterozygous conditional knockout mice also exhibited motor behavioral deficits. Thus, NaV1.1 haploinsufficiency in sensory neurons impairs both proprioceptor function and motor behaviors. Importantly, human patients harboring NaV1.1 loss-of-function mutations often present with motor delays and ataxia; therefore, our data suggest sensory neuron dysfunction contributes to the clinical manifestations of neurological disorders in which NaV1.1 function is compromised. Collectively, we present the first evidence that NaV1.1 is essential for mammalian proprioceptive signaling and behaviors.
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