Exploring the Heterogeneous Structural Dynamics of Class II Lanthipeptide Synthetases with Hydrogen-Deuterium Exchange Mass Spectrometry (HDX-MS).

Class II lanthipeptide synthetases (LanM enzymes) catalyze the installation of multiple thioether bridges into genetically encoded peptides to produce macrocyclic lanthipeptides, a class of biologically active natural products. Collectively, LanM enzymes install thioether rings of different sizes, topologies, and stereochemistry into a vast array of different LanA precursor peptide sequences. The factors that govern the outcome of the LanM-catalyzed reaction cascade are not fully characterized but are thought to involve both intermolecular interactions and intramolecular conformational changes in the [LanM:LanA] Michaelis complex. To test this hypothesis, we have combined AlphaFold modeling with hydrogen-deuterium exchange mass spectrometry (HDX-MS) analysis of a small collection of divergent LanM/LanA systems to investigate the similarities and differences in their conformational dynamic properties. Our data indicate that LanA precursor peptide binding triggers relatively conserved changes in the structural dynamics of the LanM dehydratase domain, supporting the existence of a similar leader peptide binding mode across the LanM family. In contrast, changes induced in the dynamics of the LanM cyclase domain were more highly variable between enzymes, perhaps reflecting different peptide-cyclase interactions and/or different modes of allosteric activation in class II lanthipeptide biosynthesis. Our analysis highlights the ability of the emerging AlphaFold platform to predict protein-peptide interactions that are supported by other lines of experimental evidence. The combination of AlphaFold modeling with HDX-MS analysis should emerge as a useful approach for investigating other conformationally dynamic enzymes involved in peptide natural product biosynthesis.

Partially Modified Peptide Intermediates in Lanthipeptide Biosynthesis Alter the Structure and Dynamics of a Lanthipeptide Synthetase.

Lanthipeptide synthetases construct macrocyclic peptide natural products by catalyzing an iterative cascade of post-translational modifications. Class II lanthipeptide synthetases (LanM enzymes) catalyze multiple rounds of peptide dehydration and thioether macrocycle formation in a manner that guides precursor peptide maturation to the biologically active final product with high fidelity. The mechanistic details underlying the contradictory phenomena of substrate flexibility coupled with high biosynthetic fidelity have proven challenging to illuminate. In this work, we employ mass spectrometry to investigate how the structure of a maturing precursor lanthipeptide (HalA2) influences the local and global structure of its cognate lanthipeptide synthetase (HalM2). Using enzymatically synthesized HalA2 peptides that contain sets of native thioether macrocycles, we employ ion mobility mass spectrometry (IM-MS) to show that HalA2 macrocyclization alters the conformational landscape of the HalM2 enzyme in a systematic manner. Hydrogen-deuterium exchange mass spectrometry (HDX-MS) studies show that local HalM2 structural dynamics also change in response to HalA2 post-translational modification. Notably, deuterium uptake in a critical HalM2 α-helical region depends on the number of thioether macrocycles present in the HalA2 core peptide. Binding of the isolated leader and core peptide portions of the modular HalA2 precursor led to a synergistic structuring of this α-helical region, providing evidence for distinct leader and core peptide binding sites that independently alter the dynamics of this functionally critical α-helix. The data support a mechanistic model where the sequential post-translational modification of HalA2 alters the conformational dynamics of HalM2 in regions of the enzyme that are known to be functionally critical.

Mutations in Dynamic Structural Elements Alter the Kinetics and Fidelity of the Multifunctional Class II Lanthipeptide Synthetase, HalM2.

Class II lanthipeptide synthetases (LanM enzymes) catalyze the multistep post-translational modification of genetically encoded precursor peptides into macrocyclic (often antimicrobial) lanthipeptides. The reaction sequence involves dehydration of serine/threonine residues, followed by intramolecular addition of cysteine thiols onto the nascent dehydration sites to construct thioether bridges. LanMs utilize two separate active sites in an iterative yet highly coordinated manner to maintain a remarkable level of regio- and stereochemical control over the multistep maturation. The mechanisms underlying this biosynthetic fidelity remain enigmatic. We recently demonstrated that proper function of the haloduracin ß synthetase (HalM2) requires dynamic structural elements scattered across the surface of the enzyme. Here, we perform kinetic simulations, structural analysis of reaction intermediates, hydrogen-deuterium exchange mass spectrometry studies, and molecular dynamics simulations to investigate the contributions of these dynamic HalM2 structural elements to biosynthetic efficiency and fidelity. Our studies demonstrate that a large, conserved loop (HalM2 residues P349-P405) plays essential roles in defining the precursor peptide binding site, facilitating efficient peptide dehydration, and guiding the order of thioether ring formation. Moreover, mutations near the interface of the HalM2 dehydratase and cyclase domains perturb cyclization fidelity and result in aberrant thioether topologies that cannot be corrected by the wild type enzyme, suggesting an element of kinetic control in the normal cyclization sequence. Overall, this work provides the most comprehensive correlation of the structural and functional properties of a LanM enzyme reported to date and should inform mechanistic studies of the biosynthesis of other ribosomally synthesized and post-translationally modified peptide natural products.

Exploring the Conformational Landscape of a Lanthipeptide Synthetase Using Native Mass Spectrometry.

