Ion trap versus low-energy beam-type collision-induced dissociation of protonated ubiquitin ions

The beam-type and ion trap collision-induced dissociation (CID) behaviors of protonated bovine ubiquitin ions were studied for charge states ranging from +6 to +12 on a modified triple quadrupole/linear ion trap tandem mass spectrometer. Both beam-type CID and ion trap CID were conducted in a high-pressure linear ion trap, followed by proton-transfer ion/ion reactions to reduce the charge states of product ions mostly to +1. The product ions observed under each activation condition were predominantly b- and y-type ions. Fragmentation patterns showed a much stronger dependence on parent ion charge state with ion trap CID than with beam-type CID using nitrogen as the collision gas, with preferential cleavages C-terminal to aspartic acid at relatively low charge states, nonspecific fragmentation at moderate charge states, and favored cleavages N-terminal to proline residues at high charge states. In the beam-type CID case, extensive cleavage along the protein backbone was noted, which yielded richer sequence information (77% of backbone amide bond cleavages) than did ion trap CID (52% of backbone amide bond cleavages). Collision gas identity and collision energy were also evaluated in terms of their effects on the beam-type CID spectrum. The use of helium as collision gas, as opposed to nitrogen, resulted in CID behavior that was sensitive to changes in collision energy. At low collision energies, the beam-type CID data resembled the ion trap CID data with preferential cleavages predominant, while at high collision energies, nonspecific fragmentation was observed with increased contributions from sequential fragmentation.     

Ion trap collisional activation of the (M + 2H)2+ - (M + 17H)17+ ions of human hemoglobin beta-chain

The parent ions of human hemoglobin beta-chain ranging in charge from 2+ to 17+ have been subjected to ion trap collisional activation. The highest charge-state ions (17+ to 13+) yielded series of products arising from dissociation of adjacent residues. The intermediate charge-state ions (12+ to 5+) tended to fragment preferentially at the N-terminal sides of proline residues and the C-terminal sides of acidic residues. Many, but not all, of the possible cleavages at proline, aspartic acid, and glutamic acid residues were represented in the spectra. The lowest charge-state ions were difficult to dissociate with high efficiency and yielded spectra with poorly defined product ion signals. This observation is attributed to sequential fragmentations arising from losses of small molecules such as water and/or ammonia. The poor fragmentation efficiency observed for the low charge states is due at least in part to the low trapping wells used to store the ions. Higher ion stabilities due to lower Coulombic repulsion and charges being sequestered at highly basic sites may also play an important role. Ion/ion proton-transfer reactions involving protein parent ions allows for the formation of a wide range of parent ion charge states. In addition, the ion/ion proton-transfer reactions involving protein dissociation products simplify interpretation of the product ion spectra.     

Tandem mass spectrometry of ribonuclease A and B: N-linked glycosylation site analysis of whole protein ions

Recently, an approach for the "top down" sequence analysis of whole protein ions has been developed, employing electrospray ionization, collision-induced dissociation, and ion/ion proton-transfer reactions in a quadrupole ion trap mass spectrometer. This approach has now been extended to an analysis of the [M + 12H]12+ to [M + 5H]5+ ions of ribonuclease A and its N-linked glycosylated analogue, ribonuclease B, to determine the influence of the posttranslational modification on protein fragmentation. In agreement with previous studies on the fragmentation of a range of protein ions, facile gas-phase fragmentation was observed to occur along the protein backbone at the C-terminal of aspartic acid residues, and at the N-terminal of proline, depending on the precursor ion charge state. Interestingly, no evidence was found for gas-phase deglycosylation of the N-linked sugar in ribonuclease B, presumably due to effective competition from the facile amide bond cleavage channels that "protect" the N-linked glycosidic bond from cleavage. Thus, localization of the posttranslational modification site may be determined by analysis of the "protein fragment ion mass fingerprint".     

