Unmasking the skiptic task of TDP‐43

The mechanism by which mutations in TAR DNA‐binding protein 43 (TDP‐43) cause neurodegeneration remains incompletely understood. In this issue of The EMBO Journal, Fratta et al ( 2018 ) describe how a point mutation in the C‐terminal low complexity domain of TDP‐43 leads to the skipping of otherwise constitutively conserved exons. In vivo, this mutation triggers late‐onset progressive neuromuscular disturbances, as seen in amyotrophic lateral sclerosis (ALS), suggesting that TDP‐43 splicing gain‐of‐function contributes to ALS pathogenesis.     

Absence of TDP‐43 is difficult to digest

It is well established that TDP‐43 accumulates in degenerating neurons in patients with ALS/FTLD, which might affect normal TDP‐43 function. In this issue of The EMBO Journal Xia et al ( 2016 ) show a novel connection between TDP‐43 loss of function and autophagy failure. Using knockdown models of TDP‐43, they observed enhanced autophagosome and lysosome biogenesis through mTORC1 activity inhibition and TFEB activation. Impaired autophagosome–lysosome fusion was also observed, however in an mTORC1‐independent manner. The data identify dysfunctions at multiple stages of the autophagic pathway following TDP‐43 depletion that might represent possible targets of future therapeutic interventions.     

Expression of ALS‐linked TDP‐43 mutant in astrocytes causes non‐cell‐autonomous motor neuron death in rats

Mutation of Tar DNA‐binding protein 43 (TDP‐43) is linked to amyotrophic lateral sclerosis. Although astrocytes have important roles in neuron function and survival, their potential contribution to TDP‐43 pathogenesis is unclear. Here, we created novel lines of transgenic rats that express a mutant form of human TDP‐43 (M337V substitution) restricted to astrocytes. Selective expression of mutant TDP‐43 in astrocytes caused a progressive loss of motor neurons and the denervation atrophy of skeletal muscles, resulting in progressive paralysis. The spinal cord of transgenic rats also exhibited a progressive depletion of the astroglial glutamate transporters GLT‐1 and GLAST. Astrocytic expression of mutant TDP‐43 led to activation of astrocytes and microglia, with an induction of the neurotoxic factor Lcn2 in reactive astrocytes that was independent of TDP‐43 expression. These results indicate that mutant TDP‐43 in astrocytes is sufficient to cause non‐cell‐autonomous death of motor neurons. This motor neuron death likely involves deficiency in neuroprotective genes and induction of neurotoxic genes in astrocytes.     

Parkin reverses TDP‐43‐induced cell death and failure of amino acid homeostasis

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.

     

Growth‐associated protein 43 promotes thyroid cancer cell lines progression via epithelial‐mesenchymal transition

Thyroid cancer is maintaining at a high incidence level and its carcinogenesis is mainly affected by a complex gene interaction. By analysis of the next‐generation resequencing of paired papillary thyroid cancer (PTC) and adjacent thyroid tissues, we found that Growth Associated Protein 43 (GAP43), a phosphoprotein activated by protein kinase C, might be novel markers associated with PTC. However, its function in thyroid carcinoma has been poorly understood. We discovered that GAP43 was significantly overexpressed in thyroid carcinoma and these results were consistent with that in The Cancer Genome Atlas (TCGA) cohort. In addition, some clinicopathological features of GAP43 in TCGA database showed that up‐regulated GAP43 is significantly connected to lymph node metastasis (P < 0.001) and tumour size (P = 0.038). In vitro experiments, loss of function experiments was performed to investigate GAP43 in PTC cell lines (TPC‐1 and BCPAP). The results proved that GAP43 knockdown in PTC cell significantly decreased the function of cell proliferation, colony formation, migration, and invasion and induced cell apoptosis. Furthermore, we also indicated that GAP43 could modulate the expression of epithelial‐mesenchymal transition‐related proteins, which could influence invasion and migration. Put those results together, GAP43 is a gene which was associated with PTC and might be a potential therapeutic target.     

