Novel pyroelectric and switched ferroelectric ion sources in mass spectrometry implementation and applications /

Neidholdt, Evan L. Beauchamp, Jesse L. Blake, Geoffrey A.

January 1900

Thesis (Ph. D.) -- California Institute of Technology, 2010. / Title from home page (viewed 06/21/2010). Advisor and committee chair names found in the thesis' metadata record in the digital repository. Includes bibliographical references.

Mass spectrometry. Ion sources.

Enhanced electrospray ionization for mass spectrometry and ion mobility spectrometry /

Zhou, Li,

January 2006

Thesis (Ph. D.)--Brigham Young University. Dept. of Chemistry and Biochemistry, 2006. / Includes bibliographical references.

Accelerator mass spectrometry for radiocarbon dating : advances in theory and practice

Bronk, Christopher Ramsey

January 1987

Accelerator mass spectrometry (AMS) has been used routinely for radiocarbon measurements for several years. During this period it has become evident neither the accuracy nor the range of the technique were as great as had originally been hoped. This thesis describes both theoretical work to understand the reasons for this and practical solutions to overcome some of the problems. The production and transport of the ions used in the measurements are found to be the most crucial stages in the process. The theories behind ion production by sputtering are discussed and applied to the specific case of carbon sputtered by caesium. Experimental evidence is also examined in relation to the theories. The phenomena of space charge and lens aberrations are discussed along with the interaction between ion beams and gas molecules in the vacuum. Computer programs for calculating phase space transformations are then described; these are designed to help investigations of the effects of space charge and aberrations on AMS measurements. Calculations using these programs are discussed in relation both to measured ion beam profiles in phase space and to the current dependent transmission of ions through the Oxford radiocarbon accelerator. Improvements have been made to this accelerator and these are discussed in the context of the calculations. There are many reasons for wishing to produce C^- ions directly from carbon dioxide. The most suitable type of source for achieving this is the Middleton High Intensity Sputter Source. Experiments to evaluate the performance of such a source are described and detailed design criteria established. An ion source designed and built specifically for radiocarbon measurements using carbon dioxide is described. Experiments to evaluate its performance and investigate the underlying physical processes are discussed. The source is found to have a high efficiency enabling small samples (<100 μg of carbon) to be measured. The cross contamination is measured to be low (<0.1%) and the background currents are small; the implications of these results are discussed.

539.7

The development and application of miniaturised FAIMS combined with mass spectrometry in bioanalysis

Arthur, Kayleigh L.

January 2017

In this thesis, a miniaturised field asymmetric waveform ion mobility spectrometry (FAIMS) device is combined with mass spectrometry (MS), and liquid chromatography, for the development and application of bioanalytical methodologies. FAIMS is a highly orthogonal to MS and LC and has the potential to enhance both targeted and non-targeted bioanalytical applications. Chapter two demonstrates the capability of the FAIMS combined with mass spectrometry to reduce the complexity of the mass spectrum by separating species of different charge states and overlapping mass-to-charge ratios that are challenging to separate by MS. FAIMS selected transmission shows improvement in signal-to-noise ratios for low intensity species and enables visualisation of species undetectable without FAIMS. Chapter three describes the development of an LC-FAIMS-MS method for the rapid analysis of saliva for the identification of potential biomarkers as a result of oxidative stress. The combination of FAIMS showed a reduction in saliva matrix interferences resulting in improved discrimination and peak integration of two salivary oxypurine compounds in a rapid LC-FAIMS-MS method. Chapter four investigates the FAIMS separation of seven steroid metabolites with a range of cationic adducts, in order to develop a rapid screening LC-FAIMS-MS method for the determination of isobaric steroid metabolites in urine. LC-FAIMS-MS analysis of the steroid metabolites shows improved discrimination of co-eluting and isobaric steroid metabolites with improvements in signal-to-noise ratio with reductions in chemical noise, demonstrating the potential of combining FAIMS with LC-MS. Chapter five demonstrates the potential of FAIMS to increase peak capacity in non-targeted omics applications, by combining rapid compensation field scanning of the FAIMS with ultra-high performance LC-MS. The rapid scanning of the FAIMS allows acquisition of full scan FAIMS and MS nested data sets within the timescale of a UHPLC chromatographic peak, and is applied to the non-targeted profiling of human urine. Improvements in the number of features detected using LC-FAIMS-MS were as a result of reductions in chemical noise and separation of co-eluting isobaric species across the whole analytical space, demonstrating the potential of combining FAIMS with LC and MS.

