Native ion mobility mass spectrometry (MS) and surface induced dissociation (SID) are applied to study the integral membrane protein complexes AmtB and AqpZ. Fragments produced from SID are consistent with the solved structures of these complexes. SID is, therefore, a promising tool for characterization of membrane protein complexes.

Mass spectrometry continues to develop as a valuable tool in the analysis of proteins and protein complexes. In protein complex mass spectrometry studies, surface-induced dissociation (SID) has been successfully applied in quadrupole time-of-flight (Q-TOF) instruments. SID provides structural information on noncovalent protein complexes that is complementary to other techniques. However, the mass resolution of Q-TOF instruments can limit the information that can be obtained for protein complexes by SID. Fourier transform ion cyclotron resonance mass spectrometry (FT-ICR MS) provides ultrahigh resolution and ultrahigh mass accuracy measurements. In this study, an SID device was designed and successfully installed in a hybrid FT-ICR instrument in place of the standard gas collision cell. The SID-FT-ICR platform has been tested with several protein complex systems (homooligomers, a heterooligomer, and a protein–ligand complex, ranging from 53 to 85 kDa), and the results are consistent with data previously acquired on Q-TOF platforms, matching predictions from known protein interface information. SID fragments with the same m/z but different charge states are well-resolved based on distinct spacing between adjacent isotope peaks, and the addition of metal cations and ligands can also be isotopically resolved with the ultrahigh mass resolution available in FT-ICR.

Mass spectrometry has emerged as a useful tool in the study of proteins and protein complexes. It is of fundamental interest to explore how the structures of proteins and protein complexes are affected by the absence of solvent and how this alters with increasing time in the gas phase. Here we demonstrate that a range of protein and protein complexes can be confined within the Trap T-wave region of a modified Waters Synapt G2S instrument, including monomeric (β-lactoglobulin), dimeric (β-lactoglobulin and enolase), tetrameric (streptavidin, concanavalin A, and pyruvate kinase), and pentameric (C-reactive protein) complexes, ranging in size up to 237 kDa. We demonstrate that complexes can be confined within the Trap region for varying lengths of time over the range 1–60 s and with up to 86% trapping efficiency for 1 s trapping. Furthermore, using model systems, we show that these noncovalent complexes can also be fragmented by surface-induced dissociation (SID) following trapping. SID reveals similar dissociation patterns over all trapping times studied for unactivated protein complexes, suggesting that any conformational changes occurring over this time scale are insufficient to cause substantial differences in the SID spectra of these complexes. Intentional alteration of structure by cone activation produces a distinct SID spectrum, with the differences observed being conserved, in comparison to unactivated complex, after trapping. However, subtle differences in the SID spectra of the activated complex are also observed as a function of trapping time.

The b2 structures of model systems Xxx-Flp-Ala (Flp = 4R-fluoroproline) and Xxx-flp-Ala (flp = 4S-fluoroproline) (where Xxx is Val or Tyr) were studied by action IRMPD spectroscopy. Proline ring substitutions influence the trans/cis isomerization of the precursor ion, resulting in different b2 fragment ion structures by collision induced dissociation. Vibrational spectra of the b2 ions of Val-Flp and Val-flp exhibit highly intense bands at ~1970 cm−1, revealing that the dominant ion in each case is an oxazolone. The major difference between the spectra of b2 ions for R vs. S fluoroproline is a collection of peaks at 1690 and 1750 cm−1, characteristic of a diketopiperazine structure, which were only present in the 4S-fluoroproline (flp) cases. This suggests only one b2 ion structure (oxazolone) is being formed for Flp-containing peptides, whereas flp-containing peptides produce a mixture of a dominant oxazolone with a lower population of diketopiperazine. In solution, Flp is known to possess a higher trans percentage in the N-terminally adjacent peptide bond, with flp inducing a greater proportion of the cis conformation. The diketopiperazine formation observed here correlates directly with the Ktrans/cis trend previously shown in solution, highlighting that the trans/cis isomerization likelihood for proline residues modified in the 4th position is retained in the gas-phase.

