Project description:Glycoprotein is one of the most complex biomacromolecule，accounting for over 50% of total human proteins and the majority of biopharmaceuticals, exerting profound influences on various essential biological processes. With multiple N-glycosylation sites and O- glycosylation sites on the protein backbone, decoding of unknown glycoprotein is very challenging due to the inherent variability and bias on the detectability of the glycopeptides, leading to incomplete coverage of certain backbone regions and ambiguous identification of glycan modifications. Here, we demonstrated an integrative approach for decoding glycoprotein, which is featured with combination of deglycosylation-mediated de novo sequencing with glycosylation site characterization. We utilized enzymatic deglycosylation for N-/ O- glycan to achieve complete sequence coverage, as well as EThcD fragmentation enabling the identification of high-quality long peptides to facilitate the precise protein assembly. We subsequently applied this method to de novo sequencing of Etanercept, a highly glycosylated therapeutic recombinant TNFR: Fc-fusion protein, and three new TNFR: Fc-fusion biologics whose sequence were largely unknown, unveiling subtle distinctions in the primary sequences. Finally, the N-/ O-glycosylation modifications of these proteins were characterized at different levels—subunit, glycopeptide, and glycan. We believe that this strategy bridges the gap between the de novo sequencing and glycosylation modification, providing the complete information of the primary structure and glycosylation modifications for glycoproteins. Notably, our method could be a robust solution for accurate sequencing the glycoproteins and has practical value in biopharmaceutical industry.

Project description:Elucidating antibody sequences is crucial for understanding antigen binding and advancing therapeutic and research applications. However, current de novo sequencing technology is hindered by high costs, low throughput, missing ion information, and assembly limitations in accuracy and robustness. Here, we developed a refined sequencing solution by integrating Single-Pot Multi-Enzymatic Gradient Digestion (SP-MEGD) with a beam search-based assembler (Fusion) to decipher complete sequences. This solution achieved high accuracy (over 99%) in antibody reconstruction. Biological validation of multiple commercial antibodies with unavailable sequences further supports its effectiveness. Additionally, our solution can discriminate and achieve over 99% accurate sequence coverage of mixtures containing two or three COVID-19 neutralizing antibodies. To our knowledge, this is the first study to enable simultaneous sequencing of multiple antibodies using only bottom-up mass spectrometry, improving throughput without increasing duration or expense. In summary, our method advances antibody research by enhancing the accuracy and efficiency of complex antibody sequencing.

Project description:In multiple myeloma diseases, monoclonal immunoglobulin light chains (LCs) are abundantly produced, with as a consequence in some cases the formation of deposits affecting various organs, such as kidney, while in other cases to remain soluble up to concentrations of several g.L-1 in plasma. The exact factors crucial for the solubility of light chains are poorly understood, but it can be hypothesized that their amino acid sequence plays an important role. Determining the precise sequences of patient-derived light chains is therefore highly desirable. We establish here a novel de novo sequencing workflow for patient-derived LCs, based on the combination of bottom-up and top-down proteomics without database search. PEAKS is used for the de novo sequencing of peptides that are further assembled into full length LC sequences using ALPS. Top-down proteomics provides the molecular masses of proteoforms and allows the exact determination of the amino acid sequence including all post translational modifications. This pipeline is then used for the complete de novo sequencing of LCs extracted from the urine of 10 patients with multiple myeloma. We show that for the bottom-up part, digestions with trypsin and Nepenthes digestive fluid are sufficient to produce overlapping peptides able to generate the best sequence candidates. Top-down proteomics is absolutely required to achieve 100% final sequence coverage and characterize clinical samples containing several LCs . Our work highlights an unexpected range of modifications.

Project description:Dependent on concise, pre-defined protein sequence databases, traditional search algorithms perform poorly when analyzing mass spectra derived from wholly uncharacterized protein products. Conversely, de novo peptide sequencing algorithms can interpret mass spectra without relying on reference databases. However, such algorithms have been difficult to apply to complex protein mixtures, in part due to a lack of methods for automatically validating de novo sequencing results. Here, we present novel metrics for benchmarking de novo sequencing algorithm performance on large scale proteomics datasets, and present a method for accurately calibrating false discovery rates on de novo results. We also present a novel algorithm (LADS) which leverages experimentally disambiguated fragmentation spectra to boost sequencing accuracy and sensitivity. LADS improves sequencing accuracy on longer peptides relative to other algorithms and improves discriminability of correct and incorrect sequences. Using these advancements, we demonstrate accurate de novo identification of peptide sequences not identifiable using database search-based approaches.

Project description:Shotgun protein sequencing with meta-contig assembly. Full-length de novo sequencing from tandem mass (MS/MS) spectra of unknown proteins such as antibodies or proteins from organisms with unsequenced genomes remains a challenging open problem. Conventional algorithms designed to individually sequence each MS/MS spectrum are limited by incomplete peptide fragmentation or low signal to noise ratios and tend to result in short de novo sequences at low sequencing accuracy. Our shotgun protein sequencing (SPS) approach was developed to ameliorate these limitations by first finding groups of unidentified spectra from the same peptides (contigs) and then deriving a consensus de novo sequence for each assembled set of spectra (contig sequences). But whereas SPS enables much more accurate reconstruction of de novo sequences longer than can be recovered from individual MS/MS spectra, it still requires error-tolerant matching to homologous proteins to group smaller contig sequences into full-length protein sequences, thus limiting its effectiveness on sequences from poorly annotated proteins. Using low and high resolution CID and high resolution HCD MS/MS spectra, we address this limitation with a Meta-SPS algorithm designed to overlap and further assemble SPS contigs into Meta-SPS de novo contig sequences extending as long as 100 amino acids at over 97% accuracy without requiring any knowledge of homologous protein sequences. We demonstrate Meta-SPS using distinct MS/MS data sets obtained with separate enzymatic digestions and discuss how the remaining de novo sequencing limitations relate to MS/MS acquisition settings.

