Electrospray ionization (ESI) generates intact gas-phase ions from analytes in solution for mass spectrometric investigations. ESI can proceed via different mechanisms. Low molecular weight analytes follow the ion evaporation model (IEM), whereas the charged residue model (CRM) applies to large globular species. A chain ejection model (CEM) has been proposed for disordered polymers.
Electrospray ionization (ESI) of native proteins results in a narrow distribution of low protonation states. ESI for these folded species proceeds via the charged residue mechanism. In contrast, ESI of unfolded proteins yields a wide distribution of much higher charge states. The current work develops a model that can account for this effect. Recent molecular dynamics simulations revealed that ESI for unfolded polypeptide chains involves protein ejection from nanodroplets, representing a type of ion evaporation mechanism (IEM). We point out the analogies between this IEM, and the dissociation of gaseous protein complexes after collisional activation. The latter process commences with unraveling of a single subunit, in concert with Coulombically driven proton transfer. The subunit then separates from the residual complex as a highly charged ion. We propose that similar charge equilibration events accompany the IEM of unfolded proteins, thereby causing the formation of high ESI charge states. A bead chain model is used for examining how charge is partitioned as protein and droplet separate. It is shown that protein ejection from differently sized ESI droplets generates a range of protonation states. The predicted behavior agrees well with experimental data.
Hydrogen/deuterium exchange (HDX) mass spectrometry (MS) is a widely used technique for probing protein structure and dynamics. Exposure to D2O induces the deuteration of backbone N-H groups via a process that involves transient excursions to partially unfolded protein conformers. The resulting mass shifts can be probed by MS, usually in combination with proteolytic digestion and/or electron-based fragmentation. Studies on protein-ligand complexes represent a particularly important HDX/MS application. The prevailing view is that ligand binding should reduce deuteration rates, and it is often expected that this reduction will be most pronounced in the vicinity of the interaction site. Many protein-ligand systems do indeed behave in a fashion that is consistent with this paradigm. In this review we point out that the opposite effect may be encountered as well. Also, mixed scenarios are possible where ligand binding induces elevated HDX rates in some protein regions, whereas rates in other segments are reduced. We present a framework that links ligand-induced changes in HDX kinetics to alterations in the occupancy of excited protein conformers. Spontaneous ligand binding will always lower the free energy of the ground state. In contrast, the corresponding free energy shifts of excited states are largely unpredictable, giving rise to a range of possible HDX responses. "Type 1" scenarios, characterized by a reduction of HDX rates are just as feasible as "Type 2" behavior where deuteration is accelerated. Even "Type 0" phenomena may be encountered, where HDX rates are unaffected by the presence of ligand. Type 0/1/2 scenarios can coexist in the same protein (these terms are not to be confused with the EX1/EX2 expressions which refer to a different aspect of protein HDX). Allosteric effects and ligand-induced protein-protein contacts can affect the outcome of protein-ligand binding studies as well. In summary, comparative HDX measurements conducted in the presence and in the absence ligand provide a detailed fingerprint of biomolecular interactions. However, protein-ligand interactions can elicit a wide range of responses, and the interpretation of binding site mapping experiments may not always be straightforward.
F0F1 ATP synthase harnesses a transmembrane electrochemical gradient for the production of ATP. When operated in reverse, this multiprotein complex catalyzes ATP hydrolysis. In bacteria, the ε subunit is involved in regulating this ATPase activity. Also, ε is essential for coupling ATP hydrolysis (or synthesis) to proton translocation. The ε subunit consists of a β sandwich and two C-terminal helices, α1 and α2. The protein can switch from a compact fold to an alternate conformation where α1 and α2 are separated, resulting in an extended structure. ε from the thermophile Bacillus PS3 (Tε) binds ATP with high affinity such that this protein may function as an intracellular ATP level sensor. ATP binding to isolated Tε triggers a major conformational transition. Earlier data were interpreted in terms of an ATP + Tεextended → ATP·Tεcompact transition that may mimic aspects of the regulatory switching within F0F1 (Yagi et al. (2007) Proc. Natl. Acad. Sci. U.S.A., 104, 11233–11238). In this work, we employ complementary biophysical techniques for examining the ATP-induced conformational switching of isolated Tε. CD spectroscopy confirmed the occurrence of a large-scale conformational transition upon ATP binding, consistent with the formation of stable helical structure. Hydrogen/deuterium exchange (HDX) mass spectrometry revealed that this transition is accompanied by a pronounced stabilization in the vicinity of the ATP-binding pocket. Surprisingly, dramatic stabilization is also seen in the β8−β9 region, which is remote from the site of ATP interaction. Analytical ultracentrifugation uncovered a previously unrecognized feature of Tε: a high propensity to undergo dimerization in the presence of ATP. Comparison with existing crystallography data strongly suggests that the unexpected β8−β9 HDX protection is due to newly formed protein–protein contacts. Hence, ATP binding to isolated Tε proceeds according to 2ATP + 2Tεextended → (ATP·Tεcompact)2. Implications of this dimerization propensity for the possible role of Tε as an antibiotic target are discussed.
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