Gated Trapped Ion Mobility Spectrometry Coupled to Fourier Transform Ion Cyclotron Resonance Mass Spectrometry.

Analysis of molecules by ion mobility spectrometry coupled with mass spectrometry (IMS-MS) provides chemical information on the three dimensional structure and mass of the molecules. The coupling of ion mobility to trapping mass spectrometers has historically been challenging due to the large differences in analysis time between the two devices. In this paper we present a modification of the trapped ion mobility (TIMS) analysis scheme termed "Gated TIMS" that allows efficient coupling to a Fourier Transform Ion Cyclotron Resonance (FT-ICR) analyzer. Analyses of standard compounds and the influence of source conditions on the TIMS distributions produced by ion mobility spectra of labile ubiquitin protein ions are presented. Ion mobility resolving powers up to 100 are observed. Measured collisional cross sections of ubiquitin ions are in excellent qualitative and quantitative agreement to previous measurements. Gated TIMS FT-ICR produces results comparable to those acquired using TIMS/time-of-flight MS instrument platforms as well as numerous drift tube IMS-MS studies published in the literature.

Cryogenic Ion Mobility-Mass Spectrometry: Tracking Ion Structure from Solution to the Gas Phase.

Electrospray ionization (ESI) combined with ion mobility-mass spectrometry (IM-MS) is adding new dimensions, that is, structure and dynamics, to the field of biological mass spectrometry. There is increasing evidence that gas-phase ions produced by ESI can closely resemble their solution-phase structures, but correlating these structures can be complicated owing to the number of competing effects contributing to structural preferences, including both inter- and intramolecular interactions. Ions encounter unique hydration environments during the transition from solution to the gas phase that will likely affect their structure(s), but many of these structural changes will go undetected because ESI-IM-MS analysis is typically performed on solvent-free ions. Cryogenic ion mobility-mass spectrometry (cryo-IM-MS) takes advantage of the freeze-drying capabilities of ESI and a cryogenically cooled IM drift cell (80 K) to preserve extensively solvated ions of the type [M + xH](x+)(H2O)n, where n can vary from zero to several hundred. This affords an experimental approach for tracking the structural evolution of hydrated biomolecules en route to forming solvent-free gas-phase ions. The studies highlighted in this Account illustrate the varying extent to which dehydration can alter ion structure and the overall impact of cryo-IM-MS on structural studies of hydrated biomolecules. Studies of small ions, including protonated water clusters and alkyl diammonium cations, reveal structural transitions associated with the development of the H-bond network of water molecules surrounding the charge carrier(s). For peptide ions, results show that water networks are highly dependent on the charge-carrying species within the cluster. Specifically, hydrated peptide ions containing lysine display specific hydration behavior around the ammonium ion, that is, magic number clusters with enhanced stability, whereas peptides containing arginine do not display specific hydration around the guanidinium ion. Studies on the neuropeptide substance P illustrate the ability of cryo-IM-MS to elucidate information about heterogeneous ion populations. Results show that a kinetically trapped conformer is stabilized by a combination of hydration and specific intramolecular interactions, but upon dehydration, this conformer rearranges to form a thermodynamically favored gas-phase ion conformation. Finally, recent studies on hydration of the protein ubiquitin reveal water-mediated dimerization, thereby illustrating the extension of this approach to studies of large biomolecules. Collectively, these studies illustrate a new dimension to studies of biomolecules, resulting from the ability to monitor snapshots of the structural evolution of ions during the transition from solution to gas phase and provide unparalleled insights into the intricate interplay between competing effects that dictate conformational preferences.

Fundamentals of Trapped Ion Mobility Spectrometry Part II: Fluid Dynamics.

Trapped ion mobility spectrometry (TIMS) is a new high resolution (R up to ~300) separation technique that utilizes an electric field to hold ions stationary against a moving gas. Recently, an analytical model for TIMS was derived and, in part, experimentally verified. A central, but not yet fully explored, component of the model involves the fluid dynamics at work. The present study characterizes the fluid dynamics in TIMS using simulations and ion mobility experiments. Results indicate that subsonic laminar flow develops in the analyzer, with pressure-dependent gas velocities between ~120 and 170 m/s measured at the position of ion elution. One of the key philosophical questions addressed is: how can mobility be measured in a dynamic system wherein the gas is expanding and its velocity is changing? We noted previously that the analytically useful work is primarily done on ions as they traverse the electric field gradient plateau in the analyzer. In the present work, we show that the position-dependent change in gas velocity on the plateau is balanced by a change in pressure and temperature, ultimately resulting in near position-independent drag force. That the drag force, and related variables, are nearly constant allows for the use of relatively simple equations to describe TIMS behavior. Nonetheless, we derive a more comprehensive model, which accounts for the spatial dependence of the flow variables. Experimental resolving power trends were found to be in close agreement with the theoretical dependence of the drag force, thus validating another principal component of TIMS theory.

