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.     

Determination of dissociation constants for protein-ligand complexes by electrospray ionization mass spectrometry

A fully automated biophysical assay based on electrospray ionization mass spectrometry (ESI-MS) for the determination of the dissociation constants (KD) between soluble proteins and low molecular mass ligands is presented. The method can be applied to systems where the relative MS response of the protein and the protein-ligand complexes do not reflect relative concentrations. Thus, the employed approach enables the use of both electrostatically and nonpolar bound complexes. The dynamic range is wider than for most biological assays, which facilitates the process of establishing a structure-activity relationship. This fully automated ESI-MS assay is now routinely used for ligand screening. The entire procedure is described in detail using hGHbp, a 25-kDa extracellular soluble domain of the human growth hormone receptor, as a model protein.     

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.     

Probing the stoichiometry and oxidation states of metal centers in iron-sulfur proteins using electrospray FTICR mass spectrometry

Electrospray ionization (ESI) Fourier transform ion cyclotron resonance mass spectrometry is used to determine the stoichiometry and oxidation states of the metal centers in several iron-sulfur proteins. Samples are introduced into the ESI source under nondenaturing conditions in order to observe intact metal-containing protein ions. The stoichiometry and oxidation state of the metal or metal-sulfur cluster in the protein ion can be derived from the mass spectrum. Mononuclear metal-containing proteins and [4Fe-4S] centers are very stable and yield the molecular ion with little or no fragmentation. Proteins that contain [2Fe-2S] clusters are less stable and yield loss of one or two sulfur atoms from the molecular species, although the molecular ion is more abundant than the fragment peaks. [3Fe-4S]-containing proteins are the least stable of the species investigated, yielding abundant peaks corresponding to the loss of one to four sulfur atoms in addition to a peak representing the molecular ion. Isotope labeling experiments show that the sulfur loss originates from the [3Fe-4S] center. Negative ion mode mass spectra were obtained and found to produce much more stable [3Fe-4S]-containing ions than obtained in positive ion mode. ESI analysis of the same proteins under denaturing conditions yields mass spectra of the apo form of the proteins. Disulfide bonds are observed in the apoprotein mass spectra that are not present in the holoprotein. These result from oxidative coupling of the cysteinyl sulfur atoms that are responsible for binding the metal center. In addition, inorganic sulfide is found to incorporate itself into the apoprotein by forming sulfur bridges between cysteine residues.     

Infrared multiphoton dissociation in quadrupole time-of-flight mass spectrometry: top-down characterization of proteins

The first implementation of infrared multiphoton dissociation (IRMPD) for a hybrid quadrupole time-of-flight (QqTOF) mass spectrometer is reported. Ions were trapped in the radio frequency-only quadrupole (q2), which normally serves as a collision cell, and irradiated by a continuous CO2 IR laser. The laser beam was introduced coaxially with the quadrupoles in order to maximize overlap with the ion path. The resolution of the TOF mass analyzer allowed direct charge state determination for fragments smaller than 7 kDa. For larger fragments, the charge state could be assigned using the multiple losses of water, characteristic for IRMPD of proteins. The analytical performance is demonstrated by top-down sequencing of several representative proteins (equine myoglobin, bovine casein, and human insulin and chaperonin 10). Various post-translational modifications such as phosphorylation, acetylation, formation of disulfide bridges, and removal of N-terminal methionine followed by acetylation are detected and characterized. The utility of IRMPD for the analysis of biological samples is demonstrated in a study of a recently identified potential marker for endometrial cancer, chaperonin 10.     

Pulsed electrospray for mass spectrometry

Pulsed electrospray has been developed and been reported for the first time. This new technique is based on the principle of pulsed ion sources, combined with the conventional electrospray. The pulsed ion spray was realized by a homemade pulsed HV circuit and was monitored by a digital microscope and an oscilloscope. Results show that the pulsed ESI device can be operated under proper conditions for a clear on-and-off spray process and that the device was kept in good electric contact for electrospray when pulsed HV was on. A pulsed ion current and pulsed mass spectra can be achieved with this pulsed ESI device. Furthermore, it has been noted that, under the same conditions (i.e., shape and size of sprayer tip, distance from sprayer tip to sampling nozzle, and other parameters for mass spectrometer), stable electrospray could be obtained for lower flow rates with a pulsed spray device. This experimental fact indicates the possible reduction in the total sample consumed could be realized by exploiting this novel design.     

