Here we describe a detailed protocol for both data collection and interpretation with respect to ion mobility-mass spectrometry analysis of large protein assemblies. Ion mobility is a technique that can separate gaseous ions based on their size and shape. Specifically, within this protocol, we cover general approaches to data interpretation, methods of predicting whether specific model structures for a given protein assembly can be separated by ion mobility, and generalized strategies for data normalization and modeling. The protocol also covers basic instrument settings and best practices for both observation and detection of large noncovalent protein complexes by ion mobility-mass spectrometry. INTRODUCTIONLarge-scale interaction maps suggest a complex interplay of proteins within a myriad of functional assemblies 1,2 . A critical step in assigning functions to these assemblies is to determine their structure 3 . This goal is challenging, as many of these assemblies exist in low-copy numbers within cells, are frequently heterogeneous and may interact only transiently. Consequently, structural information for many protein complexes is not readily accessible by using the classical tools of structural biology (e.g., X-ray crystallography, nuclear magnetic resonance spectroscopy). New approaches are being developed that involve integrating data from a number of lower-resolution experimental methods and by combining distance and interaction restraints from these methods with homology modeling, architectural or even atomic models are being generated 4 . These restraints can be derived from a variety of experimental measurements including MS of intact complexes, chemical cross-linking, fluorescence resonance energy transfer, small angle X-ray scattering, and analytical ultracentrifugation 5,6 . One very recent addition to this series of biophysical tools is ion mobility separation coupled to mass spectrometry (IM-MS). IM is an established technique for studying shape and conformation in small molecules and individual proteins in the gas phase 7-10 but has only recently been applied to intact protein complexes 11,12 . When IM is coupled with MS, mass and consequently subunit composition can be determined simultaneously with the overall topology of protein complexes 10,12,13 .IM-MS analysis is performed by first ionizing the protein complex of interest. In our experiments, nano-electrospray ionization is used, typically requiring careful preparation procedures for most protein complexes. These procedures, as well as general practical aspects of sample preparation, are detailed in a protocol by Hernández and Robinson 14 . Although they are not discussed in detail here, knowledge of the materials and protocol steps described in that work are critical to the success of the protocol described below.After ionization, ions are injected into a region containing neutral gas at a controlled pressure (e.g., 0.5 mBar of nitrogen gas). Under the influence of a relatively weak electric field, injected ions undergo IM separation [7]...
Collision cross sections in both helium and nitrogen gases were measured directly using a drift cell with RF ion confinement inserted within a quadrupole/ion mobility/time-of-flight hybrid mass spectrometer (Waters Synapt HDMS, Manchester, U.K.). Collision cross sections for a large set of denatured peptide, denatured protein, native-like protein, and native-like protein complex ions are reported here, forming a database of collision cross sections that spans over 2 orders of magnitude. The average effective density of the native-like ions is 0.6 g cm(-3), which is significantly lower than that for the solvent-excluded regions of proteins and suggests that these ions can retain significant memory of their solution-phase structures rather than collapse to globular structures. Because the measurements are acquired using an instrument that mimics the geometry of the commercial Synapt HDMS instrument, this database enables the determination of highly accurate collision cross sections from traveling-wave ion mobility data through the use of calibration standards with similar masses and mobilities. Errors in traveling-wave collision cross sections determined for native-like protein complexes calibrated using other native-like protein complexes are significantly less than those calibrated using denatured proteins. This database indicates that collision cross sections in both helium and nitrogen gases can be well-correlated for larger biomolecular ions, but non-correlated differences for smaller ions can be more significant. These results enable the generation of more accurate three-dimensional models of protein and other biomolecular complexes using gas-phase structural biology techniques.
