Stephen J. Valentine

Conformer-Dependent Proton-Transfer Reactions of Ubiquitin Ions

The conformations of ubiquitin ions before and after being exposed to proton transfer reagents have been studied by using ion mobility/mass spectrometry techniques. Ions were produced by electrospray ionization and exposed to acetone, acetophenone, n-butylamine, and 7-methyl-1,5,7-triazabicyclo[4.4.0]dec-5-ene. Under the conditions employed, the +4 to +13 charge states were formed and a variety of conformations, which we have characterized as compact, partially folded, and elongated, have been observed. The low charge state ions have cross sections that are similar to those calculated for the crystal conformation. High charge states favor unfolded conformations. The ion mobility distributions recorded after ions have been exposed to each base show that the lowest charge state that is formed during proton-transfer reactions favors a compact conformation. More open conformations are observed for the higher charge states that remain after reaction. The results show that for a given charge state, the apparent gas-phase acidities of the different conformations are ordered as compact < partially folded < elongated.

A database of 660 peptide ion cross sections: Use of intrinsic size parameters for bona fide predictions of cross sections

An ion trap/ion mobility/time-of-flight mass spectrometry technique has been used to measure collision cross sections for 660 peptide ions generated by tryptic digestion of 34 common proteins. Measured cross sections have been compiled into a database that contains peptide molecular weight and sequence information. The database is used to generate average intrinsic contributions to cross section (size parameters) for different amino acid residues by solving systems of equations that relate the unknown contributions of individual residues to the sequences and cross sections of database peptides. Size parameters are combined with information about amino acid composition to calculate cross sections for database peptides. Bona fide cross section predictions (made prior to measurement) for peptides observed in tryptic digests of sperm whale myoglobin and yeast enolase are made. Eight of 10 predicted cross sections are within 2% of the experimental values and all 10 are within 3.2%. The utility of size parameters for cross section prediction is explored and discussed.

Number of solution states of bradykinin from ion mobility and mass spectrometry measurements.

Ion mobility and mass spectrometry measurements have been used to examine the populations of different solution structures of the nonapeptide bradykinin. Over the range of solution compositions studied, from 0:100 to 100:0 methanol:water and 0:100 to 90:10 dioxane:water, evidence for 10 independent populations of bradykinin structures in solution is found. In some solutions as many as eight structures may coexist. The solution populations are substantially different than the gas-phase equilibrium distribution of ions, which exhibits only three distinct states. Such a large number of coexisting structures explains the inability of traditional methods of characterization such as nuclear magnetic resonance spectroscopy and crystallography to determine detailed structural features for some regions of this peptide.

Multidimensional separations of complex peptide mixtures: a combined high-performance liquid chromatography/ion mobility/time-of-flight mass spectrometry approach

High-performance liquid chromatography (HPLC) has been combined with high-resolution ion mobility separations and time-of-flight mass spectrometry (MS) for the analysis of complex biomolecular mixtures such as those that arise upon tryptic digestion of protein mixtures. In this approach, components in a mixture are separated using reversed phase HPLC. As mixtures of peptides exit the column, they are electrosprayed into an ion mobility/time-of-flight mass spectrometer. Mixtures of ions are separated based on differences in mobilities through a buffer gas, and subsequently dispersed by differences in mass-to-charge (m/z) ratios in a mass spectrometer. The multidimensional approach is feasible because of the large differences in timescales of the HPLC (minutes), ion mobility (milliseconds), and time-of-flight (microseconds) techniques. Peak capacities for the two-dimensional liquid chromatography-ion mobility separations (LC-IMS) and three-dimensional LC-IMS-MS separations are estimated to be ∼900 to 1 200 and ∼3.7 to 4.6 × 105, respectively. The experimental apparatus and data acquisition considerations are described; data for a mixture of peptides obtained upon tryptic digestion of five proteins (albumin, bovine and pig; cytochrome c, horse; hemoglobin, dog and pig) are presented to illustrate the approach.

High-order structure and dissociation of gaseous peptide aggregates that are hidden in mass spectra

Injected-ion mobility and high-pressure ion mobility techniques have been used to examine the conformations of bradykinin, insulin chain A, and several other peptide ions in the gas phase. Under the experimental conditions employed, evidence for multimer formation in the mass spectra of peptides is minimal or absent altogether. However, ion mobility distributions show that aggregates of peptides (containing a single charge per monomer unit) are observed at the same mass-to-charge ratios as the singly charged parent ions. Collision cross sections for these clusters show that they have tightly packed roughly spherical conformations. We have bracketed the average density as 0. 87 ρ < ρ < 1. 00 g cm−3. In some cases, specific stable aggregate forms within a cluster size can be distinguished indicating that some high order structures are favored in the gas phase. Multimer formation between different sizes of polyalanine peptides shows no evidence for size specificity in aggregate formation. Collisional and thermal excitation studies have been used to examine structural transitions and dissociation of the multimers. Aggregates appear to dissociate via loss of singly charged monomers. The observation that peptide multimers can be concealed in mass spectral data requires that fragmentation patterns and reactivity studies of singly charged monomers be undertaken with care.

