The effect of charge and temperature on gas phase protein conformational landscapes : an ion mobility mass spectrometry investigation

Jhingree, Jacquelyn

January 2018

The amino acid sequence of a protein determines its 3D fold, the ease with which its native structure is formed, its function, the conformational preferences sampled and the tendency to interact with itself (aggregation) and binding partners. In addition, certain conformational preferences can lead to dysfunction resulting in different diseased states in organisms. All of these conformations can be described by a protein's energy landscape; a native (functional) state being localised at the energy minimum. As protein dynamics is crucial to function it is important to monitor the sampling of different conformations. Thus the work in this thesis reports on two methods for monitoring protein conformation and conformational change in the gas phase using ion mobility mass spectrometry (IM-MS). The measurement from IM-MS methods allow the determination of a collision cross section (CCS) which is an indicator of a molecule's 3D shape. First, the effect of charge on protein structure is investigated by manipulation of protein charge, post electrospray ionisation (ESI), by exposure to radical anions of the electron transfer reagent, 1,3-dicyanaobenzene; the charge reduced products formed are the result of electron transfer to the charged protein without any dissociation (ETnoD). IM-MS is used to monitor the conformational preferences of the altered and unaltered precursor and its products. Secondly, intermediate (transient) conformers are formed by activating the charged protein in the source region of an instrument post ESI. Activation of the protein precursor allows the sampling of different conformational preferences after energetic barriers have been overcome; IM-MS following activation allows for the monitoring of protein conformational change before and after. Further, variable temperature (VT) IM-MS allows for the deduction of intermediate structures with a focus on measurements at cryogenic temperatures whereby intermediate structures can be 'frozen out' post activation; intermediate structures which would otherwise anneal out at room temperature. With both methods a range of conformer populations are mapped for different protein molecules sampled upon different energetic inputs (via activation) and the disruption of intramolecular neutralising contacts/salt bridges (via charge reduction) one of the main interactions responsible for maintaining the structural integrity (3D fold) of proteins.

540

Conformational Dynamics of Biomolecules by Trapped Ion Mobility Spectrometry Dynamics

Molano-Arévalo, Juan Camilo

16 April 2018

One of the main goals in structural biology is to understand the folding mechanisms and three-dimensional structure of biomolecules. Many biomolecular systems adopt multiple structures as a function of their microenvironment, which makes them difficult to be characterized by traditional structural biology tools (e.g., NMR, X-ray crystallography). As an alternative, complementary tools that can capture and sample multiple conformations needed to be developed. In the present work, we pioneered the application of a new variant of ion mobility spectrometry, trapped ion mobility spectrometry (TIMS), which provides high mobility resolving power and the possibility to study kinetically trapped intermediates as a function of the starting solution (e.g., pH and organic content) and gas-phase conditions (e.g., collisional activation, molecular dopants, hydrogen/deuterium back-exchange). When coupled to mass spectrometry (TIMS-MS), action spectroscopy (IRMPD), molecular dynamics and biochemical approaches (e.g., fluorescence lifetime spectroscopy), a comprehensive description of the biomolecules dynamics and tridimensional structural can be obtained. These new set of tools were applied for the first time to the study of Flavin Adenine Dinucleotide (FAD), Nicotineamide Adenine Dinucleotide (NAD), globular protein cytochrome c (cyt c), the 31 knot YibK protein, 52 knot ubiquitin C terminal hydrolase (UCH) protein, and the 61 knot halo acid dehydrogenase (DehI) protein.

Ion Mobility Spectrometry

Mass Spectrometry

Structural Biology

Analytical Chemistry

Analytical Chemistry

Structural Biology

Discovery and Targeted Monitoring of Biomarkers Using Liquid Chromatography, Ion Mobility Spectrometry , and Mass Spectrometry

Adams, Kendra J

22 March 2018

The complexity of biological matrices makes the detection and quantification of compounds of interest challenging. For successful targeted or untargeted identification of compounds within a biological environment, the use of complementary separation techniques is routinely required; in many situations, a single analytical technique is not sufficient. In the present dissertation, a multidimensional analytical technique was developed and evaluated, a combination of new sample preparation/extraction protocols, liquid chromatography, trapped ion mobility and mass spectrometry (e.g., LC-TIMS-MS and LC-TIMS-MS/MS). The performance of these techniques was evaluated for the detection of polybrominated diphenyl ethers metabolites, polychlorinated biphenyls metabolites in human plasma, opioid metabolites in human urine, and lipids in Dictyostelium discoideum cells. The new workflows and methods described in the body of this dissertation allows for rapid, selective, sensitive and high-resolution detection of biomarkers in biological matrices with increased confidence, sensitivity and shorter sample preparation and analysis time.

