The E3 ubiquitin ligase Parkin plays a central role in the pathogenesis of many neurodegenerative diseases. Parkin promotes specific ubiquitination and affects the localization of transactivation response DNA‐binding protein 43 (TDP‐43), which controls the translation of thousands of mRNAs. Here we tested the effects of lentiviral Parkin and TDP‐43 expression on amino acid metabolism in the rat motor cortex using high frequency 13C NMR spectroscopy. TDP‐43 expression increased glutamate levels, decreased the levels of other amino acids, including glutamine, aspartate, leucine and isoleucine, and impaired mitochondrial tricarboxylic acid cycle. TDP‐43 induced lactate accumulation and altered the balance between excitatory (glutamate) and inhibitory (GABA) neurotransmitters. Parkin restored amino acid levels, neurotransmitter balance and tricarboxylic acid cycle metabolism, rescuing neurons from TDP‐43‐induced apoptotic death. Furthermore, TDP‐43 expression led to an increase in 4E‐BP levels, perhaps altering translational control and deregulating amino acid synthesis; while Parkin reversed the effects of TDP‐43 on the 4E‐BP signaling pathway. Taken together, these data suggest that Parkin may affect TDP‐43 localization and mitigate its effects on 4E‐BP signaling and loss of amino acid homeostasis.
Cholinergic signaling plays an important role in regulating the growth and regeneration of axons in the nervous system. The α7 nicotinic receptor (α7) can drive synaptic development and plasticity in the hippocampus. Here, we show that activation of α7 significantly reduces axon growth in hippocampal neurons by coupling to G protein‐regulated inducer of neurite outgrowth 1 (Gprin1), which targets it to the growth cone. Knockdown of Gprin1 expression using RNAi is found sufficient to abolish the localization and calcium signaling of α7 at the growth cone. In addition, an α7/Gprin1 interaction appears intimately linked to a Gαo, growth‐associated protein 43, and CDC42 cytoskeletal regulatory pathway within the developing axon. These findings demonstrate that α7 regulates axon growth in hippocampal neurons, thereby likely contributing to synaptic formation in the developing brain.
Motile growth cones lead growing axons through developing tissues to synaptic targets. These behaviors depend on the organization and dynamics of actin filaments that fill the growth cone leading margin [peripheral (P‐) domain]. Actin filament organization in growth cones is regulated by actin‐binding proteins that control all aspects of filament assembly, turnover, interactions with other filaments and cytoplasmic components, and participation in producing mechanical forces. Actin filament polymerization drives protrusion of sensory filopodia and lamellipodia, and actin filament connections to the plasma membrane link the filament network to adhesive contacts of filopodia and lamellipodia with other surfaces. These contacts stabilize protrusions and transduce mechanical forces generated by actomyosin activity into traction that pulls an elongating axon along the path toward its target. Adhesive ligands and extrinsic guidance cues bind growth cone receptors and trigger signaling activities involving Rho GTPases, kinases, phosphatases, cyclic nucleotides, and [Ca++] fluxes. These signals regulate actin‐binding proteins to locally modulate actin polymerization, interactions, and force transduction to steer the growth cone leading margin toward the sources of attractive cues and away from repellent guidance cues.
The mammalian target of rapamycin (mTOR) signalling cascade is involved in the intracellular regulation of protein synthesis, specifically for proteins involved in controlling neuronal morphology and facilitating synaptic plasticity. Research has revealed that the activity of the mTOR cascade is influenced by several extracellular and environmental factors that have been implicated in schizophrenia. Therefore, there is reason to believe that one of the downstream consequences of dysfunction or hypofunction of these factors in schizophrenia is disrupted mTOR signalling and hence impaired protein synthesis. This results in abnormal neurodevelopment and deficient synaptic plasticity, outcomes which could underlie some of the positive, negative and cognitive symptoms of schizophrenia. This review will discuss the functional roles of the mTOR cascade and present evidence in support of a novel mTOR‐based hypothesis of the neuropathology of schizophrenia.
The neurotransmitter serotonin underlies many of the brain's functions. Understanding serotonin neurochemistry is important for improving treatments for neuropsychiatric disorders such as depression. Antidepressants commonly target serotonin clearance via serotonin transporters and have variable clinical effects. Adjunctive therapies, targeting other systems including serotonin autoreceptors, also vary clinically and carry adverse consequences. Fast scan cyclic voltammetry is particularly well suited for studying antidepressant effects on serotonin clearance and autoreceptors by providing real‐time chemical information on serotonin kinetics in vivo. However, the complex nature of in vivo serotonin responses makes it difficult to interpret experimental data with established kinetic models. Here, we electrically stimulated the mouse medial forebrain bundle to provoke and detect terminal serotonin in the substantia nigra reticulata. In response to medial forebrain bundle stimulation we found three dynamically distinct serotonin signals. To interpret these signals we developed a computational model that supports two independent serotonin reuptake mechanisms (high affinity, low efficiency reuptake mechanism, and low affinity, high efficiency reuptake system) and bolsters an important inhibitory role for the serotonin autoreceptors. Our data and analysis, afforded by the powerful combination of voltammetric and theoretical methods, gives new understanding of the chemical heterogeneity of serotonin dynamics in the brain. This diverse serotonergic matrix likely contributes to clinical variability of antidepressants.
