The presence of a single D-amino acid in a peptide is very difficult to detect. Mass spectrometry-based approaches rely on differences in fragmentation between all L-amino acid-containing peptides and single D-amino acid-containing peptides (which are epimers) for identification. The success of this approach is dependent on the structural sensitivity of the fragmentation method. Recently, experiments have demonstrated that fragmentation initiated by radical chemistry, or radical-directed dissociation (RDD), is particularly sensitive to the structure of the ion being fragmented. Herein, RDD is used to identify the presence of D-serine, D-alanine, or D-aspartic acid in eight biologically relevant peptides. It is demonstrated that chiral disambiguation by RDD is dependent on both the initial radical site and subsequent radical migration. Fortuitously, RDD can be initiated by a variety of different radical precursors which can be associated with the peptide via covalent or noncovalent means, and RDD can be examined in all observable charge states (both positive and negative). This diversity enables numerous initial radical sites and migration pathways to be explored. For all but one of the peptides that were examined, RDD provides significantly better chiral discrimination than CID. Quantitation of peptide epimers by RDD is also described.
Post-translational modifications that do not result in a change in mass are particularly difficult to detect by mass spectrometry. For example, isomerization of aspartic acid or epimerization of any chiral residue within a peptide do not lead to mass shifts but can be identified by examination of independently acquired tandem mass spectra or by combination with another technique. For analysis of a biological sample, this means that liquid chromatography or some other type of separation must be used to first separate the isomers from one another. Furthermore, each specific m/z of interest must be sampled repeatedly to allow for comparison of the tandem mass spectra from each separated isomer, which contrasts with the traditional approach in proteomics where the goal is typically to avoid resampling the same m/z. We illustrate that isomerization and epimerization of peptides can be identified in this fashion by examination of long-lived crystallin proteins extracted from a sheep eye lens. Tandem mass spectrometry relying on a combination of radical directed dissociation (RDD) and collision induced dissociation (CID) following separation by liquid chromatography was used to identify modified peptides. Numerous sites of isomerization and epimerization, including several that have not been previously identified, were determined with peptide specificity. It is demonstrated that the specific sites of amino acid isomerization within each peptide can be identified by comparison with synthetic peptides. For α-crystallin proteins, the sites that undergo the greatest degree of isomerization correspond to disordered regions, which may have important implications on chaperone functionality within the context of aging.
Novel p-iodobenzoate-based labelling reagents are shown to be effective photocaged precursors for synthesizing biomolecular radicals site-selectively in the gaseous and condensed phases. In vacuo, a single pulse of UV photons (266 nm) is sufficient to quantitatively photolyse the C-I bond. In aqueous solutions, the photolysis half-life is estimated to be 2.5 minutes when irradiating with a 15 W compact fluorescent lamp (254 nm).
Structural investigations of large biomolecules in the gas phase are challenging. Herein, it is reported that action spectroscopy taking advantage of facile carbon-iodine bond dissociation can be used to examine the structures of large molecules, including whole proteins. Iodotyrosine serves as the active chromophore, which yields distinctive spectra depending on the solvation of the side chain by the remainder of the molecule. Isolation of the chromophore yields a double featured peak at 290 nm, which becomes a single peak with increasing solvation. Deprotonation of the side chain also leads to reduced apparent intensity and broadening of the action spectrum. The method can be successfully applied to both negatively and positively charged ions in various charge states, although electron detachment becomes a competitive channel for multiply charged anions. In all other cases, loss of iodine is by far the dominant channel which leads to high sensitivity and simple data analysis. The action spectra for iodotyrosine, the iodinated peptides KGYDAKA, DAYLDAG, and the small protein ubiquitin are reported in various charge states. * to whom correspondence should be addressed: ryan.julian@ucr.edu, adamt@uow.edu.au RECEIVED DATE (to be automatically inserted after your manuscript is accepted if required according to the journal that you are submitting your paper to) 2 Abstract. Structural investigations of large biomolecules in the gas phase are challenging. Herein, it is reported that action spectroscopy taking advantage of facile carbon-iodine bond dissociation can be used to examine the structures of large molecules, including whole proteins. Iodotyrosine serves as the active chromophore, which yields distinctive spectra depending on the solvation of the side chain by the remainder of the molecule. Isolation of the chromophore yields a double featured peak at ~290 nm, which becomes a single peak with increasing solvation. Deprotonation of the side chain also leads to reduced apparent intensity and broadening of the action spectrum. The method can be successfully applied to both negatively and positively charged ions in various charge states, although electron detachment becomes a competitive channel for multiply charged anions. In all other cases, loss of iodine is by far the dominant channel which leads to high sensitivity and simple data analysis. The action spectra for iodotyrosine, the iodinated peptides KGYDAKA, DAYLDAG, and the small protein ubiquitin are reported in various charge states.
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