Early detection of prostate cancer may lead to the overdiagnosis and overtreatment of patients as well as missing significant cancers. The current diagnostic approach uses elevated serum... Show moreEarly detection of prostate cancer may lead to the overdiagnosis and overtreatment of patients as well as missing significant cancers. The current diagnostic approach uses elevated serum concentrations of prostate-specific antigen (PSA) as an indicator of risk. However, this test has been widely criticized as it shows poor specificity and sensitivity. In order to improve early detection and diagnosis, several studies have investigated whether different PSA proteoforms are correlated to prostate cancer. Until now, studies and methodologies for the comprehensive characterization of PSA proteoforms from biofluids are scarce. For this purpose, we developed an intact protein assay to analyze PSA by capillary electrophoresis-electrospray ionization-mass spectrometry after affinity purification from patients? urine. Here, we determined six proteolytic cleavage variants. In regard to glycosylation, tri-, di-, mono- and non-sialylated complex-type N-glycans were found on non-cleaved PSA, as well as the non-glycosylated variant. The performance of the intact protein assay was assessed using a pooled sample, obtaining an inter-day variability of 15%. Furthermore, urinary patient samples were analyzed by intact protein analysis and a bottom-up approach (glycopeptide analysis). This combined approach revealed complimentary information on both levels, demonstrating the benefit of using two orthogonal techniques to provide a thorough profile of urinary PSA.Significance: The detection of clinically relevant prostate cancer requires a more specific and sensitive biomarker and, in this case, several PSA proteoforms may be able to aid or improve the current PSA test. However, a comprehensive analysis of the intact PSA proteoform profile is still lacking. This study investigated the PSA proteoforms present in urine and, in particular, determined the relative contribution of cleaved PSA and noncleaved PSA forms to the total glycosylation profile. Importantly, intact protein analysis did not require further sample treatment before being measured by CE-ESI-MS. Furthermore, its glycosylation was also assessed in a bottom-up approach to provide complementary information. Overall, these results represent an important basis for future characterization and biomarker studies. Show less
Gstottner, C.; Nicolardi, S.; Haberger, M.; Reusch, D.; Wuhrer, M.; Dominguez Vega, E. 2020
Bispecific antibodies (BsAb) are next-generation, antibody-based pharmaceuticals which come with a great functional versatility and often a vast structural heterogeneity. Although engineering of... Show moreBispecific antibodies (BsAb) are next-generation, antibody-based pharmaceuticals which come with a great functional versatility and often a vast structural heterogeneity. Although engineering of the primary sequence of BsAbs guides the proper pairing of the different chains, several side products can often be observed contributing to the macroheterogeneity of these products. Furthermore, changes in the amino acid sequence can result in different protein modifications which can affect the properties of the antibody and further increase the structural complexity. A multi-methods approach can be used for the characterization of their heterogeneity but new analytical strategies are needed for a more accurate and in-depth analysis.Here, we present a combination of intact antibody and subunit-specific mass measurements using sheathless capillary electrophoresis-mass spectrometry for assessing the macro- and microheterogeneity of BsAbs. Two homologous BsAbs with the same bispecificity but slightly different amino acid sequences were analyzed. Intact measurements were performed using a positively coated capillary and a background electrolyte (BGE) consisting of 3% acetic acid. For intact BsAbs, the separation permitted the characterization of free light chains, homo- and heterodimers as well as incomplete assemblies. For subunit-specific measurements, BsAbs were hinge region cleaved using two different enzymes (SpeB and IdeS) followed by disulfide-bond reduction. The six different subunits (Lc1, Lc2, Fd'1, Fd'2, (Fc/2)1 and (Fc/2)2) were separated using the same positively-coated capillary and a BGE consisting of 20% acetic acid and 10% methanol. Mass measurements of hinge region cleaved antibodies were performed at isotopic resolution (resolving power 140000 at m/z 1100) for a more confident analysis of low abundance proteoforms. For both BsAbs several proteoforms with e.g. pyroglutamic acid (Pyro-Glu) or glycation which could not be properly assigned at the intact level, were accurately determined in the subunits showing the complementarity of both approaches. (C) 2020 Elsevier B.V. All rights reserved. Show less
Gstottner, C.; Vergoossen, D.L.E.; Wuhrer, M.; Huijbers, M.G.M.; Dominguez Vega, E. 2020