Nano-LC FTICR tandem mass spectrometry for top-down proteomics: routine baseline unit mass resolution of whole cell lysate proteins up to 72 kDa

Current high-throughput top-down proteomic platforms provide routine identification of proteins less than 25 kDa with 4-D separations. This short communication reports the application of technological developments over the past few years that improve protein identification and characterization for masses greater than 25 kDa. Advances in separation science have allowed increased numbers of proteins to be identified, especially by nanoliquid chromatography (nLC) prior to mass spectrometry (MS) analysis. Further, a goal of high-throughput top-down proteomics is to extend the mass range for routine nLC MS analysis up to 80 kDa because gene sequence analysis predicts that ~70% of the human proteome is transcribed to be less than 80 kDa. Normally, large proteins greater than 50 kDa are identified and characterized by top-down proteomics through fraction collection and direct infusion at relatively low throughput. Further, other MS-based techniques provide top-down protein characterization, however at low resolution for intact mass measurement. Here, we present analysis of standard (up to 78 kDa) and whole cell lysate proteins by Fourier transform ion cyclotron resonance mass spectrometry (nLC electrospray ionization (ESI) FTICR MS). The separation platform reduced the complexity of the protein matrix so that, at 14.5 T, proteins from whole cell lysate up to 72 kDa are baseline mass resolved on a nano-LC chromatographic time scale. Further, the results document routine identification of proteins at improved throughput based on accurate mass measurement (less than 10 ppm mass error) of precursor and fragment ions for proteins up to 50 kDa.     

Two decades of studying non-covalent biomolecular assemblies by means of electrospray ionization mass spectrometry

Mass spectrometry (MS) is a recognized approach for characterizing proteins and the complexes they assemble into. This application of a long-established physico-chemical tool to the frontiers of structural biology has stemmed from experiments performed in the early 1990s. While initial studies focused on the elucidation of stoichiometry by means of simple mass determination, developments in MS technology and methodology now allow researchers to address questions of shape, inter-subunit connectivity and protein dynamics. Here, we chart the remarkable rise of MS and its application to biomolecular complexes over the last two decades.     

Signal response of coexisting protein conformers in electrospray mass spectrometry

Electrospray ionization mass spectrometry (ESI-MS) is a commonly used tool for characterizing conformational changes of proteins in solution. Different conformations can be distinguished on the basis of their ESI charge state distributions. ESI-MS studies carried out under semidenaturing conditions result in bi- or multimodal distributions that reflect the presence of coexisting conformers. This study explores whether the concentration ratios of these species in solution are reflected in the measured ion intensities. Experiments on two model proteins, lysozyme and myoglobin, reveal that non-native polypeptide chains tend to result in a much stronger signal response than natively folded species. The measured ion intensity ratios can differ from the actual concentration ratios by as much as 2 orders of magnitude. It is proposed that the higher ionization efficiency of unfolded proteins is due to their partially hydrophobic character, which results in a larger surface activity and facilitates protein transfer into ion-producing progeny droplets. Conversely, natively folded proteins have a lower affinity for the air/liquid interface, such that ionization of these conformers is suppressed. The extent of ion suppression is strongly dependent on the experimental conditions such as flow rate and protein concentration, which determine if ESI occurs in a charge deficient or a charge surplus regime. These aspects should be taken into account for the design of ESI-MS-based protein folding experiments and for studies that use ion intensity ratios for the determination of protein-ligand binding affinities.     

High-mass accuracy of product ions produced by SORI-CID using a dual electrospray ionization source coupled with FTICR mass spectrometry