Analysis of protein phosphorylation in the regions of consecutive serine/threonine residues by negative ion electrospray collision-induced dissociation. Approach to pinpointing of phosphorylation sites

Pinpointing of phosphorylation sites by positive ion collision-induced dissociation (CID) in phosphopeptides containing consecutive Ser/Thr residues (Ser/Thr clusters) is frequently hampered by the lack of backbone cleavage between adjacent Ser/Thr or pSer/pThr sites. In this study, we demonstrate that in negative ion collision-induced dissociation phosphorylated and unmodified residues of Ser/Thr clusters exhibit a very selective behavior toward cleavage of their N-Calpha bonds. Ser/Thr clusters were defined as two and more consecutive serine or threonine residues in phosphopeptide sequences. Dissociation reactions at pSer are significantly more abundant than those of unmodified sites. Thr residues exhibit the same effect, but the cleavages occurring at pThr are generally less prominent than those at pSer. The correlation observed between the facility of the amine backbone bond dissociation of phosphopeptides and the presence of the phosphate group on the side chain residues of Ser and Thr is attributed to the different magnitudes of electron density on the Calpha atoms of the amino acid in phosphorylated and unmodified forms. The results of this study indicate that the intensity ratio of the fragments generated by N-Calpha bond cleavage within the phosphopeptide Ser/Thr clusters represents a reliable and general marker for pinpointing of phosphorylation sites. The presented data illustrate that negative ion electrospray CID is superior over the standard positive ion mode approach for the localization of protein phosphorylation inside Ser/Thr clusters.     

Selective, sensitive, and rapid phosphopeptide identification in enzymatic digests using ESI-FTICR-MS with infrared multiphoton dissociation

Rapid screening for phosphopeptides within complex proteolytic digests involving electrospray ionization Fourier transform ion cyclotron resonance mass spectrometry (ESI-FTICR-MS) in the negative ion mode with infrared multiphoton dissociation (IRMPD) accompanied by improved phosphopeptide sensitivity and selectivity is demonstrated with the tryptic digests of the naturally phosphorylated proteins bovine alpha- and beta-casein. All peptides in a complex proteolytic digest can be examined simultaneously for phosphorylation with a 4-s IR laser pulse at 7-11 W where phosphopeptide signature ions form upon irradiation, as the low energy of activation phosphate moiety cleavage transpires without the dissociation of the unphsophorylated peptide population. The tyrosine phosphorylated peptide HGLDN-pY-R, its nonphosphorylated analogue HGLDNYR, the kinase domain of insulin receptor unphosphorylated TRDIYETDYYRK, monophosphorylated TRDIYED-pY-YRK, and triphosphorylated TRDI-pY-ETD-pY-pY-RK were also used as model peptides in this research. The sensitivity and selectivity of phosphopeptides is shown to greatly improve when the volatile base piperidine is used to adjust the pH of th     

Dissociation of multiple protein ion charge states following a single gas-phase purification and concentration procedure

The formation of a range of precursor ion charge states from a single concentrated and purified charge state, followed by activation of each charge state, is introduced as a means to obtain more protein structural information than is available from dissociation of a single charge state alone. This approach is illustrated using off-resonance collisional activation of the [M + 8H]8+ to [M + 6H]6+ precursor ions of the bacteriophage MS2 viral coat protein following concentration and purification of the [M + 8H]8+ charge state. This range of charge states was selected on the basis of an ion trap collisional activation study of the effects of precursor ion charge state on the dissociation of the [M + 12H]12+ to [M + 5H]5+ ions. Gas-phase ion/ion proton-transfer reactions and the ion parking technique were applied to purify and concentrate selected precursor ion charge states as well as to simplify the product ion spectra. The high-charge-state ions fragment preferentially at the N-terminal side of proline residues while the product ion spectra of the lowest charge states investigated are dominated by C-terminal aspartic acid cleavages. Maximum structural information is obtained by fragmentation of the intermediate-charge states.     