Bispecific monoclonal antibodies (BsAbs) are receiving great attention due to their extensive benefits as biopharmaceuticals and their involvement in IgG4 mediated autoimmune diseases. While the... Show moreBispecific monoclonal antibodies (BsAbs) are receiving great attention due to their extensive benefits as biopharmaceuticals and their involvement in IgG4 mediated autoimmune diseases. While the production of BsAbs is getting more accessible, their analytical characterization remains challenging. We explored the potential of sheathless CE-MS for monitoring exchange efficiency and stability of in-house produced bispecific antibodies. Two IgG4 bispecific antibodies with different molecular characteristics were prepared using controlled Fragment antigen binding (Fab)-arm exchange. Separation of BsAbs from their parent monospecific antibodies was achieved using a polyethyleniimine (PEI)-coated capillary and acidic background electrolytes permitting reliable assessment of the exchange efficiency. This was especially valuable for a Fab-glycosylated BsAb where the high glycan heterogeneity resulted in an overlap of masses with the monospecific parent antibody, hindering their discrimination by MS only. The method showed also good capabilities to monitor the stability of the generated BsAbs under different storage conditions. The levels of degradation products were different for the studied antibodies indicating pronounced differences in stability. Overall, the proposed method represents a useful analytical tool for exchange efficiency and stability studies of bispecific antibodies. Show less
Gargano, A.F.G.; Schouten, O.; Schaick, G. van; Roca, L.S.; Berg-Verleg, J.H. van den; Haselberg, R.; ... ; Somsen, G.W. 2020
Many industrial enzymes exhibit macro- and micro-heterogeneity due to co-occurring post-translational modifications. The resulting proteoforms may have different activity and stability and,... Show moreMany industrial enzymes exhibit macro- and micro-heterogeneity due to co-occurring post-translational modifications. The resulting proteoforms may have different activity and stability and, therefore, the characterization of their distributions is of interest in the development and monitoring of enzyme products. Protein glycosylation may play a critical role as it can influence the expression, physical and biochemical properties of an enzyme.We report the use of hydrophilic interaction liquid chromatography-mass spectrometry (HILIC-MS) to profile intact glycoform distributions of high mannose-type N-glycosylated proteins, using an industrially produced fungal lipase for the food industry as an example. We compared these results with conventional reversed phase LC-MS (RPLC-MS) and sodium dodecyl sulfate-polyacrylamide gel-electrophoresis (SDS-PAGE). HILIC appeared superior in resolving lipase heterogeneity, facilitating mass assignment of N-glycoforms and sequence variants. In order to understand the glycoform selectivity provided by HILIC, fractions from the four main HILIC elution bands for lipase were taken and subjected to SDS-PAGE and bottom-up proteomic analysis. These analyses enabled the identification of the most abundant glycosylation sites present in each fraction and corroborated the capacity of HILIC to separate protein glycoforms based on the number of glycosylation sites occupied.Compared to RPLC-MS, HILIC-MS reducted the sample complexity delivered to the mass spectrometer, facilitating the assignment of the masses of glycoforms and sequence variants as well as increasing the number of glycoforms detected (69 more proteoforms, 177% increase). The HILIC-MS method required relatively short analysis time (<30 min), in which over 100 glycoforms were distinguished.We suggest that HILIC(-MS) can be a valuable tool in characterizing bioengineering processes aimed at steering protein glycoform expression as well as to check the consistency of product batches. (C) 2020 Elsevier B.V. All rights reserved. Show less
Haselberg, R.; Vijlder, T. de; Heukers, R.; Smit, M.J.; Romijn, E.P.; Somsen, G.W.; Dominguez-Vega, E. 2018
Antibody-based pharmaceuticals often encompass a complex structural heterogeneity requiring enhanced analytical methods for reliable characterization of variants and degradation products. We have... Show moreAntibody-based pharmaceuticals often encompass a complex structural heterogeneity requiring enhanced analytical methods for reliable characterization of variants and degradation products. We have explored the capabilities of low-flow sheathless capillary electrophoresis-mass spectrometry (CE-MS) for the high-resolution and sensitive profiling of antibody therapeutics. Near-zero electroosmotic flow was achieved by employing a novel neutral capillary coating that also prevents protein adsorption. CE-MS analysis of intact model proteins using an acidic background electrolyte demonstrated satisfactory performance, with overall migration-time RSDs below 2.2% from three different capillaries tested. For system evaluation, three nanobody preparations, including mono- and bivalent forms, and three monoclonal antibodies (mAbs) were analyzed. Intact nanobodies were resolved from their degradation products, which could be assigned to deamidated, cleaved, and truncated forms at the C-terminal tag. Excellent resolution of isomeric deamidated products was obtained. The mAbs were analyzed intact and after digestion by the endoproteinase IdeS (middle-up approach). CE-MS of intact mAbs provided resolution of clipped species (e.g. light chain and light chain-heavy chain fragments) from the native protein. Moreover, glycoforms containing sialic acids were resolved from their non-sialylated counterparts. For IdeS-digested, F (ab)(2) and Fc/2 portions where efficiently resolved for the three mAbs. Whereas the migration time of the Fc/2 fragments was fairly similar, the migration time of the F (ab)(2) part was strongly varied among the mAbs. For all mAbs, separation of Fc/2 charge variants - including sialylated glycoforms and other post-translational modifications, such as loss of C-terminal lysine or asparagine deamidation - was achieved. This allowed a detailed and reliable assessment of the Fc/2 heterogeneity (18-33 proteoforms) of the three analyzed mAbs. (C) 2018 The Authors. Published by Elsevier B.V. Show less