Although the aberrant assembly of mutant superoxide dismutase 1 (mSOD1) is implicated in the pathogenesis of familial amyotrophic lateral sclerosis (ALS), the molecular basis of superoxide dismutase 1 (SOD1) oligomerization remains undetermined. We investigated the roles of transglutaminase 2 (TG2), an endogenous cross‐linker in mSOD1‐linked ALS. TG2 interacted preferentially with mSOD1 and promoted its oligomerization in transfected cells. Purified TG2 directly oligomerized recombinant mutant SOD1 and the apo‐form of the wild‐type SOD1 proteins in a calcium‐dependent manner, indicating that misfolded SOD1 is a substrate of TG2. Moreover, the non‐cell‐autonomous effect of extracellular TG2 on the neuroinflammation was suggested, since the TG2‐mediated soluble SOD1 oligomers induced tumor necrosis factor‐α, interleukin‐1β, and nitric oxide in microglial BV2 cells. TG2 was up‐regulated in the spinal cord of pre‐symptomatic G93A SOD1 transgenic mice and in the hypoglossal nuclei of mice suffering nerve ligation. Furthermore, inhibition of spinal TG2 by cystamine significantly delayed the progression and reduced SOD1 oligomers and microglial activation. These results indicate a novel role of TG2 in SOD1 oligomer‐mediated neuroinflammation, as well as in the involvement in the intracellular aggregation of misfolded SOD1 in ALS.
There has been great interest in enhancing endogenous protein maintenance pathways such as the heat‐shock chaperone response, as it is postulated that enhancing clearance of misfolded proteins could have beneficial disease modifying effects in amyotrophic lateral sclerosis and other neurodegenerative disorders. In cultured cell models of mutant SOD1 aggregation, co‐expression of αB‐crystallin (αB‐crys) has been shown to inhibit the formation of detergent‐insoluble forms of mutant protein. Here, we describe the generation of a new line of transgenic mice that express αB‐crys at > 6‐fold the normal level in spinal cord, with robust increases in immunoreactivity throughout the spinal cord grey matter and, specifically, in spinal motor neurons. Surprisingly, spinal cords of mice expressing αB‐crys alone contained 20% more motor neurons per section than littermate controls. Raising αB‐crys by these levels in mice transgenic for either G93A or L126Z mutant SOD1 had no effect on the age at which paralysis developed. In the G93A mice, which showed the most robust degree of motor neuron loss, the number of these cells declined by the same proportion as in mice expressing the mutant SOD1 alone. In paralyzed bigenic mice, the levels of detergent‐insoluble, misfolded, mutant SOD1 were similar to those of mice expressing mutant SOD1 alone. These findings indicate that raising the levels of αB‐crys in spinal motor neurons by 6‐fold does not produce the therapeutic effects predicted by cell culture models of mutant SOD1 aggregation.
Cystatin C (CysC) is a major protein component of Bunina bodies, which are a pathological hallmark observed in the remaining motor neurons of patients with amyotrophic lateral sclerosis (ALS). Dominant mutations in the SOD1 gene, encoding Cu/Zn superoxide dismutase (SOD1), are causative for a subset of inherited ALS cases. Our previous study showed that CysC exerts a neuroprotective effect against mutant SOD1‐mediated toxicity in vitro; however, in vivo evidence of the beneficial effects mediated by CysC remains obscure. Here we examined the therapeutic potential of recombinant human CysC in vivo using a mouse model of ALS in which the ALS‐linked mutated SOD1 gene is expressed (SOD1G93A mice). Intracerebroventricular administration of CysC during the early symptomatic SOD1G93A mice extended their survival times. Administered CysC was predominantly distributed in ventral horn neurons including motor neurons, and induced autophagy through AMP‐activated kinase activation to reduce the amount of insoluble mutant SOD1 species. Moreover, PGC‐1α, a disease modifier of ALS, was restored by CysC through AMP‐activated kinase activation. Finally, the administration of CysC also promoted aggregation of CysC in motor neurons, which is similar to Bunina bodies. Taken together, our findings suggest that CysC represents a promising therapeutic candidate for ALS.
Cu/Zn‐superoxide dismutase is misfolded in familial and sporadic amyotrophic lateral sclerosis, but it is not clear how this triggers endoplasmic reticulum (ER) stress or other pathogenic processes. Here, we demonstrate that mutant SOD1 (mSOD1) is predominantly found in the cytoplasm in neuronal cells. Furthermore, we show that mSOD1 inhibits secretory protein transport from the ER to Golgi apparatus. ER‐Golgi transport is linked to ER stress, Golgi fragmentation and axonal transport and we also show that inhibition of ER‐Golgi trafficking preceded ER stress, Golgi fragmentation, protein aggregation and apoptosis in cells expressing mSOD1. Restoration of ER‐Golgi transport by over‐expression of coatomer coat protein II subunit Sar1 protected against inclusion formation and apoptosis, thus linking dysfunction in ER‐Golgi transport to cellular pathology. These findings thus link several cellular events in amyotrophic lateral sclerosis into a single mechanism occurring early in mSOD1 expressing cells.
