7A), corroborating our Western blot analysis indicating that the

7A), corroborating our Western blot analysis indicating that the neurotoxin failed to alter NF-L content. In addition, we did not detect significantly decreased immunofluorescence for NeuN ( Fig. 7B). Moreover,

Western blot analysis with anti-caspase 3 antibody showed that in (PhTe)2 treated striatal slices this key caspase is activated, indicating apoptotic cell death (Fig. 8A). In an attempt to determine signaling mechanisms involved in the neuronal damage we evaluated the PI3K/Akt signaling pathway. Western blot analysis using anti-Akt antibody showed decreased see more phosphoAkt immunoreactivity (Fig. 8B) in (PhTe)2 treated slices, which is compatible with down-regulated survival mechanisms in the striatum of treated animals (Zhao et al., 2006). Also, it was evaluated the GSK-3-β activity, since it is described as a kinase that can be modulated PD-L1 mutation by Akt activity (Zhao et al., 2006). We found that phosphoGSK-3-β (Ser9) was not altered in the striatum of (PhTe)2 injected rats, suggesting that this kinase is not directly implicated in the neurotoxicity of this compound (Fig. 8C). Fig. 8D depicts the representative immunological reaction of active caspase 3, Akt and phosphoAkt. We have previously demonstrated that young rats (15 day-old) acutely injected with (PhTe)2 at 0.3 μmol/kg of body weight

presented weight loss from day 2 up to day 6 after drug exposure, indicating systemic toxicity at this concentration (Heimfarth et al., 2008). In the present study we attempted to further investigate the mechanisms underlying neurotoxicity of (PhTe)2 in acutely injected 15 day-old rats. We have chosen the striatum, since it is well known that, in rodents, neurotoxins produce a number of neurochemical changes in striatal glial and neuronal cells (Pierozan et al., 2012). Therefore, elucidation of the biochemical steps leading to (PhTe)2-induced neurotoxicity provide us new

clues to the mechanisms underlying the actions of this neurotoxin in brain. these Hyperphosphorylated IF proteins NF-L, NF-M and NF-H from neurons as well as GFAP and vimentin from rat astrocytes reflect an altered activity of the phosphorylating system associated with the IF proteins in this cerebral structure. Despite the physiological role of NF phosphorylation is to date not completely clear, phosphorylation of amino-terminal domain of NF-L and other IF subunits has been related to their association into filamentous structures (for review see Sihag et al., 2007), while in vitro phosphorylation of carboxyl-terminal domains of NF-H and NF-M straightens individual NFs and promotes their alignment into bundles ( Leterrier et al., 1996). Otherwise, the in vivo phosphorylation of these proteins is associated with an increased interNF spacing ( Hsieh et al., 1994). As a consequence, NF-H and NF-M carboxyl-terminal side arms extend and form cross-bridges among NF and other cytoskeletal elements ( Gotow et al., 1994).

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