In recent years, small protein oligomers have been implicated in the aetiology of a number of important amyloid diseases, such as type 2 diabetes, Parkinson's disease and Alzheimer's disease. As a consequence, research efforts are being directed away from traditional targets, such as amyloid plaques, and towards characterization of early oligomer states. Here we present a new analysis method, ion mobility coupled with mass spectrometry, for this challenging problem, which allows determination of in vitro oligomer distributions and the qualitative structure of each of the aggregates. We applied these methods to a number of the amyloid-β protein isoforms of Aβ40 and Aβ42 and showed that their oligomer-size distributions are very different. Our results are consistent with previous observations that Aβ40 and Aβ42 self-assemble via different pathways and provide a candidate in the Aβ42 dodecamer for the primary toxic species in Alzheimer's disease.Many diseases share the common trait of peptide-protein misfolding that leads to oligomerization and, eventually, formation of plaques of β-sheet structure. Prominent among these are type 2 diabetes 1 , Parkinson's disease 2 and Alzheimer's disease 3,4 . Of these, Alzheimer's disease is the leading cause of late-life dementia and is the focus of this paper. An increasing body of evidence links oligomerization of a ubiquitous peptide, the amyloid-β [3][4][5][6] . For this reason, elucidation of pathways of oligomer formation may be critical for the identification of therapeutic targets.Many types of oligomeric amyloid-β assemblies have been described (for a review, see Lazo et al. 7 ). Recently, Bitan et al. [8][9][10] used photoinduced cross-linking of unmodified proteins (PICUP) to reveal that the 42-residue form of amyloid-β, Aβ42, formed (Aβ42) 5 and (Aβ42) 6 oligomers ('paranuclei') that could oligomerize to form structures of higher order. Aβ40 did not form paranuclei, but instead existed as a mixture of monomers, dimers, trimers and tetramers. Chen and Glabe 11 , in contrast, used fluorescence and gel electrophoresis to determine oligomer states of amyloid-β refolded from denaturing solutions. They observed only Aβ42 monomer and trimer bands, and no oligomers of Aβ40. Differences such as these may exist because of the diverse experimental systems used to monitor amyloid-β selfassociation. Also, it has been argued that, in addition to the intrinsic potential of amyloid-β to traverse different assembly pathways, flaws in experimental design may have misled researchers in their quest to elucidate fully the amyloid-β oligomerization process 12 . Hence there is significant uncertainty about amyloid-β oligomer states and their position and relevance to amyloid-β aggregation. Results and discussionWe used a different, more direct, method to probe the amyloid-β oligomerization process: ion mobility coupled with mass spectrometry [13][14][15] . Details are given in the Methods section.Here the results for Aβ40 are given as an example. The mass spectrum of Aβ40 is s...
We have examined the architecture of a protein complex in the absence of bulk water. By determining collision cross sections of assemblies of the trp RNA binding protein, TRAP, we established that the 11-membered ring topology of the complex can be maintained within a mass spectrometer. We also found that the binding of tryptophan enhances the stability of the ring structure and that addition of a specific RNA molecule increases the size of the complex and prevents structural collapse. These results provide definitive evidence that protein quaternary structure can be maintained in the absence of bulk water and highlight the potential of ion mobility separation for defining shapes of heterogeneous macromolecular assemblies.
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Over the past two decades, mass spectrometry (MS) has emerged as a bone fide approach for structural biology. MS can inform on all levels of protein organization, and enables quantitative assessments of their intrinsic dynamics. The key advantages of MS are that it is a sensitive, high-resolution separation technique with wide applicability, and thereby allows the interrogation of transient protein assemblies in the context of complex mixtures. Here we describe how molecular-level information is derived from MS experiments, and how it can be combined with spatial and dynamical restraints obtained from other structural biology approaches to allow hybrid studies of protein architecture and movements.
The application of mass spectrometry (MS) to the study of progressively larger and more complex macromolecular assemblies is proving increasingly useful for structural biologists. The scope of this approach has recently been widened through the application of a tandem MS procedure. This two-step technique involves the selection of specific assemblies in the gas phase and inducing their dissociation through collisions with argon atoms. Here, we investigate the mechanism of this process and show that dissociation of subunits from a macromolecular assembly follows a sequential pathway, with the partitioning of charge between the dissociation products governed primarily by their relative surface areas. Using this basis of understanding, we highlight differences in the dissociation pathways of three related macromolecular assemblies and show how these are a direct consequence of changes in both local and global oligomeric organization.
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