Ion mobility mass spectrometry data were collected on a set of five class II lasso peptides and their branched-cyclic topoisomers prepared in denaturing solvent conditions with and without sulfolane as a supercharging agent. Sulfolane was shown not to affect ion mobility results and to allow the formation of highly charged multiply protonated molecules. Drift time values of low charged multiply protonated molecules were found to be similar for the two peptide topologies, indicating the branched-cyclic peptide to be folded in the gas phase into a conformation as compact as the lasso peptide. Conversely, high charge states enabled a discrimination between lasso and branched-cyclic topoisomers, as the former remained compact in the gas phase while the branched-cyclic topoisomer unfolded. Comparison of the ion mobility mass spectrometry data of the lasso and branched-cyclic peptides for all charge states, including the higher charge states obtained with sulfolane, yielded three trends that allowed differentiation of the lasso form from the branched-cyclic topology: low intensity of highly charged protonated molecules, even with the supercharging agent, low change in collision cross sections with increasing charge state of all multiply protonated molecules, and narrow ion mobility peak widths associated with the coexistence of fewer conformations and possible conformational changes.
Lasso peptides constitute a structurally unique class of ribosomally synthesized and post-translationally modified peptides (RiPPs) characterized by a mechanically interlocked structure in which the C-terminal tail of the peptide is threaded and trapped within an N-terminal macrolactam ring. Tandem mass spectrometry using collision induced dissociation (CID) and electron capture dissociation (ECD) have shown previously different fragmentation patterns for capistruin, microcin J25 and their corresponding branched-cyclic forms in which the C-terminal tail is unthreaded. In order to develop general rules that unambiguously discriminate the lasso and branched-cyclic topologies, this report presents experimental evidence for a set of twenty-one lasso peptides analyzed by CID and electron transfer dissociation (ETD). CID experiments on lasso peptides specifically yielded mechanically interlocked species with associated b and y fragments. For class II lasso peptides, these lasso-specific fragments were observed only for peptides in which the loop, located above the macrolactam ring, was strictly longer than four amino acid residues. For class I and III lasso peptides, part of the C-terminal tail remains covalently linked to the macrolactam ring by disulfide bonds; associated b and y fragments therefore do not clearly constitute a signature of the lasso topology. ETD experiments of lasso peptides showed a significant increase of hydrogen migration events in the loop region when compared to their branched-cyclic topoisomers, leading to the formation of specific c˙/z' fragments for all lasso peptides, regardless of their class and loop size. Our experiments enabled us to establish general rules for obtaining structural details from CID and ETD fragmentation patterns, obviating the need for structure determination by NMR or X-ray crystallography.
In the field of functionalized polyoxometalates, organosilyl derivatives of polyoxotungstate constitute a special class of hybrid organic-inorganic system. The first organosilyl derivative of the monovacant Dawson heteropolyoxotungstate [alpha2-P2W17O61]10- was obtained by three different methods. The use of two organosilanes as reagents enabled the preparation of the functionalized polyoxometalate [alpha2-P2W17O61(RSi)2O]6- in good yield. Electrospray (ESI-MS) and matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry, and 183W, 31P, and 29Si NMR spectroscopy were used to characterize the composite systems. In several cases, ESI-MS analyses generated reduction processes which were compared to those related to [PMo11VO40]4-, the highly reducible Keggin polyoxometalate.
Lasso peptides are characterized by a mechanically interlocked structure, where the C-terminal tail of the peptide is threaded and trapped within an N-terminal macrolactam ring. Their compact and stable structures have a significant impact on their biological and physical properties and make them highly interesting for drug development. Ion mobility - mass spectrometry (IM-MS) has shown to be effective to discriminate the lasso topology from their corresponding branched-cyclic topoisomers in which the C-terminal tail is unthreaded. In fact, previous comparison of the IM-MS data of the two topologies has yielded three trends that allow differentiation of the lasso fold from the branched-cyclic structure: (1) the low abundance of highly charged ions, (2) the low change in collision cross sections (CCS) with increasing charge state and (3) a narrow ion mobility peak width. In this study, a three-dimensional plot was generated using three indicators based on these three trends: (1) mean charge divided by mass (ζ), (2) relative range of CCS covered by all protonated molecules (ΔΩ/Ω) and (3) mean ion mobility peak width (δΩ). The data were first collected on a set of twenty one lasso peptides and eight branched-cyclic peptides. The indicators were obtained also for eight variants of the well-known lasso peptide MccJ25 obtained by site-directed mutagenesis and further extended to five linear peptides, two macrocyclic peptides and one disulfide constrained peptide. In all cases, a clear clustering was observed between constrained and unconstrained structures, thus providing a new strategy to discriminate mechanically interlocked topologies. Graphical Abstract ᅟ.
Lignocellulosic
biomass, in particular wood, is a complex mixture
containing cellulose, hemicellulose, lignin, and other trace compounds.
Chemical analysis of these biomasses, especially lignin components,
is a challenge. Lignin is a highly reticulated polymer that is poorly
soluble and usually requires chemical, enzymatic, or thermal degradation
for its analysis. Here, we studied the thermal degradation of lignocellulosic
biomass using a direct insertion probe (DIP). The DIP was used with
two ionization sources: atmospheric pressure chemical ionization (APCI)
and atmospheric pressure photoionization (APPI) coupled to ultrahigh-resolution
mass spectrometry. Beech lignocellulosic biomass samples were used
to develop the DIP-APCI/APPI methodology. Two other wood species (maple
and oak) were analyzed after optimization of DIP parameters. The two
ionization sources were compared at first and showed different responses
toward beech samples, according to the source specificity. APPI was
more specific to lignin degradation compounds, whereas APCI covered
a larger variety of oxygenated compounds, e.g., fatty acids and polyphenolics
compounds, in addition to lignin degradation products. The study of
the thermodesorption profile gave information on the different steps
of lignocellulosic biomass pyrolysis. The comparison of the three
feed sample types (oak, maple, and beech), using principal component
analysis (PCA) with DIP-APCI experiments, showed molecular level differences
between beech wood pellets and the two other wood species (maple and
oak).
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