Subcellular trafficking of neuronal receptors is known to play a key role in synaptic development, homeostasis, and plasticity. We have developed a ligand‐targeted and photo‐cleavable probe for delivering a synthetic fluorophore to AMPA receptors natively expressed in neurons. After a receptor is bound to the ligand portion of the probe molecule, a proteinaceous nucleophile reacts with an electrophile on the probe, covalently bonding the two species. The ligand may then be removed by photolysis, returning the receptor to its non‐liganded state while leaving intact the new covalent bond between the receptor and the fluorophore. This strategy was used to label polyamine‐sensitive receptors, including calcium‐permeable AMPA receptors, in live hippocampal neurons from rats. Here, we describe experiments where we examined specificity, competition, and concentration on labeling efficacy as well as quantified receptor trafficking. Pharmacological competition during the labeling step with either a competitive or non‐competitive glutamate receptor antagonist prevented the majority of labeling observed without a blocker. In other experiments, labeled receptors were observed to alter their locations and we were able to track and quantify their movements.
Synaptic impairment rather than neuronal loss may be the leading cause of cognitive dysfunction in brain aging. Certain small Rho‐GTPases are involved in synaptic plasticity, and their dysfunction is associated with brain aging and neurodegeneration. Rho‐GTPases undergo prenylation by attachment of geranylgeranylpyrophosphate (GGPP) catalyzed by GGTase‐I. We examined age‐related changes in the abundance of Rho and Rab proteins in membrane and cytosolic fractions as well as of GGTase‐I in brain tissue of 3‐ and 23‐month‐old C57BL/6 mice. We report a shift in the cellular localization of Rho‐GTPases toward reduced levels of membrane‐associated and enhanced cytosolic levels of those proteins in aged mouse brain as compared with younger mice. The age‐related reduction in membrane‐associated Rho proteins was associated with a reduction in GGTase‐Iβ levels that regulates binding of GGPP to Rho‐GTPases. Proteins prenylated by GGTase‐II were not reduced in aged brain indicating a specific targeting of GGTase‐I in the aged brain. Inhibition of GGTase‐I in vitro modeled the effects of aging we observed in vivo. We demonstrate for the first time a decrease in membrane‐associated Rho proteins in aged brain in association with down‐regulation of GGTase‐Iβ. This down‐regulation could be one of the mechanisms causing age‐related weakening of synaptic plasticity.
Dopaminergic neurotransmission in the nucleus accumbens is important for various reward‐related cognitive processes including reinforcement learning. Repeated cocaine enhances hippocampal synaptic plasticity, and phasic elevations of accumbal dopamine evoked by unconditioned stimuli are dependent on impulse flow from the ventral hippocampus. Therefore, sensitized hippocampal activity may be one mechanism by which drugs of abuse enhance limbic dopaminergic activity. In this study, in vivo microdialysis in freely moving adult male Sprague–Dawley rats was used to investigate the effect of repeated cocaine on ventral hippocampus‐mediated dopaminergic transmission within the medial shell of the nucleus accumbens. Following seven daily injections of saline or cocaine (20 mg/kg, ip), unilateral infusion of N‐methyl‐d ‐aspartate (NMDA, 0.5 μg) into the ventral hippocampus transiently increased both motoric activity and ipsilateral dopamine efflux in the medial shell of the nucleus accumbens, and this effect was greater in rats that received repeated cocaine compared to controls that received repeated saline. In addition, repeated cocaine altered NMDA receptor subunit expression in the ventral hippocampus, reducing the NR2A : NR2B subunit ratio. Together, these results suggest that repeated exposure to cocaine produces maladaptive ventral hippocampal‐nucleus accumbens communication, in part through changes in glutamate receptor composition.
