14 research outputs found

    Beneficial Effect of Phenytoin and Carbamazepine on GFAP Gene Expression and Mutant GFAP Folding in a Cellular Model of Alexander's Disease

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    Alexander's disease (AxD) is a rare, usually relentlessly progressive disorder of astroglial cells in the central nervous system related to mutations in the gene encoding the type III intermediate filament protein, glial fibrillary acidic protein (GFAP). The pathophysiology of AxD is only partially understood. Available data indicate that an excessive GFAP gene expression may play a role. In particular, a "threshold hypothesis" has been reported, suggesting that mutant GFAP representing about 20% of the total cellular GFAP should be sufficient to cause disease. Thus, strategies based on reducing cellular mutant GFAP protein levels and/or activating biological processes involved in the correct protein folding could be effective in counteracting the toxic effect of misfolded GFAP. Considering that clomipramine (CLM), which has been selected by a wide small molecules screening as the greatest inhibitory potential drug against GFAP expression, is contraindicated because of its proconvulsant activity in the infantile form of AxD, which is also characterized by the occurrence of epileptic seizures, two powerful antiepileptic agents, carbamazepine (CBZ) and phenytoin (PHT), which share specific stereochemical features in common with CLM, were taken into consideration in a reliable in vitro model of AxD. In the present work, we document for the first time that CBZ and PHT have a definite inhibitory effect on pathological GFAP cellular expression and folding. Moreover, we confirm previous results of a similar beneficial effect of CLM. In addition, we have demonstrated that CBZ and CLM play a refolding effect on mutant GFAP proteins, likely ascribed at the induction of CRYAB expression, resulting in the decrease of mutant GFAP aggregates formation. As CBZ and PHT are currently approved for use in humans, their documented effects on pathological GFAP cellular expression and folding may indicate a potential therapeutic role as disease-modifying agents of these drugs in the clinical management of AxD, particularly in AxD patients with focal epilepsy with and without secondary generalization

    MiR-204 mediates post-transcriptional down-regulation of PHOX2B gene expression in neuroblastoma cells

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    Neuroblastoma (NB) is a rare childhood cancer of the peripheral sympathetic nervous system and accounts for approximately 10% of all pediatric tumors. Heterozygous PHOX2B mutations have been found in association with NB development in familial, sporadic and syndromic cases. In addition, the PHOX2B gene is widely over-expressed both in tumor samples and NB cell lines. Post-transcriptional gene regulation is known to be involved in mRNA stability and, in NB, microRNAs (miRNAs) seem to be responsible for altered expression of genes driving differentiation, apoptosis, and migration. To assess the possible impact of post-transcriptional regulation in NB cell lines, we have focused on the PHOX2B mRNA stability by both in silico analysis and functional studies on its 3\u2032untranslated region (3\u2032UTR). PHOX2B gene expression has resulted under post-transcriptional control, as suggested by: i) instability of PHOX2B mRNA, demonstrated by short mRNA half-life levels in both IMR32 and LAN-1 cell lines, ii) role of the PHOX2B-3\u2032UTR, confirmed by the activity of proper reporter constructs, and iii) miRNA-204, shown to enhance the PHOX2B 3\u2032UTR mediated down-regulation of the reporter construct activity. Finally, miRNA-204 has resulted to decrease the stability of the PHOX2B mRNA at different extents in the presence of different SNP rs1063611 alleles. Therefore, post-transcriptional down-regulation of the PHOX2B gene takes place in NB cell lines and miRNA-204 participates in such a 3\u2032UTR mediated control

    Identification of novel pathways and molecules able to down-regulate PHOX2B gene expression by in vitro drug screening approaches in neuroblastoma cells

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    PHOX2B is a transcription factor involved in the regulation of neurogenesis and in the correct differentiation of the autonomic nervous system. The pathogenetic role of PHOX2B in neuroblastoma (NB) is supported by mutations in familial, sporadic and syndromic cases of NB and overexpression of PHOX2B and its target ALK in tumor samples and NB cell lines. Starting from these observations, we have performed in vitro drug screening approaches targeting PHOX2B overexpression as a potential pharmacological means in NB. In particular, in order to identify molecules able to decrease PHOX2B expression, we have evaluated the effects of 70 compounds in IMR-32 cell line stably expressing the luciferase gene under the control of the PHOX2B promoter. Curcumin, SAHA and trichostatin A showed to down-regulate the PHOX2B promoter activity which resulted in a decrease of both protein and mRNA expressions. In addition, we have observed that curcumin acts by interfering with PBX-1/MEIS-1, NF-\u3baB and AP-1 complexes, in this work demonstrated for the first time to regulate the transcription of the PHOX2B gene. Finally, combined drug treatments showed successful effects in down-regulating the expression of both PHOX2B and its target ALK genes, thus supporting the notion of the effectiveness of molecule combination in tumor therapy

    The signaling lipid phosphatidylinositol-3,5-bisphosphate targets plant CLC-a anion/H+exchange activity

