Project description:Mass spectrometry is the premier tool for identifying and quantifying site-specific protein glycosylation globally. Analysis of intact glycopeptides often requires an enrichment step, after which the samples remain highly complex and exhibit a broad dynamic range of abundance. Here, we evaluated the analytical benefits of high-field asymmetric waveform ion mobility spectrometry (FAIMS) coupled to nano-liquid chromatography mass spectrometry (nLC-MS) for analyses of intact glycopeptide devoid of any enrichment step. We compared the effects of compensation voltage on the transmission of N- and O-glycopeptides derived from heterogeneous protein mixtures using two FAIMS devices. We comprehensively demonstrate the performance characteristics of the FAIMS device for glycopeptide analysis and recommend optimal electrode temperature and compensation voltage (CV) settings for N- and O-glycopeptide analysis. Under optimal CV settings, FAIMS-assisted gas-phase fractionation in conjunction with chromatographic reverse phase separation resulted in a 31% increase in the detection of both N- and O-glycopeptide compared to control experiments without FAIMS. Overall, our results demonstrate that FAIMS provides an alternative means to access glycopeptides without any enrichment providing an unbiased global glycoproteome landscape. In addition, our work provides the framework to verify ‘difficult-to-identify’ glycopeptide features.

Project description:NLC are generated from the in vitro culture of PBMC from CLL patients. These NLC derived from the differentiation of blood monocytes in contact with blood leukemic cells, We used microarrays to detail the global programme of NLC gene expression compared to monocytes gene expression.

Project description:The study of the roles of macrophages in the microenvironment of cancer cells (tumor-associated macrophages, TAM) has gained deep insight over the recent years. Here, we describe gene expression profile of chronic lymphocytic leukemia (CLL)-associated macrophages, also called nurse-like cells (NLC), derived from in vitro co-cultures system. We define these NLC as M2-oriented, TAM-like specific subset of macrophages, with very few inter-individual variations in gene expression profiles. CLL patients PBMC were isolated and cultured for 15 days in vitro. NLC were then isolated, mRNA were purified and hybridized on Affymetrix U133 plus 2.0 chips. Data were normalized by RMA5

Project description:Here we employ a nLC-MS/MS method to separate small amounts of purified immunoglobulins to characterize the N-glycan reportoire and site occupancy of bulk serum antibodies. Using this method, we have established, for the first time within individual donors, the N-linked glycan repotoire for bulk IgG1, IgG4, IgA1, IgA2 and IgM in healthy individuals. This is crucial for developing a platform to define disease-specific N-glycan signatures for different isotypes to help tune antibodes to induce protection.

Project description:The study of the roles of macrophages in the microenvironment of cancer cells (tumor-associated macrophages, TAM) has gained deep insight over the recent years. Here, we describe gene expression profile of chronic lymphocytic leukemia (CLL)-associated macrophages, also called nurse-like cells (NLC), derived from in vitro co-cultures system. We define these NLC as M2-oriented, TAM-like specific subset of macrophages, with very few inter-individual variations in gene expression profiles.

Project description:Glycosylation is an important post-translational modification characterized by extensive heterogeneity. While mass spectrometry (MS) is the premier technique to characterize glycoproteins, the study of intact glycopeptides presents challenges often not observed in the study of unmodified species. High-field asymmetric waveform ion mobility spectrometry (FAIMS) involves in-line gas-phase separation and offers the potential to analyze glycopeptides without prior enrichment. While FAIMS has been assessed for its use in glycoproteomics, most of these studies focus heavily or exclusively on N-glycoproteomics. Therefore, we evaluated FAIMS for O-glycoprotein and mucin analysis. We generated three samples: the mucin-domain glycoprotein podocalyxin, a recombinant glycoprotein mixture, and a WGA enriched human platelet sheddome. Although FAIMS allowed for the identification of new podocalyxin O-glycosites, it yielded less glycopeptide identifications and glycoforms. FAIMS seemed to be more useful in the increasingly complex samples, since we observed a higher number of identified glycosylated species. Because of the labile nature of glycosidic bonds, and presence of a buffer gas in FAIMS separation, we investigated the possibility of increased in-source fragmentation during FAIMS analysis. We compared total ion chromatograms of identifications eluting within a minute of identifications bearing larger glycan structures, albeit with the same peptide backbone. FAIMS experiments showed a 2-5-fold increase in spectral matches from in-FAIMS fragmentation compared to control experiments. These results were also replicated in other previously published data, indicating that this is a systematic behavior. In summary, our study highlights that, although there are potential benefits gained when using FAIMS separation, caution must be exercised when using FAIMS due to in-FAIMS fragmentation, which limits its applicability in the field of O-glycoproteomics.

Project description:Proteomic biomarker discovery using formalin-fixed paraffin-embedded (FFPE) tissue requires robust workflows to support the analysis of large cohorts of patient samples. It also requires finding a reasonable balance between achieving high proteomic depth and limiting overall analysis time. To this end, we evaluated the merits of online coupling of disposable trap column nano-flow liquid chromatography, high-field asymmetric-waveform ion-mobility spectrometry (FAIMS) and tandem mass spectrometry (nLC-FAIMS-MS/MS). The data shows that ≤ 600 ng of peptide digest should be loaded onto the chromatographic part of the system. Careful characterization of the FAIMS settings enabled the choice of optimal combinations of compensation voltages (CV) as a function of the employed LC gradient time. We found nLC-FAIMS-MS/MS to be on par with stage tip-based off-line high pH reversed phase fractionation in terms of proteomic depth and reproducibility of protein quantification (coefficient of variation ≤ 15% for 90 % of all proteins) but requiring 50% less sample and substantially reducing sample handling. Using FFPE material from lymph node, lung and prostate tissue as examples, we show that nLC-FAIMS-MS/MS can identify 5-6,000 proteins from the respective tissue within a total of 3 hours of analysis time.

Project description:Glomus sp. MS strain:MS Genome sequencing

Project description:Methanosarcina barkeri MS strain:MS Raw sequence reads

Project description:Hydrophilic Interaction Liquid Chromatography (HILIC) glycopeptide enrichment is an indispensable tool for the high-throughput characterisation of glycoproteomes. Despite its utility, HILIC enrichment is associated with a number of short comings including requiring large amounts of starting material, potentially introducing chemical artefacts such as formylation when high concentrations of formic acid are used, and biasing/under-sampling specific classes of glycopeptides. Here we investigate HILIC enrichment independent approaches for the study of bacterial glycoproteomes. Using three Burkholderia species (B. cenocepacia, B. dolosa and B. ubonensis) we demonstrate that short aliphatic O-linked glycopeptides are typically absent from HILIC enrichments yet are readily identified in whole proteome samples. Using high-field asymmetric waveform ion mobility spectrometry (FAIMS) fractionation we show that at high compensation voltages (CVs) short aliphatic glycopeptides can be enriched from complex samples providing an alternative means to identify glycopeptides recalcitrant to hydrophilic based enrichment. Combining whole proteome and FAIMS analysis we show that the observable glycoproteome of these Burkholderia species is at least 30% larger than initially thought. Excitingly, the ability to enrich glycopeptides using FAIMS appears generally applicable, with the N-linked glycopeptides of Campylobacter fetus subsp. fetus also enrichable at high FAIMS CVs. Taken together, these results demonstrate that FAIMS provides an alternative means to access glycopeptides and is a valuable tool for glycoproteomic analysis.