Mitochondrial glutathione (GSH) is a key endogenous antioxidant and its maintenance is critical for cell survival. Here, we generated stable NSC34 motor neuron‐like cell lines over‐expressing the mitochondrial GSH transporter, the 2‐oxoglutarate carrier (OGC), to further elucidate the importance of mitochondrial GSH transport in determining neuronal resistance to oxidative stress. Two stable OGC cell lines displayed specific increases in mitochondrial GSH content and resistance to oxidative and nitrosative stressors, but not staurosporine. Inhibition of transport through OGC reduced levels of mitochondrial GSH and resensitized the stable cell lines to oxidative stress. The stable OGC cell lines displayed significant up‐regulation of the anti‐apoptotic protein, B cell lymphoma 2 (Bcl‐2). This result was reproduced in parental NSC34 cells by chronic treatment with GSH monoethylester, which specifically increased mitochondrial GSH levels. Knockdown of Bcl‐2 expression decreased mitochondrial GSH and resensitized the stable OGC cells to oxidative stress. Finally, endogenous OGC was co‐immunoprecipitated with Bcl‐2 from rat brain lysates in a GSH‐dependent manner. These data are the first to show that increased mitochondrial GSH transport is sufficient to enhance neuronal resistance to oxidative stress. Moreover, sustained and specific enhancement of mitochondrial GSH leads to increased Bcl‐2 expression, a required mechanism for the maintenance of increased mitochondrial GSH levels.
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.
A growing body of evidence indicates that valproic acid (VPA), a histone deacetylase inhibitor used to treat epilepsy and mood disorders, has histone deacetylase‐related and ‐unrelated neurotoxic activity, the mechanism of which is still poorly understood. We report that VPA induces neuronal cell death through an atypical calpain‐dependent necroptosis pathway that initiates with downstream activation of c‐Jun N‐terminal kinase 1 (JNK1) and increased expression of receptor‐interacting protein 1 (RIP‐1) and is accompanied by cleavage and mitochondrial release/nuclear translocation of apoptosis‐inducing factor, mitochondrial release of Smac/DIABLO, and inhibition of the anti‐apoptotic protein X‐linked inhibitor of apoptosis (XIAP). Coinciding with apoptosis‐inducing factor nuclear translocation, VPA induces phosphorylation of the necroptosis‐associated histone H2A family member H2AX, which is known to contribute to lethal DNA degradation. These signals are inhibited in neuronal cells that express constitutively activated MEK/ERK and/or PI3‐K/Akt survival pathways, allowing them to resist VPA‐induced cell death. The data indicate that VPA has neurotoxic activity and identify a novel calpain‐dependent necroptosis pathway that includes JNK1 activation and RIP‐1 expression.
Trafficking of G protein‐coupled receptors plays a crucial role in controlling the precise signalling of the receptor as well as its proper regulation. Metabotropic glutamate receptor 1 (mGluR1), a G protein‐coupled receptor, is a member of the group I mGluR family. mGluR1 plays a critical role in neuronal circuit formation and also in multiple types of synaptic plasticity. This receptor has also been reported to be involved in various neuropsychiatric diseases. Other than the central nervous system, mGluR1 plays crucial roles in various non‐neuronal cells like hepatocytes, skin cells, etc. Although it has been reported that mGluR1 gets endocytosed on ligand application, the events after the internalization of the receptor has not been studied. We show here that mGluR1 internalizes on ligand application. Subsequent to endocytosis, majority of the receptors localize at the recycling compartment and no significant presence of the receptor was noticed in the lysosome. Furthermore, mGluR1 returned to the cell membrane subsequent to ligand‐mediated internalization. We also show here that the recycling of mGluR1 is dependent on the activity of protein phosphatase 2A. Thus, our data suggest that the ligand‐mediated internalized receptors recycle back to the cell surface in protein phosphatase 2A‐dependent manner.
HIV‐1 invades CNS in the early course of infection, which can lead to the cascade of neuroinflammation. NADPH oxidases (NOXs) are the major producers of reactive oxygen species (ROS), which play important roles during pathogenic insults. The molecular mechanism of ROS generation via microRNA‐mediated pathway in human microglial cells in response to HIV‐1 Tat protein has been demonstrated in this study. Over‐expression and knockdown of microRNAs, luciferase reporter assay, and site‐directed mutagenesis are main molecular techniques used in this study. A significant reduction in miR‐17 levels and increased NOX2, NOX4 expression levels along with ROS production were observed in human microglial cells upon HIV‐1 Tat C exposure. The validation of NOX2 and NOX4 as direct targets of miR‐17 was done by luciferase reporter assay. The over‐expression and knockdown of miR‐17 in human microglial cells showed the direct role of miR‐17 in regulation of NOX2, NOX4 expression and intracellular ROS generation. We demonstrated the regulatory role of cellular miR‐17 in ROS generation through over‐expression and knockdown of miR‐17 in human microglial cells exposed to HIV‐1 Tat C protein.