Charge-state-dependent sequence analysis of protonated ubiquitin ions via ion trap tandem mass spectrometry

One of the major factors governing the "top-down" sequence analysis of intact multiply protonated proteins by tandem mass spectrometry is the effect of the precursor ion charge state on the formation of product ions. To more fully understand this effect, electrospray ionization coupled to a quadrupole ion trap mass spectrometer, collision-induced dissociation, and gas-phase ion/ion reactions have been employed to examine the fragmentation of the [M + 12H]12+ to [M + H]+ ions of bovine ubiquitin. At low charge states (+1 to +6), loss of NH3 or H2O from the protonated precursor and directed cleavage at aspartic acid residues was observed. At intermediate charge states, (+7, +8, and +9), extensive nonspecific fragmentation of the protein backbone was observed, with 50% sequence coverage obtained from the [M + 8H]8+ ion alone. At high charge states, (+10, +11, +12), the single dominant channel that was observed was the preferential fragmentation of a single proline residue. These data can be readily explained in terms of the current model for intramolecular proton mobilization, that is, the "mobile proton model", the mechanisms for amide bond dissociation developed for protonated peptides, as well as the structures of the multiply charged ions of ubiquitin in the gas phase, examined by ion mobility and hydrogen/deuterium exchange measurements.     

Phosphate group-driven fragmentation of multiply charged phosphopeptide anions. Improved recognition of peptides phosphorylated at serine, threonine, or tyrosine by negative ion electrospray tandem mass spectrometry

The nanoelectrospray product ion spectra of multiply charged phosphopeptide anions reveal the occurrence of phosphate-specific high-mass fragment ions of the type [M - nH - 79](n-1)-. These so far unrecognized fragments, which are observed for phosphoserine-, phosphothreonine-, and phosphotyrosine-containing peptides, are the counterparts of the established inorganic phosphopeptide marker ion found at m/z 79 = [PO3]-. The high-mass marker ions are formed with high efficiency at moderate collision offset values and are particularly useful for sensitive recognition of pSer-, pThr-, and pTyr-peptides due to the low background level in MS/MS spectra at m/z values above those of the precursor ions. By virtue of this feature, the detection of the new phosphorylation-specific fragment ions appears to be more sensitive than the detection of the low-mass phosphate marker ion at m/z 79, where a higher interference by nonspecific background signals is generally observed. The number of phosphate groups within a phosphopeptide can also be estimated on the basis of the [M - nH - 79](n-1)- ions, since these exhibit an effective, sequential neutral loss of H3PO4 of the residing phosphate groups. A mechanistic explanation for the formation of the [M - nH - 79](n-1)- ions from multiply charged phosphopeptides is given. The high-mass marker ions are proposed to originate from phosphopeptide anions, which carry two negative charges located at the phosphate group. A new search tool denominated "variable m/z gain analysis", which utilizes these newly recognized high-mass fragments for spotting of phosphopeptides in a negative ion parent scan, is proposed. The findings strengthen the value of negative ion ESI-MS/MS for analysis of protein phosphorylation.     

Improved sensitivity for phosphopeptide mapping using capillary column HPLC and microionspray mass spectrometry: comparative phosphorylation site mapping from gel-derived proteins

