Your search keyword '"Boggs DG"' showing total 8 results

1. Conformation-Dependent Hydrogen-Bonding Interactions in a Switchable Artificial Metalloprotein.

Author

Fatima S, Mehrafrooz B, Boggs DG, Ali N, Singh S, Thielges MC, Bridwell-Rabb J, Aksimentiev A, and Olshansky L

Subjects

Catalytic Domain, Hydrogen Bonding, Metalloproteins chemistry, Metalloproteins metabolism, Metalloproteins genetics, Molecular Dynamics Simulation, Protein Conformation

Abstract

Hydrogen-bonding (H-bonding) interactions in metalloprotein active sites can critically regulate enzyme function. Changes in the protein structure triggered by interplay with substrates, products, and partner proteins are often translated to the metallocofactor by way of specific changes in H-bond networks connected to the active site. However, the complexities of metalloprotein architecture and mechanism often preclude our ability to define the precise molecular interactions giving rise to these intricate regulatory pathways. To address this shortcoming, we have developed conformationally switchable artificial metalloproteins (swArMs) in which allosteric Gln-binding triggers protein conformational changes that impact the microenvironment surrounding an installed metallocofactor. Herein, we report a combined structural, spectroscopic, and computational approach to enhance the conformation-dependent changes in H-bond interactions surrounding the metallocofactor site of a swArM. Structure-informed molecular dynamics simulations were employed to predict point mutations that could enhance active site H-bond interactions preferentially in the Gln-bound holo -conformation of the swArM. Testing our predictions via the unique infrared spectral signals associated with the metallocofactor site, we have identified three key residues capable of imparting conformational control over the metallocofactor microenvironment. The resultant swArMs not only model biologically relevant structural regulation but also provide an enhanced Gln-responsive biological probe to be leveraged in future biosensing applications.

Published

2024

2. Structure-driven development of a biomimetic rare earth artificial metalloprotein.

Author

Thompson PJ, Boggs DG, Wilson CA, Bruchs AT, Velidandla U, Bridwell-Rabb J, and Olshansky L

Subjects

Metalloproteins chemistry, Metalloproteins metabolism, Alcohol Dehydrogenase metabolism, Alcohol Dehydrogenase chemistry, Crystallography, X-Ray, PQQ Cofactor metabolism, PQQ Cofactor chemistry, Biomimetic Materials chemistry, Biomimetic Materials metabolism, Metals, Rare Earth chemistry, Metals, Rare Earth metabolism, Models, Molecular, Lanthanum chemistry, Lanthanum metabolism, Methylobacterium extorquens enzymology, Methylobacterium extorquens metabolism

Abstract

The 2011 discovery of the first rare earth-dependent enzyme in methylotrophic Methylobacterium extorquens AM1 prompted intensive research toward understanding the unique chemistry at play in these systems. This enzyme, an alcohol dehydrogenase (ADH), features a La 3+ ion closely associated with redox-active coenzyme pyrroloquinoline quinone (PQQ) and is structurally homologous to the Ca 2+ -dependent ADH from the same organism. AM1 also produces a periplasmic PQQ-binding protein, PqqT, which we have now structurally characterized to 1.46-Å resolution by X-ray diffraction. This crystal structure reveals a Lys residue hydrogen-bonded to PQQ at the site analogously occupied by a Lewis acidic cation in ADH. Accordingly, we prepared K 142 A- and K 142 D-PqqT variants to assess the relevance of this site toward metal binding. Isothermal titration calorimetry experiments and titrations monitored by UV-Vis absorption and emission spectroscopies support that K 142 D-PqqT binds tightly ( K d = 0.6 ± 0.2 μM) to La 3+ in the presence of bound PQQ and produces spectral signatures consistent with those of ADH enzymes. These spectral signatures are not observed for WT- or K 142 A-variants or upon addition of Ca 2+ to PQQ ⸦ K 142 D-PqqT. Addition of benzyl alcohol to La 3+ -bound PQQ ⸦ K 142 D-PqqT (but not Ca 2+ -bound PQQ ⸦ K 142 D-PqqT, or La 3+ -bound PQQ ⸦ WT-PqqT) produces spectroscopic changes associated with PQQ reduction, and chemical trapping experiments reveal the production of benzaldehyde, supporting ADH activity. By creating a metal binding site that mimics native ADH enzymes, we present a rare earth-dependent artificial metalloenzyme primed for future mechanistic, biocatalytic, and biosensing applications., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

3. Purification and characterization of a Rieske oxygenase and its NADH-regenerating partner proteins.

Author

Barroso GT, Garcia AA, Knapp M, Boggs DG, and Bridwell-Rabb J

Subjects

Bacterial Proteins metabolism, Bacterial Proteins isolation & purification, Bacterial Proteins chemistry, Bacterial Proteins genetics, Oxygenases metabolism, Oxygenases chemistry, Oxygenases isolation & purification, Crystallography, X-Ray methods, Electron Transport Complex III metabolism, Electron Transport Complex III chemistry, Electron Transport Complex III isolation & purification, NADP metabolism, NAD metabolism

