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Characterization of cysteinylation of pharmaceutical‐grade human serum albumin by electrospray ionization mass spectrometry and low‐energy collision‐induced dissociation tandem mass spectrometry
Author(s) -
Kleinova Martina,
Belgacem Omar,
Pock Katharina,
Rizzi Andreas,
Buchacher Andrea,
Allmaier Günter
Publication year - 2005
Publication title -
rapid communications in mass spectrometry
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.528
H-Index - 136
eISSN - 1097-0231
pISSN - 0951-4198
DOI - 10.1002/rcm.2154
Subject(s) - chemistry , human serum albumin , electrospray ionization , mass spectrometry , chromatography , analytical chemistry (journal) , tandem mass spectrometry , collision induced dissociation , mass spectrum , ionization , ion , protein mass spectrometry , organic chemistry
Abstract Three samples of albumin derived from human plasma (pharmaceutical grade, HSA) obtained from different commercial sources were investigated for their micro‐heterogeneities by means of electrospray ionization (ESI) ion trap mass spectrometry (ITMS). The study covered MS analyses of the intact proteins as well as on the tryptic peptide level. The intact protein samples were analyzed without any separation step except for simple desalting. With these samples we observed in the positive ion ESI mass spectra that the multiply charged ion signals of HSA consisted of a number of fully or partly resolved peaks with relative intensities depending on the analyzed sample. The non‐modified form of HSA was detected in the three HSA preparations at m/z values of 66448 ± 3.6, 66450 ± 0.6 and 66451 ± 3.2 ([MH] + ), respectively. The value calculated from the amino acid sequence was 66439. The second compound present with high intensity (in two cases the base peak in the deconvoluted mass spectrum) is interpreted as a modified HSA, and the molecular mass increase in relation to the unmodified HAS was between 116 and 118 Da ( m/z of 66 564, 66 567 and 66 569), suggesting the presence of a covalently bound cysteine residue. A further peak in the deconvoluted ESI spectra was found in all three samples with rather low signal/noise ratio at m/z 66 619, 66 621 and 66 613, respectively, which may correspond to a non‐enzymatic glycation described in the literature. The verification of the proposed covalent HSA modifications was subsequently done on the peptide level using high‐performance liquid chromatography (HPLC)/ESI‐MS and HPLC/ESI‐MS/MS including low‐energy collision‐induced dissociation (CID). Prior to the tryptic digestion, the HSA samples were alkylated without a prior reduction step. Following this procedure we detected peptides of the sequence T21‐41 that included the Cys‐34 residue in both forms: cysteinylated ( m/z 639.15 [M+4H] 4+ ) as well as vinylpyridine‐alkylated ( m/z 635.69 [M+4H] 4+ , which means in its previously native free SH form). In the next step on‐line LC/ESI low‐energy CID MS/MS experiments were performed to verify these two proposed structures. By means of MS/MS analysis of the mentioned ions the described modification (cysteinylation) at the Cys‐34 residue could be proven. This abundant modification of HSA in pharmaceutical‐grade preparations could be unambiguously identified as cysteinylation at the Cys‐34 residue. On the other hand, the proposed non‐enzymatic glycation was not detectable on the peptide level in the on‐line HPLC/ESI‐MS mode, maybe due to the low concentration in the three samples under investigation. Copyright © 2005 John Wiley & Sons, Ltd.