Water-Mediated Dimerization of Ubiquitin Ions Captured by Cryogenic Ion Mobility-Mass Spectrometry.

The dynamics, structures, and functions of most biological molecules are strongly influenced by the nature of the peptide's or protein's interaction with water. Here, cryogenic ion mobility-mass spectrometry studies of ubiquitin have directly captured a water-mediated protein-protein binding event involving hydrated, noncovalently bound dimer ions in solution, and this interaction has potential relevance to one of the most important protein-protein interactions in nature. As solvent is removed, dimer ions, viz. [2 M + 14H](14+), can be stabilized by only a few attached water molecules prior to dissociation into individual monomeric ions. The hydrophobic patch of ubiquitin formed by the side chains of Leu-8, Ile-44, and Val-70 meet all the necessary conditions for a protein-protein binding "hot spot," including the requirement for occlusion of water to nearby hydrophilic sites, and it is suggested that this interaction is responsible for formation of the hydrated noncovalent ubiquitin dimer.

Unfolding of Hydrated Alkyl Diammonium Cations Revealed by Cryogenic Ion Mobility-Mass Spectrometry.

Hydration of the ammonium ion plays a key role in determining the biomolecular structure as well as local structure of water in aqueous environments. Experimental data obtained by cryogenic ion mobility-mass spectrometry (cryo-IM-MS) show that dehydration of alkyl diammonium cations induces a distinct unfolding transition at a critical number of water molecules, n = 21 to 23, n = 24 to 26, and n = 27 to 29, for 1,7-diaminoheptane, 1,8-diaminooctane, and 1,10-diaminodecane, respectively. Results are also presented that reveal compelling evidence for unique structural transitions of hydrated ammonium ions associated with the development of the hydrogen-bond network around individual charged groups. The ability to track the evolution of structure upon stepwise dehydration provides direct insight into the intricate interplay between solvent-molecule interactions that are responsible for defining conformations. Such insights are potentially valuable in understanding how ammonium ion solvation influences conformation(s) of larger biomolecules.

Microheterogeneity within conformational states of ubiquitin revealed by high resolution trapped ion mobility spectrometry.

The present work employs trapped ion mobility spectrometry (TIMS) for the analysis of ubiquitin ions known to display a multitude of previously unresolved interchangeable conformations upon electrospray ionization. The conformational distributions of ubiquitin [M + 6H](6+) through [M + 13H](13+) ions observed by TIMS are nearly identical to numerous drift tube ion mobility spectrometry studies reported in the literature. At an experimental resolving power up to ∼300, many of the congested conformations within the well-known compact, partially folded, and elongated [M + 7H](7+) states are separated. Minimizing the voltages (RF and DC) in the entrance funnel results in exclusive observation of compact [M + 7H](7+) conformers. However, under these conditions, the mobility-dependent pseudopotential coefficient may discriminate against ions having larger collision cross sections-a universal effect for all RF ion guides, funnels, and traps operating in the presence of a gas. The data presented underscore the complications associated with direct comparison of collision cross section values that represent an ensemble average of multiple underlying conformations. As illustrated herein, the microheterogeneity within a particular conformational family and the relative state-to-state abundance can be altered by solvent memory, energetic, and kinetic effects.

From solution to gas phase: the implications of intramolecular interactions on the evaporative dynamics of substance P during electrospray ionization.

Substance P (RPKPQQFFGLM-NH2) [M + 3H](3+) ions have been shown to occupy two distinct conformer states, a compact population of conformers that is formed by evaporation of hydrated ions, and an elongated population of conformers that is formed by collisional heating of the compact conformer. Molecular dynamics (MD) simulations and amino acid mutations revealed that the compact conformer is stabilized by intramolecular interactions between the localized charge-carrying sites, specifically the N-terminus, R(1), and K(3), with the side chains of glutamine and phenylalanine residues present in the peptide. Here, we employ amino acid mutations and cryogenic ion mobility-mass spectrometry (cryo-IM-MS) in an effort to understand how eliminating specific intramolecular interactions alters ion hydration, as well as the dehydration dynamics of substance P during the final stages of the electrospray process. The results clearly illustrate a direct link between the stabilizing effects of intramolecular self-solvation and the formation of substance P [M + 3H](3+) ions. Most notably, removal of these stabilizing interactions leads to a reduction in the abundances of [M + 3H](3+) ions induced by charge reduction reactions, i.e., loss of H(+)(H2O)n ions to form [M + 2H](2+) ions during the final stages of the electrospray process.

