Wang Fudi, Lothrop Adam P, James Nicholas G, Griffiths Tanya A M, Lambert Lisa A, Leverence Rachael, Kaltashov Igor A, Andrews Nancy C, MacGillivray Ross T A, Mason Anne B
Division of Hematology/Oncology, Children's Hospital Boston, and Harvard Medical School, Boston, MA 02115, USA.
Biochem J. 2007 Aug 15;406(1):85-95. doi: 10.1042/BJ20070384.
In a search for genes that modify iron homoeostasis, a gene (1300017J02Rik) was located immediately upstream of the murine TF (transferrin) gene. However, expression of the 1300017J02Rik gene product was not responsive to a number of modulators of iron metabolism. Specifically, expression was not altered in mouse models of iron disorders including mice with deficiencies in the haemochromatosis protein Hfe, the recombination-activating protein, Rag, beta2-microglobulin, TF, ceruloplasmin or Hb, or in mice with microcytic anaemia. Additionally, neither lipopolysaccharide nor hypoxia treatment resulted in any significant changes in the 1300017J02Rik expression level. The genomic DNA sequence suggested that the 1300017J02Rik gene product might be a protein equivalent to the pICA {porcine ICA [inhibitor of CA (carbonic anhydrase)]}. The coding region for the murine 1300017J02Rik gene was placed into the pNUT expression vector. Transformed BHK cells (baby-hamster kidney cells) were transfected with this plasmid, resulting in secretion of recombinant mICA (murine ICA) into the tissue culture medium. Following purification to homogeneity, the yield of mICA from the BHK cells was found to be considerably greater (at least 4-fold) than the yield of pICA from a previously reported Pichia pastoris (yeast) expression system. MS showed that the recombinant mICA was a glycoprotein that associated with CA in a 1:1 stoichiometry. Despite its high sequence similarity to TF, titration experiments showed that mICA was unable to bind iron specifically. Although enzymatic assays revealed that mICA was able to inhibit CA, it is unclear if this is its sole or even its major function since, to date, humans and other primates appear to lack functional ICA. Lastly, we note that this member of the TF superfamily is a relatively recent addition resulting from a tandem duplication event.
在寻找调节铁稳态的基因时,发现一个基因(1300017J02Rik)紧邻小鼠转铁蛋白(TF)基因上游。然而,1300017J02Rik基因产物的表达对多种铁代谢调节剂无反应。具体而言,在铁紊乱小鼠模型中,包括血色病蛋白Hfe、重组激活蛋白Rag、β2-微球蛋白、TF、铜蓝蛋白或血红蛋白缺乏的小鼠,以及小细胞贫血小鼠,其表达均未改变。此外,脂多糖和缺氧处理均未导致1300017J02Rik表达水平发生任何显著变化。基因组DNA序列表明,1300017J02Rik基因产物可能是一种与猪ICA(碳酸酐酶抑制剂)等效的蛋白质。将小鼠1300017J02Rik基因的编码区插入pNUT表达载体。用该质粒转染转化的BHK细胞(幼仓鼠肾细胞),导致重组小鼠ICA(mICA)分泌到组织培养基中。纯化至同质后,发现BHK细胞产生的mICA产量比先前报道的毕赤酵母(酵母)表达系统产生的pICA产量高得多(至少4倍)。质谱分析表明,重组mICA是一种糖蛋白,与碳酸酐酶(CA)以1:1的化学计量比结合。尽管其与TF具有高度的序列相似性,但滴定实验表明mICA不能特异性结合铁。虽然酶活性测定显示mICA能够抑制CA,但目前尚不清楚这是否是其唯一甚至主要功能,因为迄今为止,人类和其他灵长类动物似乎缺乏功能性ICA。最后,我们注意到TF超家族的这一成员是串联重复事件导致的相对较新的成员。