Robust Fluorescence Collection Module for Wide-Bore Ion Cyclotron Resonance Mass Spectrometers.

Mass spectrometers are at the heart of the most powerful toolboxes available to scientists when studying molecular structure, conformation, and dynamics in controlled molecular environments. Improved molecular characterization brought about by the implementation of new orthogonal methods into mass spectrometry-enabled analyses opens deeper insight into the complex interplay of forces that underlie chemistry. Here, we detail how one can add fluorescence detection to commercial ultrahigh-resolution Fourier transform ion cyclotron resonance (FT-ICR) mass spectrometers without adverse effects to its preexisting analytical tools. This advance enables measurements based on fluorescence detection, such as Förster resonance energy transfer (FRET), to be used in conjunction with other MS/MS techniques to probe the conformation and dynamics of large biomolecules, such as proteins and their complexes, in the highly controlled environment of a Penning trap.

Gas-Phase Fluorescence of Proflavine Reveals Two Close-Lying, Brightly Emitting States.

Surprising excitation-dependent, dual emission from a small organic model fluorophore is reported. Gas-phase fluorescence spectra of proflavine (a diaminoacridine) ions reveal two long-lived emitting states, with distinct bands separated by just 1700 cm-1. The relative intensities of these two bands depend on the excitation wavelength. Time-dependent density functional theory (TD-DFT) calculations support the existence of two close-lying singlet electronic states, with excitation into S2 predicted to be >1000-fold more likely than into S1. These data strongly suggest that internal conversion (IC) rates are suppressed relative to solvated proflavine, and that IC is competitive with intramolecular vibrational relaxation (IVR). This work offers an in-depth assessment of the gas-phase photophysics of a simple fluorophore that could open a new pathway to understanding dual emission in fluorophores.

Intrinsic Turn-On Response of Thioflavin†T in Complexes.

The fluorescence enhancement ("turn-on") response of the amyloid-sensing dye thioflavin T (ThT) is examined in vacuo, where solvent interactions are absent. Upon the complexation of ThT with a derivatized ß-cyclodextrin, heptakis-[6-deoxy-6-(3-sulfanylpropanoic acid)]-ß-cyclodextrin, turn-on responses in both the gas phase and solution phase were observed. In contrast, turn-on response was not detected when ThT was bound to gaseous cucurbit[7]uril or human telomeric DNA 22AG, whereas clear turn-on response occurs in solution. The observed difference in turn-on response in the gas phase emphasizes the key interplay between chromophore, host and solvent and demonstrates the utility of gas-phase spectroscopy to tease out the balance among intermolecular forces driving the behavior of important chromophores in solution.

Protomers of DNA-binding dye fluoresce different colours: intrinsic photophysics of Hoechst 33258.

A key utility of fluorophores lies in sensing applications: the detection of changes to emission caused by differences in their microenvironment. The rational design of fluorescent sensors remains a significant challenge because of the complexity of factors which control molecular deactivation pathways. Here, in an effort to define the structural criteria underlying the fluorescence turn-on response of Hoechst 33258 (H33258) upon binding to the DNA minor groove, we examine this sensor's intrinsic properties in minimalist microenvironments. We first characterised the intrinsic photophysics of gaseous mono- and di-protonated H33258 ions, then introduced intermolecular interactions by complexation with double-stranded (ds) DNA. Selected-ion laser-induced fluorescence (SILIF) and photodissociation of the gaseous monoprotomers indicate the presence of multiple populations with distinct fluorescence and dissociation properties. We assign one of these to a kinetically-trapped form which is protonated at the site favored in solution. The other form exhibits a more intense emission band which is shifted by more than 6000 cm-1 to the red of the first form. Quantum chemical calculations reveal that this second population is likely a newly-identified protomer, which is considerably more stable in the gas phase than conformations with the solution protonation site. Two routes that increase the fluorescence of H33258 in solution - formation of the diprotomer and complexation with dsDNA - do not produce an increase in fluorescence in the gas phase. However, two other outcomes parallel behaviour. First, the similarity of action spectra of the gaseous dsDNA-H33258 complex and the unbound diprotomer suggest that the dye may be diprotomeric when in complex with gaseous dsDNA. Second, the photodissociation power dependence measurements indicate the presence of at least two distinct populations of both H33258 in complex with dsDNA and in its unbound diprotomeric form. Overall, the results reported here reveal unexplored aspects of the potential energy landscape of H33258, including a new, stable, highly-fluorescent form that may be useful to consider in sensing applications. Moreover, the results reinforce how structure, deactivation pathways and other photophysical properties are intertwined for this DNA-binding dye, which may offer strategies for improved control of DNA-targeting drugs and sensors.