Reversible protein phosphorylation regulates many cellular processes. Understanding how phosphorylation controls a given pathway usually involves specific knowledge of which amino acid residues are phosphorylated on a given protein. This is often a nontrivial task. In addition to the difficulties involved in purifying sufficient amounts of any given protein, most phosphoproteins contain multiple, substoichiometric sites of phosphorylation. In this paper, we describe substantial improvements made to our previously reported multidimensional electrospray MS-based phosphopeptide mapping technique that have resulted in a 20-fold increase in sensitivity for the overall process. Chief among these improvements are the incorporation of capillary chromatography and a microionspray source for the mass spectrometer into the first dimension of the analysis. In the first dimension of the process, phosphopeptides present in the proteolytic digest of a protein are selectively detected and collected into fractions during on-line LC/ESMS, which monitors for phosphopeptide specific marker ions. The phosphopeptide containing fractions are then analyzed in the second dimension by either MALDI-PSD or nano-ES with precursor ion scanning. The relative merits and limitations of these two techniques for phosphopeptide detection are demonstrated. The enhancement in sensitivity of the method under the new experimental conditions makes it suitable for phosphorylation mapping (from selective detection through sequencing) on gel-separated phosphoproteins where the level of phosphorylation at any given site is <200 fmol. Furthermore, this method detects serine, threonine, and tyrosine phosphorylation equally well. We have successfully employed this new configuration to map 11 in vivo sites of phosphorylation on the Saccharomyces cerevisiae protein kinase YAK1. YAK1 peptides containing all five YAK1 PKA consensus sites are phosphorylated, suggesting that YAK1 is an in vivo substrate for PKA. In addition, four peptides containing cdk sites and the autophosphorylation site at Tyr530 were found to be phosphorylated. Because the first dimension of this method generates a phosphorylation profile that can be used for a semiquantitative evaluation of site specific phosphoxylation, we evaluated its ability to detect site-specific changes in the phosphorylation profile of a protein in response to altered cellular conditions. This comparative phosphopeptide mapping strategy allowed us to detect a change in phosphorylation stoichiometry on the motor protein myosin-V in response to treatment with either mitotic or interphase Xenopus egg extracts and to identify the single functionally significant phosphorylation site that regulates myosin-V cargo binding.     

Analysis of phosphorylated peptides by ion mobility-mass spectrometry

An ion mobility-mass spectrometry technique for rapid screening of phosphopeptides in protein digests is described. A data set of 43 sequences (ranging in mass from 400 to 3000 m/z) of model and tryptic peptides, including serine, threonine, and tyrosine phosphorylation, was investigated, and the data support our previously reported observation (Ruotolo, B. T.; Verbeck, G. F., IV; Thomson, L. M.; Woods, A. S.; Gillig, K. J.; Russell, D. H. J. Proteome Res. 2002, 1, 303.) that the drift time-m/z relationship for singly charged phosphorylated peptide ions is different from that for nonphosphorylated peptides. The data further illustrate that a combined data-dependent IM-MS/MS approach for phosphopeptide screening would have enhanced throughput over conventional MS/MS-based methodologies.     

Facile identification of phosphorylation sites in peptides by radical directed dissociation

Identification of phosphorylation sites is of interest due to their importance in protein regulation; however, the identification of the exact sites of this modification is not always easily obtained due to the dynamic nature of phosphorylation and the challenges faced during mass spectrometric analysis. Herein we elaborate on our previous communication (Diedrich, J. K.; Julian, R. R. J. Am. Chem. Soc. 2008, 130, 12212-12213) describing a novel technique for assignment of phosphorylation in a site-specific and facile manner. Phosphorylation sites are selectively modified through β elimination followed by Michael addition chemistry to install a photolabile group. Photodissociation with 266 nm light yields homolytic cleavage at the modification site, generating a β radical which is poised to fragment the peptide backbone. Dissociation primarily yields d-type ions at the previously phosphorylated residue, allowing facile identification. Radical directed fragmentation also occurs in smaller abundances at neighboring residues. The mechanisms behind this selective radical fragmentation are presented and the utility is discussed. Fragmentation is shown to be independent of charge state allowing analysis of a wide variety of peptide sequences including peptides with multiple phosphorylation sites. A comparison of this technique is made with collision induced dissociation (CID) and electron capture dissociation (ECD) for representative peptides.     

