Screening for Transglutaminase-Catalyzed Modifications by Peptide Mass Finger Printing Using Multipoint Recalibration on Recognized Peaks for High Mass Accuracy

Detection of posttranslational modifications is expected to be one of the major future experimental challenges for proteomics. We describe herein a mass spectrometric procedure to screen for protein modifications by peptide mass fingerprinting that is based on post-data acquisition improvement of the mass accuracy by exporting the peptide mass values into analytical software for multipoint recalibration on recognized peaks. Subsequently, the calibrated peak mass data set is used in searching for modified peptides, i.e., peptides possessing specific mass deviations. In order to identify the location of Lys- and Gln-residues available for transglutaminase-catalyzed isopeptide bond formation, mammalian small heat shock proteins (sHsps) were screened for labeling with the two hexapeptide probes GQDPVR and GNDPVK in presence of transglutaminase. Peptide modification due to cross-linking of the GQDPVR hexa-peptide probe was detected for C-terminal Lys residues. Novel transglutaminase-susceptible Gln sites were identified in two sHsps (Q31/Q27 in Hsp20 and HspB2, respectively), by cross-linking of the GNDPVK hexapeptide probe. Deamidation of specific Gln residues was also detected, as well an isopeptide derived from intramolecular Gln-Lys isopeptide bond formation. We conclude that peptide mass fingerprinting can be an efficient way of screening for various posttranslational modifications. Basically any instrumentation for MALDI mass spectrometry can be used, provided that post-data acquisition recalibration is applied

Chemical cross-linking of the chloroplast localized small heat-shock protein, Hsp21, and the model substrate citrate synthase

The molecular mechanism whereby the small heat-shock protein (sHsp) chaperones interact with and prevent aggregation of other proteins is not fully understood. We have characterized the sHsp–substrate protein interaction at normal and increased temperatures utilizing a model substrate protein, citrate synthase (CS), widely used in chaperone assays, and a dodecameric plant sHsp, Hsp21, by chemical cross-linking with 3,3′-Dithiobis[sulfosuccinimidylpropionate] (DTSSP) and mass spectrometric peptide mapping. In the absence of CS, the cross-linker captured Hsp21 in dodecameric form, even at increased temperature (47°C). In the presence of equimolar amounts of CS, no Hsp21 dodecamer was captured, indicating a substrate-induced Hsp21 dodecamer dissociation by equimolar amounts of CS. Cross-linked Hsp21–Hsp21 dipeptides indicated an exposure of the Hsp21 C-terminal tails and substrate-binding sites normally covered by the C terminus. Cross-linked Hsp21–CS dipeptides mapped to several sites on the surface of the CS dimer, indicating that there are numerous weak and short-lived interactions between Hsp21 and CS, even at normal temperatures. The N-terminal arms especially interacted with a motif in the CS dimer, which is absent in thermostable forms of CS. The cross-linking data suggest that the presence of substrate rather than temperature influences the conformation of Hsp21

Small heat shock proteins prevent aggregation of citrate synthase and bind to the N-terminal region which is absent in thermostable forms of citrate synthase

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