Compared to traditional collision induced dissociation methods, electron capture dissociation (ECD) provides more comprehensive characterization of large peptides and proteins as well as preserves labile post-translational modifications. However, ECD experiments are generally restricted to the high magnetic fields of FTICR-MS that enable the reaction of large polycations and electrons. Here, we demonstrate the use of an electromagnetostatic ECD cell to perform ECD and hybrid ECD methods utilizing 193 nm photons (ECuvPD) or collisional activation (EChcD) in a benchtop quadrupole-Orbitrap mass spectrometer. The electromagnetostatic ECD cell was designed to replace the transfer octapole between the quadrupole and C-trap. This implementation enabled facile installation of the ECD cell, and ions could be independently subjected to ECD, UVPD, HCD, or any combination. Initial benchmarking and characterization of fragmentation propensities for ECD, ECuvPD, and EChcD were performed using ubiquitin (8.6 kDa). ECD yielded extensive sequence coverage for low charge states of ubiquitin as well as for the larger protein carbonic anhydrase II (29 kDa), indicating pseudo-activated ion conditions. Additionally, relatively high numbers of d- and w-ions enable differentiation of isobaric isoleucine and leucine residues and suggest a distribution of electron energies yield hot-ECD type fragmentation. We report the most comprehensive characterization to date for model proteins up to 29 kDa and a monoclonal antibody at the subunit level. ECD, ECuvPD, and EChcD yielded 93, 95, and 91% sequence coverage, respectively, for carbonic anhydrase II (29 kDa), and targeted online analyses of monoclonal antibody subunits yielded 86% overall antibody sequence coverage.
Resonant electron capture mass spectra of aliphatic and aromatic amino acids and their methyl esters show intense [M-H](-) negative ions in the low-energy range. Ion formation results from a predissociation mechanism mediated by the low-energy pi*oo resonant state. Methylation in general has little influence on the electronic structure according to quantum chemical calculations, but the corresponding ions from the methyl esters, [M-Me](-), could be ascertained to arise only at higher resonance energies. Aromatic amino acids are characterized by an additional low-energy fragmentation channel associated with the generation of negative ions with loss of the side chain. The complementary negative ions of the side chains are more efficiently produced at higher energies. The results have significant implications in biological systems as they suggest that amino acids can serve as radiation protectors since they have been found to efficiently thermalize electrons.
As
the application of mass spectrometry intensifies in scope and
diversity, the need for advanced instrumentation addressing a wide
variety of analytical needs also increases. To this end, many modern,
top-end mass spectrometers are designed or modified to include a wider
range of fragmentation technologies, for example, ECD, ETD, EThcD,
and UVPD. Still, the majority of instrument platforms are limited
to more conventional methods, such as CID and HCD. While these latter
methods have performed well, the less conventional fragmentation methods
have been shown to lead to increased information in many applications
including middle-down proteomics, top-down proteomics, glycoproteomics,
and disulfide bond mapping. We describe the modification of the popular
Q Exactive Orbitrap mass spectrometer to extend its fragmentation
capabilities to include ECD. We show that this modification allows
≥85% matched ion intensity to originate from ECD fragment ion
types as well as provides high sequence coverage (≥60%) of
intact proteins and high fragment identification rates with ∼70%
of ion signals matched. Finally, the ECD implementation promotes selective
disulfide bond dissociation, facilitating the identification of disulfide-linked
peptide conjugates. Collectively, this modification extends the capabilities
of the Q Exactive Orbitrap mass spectrometer to a range of new applications.
Bacteria Vibrio sp. isolated from the sponge Dysidea sp. were shown to biosynthesize brominated diphenyl ethers. We identified one of the bacterial brominated metabolites, using gas liquid chromatography and mass spectrometry to compare this product with standard 3,5-dibromo-2-(3',5'-dibromo-2'-methoxyphenoxy)phenol. The latter has been isolated from ethanol extracts of the sponge Dysidea sp.
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