Identification of non-essential host genes required for PrP106-126 mediated neurotoxicity

Stobart, Michael

31 August 2011

Prion diseases are invariably fatal proteinaceous neurodegenerative disorders of the central nervous system. The infectious agent is the host encoded prion protein which has undergone a post-translational refolding from a predominantly alpha-helical to highly beta-sheet containing structure. The mechanism of prion-induced neurotoxicity remains elusive in large part due to the absence of a sufficiently neurotoxic cell culture assay. A modern technique for identifying previously unrecognized mediators of a biological pathway is to screen a commercially available library of gene silencing molecules targeting all known open reading frames. Synthetic gene silencing molecules, such as short hairpin RNA (shRNA), employ the endogenous gene silencing pathway to inhibit protein synthesis. To date, no publication has described the implementation of a large-scale library to screen for genetic mediators of prion neurotoxicity. This project was aimed at developing a cell culture model of acute prion neurotoxicity and screening a library of shRNA molecules in order to identify previously unrecognized gene targets essential to prion-induced neurotoxicity. Using a fragment of the prion protein (PrP106-126 peptide) to mimic prion neurotoxicity, human neuroblastoma cells transduced with a retroviral shRNA library were screened for resistance. Involvement of a subset of library identified gene targets in prion disease was assessed in vivo by quantitative real-time PCR (qPCR) analysis. Validation of the protection conferred by reducing expression of a gene target of interest was accomplished using individual lentiviral vectors expressing shRNA. Of the approximately 54,000 shRNA sequences screened, 80 different shRNA sequences recovered from neurotoxic prion peptide-resistant cells were considered to be of interest. Of these, 49 corresponding gene targets were assessed in vivo by qPCR with the majority demonstrating significant differential expression in brains of prion infected mice. Validation of the protection conferred from knockdown of two identified genes, abcb4 and ube2cbp, was completed. Knockdown of either gene imparted significant protection against prion-induced neurotoxicity, with qPCR analysis confirming significantly reduced mRNA transcript levels. Overall, the validity of the novel assay system developed has been demonstrated, and the first comprehensive list of gene candidates involved in mediating acute prion neurotoxicity has been determined.

prions

RNAi

neurotoxicity

screen

Identification of non-essential host genes required for PrP106-126 mediated neurotoxicity

Stobart, Michael

31 August 2011

Prion diseases are invariably fatal proteinaceous neurodegenerative disorders of the central nervous system. The infectious agent is the host encoded prion protein which has undergone a post-translational refolding from a predominantly alpha-helical to highly beta-sheet containing structure. The mechanism of prion-induced neurotoxicity remains elusive in large part due to the absence of a sufficiently neurotoxic cell culture assay. A modern technique for identifying previously unrecognized mediators of a biological pathway is to screen a commercially available library of gene silencing molecules targeting all known open reading frames. Synthetic gene silencing molecules, such as short hairpin RNA (shRNA), employ the endogenous gene silencing pathway to inhibit protein synthesis. To date, no publication has described the implementation of a large-scale library to screen for genetic mediators of prion neurotoxicity. This project was aimed at developing a cell culture model of acute prion neurotoxicity and screening a library of shRNA molecules in order to identify previously unrecognized gene targets essential to prion-induced neurotoxicity. Using a fragment of the prion protein (PrP106-126 peptide) to mimic prion neurotoxicity, human neuroblastoma cells transduced with a retroviral shRNA library were screened for resistance. Involvement of a subset of library identified gene targets in prion disease was assessed in vivo by quantitative real-time PCR (qPCR) analysis. Validation of the protection conferred by reducing expression of a gene target of interest was accomplished using individual lentiviral vectors expressing shRNA. Of the approximately 54,000 shRNA sequences screened, 80 different shRNA sequences recovered from neurotoxic prion peptide-resistant cells were considered to be of interest. Of these, 49 corresponding gene targets were assessed in vivo by qPCR with the majority demonstrating significant differential expression in brains of prion infected mice. Validation of the protection conferred from knockdown of two identified genes, abcb4 and ube2cbp, was completed. Knockdown of either gene imparted significant protection against prion-induced neurotoxicity, with qPCR analysis confirming significantly reduced mRNA transcript levels. Overall, the validity of the novel assay system developed has been demonstrated, and the first comprehensive list of gene candidates involved in mediating acute prion neurotoxicity has been determined.

