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 posttranslational 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.
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.
We present a potential mechanism for emergence of catalytic activity that is essential for survival, from a non-catalytic protein fold. The type B dihydrofolate reductase (DfrB) family of enzymes were first identified in pathogenic bacteria because their dihydrofolate reductase activity is sufficient to provide trimethoprim (TMP) resistance. DfrB enzymes are described as poorly evolved as a result of their unusual structural and kinetic features. No characterized protein shares sequence homology with DfrB enzymes; how they evolved to emerge in the modern resistome is unknown. In this work, we identify DfrB homologues from a database of putative and uncharacterized proteins. These proteins include an SH3-like fold homologous to the DfrB enzymes, embedded in a variety of additional structural domains. By means of functional, structural and biophysical characterization, we demonstrate that these distant homologues and their extracted SH3-like fold can display dihydrofolate reductase activity and confer TMP resistance. We provide evidence of tetrameric assembly and catalytic mechanism analogous to that of DfrB enzymes. These results contribute, to our knowledge, the first insights into a potential evolutionary path taken by this SH3-like fold to emerge in the modern resistome following introduction of TMP. This article is part of the theme issue ‘Reactivity and mechanism in chemical and synthetic biology’.
Lanthipeptides are ribosomally-synthesized and post-translationally modified peptide (RiPP) natural products that are biosynthesized in a multistep maturation process by enzymes (lanthipeptide synthetases) that possess relaxed substrate specificity. 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 nanoelectrospray ionization coupled to ion mobility mass spectrometry (nanoESI-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 non-covalent 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, and that the precursor peptide itself exhibits higher order structure in the mass spectrometer. 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 nanoESI-IM-MS as a versatile approach for unraveling the relationships between protein structure and biochemical function in RiPP biosynthetic systems.
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