A novel TXNIP‐based mechanism for Cx43‐mediated regulation of oxidative drug injury

Gap junctions (GJs) play an important role in the regulation of cell response to many drugs. However, little is known about their mechanisms. Using an in vitro model of cytotoxicity induced by geneticin (G418), we explored the potential signalling mechanisms involved. Incubation of cells with G418 resulted in cell death, as indicated by the change in cell morphology, loss of cell viability and activation of caspase‐3. Before the onset of cell injury, G418 induced reactive oxygen species (ROS) generation, activated oxidative sensitive kinase P38 and caused a shift of connexin 43 (Cx43) from non‐phosphorylated form to hyperphosphorylated form. These changes were largely prevented by antioxidants, suggesting an implication of oxidative stress. Downregulation of Cx43 with inhibitors or siRNA suppressed the expression of thioredoxin‐interacting protein (TXNIP), activated Akt and protected cells against the toxicity of G418. Further analysis revealed that inhibition of TXNIP with siRNA activated Akt and reproduced the protective effect of Cx43‐inhibiting agents, whereas suppression of Akt sensitized cells to the toxicity of G418. Furthermore, interference of TXNIP/Akt also affected puromycin‐ and adriamycin‐induced cell injury. Our study thus characterized TXNIP as a presently unrecognized molecule implicated in the regulatory actions of Cx43 on oxidative drug injury. Targeting Cx43/TXNIP/Akt signalling cascade might be a promising approach to modulate cell response to drugs.     

Profiling the genes affected by pathogenic TDP‐43 in astrocytes

Mutation in TAR DNA binding protein 43 (TDP‐43) is a causative factor of amyotrophic lateral sclerosis and frontotemporal lobar degeneration. Neurodegeneration may not require the presence of pathogenic TDP‐43 in all types of relevant cells. Rather, expression of pathogenic TDP‐43 in neurons or astrocytes alone is sufficient to cause cell‐autonomous or non‐cell‐autonomous neuron death in transgenic rats. How pathogenic TDP‐43 in astrocytes causes non‐cell‐autonomous neuron death, however, is not clear. Here, we examined the effect of pathogenic TDP‐43 on gene expression in astrocytes. Microarray assay revealed that pathogenic TDP‐43 in astrocytes preferentially altered expression of the genes encoding secretory proteins. Whereas neurotrophic genes were down‐regulated, neurotoxic genes were up‐regulated. Representative genes Lcn2 and chitinase‐3‐like protein 1 were markedly up‐regulated in astrocytes from primary culture and intact transgenic rats. Furthermore, synthetic chitinase‐3‐like protein 1 induced neuron death in a dose‐dependent manner. Our results suggest that TDP‐43 pathogenesis is associated with the simultaneous induction of multiple neurotoxic genes in astrocytes, which may synergistically produce adverse effects on neuronal survival and contribute to non‐cell‐autonomous neuron death.

     

Aliskiren‐attenuated myocardium apoptosis via regulation of autophagy and connexin‐43 in aged spontaneously hypertensive rats

There are controversies about the mechanism of myocardium apoptosis in hypertensive heart disease. The aim of this study was to investigate the relationship among autophagy, Cx43 and apoptosis in aged spontaneously hypertensive rats (SHRs) and establish whether Aliskiren is effective or not for the treatment of myocardium apoptosis. Twenty‐one SHRs aged 52 weeks were randomly divided into three groups, the first two receiving Aliskiren at a dose of 10 and 25 mg/kg/day respectively; the third, placebo for comparison with seven Wistar‐Kyoto (WKY) as controls. After a 2‐month treatment, systolic blood pressure (SBP), heart to bw ratios (HW/BW%) and angiotensin II (AngII) concentration were significantly enhanced in SHRs respectively. Apoptotic cardiomyocytes detected with TUNEL and immunofluorescent labelling for active caspase‐3 increased nearly fourfolds in SHRs, with a decline in the expression of survivin and AKT activation, and an increase in caspase‐3 activation and the ratio of Bax/Bcl‐2. Myocardium autophagy, detected with immunofluorescent labelling for LC3‐II, increased nearly threefolds in SHRs, with the up‐regulation of Atg5, Atg16L1, Beclin‐1 and LC3‐II. The expression of Cx43 plaque was found to be down‐regulated in SHRs. Aliskiren significantly reduced SBP, HW/BW%, AngII concentration and the expression of AT₁R. Thus, Aliskiren protects myocardium against apoptosis by decreasing autophagy, up‐regulating Cx43. These effects showed a dose‐dependent tendency, but no significance. In conclusion, the myocardium apoptosis developed during the hypertensive end‐stage of SHRs could be ameliorated by Aliskiren via the regulation of myocardium autophagy and maladaptive remodelling of Cx43.     