Lanthipeptides are ribosomally synthesized and post-translationally modified peptide (RiPP) natural products. These genetically encoded peptides are biosynthesized by multifunctional enzymes (lanthipeptide synthetases) that possess relaxed substrate specificity and catalyze iterative rounds of post-translational modification. Recent evidence has suggested that some lanthipeptide synthetases are structurally dynamic enzymes that are allosterically activated by precursor peptide binding and that conformational sampling of the enzyme-peptide complex may play an important role in defining the efficiency and sequence of biosynthetic events. These "biophysical" processes, while critical for defining the activity and function of the synthetase, remain very challenging to study with existing methodologies. Herein, we show that native mass spectrometry coupled to ion mobility (native IM-MS) provides a powerful and sensitive means for investigating the conformational landscapes and intermolecular interactions of lanthipeptide synthetases. Namely, we demonstrate that the class II lanthipeptide synthetase (HalM2) and its noncovalent complex with the cognate HalA2 precursor peptide can be delivered into the gas phase in a manner that preserves native structures and intermolecular enzyme-peptide contacts. Moreover, gas phase ion mobility studies of the natively folded ions demonstrate that peptide binding and mutations to dynamic structural elements of HalM2 alter the conformational landscape of the enzyme. Cumulatively, these data support previous claims that lanthipeptide synthetases are structurally dynamic enzymes that undergo functionally relevant conformational changes in response to precursor peptide binding. This work establishes native IM-MS as a versatile approach for characterizing intermolecular interactions and for unraveling the relationships between protein structure and biochemical function in RiPP biosynthetic systems.

Insights into the Dynamic Structural Properties of a Lanthipeptide Synthetase using Hydrogen-Deuterium Exchange Mass Spectrometry.

The biosynthesis of ribosomally synthesized and post-translationally modified peptides (RiPPs) proceeds via the multistep maturation of genetically encoded precursor peptides, often catalyzed by enzymes with multiple functions and iterative activities. Recent studies have suggested that, among other factors, conformational sampling of enzyme:peptide complexes likely plays a critical role in defining the kinetics and, ultimately, the set of post-translational modifications in these systems. However, detailed characterizations of these putative conformational sampling mechanisms have not yet been possible on many RiPP biosynthetic systems. In this study, we report the first comprehensive application of hydrogen-deuterium exchange mass spectrometry (HDX-MS) to study the biophysical properties of a RiPP biosynthetic enzyme. Using the well-characterized class II lanthipeptide synthetase HalM2 as a model system, we have employed HDX-MS to demonstrate that HalM2 is indeed a highly structurally dynamic enzyme. Using this HDX-MS approach, we have identified novel precursor peptide binding elements, have uncovered long-range structural communication across the enzyme that is triggered by ligand binding and ATP hydrolysis, and have detected specific interactions between the HalM2 synthetase and the leader- and core-peptide subdomains of the modular HalA2 precursor peptide substrate. The functional relevance of the dynamic HalM2 elements discovered in this study are validated with biochemical assays and kinetic analysis of a panel of HDX-MS guided variant enzymes. Overall, the data have provided a wealth of fundamentally new information on LanM systems that will inform the rational manipulation and engineering of these impressive multifunctional catalysts. Moreover, this work highlights the broad utility of the HDX-MS platform for revealing important biophysical properties and enzyme structural dynamics that likely play a widespread role in RiPP biosynthesis.

A Hydrogen-Deuterium Exchange Mass Spectrometry (HDX-MS) Platform for Investigating Peptide Biosynthetic Enzymes.

Hydrogen-deuterium exchange mass spectrometry (HDX-MS) is a powerful method for the biophysical characterization of enzyme conformational changes and enzyme-substrate interactions. Among its many benefits, HDX-MS consumes only small amounts of material, can be performed under near native conditions without the need for enzyme/substrate labeling, and can provide spatially resolved information on enzyme conformational dynamics-even for large enzymes and multiprotein complexes. The method is initiated by the dilution of the enzyme of interest into buffer prepared in D2O. This triggers the exchange of protium in peptide bond amides (N-H) with deuterium (N-D). At the desired exchange time points, reaction aliquots are quenched, the enzyme is proteolyzed into peptides, the peptides are separated by ultra-performance liquid chromatography (UPLC), and the change in mass of each peptide (due to the exchange of hydrogen for deuterium) is recorded by MS. The amount of deuterium uptake by each peptide is strongly dependent on the local hydrogen bonding environment of that peptide. Peptides present in very dynamic regions of the enzyme exchange deuterium very rapidly, whereas peptides derived from well-ordered regions undergo exchange much more slowly. In this manner, the HDX rate reports on local enzyme conformational dynamics. Perturbations to deuterium uptake levels in the presence of different ligands can then be used to map ligand binding sites, identify allosteric networks, and to understand the role of conformational dynamics in enzyme function. Here, we illustrate how we have used HDX-MS to better understand the biosynthesis of a type of peptide natural products called lanthipeptides. Lanthipeptides are genetically encoded peptides that are post-translationally modified by large, multifunctional, conformationally dynamic enzymes that are difficult to study with traditional structural biology approaches. HDX-MS provides an ideal and adaptable platform for investigating the mechanistic properties of these types of enzymes.