17 research outputs found

    FOXO3a is broadly neuroprotective in vitro and in vivo against insults implicated in motor neuron diseases

    Get PDF
    Aging is a risk factor for the development of adult-onset neuro-degenerative diseases. While some of the molecular pathways regulating longevity and stress resistance in lower organisms are defined (i.e., those activating the transcriptional regulators DAF-16 and HSF-1 in C. elegans), their relevance to mammals and disease susceptibility are unknown. We studied the signaling controlled by the mammalian homolog of DAF-16, FOXO3a, in model systems of motor neuron disease. Neuron death elicited in vitro by excitotoxic insult or the expression of mutant SOD1, mutant p150(glued) or polyQ expanded androgen receptor was abrogated by expression of nuclear-targeted FOXO3a. We identify a compound (Psammaplysene A, PA) that increases nuclear localization of FOXO3a in vitro and in vivo and show that PA also protects against these insults in vitro. Administration of PA to invertebrate model systems of neurodegeneration similarly blocked neuron death in a DAF-16/FOXO3a-dependent manner. These results indicate that activation of the DAF-16/FOXO3a pathway, genetically or pharmacologically, confers protection against the known causes of motor neuron diseases

    Evidence that hypoxia-inducible factor-1 (HIF-1) mediates transcriptional activation of Interleukin-1\u3b2(1L-1\u3b2)in astrocyte cultures

    No full text
    Hypoxia-inducible factor-1 (HIF-1) is a heterodimeric transcription factor composed of HIF-1\u3b1 and HIF-1\u3b2 subunits and involved in the regulation of gene expression in adaptive response to hypoxia. This study reports that the inflammatory cytokine interleukin-1\u3b2 (IL-1\u3b2) shares common features of other known HIF-1\u3b1-regulated genes. Both human and mouse IL-1\u3b2 genes carry multiple HIF-1-binding sites in their promoter regions and are up-regulated by hypoxia and CoCl2 in human and mouse astrocytes in parallel with up-regulation of HIF-1\u3b1 mRNA and protein. Inhibition of HIF-1\u3b1 degradation by proteasome inhibitor, MG-132, potentiated hypoxia-induced IL-1\u3b2 release from human astrocytes, and this response was blocked in the presence of CdCl2. Mouse astrocytes with Hif1\u3b1+/ 12 genotype demonstrated attenuated up-regulation of both HIF-1\u3b1 and IL-1\u3b2 by hypoxia and CoCl2. Mutation of HIF-1-binding sites in the IL-1\u3b2 promoter abolished hypoxia-induced transactivation of the reporter gene transfected into human astrocytes. Similarly, HIF-1 binding \u201cdecoy\u201d oligonuleotide transfected into astrocytes inhibited both hypoxia-induced transactivation of the HIF-1 reporter gene and IL-1\u3b2 secretion from transfected astrocytes. Collectively, the evidence suggests that the transcriptional activation of IL-1\u3b2 in astrocytes exposed to hypoxia occurs via HIF-1.NRC publication: Ye

    GluR1 controls dendrite growth through its binding partner, SAP97

    No full text
    Activity-dependent dendrite elaboration influences the pattern of interneuronal connectivity and network function. In the present study, we examined the mechanism by which the GluR1 subunit of AMPA receptors controls dendrite morphogenesis. GluR1 binds to SAP97, a scaffolding protein that is a component of the postsynaptic density, via its C-terminal 7 aa. We find that elimination of this interaction in vitro or in vivo (by deleting the C-terminal 7 aa of GluR1, GluR1Delta7) does not influence trafficking, processing, or cell surface GluR1 expression but does prevent translocation of SAP97 from the cytosol to membranes. GluR1 and SAP97 together at the plasma membrane promotes dendrite branching in an activity-dependent manner, although this does not require physical association. Our findings suggest that the C-terminal 7 aa of GluR1 are essential for bringing SAP97 to the plasma membrane, where it acts to translate the activity of AMPA receptors into dendrite growth

    Inhibition of cytohesins protects against genetic models of motor neuron disease

    No full text
    Mutant genes that underlie Mendelian forms of amyotrophic lateral sclerosis (ALS) and biochemical investigations of genetic disease models point to potential driver pathophysiological events involving endoplasmic reticulum (ER) stress and autophagy. Several steps in these cell biological processes are known to be controlled physiologically by small ADP-ribosylation factor (ARF) signaling. Here, we investigated the role of ARF guanine nucleotide exchange factors (GEFs), cytohesins, in models of ALS. Genetic or pharmacological inhibition of cytohesins protects motor neurons in vitro from proteotoxic insults and rescues locomotor defects in a Caenorhabditis elegans model of disease. Cytohesins form a complex with mutant superoxide dismutase 1 (SOD1), a known cause of familial ALS, but this is not associated with a change in GEF activity or ARF activation. ER stress evoked by mutant SOD1 expression is alleviated by antagonism of cytohesin activity. In the setting of mutant SOD1 toxicity, inhibition of cytohesin activity enhances autophagic flux and reduces the burden of misfolded SOD1. These observations suggest that targeting cytohesins may have potential benefits for the treatment of ALS

    Neurons undergo pathogenic metabolic reprogramming in models of familial ALS.

    Get PDF
    OBJECTIVES: Normal cellular function requires a rate of ATP production sufficient to meet demand. In most neurodegenerative diseases (including Amyotrophic Lateral Sclerosis [ALS]), mitochondrial dysfunction is postulated raising the possibility of impaired ATP production and a need for compensatory maneuvers to sustain the ATP production/demand balance. We investigated intermediary metabolism of neurons expressing familial ALS (fALS) genes and interrogated the functional consequences of glycolysis genes in fitness assays and neuronal survival. METHODS: We created a pure neuronal model system for isotopologue investigations of fuel utilization. In a yeast platform we studied the functional contributions of glycolysis genes in a growth fitness assay iafter expressing of a fALS gene. RESULTS: We find in our rodent models of fALS, a reduction in neuronal lactate production with maintained or enhanced activity of the neuronal citric acid cycle. This rewiring of metabolism is associated with normal ATP levels, bioenergetics, and redox status, thus supporting the notion that gross mitochondrial function is not compromised in neurons soon after expressing fALS genes. Genetic loss-of-function manipulation of individual steps in the glycolysis and the pentose phosphate pathway blunt the negative phenotypes seen in various fALS models. CONCLUSIONS: We propose that neurons adjust fuel utilization in the setting of neurodegenerative disease-associated alteration in mitochondrial function in a baleful manner and targeting this process can be healthful

    Role of GluR1 in activity−dependent motor system development

    No full text
    Activity−dependent specification of neuronal architecture during early postnatal life is essential for refining the precision of communication between neurons. In the spinal cord under normal circumstances, the AMPA receptor subunit GluR1 is expressed at high levels by motor neurons and surrounding interneurons during this critical developmental period, although the role it plays in circuit formation and locomotor behavior is unknown. Here, we show that GluR1 promotes dendrite growth in a non−cell−autonomous manner in vitro and in vivo. The mal−development of motor neuron dendrites is associated with changes in the pattern of interneuronal connectivity within the segmental spinal cord and defects in strength and endurance. Transgenic expression of GluR1 in adult motor neurons leads to dendrite remodeling and supernormal locomotor function. GluR1 expression by neurons within the segmental spinal cord plays an essential role in formation of the neural network that underlies normal motor behavior
    corecore