Fundamentals of trapped ion mobility spectrometry.

Trapped ion mobility spectrometry (TIMS) is a relatively new gas-phase separation method that has been coupled to quadrupole orthogonal acceleration time-of-flight mass spectrometry. The TIMS analyzer is a segmented rf ion guide wherein ions are mobility-analyzed using an electric field that holds ions stationary against a moving gas, unlike conventional drift tube ion mobility spectrometry where the gas is stationary. Ions are initially trapped, and subsequently eluted from the TIMS analyzer over time according to their mobility (K). Though TIMS has achieved a high level of performance (R > 250) in a small device (<5 cm) using modest operating potentials (<300 V), a proper theory has yet to be produced. Here, we develop a quantitative theory for TIMS via mathematical derivation and simulations. A one-dimensional analytical model, used to predict the transit time and theoretical resolving power, is described. Theoretical trends are in agreement with experimental measurements performed as a function of K, pressure, and the axial electric field scan rate. The linear dependence of the transit time with 1/K provides a fundamental basis for determination of reduced mobility or collision cross section values by calibration. The quantitative description of TIMS provides an operational understanding of the analyzer, outlines the current performance capabilities, and provides insight into future avenues for improvement.

From solution to the gas phase: factors that influence kinetic trapping of substance P in the gas phase.

Substance P (RPKPQQFFGLM-NH2) [M + 3H](3+) ions have been shown to exist as two conformers: one that is kinetically trapped and one that is thermodynamically more stable and therefore energetically preferred. Molecular dynamics (MD) simulations suggested that the kinetically trapped population is stabilized by interactions between the charge sites and the polar side chains of glutamine (Q) located at positions 5 and 6 and phenylalanine (F) located at positions 7 and 8. Here, the individual contributions of these specific intramolecular interactions are systematically probed through site-directed alanine mutations of the native amino acid sequence. Ion mobility spectrometry data for the mutant peptide ions confirm that interactions between the charge sites and glutamine/phenylalanine (Q/F) side chains afford stabilization of the kinetically trapped ion population. In addition, experimental data for proline-to-alanine mutations at positions 2 and 4 clearly show that interactions involving the charge sites and the Q/F side chains are altered by the cis/trans orientations of the proline residues and that mutation of glycine to proline at position 9 supports results from MD simulations suggesting that the C-terminus also provides stabilization of the kinetically trapped conformation.

High resolution trapped ion mobility spectrometery of peptides.

In the present work, we employ trapped ion mobility spectrometry (TIMS) for conformational analysis of several model peptides. The TIMS distributions are extensively compared to recent ion mobility spectrometry (IMS) studies reported in the literature. At a resolving power (R) exceeding 250, many new features, otherwise hidden by lower resolution IMS analyzers, are revealed. Though still principally limited by the plurality of conformational states, at present, TIMS offers R up to ∼3 to 8 times greater than modern drift tube or traveling wave IMS techniques, respectively. Unlike differential IMS, TIMS not only is able to resolve congested conformational features but also can be used to determine information about their relative size, via the ion-neutral collision cross section, offering a powerful new platform to probe the structure and dynamics of biochemical systems in the gas phase.

Evolution of Hydrogen-Bond Networks in Protonated Water Clusters H(+)(H2O)n (n = 1 to 120) Studied by Cryogenic Ion Mobility-Mass Spectrometry.

Cryogenic (80 K) ion mobility-mass spectrometry (cryo-IM-MS) is employed to study structural transitions of protonated water clusters in both the small, H(+)(H2O)n (n = 1 to 30), and large, (n = 31 to ∼120), size regions. In agreement with previous studies, we find compelling evidence of regions of uniform cluster decay in the small size region, accompanied by sharp transition points whereby the loss of a single water monomer induces a different H-bonding motif. The investigation of the isomeric distribution of each species at 80 K reveals experimental evidence supporting the notion that H(+)(H2O)n (n = 6) is the smallest system to possess both Eigen- (H3O(+)) and Zundel- (H5O2(+)) centered structures. Cryo-IM-MS is particularly well-suited for studying clusters in the large size region, for which previous spectroscopic experimental studies are scarce.

