Exploring the Role of Cofactor and Protein Sequence Variability Across the Old Yellow Enzyme Superfamily Público
Iamurri, Samantha (Summer 2019)
Abstract
Over the past century enzymes have been the center of intense research efforts focused on the discovery and engineering of novel biocatalysts to produce industrially and commercially relevant chemical compounds. Most of these efforts involve enhancing enzyme efficiency, stereospecificity, stability, and substrate scope through alterations to the native protein backbone. Certain enzymes, however, require small molecule chemical cofactors to perform their native functions. Accordingly, engineering of natural cofactors represents parallel strategy for enzyme customization that can be used alongside traditional backbone modification methodologies. On a more fundamental level, cofactor engineering may also be employed to probe the mechanistic and biophysical characteristics of protein catalysts.
This dissertation thus utilizes engineered cofactor analogs to examine the functional role of the native cofactor flavin mononucleotide (FMN) in the folding of Old Yellow Enzyme 1 (OYE1) from Saccharomyces pastorianus. Preliminary work with a cell-free protein expression system determined that FMN must be present during OYE1 synthesis to produce catalytically functional enzymes, disputing a longstanding assumption that the cofactor’s presence is unnecessary for proper folding. Nascent OYE1 was then supplemented with cofactor analogs containing key elements of the native FMN in order to systematically study the contribution of specific chemical groups towards proper enzyme folding. Activity assay data suggest that the flavin’s isoalloxazine and terminal phosphate moieties are essential for productive OYE1 folding.
With the endless industrial demand for new biocatalysts, this work also details our exploration into the OYE superfamily in search of novel enzymes. Using sequence similarity networks (SSNs) to visually guide our sampling efforts, we have doubled the number of characterized OYEs and have begun functionally profiling the entire superfamily in an unprecedented manner. Excitingly, we have identified a number of novel catalysts capable of catalytically out-performing any of the previously reported native or engineered OYE family members.
Table of Contents
Chapter 1: General Introduction 1
General Introduction 2
Chemical Versatility of Cofactors 3
Artificial Metalloenzymes (ArMs) 11
Flavin Cofactors 15
Flavoenzymes 18
Old Yellow Enzymes 24
Beyond OYE1, the OYE superfamily 28
Cell-Free Protein Expression 31
Aims and Scope of the Dissertation 33
References 34
Chapter 2: Truncated FAD synthetase for direct biocatalytic conversion of riboflavin and analogs to their corresponding flavin mononucleotides 54
Abstract 55
Introduction 55
Results and discussion 59
Heterologous expression and purification of full-length and truncated FADSs 59
Characterization of secondary structure and stability by circular dichroism spectroscopy 61
Catalytic activity with RF and flavin analogs 62
Supplemental Information 65
Materials and Methods 65
References 71
Chapter 3: Elucidating the Role of FMN in the Productive Folding of Old Yellow Enzyme 1 73
Introduction 74
Synthesis of FMN Analogs 78
Cofactor Analogs 1, 3, 4 78
Cofactor Analog 2 79
Results and Discussion 81
ITC Binding Studies of FMN (analogs) 81
PURE System Folding Studies of OYE1 84
Conclusion 87
Experimental 89
General Information 89
Synthesis of (2R,3S,4S)-5-(2,6-dioxo-1,2,3,6-tetrahydro-9H-purin-9-yl)-2,3,4-trihydroxypentyl phosphate (1) 89
Synthesis of (2R,3S,4S)-5-(9H-carbazol-9-yl)pentane-1,2,3,4-tetraol (2) 91
Synthesis of (2R,3S,4S)-5-ammonio-2,3,4-trihydroxypentyl phosphate (3) 93
Synthesis of (2R,3S,4S)-2,3,4,5-tetrahydroxypentyl phosphate (4) 93
Conversion of Deoxyriboflavin to DeoxyFMN 94
Expression and Purification of OYE1 94
Isothermal Calorimetry Binding Studies 96
PURExpress In vitro Transcription/Translation of OYE1 with FMN (analogs) 96
Cofactor Competition and Enzymatic Activity Assay 97
References 98
Chapter 4: Exploration of the Old Yellow Enzyme Superfamily Utilizing Sequence Similarity Networks 100
Introduction 101
Results and Discussion 107
Sequence Similarity Network (SSN) 107
Selection of Novel OYE Family Members 110
Evaluation of Novel OYE Family Members 110
Solubility of Novel OYE Family Members 118
Conclusion 121
Experimental 123
General Information 123
PURExpress In vitro Transcription/Translation of OYE Library Members 123
Enzymatic Activity Assay for OYE Library Members 124
Solubility of OYE Library Members 125
Supplemental 126
References 133
Chapter 5: Conclusions and Future Work 143
General Conclusions 144
Continued Use of Cofactor Engineering 145
Further Exploration of the OYE Superfamily 147
References 151
About this Dissertation
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