Project description:We demonstrate a method for direct de novo sequencing of monoclonal IgG from the purified antibody products. The method uses a panel of multiple complementary proteases to generate suitable peptides for de novo sequencing by LC-MS/MS in a bottom-up fashion. Furthermore, we apply a dual fragmentation scheme, using both stepped high-energy collision dissociation (stepped HCD) and electron transfer high-energy collision dissociation (EThcD) on all peptide precursors. The method achieves full sequence coverage of the monoclonal antibody Herceptin, with an accuracy of 98% in the variable regions. We applied the method to sequence the widely used anti-FLAG-M2 mouse monoclonal antibody, which we successfully validated by remodeling a high-resolution crystal structure of the Fab and demonstrating binding to a FLAG-tagged target protein in Western blot analysis. The method thus offers robust and reliable sequences of monoclonal antibodies.

Project description:We describe a new strategy for LC-MS/MS based full length protein sequencing. Protein samples were unspecific hydrolyzed by three different methods(proteinase K, papain and microwave-assisted acid hydrolysis) to improve overlapping degree of peptides. After LC-MS/MS analysis, peptide sequences were gernated by de novo peptide sequencing program Pnovo. A new sequence assembly program, based on de brujin graph and Overlap-Layout-Consensus strategy, was desined to generate full length protein sequence using Pnovo results.

Project description:Protein glycosylation is a critical post-translational modification that plays vital roles in cellular function and disease, including infection, autoimmunity and cancer. Techniques that measure specific glycosylated proteins face challenges in sensitivity and throughput, preventing applications in single cells. We introduce Glycan Proximity Sequencing (GPS) for the integrated profiling of proteins, glycosylation and protein-specific glycoforms, as well as mRNA in single cells. GPS achieves affinity-based detection of proteins and their modifications via proximity-based single-cell RNA sequencing. Experiments using mixtures of T and B cells, together with a GnTI-knockout mutant, demonstrated sensitive detection of both global and protein-specific glycosylation differences. Applied to human peripheral blood mononuclear cells, GPS revealed dynamic glycan remodeling patterns during T cell differentiation and potential galectin-binding glycoproteins for modulating immune responses. Notably, we identified a new CD45:LELhigh subcluster of terminally differentiated effector memory CD8+ T cells that are enriched for poly-LacNAc and 2,3-sialylation modifications and associated with exhaustion and susceptibility to galectin-1–induced apoptosis. GPS also captured glycosylation changes in response to perturbations like sialidase treatment and T cell activation. GPS is a scalable and sensitive platform for single-cell glycoproteomics and protein-specific biomarker discovery, and it can reveal mechanistic insights on the role of glycosylation in T cell differentiation.

Project description:The characterization of therapeutic glycoproteins is challenging due to the structural micro- and macro-heterogeneity of the protein glycosylation. This study presents an in-depth strategy for glycosylation analysis using first-generation erythropoietin (epoetin beta), including a developed top-down mass spectrometric workflow for N-glycan analysis, bottom-up mass spectrometric methods for site-specific N-glycosylation and a LC-MS approach for O-glycan identi-fication. Permethylated N-glycans, peptides and enriched glycopeptides of erythropoietin were analyzed by nanoLC-MS/MS and de-N-glycosylated erythropoietin was measured by LC-MS, enabling the qualitative and quantitative analysis of glycosylation and different glycan modifications (e.g., phosphorylation and O-acetylation). Extending the coverage of our newly developed Python script to phosphorylated N-glycans enabled the identification of 140 N-glycan compositions (237 N-glycan structures) from erythropoietin. The site-specificity of N-glycans was revealed at glycopeptide level by pGlyco software using different proteases. In total, 215 N-glycan compositions were identified from N-glycan and glycopeptide analysis. Moreover, LC-MS analysis of de-N-glycosylated erythropoietin species identified two different O-glycan compositions, based on the mass shifts between non-O-glycosylated and O-glycosylated species. This integrated strategy allows the in-depth glycosylation analysis of a therapeutic glycoprotein to understand its pharmacological properties and improving the manufacturing processes.

Project description:In this study, we used electron-transfer/higher energy collision dissociation (EThcD) fragmentation to develop a mass-spectrometric (MS) method for distinguishing between Ile and Leu in Bovine Serum Albumin (BSA) and a SARS-CoV-1 anti-receptor binding domain (RBD) Spike monoclonal antibody (mAb). Supplemental activation normalized collision energy (SA-NCE) values were optimized. Combinations of multiple enzyme digestions, coupled with higher-energy collisional dissociation (HCD) and EThcD fragmentation, were used to increase coverage of all amino acid residues of the antibody. The data was searched with Supernovo™, which generated a complete de novo sequence for the test mAb and two additional SARS-CoV-2 human mAbs, giving correct sequences for the variable regions and selection between Ile and Leu residues. We then used the method on an additional set of twenty-five anti-hemagglutinin (HA) influenza antibodies of unknown sequence and determined high confidence sequences for >99% of the complementarity determining regions (CDRs). Importantly, the recombinant expression of these mAbs verified their binding and specificity to the HA influenza antigen. Unique glycosylation sites were also identified for eight antibodies. Our findings indicate this methodology results in almost complete antibody sequence coverage with >90% of residues determined with high confidence. Ile/Leu residues can be differentiated and glycosylation sites can be reliably identified.