James L. Stephenson

Charge dependence of protonated insulin decompositions

Abstract Ion trap collisional activation is used to study the effects of charge state on protonated insulin decompositions for three forms of insulin: bovine, porcine, and human. Tandem mass spectrometry data are presented for ions with one to five protons dissociated under identical resonance excitation conditions. The (M+5H)5+ and (M+4H)4+ ions fragment exclusively by peptide bond cleavage of bonds outside the cycles formed by the disulfide linkages present in the insulin molecule, whereas the (M+3H)3+ and (M+2H)2+ ions appear to show a mixture of peptide bond cleavage and fragments arising from mechanisms associated with disulfide bond cleavage. The (M+H)+ ion fragments almost exclusively by way of disulfide bond cleavage, with the only major exception being cleavage on the C-terminal side of glutamic acid residues external to the cycles formed by the disulfide linkages.

Ion trap collisional activation of disulfide linkage intact and reduced multiply protonated polypeptides

The presence of disulfide linkages in multiply charged polypeptide ions tends to inhibit the formation of structurally informative product ions under conventional quadrupole ion trap collisional activation conditions. In particular, fragmentation that requires two cleavages (i.e., cleavage of a disulfide linkage and a peptide linkage) is strongly suppressed. Reduction of the disulfide linkage(s) by use of dithiothreitol yields parent ions upon electrospray without this complication. Far richer structural information is revealed by ion trap collisional activation of the disulfide-reduced species than from the native species. These observations are illustrated with doubly protonated native and reduced somatosin, the [M + 5H](5+) ion of native bovine insulin and the [M + 4H](4+) and [M + 3H](3+) ions of the B-chain of bovine insulin produced by reduction of the disulfide linkages in insulin, and the [M + 11H](11+) ion of native chicken lysozyme and the [M + 11H](11+) and [M + 14H](14+) ions of reduced lysozyme. In each case, the product ions produced by ion trap collisional activation were subjected to ion/ion proton transfer reactions to facilitate interpretation of the product ion spectra. These studies clearly suggest that the identification of polypeptides with one or more disulfide linkages via application of ion trap collisional activation to the multiply charged parent ions formed directly by electrospray could be problematic. Means for cleaving the disulfide linkage, such as reduction by dithiothreitol prior to electrospray, are therefore desirable in these cases.

Automated Proteomics of E. coli via Top-Down Electron-Transfer Dissociation Mass Spectrometry

Electron-transfer dissociation (ETD) has recently been introduced as a fragmentation method for peptide and protein analysis. Unlike collisionally induced dissociation (CID), fragmentation by ETD occurs randomly along the peptide backbone. With the use of the sequences determined from the protein termini and the parent protein mass, intact proteins can be unambiguously identified. Because of the fast kinetics of these reactions, top-down proteomics can be performed using ETD in a linear ion trap mass spectrometer on a chromatographic time scale. Here we demonstrate the utility of ETD in high-throughput top-down proteomics using soluble extracts of E. coli. Development of a multidimensional fractionation platform, as well as a custom algorithm and scoring scheme specifically designed for this type of data, is described. The analysis resulted in the robust identification of 322 different protein forms representing 174 proteins, comprising one of the most comprehensive data sets assembled on intact proteins to date.

High explosives vapor detection by glow discharge ion trap mass spectrometry

The combination of atmospheric sampling glow discharge ionization with quadrupole ion trap mass spectrometry for the detection of traces of high explosives is described. Atmospheric sampling glow discharge provides a simple, rugged, and efficient means for anion formation while the quadrupole ion trap provides for efficient tandem mass spectrometry. Mass-selective ion accumulation and non-specific ion activation methods can be used to overcome deleterious effects arising from ion/ion interactions. Such interactions constitute the major potential technical barrier to the use of the ion trap for real-time monitoring of targeted compounds in uncontrolled and highly variable matrices. Tailored waveforms can be used to effect both mass-selective ion accumulation and ion activation. Concatenated tailored waveforms allow for both functions in a single experiment, thereby providing the capability for monitoring several targeted species simultaneously.

Charge manipulation for improved mass determination of high-mass species and mixture components by electrospray mass spectrometry

The manipulation of the charge states of high-mass ions can facilitate mass determination in electrospray (ES) mass spectrometry. Specifically, the reduction of charge (which leads to ions of higher mass-to-charge ratios) can significantly reduce peak overlap. Signals associated with various charge states of high-mass ions are more easily resolved at low charge states and chemical noise tends to be significantly lower at high mass-to-charge ratios than in the normal mass-to-charge window typically associated with electrospray. Algorithms that transform ES mass spectra to zero-charge spectra are most likely to yield unambiguous results when charge states are clearly resolved and when signal-to-noise ratios are relatively high. Charge manipulation can enhance the value of the transformation algorithms in cases in which compromises their utility. Such situations include ES mass spectra of high-mass species that yield charge states that are not baseline resolved, mixtures with many components and mixtures in which the signals from major components overwhelm signals from minor components. Examples of improved mass determination are illustrated for proteins using ion-ion chemistry as the means for charge state manipulation and the quadrupole ion trap as the mass analyzer.

