Dopamine Neurons from Transgenic Mice with a Knockout of the p53 Gene Resist MPTP Neurotoxicity

Patricia A. Trimmer , Trisha S. Smith , Anthony B. Jung , James P. Bennett
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引用次数: 132

Abstract

We have examined MPTP toxicity to dopamine neurons of mice homozygous for a transgenic knockout of the p53 growth control gene (p53−/−). MPTP at a total dose of 96 mg/kg administered in four doses over two days produced a non-homogeneous loss of striatal dopamine transport sites and quantitatively reduced 3H–mazindol binding to similar degrees in p53−/−and wild type controls 2 and 3 weeks after starting MPTP. Nigral DA neurons stained immunohistochemically for tyrosine hydroxylase were counted using both manual and automated methods and found to be reduced 29—34% in wild type controls but were not reduced in p53−/−. Mean DA neuronal surface areas were reduced 63—68% by MPTP in controls and 35—50% in p53−/−. We conclude that p53 protein appears necessary for complete expression of MPTP neurotoxicity to dopamine neurons. Our findings suggest that the p53 gene and other growth control genes may regulate dopamine neuronal death in PD.

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敲除p53基因的转基因小鼠多巴胺神经元抵抗MPTP神经毒性
我们研究了MPTP对纯合子小鼠多巴胺神经元的毒性,以转基因敲除p53生长控制基因(p53 - / -)。MPTP总剂量为96 mg/kg,分4次给药,持续2天,在p53 - / -和野生型对照中,纹状体多巴胺转运位点的非均匀性丧失,在MPTP开始2周和3周后,3H-mazindol结合的定量减少程度相似。使用人工和自动方法对酪氨酸羟化酶免疫组化染色的黑质DA神经元进行计数,发现野生型对照减少29-34%,但p53−/−未减少。MPTP使对照组DA神经元表面积平均减少63-68%,p53 - / -组平均减少35-50%。我们得出结论,p53蛋白似乎是MPTP对多巴胺神经元的神经毒性完全表达所必需的。我们的研究结果提示p53基因和其他生长控制基因可能调控帕金森病中多巴胺神经元的死亡。
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