Application of sample displacement batch chromatography for fractionation of proteoforms.

Fractionation of proteoforms is currently the most challenging topic in the field of proteoform analysis. The need for considering the existence of proteoforms in experimental approaches is not only important in Life Science research in general but especially in the manufacturing of therapeutic proteins (TPs) like recombinant therapeutic antibodies (mAbs). Some of the proteoforms of TPs have significantly decreased actions or even cause side effects. The identification and removal of proteoforms differing from the main species, having the desired action, is challenging because the difference in the composition of atoms is often very small and their concentration in comparison to the main proteoform can be low. In this study, we demonstrate that sample displacement batch chromatography (SDBC) is an easy-to-handle, economical, and efficient method for fractionating proteoforms. As a model sample a commercial ovalbumin fraction was used, containing many ovalbumin proteoforms. The most promising parameters for the SDBC were determined by a screening approach and applied for a 10-segment fractionation of ovalbumin with cation exchange chromatography resins. Mass spectrometry of intact proteoforms was used for characterizing the SDBC fractionation process. By SDBC, a significant separation of different proteoforms was obtained.

Correlating Glycoforms of DC-SIGN with Stability Using a Combination of Enzymatic Digestion and Ion Mobility Mass Spectrometry.

The immune scavenger protein DC-SIGN interacts with glycosylated proteins and has a putative role in facilitating viral infection. How these recognition events take place with different viruses is not clear and the effects of glycosylation on the folding and stability of DC-SIGN have not been reported. Herein, we report the development and application of a mass-spectrometry-based approach to both uncover and characterise the effects of O-glycans on the stability of DC-SIGN. We first quantify the Core 1 and 2 O-glycan structures on the carbohydrate recognition and extracellular domains of the protein using sequential exoglycosidase sequencing. Using ion mobility mass spectrometry, we show how specific O-glycans, and/or single monosaccharide substitutions, alter both the overall collision cross section and the gas-phase stability of the DC-SIGN isoforms. We find that rather than the mass or length of glycoprotein modifications, the stability of DC-SIGN is better correlated with the number of glycosylation sites.

Universal Solid-Phase Protein Preparation (USP3) for Bottom-up and Top-down Proteomics.

Selecting a sample preparation strategy for mass spectrometry-based proteomics is critical to the success of quantitative workflows. Here we present a universal, solid-phase protein preparation (USP3) method which is rapid, robust, and scalable, facilitating high-throughput protein sample preparation for bottom-up and top-down mass spectrometry (MS) analysis. This technique builds upon the single-pot solid-phase-enhanced sample preparation (SP3) where we now demonstrate its scalability (low to high micrograms of protein) and the influence of variables such as bead and enzyme amounts on the efficiency of protein digestion. We also incorporate acid hydrolysis of DNA and RNA during complete proteome extraction resulting in a more reliable method that is simple and easy to implement for routine and high-throughput analysis of proteins. We benchmarked the performance of this technique against filter-aided sample preparation (FASP) using 30 µg of total HeLa protein lysate. We also show that the USP3 method is compatible with top-down MS where we reproducibly detect over 1800 proteoforms from 50 µg of HeLa protein lysate. The USP3 protocol allows for efficient and reproducible data to be generated in a cost-effective and robust manner with minimal down time between sample collection and analysis by MS.

Characterization and Detection of Erythropoietin Fc Fusion Proteins Using Liquid Chromatography-Mass Spectrometry.

Erythropoietin Fc (EPO-Fc) fusion proteins are potential drug candidates that have been designed for the treatment of anemia in humans by stimulating erythrocyte production. Such compounds can be considered performance-enhancing agents that may be used by athletes in endurance sports. This study describes the primary structure of commercially available EPO-Fc based on comprehensive liquid chromatography coupled with mass spectrometry (LC-MS) analysis. A bottom-up approach and the intact molecular weight (MW) measurement of deglycosylated protein and its IdeS proteolytic fractions was used to determine the amino acid sequence of EPO-Fc. Using multiple proteases, peptides covering unknown fusion breakpoints (spacer peptides) were identified. We demonstrated that "spacer peptides" can be used in the determination of EPO-Fc fusion proteins in biological samples using common LC-tandem MS methods.

Effect of altered solution conditions on tau conformational dynamics: Plausible implication on order propensity and aggregation.

Intrinsically disordered protein tau plays a central role in maintaining neuronal network by stabilizing microtubules in axon. Tau reportedly possesses random coil architecture, which is largely inert to alteration in solution conditions. However, the presence of transient compact conformers and residual structure has been evident from previous reports. Also, during Alzheimer's disease, misfolded tau detaches from microtubule and forms ordered filaments, which is the hallmark of the disease. Despite its fundamental role in neuronal physiology and in pathological cascade of several fatal neurodegenerative diseases, tau conformational dynamics remains poorly understood. In the present study, we have explored the effect of ionic strength, temperature and solvent polarity on tau40 conformational preferences using ion mobility mass spectrometry. Investigation of collision cross section revealed that while low ionic strength, elevated temperature and reduced solvent polarity mostly induced partial collapse in tau40 conformers, higher ionic strength led to an expansion of the molecule. Limited proteolysis identified segments of tau40 projection domain and proline-rich region having high order propensity and a C-terminal region having vulnerability for further expansion at altered solution conditions. The high susceptibility for disorder-to-order transition in the above region of the protein might have crucial implication on its role as microtubule spacers, and in cellular signaling cascade. The conformational adaptation of tau40 did not enhance the heparin-induced aggregation proclivity of the protein. Nevertheless, the observed correlation of electrostatic interaction with fibrillation propensity of tau40 might indicate plausible link between hyperphosphorylation at diseased state with tau conformation and self-assembly.

Characterization of Protein Glycoforms at Intact Level by Orbitrap Mass Spectrometry.

Intact mass analysis of proteins is simple, fast, and specific, and it effectively provides structural insight into the proteoforms or variants of the analyzed protein. For instance, the multiple glycoforms of recombinant monoclonal antibodies can be effectively analyzed by intact mass spectrometry (MS). A recent development in the Orbitrap technology has made this platform particularly well suited for analysis of large intact biomolecules, and here we describe procedures for performing intact mass analysis of intact glycoproteins using the Orbitrap platform, with the aim of identifying and quantitating the glycoforms. Emphasis is placed on the analysis of biopharmaceutical immunoglobulins (IgGs), but the procedures can be extended to other glycoproteins as needed.

Determination of Phosphohistidine Stoichiometry in Histidine Kinases by Intact Mass Spectrometry.

Protein histidine phosphorylation has largely remained unexplored due to the challenges of analyzing relatively unstable phosphohistidine-containing proteins. We describe a procedure for determining the stoichiometry of histidine phosphorylation on the human histidine kinases NME1 and NME2 by intact mass spectrometry under conditions that retain this acid-labile protein modification. By characterizing these two model histidine protein kinases in the absence and presence of a suitable phosphate donor, the stoichiometry of histidine phosphorylation can be determined. The described method can be readily adapted for the analysis of other proteins containing phosphohistidine.