Tandem mass spectrometry of sulfated heparin-like glycosaminoglycan oligosaccharides

The structural characterization of heparin-like glycosaminoglycans (HLGAGs) is a major challenge in glycobiology. These linear, sulfated oligosaccharides are expressed on animal cell surfaces, in extracellular matrixes, basement membranes, and mast cell granules and bind with varying degrees of specificity to families of proteases, growth factors, chemokines, and blood coagulation proteins. Cell surface HLGAGs bind growth factors and growth factor receptors and serve as coreceptors in these interactions. Understanding of the mechanism and regulation of growth factor-receptor binding requires efficient determination of cell surface HLGAG structures and the variations in their expression in response to the cellular environment. The solution to this problem entails rapid, sensitive structural analysis of these molecules. To date, HLGAG sequencing requires multistep processes that combine chemical and enzymatic degradation with gel-based or mass spectrometry-based detection systems. Although tandem mass spectrometry has revolutionized proteomics, the fragility of sulfate groups has limited its usefulness in the analysis of HLGAGs. This work demonstrates that tandem mass spectrometry can be effectively used to determine HLGAG structures while minimizing losses of SO3. First, collision-induced dissociation (CID) is shown to produce abundant backbone cleavage ions for HLGAG oligosaccharides, provided that most sulfate groups are deprotonated. Fragmentation of different precursor ion charge states produces complementary data on the structure of the HLGAG. Second, calcium ion complexation of HLGAGs stabilizes the sulfate groups, increases the relative abundances of backbone cleavage ions, and decreases the abundances of ions produced from SO3 losses.     

High-sensitivity electron capture dissociation tandem FTICR mass spectrometry of microelectrosprayed peptides

Electron capture dissociation (ECD) has previously been shown by other research groups to result in greater peptide sequence coverage than other ion dissociation techniques and to localize labile posttranslational modifications. Here, ECD has been achieved for 10-13-mer peptides microelectrosprayed from 10 nM (10 fmol/microL) solutions and for tryptic peptides from a 50 nM unfractionated digest of a 28-kDa protein. Tandem Fourier transform ion cyclotron resonance (FTICR) mass spectra contain fragment ions corresponding to cleavages at all possible peptide backbone amine bonds, except on the N-terminal side of proline, for substance P and neurotensin. For luteinizing hormone-releasing hormone, all but two expected backbone amine bond cleavages are observed. The tandem FTICR mass spectra of the tryptic peptides contain fragment ions corresponding to cleavages at 6 of 12 (1545.7-Da peptide) and 8 of 21 (2944.5-Da peptide) expected backbone amine bonds. The present sensitivity is 200-2000 times higher than previously reported. These results show promise for ECD as a tool to produce sequence tags for identification of peptides in complex mixtures available only in limited amounts, as in proteomics.     

Factors that influence fragmentation behavior of N-linked glycopeptide ions

The investigation of site-specific glycosylation is essential for further understanding the many biological roles that glycoproteins play; however, existing methods for characterizing site-specific glycosylation either are slow or yield incomplete information. Mass spectrometry (MS) is being applied to investigate site-specific glycosylation with bottom-up proteomic type strategies. When using these approaches, tandem mass spectrometry techniques are often essential to verify glycopeptide composition, minimize false positives, and investigate structure. The fragmentation behavior of glycopeptide ions has previously been investigated with multiple techniques including collision induced dissociation (CID), infrared multiphoton dissociation (IRMPD) and electron capture dissociation (ECD); however, due to the almost exclusive analysis of multiply protonated tryptic glycopeptide ions, some dissociation behaviors of N-linked glycopeptide ions have not been fully elucidated. In this study, IRMPD of N-linked glycopeptides has been investigated with a focus on the effects of charge state, charge carrier, glycan composition, and peptide composition. Each of these parameters was shown to influence the fragmentation behavior of N-linked glycopeptide ions. For example, in contrast to previously reported accounts that IRMPD results only in glycosidic bond cleavage, the fragmentation of singly protonated glycopeptide ions containing a basic amino acid residue almost exclusively resulted in peptide backbone cleavage. The fragmentation of the doubly protonated glycopeptide ion exhibited fragmentation similar to that previously reported; however, when the same glycopeptide was sodium coordinated, a previously inaccessible series of glycan fragments were observed. Molecular modeling calculations suggest that differences in the site of protonation and metal ion coordination may direct glycopeptide ion fragmentation.     

