Erythromycin A (EryA) was studied by electrospray ionisation tandem mass spectrometry (ESI-MS/MS) with the aim of developing a methodology for the structural elucidation of novel erythromycins developed by biological synthetic methods. Skimmer dissociation along with sequential mass spectrometry studies (up to MS5) have been employed in this study. In the low-resolution MS/MS analysis of the polyketides, there are several fragment ions that are easily assigned to various neutral losses. These have all been confirmed by accurate-mass measurements. There is also a series of peaks due to ring opening and fragmentation that can only be assigned by high-resolution MSn analysis. Further experiments were performed in deuterated media (D2O/CD3OD 50%) which, along with the high-resolution MSn of erythromycin analogues, has enabled us to identify some of the steps in the ring fragmentation, particularly the loss of the polyketide starter acid. This is an essential step for determining structural alterations in the novel polyketides, but further labelling experiments and studies on more erythromycin analogues are required before the complete fragmentation pathway can be confirmed.
Erythromycin A (EryA), sec-butyl erythromycin B (SEryB), oleandomycin (Olean) and a synthetic derivative, roxithromycin (Rox), were used to investigate the fragmentation of polyketide macrolide antibiotics by collision induced dissociation (CID) tandem mass spectrometry (MS/MS). Analyses were performed with two commercially available mass spectrometers: a Q-TOF hybrid quadrupole time-of-flight instrument and a BioApex II (4.7 Tesla) Fourier transform ion cyclotron resonance (FTICR) instrument both equipped with electrospray ionisation (ESI) sources. One of the first fragmentation processes is the loss of an H(2)O molecule from the [M+H](+) ion. EryA has three hydroxyl groups on the polyketide ring and loses three H(2)O molecules during CID. This study indicates that these facts are not necessarily related. Deuterium exchange experiments were carried out in order to isotopically label free hydroxyl groups. (18)O-exchange experiments were also carried out in order to label the carbonyl group at the 9-position. In EryA and its analogue the first H(2)O loss shifts in mass from loss of 18 Da to loss of 20 Da in deuterated solvents. For both molecules the loss also shifts in mass from loss of 18 Da to loss of 20 Da during the (18)O-exchange experiments. This suggests that the first loss of H(2)O is from the 9-position carbonyl group, indicating that this, and not the nitrogen of the amino sugar, is the site of protonation of the activated MH(+) ions. For Rox the initial loss of H(2)O is replaced by loss of the 9-position oxime group, the rest of the fragmentation sequence being the same as for EryA. For Olean, there is no H(2)O loss from the parent ion. The results have allowed the proposal of a mechanism for the first loss of H(2)O in the EryA MS/MS fragmentation.
A series of tetrasubstituted polyketide delta-lactones were used to evaluate whether gas chromatography/tandem mass spectrometry (GC/MS/MS) and electrospray mass spectrometry (ESI-MS) are useful techniques for probing the structure and stereochemistry of such highly functionalised molecules. Analyses were performed with two commercially available mass spectrometers: a Finnigan/MAT GCQ instrument (CI source) and a Q-TOF Hybrid quadrupole time-of-flight instrument (ESI source). The analyses revealed that a range of variation in the structure and stereochemistry of the lactones did not affect the fragmentation pathway common to these molecules. By accurate mass determination (ESI-MS), the first two fragmentations were assigned to losses of water. Although it was anticipated that the initial dehydration would include the hydroxyl group at the 3-position of the lactones, evidence from deuterium- and (18)O-labelling studies suggests that the losses of water instead involve the oxygen atoms in the ester bond. Attempts to identify further the structures of daughter ions by GC/MS/MS were complicated by extensive rearrangements and non-specific hydrogen/deuterium migrations within the lactones. Together, these results illustrate the limitations of mass spectrometry in the structural elucidation of complex molecules. Copyright 1999 John Wiley& Sons, Ltd.
Erythromycin A (EryA) was studied by electrospray ionisation tandem mass spectrometry (ESI-MS/MS) with the aim of developing a methodology for the structural elucidation of novel erythromycins developed by biological synthetic methods. Skimmer dissociation along with sequential mass spectrometry studies (up to MS5) have been employed in this study. In the low-resolution MS/MS analysis of the polyketides, there are several fragment ions that are easily assigned to various neutral losses. These have all been confirmed by accurate-mass measurements. There is also a series of peaks due to ring opening and fragmentation that can only be assigned by high-resolution MSn analysis. Further experiments were performed in deuterated media (D2O/CD3OD 50%) which, along with the high-resolution MSn of erythromycin analogues, has enabled us to identify some of the steps in the ring fragmentation, particularly the loss of the polyketide starter acid. This is an essential step for determining structural alterations in the novel polyketides, but further labelling experiments and studies on more erythromycin analogues are required before the complete fragmentation pathway can be confirmed.
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