On-MALDI-Target N-Glycan Nonreductive Amination by 2-Aminobenzoic Acid.

2-Aminobenzoic acid (2-AA) is widely used as a labeling reagent to derivatize released N-glycans at their free reducing terminus by reductive amination. 2-AA-labeled glycans have increased mass spectrometric sensitivity for their identification and enable fluorescence-chromatography-based glycan quantification. Drawbacks are that the labeling process is labor intensive and time consuming. Clean up of labeled glycans via removal of excess of labeling reagents often leads to sample losses. Here, we report use of 2-AA for labeling N-glycans on a MALDI target through nonreductive amination, while simultaneously functioning as a matrix in MALDI-MS glycan analysis. Coupling 2-AA to glycans results in significant increases of glycan anionic signals as compared to that using the traditional 2,5-dihydroxybenzoic acid (2,5-DHB) matrix. The on-MALDI-target sample preparation is a single-step protocol with high derivatization efficiency. It is also noticed that 2-AA-labeled glycan generated dominant deprotonated molecular anions with much fewer and low-intensity sodium adducts and therefore greatly simplified glycan profiles. We further explored its application in the N-glycan profile of a biotherapeutic monoclonal antibody and was able to achieve sensitive glycan identification at a low microgram level of glycoprotein. This 2-AA on-MALDI-target glycan derivatization eliminates tedious sample preparation and avoids sample loss. It is generally applicable for other applications (e.g., glycomics), where limited amounts of glycoproteins are available for analysis.

Defining Changes in the Spatial Distribution and Composition of Brain Lipids in the Shiverer and Cuprizone Mouse Models of Myelin Disease.

Myelin is composed primarily of lipids and diseases affecting myelin are associated with alterations in its lipid composition. However, correlation of the spatial (in situ) distribution of lipids with the disease-associated compositional and morphological changes is not well defined. Herein we applied high resolution matrix-assisted laser desorption ionization imaging mass spectrometry (MALDI-IMS), immunohistochemistry (IHC), and liquid chromatography-electrospray ionization-mass spectrometry (LC-ESI-MS) to evaluate brain lipid alterations in the dysmyelinating shiverer (Shi) mouse and cuprizone (Cz) mouse model of reversible demyelination. MALDI-IMS revealed a decrease in the spatial distribution of sulfatide (SHexCer) species, SHexCer (d42:2), and a phosphatidylcholine (PC) species, PC (36:1), in white matter regions like corpus callosum (CC) both in the Shi mouse and Cz mouse model. Changes in these lipid species were restored albeit not entirely upon spontaneous remyelination after demyelination in the Cz mouse model. Lipid distribution changes correlated with the local morphological changes as confirmed by IHC. LC-ESI-MS analyses of CC extracts confirmed the MALDI-IMS derived reductions in SHexCer and PC species. These findings highlight the role of SHexCer and PC in preserving the normal myelin architecture and our experimental approaches provide a morphological basis to define lipid abnormalities relevant to myelin diseases.

Discovery and investigation of O-xylosylation in engineered proteins containing a (GGGGS)n linker.

Protein engineering is a powerful tool for designing or modifying therapeutic proteins for enhanced efficacy, greater safety, reduced immunogenicity, and better delivery. GGGGS [(G4S)n] linkers are commonly used when engineering a protein, because of their flexibility and resistance to proteases. However, post-translational modifications (PTMs) can occur at the Ser residue in these linkers. Here, we report, for the first time, the occurrence of O-xylosylation at the serine residue in (G4S)n>2 linkers. The O-xylosylation was discovered as a result of molecular mass determination, peptide mapping analysis, and MS/MS sequencing. Our investigation showed that (i) O-xylosylation is a common PTM for (G4S)(n>2) linkers; (ii) GSG is the motif for O-xylosylation; and (iii) the total amount of xylosylation per linker increases as the number of GSG motifs in the linker increases. Our investigation has also shown that the O-xylosylation level is clone-dependent, to a certain degree, but the xylosylation level varies considerably among the proteins examined-from <2% to >25% per linker-likely depending on the accessibility to the sites by the xylosyltransferase. Our work demonstrates that potential therapeutic proteins containing (G4S)n linkers should be closely monitored for O-xylosylation in order to ensure that drugs are homogeneous and of high quality. The strategies for elimination and reduction of O-xylosylation were also examined and are discussed.