Myocardin and microRNA‐1 modulate bladder activity through connexin 43 expression during post‐natal development

Overactive bladder (OAB) is a pervasive clinical problem involving alterations in both neurogenic and myogenic activity. While there has been some progress in understanding neurogenic inputs to OAB, the mechanisms controlling myogenic bladder activity are unclear. We report the involvement of myocardin (MYOCD) and microRNA‐1 (miR‐1) in the regulation of connexin 43 (GJA1), a major gap junction in bladder smooth muscle, and the collective role of these molecules during post‐natal bladder development. Wild‐type (WT) mouse bladders showed normal development from early post‐natal to adult including increases in bladder capacity and maintenance of normal sensitivity to cholinergic agents concurrent with down‐regulation of MYOCD and several smooth muscle cell (SMC) contractile genes. Myocardin heterozygous‐knockout mice exhibited reduced expression of Myocd mRNA and several SMC contractile genes concurrent with bladder SMC hypersensitivity that was mediated by gap junctions. In both cultured rat bladder SMC and in vivo bladders, MYOCD down‐regulated GJA1 expression through miR‐1 up‐regulation. Interestingly, adult myocardin heterozygous‐knockout mice showed normal increases in bladder and body weight but lower bladder capacity compared to WT mice. These results suggest that MYOCD down‐regulates GJA1 expression via miR‐1 up‐regulation, thereby contributing to maintenance of normal sensitivity and development of bladder capacity. J. Cell. Physiol. 228: 1819–1826, 2013. © 2013 Wiley Periodicals, Inc.     

Gastrodin alleviates Tourette syndrome via Nrf‐2/HO‐1/HMGB1/NF‐кB pathway

The aim is to study the effects of gastrodin (GA) on striatal inflammation and oxidative stress in rats with Tourette syndrome (TS). The rat model of TS was induced by 3,3′‐iminodipropionitrile. Behavioral tests were carried out by stereotype experiment. The concentrations of amino acid transmitters glutamic acid (Glu) and γ‐aminobutyric acid (GABA) in striatum were determined by high‐performance liquid chromatography. Superoxide dismutase (SOD) and malondialdehyde (MDA) in serum and striatum were detected by commercial kits. Cytokines in serum and striatum were detected by enzyme‐linked immunosorbent assay kits. Western blot analysis was used to detect striatum nuclear erythroid factor 2‐related factor 2 (Nrf‐2)/heme oxygenase‐1 (HO‐1)/high mobility group box 1 protein (HMGB1)/nuclear factor‐кB (NF‐кB) pathway‐related proteins. The expressions of Nrf‐2 and P‐NF‐кBp65 in striatum were detected by immunohistochemistry. Compared with the control group, the stereotype scores of rats in the model group significantly increased, and the contents of Glu and GABA in striatum obviously increased. GA significantly reduced the stereotype scores and decreased the contents of Glu and GABA. The levels of SOD in serum and striatum were decreased and the content of MDA in serum and striatum were increased compared with the control group, while GA significantly restored the changes. GA significantly adjusted Nrf‐2/HO‐1/HMGB1/NF‐кB pathway‐related proteins changes consistent with immunohistochemical changes. GA may protect striatum of rats with TS by regulating Nrf‐2/HO‐1/HMGB1/NF‐кB pathway protein changes in striatum.     

A single N‐terminal phosphomimic disrupts TDP‐43 polymerization,phase separation,and RNA splicing

TDP‐43 is an RNA‐binding protein active in splicing that concentrates into membraneless ribonucleoprotein granules and forms aggregates in amyotrophic lateral sclerosis (ALS) and Alzheimer's disease. Although best known for its predominantly disordered C‐terminal domain which mediates ALS inclusions, TDP‐43 has a globular N‐terminal domain (NTD). Here, we show that TDP‐43 NTD assembles into head‐to‐tail linear chains and that phosphomimetic substitution at S48 disrupts TDP‐43 polymeric assembly, discourages liquid–liquid phase separation (LLPS) in vitro, fluidizes liquid–liquid phase separated nuclear TDP‐43 reporter constructs in cells, and disrupts RNA splicing activity. Finally, we present the solution NMR structure of a head‐to‐tail NTD dimer comprised of two engineered variants that allow saturation of the native polymerization interface while disrupting higher‐order polymerization. These data provide structural detail for the established mechanistic role of the well‐folded TDP‐43 NTD in splicing and link this function to LLPS. In addition, the fusion‐tag solubilized, recombinant form of TDP‐43 full‐length protein developed here will enable future phase separation and in vitro biochemical assays on TDP‐43 function and interactions that have been hampered in the past by TDP‐43 aggregation.     