For our nervous system to function properly, each neuron must generate a single axon and elongate the axon to reach its target. It is known that actin filaments and their dynamic interaction with microtubules within growth cones play important roles in inducing axon extension. However, it remains unclear how cytoskeletal dynamics is controlled in growth cones. In this study, we report that Rufy3, a RUN domain‐containing protein, is a neuron‐specific and actin filament‐relevant protein. We find that the appropriate expression of Rufy3 in mouse hippocampal neurons is required for the development of a single axon and axon growth. Our results show that Rufy3 specifically interacts with actin filament‐binding proteins, such as Fascin, and colocalizes with Fascin in growth cones. Knockdown of Rufy3 impairs the distribution of Fascin and actin filaments, accompanied by an increased proportion of neurons with multiple axons and a decrease in the axon length. Therefore, Rufy3 may be particularly important for neuronal axon elongation by interacting with Fascin to control actin filament organization in axonal growth cones.
Most physiological processes in mammals are synchronized to the daily light:dark cycle by a circadian clock located in the hypothalamic suprachiasmatic nucleus. Signal transduction of light‐induced phase advances of the clock is mediated through a neuronal nitric oxide synthase‐guanilyl cyclase pathway. We have employed a novel nitric oxide‐donor, N‐nitrosomelatonin, to enhance the photic synchronization of circadian rhythms in hamsters. The intraperitoneal administration of this drug before a sub‐saturating light pulse at circadian time 18 generated a twofold increase of locomotor rhythm phase‐advances, having no effect over saturating light pulses. This potentiation was also obtained even when inhibiting suprachiasmatic nitric oxide synthase activity. However, N‐nitrosomelatonin had no effect on light‐induced phase delays at circadian time 14. The photic‐enhancing effects were correlated with an increased suprachiasmatic immunoreactivity of FBJ murine osteosarcoma viral oncogene and period1. Moreover, in vivo nitric oxide release by N‐nitrosomelatonin was verified by measuring nitrate and nitrite levels in suprachiasmatic nuclei homogenates. The compound also accelerated resynchronization to an abrupt 6‐h advance in the light:dark cycle (but not resynchronization to a 6‐h delay). Here, we demonstrate the chronobiotic properties of N‐nitrosomelatonin, emphasizing the importance of nitric oxide‐mediated transduction for circadian phase advances.
Retinal degenerative diseases (RDs) are a group of inherited diseases characterized by the loss of photoreceptor cells. Selective photoreceptor loss can be induced in mice by an intraperitoneal injection of N‐methyl‐N‐nitrosourea (MNU) and, because of its selectivity, this model is widely used to study the mechanism of RDs. Although it is known that calcium‐calpain activation and lipid peroxidation are involved in the initiation of cell death, the precise mechanisms of this process remain unknown. Heat shock protein 70 (HSP70) has been shown to function as a chaperone molecule to protect cells against environmental and physiological stresses. In this study, we investigated the role of HSP70 on photoreceptor cell death in mice. HSP70 induction by valproic acid, a histone deacetylase inhibitor, attenuated the photoreceptor cell death by MNU through inhibition of apoptotic caspase signals. Furthermore, HSP70 itself was rapidly and calpain‐dependently cleaved after MNU treatment. Therefore, HSP70 induction by valproic acid was dually effective against MNU‐induced photoreceptor cell loss as a result of its anti‐apoptotic actions and its ability to prevent HSP70 degradation. These findings might help lead us to a better understanding of the pathogenic mechanism of RDs.
The administration of pan histone deacetylase (HDAC) inhibitors reduces ischemic damage to the CNS, both in vitro and in animal models of stroke, via mechanisms which we are beginning to understand. The acetylation of p53 is regulated by Class I HDACs and, because p53 appears to play a role in ischemic pathology, the purpose of this study was to discover, using an in vitro white matter ischemia model and an in vivo cerebral ischemia model, if neuroprotection mediated by HDAC inhibition depended on p53 expression. Optic nerves were excised from wild‐type and p53‐deficient mice, and then subjected to oxygen–glucose deprivation in the presence and absence of a specific inhibitor of Class I HDACs (MS‐275, entinostat) while compound action potentials were recorded. Furthermore, transient focal ischemia was imposed on wild‐type and p53‐deficient mice, which were subsequently treated with MS‐275. Interestingly, and in both scenarios, the beneficial effects of MS‐275 were most pronounced when p53 was absent. These results suggest that modulation of p53 activity is not responsible for MS‐275‐mediated neuroprotection, and further illustrate how HDAC inhibitors variably influence p53 and associated apoptotic pathways.