Ion-ion proton transfer reactions of bio-ions involving noncovalent interactions: Holomyoglobin

Multiply protonated horse skeletal muscle holomyoglobin and apomyoglobin have been subjected to ion-ion proton transfer reactions with anions derived from perfluoro-1,3-dimethylcyclohexane in a quadrupole ion trap operated with helium as a bath gas at 1 mtorr. Neither the apomyoglobin nor holomyoglobin ions show any sign of fragmentation associated with charge state reduction to the 1 + charge state. This is particularly noteworthy for the holomyoglobin ions, which retain the noncovalently bound heme group. For example, no sign of heme loss is associated with charge state reduction from the 9 + charge state of holomyoglobin to the 1 + charge state despite the eight consecutive highly exothermic proton transfer reactions required to bring about this charge change. This result is consistent with calculations that show the combination of long ion lifetime and the high ion-helium collision rate relative to the ion-ion collision rate makes fragmentation unlikely for high mass ions in the ion trap environment even for noncovalently bound complexes of moderate binding strength. The ion-ion proton transfer rates for holo- and apomyoglobin ions of the same charge state also were observed to be indistinguishable, which supports the expectation that ion-ion proton transfer rates are insensitive to ion structure and are determined primarily by the attractive Coulomb field.

Ion/ion chemistry as a top-down approach for protein analysis.

Developing methodology for analyzing complex protein mixtures in a rapid fashion is one of the most challenging problems facing analytical biochemists today. Recent advances in mass spectrometry for the analysis of intact proteins (i.e. the top-down approach) show great promise for rapid protein identification. The ion/ion chemistry approach for the detection and identification of target proteins in complex matrices, determination of fragmentation channels as a function of precursor ion charge state, and post-translational modification characterization are discussed with particular emphasis on tandem mass spectrometry of intact proteins.

“Fast excitation” cid in a quadrupole ion trap mass spectrometer

Collision-induced dissociation (CID) in a quadrupole ion trap mass spectrometer is usually performed by applying a small amplitude excitation voltage at the same secular frequency as the ion of interest. Here we disclose studies examining the use of large amplitude voltage excitations (applied for short periods of time) to cause fragmentation of the ions of interest. This process has been examined using leucine enkephalin as the model compound and the motion of the ions within the ion trap simulated using ITSIM. The resulting fragmentation information obtained is identical with that observed by conventional resonance excitation CID. “Fast excitation” CID deposits (as determined by the intensity ratio of the a4/b4 ion of leucine enkephalin) approximately the same amount of internal energy into an ion as conventional resonance excitation CID where the excitation signal is applied for much longer periods of time. The major difference between the two excitation techniques is the higher rate of excitation (gain in kinetic energy) between successive collisions with helium atoms with “fast excitation” CID as opposed to the conventional resonance excitation CID. With conventional resonance excitation CID ions fragment while the excitation voltage is still being applied whereas for “fast excitation” CID a higher proportion of the ions fragment in the ion cooling time following the excitation pulse. The fragmentation of the (M+17H)17+ of horse heart myoglobin is also shown to illustrate the application of “fast excitation” CID to proteins.

Decompositions of odd- and even-electron anions derived from deoxy-polyadenylates

Radical anions have been formed via electron transfer from multiply charged 5′-d(AAA)-3′ and 5′-d(AAAA)-3′ anions to CCl3+. These ions have been isolated in a quadrupole ion trap operated with helium bath gas at a pressure of 1 mtorr and subjected to resonance excitation (i. e., conventional ion trap collisional activation). Collisional activation of the even-electron species of the same charge state formed directly via electrospray was also performed by using essentially identical conditions. The collisional activation data can be compared directly without ambiguity arising from differences in parent ion internal energies and/or dissociation time frames. Both the odd- and even-electron anions yield extensive sequence-informative fragmentation but show significant differences in the extent of nucleobase loss and in the relative contributions from the various sequence diagnostic dissociation channels. The results of this study indicate that radical anions derived from multiply deprotonated oligo-deoxynucleotides that survive the electron transfer process are stable with respect to fragmentation in the ion trap environment under normal storage conditions and that the unimolecular dissociation behavior of these ions differs from the even-electron anions of the same charge state. These findings suggest, therefore, that odd- and even-electron anions might be used to provide complementary sequence information in cases in which neither ion type provides the full sequence.

Gas phase H/D exchange kinetics: DI versus D2O

The gas phase H/D exchange reactions of bradykinin (M + 3H)3+ ions with D2O and DI were monitored in a quadrupole ion trap mass spectrometer. The H/D exchange kinetics of both chemical probes (D2O and DI) indicate the presence of two noninterconverting reactive gas phase ion populations of bradykinin (M + 3H)3+ at room temperature. The H/D exchange involving DI, however, generally proceeds faster than that involving D2O. The rate observations described here can be rationalized on the basis of the “relay mechanism” (see Campbell et al. J. Am. Chem. Soc.1995, 117, 12840–12854) recently proposed to account for H/D exchange between D2O and gaseous protonated polypeptides. The higher exchange rate with DI is believed to arise primarily as a result of its lower gas-phase acidity relative to that of D2O and, secondarily, as a result of the longer bond length of DI relative to that of OD in D2O.