Docherty J C, Firneisz G D, Schacter B A
Arch Biochem Biophys. 1984 Dec;235(2):657-64. doi: 10.1016/0003-9861(84)90241-8.
Physiological heme degradation is mediated by the heme oxygenase system consisting of heme oxygenase and NADPH-cytochrome P-450 reductase. Biliverdin IX alpha is formed by elimination of one methene bridge carbon atom as CO. Purified NADPH-cytochrome P-450 reductase alone will also degrade heme but biliverdin is a minor product (15%). The enzymatic mechanisms of heme degradation in the presence and absence of heme oxygenase were compared by analyzing the recovery of 14CO from the degradation of [14C]heme. 14CO recovery from purified NADPH-cytochrome P-450 reductase-catalyzed degradation of [14C]methemalbumin was 15% of the predicted value for one molecule of CO liberated per mole of heme degraded. 14CO2 and [14C]formic acid were formed in amounts (18 and 98%, respectively), suggesting oxidative cleavage of more than one methene bridge per heme degraded, similar to heme degradation by hydrogen peroxide. The reaction was strongly inhibited by catalase, but superoxide dismutase had no effect. [14C]Heme degradation by the reconstituted heme oxygenase system yielded 33% 14CO. Near-stoichiometric recovery of 14CO was achieved after addition of catalase to eliminate side reactions. Near-quantitative recovery of 14CO was also achieved using spleen microsomal preparations. Heme degradation by purified NADPH-cytochrome P-450 reductase appeared to be mediated by hydrogen peroxide. The major products were not bile pigments, and only small amounts of CO were formed. The presence of heme oxygenase, and possibly an intact membrane structure, were essential for efficient heme degradation to bile pigments, possibly by protecting the heme from indiscriminate attack by active oxygen species.
生理性血红素降解由血红素加氧酶系统介导,该系统由血红素加氧酶和NADPH - 细胞色素P - 450还原酶组成。胆绿素IXα是通过消除一个亚甲基桥碳原子作为CO而形成的。单独纯化的NADPH - 细胞色素P - 450还原酶也会降解血红素,但胆绿素是次要产物(15%)。通过分析[14C]血红素降解中14CO的回收率,比较了有无血红素加氧酶时血红素降解的酶促机制。从纯化的NADPH - 细胞色素P - 450还原酶催化的[14C]高铁血红蛋白白蛋白降解中回收的14CO为每摩尔降解的血红素释放一摩尔CO的预测值的15%。14CO2和[14C]甲酸的生成量分别为(18%和98%),这表明每降解一个血红素,不止一个亚甲基桥发生氧化裂解,类似于过氧化氢对血红素的降解。该反应受到过氧化氢酶的强烈抑制,但超氧化物歧化酶没有影响。重组血红素加氧酶系统对[14C]血红素的降解产生了33%的14CO。加入过氧化氢酶以消除副反应后,实现了接近化学计量的14CO回收。使用脾微粒体制剂也实现了接近定量的14CO回收。纯化的NADPH - 细胞色素P - 450还原酶对血红素的降解似乎是由过氧化氢介导的。主要产物不是胆汁色素,仅形成少量的CO。血红素加氧酶的存在以及可能完整的膜结构对于有效地将血红素降解为胆汁色素至关重要,这可能是通过保护血红素免受活性氧的无差别攻击来实现的。
