Your search keyword '"Dawson, Christopher D."' showing total 4 results

1. Molecular basis of C-S bond cleavage in the glycyl radical enzyme isethionate sulfite-lyase.

Author

Dawson, Christopher D., Irwin, Stephania M., Backman, Lindsey R.F., Le, Chip, Wang, Jennifer X., Vennelakanti, Vyshnavi, Yang, Zhongyue, Kulik, Heather J., Drennan, Catherine L., and Balskus, Emily P.

Subjects

*HYDROGEN sulfide, *ENZYMES, *HUMAN microbiota, *RADICALS (Chemistry), *GUT microbiome, *HYDROGEN production

Abstract

Desulfonation of isethionate by the bacterial glycyl radical enzyme (GRE) isethionate sulfite-lyase (IslA) generates sulfite, a substrate for respiration that in turn produces the disease-associated metabolite hydrogen sulfide. Here, we present a 2.7 Å resolution X-ray structure of wild-type IslA from Bilophila wadsworthia with isethionate bound. In comparison with other GREs, alternate positioning of the active site β strands allows for distinct residue positions to contribute to substrate binding. These structural differences, combined with sequence variations, create a highly tailored active site for the binding of the negatively charged isethionate substrate. Through the kinetic analysis of 14 IslA variants and computational analyses, we probe the mechanism by which radical chemistry is used for C-S bond cleavage. This work further elucidates the structural basis of chemistry within the GRE superfamily and will inform structure-based inhibitor design of IsIA and thus of microbial hydrogen sulfide production. [Display omitted] • Molecular basis for sulfite production in the human gut • Crystallographic snapshots of a glycyl radical enzyme found in the human gut • Molecular mechanism of radical-based C-S bond cleavage investigated • Canonical glycyl radical enzyme β barrel is tailored to enable sulfonate binding Dawson, Irwin et al. provide a molecular depiction of how sulfite, a precursor to the cancer- and Crohn's disease-associated metabolite hydrogen sulfide, is generated from isethionate by the enzyme isethionate sulfite-lyase in the human gut microbiota. [ABSTRACT FROM AUTHOR]

Published

2021

2. New tricks for the glycyl radical enzyme family.

Author

Backman, Lindsey R. F., Funk, Michael A., Dawson, Christopher D., and Drennan, Catherine. L.

Subjects

*MOLECULAR structure of enzymes, *ANAEROBIC metabolism, *FORMATE acetyltransferase, *RIBONUCLEOSIDE diphosphate reductase, *CHOLINE, *TOLUENE, *TRIMETHYLAMINE

Abstract

Glycyl radical enzymes (GREs) are important biological catalysts in both strict and facultative anaerobes, playing key roles both in the human microbiota and in the environment. GREs contain a backbone glycyl radical that is post-translationally installed, enabling radical-based mechanisms. GREs function in several metabolic pathways including mixed acid fermentation, ribonucleotide reduction and the anaerobic breakdown of the nutrient choline and the pollutant toluene. By generating a substrate-based radical species within the active site, GREs enable C-C, C-O and C-N bond breaking and formation steps that are otherwise challenging for nonradical enzymes. Identification of previously unknown family members from genomic data and the determination of structures of well-characterized GREs have expanded the scope of GRE-catalyzed reactions as well as defined key features that enable radical catalysis. Here, we review the structures and mechanisms of characterized GREs, classifying members into five categories. We consider the open questions about each of the five GRE classes and evaluate the tools available to interrogate uncharacterized GREs. [ABSTRACT FROM AUTHOR]

Published

2017

3. A rapid and sensitive assay for quantifying the activity of both aerobic and anaerobic ribonucleotide reductases acting upon any or all substrates.

Author

Levitz, Talya S., Andree, Gisele A., Jonnalagadda, Rohan, Dawson, Christopher D., Bjork, Rebekah E., and Drennan, Catherine L.