Whole protein dissociation in a quadrupole ion trap: identification of an a priori unknown modified protein

A protein mixture derived from a whole cell lysate fraction of Saccharomyces cerevisiae, which contains roughly 19 proteins, has been analyzed to identify an a priori unknown modified protein using a quadrupole ion trap tandem mass spectrometer. Collection of the experimental data was facilitated by collision-induced dissociation and ion/ion proton-transfer reactions in multistage mass spectrometry procedures. Ion/ion reactions were used to manipulate charge states of both parent ions and product ions for the purpose of concentrating charge into the parent ion of interest and to reduce the product ion charge states for determination of product ion mass and abundance. The identification of the protein was achieved by matching the uninterpreted product ion spectrum against protein sequence databases with varying degrees of annotation, coupled with a scoring scheme weighted for the relative abundances of the experimentally observed product ions and the frequency of fragmentations occurring at preferential sites. The protein was identified to be an acetylated yeast heat shock protein, HS12_Yeast (11.6 kDa), with the initiating methionine residue removed. This constitutes the first example of the identification of an a priori unknown protein that is not present in an annotated protein database using a "top-down" approach with a quadrupole ion trap. This example illustrates the utility of relatively low cost instrumentation with modest mass analysis characteristics for the identification of modified proteins without recourse to enzymatic digestion. It also illustrates how experimental data can be used interactively with protein databases when the modified protein of interest is not initially present in the database.     

Electron capture dissociation and infrared multiphoton dissociation MS/MS of an N-glycosylated tryptic peptic to yield complementary sequence information

Glycoproteins are a functionally important class of biomolecules for which structural elucidation presents a challenge. Fragmentation of N-glycosylated peptides, employing collisionally activated dissociation, typically yields product ions that result from dissociation at glycosidic bonds, with little occurrence of dissociation at peptide backbone sites. We have applied two dissociation techniques, electron capture dissociation (ECD) and infrared multiphoton dissociation (IRMPD), in a 7-T Fourier transform ion cyclotron resonance mass spectrometer, in the investigation of an N-glycosylated peptide from an unfractionated tryptic digest of the lectin of the coral tree, Erythrina corallodendron. ECD provided c and z. ions derived from the peptide backbone, with no observed loss of sugars. Cleavage at 11 of 15 backbone amine bonds was observed. The lack of cleavage at sites located close to the glycosylated asparagine residue may result from steric blocking by the glycan. IRMPD provided abundant fragment ions, primarily through dissociation at glycosidic linkages. The monosaccharide composition and the presence of three glycan branch sites could be determined from the IRMPD fragments. The two types of spectra, obtained with the same instrument, thus provide complementary structural information about the glycopeptide. The current result extends the applicability of ECD for glycopeptide analysis to N-glycosylated peptides and to peptides containing branched, highly substituted glycans.     

Phosphopeptide anion characterization via sequential charge inversion and electron-transfer dissociation

Sequential ion/ion reactions have been used to characterize phosphopeptides present in relatively simple peptide mixtures, including one generated from the tryptic digestion of alpha-casein. The phosphopeptides in these mixtures gave rise to either low or no signals via positive ion electrospray ionization. Strong signals, however, were generated in the negative ion mode. An initial ion/ion reaction that employed multiply protonated amino-terminated dendrimers converted phosphopeptide anions to the doubly protonated species. The doubly charged cations were then subjected to ion/ion electron transfer to induce dissociation. Electron-transfer dissociation of doubly positively charged phosphopeptides yields characteristic c- and z-type fragment ions by dissociation of the N-C(alpha) bond along the peptide backbone while preserving the labile posttranslational modifications. These results illustrate the ability to alter ion charge after ion formation and prior to structural interrogation. Phosphopeptides provide an example where it can be difficult to form strong doubly charged cation signals directly when they are present in mixtures, which, as a result, precludes the use of electron-transfer dissociation as a structural probe. The sequential ion/ion reaction process described here, therefore, can provide a new capability for structural interrogation in phosphoproteomics.     