Analytical Chemistry

Mass Spectrometry

Trapped Ion Mobility Spectrometry

Liquid Chromatography

Biomarkers

Endocrine Disruptors

Lipids

Analytical Chemistry

In-depth determination of the connectivity and topology of (co)polymers by state-of-the-art mass spectrometry

De Winter, Julien J

21 March 2011

Nowadays, polymer chemists undertake considerable efforts to achieve the preparation of new macromolecules and a perfect control over the macromolecular engineering, i.e. the mass parameters but also over the chain and end-group compositions, topology, etc… is definitively expected. In addition, more complex architectures, such as brush (co)polymers, jellyfish-like topologies…, are required to improve or drastically modify the physicochemical properties of the materials. As a direct consequence of the development of such complex molecular objects, sophisticated techniques are required for the in-depth characterization of the macromolecules, since the exact compositions and structures should be fully and unambiguously identified. Given the fact that the usual characterization tools such as Nuclear Magnetic Resonance (NMR) and Gel Permeation Chromatography (GPC) are extensively used, their abilities have been intensively developed to account for the increasing complexity and diversity of the targeted molecules. Nevertheless, all the usual techniques are averaging methodologies since they only provide pieces of information about the polymer mixture instead of affording data on the individual macromolecules. Since few decades, mass spectrometry (MS) has become as used as NMR and GPC for polymer characterization. In the context of large molecules analysis, MS undoubtedly underwent an impressive craze with the development of two modern ionization procedures, namely Electrospray Ionization (ESI) and Matrix-assisted Laser Desorption/Ionization (MALDI). Those ionization procedures permit the vaporization of macromolecules allowing the intact polymers to be analyzed without a too extensive level of degradation. ESI and MALDI are often considered as soft ionization methods since they offer the possibility to observe ions corresponding to the intact molecules. After their production in the ion source, ions corresponding to the polymer molecules can be mass analyzed by the mass spectrometer and important parameters such as the molecular weight distribution (Mn and Mw), polydispersity index (PDI), the nature of the monomer units and the end-groups can be derived from the measure of the mass-to-charge ratios of the produced ions. In the first part of the present thesis, we studied the MS behavior of different classes of polymers when submitted to ESI and MALDI ionizations. The investigations were devoted to the validation of MS as a truly reliable methodology for fragile polymers such as aliphatic polyesters for instance. In this context, a preliminary MS investigation on semi-telechelic polyethers revealed the importance of the source parameters for the characterization of polymers presenting fragile moieties. We also demonstrated the huge importance of the matrix molecule selection for the MALDI analyses of polymers. In particular, we introduced a new matrix for the MALDI measurements of electroconjugated polymers such as polythiophenes. After the study of the influence of the source parameters on the MS data, a complete study by single stage MS and double stage MS (MS/MS) on newly synthesized polylactides (PLA) was performed. The PLA samples were prepared following original procedures using carbene as catalyst. Finally, to achieve the MS study of PLA ions, we used ion mobility-mass spectrometry (IM-MS) experiments to obtained information on the tridimensional structure of the gas phase PLA ions. In particular, we put a special emphasis on the influence of the charge and size of the polymer chains on their gas-phase conformations. The conclusions derived from the MS/MS and IM-MS results were fully supported by theoretical calculations. In the second part of the thesis, the acquired MS experience was applied to the fine characterization of macromolecules presenting complex architectures obtained by two different polymerization procedures: (i) cobalt-mediated radical polymerization of inter alia acrylonitrile and vinyl acetate and (ii) ring-opening polymerization (ROP) of lactones using non-organometallic catalysts. In particular, mass spectrometry was used to tune the experimental conditions for the ROP of â-lactones using different phosphazenes as catalysts. As an ultimate conclusion, this work points to the very efficient synergy between polymer synthesis, mass spectrometry and theoretical calculations. We believe that this thesis paves the way for innumerable possibilities in the future.

ion mobility

collision induced dissociation

mass spectrometry

macromolecules

controlled synthesis

biodegradable polymers

Comparison of Ion Mobility Spectrometry and Gas Chromatography with Dry Electrolytic Conductivity Detection for the Determination of Polychlorinated Biphenyls in Humus-Rich Soil

Orton, Maureen L.

