Lenartowicz Malgorzata, Moos Torben, Ogórek Mateusz, Jensen Thomas G, Møller Lisbeth B
Department of Genetics and Evolution, Institute of Zoology, Jagiellonian University Krakow, Poland.
Section of Neurobiology, Biomedicine, Institute of Medicine and Health Technology, Aalborg University Aalborg, Denmark.
Front Mol Neurosci. 2016 Aug 18;9:68. doi: 10.3389/fnmol.2016.00068. eCollection 2016.
Deficiency of one of the copper transporters ATP7A and ATP7B leads to the rare X-linked disorder Menkes Disease (MD) or the rare autosomal disorder Wilson disease (WD), respectively. In order to investigate whether the ATP7A and the ATP7B genes may be transcriptionally regulated, we measured the expression level of the two genes at various concentrations of iron, copper, and insulin. Treating fibroblasts from controls or from individuals with MD or WD for 3 and 10 days with iron chelators revealed that iron deficiency led to increased transcript levels of both ATP7A and ATP7B. Copper deficiency obtained by treatment with the copper chelator led to a downregulation of ATP7A in the control fibroblasts, but surprisingly not in the WD fibroblasts. In contrast, the addition of copper led to an increased expression of ATP7A, but a decreased expression of ATP7B. Thus, whereas similar regulation patterns for the two genes were observed in response to iron deficiency, different responses were observed after changes in the access to copper. Mosaic fibroblast cultures from female carriers of MD treated with copper or copper chelator for 6-8 weeks led to clonal selection. Cells that express the normal ATP7A allele had a selective growth advantage at high copper concentrations, whereas more surprisingly, cells that express the mutant ATP7A allele had a selective growth advantage at low copper concentrations. Thus, although the transcription of ATP7A is regulated by copper, clonal growth selection in mosaic cell cultures is affected by the level of copper. Female carriers of MD are rarely affected probably due to a skewed inactivation of the X-chromosome bearing the ATP7A mutation.
铜转运蛋白ATP7A和ATP7B之一的缺陷分别导致罕见的X连锁疾病门克斯病(MD)或罕见的常染色体疾病威尔逊病(WD)。为了研究ATP7A和ATP7B基因是否可能受到转录调控,我们测量了这两个基因在不同浓度的铁、铜和胰岛素条件下的表达水平。用铁螯合剂处理来自对照个体或患有MD或WD个体的成纤维细胞3天和10天,结果显示缺铁导致ATP7A和ATP7B的转录水平均升高。用铜螯合剂处理导致铜缺乏,这使得对照成纤维细胞中的ATP7A下调,但令人惊讶的是,WD成纤维细胞中并未出现这种情况。相反,添加铜导致ATP7A表达增加,但ATP7B表达减少。因此,尽管在缺铁时观察到这两个基因有相似的调控模式,但在铜供应变化后观察到了不同的反应。用铜或铜螯合剂处理MD女性携带者的嵌合成纤维细胞培养物6 - 8周会导致克隆选择。在高铜浓度下,表达正常ATP7A等位基因的细胞具有选择性生长优势,而更令人惊讶的是,在低铜浓度下,表达突变ATP7A等位基因的细胞具有选择性生长优势。因此,尽管ATP7A的转录受铜调控,但嵌合细胞培养中的克隆生长选择受铜水平的影响。MD女性携带者很少受到影响,可能是由于携带ATP7A突变的X染色体发生了偏态失活。