prions

RNAi

neurotoxicity

screen

The Murine Brain Slice as a Model for Investigation of Environmental Toxin Involvement in the Etiology of Parkinson's Disease

Freeborn, Ethan Ray

13 August 1999

Epidemiological and analytical studies have suggested that environmental exposure to neurotoxic insecticides may exist as a factor in the etiology of Parkinson's Disease (PD). This study has focused on two insecticides, dieldrin and heptachlor epoxide, members of the cyclodiene class of insecticides. The cyclodienes are environmentally persistent, and brain residues of these compounds are correlated with the occurrence of PD. Cyclodiene mode of action has been attributed to two mechanisms: 1) facilitation of neurotransmitter release (with specificity for release of dopamine) and 2) antagonism of the inhibitory neurotransmitter, GABA. In order to assess the relative contributions of these two mechanisms leading to toxicity, eletrophysiological studies were undertaken in murine striatal slices. Extracellular recordings of spontaneous nerve discharge were used to compare the effects of the cyclodienes and the prototypical GABA antagonist, picrotoxinin, upon striatal neurons. At low micromolar concentrations of cyclodiene, depression of firing, consistent with dopamine release and not GABA antagonism, was seen. Alternatively, application of the prototypical GABA antagonist, picrotoxinin, produced excitation in slices. Additionally, the inhibitory action of dieldrin was blocked by a dopamine receptor (D1) antagonist, fluphenazine, verifying that cyclodiene-released dopamine was responsible for the observed depression of striatal neurons. These results suggest that the ability of these cyclodienes to evoke neurotransmitter release may significantly contribute to the neurotoxicity of these cyclodienes in vivo. In light of this data, the neurotoxic potential of the cyclodiene insecticides must be reassessed, particularly within the scope of PD. / Master of Science

stiatum

insecticides

neurotoxicity

Efeitos da administração subaracnóidea de cetamina S(+), sem conservantes, sobre a medula espinhal e as meninges: estudo experimental no cão

Rojas, Alfredo Cury [UNESP]

27 February 2008

Made available in DSpace on 2014-06-11T19:29:05Z (GMT). No. of bitstreams: 0 Previous issue date: 2008-02-27Bitstream added on 2014-06-13T18:58:30Z : No. of bitstreams: 1 rojas_ac_me_botfm.pdf: 611857 bytes, checksum: 6da0fa6f131c9d3fbd13811bf4e64573 (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Clicar acesso eletrônico abaixo. / Click electronic access below.

Anestesiologia

Meninges

Medula espinhal

Neurotoxicity

The Contribution of Ammonia to Methamphetamine Neurotoxicity

Halpin, Laura E.

20 August 2013

No description available.

Neurosciences

Methamphetamine

ammonia

neurotoxicity

liver

MDMA and Glutamate: Implications for Hippocampal GABAergic Neurotoxicity

Huff, Courtney L., M.S.

02 June 2016

No description available.