Resistance to change and vulnerability to stress: autistic‐like features of GAP43‐deficient mice

There is an urgent need for animal models of autism spectrum disorder (ASD) to understand the underlying pathology and facilitate development and testing of new treatments. The synaptic growth‐associated protein‐43 (GAP43) has recently been identified as an autism candidate gene of interest. Our previous studies show many brain abnormalities in mice lacking one allele for GAP43 [GAP43 (+/?)] that are consistent with the disordered connectivity theory of ASD. Thus, we hypothesized that GAP43 (+/?) mice would show at least some autistic‐like behaviors. We found that GAP43 (+/?) mice, relative to wild‐type (+/+) littermates, displayed resistance to change, consistent with one of the diagnostic criteria for ASD. GAP43 (+/?) mice also displayed stress‐induced behavioral withdrawal and anxiety, as seen in many autistic individuals. In addition, both GAP43 (+/?) mice and (+/+) littermates showed low social approach and lack of preference for social novelty, consistent with another diagnostic criterion for ASD. This low sociability is likely because of the mixed C57BL/6J 129S3/SvImJ background. We conclude that GAP43 deficiency leads to the development of a subset of autistic‐like behaviors. As these behaviors occur in a mouse that displays disordered connectivity, we propose that future anatomical and functional studies in this mouse may help uncover underlying mechanisms for these specific behaviors. Strain‐specific low sociability may be advantageous in these studies, creating a more autistic‐like environment for study of the GAP43‐mediated deficits of resistance to change and vulnerability to stress.     

TDP‐43 loss of function increases TFEB activity and blocks autophagosome–lysosome fusion

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disease that is characterized by selective loss of motor neurons in brain and spinal cord. TAR DNA‐binding protein 43 (TDP‐43) was identified as a major component of disease pathogenesis in ALS, frontotemporal lobar degeneration (FTLD), and other neurodegenerative disease. Despite the fact that TDP‐43 is a multi‐functional protein involved in RNA processing and a large number of TDP‐43 RNA targets have been discovered, the initial toxic effect and the pathogenic mechanism underlying TDP‐43‐linked neurodegeneration remain elusive. In this study, we found that loss of TDP‐43 strongly induced a nuclear translocation of TFEB, the master regulator of lysosomal biogenesis and autophagy, through targeting the mTORC1 key component raptor. This regulation in turn enhanced global gene expressions in the autophagy–lysosome pathway (ALP) and increased autophagosomal and lysosomal biogenesis. However, loss of TDP‐43 also impaired the fusion of autophagosomes with lysosomes through dynactin 1 downregulation, leading to accumulation of immature autophagic vesicles and overwhelmed ALP function. Importantly, inhibition of mTORC1 signaling by rapamycin treatment aggravated the neurodegenerative phenotype in a TDP‐43‐depleted Drosophila model, whereas activation of mTORC1 signaling by PA treatment ameliorated the neurodegenerative phenotype. Taken together, our data indicate that impaired mTORC1 signaling and influenced ALP may contribute to TDP‐43‐mediated neurodegeneration.     

HIV increases the release of dickkopf‐1 protein from human astrocytes by a Cx43 hemichannel‐dependent mechanism

Human immunodeficiency virus‐1 (HIV) is a public health issue and a major complication of the disease is NeuroAIDS. In vivo, microglia/macrophages are the main cells infected. However, a low but significant number of HIV‐infected astrocytes has also been detected, but their role in the pathogenesis of NeuroAIDS is not well understood. Our previous data indicate that gap junction channels amplify toxicity from few HIV‐infected into uninfected astrocytes. Now, we demonstrated that HIV infection of astrocytes results in the opening of connexin43 hemichannels (HCs). HIV‐induced opening of connexin43 HCs resulted in dysregulated secretion of dickkopf‐1 protein (DKK1, a soluble wnt pathway inhibitor). Treatment of mixed cultures of neurons and astrocytes with DKK1, in the absence of HIV infection, resulted in the collapse of neuronal processes. HIV infection of mixed cultures of human neurons and astrocytes also resulted in the collapse of neuronal processes through a DKK1‐dependent mechanism. In addition, dysregulated DKK1 expression in astrocytes was observed in human brain tissue sections of individuals with HIV encephalitis as compared to tissue sections from uninfected individuals. Thus, we demonstrated that HIV infection of astrocytes induces dysregulation of DKK1 by a HC‐dependent mechanism that contributes to the brain pathogenesis observed in HIV‐infected individuals.