The effect of methylation on the intrinsic photophysical properties of simple rhodamines.

The rational design of rhodamines and other fluorescent probes for different functions would benefit from an improved understanding of their photophysics. Key photophysical properties, including fluorescence, depend on the outcome of competing pathways for intra- and intermolecular energy flow within and from excited state molecules. In the work reported here, we simplify this complex landscape by eliminating solvent interactions, revealing intrinsic photophysical effects of systematic structural changes. Selected-ion laser-induced fluorescence (SILIF) is used to examine the effects of stepwise N-methylation on a rhodamine scaffold, starting with the simple rhodamine 123, in the gas phase. Fluorescence excitation and emission spectra together with fluorescence lifetime measurements are reported and discussed. While the systematic decrease in gas-phase 0-0 transition energy by 500 cm-1 per methylation is in line with expectations from solution studies, other trends are observed that are not apparent in solution studies. These include a notable narrowing of spectral profiles, three-fold decrease in Stokes shift and an ∼three-fold increase in brightness as the number of N-methylations rises from zero to four. Most surprising, while rhodamine 123 displays the expected textbook mirror-image symmetry between excitation and emission spectra, the emission spectrum of its tetra N-methylated derivative is ∼30% broader than the excitation spectrum. The likelihood that this difference reflects emission prior to complete vibrational redistribution of energy within the excited state of the larger rhodamines is discussed. This suggestion goes against conventional wisdom about the timescale of energy redistribution within molecules of this size, an understanding which was developed from solution studies. Overall, this study furthers our understanding of energy flow within an important class of fluorophores, highlights the consequences of energy flow between fluorophores and surrounding solvent, and provides benchmark experimental data for solvent-free chromophores to assist and calibrate computational work.

Hydrogen-Deuterium Exchange and Electron Capture Dissociation to Interrogate the Conformation of Gaseous Melittin Ions.

There is a need in the field of biological mass spectrometry for structural tools which can report on regional, rather than solely global, structure of gaseous protein ions. Site-specific hydrogen-deuterium (H/D) exchange has shown promise in fulfilling this need, but requires additional method development to prove its utility. In this study, we use H/D exchange and electron capture dissociation (ECD) to probe the gaseous structure of two peptides which are α-helical in solution and which differ by a single point mutation. Global H/D exchange levels, ECD fragmentation profiles, and region specific H/D exchange profiles are compared between wild type (WT) melittin, which adopts a hinged helix conformation in solution, and a mutant P14A melittin which folds into a single helix in solution. High protection from H/D exchange by both peptides is consistent with retention of secondary structure in the gas phase (or refolding into some other compact structure). The P14A mutant melittin exhibits lower ECD fragmentation efficiency than WT melittin, suggesting that it contains more secondary structure in the gas phase, which may indicate that these peptides retain some memory of their solution-phase structures. Examination of the isotopic distributions of fragment ions derived from H/D exchange with subsequent ECD reveals that the C-terminus of these peptides adopts multiple conformations. The results reported here offer insight into the stability of alpha helices in the gas phase, and also highlight the value of combining gas-phase H/D exchange with electron capture dissociation to interrogate gaseous peptide conformation.

Deuterium isotope effect in fluorescence of gaseous oxazine dyes.