Evidence for a Quasi-Equilibrium Distribution of States for Bradykinin [M + 3H]3+ Ions in the Gas Phase

Multidimensional ion mobility spectrometry coupled with mass spectrometry (IMS-IMS-MS) techniques are used to select and activate six different gas-phase conformations of bradykinin [M + 3H](3+) ions. Drift time distributions as a function of activation voltage show that at low voltages selected structures undergo conformational transitions in what appears to be a pathway dependent fashion. Over a relatively wide range of intermediate activation voltages a distribution of states that is independent of the initial conformation selected for activation (as well as the activation voltage in this intermediate region) is established. This distribution appears to represent an equilibrium distribution of gas-phase structures that is reached prior to the energy required for dissociation. Establishment of a quasi-equilibrium prior to dissociation results in identical dissociation patterns for different selected conformations. A discussion of the transition from solution-like to gas-phase structures is provided.

Conformation types of ubiquitin [M+8H]8+ Ions from water:methanol solutions: evidence for the N and A States in aqueous solution.

Ion mobility and mass spectrometry measurements are used to examine the gas-phase populations of [M+8H](8+) ubiquitin ions formed upon electrospraying 20 different solutions from 100:0 to 5:95 water:methanol that are maintained at pH = 2.0. Over this range of solution conditions, mobility distributions for the +8 charge state show substantial variations. Here we develop a model that treats the combined measurements as one data set. By varying the relative abundances of a discrete set of conformation types, it is possible to represent distributions obtained from any solution. For solutions that favor the well-known A-state ubiquitin, it is possible to represent the gas-phase distributions with seven conformation types. Aqueous conditions that favor the native structure require four more structural types to represent the distribution. This analysis provides the first direct evidence for trace amounts of the A state under native conditions. The method of analysis presented here should help illuminate how solution populations evolve into new gas-phase structures as solvent is removed. Evidence for trace quantities of previously unknown states under native solution conditions may provide insight about the relationship of dynamics to protein function as well as misfolding and aggregation phenomena.

Temperature-Dependent H/D Exchange of Compact and Elongated Cytochrome c Ions in the Gas Phase

Isotopic exchange reactions of compact and elongated conformations of gaseous cytochrome c ions (+5 and +9 states) with D2O have been measured as a function of temperature (from 300 to ∼440 K) using ion mobility techniques. Rate constants for those sites that exchange at high temperatures (>400 K) are about an order of magnitude smaller than rate constants for sites that exchange at 300 K. Although the exchange rates decrease, the maximum exchange levels for rapidly exchanging sites increase with temperature. At 300 K, exchange levels of 53 ± 3 and 63 ± 3 are measured for the compact and elongated states, respectively. From 300 to 335 K, the exchange levels increase slightly to ∼60 to 70 hydrogens. Above 335 K, the levels increase to a value of ∼200 for the +5 state and ∼190 for the +9 state, near the maximum possible levels, 200 and 204 for these respective charge states. Molecular dynamics simulations have been carried out on structures having calculated cross sections that are near the experimental values in order to explore the exchange process. Overall, it appears that charge site and exchange site proximities are important factors in the exchange profiles for the elongated +9 ion and the compact +5 ion.

Gas-phase separations of protease digests

A mixture of peptides from a complete tryptic digest of ubiquitin has been analyzed by ion mobility/time-of-flight mass spectrometry techniques. All components of the mixture were electrosprayed and ions were separated in the gas phase based on differences in their mobilities through helium before being dispersed into a time-of-flight mass spectrometer for mass-to-charge analysis. The data show that ions separate into families primarily according to differences in their charge states and, to a lesser extent, differences in conformation. This approach reduces spectral congestion typically associated with electrosprayed mixtures and provides charge assignments for mass-to-charge ratio data. Gas-phase separations of ions appear to provide a new physical basis for characterizing components of biological mixtures.

Developing liquid chromatography ion mobility mass spectometry techniques.

When a packet of ions in a buffer gas is exposed to a weak electric field, the ions will separate according to differences in their mobilities through the gas. This separation forms the basis of the analytical method known as ion mobility spectroscopy and is highly efficient, in that it can be carried out in a very short time frame (micro- to milliseconds). Recently, efforts have been made to couple the approach with liquid-phase separations and mass spectrometry in order to create a high-throughput and high-coverage approach for analyzing complex mixtures. This article reviews recent work to develop this approach for proteomics analyses. The instrumentation is described briefly. Several multidimensional data sets obtained upon analyzing complex mixtures are shown in order to illustrate the approach as well as provide a view of the limitations and required future work.