Department of Animal & Avian Sciences and Department of Cell Biology & Molecular Genetics, University of Maryland, College Park, Maryland 20742, USA.
J Biol Chem. 2012 Feb 10;287(7):4914-24. doi: 10.1074/jbc.M111.326785. Epub 2011 Dec 15.
Caenorhabditis elegans and human HRG-1-related proteins are conserved, membrane-bound permeases that bind and translocate heme in metazoan cells via a currently uncharacterized mechanism. Here, we show that cellular import of heme by HRG-1-related proteins from worms and humans requires strategically located amino acids that are topologically conserved across species. We exploit a heme synthesis-defective Saccharomyces cerevisiae mutant to model the heme auxotrophy of C. elegans and demonstrate that, under heme-deplete conditions, the endosomal CeHRG-1 requires both a specific histidine in the predicted second transmembrane domain (TMD2) and the FARKY motif in the C terminus tail for heme transport. By contrast, the plasma membrane CeHRG-4 transports heme by utilizing a histidine in the exoplasmic (E2) loop and the FARKY motif. Optimal activity under heme-limiting conditions, however, requires histidine in the E2 loop of CeHRG-1 and tyrosine in TMD2 of CeHRG-4. An analogous system exists in humans, because mutation of the synonymous histidine in TMD2 of hHRG-1 eliminates heme transport activity, implying an evolutionary conserved heme transport mechanism that predates vertebrate origins. Our results support a model in which heme is translocated across membranes facilitated by conserved amino acids positioned on the exoplasmic, cytoplasmic, and transmembrane regions of HRG-1-related proteins. These findings may provide a framework for understanding the structural basis of heme transport in eukaryotes and human parasites, which rely on host heme for survival.
秀丽隐杆线虫和人类 HRG-1 相关蛋白是保守的、膜结合的通透酶,通过目前尚未确定的机制在后生动物细胞中结合和转运血红素。在这里,我们表明,来自线虫和人类的 HRG-1 相关蛋白对血红素的细胞内摄取需要在拓扑上跨物种保守的策略性氨基酸。我们利用血红素合成缺陷型酿酒酵母突变体来模拟秀丽隐杆线虫的血红素营养缺陷,并证明在血红素耗尽的条件下,内体 CeHRG-1 需要预测的第二跨膜结构域(TMD2)中的特定组氨酸和 C 末端尾部的 FARKY 基序才能进行血红素转运。相比之下,质膜 CeHRG-4 通过利用外质(E2)环中的组氨酸和 C 末端尾部的 FARKY 基序来转运血红素。然而,在血红素限制条件下,最佳活性需要 CeHRG-1 的 E2 环中的组氨酸和 CeHRG-4 的 TMD2 中的酪氨酸。在人类中存在类似的系统,因为 hHRG-1 的 TMD2 中的同义组氨酸的突变消除了血红素转运活性,这意味着存在一种进化保守的血红素转运机制,它先于脊椎动物的起源。我们的结果支持一种模型,即血红素通过定位在 HRG-1 相关蛋白的外质、细胞质和跨膜区域的保守氨基酸在跨膜转运。这些发现可能为理解真核生物和依赖宿主血红素生存的人类寄生虫的血红素转运的结构基础提供一个框架。