As our understanding of motor circuit function increases, our need to understand how circuits form to ensure proper function becomes increasingly important. Recently, deleted in colorectal cancer (DCC) has been shown to be important in the development of spinal circuits necessary for gait. Importantly, humans with mutation in DCC show mirror movement disorders pointing to the significance of DCC in the development of spinal circuits for coordinated movement. Although DCC binds a number of ligands, the intracellular signaling cascade leading to the aberrant spinal circuits remains unknown. Here, we show that the non‐catalytic region of tyrosine kinase adaptor (NCK) proteins 1 and 2 are distributed in the developing spinal cord. Using dissociated dorsal spinal neuron cultures we show that NCK proteins are necessary for the outgrowth and growth cone architecture of DCC+ve dorsal spinal neurons. Consistent with a role for NCK in DCC signaling, we show that loss of NCK proteins leads to a reduction in the thickness of TAG1+ve commissural bundles in the floor plate and loss of DCC mRNA in vivo. We suggest that DCC signaling functions through NCK1 and NCK2 and that both proteins are necessary for the establishment of normal spinal circuits necessary for gait.
Taste information from type III taste cells to gustatory neurons is thought to be transmitted via synapses. However, the molecular mechanisms underlying taste transduction through this pathway have not been fully elucidated. In this study, to identify molecules that participate in synaptic taste transduction, we investigated whether complexins (Cplxs), which play roles in regulating membrane fusion in synaptic vesicle exocytosis, were expressed in taste bud cells. Among four Cplx isoforms, strong expression of Cplx2 mRNA was detected in type III taste cells. To investigate the function of CPLX2 in taste transduction, we observed taste responses in CPLX2‐knockout mice. When assessed with electrophysiological and behavioral assays, taste responses to some sour stimuli in CPLX2‐knockout mice were significantly lower than those in wild‐type mice. These results suggested that CPLX2 participated in synaptic taste transduction from type III taste cells to gustatory neurons.
The positron emission tomography (PET) ligand 11C‐labeled Pittsburgh compound B (PIB) is used to image β‐amyloid (Aβ) deposits in the brains of living subjects with the intent of detecting early stages of Alzheimer's disease (AD). However, deposits of human‐sequence Aβ in amyloid precursor protein transgenic mice and non‐human primates bind very little PIB. The high stoichiometry of PIB:Aβ binding in human AD suggests that the PIB‐binding site may represent a particularly pathogenic entity and/or report local pathologic conditions. In this study, 3H‐PIB was employed to track purification of the PIB‐binding site in > 90% yield from frontal cortical tissue of autopsy‐diagnosed AD subjects. The purified PIB‐binding site comprises a distinct, highly insoluble subfraction of the Aβ in AD brain with low buoyant density because of the sodium dodecyl sulfate‐resistant association with a limited subset of brain proteins and lipids with physical properties similar to lipid rafts and to a ganglioside:Aβ complex in AD and Down syndrome brain. Both the protein and lipid components are required for PIB binding. Elucidation of human‐specific biological components and pathways will be important in guiding improvement of the animal models for AD and in identifying new potential therapeutic avenues.
During neuronal differentiation, axonal elongation is regulated by both external and intrinsic stimuli, including neurotropic factors, cytoskeleton dynamics, second messengers such as cyclic adenosine monophosphate (cAMP), and neuronal excitability. Chloride intracellular channel 1 (CLIC1) is a cytoplasmic hydrophilic protein that, upon stimulation, dimerizes and translocates to the plasma membrane, where it contributes to increase the membrane chloride conductance. Here, we investigated the expression of CLIC1 in primary hippocampal neurons and retinal ganglion cells (RGCs) and examined how the functional expression of CLIC1 specifically modulates neurite outgrowth of neonatal murine RGCs. Using a combination of electrophysiology and immunohistochemistry, we found that CLIC1 is expressed in hippocampal neurons and RGCs and that the chloride current mediated by CLIC1 is required for maintaining growth cone morphology and sustaining cAMP‐stimulated neurite elongation in dissociated immunopurified RGCs. In cultured RGCs, inhibition of CLIC1 ionic current through the pharmacological blocker IAA94 or a specific anti‐CLIC1 antibody directed against its extracellular domain prevents the neurite outgrowth induced by cAMP. CLIC1‐mediated chloride current, which results from an increased open probability of the channel, is detected only when cAMP is elevated. Inhibition of protein kinase A prevents such current. These results indicate that CLIC1 functional expression is regulated by cAMP via protein kinase A and is required for neurite outgrowth modulation during neuronal differentiation.
In this study, in vitro and in vivo experiments were carried out with the high‐affinity multifunctional D2/D3 agonist D‐512 to explore its potential neuroprotective effects in models of Parkinson's disease and the potential mechanism(s) underlying such properties. Pre‐treatment with D‐512 in vitro was found to rescue rat adrenal Pheochromocytoma PC12 cells from toxicity induced by 6‐hydroxydopamine administration in a dose‐dependent manner. Neuroprotection was found to coincide with reductions in intracellular reactive oxygen species, lipid peroxidation, and DNA damage. In vivo, pre‐treatment with 0.5 mg/kg D‐512 was protective against neurodegenerative phenotypes associated with systemic administration of MPTP, including losses in striatal dopamine, reductions in numbers of DAergic neurons in the substantia nigra (SN), and locomotor dysfunction. These observations strongly suggest that the multifunctional drug D‐512 may constitute a novel viable therapy for Parkinson's disease.