•Surface collision of D2 tetramers yields dimers that further fragment to monomers•Collision energy needed for dissociation tracks with dimer-dimer interface area•Location of ligand binding sites affects tetramer dissociation behaviorUnderstanding of protein complex assembly and the effect of ligand binding on their native topologies is integral to discerning how alterations in their architecture can affect function. Probing the disassembly pathway may offer insight into the mechanisms through which various subunits self-assemble into complexes. Here, a gas-phase dissociation method, surface-induced dissociation (SID) coupled with ion mobility (IM), was utilized to determine whether disassembly pathways are consistent with the assembly of three homotetramers and to probe the effects of ligand binding on conformational flexibility and tetramer stability. The results indicate that the smaller interface in the complex is initially cleaved upon dissociation, conserving the larger interface, and suggest that assembly of a D2 homotetramer from its constituent monomers occurs via a C2 dimer intermediate. In addition, we demonstrate that ligand-mediated changes in tetramer SID dissociation behavior are dependent on where and how the ligand binds.Figure optionsDownload full-size imageDownload high-quality image (188 K)Download as PowerPoint slide

One attractive feature of ion mobility mass spectrometry (IM-MS) lies in its ability to provide experimental collision cross section (CCS) measurements, which can be used to distinguish different conformations that a protein complex may adopt during its gas-phase unfolding. However, CCS values alone give no detailed information on subunit structure within the complex. Consequently, structural characterization typically requires molecular modeling, which can have uncertainties without experimental support. One method of obtaining direct experimental evidence on the structures of these intermediates is utilizing gas-phase activation techniques that can effectively dissociate the complexes into substructures while preserving the native topological information. The most commonly used activation method, collision-induced dissociation (CID) with low-mass target gases, typically leads to unfolding of monomers of a protein complex. Here, we describe a method that couples IM-MS and surface-induced dissociation (SID) to dissociate the source-activated precursors of three model protein complexes: C-reactive protein (CRP), transthyretin (TTR), and concanavalin A (Con A). The results of this study confirm that CID involves the unfolding of the protein complex via several intermediates. More importantly, our experiments also indicate that retention of similar CCS between different intermediates does not guarantee retention of structure. Although CID spectra (at a given collision energy) of source-activated, mass-selected precursors do not distinguish between native-like, collapsed, and expanded forms of a protein complex, dissociation patterns and/or average charge states of monomer products in SID of each of these forms are unique.

The direct determination of the overall topology and inter-subunit contacts of protein complexes plays an integral role in understanding how different subunits assemble into biologically relevant multisubunit complexes. Mass spectrometry has emerged as a useful structural biological tool because of its sensitivity, high tolerance for heterogeneous mixtures and the fact that crystals are not required. Perturbation of subunit interfaces in solution followed by gas-phase detection using mass spectrometry is a current means of probing the disassembly and hence assembly of protein complexes. Herein, we present an alternative method that employs native mass spectrometry coupled with ion mobility and two stages of surface induced dissociation (SID) where protein complexes are dissociated into subcomplexes in the first SID stage. The subcomplexes are then separated by ion mobility and subsequently fragmented into their individual monomers in the second SID stage (SID-IM-SID), providing information on how individual subunits assemble into protein complexes with different native topologies. The results also illustrate complex dependent differences in charge redistribution onto individual monomers obtained in SID-IM-SID.