High-mass accuracy is demonstrated using internal calibration for product ions produced by sustained off-resonance irradiation collision-induced dissociation (SORI-CID) of a 15-mer oligonucleotide, 5'-(CTG)5-3'. Internal calibration for this tandem MS experiment was accomplished using a dual electrospray ionization (ESI) source coupled with Fourier transform ion cyclotron resonance mass spectrometry (FTICR-MS) utilizing hexapole accumulation and gated trapping. The pulse sequence entails injection, trapping, and gas-phase isolation of the precursor ion of interest followed by the SORI-CID of this ion and, subsequently, injection and trapping of the internal mass calibrant (i.e., poly(ethylene glycol) with a 1000 Da average mass). The product ions and the poly(ethylene glycol) ions are then simultaneously excited by a broadband frequency chirp excitation waveform and detected. This technique corrects for space-charge effects on the measurement of an ion's cyclotron frequency experienced when externally calibrated data are used. While external calibration for FTICR-MS can result in mass errors of greater than 100 ppm, this internal standardization method demonstrated significantly more consistent accurate mass measurements with average mass errors ranging from -1.2 to -3.2 ppm for the 15-mer oligonucleotide used in this study. This method requires limited modifications to ESI-FTICR mass spectrometers and is applicable for both positive and negative modes of ionization as well as other sample types (e.g., pharmaceuticals, proteins, etc.).     

gamma-Ray-mediated oxidative labeling for detecting protein conformational changes by electrospray mass spectrometry

Exposure of proteins to hydroxyl radicals induces the incorporation of oxygen atoms into solvent-exposed side chains. Earlier studies have employed this approach for mapping protein-protein interactions in mass spectrometry-based footprinting experiments. This work explores whether the overall level of gamma-ray mediated oxidative labeling can be used for monitoring large-scale conformational changes. According to a recently developed kinetic model (Tong, X.; Wren, J. C.; Konermann, L. Anal. Chem. 2007, 79, 6376-6382), the apparent first-order rate constant for oxidative labeling can be approximated as k(app) = k(RAD)/([P](tot) + C/k(u)), where k(RAD) is the primary rate of *OH formation, [P](tot) is the protein concentration, C reflects the presence of competing radical deactivation channels, and ku is the rate constant at which hydroxyl radicals react with the protein. The current study introduces conformational effects into this model by proposing that k(u) = [see text for formula] , where N is the number of amino acids, alphai is a measure for the solvent exposure of residue i, and k(ch)(i) is the oxidation rate constant that would apply for a completely solvent-exposed side chain. Using myoglobin and cytochrome c as model systems, it is demonstrated that unfolding by addition of H(3)PO(4) increases k(app) by up to 30% and 70%, respectively. Unfolding by other commonly used denaturants such as organic acids or urea results in dramatically lower oxidation levels than for the native state, a behavior that is due to the radical scavenging activity of these substances (corresponding to an increased value of C). Control experiments on model peptides are suitable for identifying such "secondary" effects, i.e., factors that modify oxidation levels without being related to conformational changes. In conclusion, the overall *OH labeling level represents a viable probe of large-scale protein conformational changes only under conditions where secondary effects are known to be minimal and where [P](tot) is constant.     

Chip-type asymmetrical flow field-flow fractionation channel coupled with mass spectrometry for top-down protein identification

A chip-type design asymmetrical flow field-flow fractionation (AF4) channel has been developed for high-speed separation of proteins and top-down proteomic analysis using online coupled electrospray ionization mass spectrometry (ESI-MS). The new miniaturized AF4 channel was assembled by stacking multilayer thin stainless steel (SS, 1.5 mm each) plates embedded with an SS frit in such a way that the total thickness of the channel assembly was about 6 mm. The efficiency of the miniaturized AF4 channel at different channel lengths was examined with the separation of protein standards by adjusting flow rates in which an identical effective channel flow rate or an identical void time can be maintained at different channels. Detection limit, overloading effect, reproducibility, and influence of channel membrane materials on separation efficiency were investigated. Desalting and purification of proteins achieved during the AF4 operation by the action of an exiting crossflow and the use of aqueous mass-spectrometry-compatible (MS-compatible) buffer were advantageous for online coupling of the chip-type AF4 with ESI-MS. The direct coupling of AF4 and ESI-MS capabilities was demonstrated for the high-speed separation and identification of carbonic anhydrase (29 kDa) and transferrin (78 kDa) by full scan MS and for the first top-down identification of proteins with AF4-ESI-MS-MS using collision-induced fragmentation (CID). The presence of intact dimers (156 kDa) of transferrin was confirmed by AF4-ESI-MS via size separation of the dimers from monomers, followed by multiply charged ion spectral analysis of the dimers and molecular mass determinations. It was also found from these experiments that AF4-ESI-MS analysis of transferrin exhibited an increased signal-to-noise ratio compared to that of direct ESI-MS analysis due to online purification of the protein sample and size separation of dimers with AF4.     