CNS trauma generates a proteolytic imbalance contributing to secondary injury, including axonopathy and neuron degeneration. Kallikrein 6 (Klk6) is a serine protease implicated in neurodegeneration, and here we investigate the role of protease‐activated receptors 1 (PAR1) and PAR2 in mediating these effects. First, we demonstrate Klk6 and the prototypical activator of PAR1, thrombin, as well as PAR1 and PAR2, are each elevated in murine experimental traumatic spinal cord injury (SCI) at acute or subacute time points. Recombinant Klk6 triggered extracellular signal‐regulated kinase (ERK1/2) signaling in cerebellar granule neurons and in the NSC34 spinal cord motoneuron cell line, in a phosphoinositide 3‐kinase and MEK‐dependent fashion. Importantly, lipopeptide inhibitors of PAR1 or PAR2, and PAR1 genetic deletion, each reduced Klk6‐ERK1/2 activation. In addition, Klk6 and thrombin promoted degeneration of cerebellar neurons and exacerbated glutamate neurotoxicity. Moreover, genetic deletion of PAR1 blocked thrombin‐mediated cerebellar neurotoxicity and reduced the neurotoxic effects of Klk6. Klk6 also increased glutamate‐mediated Bim signaling, poly‐ADP‐ribose polymerase cleavage and lactate dehydrogenase release in NSC34 motoneurons and these effects were blocked by PAR1 and PAR2 lipopeptide inhibitors. Taken together, these data point to a novel Klk6‐signaling axis in CNS neurons that is mediated by PAR1 and PAR2 and is positioned to contribute to neurodegeneration.
Our previous work has suggested that traumatic noise activates Rho‐GTPase pathways in cochlear outer hair cells (OHCs), resulting in cell death and noise‐induced hearing loss (NIHL). In this study, we investigated Rho effectors, Rho‐associated kinases (ROCKs), and the targets of ROCKs, the ezrin‐radixin‐moesin (ERM) proteins, in the regulation of the cochlear actin cytoskeleton using adult CBA/J mice under conditions of noise‐induced temporary threshold shift (TTS) and permanent threshold shift (PTS) hearing loss, which result in changes to the F/G‐actin ratio. The levels of cochlear ROCK2 and p‐ERM decreased 1 h after either TTS‐ or PTS‐noise exposure. In contrast, ROCK2 and p‐ERM in OHCs decreased only after PTS‐, not after TTS‐noise exposure. Treatment with lysophosphatidic acid, an activator of the Rho pathway, resulted in significant reversal of the F/G‐actin ratio changes caused by noise exposure and attenuated OHC death and NIHL. Conversely, the down‐regulation of ROCK2 by pretreatment with ROCK2 siRNA reduced the expression of ROCK2 and p‐ERM in OHCs, exacerbated TTS to PTS, and worsened OHC loss. Additionally, pretreatment with siRNA against radixin, an ERM protein, aggravated TTS to PTS. Our results indicate that a ROCK2‐mediated ERM‐phosphorylation signaling cascade modulates noise‐induced hair cell loss and NIHL by targeting the cytoskeleton.
The protein kinase C γ (PKCγ) undergoes multistep activation and participates in various cellular processes in Purkinje cells. Perturbations in its phosphorylation state, conformation or localization can disrupt kinase signalling, such as in spinocerebellar ataxia type 14 (SCA14) that is caused by missense mutations in PRKCG encoding for PKCγ. We previously showed that SCA14 mutations enhance PKCγ membrane translocation upon stimulation owing to an altered protein conformation. As the faster translocation did not result in an increased function, we examined how SCA14 mutations induce this altered conformation of PKCγ and what the consequences of this conformational change are on PKCγ life cycle. Here, we show that SCA14‐related PKCγ‐V138E exhibits an exposed C‐terminus as shown by fluorescence resonance energy transfer‐fluorescence lifetime imaging microscopy in living cells, indicative of its partial unfolding. This conformational change was associated with faster phorbol 12‐myristate 13‐acetate‐induced translocation and accumulation of fully phosphorylated PKCγ in the insoluble fraction, which could be rescued by coexpressing PDK1 kinase that normally triggers PKCγ autophosphorylation. We propose that the SCA14 mutation V138E causes unfolding of the C1B domain and exposure of the C‐terminus of the PKCγ‐V138E molecule, resulting in a decrease of functional kinase in the soluble fraction.
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