Pharmaceuticals

MDMA

GABA

Neurotoxicity

Hippocampus

The Role of Metabolism in Ecstasy-Mediated Serotonergic Neurotoxicity

Erives Quezada, Gladys Vanessa

January 2009

3,4-(±)-Methylenedioxymethamphetamine (MDMA) is a synthetic amphetamine derivative commonly used as a recreational drug. Although the selectivity of MDMA for the serotonergic system in rat and humans is well established, the specific mechanism associated with MDMA-induced neurotoxicity is not fully understood. The long-term neurotoxicity of MDMA appears to be dependent upon systemic metabolism since direct administration of MDMA into the brain fails to reproduce the neurotoxic effects seen following peripheral administration, indicating that the parent compound alone is unlikely to be responsible for the neurotoxicity. MDMA is O-demethylenated to the catechol metabolite N-methyl-α-methyldopamine (N-Me-α-MeDA) and N-demethylated to MDA by cytochrome (s) P450 (CYP450). Thioether (glutathione and N-acetylcysteine) metabolites of N-Me-α-MeDA and α-MeDA are neurotoxic and can be found in rat brain following s.c. injection of MDMA. Because multidose administration of MDMA is typical of drug intake during rave parties, we investigated the effects of multiple doses of MDMA on the concentration of neurotoxic thioether metabolites in rat brain. Administration of MDMA at 12-h intervals for a total of four injections led to a significant accumulation of the N-Me-α-MeDA thioether metabolites in striatal dialysate. In contrast, acute release of 5-HT concentrations was decreased. Since isoenzymes of the CYP2D subfamily (30% metabolism), and the CYP2B or CYP3A1 isoforms, catalyze the low and high KM O-demethylenation reactions, respectively, we subsequently examined the potential role of CYP2D1 in both a genetic and pharmacological model. The data is consistent with the hypothesis that systemic metabolism of MDMA contributes to MDMA-induced serotonergic neurotoxicity via the 20) generation of reactive metabolites. In both the genetic and pharmacological models of CYP2D1 deficiency, attenuation of MDMA-mediated decreases in brain 5-HT concentrations were in the same range (30-40%). Finally, we examined the contribution of various transporters using genetic and pharmacological models to investigate the mechanisms regulating the concentration of thioether metabolites in MDMA neurotoxicity. The data suggest that by regulating various transporters and brain concentrations of the neurotoxic thioether metabolites of MDMA, may subsequently modulate the degree of neurotoxicity. However, further studies are necessary to understand the precise mechanism by which Mrp’s and Oat1 transporters modulate MDMA-neurotoxicity. Taken together, these studies are consistent with the view that neurotoxicity of MDMA requires systemic metabolism to form α-MeDA and N-Me-α- MeDA by CYP2D6. Therefore, It is likely that neurotoxicity is mediated by the formation of systemic neurotoxic metabolites.

MDMA

metabolism

neurotoxicity

rat

serotonin

thioether metabolites

HIV AND OPIATES-MEDIATED NEUROTOXICITY: GSK3β IS A POTENTIAL THERAPEUTIC TARGET

Masvekar, Ruturaj

01 January 2014

HIV-1 enters the CNS soon after initial systemic infection. HIV-1 can induce a wide range of neurological deficits, collectively known as HIV-1-associated neurocognitive disorders (HAND). Mature neurons are not infected by HIV-1; instead, infected and/or activated glial cells release various viral and cellular factors that induce direct and/or indirect neuronal toxicity, leading to HAND. Injection drug abuse is a significant risk factor for HIV-infection, and opiate drug abusers show increased HIV-neuropathology, even with anti-retroviral treatments. Our previous work has largely modeled HIV-neuropathology using the individual viral proteins Tat or gp120, with murine striatal neurons as targets. To model disease processes more closely, the current study uses supernatant from HIV-1-infected cells. Supernatant from HIV-1SF162 (R5-tropic)-infected differentiated-U937 cells (HIV+sup) was collected and p24 level was measured by ELISA to assess the infection. We assessed HIV+sup effects on neuronal survival and neurite growth/pruning with or without concurrent exposure to morphine, an opiate that preferentially acts through µ-opioid receptors. Effects of HIV+sup ± morphine were assessed on neuronal populations, and also by time-lapse imaging of individual cells. HIV+sup caused dose-dependent toxicity over a range of p24 levels (10-500 pg/ml). Significant interactions occurred with morphine at lower p24 levels (10 and 25 pg/ml). In the presence of glia, selective neurotoxic measures were significantly enhanced and interactions with morphine were also augmented. Importantly, the arrest of neurite growth that occurred with exposure to HIV+sup was reversible unless neurons were continuously exposed to morphine. Thus, while reducing HIV-infection levels may be protective, ongoing exposure to opiates may limit recovery. During early stage of HIV-infection R5-tropic viruses are predominant, but during later stages of disease X4-tropic viruses are more predominant; co-receptor usage switch from CCR5 to CXCR4 is crucial in disease progression to AIDS. Some previous studies have shown that drugs of abuse interact with virus or viral proteins in strain/tropism-dependent manner. Therefore, we also assessed neurotoxic effects and interactions with opiates by supernatant from HIV-1LAI (X4-tropic)-infected H9 cells. Neurotoxic effects and the interactions with opiates of HIV-1LAI-supernatant are quantitatively similar to that of HIV-1SF162. Surprisingly, the cytokine/chemokine release profile of HIV-1LAI-infected H9 cells is similar to that of HIV-1SF162-infected U937 cells. Only in the presence of glia, HIV-1LAI virion induced neurotoxic effects, but no interactions with morphine were seen. Also our studies have shown that HIV-1LAI virions are slightly more neurotoxic than HIV-1SF162. Altogether, largely our results suggest that HIV+sup mediated neurotoxicity and the interactions with opiates are majorly attributed to cytotoxic factors released from infected and activated cells instead of viral strain specific factors. Although there is a correlation between opiate drug abuse and progression of HAND, the mechanisms that underlie interactions between HIV-1 and opiates remain obscure. Previous studies have shown that HIV-1 induces neurotoxic effects through abnormal activation of GSK3β. Interestingly, expression of GSK3β has shown to be elevated in the brains of young opiate abusers suggesting that GSK3β is also linked to neuropathology seen with opiate abusing patients. Thus, we hypothesized that GSK3β activation is a point of convergence for HIV- and opiate-mediated interactive neurotoxic effects. Cultures of striatal neurons were treated with HIV+sup (R5-tropic), in the presence or absence of morphine and GSK3β inhibitors. Our results show that multiple GSK3β inhibitors significantly reduce HIV-1-mediated neurotoxic outcomes, and also negate interactions with morphine that result in cell death. This suggests that GSK3β-activation is an important point of convergence and a potential therapeutic target for HIV- and opiate-mediated neurocognitive deficits.