Structural analysis of polymer end groups by electrospray ionization high-energy collision-induced dissociation tandem mass spectrometry

Chemical structures of polymer end groups play an important role in determining the functional properties of a polymeric system. We present a mass spectrometric method for determining end group structures. Polymeric ions are produced by electrospray ionization (ESI), and they are subject to source fragmentation in the ESI interface region to produce low-mass fragment ions. A series of source-fragment ions containing various numbers of monomer units are selected for high-energy collision-induced dissociation (CID) in a sector/time-of-flight tandem mass spectrometer. It is shown that high-energy CID spectra of source-induced fragment ions are very informative for end group structure characterization. By comparing the CID spectra of fragment ions with those of known chemicals, it is possible to unambiguously identify the end group structures. The utility of this technique is illustrated for the analysis of two poly(ethylene glycol)-based slow-releasing drugs where detailed structural characterization is of significance for drug formulation, quality control, and regulatory approval. Practical issues related to the application of this method are discussed.     

Desorption electrospray ionization mass spectrometry of glycosaminoglycans and their protein noncovalent complex

Glycosaminoglycans heparin and heparan sulfate are biologically active polysulfated carbohydrates that are among the most challenging biopolymers with regards to their structural analysis and functional assessment. Fragmentation of oligosaccharides and sulfate loss are important hindrance to their analysis by mass spectrometry (MS), requiring thus soft ionization methods. The recently introduced soft ionization method desorption electrospray ionization (DESI) has been applied here to heparin and heparan sulfate oligosaccharides, showing that DESI-MS is well suited for the detection of such fragile biomolecules in their intact form. Characterization of complicated oligosaccharides such as synthetic heparin octadecasulfated dodecasaccharide was successfully achieved. The use of water for a spray solvent instead of denaturing organic solvents allowed the first DESI-MS detection of noncovalent biomolecular complexes between heparin oligosaccharides and the chemokine Stromal Cell-derived Factor-1. The hyphenation of the DESI ion source with the high-resolution LTQ-Orbitrap MS analyzer led to high accuracy of mass measurement and enabled unambiguous determination of the protein-bound sulfated oligosaccharide.     

A micromachined chip-based electrospray source for mass spectrometry

A micromachining process is described for fabricating a mass spectrometry electrospray source on a silicon chip. The process utilizes polymer (parylene) layers to form a system of chambers, filters, channels, and hollow needle structures (electrospray emitters) that extend more than a millimeter beyond the edge of the silicon substrate. The use of photoresist as the sacrificial layer facilitates the creation of long channels. Access to the channel structures on the chip is through a port etched through the silicon substrate that also serves as a sample reservoir. A reusable chip holder consisting of two plastic plates and an elastomer gasket provides the means to mount the chip in front of the mass spectrometer inlet and make electrical and gas connections. The electrospray emitters have tapered tips with 5 microns x 10 microns rectangular openings. The shape of the tip can be varied depending on the shape of the mask used to protect the parylene structures during the final plasma etch. The parylene emitters are physically robust and require only a high electric field to achieve stable electrospray operation over a period of a few hours. Direct comparisons with conventional glass or fused silica emitters indicated very similar performance with respect to signal strength and stability, spectral quality, and endurance. The automated MS/MS analysis of a mixture of tryptic peptides was no more difficult and yielded nearly identical results as the analysis of the same sample using a conventional nanospray device. This work demonstrates that an efficient electrospray interface to mass spectrometry can be integrated with other on-chip structures and mass-produced using a batch process.     

An on-line protein digestion device for rapid peptide mapping by electrospray mass spectrometry

A simple laboratory-constructed device has been developed for fast on-line protein digestion followed by peptide mapping by use of electrospray mass spectrometry. Taking advantage of its nonsolubility properties at near-neutral pH values, pepsin could be nonpermanently attached to the PEEK tube commonly employed as transfer capillary between the syringe and the electrospray ion source. After optimization of experimental conditions such as pH, solvent, and exposure time, efficient digestion of several model proteins of molecular weights between 14,000 and 66,000, some having disulfide bridges, was successfully carried out. This technique provided reliable and reproducible sequence information by means of C-terminal-specific cleavages of aromatic and hydrophobic residues. As an application, protein identification could be achieved using a protein database search software.     

