Mechanistic Insights into the Functioning of a Two-Subunit GMP Synthetase, an Allosterically Regulated, Ammonia Channeling Enzyme

Guanosine 5′-monophosphate (GMP) synthetases, enzymes that catalyze the conversion of xanthosine 5′-monophosphate (XMP) to GMP, are composed of two different catalytic units, which are either two domains of a polypeptide chain or two subunits that associate to form a complex. The glutamine amidotransferase (GATase) unit hydrolyzes glutamine generating ammonia, and the ATP pyrophosphatase (ATPPase) unit catalyzes the formation of an AMP-XMP intermediate. The substrate-bound ATPPase allosterically activates GATase, and the ammonia thus generated is tunneled to the ATPPase active site where it reacts with AMP-XMP generating GMP. In ammonia channeling enzymes reported thus far, a tight complex of the two subunits is observed, while the interaction of the two subunits of Methanocaldococcus jannaschii GMP synthetase (MjGMPS) is transient with the underlying mechanism of allostery and substrate channeling largely unclear. Here, we present a mechanistic model encompassing the various steps in the catalytic cycle of MjGMPS based on biochemical experiments, crystal structure, and cross-linking mass spectrometry guided integrative modeling. pH dependence of enzyme kinetics establishes that ammonia is tunneled across the subunits with the lifetime of the complex being ≤0.5 s. The crystal structure of the XMP-bound ATPPase subunit reported herein highlights the role of conformationally dynamic loops in enabling catalysis. The structure of MjGMPS derived using restraints obtained from cross-linking mass spectrometry has enabled the visualization of subunit interactions that enable allostery under catalytic conditions. We integrate the results and propose a functional mechanism for MjGMPS detailing the various steps involved in catalysis

Mechanistic Insights into the Functioning of a Two-Subunit GMP Synthetase, an Allosterically Regulated, Ammonia Channeling Enzyme

Guanosine 5′-monophosphate (GMP) synthetases, enzymes that catalyze the conversion of xanthosine 5′-monophosphate (XMP) to GMP, are composed of two different catalytic units, which are either two domains of a polypeptide chain or two subunits that associate to form a complex. The glutamine amidotransferase (GATase) unit hydrolyzes glutamine generating ammonia, and the ATP pyrophosphatase (ATPPase) unit catalyzes the formation of an AMP-XMP intermediate. The substrate-bound ATPPase allosterically activates GATase, and the ammonia thus generated is tunneled to the ATPPase active site where it reacts with AMP-XMP generating GMP. In ammonia channeling enzymes reported thus far, a tight complex of the two subunits is observed, while the interaction of the two subunits of Methanocaldococcus jannaschii GMP synthetase (MjGMPS) is transient with the underlying mechanism of allostery and substrate channeling largely unclear. Here, we present a mechanistic model encompassing the various steps in the catalytic cycle of MjGMPS based on biochemical experiments, crystal structure, and cross-linking mass spectrometry guided integrative modeling. pH dependence of enzyme kinetics establishes that ammonia is tunneled across the subunits with the lifetime of the complex being ≤0.5 s. The crystal structure of the XMP-bound ATPPase subunit reported herein highlights the role of conformationally dynamic loops in enabling catalysis. The structure of MjGMPS derived using restraints obtained from cross-linking mass spectrometry has enabled the visualization of subunit interactions that enable allostery under catalytic conditions. We integrate the results and propose a functional mechanism for MjGMPS detailing the various steps involved in catalysis

Mechanistic Insights into the Functioning of a Two-Subunit GMP Synthetase, an Allosterically Regulated, Ammonia Channeling Enzyme

Guanosine 5′-monophosphate (GMP) synthetases, enzymes that catalyze the conversion of xanthosine 5′-monophosphate (XMP) to GMP, are composed of two different catalytic units, which are either two domains of a polypeptide chain or two subunits that associate to form a complex. The glutamine amidotransferase (GATase) unit hydrolyzes glutamine generating ammonia, and the ATP pyrophosphatase (ATPPase) unit catalyzes the formation of an AMP-XMP intermediate. The substrate-bound ATPPase allosterically activates GATase, and the ammonia thus generated is tunneled to the ATPPase active site where it reacts with AMP-XMP generating GMP. In ammonia channeling enzymes reported thus far, a tight complex of the two subunits is observed, while the interaction of the two subunits of Methanocaldococcus jannaschii GMP synthetase (MjGMPS) is transient with the underlying mechanism of allostery and substrate channeling largely unclear. Here, we present a mechanistic model encompassing the various steps in the catalytic cycle of MjGMPS based on biochemical experiments, crystal structure, and cross-linking mass spectrometry guided integrative modeling. pH dependence of enzyme kinetics establishes that ammonia is tunneled across the subunits with the lifetime of the complex being ≤0.5 s. The crystal structure of the XMP-bound ATPPase subunit reported herein highlights the role of conformationally dynamic loops in enabling catalysis. The structure of MjGMPS derived using restraints obtained from cross-linking mass spectrometry has enabled the visualization of subunit interactions that enable allostery under catalytic conditions. We integrate the results and propose a functional mechanism for MjGMPS detailing the various steps involved in catalysis

Revisiting the Burden Borne by Fumarase: Enzymatic Hydration of an Olefin

Fumarate hydratase (FH) is a remarkable catalyst that decreases the free energy of the catalyzed reaction by 30 kcal mol–1, much larger than most exceptional enzymes with extraordinary catalytic rates. Two classes of FH are observed in nature: class-I and class-II, which have different folds, yet catalyze the same reversible hydration/dehydration reaction of the dicarboxylic acids fumarate/malate, with equal efficiencies. Using class-I FH from the hyperthermophilic archaeon Methanocaldococcus jannaschii (Mj) as a model along with comparative analysis with the only other available class-I FH structure from Leishmania major (Lm), we provide insights into the molecular mechanism of catalysis in this class of enzymes. The structure of MjFH apo-protein has been determined, revealing that large intersubunit rearrangements occur across apo- and holo-protein forms, with a largely preorganized active site for substrate binding. Site-directed mutagenesis of active site residues, kinetic analysis, and computational studies, including density functional theory (DFT) and natural population analysis, together show that residues interacting with the carboxylate group of the substrate play a pivotal role in catalysis. Our study establishes that an electrostatic network at the active site of class-I FH polarizes the substrate fumarate through interactions with its carboxylate groups, thereby permitting an easier addition of a water molecule across the olefinic bond. We propose a mechanism of catalysis in FH that occurs through transition-state stabilization involving the distortion of the electronic structure of the substrate olefinic bond mediated by the charge polarization of the bound substrate at the enzyme active site