Separating and visualising protein assemblies by means of preparative mass spectrometry and microscopy.

Many multi-protein assemblies exhibit characteristics which hamper their structural and dynamical characterization. These impediments include low copy number, heterogeneity, polydispersity, hydrophobicity, and intrinsic disorder. It is becoming increasingly apparent that both novel and hybrid structural biology approaches need to be developed to tackle the most challenging targets. Nanoelectrospray mass spectrometry has matured over the last decade to enable the elucidation of connectivity and composition of large protein assemblies. Moreover, comparing mass spectrometry data with transmission electron microscopy images has enabled the mapping of subunits within topological models. Here we describe a preparative form of mass spectrometry designed to isolate specific protein complexes from within a heterogeneous ensemble, and to 'soft-land' these target complexes for ex situ imaging. By building a retractable probe incorporating a versatile target holder, and modifying the ion optics of a commercial mass spectrometer, we show that we can steer the macromolecular ion beam onto a target for imaging by means of transmission electron microscopy and atomic force microscopy. Our data for the tetradecameric chaperonin GroEL show that not only are the molecular volumes of the landed particles consistent with the overall dimensions of the complex, but also that their gross topological features can be maintained.

Tandem mass spectrometry of intact GroEL-substrate complexes reveals substrate-specific conformational changes in the trans ring.

It has been suggested that the bacterial GroEL chaperonin accommodates only one substrate at any given time, due to conformational changes to both the cis and trans ring that are induced upon substrate binding. Using electrospray ionization mass spectrometry, we show that indeed GroEL binds only one molecule of the model substrate Rubisco. In contrast, the capsid protein of bacteriophage T4, a natural GroEL substrate, can occupy both rings simultaneously. As these substrates are of similar size, the data indicate that each substrate induces distinct conformational changes in the GroEL chaperonin. The distinctive binding behavior of Rubisco and the capsid protein was further investigated using tandem mass spectrometry on the intact 800-914 kDa GroEL-substrate complexes. Our data suggest that even in the gas phase the substrates remain bound inside the GroEL cavity. The analysis revealed further that binding of Rubisco to the GroEL oligomer stabilizes the chaperonin complex significantly, whereas binding of one capsid protein did not have the same effect. However, addition of a second capsid protein molecule to GroEL resulted in a similar stabilizing effect to that obtained after the binding of a single Rubisco. On the basis of the stoichiometry of the GroEL chaperonin-substrate complex and the dissociation behavior of the two different substrates, we hypothesize that the binding of a single capsid polypeptide does not induce significant conformational changes in the GroEL trans ring, and hence the unoccupied GroEL ring remains accessible for a second capsid molecule.

Mass spectrometry-based approaches to protein-ligand interactions.

One of the greatest current challenges in proteomics is to develop an understanding of cellular communication and regulation processes, most of which involve noncovalent interactions of proteins with various binding partners. Mass spectrometry plays an important role in all aspects of these research efforts. This article provides a survey of mass spectrometry-based approaches for exploring protein-ligand interactions. A wide array of techniques is available, and the choice of method depends on the specific problem at hand. For example, the high-throughput screening of compound libraries for binding to a specific receptor requires different approaches than structural studies on multiprotein complexes. This review is directed to readers wishing to obtain a concise yet comprehensive overview of existing experimental techniques. Specific emphasis is placed on emerging methods that have been developed within the last few years.

Subunit disassembly and unfolding kinetics of hemoglobin studied by time-resolved electrospray mass spectrometry.

We report the use of electrospray ionization (ESI) mass spectrometry (MS) in conjunction with online rapid mixing to monitor the kinetics of acid-induced ferrihemoglobin denaturation. Under equilibrium conditions, the hemoglobin mass spectrum is dominated by the intact heterotetramer. Dimeric and monomeric species are also observed at lower intensities. In addition, ionic signals corresponding to hexameric (tetramer-dimer) and octameric (tetramer x 2) hemoglobin species are observed. These complexes may represent weak solution-phase assemblies. The acid-induced denaturation process was monitored for reaction time ranging from 9 ms to approximately 3 s. The data obtained were subjected to a global analysis procedure which simultaneously fit all kinetic (ESI-MS intensity vs time) profiles to multiexponential expressions. Results of the global analysis are consistent with the coexistence of two subpopulations of tetrameric hemoglobin which differ in their disassembly rates and ESI charge states. The higher-charge state tetramer ions preferentially dissociate via a rapid pathway (tau(1) = 51 ms), resulting in the transient formation of a heme-saturated dimer, holo-alpha-globin, and a heme-deficient dimer. The latter is shown by MS/MS to be comprised of a heme-bound alpha-subunit complexed with an apo-beta-chain. The slow-decaying tetramer population, apparent at a slightly lower average charge state, breaks down into its monomeric constituents with no observable intermediate species (tau(2) = 390 ms). Surprisingly, unfolded apo-alpha-globin is formed more rapidly than unfolded apo-beta-globin. The appearance of the latter occurs with a relaxation time tau(3) of 1.2 s. It is postulated that accumulation of unfolded apo-beta-globin is delayed by transient population of an undetected unfolding intermediate.