The increased utility of fluorescence-based methods in recent years has highlighted the need for brighter, more efficient fluorophores. In order to design these fluorophores, an improved fundamental understanding is necessary of the structural components that intrinsically effect fluorescence efficiency. Here, we characterize the intrinsic effects of deuteration on fluorescence from gaseous oxazine dyes, without the influence of dye-solvent interactions, by making use of an ion trap mass spectrometer that has been altered to enable optical measurements. Comparison of emission spectra of four oxazine dyes: cresyl violet, oxazine 4, oxazine 170, and darrow red, show little change in profile upon deuteration of amine groups. However, deuteration significantly increases the efficiency of fluorescence with an increase in fluorescence lifetime and brightness by 10-23% for the gaseous dyes. This increase is less than half that of the quantum yield increase observed in deuterated solution. This indicates the large fluorescence efficiency changes for the oxazine dyes in deuterated solution result from a combination of both intrinsic effects as well as substantial contribution from altered fluorophore-solvent interactions. The intrinsic effects behind increased lifetime upon deuteration are explored using time-dependent density functional theory (TD-DFT) calculations of potential energy surfaces (PESs) for ground and low lying excited electronic states. In accord with experimental observations, calculated S1-S0 emission spectra show only minor differences between deuterated and non-deuterated forms indicating that the deuteration does not affect the radiative channel appreciably. Relaxed PES scans along the torsional motions of the amino groups reveal that the increase in lifetimes upon deuteration is likely due to quenching of different radiationless changes channels in different oxazine dyes. Calculations suggest that tunneling to access twisted intramolecular charge transfer states in S1 is critical in several of the oxazines. However, in at least one of the dyes examined, the large isotope effect is more likely due to differences in intersystem crossing rates. Overall, this combined experimental and computational investigation elucidates the photophysics of a well-known fluorescent scaffold and provides insight into how small differences can dramatically affect fluorescence outcomes.

Idebenone and coenzyme Q10 are novel PPARα/γ ligands, with potential for treatment of fatty liver diseases.

Current peroxisome proliferator-activated receptor (PPAR)-targeted drugs, such as the PPARγ-directed diabetes drug rosiglitazone, are associated with undesirable side effects due to robust agonist activity in non-target tissues. To find new PPAR ligands with fewer toxic effects, we generated transgenic zebrafish that can be screened in high throughput for new tissue-selective PPAR partial agonists. A structural analog of coenzyme Q10 (idebenone) that elicits spatially restricted partial agonist activity for both PPARα and PPARγ was identified. Coenzyme Q10 was also found to bind and activate both PPARs in a similar fashion, suggesting an endogenous role in relaying the states of mitochondria, peroxisomes and cellular redox to the two receptors. Testing idebenone in a mouse model of type 2 diabetes revealed the ability to reverse fatty liver development. These findings indicate new mechanisms of action for both PPARα and PPARγ, and new potential treatment options for nonalcoholic fatty liver disease (NAFLD) and steatosis.This article has an associated First Person interview with the first author of the paper.

Tuning the Intrinsic Photophysical Properties of Chlorophyll a.

In nature, the finely tuned photophysical properties of chlorophyll a (Chla) are vital to the capture and transfer of sunlight during photosynthesis. In order to better understand how these properties are influenced by the molecular environment, we have examined the intrinsic spectroscopy of Chla in vacuo. Visible photodissociation action spectra (an indirect measure of absorption) of gaseous protonated Chla and Chla complexed with metal cations are reported. These show that spectral features within the Soret band (∼350-445 nm) have markedly different intensities depending on the identity of the cation. In contrast, fluorescence emission spectra of metalated Chla complexes show only small dependences on the identity of the metal ion, with emission maxima shifting from 661 to 654 nm. Remarkably, replacing the metal ion with a proton turns off the fluorescence of this key pigment. Density functional theory geometry-optimized structures indicate that the most favorable site of protonation differs from that of metal cationization, and may help explain the surprising on/off behavior of Chla's intrinsic fluorescence.

Probing the Gaseous Structure of a ß-Hairpin Peptide with H/D Exchange and Electron Capture Dissociation.

An improved understanding of the extent to which native protein structure is retained upon transfer to the gas phase promises to enhance biological mass spectrometry, potentially streamlining workflows and providing fundamental insights into hydration effects. Here, we investigate the gaseous conformation of a model ß-hairpin peptide using gas-phase hydrogen-deuterium (H/D) exchange with subsequent electron capture dissociation (ECD). Global gas-phase H/D exchange levels, and residue-specific exchange levels derived from ECD data, are compared among the wild type 16-residue peptide GB1p and several variants. High protection from H/D exchange observed for GB1p, but not for a truncated version, is consistent with the retention of secondary structure of GB1p in the gas phase or its refolding into some other compact structure. Four alanine mutants that destabilize the hairpin in solution show levels of protection similar to that of GB1p, suggesting collapse or (re)folding of these peptides upon transfer to the gas phase. These results offer a starting point from which to understand how a key secondary structural element, the ß-hairpin, is affected by transfer to the gas phase. This work also demonstrates the utility of a much-needed addition to the tool set that is currently available for the investigation of the gaseous conformation of biomolecules, which can be employed in the future to better characterize gaseous proteins and protein complexes. Graphical Abstract ᅟ.