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    Phosphatidylinositol-3,5-bisphosphate (PI(3,5)P2) is a low-abundance signaling lipid associated with endo-lysosomal and vacuolar membranes in eukaryotic cells. Recent studies on Arabidopsis indicated a critical role of PI(3,5)P2in vacuolar acidification and morphology during ABA-induced stomatal closure, but the molecular targets in plant cells remained unknown. By using patch-clamp recordings on Arabidopsis vacuoles, we show here that PI(3,5)P2does not affect the activity of vacuolar H+-pyrophosphatase or vacuolar H+-ATPase. Instead, PI(3,5)P2at low nanomolar concentrations inhibited an inwardly rectifying conductance, which appeared upon vacuolar acidification elicited by prolonged H+pumping activity. We provide evidence that this novel conductance is mediated by chloride channel a (CLC-a), a member of the anion/H+exchanger family formerly implicated in stomatal movements in Arabidopsis. H+-dependent currents were absent in clc-a knock-out vacuoles, and canonical CLC-a-dependent nitrate/H+antiport was inhibited by low concentrations of PI(3,5)P2. Finally, using the pH indicator probe BCECF, we show that CLC-a inhibition contributes to vacuolar acidification. These data provide a mechanistic explanation for the essential role of PI(3,5)P2and advance our knowledge about the regulation of vacuolar ion transport

    Ceftriaxone has a therapeutic role in Alexander disease

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    Alexander disease (AD) (MIM 203450) is a rare, usually fatal neurodegenerative disorder, involving primarily astroglial cells in the CNS, caused by dominant mutations in the gene encoding glial fibrillary acidic protein (GFAP) (Brenner et al., 2001). It is characterized by dystrophic astrocytes containing intermediate filament aggregates (Rosenthal fibers) (RFs), in combination with myelin abnormalities (Li et al., 2005). Pathogenetic determinants include a toxic gain-of-function of mutated GFAP which causes aggregates and RFs accumulation in astrocytes and an excitotoxicity related to impairment of the buffering capacity of dystrophic astrocytes and of their ability to metabolize extracellular glutamate ([Mignot et al., 2004] and [Sullivan et al., 2007]). AD remains an untreatable genetic disease that severely limits life expectancy in affected individuals. Here we studied the tolerability and therapeutic effects of the chronic use of cycles of ceftriaxone, a beta-lactam antibiotic with neuroprotective effects (Rothstein et al., 2005), in a patient affected by adult AD with a rapidly progressive clinical course. Because AD is rare and its presentation varies it is difficult to evaluate treatments in controlled trials, thus prolonged, longitudinal single-patient studies may be a useful approach to identify the new utilization of drugs in this pathology. The successful clinical outcome related to ceftriaxone reported here in a patient with adult AD highlights the possibility that this ÎČ-lactam antibiotic may be useful for other AD patients and, possibly, for other neurodegenerative disorders with astrocyte involvement

    <i>In vitro</i> treatments with ceftriaxone promote elimination of mutant glial fibrillary acidic protein and transcription down-regulation

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    Alexander disease is a rare, untreatable and usually fatal neurodegenerative disorder caused by heterozygous mutations of the glial fibrillary acidic protein (GFAP) gene which ultimately lead to formation of aggregates, containing also αB-Crystallin, HSP27, ubiquitin and proteasome components. Recent findings indicate that up-regulation of αB-Crystallin in mice carrying GFAP mutations may temper the pathogenesis of the disease. Neuroprotective effects of ceftriaxone have been reported in various animal models and, noteworthy, we have recently shown that the chronic use of ceftriaxone in a patient affected by an adult form of Alexander disease could halt its progression and ameliorate some of the symptoms. Here we show that ceftriaxone is able to reduce the intracytoplasmic aggregates of mutant GFAP in a cellular model of Alexander disease. Underlying mechanisms include mutant GFAP elimination, concurrent with up-regulation of HSP27 and αB-Crystallin, polyubiquitination and autophagy. Ceftriaxone has also been shown to modulate the proteasome system, thus decreasing NF-ÎșB activation and GFAP promoter transcriptional regulation, which further accounts for the down-modulation of GFAP protein levels. These mechanisms provide previously unknown neuroprotective targets of ceftriaxone and confirm its potential therapeutic role in patients with Alexander disease and other neurodegenerative disorders with astrocyte involvement

    Common PHOX2B poly-alanine contractions impair RET gene transcription, predisposing to Hirschsprung disease

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    HSCR is a congenital disorder of the enteric nervous system, characterized by the absence of neurons along a variable length of the gut resulting from loss-of-function RET mutations. Congenital Central Hypoventilation Syndrome (CCHS) is a rare neurocristopathy characterized by impaired response to hypercapnia and hypoxemia caused by heterozygous mutations of the PHOX2B gene, mostly polyalanine (polyA) expansions but also missense, nonsense, and frameshift mutations, while polyA contractions are common in the population and believed neutral. HSCR associated CCHS can present in patients carrying PHOX2B mutations. Indeed, RET expression is orchestrated by different transcriptional factors among which PHOX2B, thus suggesting its possible role in HSCR pathogenesis. Following the observation of HSCR patients carrying in frame trinucleotide deletions within the polyalanine stretch in exon 3 (polyA contractions), we have verified the hypothesis that these PHOX2B variants do reduce its transcriptional activity, likely resulting in a down-regulation of RET expression and, consequently, favouring the development of the HSCR phenotype. Using proper reporter constructs, we show here that the in vitro transactivation of the RET promoter by different HSCR-associated PHOX2B polyA variants has resulted significantly lower compared to the effect of PHOX2B wild type protein. In particular, polyA contractions do induce a reduced transactivation of the RET promoter, milder compared to the severe polyA expansions associated with CCHS + HSCR, and correlated with the length of the deleted trait, with a more pronounced effect when contractions are larger
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