The collision-induced dissociation of the carboxylate anions from human blood phosphatdilycholine (PC), phosphatidylethanolamine (PE), phosphatidylserine (PS), phosphatidylinositol (PI) and phosphatidic acid (PA) containing the C18:0 (sn-1) and C20:4 (sn-2) fatty acyl residues was studied using normal phase liquid chromatography coupled with negative ion electrospray tandem mass spectrometry. The product ion peak area ratio of C18:0 to C20:4 was calculated for each phospholipid species and was found to increase with increasing collision energy for all classes. For the phospholipids with a net neutral charge (PE, PC) there was a preferential loss of the sn-2 carboxylate anion (C20:4) at low collision energy, while at higher energy there was a preferential loss of the sn-1 carboxylate anion (C18:0). For the phospholipids with a net negative charge (PI, PA, PS) the intensity of the sn-1 carboxylate anion peak was equal to or higher than the sn-2 carboxylate anion peak at the energies measured. At a given collision energy the product ion peak area ratio decreased in the order PA > or = PS > PI. Studying PS and PE species at different collision energies, it was found that for both classes the increase in the abundance ratio with increasing collision energy was largely dependent on the chain length and degree of unsaturation of the sn-2 acyl chain.
The collision-induced dissociation of the carboxylate anions from human blood phosphatdilycholine (PC), phosphatidylethanolamine (PE), phosphatidylserine (PS), phosphatidylinositol (PI) and phosphatidic acid (PA) containing the C18:0 (sn-1) and C20:4 (sn-2) fatty acyl residues was studied using normal phase liquid chromatography coupled with negative ion electrospray tandem mass spectrometry. The product ion peak area ratio of C18:0 to C20:4 was calculated for each phospholipid species and was found to increase with increasing collision energy for all classes. For the phospholipids with a net neutral charge (PE, PC) there was a preferential loss of the sn-2 carboxylate anion (C20:4) at low collision energy, while at higher energy there was a preferential loss of the sn-1 carboxylate anion (C18:0). For the phospholipids with a net negative charge (PI, PA, PS) the intensity of the sn-1 carboxylate anion peak was equal to or higher than the sn-2 carboxylate anion peak at the energies measured. At a given collision energy the product ion peak area ratio decreased in the order PA > or = PS > PI. Studying PS and PE species at different collision energies, it was found that for both classes the increase in the abundance ratio with increasing collision energy was largely dependent on the chain length and degree of unsaturation of the sn-2 acyl chain.
A new complex of cyclic peptide lactone antibiotics from Bacillus subtilis, which we named maltacines, has recently been described. The structure elucidation of four of them is reported in this paper. The amino acid sequences and structures of the peptides were found by MSn of the ring-opened linear peptides that gave uninterrupted sequences of Bn and Y''n ions. The identities of three unknown residues in the sequences were solved by a combination of derivatization with phenyl isothiocyanate (PITC), high-resolution mass spectrometry and H/D exchange. The nature and position of the cyclic structure were revealed by a chemoselective ring opening with Na18OH and was found to be a lactone formed between a hydroxyl of residue number 4 and the C-terminal amino acid number 12. For verification of the structure of the B2+ ion, peptides with different combinations of P/Q and P/K at the N-terminus were synthesized. The structures of the four peptides were found to be as follows: B1a/B2a, cyclo-4,12(P-Q-Y-HNLeu-A-E-T-Y-Orn-103-Y-I-OH); and B1b/B2b, cyclo-4,12(P-Q-Y-HNLeu-A-E-T-Y-K-103-Y-I-OH).
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