Abstract

The Rieske non-heme iron oxygenases (Rieske oxygenases) comprise a class of metalloenzymes that are involved in the biosynthesis of complex natural products and the biodegradation of aromatic pollutants. Despite this desirable catalytic repertoire, industrial implementation of Rieske oxygenases has been hindered by the multicomponent nature of these enzymes and their requirement for expensive reducing equivalents in the form of a reduced nicotinamide adenine dinucleotide cosubstrate (NAD(P)H). Fortunately, however, some Rieske oxygenases co-occur with accessory proteins, that through a downstream reaction, recycle the needed NAD(P)H for catalysis. As these pathways and accessory proteins are attractive for bioremediation applications and enzyme engineering campaigns, herein, we describe methods for assembling Rieske oxygenase pathways in vitro. Further, using the TsaMBCD pathway as a model system, in this chapter, we provide enzymatic, spectroscopic, and crystallographic methods that can be adapted to explore both Rieske oxygenases and their co-occurring accessory proteins., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

4. The NADH recycling enzymes TsaC and TsaD regenerate reducing equivalents for Rieske oxygenase chemistry.

Author

Tian J, Boggs DG, Donnan PH, Barroso GT, Garcia AA, Dowling DP, Buss JA, and Bridwell-Rabb J

Subjects

Aldehyde Dehydrogenase metabolism, NAD metabolism, Substrate Specificity, Nonheme Iron Proteins chemistry, Nonheme Iron Proteins genetics, Nonheme Iron Proteins metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Protein Structure, Tertiary, Models, Molecular, Protein Stability, Computational Biology, Oxygenases metabolism, Comamonas testosteroni enzymology, Comamonas testosteroni genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism

Abstract

Many microorganisms use both biological and nonbiological molecules as sources of carbon and energy. This resourcefulness means that some microorganisms have mechanisms to assimilate pollutants found in the environment. One such organism is Comamonas testosteroni, which metabolizes 4-methylbenzenesulfonate and 4-methylbenzoate using the TsaMBCD pathway. TsaM is a Rieske oxygenase, which in concert with the reductase TsaB consumes a molar equivalent of NADH. Following this step, the annotated short-chain dehydrogenase/reductase and aldehyde dehydrogenase enzymes TsaC and TsaD each regenerate a molar equivalent of NADH. This co-occurrence ameliorates the need for stoichiometric addition of reducing equivalents and thus represents an attractive strategy for integration of Rieske oxygenase chemistry into biocatalytic applications. Therefore, in this work, to overcome the lack of information regarding NADH recycling enzymes that function in partnership with Rieske non-heme iron oxygenases (Rieske oxygenases), we solved the X-ray crystal structure of TsaC to a resolution of 2.18 Å. Using this structure, a series of substrate analog and protein variant combination reactions, and differential scanning fluorimetry experiments, we identified active site features involved in binding NAD + and controlling substrate specificity. Further in vitro enzyme cascade experiments demonstrated the efficient TsaC- and TsaD-mediated regeneration of NADH to support Rieske oxygenase chemistry. Finally, through in-depth bioinformatic analyses, we illustrate the widespread co-occurrence of Rieske oxygenases with TsaC-like enzymes. This work thus demonstrates the utility of these NADH recycling enzymes and identifies a library of short-chain dehydrogenase/reductase enzyme prospects that can be used in Rieske oxygenase pathways for in situ regeneration of NADH., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

5. Custom tuning of Rieske oxygenase reactivity.

Author

Tian J, Liu J, Knapp M, Donnan PH, Boggs DG, and Bridwell-Rabb J

Subjects

Mixed Function Oxygenases, Catalysis, Culture, Oxygenases, Dioxygenases

Abstract

Rieske oxygenases use a Rieske-type [2Fe-2S] cluster and a mononuclear iron center to initiate a range of chemical transformations. However, few details exist regarding how this catalytic scaffold can be predictively tuned to catalyze divergent reactions. Therefore, in this work, using a combination of structural analyses, as well as substrate and rational protein-based engineering campaigns, we elucidate the architectural trends that govern catalytic outcome in the Rieske monooxygenase TsaM. We identify structural features that permit a substrate to be functionalized by TsaM and pinpoint active-site residues that can be targeted to manipulate reactivity. Exploiting these findings allowed for custom tuning of TsaM reactivity: substrates are identified that support divergent TsaM-catalyzed reactions and variants are created that exclusively catalyze dioxygenation or sequential monooxygenation chemistry. Importantly, we further leverage these trends to tune the reactivity of additional monooxygenase and dioxygenase enzymes, and thereby provide strategies to custom tune Rieske oxygenase reaction outcomes., (© 2023. Springer Nature Limited.)

Published

2023

6. A structure-function analysis of chlorophyllase reveals a mechanism for activity regulation dependent on disulfide bonds.