Protein-folding kinetics and mechanisms studied by pulse-labeling and mass spectrometry.

The "protein-folding problem" refers to the question of how and why a denatured polypeptide chain can spontaneously fold into a compact and highly ordered conformation. The classical description of this process in terms of reaction pathways has been complemented by models that describe folding as a biased conformational diffusion on a multidimensional energy landscape. The identification and characterization of short-lived intermediates provide important insights into the mechanism of folding. Pulsed hydrogen/deuterium exchange (HDX) methods are among the most powerful tools for studying the properties of kinetic intermediates. Analysis of pulse-labeled proteins by mass spectrometry (MS) provides information that is complementary to that obtained in nuclear magnetic resonance (NMR) studies; NMR data represent an average of entire protein ensembles, whereas MS can detect co-existing protein species. MS-based pulse-labeling experiments can distinguish between folding scenarios that involve parallel pathways, and those where folding is channeled through obligatory intermediates. The proteolytic digestion/MS technique provides spatially resolved information on the HDX pattern of folding intermediates. This method is especially important for proteins that are too large to be studied by NMR. Although traditional pulsed HDX protocols are based on quench-flow techniques, it is also possible to use electrospray (ESI) MS to analyze the reaction mixture on-line and "quasi-instantaneously" after labeling. This approach allows short-lived protein conformations to be studied by their HDX level, their ESI charge-state distribution, and their ligand-binding state. Covalent labeling of free cysteinyl residues provides an alternative approach to pulsed HDX experiments. Another promising development is the use of synchrotron X-rays to induce oxidation at specific sites within a protein for studying their solvent accessibility during folding.

Conformational dynamics of partially denatured myoglobin studied by time-resolved electrospray mass spectrometry with online hydrogen-deuterium exchange.

This study demonstrates the use of electrospray mass spectrometry in conjunction with rapid online mixing ("time-resolved" ESI-MS) for monitoring protein conformational dynamics under equilibrium conditions. The hydrogen/deuterium exchange (HDX) kinetics of mildly denatured myoglobin (Mb) at pD 9.3, in the presence of 27% acetonitrile, were studied with millisecond time resolution. Analytical ultracentrifugation indicates that the average protein compactness under these solvent conditions is similar to that of native holomyoglobin (hMb). The mass spectrum shows protein ions in a wide array of charge and heme binding states, indicating the presence of multiple coexisting conformations. The experimental approach used allows the HDX kinetics of all of these species to be monitored separately. A combination of EX1 and EX2 behavior was observed for hMb ions in charge states 7+ to 9+, which predominantly represent nativelike hMb in solution. The EX1 kinetics are biphasic, indicating the presence of two protein populations that undergo conformational opening events with different rate constants. The EX2 kinetics observed for nativelike hMb are biphasic as well. All other charge and heme binding states represent non-native protein conformations that are involved in rapid interconversion processes, thus leading to monoexponential EX2 kinetics with a common rate constant. Burst phase labeling for these non-native proteins occurs at 125 sites. In contrast, the nativelike protein conformation shows burst phase labeling only for 88 sites. A kinetic model is developed which is based on the assumption of three distinct (un)folding units in Mb. The model implies that the free energy landscape of the protein exhibits a major barrier. The crossing of this barrier is most likely associated with slow, cooperative opening/closing events of the heme binding pocket. Rapid conformational fluctuations on either side of the barrier give rise to the observed EX2 kinetics. Simulated HDX kinetics based on this model are in excellent agreement with the experimental data.

Characterization of transient protein folding intermediates during myoglobin reconstitution by time-resolved electrospray mass spectrometry with on-line isotopic pulse labeling.

A novel technique for studying protein folding kinetics is presented. It is based on a continuous-flow setup that is coupled to an electrospray (ESI) mass spectrometer and allows initiation of a folding reaction, followed by isotopic pulse labeling. The protein is electrosprayed "quasi-instantaneously" after exposure to the deuterated solvent. This approach yields structural information from the ESI charge state distribution and from the H/D exchange levels of individual protein states, while at the same time noncovalent interactions can be monitored. This technique is used to study the reconstitution of holomyoglobin (hMb) from unfolded apomyoglobin (aMb) and free heme. MS/MS is used to establish that a short-lived folding intermediate with two heme groups attached represents a protein-bound heme dimer. This state appears to have a compactness close to that of native hMb; however, isotopic labeling indicates a significantly perturbed structure. Another intermediate is bound to a single heme group and shows a charge state distribution similar to that of unfolded aMb. Exchange levels exhibited by this state are lower than for unfolded aMb, indicating that fewer hydrogens are exposed to the solvent and/or that more of them are involved in hydrogen bonding. Native hMb leads to the formation of low charge state ions (hMb(9+), hMb(8+)) and shows low exchange levels. However, early during reconstitution, a slightly unfolded form of the heme-protein complex contributes to the observed hMb(9+) ions. A peak width analysis reveals that the structural heterogeneity of some of the observed protein species decreases as reconstitution proceeds.