Neurotoxicity

HIV

Opiates

GSK3Beta

Medicine and Health Sciences

Evaluation of neurotoxic properties of gliotoxin

Axelsson, Viktoria

January 2006

The occurrence of mould in food and animal feed is a severe problem due to the secondary metabolites, called mycotoxins, which can possess toxic activity. Aspergillus fumigatus is a common fungus found in improperly stored animal feed and the abundance of spores of the fungus is frequently spread into the air. Gliotoxin has been identified as one of the most toxic second metabolites produced by A. fumigatus. Although A. fumigatus is known to produce mycotoxins that induce neurological syndromes, the neurotoxic properties of gliotoxin have not previously been studied. In this thesis a neurotoxic activity of gliotoxin was demonstrated by using differentiated human neuroblastoma SH-SY5Y cells as a surrogate for the nervous system. The major findings were as follows: i. Gliotoxin is highly toxic to SH-SY5Y cells and there is a correlation between the toxicity and the cellular redox status. ii. Gliotoxin reduces the number of neurites, but does not affect the cell bodies morphologically, at non-cytotoxic concentrations. This indicates that the toxin may induce peripheral axonopathy in vivo. iii. The intracellular free Ca2+ concentration is increased after exposure to gliotoxin, an effect that is the most ubiquitous feature of neuronal cell death. Simultaneously, calpains and caspases, proteases known to be involved in neuronal death and axonal degeneration, are activated. iv. The observed irreversible neurite degenerative effects of gliotoxin are mainly dependent on caspase activation, whereas calpains are involved in the gliotoxin-induced cytotoxicity. v. Gliotoxin induces a decreased rate of protein synthesis at non-cytotoxic concentration, which may contribute to the degeneration of neurites. vi. We did also succeed in developing an in vitro method for determination of toxic activity in animal feed. This study was done in collaboration with National Veterinary Institute (SVA) in Uppsala, and the method is today established and in use at Department of Animal Feed, SVA.

mycotoxin

gliotoxin

A. fumigatus

cytotoxicity

neurotoxicity

Neurochemistry

Neurokemi

Efeitos da administração subaracnóidea de cetamina S(+), sem conservantes, sobre a medula espinhal e as meninges: estudo experimental no cão /

Rojas, Alfredo Cury.

January 2008

Orientador: Eliana Marisa Ganem / Banca: Guilherme Antonio Moreira de Barros / Banca: Simone Maria D'Angelo Vanni / Resumo: Clicar acesso eletrônico abaixo. / Abstract: Click electronic access below. / Mestre

Anestesiologia.

Meninges.

Medula espinhal.

Neurotoxicity. eng