January 2007

Ion mobility spectroscopy (IMS) has been showen to provide fast on-site analysis of coarse sandy soil for the determination of polychlorinated biphenyls (PCBs). However the presence of humus results in instrument foaling and extensive down time do to instrument clean-up. For this reason a method was investigated for the ultrasonic extraction of PCBs from humus-rich soil that could be used at remote locations. Analysis of the extracted PCBs was conducted using 1) IMS and 2) gas chromatogram equipped with a dry electolytic conductiviy detector (GC/DELCD). The research conducted for this thesis outlines the method development and analysis of PCBS using these two instruments. The IMS analyiss was found to be complicated by co-extracted matrix compounds. Results and limitations of IMS analysisare present here. The method development and validation of a method for the ultrasonic extraction and analysis of PCBs using the GC/DELCD is provided.

Ion Mobility Spectroscopy

GC/DELCD

extraction of PCBs from Soil

on-site analysis

Chemistry

Laser Desorption Solid Phase Microextraction

Wang, Yan

January 2006

The use of laser desorption as a sample introduction method for solid phase microextraction (SPME) has been investigated in this research project. Three different types of analytical instruments, mass spectrometry (MS), ion mobility spectrometry (IMS) and gas chromatography (GC) were employed as detectors. The coupling of laser desorption SPME to these three instruments was constructed and described in here. <br /><br /> Solid phase microextraction/surface enhanced laser desorption ionization fibers (SPME/SELDI) were developed and have been coupled to two IMS devices. SPME/SELDI combines sampling, sample preparation and sample introduction with the ionization and desorption of the analytes. Other than being the extraction phase for the SPME fiber, the electro-conductive polymer coatings can facilitate the ionization process without the involvement of a matrix assisted laser desorption/ionization (MALDI) matrix. The performance of the SPME coatings and the experimental parameters for laser desorption SPME were investigated with the SPME/SELDI IMS devices. The new SPME/SELDI-IMS 400B device has a faster data acquisition system and a more powerful data analysis program. The optimum laser operation parameters were 250 <em>&mu;J</em> laser energy and 20 <em>Hz</em> repetition rate. Three new SPME coatings, polypyrrole (PPY), polythiophene (PTH) and polyaniline (PAN) were developed and evaluated by an IMS and a GC. The PPY coating was found to have the best performance and was used in most of the experiments. The characteristics of the PPY and the PTH SPME/SELDI fiber were then assessed with both IMS and MS. Good linearity could be observed between the fiber surface area and the signal intensity, and between the concentration and the signal intensities. <br /><br /> The ionization mechanism of poly(ethylene glycol) 400 (PEG) was studied with the SPME/SELDI-IMS 400B device. It was found that the potassiated ions and sodiated ions were both present in the ion mobility spectra. The results obtained with quadrupole time-of-flight (QTOF) MS confirmed the presence of both potassiated and sodiated ions. This result suggested that cationization is the main ionization process when polymers are directly ionized from the PPY coated silica surface. Four PEGs with different average molecular weights and poly(propylene glycol) 400 were also tested with this SPME/SELDI device. The differences between the ion mobility spectra of these polymers could be used for the fast identification of synthetic polymers. <br /><br /> The SPME/SELDI fibers were then coupled to QTOF MS and hybrid quadrupole linear ion trap (QqLIT) MS, respectively. Improved sensitivity could be achieved with QqLIT MS, as the modified AP MALDI source facilitated the ion transmission. The application of method for analysis of urine sample and the bovine serum albumin (BSA) digest were demonstrated with both PPY and PTH fibers. The LOD for leucine enkephalin in urine was determined to be 40 <em>fmol &mu;L^-1</em> with PTH coated fiber; and the LOD for the BSA digest was 2 <em>fmol &mu;L^-1</em> obtained with both PTH and PPY fibers. <br /><br /> A new multiplexed SPME/AP MALDI plate was designed and evaluated on the same QqLIT MS to improve the throughput, and the performance of this technique. The experimental parameters were optimized to obtain a significant improvement in performance. The incorporation of diluted matrix to the extraction solution improved the absolute signal and S/N ratio by 104X and 32X, respectively. The incorporation of reflection geometry for the laser illumination improved the S/N ratio by more than two orders of magnitude. The fully optimized high throughput SPME/AP MALDI configuration generated detection limit improvements on the order of 1000-7500X those achieved prior to these modifications. This system presents a possible alternative for qualitative proteomics and drug screening. <br /><br /> Laser desorption SPME as a sample introduction method for the fast analysis of non-volatile synthetic polymers was also demonstrated here. The coupling of laser desorption SPME to GC/FID and GC/MS was performed, and the advantage of laser desorption over traditional thermal desorption was demonstrated in this research. Laser desorption PEG 400 was observed more effcient than thermal desorption. Good separation was obtained even with a 1-m or 2-m column. These results demonstrate the potential of laser desorption SPME as a sample introduction method for the fast GC analysis of non-volatile compounds such as synthetic polymers.