Author

Jo M, Knapp M, Boggs DG, Brimberry M, Donnan PH, and Bridwell-Rabb J

Subjects

Disulfides, Plant Proteins chemistry, Plant Proteins metabolism, Carboxylic Ester Hydrolases chemistry, Carboxylic Ester Hydrolases metabolism, Chlorophyll metabolism, Triticum enzymology

Abstract

Chlorophyll pigments are used by photosynthetic organisms to facilitate light capture and mediate the conversion of sunlight into chemical energy. Due to the indispensable nature of this pigment and its propensity to form reactive oxygen species, organisms heavily invest in its biosynthesis, recycling, and degradation. One key enzyme implicated in these processes is chlorophyllase, an α/β hydrolase that hydrolyzes the phytol tail of chlorophyll pigments to produce chlorophyllide molecules. This enzyme was discovered a century ago, but despite its importance to diverse photosynthetic organisms, there are still many missing biochemical details regarding how chlorophyllase functions. Here, we present the 4.46-Å resolution crystal structure of chlorophyllase from Triticum aestivum. This structure reveals the dimeric architecture of chlorophyllase, the arrangement of catalytic residues, an unexpected divalent metal ion-binding site, and a substrate-binding site that can accommodate a diverse range of pigments. Further, this structure exhibits the existence of both intermolecular and intramolecular disulfide bonds. We investigated the importance of these architectural features using enzyme kinetics, mass spectrometry, and thermal shift assays. Through this work, we demonstrated that the oxidation state of the Cys residues is imperative to the activity and stability of chlorophyllase, illuminating a biochemical trigger for responding to environmental stress. Additional bioinformatics analysis of the chlorophyllase enzyme family reveals widespread conservation of key catalytic residues and the identified "redox switch" among other plant chlorophyllase homologs, thus revealing key details regarding the structure-function relationships in chlorophyllase., Competing Interests: Conflict of interests The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

7. Engineering a Conformationally Switchable Artificial Metalloprotein.

Author

Fatima S, Boggs DG, Ali N, Thompson PJ, Thielges MC, Bridwell-Rabb J, and Olshansky L

Subjects

Crystallography, X-Ray, Escherichia coli metabolism, Circular Dichroism, Kinetics, Metalloproteins chemistry

Abstract

Many naturally occurring metalloenzymes are gated by rate-limiting conformational changes, and there exists a critical interplay between macroscopic structural rearrangements of the protein and subatomic changes affecting the electronic structure of embedded metallocofactors. Despite this connection, most artificial metalloproteins (ArMs) are prepared in structurally rigid protein hosts. To better model the natural mechanisms of metalloprotein reactivity, we have developed conformationally switchable ArMs (swArMs) that undergo a large-scale structural rearrangement upon allosteric effector binding. The swArMs reported here contain a Co(dmgH) 2 (X) cofactor (dmgH = dimethylglyoxime and X = N 3 - , H 3 C - , and i Pr - ). We used UV-vis absorbance and energy-dispersive X-ray fluorescence spectroscopies, along with protein assays, and mass spectrometry to show that these metallocofactors are installed site-specifically and stoichiometrically via direct Co-S cysteine ligation within the Escherichia coli glutamine binding protein (GlnBP). Structural characterization by single-crystal X-ray diffraction unveils the precise positioning and microenvironment of the metallocofactor within the protein fold. Fluorescence, circular dichroism, and infrared spectroscopies, along with isothermal titration calorimetry, reveal that allosteric Gln binding drives a large-scale protein conformational change. In swArMs containing a Co(dmgH) 2 (CH 3 ) cofactor, we show that the protein stabilizes the otherwise labile Co-S bond relative to the free complex. Kinetics studies performed as a function of temperature and pH reveal that the protein conformational change accelerates this bond dissociation in a pH-dependent fashion. We present swArMs as a robust platform for investigating the interplay between allostery and metallocofactor regulation.

Published

2022

8. Determination of optimal time lapse for recall of patients in an incremental dental care program.

Author

Boggs DG and Schork MA

Subjects

Adolescent, Adult, Arizona, Child, Child, Preschool, Costs and Cost Analysis, Dental Prophylaxis, Dental Restoration, Permanent, Diagnosis, Oral, Fluorides, Topical administration & dosage, Humans, New Mexico, South Dakota, Time Factors, Tooth Extraction, Appointments and Schedules, Dental Care, Indians, North American

Abstract

The study was designed to determine the optimal recall interval for persons, ages 5 to 19 years, in the Indian Health Service dental care program and to determine the optimal number of persons to whom maintenance care could be provided at various recall intervals. Analyses used to determine the optimal number of persons and the optimal recall period are described. As expected, the number of services required increased as the maintenance interval increased. The maximum number of persons can be treated on a recall period of 25 to 27 months, but during this time persons 5 to 9 years old had significant increases in the number of services required. Therefore, the optimal recall interval for persons in this age group is to 10 to 12 months. The optimal recall interval for persons 10 to 14 years old is 25 to 27 months, and for persons 15 to 19 years old, 22 to 24 months.

Published

1975