Subjects

*RIBONUCLEOSIDE diphosphate reductase, *REDUCTASES, *ESCHERICHIA coli, *DEOXYRIBONUCLEOTIDES, *STREPTOCOCCUS thermophilus, *LIQUID chromatography-mass spectrometry, *BIOSYNTHESIS

Abstract

Ribonucleotide reductases (RNRs) use radical-based chemistry to catalyze the conversion of all four ribonucleotides to deoxyribonucleotides. The ubiquitous nature of RNRs necessitates multiple RNR classes that differ from each other in terms of the phosphorylation state of the ribonucleotide substrates, oxygen tolerance, and the nature of both the metallocofactor employed and the reducing systems. Although these differences allow RNRs to produce deoxyribonucleotides needed for DNA biosynthesis under a wide range of environmental conditions, they also present a challenge for establishment of a universal activity assay. Additionally, many current RNR assays are limited in that they only follow the conversion of one ribonucleotide substrate at a time, but in the cell, all four ribonucleotides are actively being converted into deoxyribonucleotide products as dictated by the cellular concentrations of allosteric specificity effectors. Here, we present a liquid chromatography with tandem mass spectrometry (LC-MS/MS)-based assay that can determine the activity of both aerobic and anaerobic RNRs on any combination of substrates using any combination of allosteric effectors. We demonstrate that this assay generates activity data similar to past published results with the canonical Escherichia coli aerobic class Ia RNR. We also show that this assay can be used for an anaerobic class III RNR that employs formate as the reductant, i.e. Streptococcus thermophilus RNR. We further show that this class III RNR is allosterically regulated by dATP and ATP. Lastly, we present activity data for the simultaneous reduction of all four ribonucleotide substrates by the E. coli class Ia RNR under various combinations of allosteric specificity effectors. This validated LC-MS/MS assay is higher throughput and more versatile than the historically established radioactive activity and coupled RNR activity assays as well as a number of the published HPLC-based assays. The presented assay will allow for the study of a wide range of RNR enzymes under a wide range of conditions, facilitating the study of previously uncharacterized RNRs. [ABSTRACT FROM AUTHOR]

Published

2022

4. Structural Investigation of Allosteric Regulation in Class III Ribonucleotide Reductases.

Author

Andree, Gisele A., Levitz, Talya S., Funk, Michael A., Dawson, Christopher D., and Drennan, Catherine L.

Abstract

R3407 --> 497.10 --> Ribonucleotide reductases (RNRs) are essential enzymes that use radical‐based chemistry to catalyze the reduction of ribonucleotides to deoxyribonucleotides. Each RNR class uses a different cofactor to generate a catalytically‐essential thiyl radical species in the enzyme active site. Anaerobic (class III) RNRs employ an oxygen‐sensitive glycyl radical cofactor installed within the glycyl radical domain (GRD) that is adjacent to the active site, whereas aerobic (class Ia) RNRs employ long‐range radical transfer between the catalytic subunit and a di‐iron/tyrosyl radical cofactor housed in the b2 subunit. To maintain intracellular nucleotide pool balance, RNRs are allosterically regulated. For the prototypical class Ia RNRs from Escherichia coli, this allosteric activity regulation involves dATP binding to the N‐terminus of the catalytic subunit in a region known as the 'cone domain', resulting in an association between the cone domain and the b2 subunit that prevents radical transfer between subunits. Despite not requiring a b2 subunit, some class III RNRs (e.g. Streptococcus thermophilus)have a cone domain and are allosterically inhibited by dATP. In this study, we investigate allosteric activity regulation for such a class III RNR, the class III RNR from Streptococcus thermophilus(StNrdD). We use a newly developed LC‐MS/MS based activity assay to show that dATP downregulates StNrdD activity and ATP upregulates activity as is true for class Ia RNRs. Using crystallography, we obtain structural data showing that ATP and dATP both bind to the cone domain, and that both the cone domain and GRD are flexible. In particular, in one monomer of StNrdD dimer, the cone domain contacts the GRD, and both domains are ordered, and in the other monomer, the cone domain is positioned away from the GRD and the GRD is disordered. These observations led us to hypothesize that the cone domains of class III RNRs, like those of class Ia RNR, regulate activity through promotion or inhibition of the radical transfer step, but instead of controlling the position of b2, the position of the GRD is allosterically regulated. In this presentation, we show the data described above and show recent cryogenic electron microscopy of ATP‐bound and dATP‐bound states of StNrdD, which reveals differential positioning of the cone domains in the presence of these allosteric effectors. We also present our current thinking about the mechanism of allosteric regulation of activity in a class III RNR. [ABSTRACT FROM AUTHOR]

Published

2022