Chemistry

solid phase microextraction

laser desorption

mass spectrometry

ion mobility spectrometry

gas chromatography

Comparison of Ion Mobility Spectrometry and Gas Chromatography with Dry Electrolytic Conductivity Detection for the Determination of Polychlorinated Biphenyls in Humus-Rich Soil

Orton, Maureen L.

January 2007

Ion mobility spectroscopy (IMS) has been showen to provide fast on-site analysis of coarse sandy soil for the determination of polychlorinated biphenyls (PCBs). However the presence of humus results in instrument foaling and extensive down time do to instrument clean-up. For this reason a method was investigated for the ultrasonic extraction of PCBs from humus-rich soil that could be used at remote locations. Analysis of the extracted PCBs was conducted using 1) IMS and 2) gas chromatogram equipped with a dry electolytic conductiviy detector (GC/DELCD). The research conducted for this thesis outlines the method development and analysis of PCBS using these two instruments. The IMS analyiss was found to be complicated by co-extracted matrix compounds. Results and limitations of IMS analysisare present here. The method development and validation of a method for the ultrasonic extraction and analysis of PCBs using the GC/DELCD is provided.

Ion Mobility Spectroscopy

GC/DELCD

extraction of PCBs from Soil

on-site analysis

Chemistry

Biophysical studies of anhydrous peptide structure

McLean, Janel Renee

15 May 2009

Defining the intrinsic properties of amino acids which dictate the formation of helices, the most common protein secondary structure element, is an essential part of understanding protein folding. Pauling and co-workers initially predicted helical peptide folding motifs in the absence of solvent, suggesting that in vacuo studies may potentially discern the role of solvation in protein structure. Ion mobility-mass spectrometry (IMMS) combines a gas-phase ion separation based on collision cross-section (apparent surface area) with time-of-flight MS. The result is a correlation of collision cross-section with mass-to-charge, allowing detection of multiple conformations of the same ion. Most gas-phase peptide ions assume a compact, globular state that minimizes exposure to the low dielectric environment and maximizes intramolecular charge solvation. Conversely, a small number of peptides adopt a more extended (β-sheet or α-helix) conformation and exhibit a larger than predicted collision cross-section. Collision cross-sections measured using IM-MS are correlated with theoretical models generated using simulated annealing and allow for assignment of the overall ion structural motif (e.g. helix vs. chargesolvated globule). Here, two series of model peptides having known solution-phase helical propensities, namely Ac-(AAKAA)nY-NH2 (n = 3, 4, 5, 6 and 7) and Ac-Y(AEAAKA)nF-NH2 (n = 2, 3, 4, and 5), are investigated using IM-MS. Both protonated ([M + H]+) and metalcoordinated ([M + X]+ where X = Li, Na, K, Rb or Cs) species were analyzed to better understand the interplay of forces involved in gas-phase helical structure and stability. The data are analyzed using computational methods to examine the influence of peptide length, primary sequence, and number of basic (Lys, K) and acidic (Glu, E) residues on anhydrous ion structure.

