posted on 2012-03-02, 00:00authored byThomas Jakoby, Bart HJ van den
Berg, Andreas Tholey
Knowledge of cleavage site specificity and activity are
major prerequisites
for understanding protease function. On the basis of a recently presented
approach for proteomic identification of cleavage sites (PICS) in
proteome-derived peptide libraries, we developed an isobaric labeling
quantitative LC–MALDI-TOF/TOF MS/MS approach (Q-PICS) for simultaneous
determination of cleavage site specificity and robust relative quantification
of proteolytic events. For GluC-protease, 737 cleavage sites were
identified in a yeast proteome-derived peptide library; 94.0% showed
the typical GluC specificity for peptide bonds at glutamyl and aspartyl
residues. The six-plex tandem mass tagging strategy allowed for three
simultaneous replicates in a single run, guaranteeing high confidence
and robust statistics for quantitative measurements. Using the quantitative
capacity of Q-PICS, we performed a comparison of cleavage site specificity
of GluC in two different buffer systems. The results support earlier
findings describing that apparent difference between the buffer systems
are probably caused by the inhibitory effect of bicarbonate on the
overall GluC activity and that the preference for Glu-X bonds compared
to Asp-X bonds is independent of the buffer system used.