Xhibit significant deficits in sciatic nerve conduction velocity, increases in latencies and alterations in myelin morphology [2]. b) Sod12/2 mice (on a C57BL/6 background) were used as a model of in vivo oxidative stress as described previously (protocol, 08080z and 0503-002) [25,50]. 6month-old Sod12/2 and their wild-type (WT) littermates were used for the biochemical studies. 6-month- and 20-month- Sod12/2 and their WT littermates were used for morphological assessments.Protein Oxidation, Misfolding and DemyelinationNerve Conduction Velocity and latencyMice were anesthetized with isofluorane and maintained at 34uC with a heating lamp. All experiments were performed with a Nicolet Viking Quest portable EMG apparatus (CareFusion, San Diego, CA, USA) as described previously [51]. Subdermal needle electrodes were MedChemExpress CB5083 cleaned with 70 alcohol between animals. Supramaximal stimulation was delivered with 0.02 millisecond electrical impulses for all experiments. Electrodes were inserted 3 cm apart and the latency of the tail distal motor action potential was measured by proximal to distal stimulation. Sciatic NCV was measured by stimulating proximal ankle electrodes with current and the latency for response at the dorsal digits divided by the distance traveled was measured. Then the stimulating electrodes were placed at the sciatic 16985061 notch and the latency to the ankle was measured, subtracted from the initial foot ankle latency and divided by the notch to the ankle to obtain values for sciatic NCV.Measurement of protein surface hydrophobicitySciatic nerves were homogenized in 50 mM tris buffer, pH 7.4, followed by photo-labeling the protein surface hydrophobic domain with BisANS (0.1 mM) under UV light-exposure as previously described [36,41]. Thereafter, equal amounts of BisANS-labeled proteins were loaded onto SDS-PAGE and visualized on an Alpha Innotech FluorChem HD2 camera utilizing UV transillumination. The level of incorporation of BisANS was measured as described in protein carbonyls and normalized to Coomassie protein stain [36,41].Determination of hydrophobicity based on primary sequencePrimary sequence for PMP22 was obtained from known sequences on Pubmed protein search for mouse and analyzed for hydrophobicity utilizing Kyte-Doolittle hydropathy plots as described previously [53].Thick sections and imagingA 1-2 cm segment of sciatic nerve at the sciatic notch for all sectioning was fixed in 4 paraformaldehyde (PFA) and was switched to buffer RE 640 price containing PBS with 4 PFA and 1 glutaraldehyde in 0.1 M sodium cacodylate buffer, post-fixed in 1 osmium tetraoxide and finally in 1 uranyl acetate. Sections were cut at 1? mM in thickness and then stained with the following solution of toluidine blue (1 g of toluidine blue, 1 g of borax and 100 mL of water). Using a 0.2 ml filtered syringe filled with prepared toluidine dye 1 drop was applied to thick sections. Slides were placed at 180 degrees on a hot plate for 10 seconds. Samples were washed with water and allowed to dry and then covered with cover slips. Sectioning of sciatic nerves was performed by the UTHSCSA electron microscopy core (San Antonio, TX) and visualized using Nikon Eclipse TE2000-U fluorescence microscope (Nikon Inc.) at 40- and 100X magnification. Axon and fiber diameters/areas were quantified utilizing Roper Scientific software and analyzed as described earlier [2,52]. The approximate circumference was quantified to determine the area and diameter of both axons and axon pl.Xhibit significant deficits in sciatic nerve conduction velocity, increases in latencies and alterations in myelin morphology [2]. b) Sod12/2 mice (on a C57BL/6 background) were used as a model of in vivo oxidative stress as described previously (protocol, 08080z and 0503-002) [25,50]. 6month-old Sod12/2 and their wild-type (WT) littermates were used for the biochemical studies. 6-month- and 20-month- Sod12/2 and their WT littermates were used for morphological assessments.Protein Oxidation, Misfolding and DemyelinationNerve Conduction Velocity and latencyMice were anesthetized with isofluorane and maintained at 34uC with a heating lamp. All experiments were performed with a Nicolet Viking Quest portable EMG apparatus (CareFusion, San Diego, CA, USA) as described previously [51]. Subdermal needle electrodes were cleaned with 70 alcohol between animals. Supramaximal stimulation was delivered with 0.02 millisecond electrical impulses for all experiments. Electrodes were inserted 3 cm apart and the latency of the tail distal motor action potential was measured by proximal to distal stimulation. Sciatic NCV was measured by stimulating proximal ankle electrodes with current and the latency for response at the dorsal digits divided by the distance traveled was measured. Then the stimulating electrodes were placed at the sciatic 16985061 notch and the latency to the ankle was measured, subtracted from the initial foot ankle latency and divided by the notch to the ankle to obtain values for sciatic NCV.Measurement of protein surface hydrophobicitySciatic nerves were homogenized in 50 mM tris buffer, pH 7.4, followed by photo-labeling the protein surface hydrophobic domain with BisANS (0.1 mM) under UV light-exposure as previously described [36,41]. Thereafter, equal amounts of BisANS-labeled proteins were loaded onto SDS-PAGE and visualized on an Alpha Innotech FluorChem HD2 camera utilizing UV transillumination. The level of incorporation of BisANS was measured as described in protein carbonyls and normalized to Coomassie protein stain [36,41].Determination of hydrophobicity based on primary sequencePrimary sequence for PMP22 was obtained from known sequences on Pubmed protein search for mouse and analyzed for hydrophobicity utilizing Kyte-Doolittle hydropathy plots as described previously [53].Thick sections and imagingA 1-2 cm segment of sciatic nerve at the sciatic notch for all sectioning was fixed in 4 paraformaldehyde (PFA) and was switched to buffer containing PBS with 4 PFA and 1 glutaraldehyde in 0.1 M sodium cacodylate buffer, post-fixed in 1 osmium tetraoxide and finally in 1 uranyl acetate. Sections were cut at 1? mM in thickness and then stained with the following solution of toluidine blue (1 g of toluidine blue, 1 g of borax and 100 mL of water). Using a 0.2 ml filtered syringe filled with prepared toluidine dye 1 drop was applied to thick sections. Slides were placed at 180 degrees on a hot plate for 10 seconds. Samples were washed with water and allowed to dry and then covered with cover slips. Sectioning of sciatic nerves was performed by the UTHSCSA electron microscopy core (San Antonio, TX) and visualized using Nikon Eclipse TE2000-U fluorescence microscope (Nikon Inc.) at 40- and 100X magnification. Axon and fiber diameters/areas were quantified utilizing Roper Scientific software and analyzed as described earlier [2,52]. The approximate circumference was quantified to determine the area and diameter of both axons and axon pl.