ion mobility

ion structure

alpha-helices

alanine-based peptides

anhydrous peptide structure

Investigation of Metalloproteins Utilizing High Resolution Mass Spectrometry

Wu, Zhaoxiang

2010 May 1900

Copper ions (Cu⁺, Cu²⁺) play important roles in many biological processes (i.e., oxidation, dioxygen transport, and electron transfer); many of the functions in these processes result from copper ions interacting with proteins and peptides. Previous studies using matrix assisted laser desorption/ionization (MALDI) mass spectrometry (MS) have shown that Cu⁺ ions preferentially bind to electron rich groups in gas phase (i.e., N-terminal amino group, the side-chains of lysine, histidine and arginine). For peptides with more than one Cu⁺ ligand, the interaction between Cu⁺ ions and ligands is described in terms of competitive binding; however, Cu⁺ coordination chemistry for multiple Cu⁺-containing proteins and peptides in gas phase is still not fully understood. In addition, no studies on the fragmentation chemistry for multiple Cu⁺-binding peptides, such as [M + 2Cu - H]⁺ ions, have been reported. The synthesized dinuclear copper complex (alpha-cyano-4-hydroxycinnamic acid (CHCA) copper salt (CHCA)₄Cu₂) enhances the ion abundances for [M + xCu - (x-1)H]⁺ (x = 1-6) ions in gas-phase when used as a MALDI matrix. Using this matrix we have investigated site-specific copper binding of several peptides using fragmentation chemistry of [M + Cu]⁺ and [M + 2Cu - H]⁺ ions. The fragmentation studies reveal that the binding of a single Cu⁺ ion and two Cu⁺ ions are different, and these differences are explained in terms of intramolecular interactions of the peptide-Cu ionic complex. The competitive Cu⁺ binding to C-terminus (i.e., amide, carboxyl, methyl ester) versus lysine, as well as cysteine (SH/SO₃H) versus arginine (guanidino), was also examined by MALDI MS and theoretical calculations (Density Functional Theory (DFT)). For example, results from theoretical and experimental (fragmentation reactions) studies on [M + Cu]⁺ and [M + 2Cu - H]⁺ ions suggest that cysteine side chains (SH/SO₃H) are important Cu⁺ ligands. Note that, the proton of the SH/SO₃H group is mobile and can be transferred to the arginine guanidino group. For [M + 2Cu - H]⁺ ions, deprotonation of the -SH/SO₃H group is energetically more favorable than that of the carboxyl group, and the resulting thiolate/sulfonate group plays an important role in the coordination structure of [M + 2Cu - H]⁺ ions.

Copper ions

protein

peptide

mass spectrometry

ion mobility

fragmentation

gas phase structure

Investigation on Gas-phase Structures of Biomolecules Using Ion Mobility-mass Spectrometry

Tao, Lei

2010 May 1900

IM-MS is a 2-D technique which provides separations based on ion shape (ion-neutral collision cross-section, Ω) and mass (m/z ratio). Ion structures can be deduced from the measured collision cross-section (Ωmeas) by calculating the collision cross-sections (Ωcalc) of candidates generated by molecular dynamics (MD) and compared with the experiment results. A database of Ωs for singly-charged peptide ions is presented. Standard proteins are digested using different enzymes (trypsin, chymotrypsin and pepsin), resulting in peptides that differ in amino acid composition. The majority (63%) of the peptide ion correlates well with the globular structures, but some exhibit Ωs that are significantly larger or smaller than the average correlation. Of the peptide ions having larger Ωs, approximately 71% are derived from trypsin digestion and most of the peptide ions that have smaller Ωs are derived from pepsin digestion (90%). We use computational simulations and clustering methods to assign backbone conformations for singly-protonated ions of the model peptide (NH2-Met-Ile-Phe-Ala-Gly-Ile-Lys-COOH) formed by both MALDI and ESI and compare the structures of MIFAGIK derivatives to test the ‘sensitivity’ of the cluster analysis method. Cluster analysis suggests that [MIFAGIK + H]+ ions formed by MALDI have a predominantly turn structure even though the low energy ions prefer partial helical conformers. Although the ions formed by ESI have Ωs that are different from those formed by MALDI, the results of cluster analysis indicate that the ions backbone structures are similar. Chemical modifications (N-acetyl, methylester, as well as addition of Boc or Fmoc groups) of MIFAGIK alter the distribution of various conformers, the most dramatic changes are observed for the [M + Na]+ ion, which show a strong preference for random coil conformers owing to the strong solvation by the backbone amide groups. Ωmeas of oligodeoxynucleotides in different length have been measured in both positive and negative modes. For a given molecular weight and charge state, Ωmeas of the oligodeoxynucleotide ions are smaller than those of the peptides, indicating their different packing efficiency. A novel generalized non-Boltzman sampling MD has been utilized to investigate the gas-phase ion conformations of dGGATC based on the free energy values. Theory predicts only one low-energy conformer for the zwitterionic form of dGGATC- while dGGATC+ ions have several stable conformers in both canonical and zwitterionic form in the gas phase, in good agreement with the experiment.

Gas-phase ion structure

Biomolecules

Ion Mobility-Mass Spectrometry

Collision cross-sections

Molecular Dynamics