Proteins were digested in normal and highly 18O-enriched water using proteases commonly employed for protein sequencing. The extent of 18O incorporation into the resulting peptide fragments was characterized by electrospray ionization (ESI) and matrix-assisted laser desorption/ionization (MALDI) mass spectrometry (MS). The endoproteinases trypsin, Lys-C and Glu-C incorporate two atoms of 18O, resulting in a mass shift of +4 D for the peptide fragments. This indicates that, following proteolytic cleavage, peptide products continue to interact with these proteases and undergo repeated binding/hydrolysis cycles, resulting in complete equilibration of both oxygens in the carboxy terminus of the fragments with oxygen from solvent water. In contrast, chymotrypsin and Asp-N incorporate only one atom of 18O, resulting in a mass shift of +2 D, indicating that after the cleavage step these proteases do not accept the peptides as substrates. In addition, it was found that the proteases trypsin, Glu-C, and Lys-C exhibit minor or nontypical sequence specificities, resulting in unexpected peptide fragments. These fragments incorporate only one 18O atom, indicating that they do not undergo further binding/hydrolysis cycles with the enzyme. Thus, it is possible to discriminate between enzyme-typical peptide fragments with mass shifts of +4 D and nontypical fragments with mass shifts of only +2 D. Based on these observations, protein digest strategies are described for the generation of 1:1 ion doublets spaced either by 2 or 4 D. In addition, the C-terminus of a protein can be identified by the absence of an ion doublet in the corresponding peptide fragment. In protein sequencing by mass spectrometry, digest protocols generating ion doublets provide the most clear-cut analytical results for the recognition of ion series in ESI-MS/MS and MALDI post-source decay (PSD) product ion spectra. Only the mass spectrometric fragment ions of a C-terminal series show ion doublets spaced either by 2 or 4 D, whereas the fragment ions belonging to an N-terminal series remain unshifted. This assignment unequivocally reveals the direction of the identified sequence.
The basic principles of multichannel devices with an array of electrospray tips for high-throughput infusion electrospray ionization mass spectrometry (ESI-MS) have been developed. The prototype plastic devices were fabricated by casting from a solvent-resistant resin. The sample wells on the device were arranged in the format of the standard 96-microtiter well plate, with each sample well connected to an independent electrospray exit port via a microchannel with imbedded electrode. A second plastic plate with distribution microchannels was employed as a cover plate and pressure distributor. Nitrogen gas was used to pressurize individual wells for transport of sample into the electrospray exit port. The design of independent microchannels and electrospray exit ports allowed very high throughput and duty cycle, as well as elimination of any potential sample carryover. The device was placed on a computer-controlled translation stage for precise positioning of the electrospray exit ports in front of the mass spectrometer sampling orifice. High-throughput ESI-MS was demonstrated by analyzing 96 peptide samples in 480 s, corresponding to a potential throughput of 720 samples/h. As a model application, the device was used for the MS determination of inhibition constants of several inhibitors of HIV-1 protease.
The N-terminal sequence myr-Gly-Asn is conserved among the myristoylated cAPK (protein kinase A) catalytic subunit isozymes Ca, Cp, and Cy. By capillary LC-MS and tandem MS, we show that, in approximately one third of the C a and C p enzyme populations from cattle, pig, rabbit, and rat striated muscle, Asn 2 is deamidated to Asp 2. This deamidation accounts for the major isoelectric variants of the cAPK C-subunits formerly called CA and Cg. Deamidation also includes characteristic isoaspartate isomeric peptides from C a and Cp. Asn 2 deamidation does not occur during C-subunit preparation and is absent in recombinant myristoylated Ca (rCa) from Escherichia coli. Deamidation appears to be the exclusive pathway for introduction of an acidic residue adjacent to the myristoylated N-terminal glycine, verified by the myristoylation negative phenotype of an rCa(Asn 2 Asp) mutant. This is the first report thus far of a naturally occumng myr-Gly-Asp sequence. Asp 2 seems to be required for the well-characterized (auto)phosphorylation of the native enzyme at Ser 10. Our results suggest that the myristoylated N terminus of cAPK is a conserved site for deamidation in vivo. Comparable myr-Gly-Asn sequences are found in several signaling proteins. This may be especially significant in view of the recent knowledge that negative charges close to myristic acid in some proteins contribute to regulating their cellular localization.
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