•Surface induced dissociation (SID) fragments Methanosarcina thermophila 20S proteasome, which consists of four stacked heptameric rings (α7β7β7α7 symmetry).•SID produces both α and β subunits while collision induced dissociation (CID) only produces the only highly charged α subunit.•The charge reduced 20S proteasome produces the α7β7 fragment, reflecting the stacked ring topology of the complex.•The combination of SID and charge reduction is shown to be a powerful tool for the study of protein complex structure.Native mass spectrometry (MS) and surface induced dissociation (SID) have been applied to study the stoichiometry and quaternary structure of non-covalent protein complexes. In this study, Methanosarcina thermophila 20S proteasome, which consists of four stacked heptameric rings (α7β7β7α7 symmetry), has been selected to explore the SID dissociation pattern of a complicated stacked ring protein complex. SID produces both α and β subunits while collision induced dissociation (CID) produces only highly charged α subunit. In addition, the charge reduced 20S proteasome produces the α7β7 fragment, reflecting the stacked ring topology of the complex. The combination of SID and charge reduction is shown to be a powerful tool for the study of protein complex structure.

Toyocamycin nitrile hydratase (TNH) is a protein hexamer that catalyzes the hydration of toyocamycin to produce sangivamycin. The structure of hexameric TNH and the arrangement of subunits within the complex, however, have not been solved by NMR or X-ray crystallography. Native mass spectrometry (MS) clearly shows that TNH is composed of two copies each of the α, β, and γ subunits. Previous surface induced dissociation (SID) tandem mass spectrometry on a quadrupole time-of-flight (QTOF) platform suggests that the TNH hexamer is a dimer composed of two αβγ trimers; furthermore, the results suggest that α–β interact most strongly (Blackwell et al. Anal. Chem. 2011, 83, 2862–2865). Here, multiple complementary MS based approaches and homology modeling have been applied to refine the structure of TNH. Solution-phase organic solvent disruption coupled with native MS agrees with the previous SID results. By coupling surface induced dissociation with ion mobility mass spectrometry (SID/IM), further information on the intersubunit contacts and relative interfacial strengths are obtained. The results show that TNH is a dimer of αβγ trimers, that within the trimer the α, β subunits bind most strongly, and that the primary contact between the two trimers is through a γ–γ interface. Collisional cross sections (CCSs) measured from IM experiments are used as constraints for postulating the arrangement of the subunits represented by coarse-grained spheres. Covalent labeling (surface mapping) together with protein complex homology modeling and docking of trimers to form hexamer are utilized with all the above information to propose the likely quaternary structure of TNH, with chemical cross-linking providing cross-links consistent with the proposed structure. The novel feature of this approach is the use of SID-MS with ion mobility to define complete connectivity and relative interfacial areas of a heterohexameric protein complex, providing much more information than is available from solution disruption. That information, when combined with CCS-guided coarse-grained modeling and covalent labeling restraints for homology modeling and trimer–trimer docking, provides atomic models of a previously uncharacterized heterohexameric protein complex.

Ticks are vectors for disease transmission because they are indiscriminant in their feeding on multiple vertebrate hosts, transmitting pathogens between their hosts. Identifying the hosts on which ticks have fed is important for disease prevention and intervention. We have previously shown that hemoglobin (Hb) remnants from a host on which a tick fed can be used to reveal the host’s identity. For the present research, blood was collected from 33 bird species that are common in the U.S. as hosts for ticks but that have unknown Hb sequences. A top-down-assisted bottom-up mass spectrometry approach with a customized searching database, based on variability in known bird hemoglobin sequences, has been devised to facilitate fast and complete sequencing of hemoglobin from birds with unknown sequences. These hemoglobin sequences will be added to a hemoglobin database and used for tick host identification. The general approach has the potential to sequence any set of homologous proteins completely in a rapid manner.

Matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry (MS) coupled with affinity capture is a well-established method to extract biological analytes from complex samples followed by label-free detection and identification. Many bioanalytes of interest bind to membrane-associated receptors; however, the matrices and high-vacuum conditions inherent to MALDI-TOF MS make it largely incompatible with the use of artificial lipid membranes with incorporated receptors as platforms for detection of captured proteins and peptides. Here we show that cross-linking polymerization of a planar supported lipid bilayer (PSLB) provides the stability needed for MALDI-TOF MS analysis of proteins captured by receptors embedded in the membrane. PSLBs composed of poly(bis-sorbylphosphatidylcholine) (poly(bis-SorbPC)) and doped with the ganglioside receptors GM1 and GD1a were used for affinity capture of the B subunits of cholera toxin, heat-labile enterotoxin, and pertussis toxin. The three toxins were captured simultaneously, then detected and identified by MS on the basis of differences in their molecular weights. Poly(bis-SorbPC) PSLBs are inherently resistant to nonspecific protein adsorption, which allowed selective toxin detection to be achieved in complex matrices (bovine serum and shrimp extract). Using GM1–cholera toxin subunit B as a model receptor–ligand pair, we estimated the minimal detectable concentration of toxin to be 4 nM. On-plate tryptic digestion of bound cholera toxin subunit B followed by MS/MS analysis of digested peptides was performed successfully, demonstrating the feasibility of using the PSLB-based affinity capture platform for identification of unknown, membrane-associated proteins. Overall, this work demonstrates that combining a poly(lipid) affinity capture platform with MALDI-TOF MS detection is a viable approach for capture and proteomic characterization of membrane-associated proteins in a label-free manner.

The quaternary structures of proteins are both important and of interest to chemists, because many proteins exist as complexes in vivo, and probing these structures allows us to better understand their biological functions. Conventional structural biology methods such as X-ray crystallography and nuclear magnetic resonance provide high-resolution information on the structures of protein complexes and are the gold standards in the field. However, other emerging biophysical methods that only provide low-resolution data (e.g. stoichiometry and subunit connectivity) on the structures of the protein complexes are also becoming more important to scientists. Mass spectrometry is one of these approaches that provide lower than atomic structural resolution, but the approach is higher throughput and provides not only better mass information than other techniques but also stoichiometry and topology.Fragile noncovalent interactions within the protein complexes can be preserved in the gas phase of MS under gentle ionization and transfer conditions. Scientists can measure the masses of the complexes with high confidence to reveal the stoichiometry and composition of the proteins. What makes mass spectrometry an even more powerful method is that researchers can further isolate the protein complexes and activate them in the gas phase to release subunits for more structural information. The caveat is that, upon gas-phase activation, the released subunits need to faithfully reflect the native topology so that useful information on the proteins can be extracted from mass spectrometry experiments. Unfortunately, many proteins tend to favor unfolding upon collision with neutral gas (the most common activation method in mass spectrometers). Therefore, this typically results in limited insights on the quaternary structure of the precursor without further manipulation of other experimental factors.Scientists have observed, however, that valuable structural information can be obtained when the gas-phase proteins are activated by collision with a surface. Subcomplexes released after surface collision are consistent with the native quaternary structure of several protein systems studied, even for a large chaperone protein, GroEL, that approaches megadalton mass. The unique and meaningful data generated from surface induced dissociation (SID) have been attributed to the fast and energetic activation process upon collision with a massive target, the surface.In this Account, we summarize our SID studies of protein complexes, with emphasis on the more recent work on the combination of ion mobility (IM) with SID. IM has gained popularity over the years not only as a gas-phase separation technique but also as a technique with the ability to measure the size and shape of the proteins in the gas phase. Incorporation of IM before SID allows different conformations of a protein to be separated and examined individually by SID for structural details. When IM is after SID, the cross sections of the SID products can be measured, providing insight on the dissociation pathways, which may mimic disassembly pathways. Furthermore, the separation by IM greatly reduces the peak overlapping (same m/z) and coalescence (merging) of SID products, improving the resolving power of the method. While there are still many unanswered questions on the fundamental properties of gas-phase proteins and a need for further research, our work has shown that SID can be a complementary gas-phase tool providing useful information for studying quaternary structures of noncovalent protein complexes.