Metal affinity capture tandem mass spectrometry for the selective detection of phosphopeptides

We report a new method called metal affinity capture that when coupled with tandem mass spectrometry (MAC-MSMS) allows for the selective detection and identification of phosphopeptides in complex mixtures. Phosphopeptides are captured as ternary complexes with Ga(III) or Fe(III) and N(alpha),N(alpha)-bis(carboxymethyl)lysine (LysNTA) in solution and electrosprayed as doubly or triply charged positive ions. The gas-phase complexes uniformly dissociate to produce a common (LysNTA + H)+ ion that is used as a specific marker in precursor ion scans. The advantages of MAC-MSMS over the current methods of phosphopeptide detection are as follows. (1) MAC-MSMS uses metal complexes that self-assemble in solution at pH <5, which is favorable for the production of positive ions by electrospray. (2) Phosphorylation at tyrosine, serine, and threonine is detected by MAC-MSMS. (3) The phosphopeptide peaks in the mass spectra are encoded with the 69Ga-71Ga isotope pattern for selective recognition in mixtures. Detection by MAC-MSMS of singly and multiply phosphorylated peptides in tryptic digests is demonstrated at low-nanomolar protein concentrations.     

Activation of intact electron-transfer products of polypeptides and proteins in cation transmission mode ion/ion reactions

Cationic peptide electron-transfer products that do not fragment spontaneously are exposed to ion trap collisional activation immediately upon formation while they pass through a high-pressure collision cell (Q2), where the electron-transfer reagent anions are stored. Radial ion acceleration, which is normal to the ion flow, is implemented by applying an auxiliary dipolar alternating current to a pair of opposing rods of the Q2 quadrupole array at a frequency in resonance with the surviving electron-transfer products. Collisional cooling of cations in the pressurized Q2 ensures efficient overlap of the positive and negative ions for ion/ion reactions and also gives rise to relatively long residence times (milliseconds) for ions in Q2, making it possible to fragment ions via radial excitation during their axial transmission. The radial activation for transmission mode electron-transfer ion/ion reactions has been demonstrated with a doubly protonated tryptic peptide, a triply protonated phosphopeptide, and [M + 7H]7+ ions of ubiquitin. In all cases, significant increases in fragment ion yields and structural information from electron-transfer dissociation (ETD) were observed, suggesting the utility of this method for improving transmission mode ETD performance for relatively low charge states of peptides and proteins.     

Increasing the negative charge of a macroanion in the gas phase via sequential charge inversion reactions

Protonated and deprotonated biological molecules in the gas phase play an important role in life sciences research. The structural information accessible from the ions is highly dependent upon their charge states. Therefore, it is desirable to develop means for increasing absolute charge states, particularly for ionization methods, such as MALDI, that yield relatively low charge ions. The work presented here demonstrates the formation of a doubly deprotonated polypeptide or oligonucleotide ion (dianion) from a singly deprotonated analogue via two sequential ion/ion proton-transfer reactions involving charge inversion. The high exoergicity and the large cross section arising from the long-range attractive Coulomb potential of ion/ion reactions make this process plausible. In this example, an overall efficiency of conversion of singly charged ions to doubly charged ions of roughly 8% for polypeptide was noted while lower efficiency (roughly 2%) observed with an oligonucleotide is likely due to a greater degree of neutralization. No other approach to increasing the net negative charge of an anion in the gas phase has as yet been reported.