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围产期铜缺乏症对大鼠脉络丛和小脑选定铜蛋白的可变反应。

Variable response of selected cuproproteins in rat choroid plexus and cerebellum following perinatal copper deficiency.

机构信息

Department of Biochemistry and Molecular Biology, University of Minnesota Medical School Duluth, 1035 University Drive, 55812, Duluth, MN.

出版信息

Genes Nutr. 2006 Mar;1(1):51-9. doi: 10.1007/BF02829936.

DOI:10.1007/BF02829936
PMID:18850220
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2736130/
Abstract

Recent immunohistochemical characterization of the copper transport protein, Ctr1, reported enriched levels in mouse choroid plexus, and enhancement by copper deficiency. To extend and confirm this, experiments were conducted with Holtzman rats. Following perinatal copper deficiency there was an 80% reduction in brain copper of 24-27 day old copper-deficient (Cu-) rat pups compared to copper-adequate (Cu+) controls. Choroid plexus immunoblot analysis with rabbit anti-hCtr1 demonstrated a 50% higher Ctr1 protein expression in Cu-samples. However, levels of copper chaperone for superoxide dismutase (CCS) were unchanged, suggesting that Ctr1 buffers the choroid plexus against copper deficiency, since CCS normally is much higher in Cu-tissues. There were 13% lower levels of cytochrome c oxidase subunit IV (COX IV) detected in Cuchoroid plexus. In contrast, in cerebellum of Cu-rats CCS was 2-fold higher and COXIV 1.7-fold lower than Cu+ rats consistent with severe copper deficiency. Brain mitochondria from Cu-rats had severe reductions in COXIV content and CCO activity and modest but significant elevations in CCS and reductions in Cu, Zn-superoxide dismutase. COXIV may be a more sensitive marker for copper deficiency than CCS and may prove useful to assess copper status.

摘要

最近的免疫组织化学研究表明,铜转运蛋白 Ctr1 在小鼠脉络丛中的含量丰富,并且铜缺乏会使其水平升高。为了进一步证实这一点,研究人员对霍尔茨曼大鼠进行了实验。在围产期铜缺乏的情况下,与铜充足(Cu+)对照组相比,24-27 日龄铜缺乏(Cu-)大鼠幼仔的大脑铜含量减少了 80%。用兔抗 hCtr1 对脉络丛进行免疫印迹分析表明,Cu-样本中的 Ctr1 蛋白表达增加了 50%。然而,超氧化物歧化酶(CCS)的铜伴侣的水平没有变化,这表明 Ctr1 缓冲了脉络丛免受铜缺乏的影响,因为 CCS 在 Cu 组织中通常更高。在 Cuchoroid plexus 中检测到细胞色素 c 氧化酶亚基 IV(COX IV)的水平降低了 13%。相比之下,在 Cu-大鼠的小脑,CCS 增加了 2 倍,COXIV 降低了 1.7 倍,这与严重的铜缺乏一致。Cu-大鼠的脑线粒体中 COXIV 的含量和 CCO 活性严重降低,CCS 和 Cu、Zn-超氧化物歧化酶的含量适度但显著升高。COXIV 可能是铜缺乏的比 CCS 更敏感的标志物,并且可能有助于评估铜状态。

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