In solution, α-helices are stabilized at the termini by a variety of different capping interactions. Study of these interactions in the gas phase provides a unique means to explore the intrinsic properties that cause this stabilization. Evidence of helical and globular conformations is presented here for gas-phase, doubly charged peptides of sequence XAnK, wherein X is D, N, Q, or L. The relative abundance of the helical conformation is found to vary as a function of peptide length and the identity of the first amino acid, consistent with solution phase studies that have looked at the identity of the first amino acid. The N-terminal, b ion fragments of the doubly charged precursor peptides are shown to form helical and globular conformations. The stability of the helical fragments is examined as a function of fragment length, N-terminal amino acid, precursor conformation, and the activation energy used to generate the fragment. At lower collision energies, helical b ions preferentially form, particularly from helical precursors. The abundance of the helical b ion population is observed to dramatically decrease for NAn and DAn b ions smaller than the b10; simulations suggest this feature is due to the b10 having two complete turns of the helix, while the b9 and smaller ions have only a partial second turn, suggesting the b10 is the lower limit for stable helical conformations in b ions. Use of higher collision energies promotes the formation of globular structures in the b ions. This characteristic is attributed to increased conformational dynamics and subsequently improved proton transfer kinetics from the b ion’s C-terminal oxazolone ring to the N-terminus.

Paper spray (PS) ionization, an ambient ionization method, has previously been explored as a direct and fast method for mass spectrometric analysis of complex mixtures. It has been applied to the analysis of a wide variety of compounds, mostly small molecules. The work reported here extends the application of PS ionization to noncovalent protein complexes on an ion mobility tandem mass spectrometer. Similar mass spectra for protein complexes were obtained by PS ionization and nanoflow electrospray ionization (nESI), indicating that intact protein complexes can be preserved in PS ionization. In addition, collisional cross sections measured by ion mobility provide evidence that the protein assemblies may remain compact by PS ionization. With PS, it is possible to detect hemoglobin tetramer from a blood sample with minimal sample preparation. This is the first report to show that PS ionization is a promising ionization method for nonconvalent protein complexes.

The interplay between the entropically and enthalpically favored products of peptide fragmentation is probed using a combined experimental and theoretical approach. These b2 ion products can take either an oxazolone or diketopiperazine structure. Cleavage after the second amide bond is often a favorable process because the products are small ring structures that are particularly stable. These structures are structurally characterized by action IRMPD spectroscopy and semi-quantified using gas-phase hydrogen–deuterium exchange. The formation of the oxazolone and diketopiperazine has been thought to be largely governed by the identity of the first two residues at the N-terminus of the peptide. We show here that the length of the precursor peptide and identity of the third residue play a significant role in the formation of the diketopiperazine structure in peptides containing an N-terminal asparagine residue. This is additionally the first instance showing an N-terminal residue with an amide side chain can promote formation of the diketopiperazine b2 ion structure.

Ion mobility (IM) and tandem mass spectrometry (MS/MS) coupled with native MS are useful for studying noncovalent protein complexes. Collision induced dissociation (CID) is the most common MS/MS dissociation method. However, some protein complexes, including glycogen phosphorylase B kinase (PHB) and L-glutamate dehydrogenase (GDH) examined in this study, are resistant to dissociation by CID at the maximum collision energy available in the instrument. Surface induced dissociation (SID) was applied to dissociate the two refractory protein complexes. Different charge state precursor ions of the two complexes were examined by CID and SID. The PHB dimer was successfully dissociated to monomers and the GDH hexamer formed trimeric subcomplexes that are informative of its quaternary structure. The unfolding of the precursor and the percentages of the distinct products suggest that the dissociation pathways vary for different charge states. The precursors at lower charge states (+21 for PHB dimer and +27 for GDH hexamer) produce a higher percentage of folded fragments and dissociate more symmetrically than the precusors at higher charge states (+29 for PHB dimer and +39 for GDH hexamer). The precursors at lower charge state may be more native-like than the higher charge state because a higher percentage of folded fragments and a lower percentage of highly charged unfolded fragments are detected. The combination of SID and charge reduction is shown to be a powerful tool for quaternary structure analysis of refractory noncovalent protein complexes, as illustrated by the data for PHB dimer and GDH hexamer.

