애기장대 ureidoglycine aminohydrolase와 ureidoglycolate amidohydrolase의 구조와 기능에 대한 연구

Abstract

학위논문 (박사)-- 서울대학교 대학원 : 농생명공학부, 2014. 8. 이상기.In plants, the ureide pathway is a metabolic route that converts the ring nitrogen atoms of purine to ammonia via sequential enzymatic reactions, playing an important role in nitrogen recovery. By using x-ray crystallography, crystal structures of two enzymes in this pathway were solved in this study: (S)-ureidoglycine aminohydrolase (UGlyAH) and the (S)-ureidoglycolate amidohydroalse (UAH), both from Arabidopsis thaliana. UGlyAH enzyme converts (S)-ureidoglycine into (S)-ureidoglycolate and ammonia, providing the final substrate to the pathway. Here, a structural and functional analysis of this enzyme from Arabidopsis thaliana (AtUGlyAH) is reported. The crystal structure of AtUGlyAH in the ligand-free form shows a monomer structure in the bi-cupin fold of the β-barrel and an octameric functional unit, as well as an Mn2+ ion binding site. The structure of AtUGlyAH in complex with (S)-ureidoglycine revealed that the Mn2+ ion acts as a molecular anchor to bind (S)-ureidoglycine and its binding mode dictates the enantioselectivity of the reaction. Further kinetic analysis characterized the functional roles of the active site residues, including the Mn2+ ion binding site and residues in the vicinity of (S)-ureidoglycine. These analyses provide molecular insights into the structure of the enzyme and its possible catalytic mechanism. In the final step of the pathway, UAH catalyzes the conversion of (S)-ureidoglycolate into glyoxylate and releases two molecules of ammonia as by-products. UAH is homologous in structure and sequence with allantoate amidohydrolase (AAH), an upstream enzyme in the pathway with a similar function as that of an amidase but with a different substrate. Both enzymes exhibit strict substrate specificity and catalyze reactions in a concerted manner, resulting in purine degradation. Here, three crystal structures of Arabidopsis thaliana UAH: bound with substrate, reaction intermediate, and product, and a structure of Escherichia coli AAH complexed with allantoate are reported. Structural analyses of UAH revealed a distinct binding mode for each ligand in a bimetal reaction center with the active site in a closed conformation. The ligand directly participates in the coordination shell of two metal ions and is stabilized by the surrounding residues. In contrast, AAH, which exhibits a substrate-binding site similar to that of UAH, requires a larger active site due to the additional ureido group in allantoate. Structural analyses and mutagenesis revealed that both enzymes undergo an open-to-close conformational transition in response to ligand binding, and that the active site size as well as the interaction environments in each UAH and AAH are determinants for substrate specificity between two structurally homologous enzymes.ABSTRACT I CONTENTS III LIST OF FIGURES VI LIST OF TABLES VIII LIST OF ABBREVIATIONS IX CHAPTER I. INTRODUCTION 1 CHAPTER II. Structural and Functional Insights into (S)-Ureidoglycine Aminohydrolase, Key Enzyme of Purine Catabolism in Arabidopsis thaliana 8 MATERIALS AND METHODS 1. Construct 9 2. Protein Expression, Purification and Crystallization 11 3. Data Collection and Structure Determination 14 4. Enzyme Assay 20 5. Metal Analysis 24 RESULTS 1. Molecular Architecture of Octameric AtUGlyAH in a Ligand-Free Form 25 2. Interactions between Monomers in the Intra- and Inter-layers 31 3. Active Site in the Ligand-Free Form of AtUGlyAH 35 4. Binding Mode of (S)-Ureidoglycine in the Binary Complex 42 5. Functional Analysis 48 DISCUSSION 53 CHAPTER III. Structural and Functional Insights into the Substrate Specificity of (S)-Ureidoglycolate Amidohydrolase from Arabidopsis thaliana and Its Comparison with Allantoate Amidohydrolase 58 MATERIALS AND METHODS 1. Construct 59 2. Protein Expression and Purification 61 3. Crystallization 62 4. Data Collection and Structure Determination 66 5. Enzyme Assay 71 RESULTS 1. Overall Structure of AtUAH 72 2. Active Site with a Bimetal Center 78 3. Binding Mode of (S)-Ureidoglycolate in a Binary Complex with AtUAH(E183A) 81 4. Binding Mode of the Intermediate and Product in the Binary Complex with AtUAH 85 5. Binding Mode of Allantoate in the Closed Conformation of the EcAAH Binary Complex 89 6. Functional Analyses 93 DISCUSSION 96 CHAPTER IV. CONCLUSIONS 103 REFERENCES 105 ABSTRACT IN KOREAN 113 CURRICULUM VITAE 116 PUBLICATIONS 117 ACKNOWLEDGEMENTS IN KOREAN118Docto

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