Cai You, Fengwei Li, Xingwang Zhang, Li Ma, Yu-Zhong Zhang, Wei Zhang, Shengying Li
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The MpaH' structure reveals a canonical α/β-hydrolase fold with an unusually large cap domain and a rare location of the acidic residue D163 of catalytic triad after strand β6. MpaH' also forms an atypical dimer with the unique C-terminal helices α13 and α14 arming the cap domain of the other protomer and indirectly participating in the substrate binding. With these characteristics, we propose that MpaH' and its homologs form a new subfamily of α/β hydrolase fold protein. 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引用次数: 3
摘要
霉酚酸(MPA)是真菌天然产物,是治疗器官移植和自身免疫性疾病的一线免疫抑制药物。在MPA的区隔生物合成中,位于过氧化物酶体中的酰基辅酶A (CoA)水解酶MpaH'催化MPA-CoA的高度特异性水解,生成最终产物MPA。MpaH'严格的底物特异性不仅避免了各种细胞酰基辅酶a的不希望的水解,而且还阻止了MpaH - coa进一步的过氧化物酶体β-氧化分解代谢。为了阐明这一重要性质的结构基础,在本研究中,我们解决了无底物形式的MpaH'和MpaH' 139a突变体与产物MPA配合物的晶体结构。MpaH'的结构揭示了典型的α/β-水解酶折叠,具有异常大的帽结构域和催化三联体在β6链后罕见的酸性残基D163。MpaH'也形成非典型二聚体,其独特的c端螺旋α13和α14连接其他原聚体的帽结构域,间接参与底物结合。基于这些特征,我们提出MpaH'及其同源物形成了一个新的α/β水解酶折叠蛋白亚家族。MpaH' s 139a /MPA复合物的晶体结构和MpaH'/MPA- coa的模型结构,以及结构导向的诱变分析和等温滴定量热法(ITC)测量,为MpaH'的高底物特异性提供了重要的机制见解。
Structural basis for substrate specificity of the peroxisomal acyl-CoA hydrolase MpaH' involved in mycophenolic acid biosynthesis.
Mycophenolic acid (MPA) is a fungal natural product and first-line immunosuppressive drug for organ transplantations and autoimmune diseases. In the compartmentalized biosynthesis of MPA, the acyl-coenzyme A (CoA) hydrolase MpaH' located in peroxisomes catalyzes the highly specific hydrolysis of MPA-CoA to produce the final product MPA. The strict substrate specificity of MpaH' not only averts undesired hydrolysis of various cellular acyl-CoAs, but also prevents MPA-CoA from further peroxisomal β-oxidation catabolism. To elucidate the structural basis for this important property, in this study, we solve the crystal structures of the substrate-free form of MpaH' and the MpaH'S139A mutant in complex with the product MPA. The MpaH' structure reveals a canonical α/β-hydrolase fold with an unusually large cap domain and a rare location of the acidic residue D163 of catalytic triad after strand β6. MpaH' also forms an atypical dimer with the unique C-terminal helices α13 and α14 arming the cap domain of the other protomer and indirectly participating in the substrate binding. With these characteristics, we propose that MpaH' and its homologs form a new subfamily of α/β hydrolase fold protein. The crystal structure of MpaH'S139A /MPA complex and the modeled structure of MpaH'/MPA-CoA, together with the structure-guided mutagenesis analysis and isothermal titration calorimetry (ITC) measurements, provide important mechanistic insights into the high substrate specificity of MpaH'.
期刊介绍:
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