Tandem mass spectrometry is a tool to dissect noncovalent protein complexes into smaller substructures for quaternary structure analysis. The commonly used activation method, collision induced dissociation (CID), often provides limited structural information from the typical dissociation pattern where unfolded monomers are ejected from the protein complex. In contrast, surface-induced dissociation (SID) has been shown to be very effective at dissociating protein complexes with less unfolding than CID. We present here SID of a large noncovalent tetradecamer protein, GroEL (801 kDa). A wide variety of products, including heptamers representative of the native topology, are released from the precursor upon SID, significantly different from the ubiquitous monomer ejection in CID. Enhanced dissociation into heptamers is observed when the charge states of the GroEL precursor are reduced by adding triethylammonium acetate into the spraying buffer. Ion mobility is utilized after SID to separate products overlapping in m/z to simplify the SID spectra. Compact heptamers from the charge-reduced tetradecamer are clearly distinguished from other overlapping species. SID can be very useful for quaternary structure studies of large noncovalent protein complexes, as manifested by the GroEL data where the tetradecamer dissociates into heptamers, reflecting the native topology of the complex.

SgrAI is a type IIF restriction endonuclease that cuts an unusually long recognition sequence and exhibits self-modulation of DNA cleavage activity and sequence specificity. Previous studies have shown that SgrAI forms large oligomers when bound to particular DNA sequences and under the same conditions where SgrAI exhibits accelerated DNA cleavage kinetics. However, the detailed structure and stoichiometry of the SgrAI–DNA complex as well as the basic building block of the oligomers have not been fully characterized. Ion mobility mass spectrometry (IM-MS) was employed to analyze SgrAI–DNA complexes and show that the basic building block of the oligomers is the DNA-bound SgrAI dimer (DBD) with one SgrAI dimer bound to two precleaved duplex DNA molecules each containing one-half of the SgrAI primary recognition sequence. The oligomers contain variable numbers of DBDs with as many as 19 DBDs. Observation of the large oligomers shows that nanoelectrospray ionization (nano-ESI) can preserve the proposed activated form of an enzyme. Finally, the collision cross section of the SgrAI–DNA oligomers measured by IM-MS was found to have a linear relationship with the number of DBDs in each oligomer, suggesting a regular, repeating structure.

The b2 structures of model systems Xxx-Flp-Ala (Flp = 4R-fluoroproline) and Xxx-flp-Ala (flp = 4S-fluoroproline) (where Xxx is Val or Tyr) were studied by action IRMPD spectroscopy. Proline ring substitutions influence the trans/cis isomerization of the precursor ion, resulting in different b2 fragment ion structures by collision induced dissociation. Vibrational spectra of the b2 ions of Val-Flp and Val-flp exhibit highly intense bands at ~1970 cm−1, revealing that the dominant ion in each case is an oxazolone. The major difference between the spectra of b2 ions for R vs. S fluoroproline is a collection of peaks at 1690 and 1750 cm−1, characteristic of a diketopiperazine structure, which were only present in the 4S-fluoroproline (flp) cases. This suggests only one b2 ion structure (oxazolone) is being formed for Flp-containing peptides, whereas flp-containing peptides produce a mixture of a dominant oxazolone with a lower population of diketopiperazine. In solution, Flp is known to possess a higher trans percentage in the N-terminally adjacent peptide bond, with flp inducing a greater proportion of the cis conformation. The diketopiperazine formation observed here correlates directly with the Ktrans/cis trend previously shown in solution, highlighting that the trans/cis isomerization likelihood for proline residues modified in the 4th position is retained in the gas-phase.

Native ion mobility mass spectrometry (MS) and surface induced dissociation (SID) are applied to study the integral membrane protein complexes AmtB and AqpZ. Fragments produced from SID are consistent with the solved structures of these complexes. SID is, therefore, a promising tool for characterization of membrane protein complexes.