From solution to the gas phase: stepwise dehydration and kinetic trapping of substance P reveals the origin of peptide conformations.

Past experimental results and molecular dynamics simulations provide evidence that, under some conditions, electrospray ionization (ESI) of biomolecules produces ions that retain elements of solution phase structures. However, there is a dearth of information regarding the question raised by Breuker and McLafferty, "for how long, under what conditions, and to what extent, can solution structure be retained without solvent?" (Proc. Natl. Acad. Sci. U.S.A. 2008, 105, 18145). Here, we use cryogenic ion mobility-mass spectrometry to experimentally probe the structural evolution of the undecapeptide substance P (SP) during the final stages of ESI. The results reveal that anhydrous SP conformers originate from evaporation of cluster ions, specifically, [SP + 2H](2+) (H2O)n (n = 0 to ∼50) and [SP + 3H](3+) (H2O)n (n = 0 to ∼30), and that major structural changes do not occur during the evaporative process. In the case of [SP + 3H](3+), the results demonstrate that a compact dehydrated conformer population can be kinetically trapped on the time scale of several milliseconds, even when an extended gas phase conformation is energetically favorable.

The periodic focusing ion funnel: theory, design, and experimental characterization by high-resolution ion mobility-mass spectrometry.

Simulation-based development and experimental characterization of a DC-only ion funnel is described herein. Radial ion confinement is achieved via periodic focusing whereby a collisionally dampened effective potential is generated in the inertial frame of an ion traversing the device with appreciable velocity. The new device, termed a periodic focusing ion funnel (PF IF), provides an efficient alternative to the rf ion funnel providing high ion transmission with fewer electrodes, simplified electrical circuitry, and reduced power supply requirements. The utility of the PF IF for structural ion mobility-mass spectrometry (IM-MS) studies is demonstrated using model peptide ions (bradykinin, gramicidin S, and trpzip 1).

Cryogenic ion mobility-mass spectrometry captures hydrated ions produced during electrospray ionization.

Evaporation of water from extensively hydrated protons and peptides formed by electrospray ionization (ESI) has been examined for the first time by cryogenic ion mobility-mass spectrometry (IM-MS). The extent of hydration was controlled using a heated capillary inlet operated between 340 and 391 K. Cold cluster ions formed in the source region were transported into a low temperature (∼80 K) IM drift tube using an electrostatic ion guide where they were separated on the basis of size-to-charge via low-energy collisions with helium gas. The eluting IM profile was subsequently pulsed into an orthogonal time-of-flight (TOF) mass spectrometer for mass-to-charge (m/z) identification of the cluster ion species. Key parameters that influence the cluster distributions were critically examined including the inlet temperature, drift tube temperature, and IM field strength. In agreement with previous studies, our findings indicate that water evaporation is largely dependent upon the particular charge-carrying species within the cluster. IM-MS results for protonated water clusters suggest that the special stability of H(+)(H(2)O)(n) (n = 21) is attributed to the presence of a compact isomer (assigned to a clathrate cage) that falls below the trendline produced by adjacent clusters in the n = 15 to 35 size range. Peptide studies are also presented in which specific and nonspecific solvation is observed for gramicidin S [GS + 2H](2+)(H(2)O)(n) (n = 0 to ∼26) and bradykinin [BK + 2H](2+)(H(2)O)(n) (n = 0 to ∼73), respectively.

Damping factor links periodic focusing and uniform field ion mobility for accurate determination of collision cross sections.

The methodology for obtaining accurate ion-neutral collision cross section (Ω) values for peptides and proteins using periodic focusing ion mobility spectrometry (PF IMS) is presented. A mobility dampening factor (represented by the term α) is introduced to account for the relative increase in ion-neutral collisions in PF IMS compared to uniform field ion mobility spectrometry (UF IMS) for equivalent operating conditions. The results show that α may be easily quantified both theoretically and empirically for a specific PF IMS design operating at a given pressure based upon the charge state of the analyte. By simply incorporating an α term into traditional UF IMS expressions, accurate Ω values were obtained with excellent agreement (≤4% difference) compared to UF IMS measurements found in the current literature.