Sensitive probes of protein structure and dynamics in well-controlled environments: combining mass spectrometry with fluorescence spectroscopy.

Combining the selectivity of mass spectrometry (MS) with laser-induced fluorescence (LIF) presents a promising route to probe the intrinsic conformation, stability and dynamics of biological macromolecules. However, applications to proteins are in their infancy. Recent advances include the realization of Förster (fluorescence) resonance energy transfer (FRET) to provide nm-range distance constraints in de-solvated proteins, and measurement of dynamic fluorescence quenching rates to assess shorter-range interactions in peptides and Trp-cage. Temperature-dependent experiments employing FRET and dynamic quenching as conformational probes enable determination of enthalpy and entropy of conformational change in de-solvated biomolecules. These developments show the feasibility of using MS-LIF to dissect complex molecular interactions. For example, MS-LIF of protein-ligand complexes and partially hydrated proteins will better elucidate the energetics of specific binding interactions and the role of the solvent in protein structure and folding.

Gas-Phase FRET Efficiency Measurements To Probe the Conformation of Mass-Selected Proteins.

Electrospray ionization and mass spectrometry have revolutionized the chemical analysis of biological molecules, including proteins. However, the correspondence between a protein's native structure and its structure in the mass spectrometer (where it is gaseous) remains unclear. Here, we show that fluorescence (Förster) resonance energy transfer (FRET) measurements combined with mass spectrometry provides intramolecular distance constraints in gaseous, ionized proteins. Using an experimental setup which combines trapping mass spectrometry and laser-induced fluorescence spectroscopy, the structure of a fluorescently labeled mutant variant of the protein GB1 was probed as a function of charge state. Steady-state fluorescence emission spectra and time-resolved donor fluorescence measurements of mass-selected GB1 show a marked decrease in the FRET efficiency with increasing number of charges on the gaseous protein, which suggests a Coulombically driven unfolding and expansion of its structure. This lies in stark contrast to the pH stability of GB1 in solution. Comparison with solution-phase single-molecule FRET measurements show lower FRET efficiency for all charge states of the gaseous protein examined, indicating that the ensemble of conformations present in the gas phase is, on average, more expanded than the native form. These results represent the first FRET measurements on a mass-selected protein and illustrate the utility of FRET for obtaining a new kind of structural information for large, desolvated biomolecules.

Moving in on the Action: An Experimental Comparison of Fluorescence Excitation and Photodissociation Action Spectroscopy.

Photodissociation action spectroscopy is often used as a proxy for measuring gas-phase absorption spectra of ions in a mass spectrometer. Although the potential discrepancy between linear optical and photodissociation spectra is generally acknowledged, direct experimental comparisons are lacking. In this work, we use a quadrupole ion trap that has been modified to enable both photodissociation and laser-induced fluorescence to assess how closely the visible photodissociation action spectrum of a fluorescent dye reflects its fluorescence excitation spectrum. Our results show the photodissociation action spectrum of gaseous rhodamine 110 is both substantially narrower and slightly red-shifted (∼120 cm(-1)) compared to its fluorescence excitation spectrum. Power dependence measurements reveal that the photodissociation of rhodamine 110 requires, on average, the absorption of three photons whereas fluorescence is a single-photon process. These differing power dependences are the key to interpreting the differences in the measured spectra. The experimental results provide much-needed quantification and insight into the differences between action spectra and linear optical spectra, and emphasize the utility of fluorescence excitation spectra to provide a more reliable benchmark for comparison with theory.

Fluorescence imaging for visualization of the ion cloud in a quadrupole ion trap mass spectrometer.

