For keeping the lens transparent [9,33]. This may explain the rapid cataract rate of LEGSKO mice at 9mos, since nuclear GSH is in much lower level i.e. 0.5 mM). In addition, ascorbic acid oxidation may play a key role in crystallin damage in the human lens nucleus when the GSH level drops below a certain threshold. In contrast, the mouse lens has barely detectable ascorbic acid [12]. Furthermore, we found elevated oxidation in the cortical region of LEGSKO lenses compared to wild type lenses, but we did not observe opacity in cortex at 9mos of LEGSKO mice. Thus it remains to be seen if 25033180 cortical cataract will also form with age. Another important function of GSH is the detoxification of the oxoaldehydes glyoxal and methylglyoxal, the latter being one of the most important sources of protein damage in aging andGenotypeAge (wks)GSH (mmole/g wet weight) Cortical Nucleus 3.0760.21 1.4660.10 2.6560.39 0.4760.10 N.DGSSG(mmole/g wet weight) Cortical 0.03160.005 0.02760.004 0.0360.007 0.2260.003 0.2160.005 Nucleus 0.0360.006 0.02260.003 0.03260.003 0.1160.001 N.DWT LEGSKO WT LEGSKO LEGSKO Cataract4 4 36 363.2360.23 1.6260.18 3.0860.33 0.9760.29 0.8960.N.D. : not detectable. doi:10.1371/journal.pone.0050832.tAge-Related Nuclear Cataract Animal ModelFigure 2. Quantitative comparison of mean levels 6 SD for protein modification by glycation at 9 mos old of WT and HomoLEGSKO mice lenses. Carboxymethyl-lysine (CML), carboxyethyl-lysine (CEL), methylglyoxal hydroimidazolone-1 (MG-H1), and glyoxal hydroimidazolone-1 (G-H1) were determined by LC/MS. No significant (n.s) change was observed between WT and LEGSKO lenses. Student’s t test was used for data analysis. doi:10.1371/journal.pone.0050832.gcataractous lenses [12,13,34]. For this reason we expected to find increased levels of carboxymethyl-lysine (CML), carboxyethyllysine (CEL) and MG-H1 hydroimidazolone. At first we were surprised that none of these Terlipressin modifications were increased. This may mean there was enough residual glutathione as cofactor of glyoxylase I for the detoxification of these AGE precursors. However, the most likely explanation is that AGE levels are very low because vitamin C is absent in normal and LEGSKO mouse lens (both are ,100 mM), except in the hSVCT2 transgenic mouse [12]. Indeed previous data from our and other laboratories have unequivocally established ascorbic acid as a major source of these AGEs in the aging lens [12,35,36]. Breeding experiments between the LEGSKO mouse and the hSVCT2 mouse will confirm the extent to which the GSH/glyoxalase system is important for MedChemExpress Met-Enkephalin protection against ascorbic acid derived AGEs. Similarly, exposure of the hSVCT2, LEGSKO and hSVCT2xLEGSKO F1 mouse to UV/VIS light is expected to provide important in vivo information on the role of GSH for protection against photoxidative damage and formation of photosensitizers resulting from tryptophan oxidation. In summary, lens-specific suppression of GSH synthesis in the LEGSKO mouse, while maintaining all other metabolic body functions intact, resulted in biochemical, biological and cataractous changes mimicking those of age-related human nuclear cataracts. Thus, the LEGSKO mouse is expected to be a useful tool for the development of pharmacological agents that can either restore the antioxidant reserve of the lens or block the distal effects of oxidant stress resulting from GSH deficiency.6J blastocysts was done at the University of Michigan Transgenic Facility, and resulting chimeric male mice were.For keeping the lens transparent [9,33]. This may explain the rapid cataract rate of LEGSKO mice at 9mos, since nuclear GSH is in much lower level i.e. 0.5 mM). In addition, ascorbic acid oxidation may play a key role in crystallin damage in the human lens nucleus when the GSH level drops below a certain threshold. In contrast, the mouse lens has barely detectable ascorbic acid [12]. Furthermore, we found elevated oxidation in the cortical region of LEGSKO lenses compared to wild type lenses, but we did not observe opacity in cortex at 9mos of LEGSKO mice. Thus it remains to be seen if 25033180 cortical cataract will also form with age. Another important function of GSH is the detoxification of the oxoaldehydes glyoxal and methylglyoxal, the latter being one of the most important sources of protein damage in aging andGenotypeAge (wks)GSH (mmole/g wet weight) Cortical Nucleus 3.0760.21 1.4660.10 2.6560.39 0.4760.10 N.DGSSG(mmole/g wet weight) Cortical 0.03160.005 0.02760.004 0.0360.007 0.2260.003 0.2160.005 Nucleus 0.0360.006 0.02260.003 0.03260.003 0.1160.001 N.DWT LEGSKO WT LEGSKO LEGSKO Cataract4 4 36 363.2360.23 1.6260.18 3.0860.33 0.9760.29 0.8960.N.D. : not detectable. doi:10.1371/journal.pone.0050832.tAge-Related Nuclear Cataract Animal ModelFigure 2. Quantitative comparison of mean levels 6 SD for protein modification by glycation at 9 mos old of WT and HomoLEGSKO mice lenses. Carboxymethyl-lysine (CML), carboxyethyl-lysine (CEL), methylglyoxal hydroimidazolone-1 (MG-H1), and glyoxal hydroimidazolone-1 (G-H1) were determined by LC/MS. No significant (n.s) change was observed between WT and LEGSKO lenses. Student’s t test was used for data analysis. doi:10.1371/journal.pone.0050832.gcataractous lenses [12,13,34]. For this reason we expected to find increased levels of carboxymethyl-lysine (CML), carboxyethyllysine (CEL) and MG-H1 hydroimidazolone. At first we were surprised that none of these modifications were increased. This may mean there was enough residual glutathione as cofactor of glyoxylase I for the detoxification of these AGE precursors. However, the most likely explanation is that AGE levels are very low because vitamin C is absent in normal and LEGSKO mouse lens (both are ,100 mM), except in the hSVCT2 transgenic mouse [12]. Indeed previous data from our and other laboratories have unequivocally established ascorbic acid as a major source of these AGEs in the aging lens [12,35,36]. Breeding experiments between the LEGSKO mouse and the hSVCT2 mouse will confirm the extent to which the GSH/glyoxalase system is important for protection against ascorbic acid derived AGEs. Similarly, exposure of the hSVCT2, LEGSKO and hSVCT2xLEGSKO F1 mouse to UV/VIS light is expected to provide important in vivo information on the role of GSH for protection against photoxidative damage and formation of photosensitizers resulting from tryptophan oxidation. In summary, lens-specific suppression of GSH synthesis in the LEGSKO mouse, while maintaining all other metabolic body functions intact, resulted in biochemical, biological and cataractous changes mimicking those of age-related human nuclear cataracts. Thus, the LEGSKO mouse is expected to be a useful tool for the development of pharmacological agents that can either restore the antioxidant reserve of the lens or block the distal effects of oxidant stress resulting from GSH deficiency.6J blastocysts was done at the University of Michigan Transgenic Facility, and resulting chimeric male mice were.
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