Oxidative stress plays an important role in neuronal cell death associated with many different neurodegenerative conditions such as cerebral ischemia and Parkinson's disease. Elevated levels of glutamate are thought to be responsible for CNS disorders through various mechanisms causing oxidative stress induced by a nonreceptor-mediated oxidative pathway which blocks cystine uptake and results in depletion of intracellular glutathione (GSH). The newly designed amide form of N-acetylcysteine (NAC), N-acetylcysteine amide (NACA), was assessed for its ability to protect PC12 cells against oxidative toxicity induced by glutamate. NACA was shown to protect PC12 cells from glutamate (Glu) toxicity, as evaluated by LDH and MTS assays. NACA prevented glutamate-induced intracellular GSH loss. In addition, NACA restored GSH synthesis in a Glu (10 mM) plus buthionine -sulfoximine (BSO) (0.2 mM)-treated group, indicating that the intracellular GSH increase is independent of g-GSC (g-glutamylcysteinyl synthetase). The increase in levels of reactive oxygen species (ROS) induced by glutamate was significantly decreased by NACA. Measurement of malondialdehyde (MDA) showed that NACA reduced glutamate-induced elevations in levels of lipid peroxidation by-products. These results demonstrate that NACA can protect PC12 cells against glutamate cytotoxicity by inhibiting lipid peroxidation, and scavenging ROS, thus preserving intracellular GSH. D
To control the rate of release of methylprednisolone (MP) in lysosomes, new dextran-MP conjugates with peptide linkers were synthesized and characterized. Methylprednisolone succinate (MPS) was attached to dextran 25 kDa using linkers with 1-5 Gly residues. The release characteristics of the conjugates in pH 4.0 and 7.4 buffers, blood, liver lysosomes, and various lysosomal proteinases were determined using a size-exclusion and/or a newly-developed reversed-phase HPLC method capable of simultaneous quantitation of MP, MPS, and all five possible MPS-peptidyl intermediates. We synthesized conjugates with ≥ 90% purity and 6.9-9.5% (w/w) degree of MP substitution. The conjugates were stable at pH 4.0, but released MP and intact MPS-peptidyl intermediates in the pH 7.4 buffer and rat blood, with faster degradation rates for longer linkers. Rat lysosomal fractions degraded the conjugates to MP and all the possible intermediates also at a rate directly proportional to the length of the peptide. Whereas the degradation of the conjugates by cysteine peptidases (papain or cathepsin B) was relatively substantial, no degradation was observed in the presence of aspartic (cathepsin D) or serine (trypsin) proteinases, which do not cleave peptide bonds with Gly. These newly-developed dextran conjugates of MP show promise for controlled delivery of MP in lysosomes.
Recent studies indicate that there is interaction between the glutamatergic neurotransmitters system and lead neurotoxicity. Previously, we have demonstrated the potential effects of glutamate in lead-induced cell death in PC12 cells and the protective role of the novel thiol antioxidant, N-acetylcysteine amide (NACA). The current study 1) investigated the potential effects of glutamate on lead exposed CD-1 mice and 2) evaluated the protective effects of NACA against glutamate and lead toxicity in CD-1 mice, and 3) compared the results with Naceytylcysteine (a well-known thiol antioxidant). Oxidative stress parameters, including glutathione (GSH), oxidized glutathione (GSSG), GSH/GSSG, and malondialdehyde (MDA) levels, were evaluated. Blood and tissue lead levels, glutamate/glutamine (Glu/Gln) ratios, GS activity, and phospholipase-A 2 (PLA 2 ) were also analyzed. Results indicated that lead and glutamate decreased GSH levels in the red blood cells, brains, livers, and kidneys. Exposure to glutamate and lead elevated the MDA levels and PLA 2 activity. NACA and NAC provided protection against the detrimental effects of lead by decreasing the blood and tissue lead levels, restoring intracellular GSH levels, and decreasing the MDA levels. NACA and NAC also increased the GS activity thereby decreasing Glu/Gln levels. However, NACA appeared to have better chelating and antioxidant properties than NAC, due to its higher liphophilicity and its ability to cross the blood-brain barrier.
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