Laser-induced fluorescence is used to visualize populations of gaseous ions stored in a quadrupole ion trap (QIT) mass spectrometer. Presented images include the first fluorescence image of molecular ions collected under conditions typically used in mass spectrometry experiments. Under these "normal" mass spectrometry conditions, the radial (r) and axial (z) full-width at half maxima (FWHM) of the detected ion cloud are 615 and 214 µm, respectively, corresponding to ~6% of r0 and ~3% of z0 for the QIT used. The effects on the shape and size of the ion cloud caused by varying the pressure of helium bath gas, the number of trapped ions, and the Mathieu parameter q z are visualized and discussed. When a "tickle voltage" is applied to the exit end-cap electrode, as is done in collisionally activated dissociation, a significant elongation in the axial, but not the radial, dimension of the ion cloud is apparent. Finally, using spectroscopically distinguishable fluorophores of two different m/z values, images are presented that illustrate stratification of the ion cloud; ions of lower m/z (higher qz) are located in the center of the trapping region, effectively excluding higher m/z (lower qz) ions, which form a surrounding layer. Fluorescence images such as those presented here provide a useful reference for better understanding the collective behavior of ions in radio frequency (rf) trapping devices and how phenomena such as collisions and space-charge affect ion distribution.

Understanding photophysical effects of cucurbituril encapsulation: a model study with acridine orange in the gas phase.

Encapsulation of dyes by cucurbituril macrocycles has proven profitable as a strategy to alter fluorescence characteristics in useful ways. Encapsulation generally results in longer fluorescence lifetimes, enhanced brightness, and solvatochromic effects not normally seen in the condensed phase. These effects have been attributed variously to both the removal of interactions with solvent molecules and to the confined environment of extremely low polarizability provided by the cucurbituril interior. It is difficult to disentangle these effects in solution. Here, we present results from gas-phase experiments designed to separate these effects, using cucurbit[7]uril (CB7), and the cationic dye acridine orange (AOH(+)) as a probe. Fluorescence properties of gaseous AOH(+) are compared with those of the gaseous AOH(+)-CB7 complex and with the properties of the dye and complex in aqueous solution. The dependence on the local environment of several spectroscopic properties is discussed, including the fluorescence excitation and emission maxima, the size of the Stokes shift, fluorescence lifetime and relative brightness. An understanding of the modulation of fluorescence properties by the local environment, such as that promoted by this work, will aid in the rational design of improved fluorophores and fluorescent sensors.

Fluorescence and electronic action spectroscopy of mass-selected gas-phase fluorescein, 2',7'-dichlorofluorescein, and 2',7'-difluorofluorescein ions.

2',7'-Dichloro- and 2',7'-difluorofluoresceins are superior alternatives to underivatized fluorescein. Although several studies characterizing their condensed-phase photophysical properties have been reported, little is known about their intrinsic characteristics. Here, the gas-phase properties of three charge states of each fluorescein are characterized using a quadrupole ion trap mass spectrometer which has been modified for spectroscopy. Electronic action spectra, constructed by monitoring the extent of photodissociation as a function of excitation wavelength, indicate that the gaseous dianions and cations resemble their solution-phase counterparts. In contrast, a large shift in the electronic action spectra of the monoanions indicates the presence of a different tautomer in the gas phase than that present in solution. The gaseous monoanion is deprotonated on the xanthene ring, rather than being deprotonated on the pendant group as found in soluion. The dianions and cations do not emit detectable fluorescence in the gas phase. In contrast, the monoanions do fluoresce, but the emission intensity is low and the spectra are broad. This work illustrates the effect of halogenation on the intrinsic properties of the dyes and provides useful fundamental understanding that promises to aid the development more robust fluorescent dyes.

Ligand migration in the gaseous insulin-CB7 complex--a cautionary tale about the use of ECD-MS for ligand binding site determination.