The functional roles of the orphan nuclear receptor, Nurr1, have been extensively studied and well established in the development and survival of midbrain dopamine neurons. As Nurr1 and other NR4A members are widely expressed in the brain in overlapping and distinct manners, it has been an open question whether Nurr1 has important function(s) in other brain areas. Recent studies suggest that up‐regulation of Nurr1 expression is critical for cognitive functions and/or long‐term memory in forebrain areas including hippocampal formation. Questions remain about the association between Nurr1 expression and Alzheimer's disease (AD) brain pathology. Here, using our newly developed Nurr1‐selective antibody, we report that Nurr1 protein is prominently expressed in brain areas with Aβ accumulation, that is, the subiculum and the frontal cortex, in the 5XFAD mouse and that Nurr1 is highly co‐expressed with Aβ at early stages. Furthermore, the number of Nurr1‐expressing cells significantly declines in the 5XFAD mouse in an age‐dependent manner, accompanied by increased plaque deposition. Thus, our findings suggest that altered expression of Nurr1 is associated with AD progression.
Clustered protocadherins (cPcdhs) comprising cPcdh‐α, ‐β, and ‐γ, encode a large family of cadherin‐like cell‐adhesion molecules specific to neurons. Impairment of cPcdh‐α results in abnormal neuronal projection patterns in specific brain areas. To elucidate the role of cPcdh‐α in retinogeniculate projections, we investigated the morphological patterns of retinogeniculate terminals in the lateral geniculate (LG) nucleus of mice with impaired cPcdh‐α. We found huge aggregated retinogeniculate terminals in the dorsal LG nucleus, whereas no such aggregated terminals derived from the retina were observed in the olivary pretectal nucleus and the ventral LG nucleus. These aggregated terminals appeared between P10 and P14, just before eye opening and at the beginning of the refinement stage of the retinogeniculate projections. Reduced visual acuity was observed in adult mice with impaired cPcdh‐α, whereas the orientation selectivity and direction selectivity of neurons in the primary visual cortex were apparently normal. These findings suggest that cPcdh‐α is required for adequate spacing of retinogeniculate projections, which may be essential for normal development of visual acuity.
EphrinA/EphA‐dependent axon repulsion is crucial for synaptic targeting in developing neurons but downstream molecular mechanisms remain obscure. Here, it is shown that ephrinA5/EphA3 triggers proteolysis of the neural cell adhesion molecule (NCAM) by the metalloprotease a disintegrin and metalloprotease (ADAM)10 to promote growth cone collapse in neurons from mouse neocortex. EphrinA5 induced ADAM10 activity to promote ectodomain shedding of polysialic acid‐NCAM in cortical neuron cultures, releasing a ~ 250 kDa soluble fragment consisting of most of its extracellular region. NCAM shedding was dependent on ADAM10 and EphA3 kinase activity as shown in HEK293T cells transfected with dominant negative ADAM10 and kinase‐inactive EphA3 (K653R) mutants. Purified ADAM10 cleaved NCAM at a sequence within the E‐F loop of the second fibronectin type III domain (Leu671‐Lys672/Ser673‐Leu674) identified by mass spectrometry. Mutations of NCAM within the ADAM10 cleavage sequence prevented EphA3‐induced shedding of NCAM in HEK293T cells. EphrinA5‐induced growth cone collapse was dependent on ADAM10 activity, was inhibited in cortical cultures from NCAM null mice, and was rescued by WT but not ADAM10 cleavage site mutants of NCAM. Regulated proteolysis of NCAM through the ephrin5/EphA3/ADAM10 mechanism likely impacts synapse development, and may lead to excess NCAM shedding when disrupted, as implicated in neurodevelopmental disorders such as schizophrenia.
Microtubules in neurons consist of highly dynamic regions as well as stable regions, some of which persist after bouts of severing as short mobile polymers. Concentrated at the plus ends of the highly dynamic regions are microtubule plus end tracking proteins called +TIPs that can interact with an array of other proteins and structures relevant to the plasticity of the neuron. It is also provocative to ponder that short mobile microtubules might similarly convey information with them as they transit within the neuron. Thus, beyond their known conventional functions in supporting neuronal architecture and organelle transport, microtubules may act as ‘information carriers’ in the neuron.
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