Top-down characterization of disulfide-rich peptides and proteins presents many challenges due to the constrained and protected amino acid backbone. Typically, chemical reduction is required to reduce the disulfide bonds and/or enzymatic digestion (bottom-up analysis) is utilized to selectively cleave the amino acid sequence prior to mass spectrometry analysis owing to the challenges associated with intact, top-down analysis of these biomolecules. While extravagant top-down characterization techniques such as ultraviolet photodissociation (UVPD) or electron capture dissociation (ECD), have demonstrated the ability to break disulfide bonds in top-down workflows, implementation of these technologies and analysis of the resulting fragmentation spectra is not trivial and often inaccessible to many laboratories and users. In the study presented herein, traditional collision induced dissociation (CID) of disulfide-rich peptides is performed to confirm the disulfide bond connectivity and localize chemical modifications for these synthetic therapeutic peptides. While collisional activation does not fragment the peptide backbone linearly (typical N- and C-terminal fragment ions) within the disulfide-bonded regions, internal and external ions are consistently produced throughout the sequence via secondary fragmentation pathways. In this study, seven disulfide-rich peptides (Peptides A - G) with similar disulfide connectivity but varying amino acid composition were subjected to collisional activation for sequencing and disulfide bond confirmation. While only four linear b- and y-type fragment ions are produced for these peptides, fragmentation throughout the amino acid sequence is observed when searching for internal and external fragment ions. These ions are typically not considered during traditional top-down sequencing experiments due to the computational challenge of having an increased search space for fragment ion identification. Through the identification of reproducible internal and external fragment ions, site-specific modifications can also be localized, such as oxidation on the 18th residue in Peptide A. Ultimately, this observation and identification of internal and external ions simplifies the experimental process and wet-chemistry required to accurately depict the disulfide connectivity and the sequencing of these traditionally challenging biomolecules. Further consideration to these non-traditional fragment ions should be given during top-down intact peptide and protein analysis, especially when non-linear sequences are involved.
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http://dx.doi.org/10.1016/j.jpba.2021.113893 | DOI Listing |
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