Knowledge of the structure of protein-ligand complexes can aid in understanding their roles within complex biological processes. Here we use electrospray ionization (ESI) coupled to a Fourier transform ion cyclotron resonance mass spectrometer to investigate the noncovalent binding of the macrocycle cucurbit[7]uril (CB7) to bovine insulin. Recent condensed-phase experiments (Chinai et al., J. Am. Chem. Soc. 133:8810-8813, 2011) indicate that CB7 binds selectively to the N-terminal phenylalanine of the insulin B-chain. Competition experiments employing ESI mass spectrometry to assess complex formation between CB7 and wild type insulin B-chain vs. a mutant B-chain, confirm that the N-terminal phenylalanine plays in important role in solution-phase binding. However, analysis of fragment ions produced by electron capture dissociation (ECD) of CB7 complexed to intact insulin and to the insulin B-chain suggests a different picture. The apparent gas-phase binding site, as identified by the ECD, lies further along the insulin B-chain. Together, these studies thus indicate that the CB7 ligand migrates in the ESI mass spectrometry analysis. Migration is likely aided by the presence of additional interactions between CB7 and the insulin B-chain, which are not observed in the crystal structure. While this conformational difference may result simply from the removal of solvent and addition of excess protons by the ESI, we propose that the migration may be enhanced by charge reduction during the ECD process itself because ion-dipole interactions are key to CB7 binding. The results of this study caution against using ECD-MS as a stand-alone structural probe for the determination of solution-phase binding sites.

Structural interrogation of electrosprayed peptide ions by gas-phase H/D exchange and electron capture dissociation mass spectrometry.

The structural characterization of gaseous biomolecular ions remains a challenging task. Here, we employ a combination of gas-phase hydrogen-deuterium exchange (HDX) and electron capture dissociation (ECD) mass spectrometry for gaining insights into the properties of two electrosprayed peptides: RA(9)K and RG(9)K. Mass analysis of ECD fragments provides spatially resolved labeling information. ND(3)-mediated HDX at peptide termini and amino acid side chains goes to completion within 1 s. Backbone amide labeling occurs more slowly, and proceeds in a structurally sensitive fashion. HDX is more extensive for RG(9)K than for RA(9)K, suggesting a more "open" conformation for the former. Residues 7-10 in RA(9)K are strongly protected, which indicates the presence of stable backbone hydrogen bonds at these sites. Our findings are consistent with the results of previous ion mobility measurements and computational investigations. Overall, it appears that the combination of gas-phase HDX and ECD represents a viable approach for uncovering structural features of biomolecular ions in the gas phase.

Infrared multiple photon dissociation action spectroscopy and computational studies of mass-selected gas-phase fluorescein and 2',7'-dichlorofluorescein ions.

Fluorescein (FL) and its derivative 2',7'-dichlorofluoroescein (DCF) are well-known fluorescent dyes used in many biological and biochemical applications. Although extensive studies have been carried out to investigate their chemical and photophysical properties in different solvent media, little is known about their intrinsic behaviors in the gas phase. Here, infrared multiple photon dissociation (IRMPD) action spectra are reported for the three charged prototropic forms of FL and DCF and compared with computed IR spectra from electronic structure calculations. In each case, the measured spectra show good agreement with the calculated spectra of the lowest energy computed conformer. Moreover, the major bands of the monoanion IRMPD spectra show striking similarities to those of the dianions and are quite different from those of the cations. These experimental results clearly indicate that the gaseous monoanions are predominantly deprotonated on the xanthene chromophore, rather than the benzoate deprotonation site favored in solution. Investigations such as this, which provide a better understanding of intrinsic properties of ionic dyes, forms a baseline from which to elucidate solvent effects and will aid the rational design of dyes possessing desirable fluorescence properties.

Gas-phase fluorescence excitation and emission spectroscopy of three xanthene dyes (rhodamine 575, rhodamine 590 and rhodamine 6G) in a quadrupole ion trap mass spectrometer.

The gas-phase fluorescence excitation, emission and photodissociation characteristics of three xanthene dyes (rhodamine 575, rhodamine 590, and rhodamine 6G) have been investigated in a quadrupole ion trap mass spectrometer. Measured gas-phase excitation and dispersed emission spectra are compared with solution-phase spectra and computations. The excitation and emission maxima for all three protonated dyes lie at higher energy in the gas phase than in solution. The measured Stokes shifts are significantly smaller for the isolated gaseous ions than the solvated ions. Laser power-dependence measurements indicate that absorption of multiple photons is required for photodissociation. Redshifts and broadening of the dispersed fluorescence spectra at high excitation laser power provide evidence of gradual heating of the ion population, pointing to a mechanism of sequential multiple-photon activation through absorption/emission cycling. The relative brightness in the gas phase follows the order R575(1.00) < R590(1.15) < R6G(1.29). Fluorescence emission from several mass-selected product ions has been measured.