Thermal dissociation of multimeric protein complexes by using nanoelectrospray mass spectrometry

The behavior of macromolecular systems at different temperatures is often crucial to their biological activity and function. While heat-induced changes of individual proteins are readily monitored by a number of spectroscopic methods, changes in noncovalent complexes of biomolecules are more challenging to interpret. Nanoelectrospray mass spectrometry is becoming increasingly powerful in the study of large noncovalent complexes, and here we describe the design, characterization, and application of a novel probe that allows the thermocontrol of the solution in the electrospray capillary. The transition temperature for the unfolding of the protein lysozyme is readily obtained and correlates closely with that measured by fluorescence spectroscopy, thereby demonstrating the validity of this approach. We apply this technique to the study of the 200-kDa complex of the small heat shock protein TaHSP16.9, revealing both its dissociation into suboligomeric species and an increase in its size and polydispersity at elevated temperatures. In contrast, gas-phase activation of this complex is also carried out and yields a dissociation pathway fundamentally different from that observed for thermal activation in solution. As such, this probe allows the study of the reversible heat-induced changes of noncovalent complexes in a biologically relevant manner.     

Estimates of protein surface areas in solution by electrospray ionization mass spectrometry

The extent of multiple charging of protein ions in electrospray ionization (ESI) mass spectra depends on the solvent-exposed surface area, but it may also be influenced by a variety of other extrinsic and intrinsic factors. Gas-phase ion chemistry (charge-transfer and charge-partitioning reactions) appears to be the major extrinsic factor influencing the extent of protonation as detected by ESI MS. In this work, we demonstrate that under carefully controlled conditions, which limit the occurrence of the charge-transfer reactions in the gas phase, charge-state distributions of protein ions can be used to assess the solvent-exposed surface area in solution. A set of proteins ranging from 5-kDa insulin to 500-kDa ferritin shows a clear correlation between the average charge in ESI mass spectra acquired under native conditions and their surface areas calculated based on the available crystal structures. An increase of the extent of charge-transfer reactions in the ESI interface results in a noticeable decrease of the average charge of protein ions across the entire range of tested proteins, while the charge-surface correlation is maintained. On the other hand, the intrinsic factors (e.g., a limited number of basic residues) do not appear to play a significant role in determining the protein ion charge. Based on these results, it is now possible to obtain estimates of the surface areas of proteins and protein complexes, for which crystal structures are not available. We also demonstrate how the ESI MS measurements can be used to characterize protein-protein interaction in solution by providing quantitative information on the subunit interfaces formed in protein associations.     

Microchannel plate for surface-induced dissociation in mass spectrometry

A new method for surface-induced dissociation of molecular ions, applied to tandem mass spectrometry, is achieved by collisions at a grazing angle on the inside channel surfaces of a microchannel plate. This technique, termed microchannel SID, is demonstrated by using both positive and negative parent ions in the energy range of 500-2000 eV. Fragmentation spectra of the pentapeptide leucine-enkephalin (555 daltons) at 500 eV show good sequence information with a net fragmentation efficiency of 14%. High mass fragmentation is demonstrated on (CsI)23Cs+ (6113 daltons), with the resultant spectrum showing all cluster fragments from n = 0 to 23.     

Chromogenic cross-linker for the characterization of protein structure by infrared multiphoton dissociation mass spectrometry

We have developed a new IR chromogenic cross-linker (IRCX) to aid in rapidly distinguishing cross-linked peptides from unmodified species in complex mixtures. By incorporating a phosphate functional group into the cross-linker, one can take advantage of its unique IR absorption properties, affording selective infrared multiphoton dissociation (IRMPD) of the cross-linked peptides. In a mock mixture of unmodified peptides and IRCX-cross-linked peptides (intramolecularly and intermolecularly cross-linked), only the peptides containing the IRCX modification were shown to dissociate upon exposure to 50 ms of 10.6-microm radiation. LC-IRMPD-MS proved to be an effective method to distinguish the cross-linked peptides in a tryptic digest of IRCX-cross-linked ubiquitin. A total of four intermolecular cross-links and two dead-end modifications were identified using IRCX and LC-IRMPD-MS. IRMPD of these cross-linked peptides resulted in secondary dissociation of all primary fragment ions containing the chromophore, producing a series of unmodified b- or y-type ions that allowed the cross-linked peptides to be sequenced without the need for collision-induced dissociation.