Al-Karadaghi S, Hansson M, Nikonov S, Jönsson B, Hederstedt L
Department of Molecular Biophysics, Lund University, Box 124, S-221 00, Lund, Sweden.
Structure. 1997 Nov 15;5(11):1501-10. doi: 10.1016/s0969-2126(97)00299-2.
The metallation of closed ring tetrapyrroles resulting in the formation of hemes, chlorophylls and vitamin B12 is catalyzed by specific enzymes called chelatases. Ferrochelatase catalyzes the terminal step in heme biosynthesis by inserting ferrous ion into protoporphyrin IX by a mechanism that is poorly understood. Mutations in the human gene for ferrochelatase can result in the disease erythropoietic protoporphyria, and a further understanding of the mechanism of this enzyme is therefore of clinical interest. No three-dimensional structure of a tetrapyrrole metallation enzyme has been available until now.
The three-dimensional structure of Bacillus subtilis ferrochelatase has been determined at 1.9 A resolution by the method of multiple isomorphous replacement. The structural model contains 308 of the 310 amino acid residues of the protein and 198 solvent molecules. The polypeptide is folded into two similar domains each with a four-stranded parallel beta sheet flanked by alpha helices. Structural elements from both domains build up a cleft, which contains several amino acid residues that are invariant in ferrochelatases from different organisms. In crystals soaked with gold and cadmium salt solutions, the metal ion was found to be coordinated to the conserved residue His 183, which is located in the cleft. This histidine residue has previously been suggested to be involved in ferrous ion binding.
Ferrochelatase seems to have a structurally conserved core region that is common to the enzyme from bacteria, plants and mammals. We propose that porphyrin binds in the identified cleft; this cleft also includes the metal-binding site of the enzyme. It is likely that the structure of the cleft region will have different conformations upon substrate binding and release.
闭环四吡咯的金属化反应导致血红素、叶绿素和维生素B12的形成,这一过程由特定的螯合酶催化。亚铁螯合酶通过一种尚未完全理解的机制,将亚铁离子插入原卟啉IX中,从而催化血红素生物合成的最后一步。人类亚铁螯合酶基因的突变可导致红细胞生成性原卟啉症,因此,对该酶机制的进一步了解具有临床意义。到目前为止,还没有四吡咯金属化酶的三维结构。
通过多同晶置换法,已确定枯草芽孢杆菌亚铁螯合酶的三维结构分辨率为1.9 Å。结构模型包含该蛋白质310个氨基酸残基中的308个以及198个溶剂分子。多肽折叠成两个相似的结构域,每个结构域都有一个由α螺旋包围的四链平行β折叠。来自两个结构域的结构元件形成一个裂隙,其中包含几个在不同生物体的亚铁螯合酶中不变的氨基酸残基。在用金和镉盐溶液浸泡的晶体中,发现金属离子与位于裂隙中的保守残基His 183配位。此前有人认为这个组氨酸残基参与亚铁离子的结合。
亚铁螯合酶似乎有一个结构保守的核心区域,这是细菌、植物和哺乳动物的该酶所共有的。我们认为卟啉结合在已确定的裂隙中;这个裂隙也包括该酶的金属结合位点。在底物结合和释放时,裂隙区域的结构可能会有不同的构象。