Resolving intrinsically disordered proteins of the cancer genome with ion mobility mass spectrometry

Jurneczko, Ewa

January 2014

For proteins the link between their structure and their function is a central tenet of biology. A common approach to understanding protein function is to ‘solve’ its structure and subsequently probe interactions between the protein and its binding partners. The first part of this approach is non-trivial for proteins where localised regions or even their entire structure fail to fold into a three-dimensional structure and yet they possess function. These so called intrinsically or inherently disordered proteins (IDP’s) or intrinsically disordered regions (IDR’s) constitute up to 40% of all expressed proteins. IDPs which have crucial roles in molecular recognition, assembly, protein modification and entropic chain activities, are often dynamic with respect to both conformation and interaction, so in the course of a protein’s ‘lifespan’ it will sample many configurations and bind to several targets. For these proteins, there is a need to develop new methods for structure characterization which exploit their biophysical properties. The solvent free environment of a mass spectrometer is ideally suited to the study of intrinsic interactions and how they contribute to structure. Ion mobility mass spectrometry is uniquely able to observe the range of structures an IDP can occupy, and also the effect of selected binding partners on altering this conformational space. This thesis details the technique of ion mobility mass spectrometry and illustrates its use in assessing the relative disorder of p53 protein. The tumour suppressor p53 is at the hub of a plethora of signalling pathways that maintain the integrity of the human genome and regulate the cell cycle. Deregulation of this protein has a great effect on carcinogenesis as mutated p53 can induce an amplified epigenetic instability of tumour cells, facilitating and accelerating the evolution of the tumour. Herein mass spectrometry provides a compelling, detailed insight into the conformational flexibility of the p53 DNA-binding domain. The plasticity of the p53 DNA-binding domain is reflected in the existence of more than one conformation, independent of any conformational changes prompted by binding. The in vacuo conformational phenotypes exhibited by common cancer-associated mutations are determined and the second-site suppressor mutation from loop L1, H115N, is probed whether it could trigger conformational changes in p53 hotspot cancer mutations. The structural basis of the binding promiscuity of p53 protein is investigated; of particular interest is the molecular interaction of the p53 N-terminus with the oncoprotein murine double minute 2, as well as with the antiapoptotic factor B-cell lymphoma-extralarge.

572.8

Biophysical studies into the structure and interactions of proteins and peptides

Harvey, Sophie Rebecca

January 2014

Investigating the structure of proteins and their interactions with other biomolecules or drug molecules, coupled with the consideration of conformational change upon binding, is essential to better understand their functions. Mass spectrometry (MS) is emerging as a powerful tool to study protein and peptide structure and interactions due to the high dynamic range, low sample consumption and high sensitivity of this technique, providing insight into the stoichiometry, intensity and stability of interactions. The hybrid technique of ion mobility-mass spectrometry (IM-MS) can provide insight into the conformations adopted by protein and peptide monomers and multimers, in addition to complexes resulting from interactions, which when coupled with molecular modelling can suggest candidate conformations for these in vacuo species and by inference their conformations in solution prior to ionisation and desolvation. The work presented in this thesis considers a number of different peptide and protein systems, highlighting how the combination of MS and IM-MS based techniques, in conjunction with other biophysical techniques such as circular dichroism (CD) spectroscopy, transmission electron microscopy (TEM) and isothermal titration calorimetry (ITC) can provide insight into these dynamic systems. First a case study into the ability of MS and IM-MS to study disorder-to-order transitions is presented. The transcription factor c-MYC can only perform its function upon binding with its binding partner MAX; deregulation of c-MYC is, however, implicated in a number of human cancers. c-MYC and MAX comprise intrinsically disordered regions which form a leucine zipper upon binding. The work presented here focuses on the leucine zipper regions of both c-MYC and MAX, their individual conformations and changes upon binding. Inhibiting the c-MYC:MAX interaction is a current target for drug therapy and hence the inhibition of this interaction with a previously identified small drug-like molecule was also examined using these techniques, to determine if such an approach may be appropriate for investigation of future therapeutics. Next the ability of MS-based techniques to preserve, transmit and distinguish between multiple conformations of a metamorphic protein was examined. The chemokine lymphotactin has been shown to exist in two distinct conformations in equilibrium in a ligand-free state. The existence of such metamorphic proteins has called into question whether traditional structural elucidation tools have been inadvertently biased towards consideration of single conformations. Here, the potential of gas-phase techniques in the study of conformationally dynamic systems is examined through the study of wild type lymphotactin and a number of constructs designed either as a minimum model of fold or to mimic one of the distinct folds. Interactions between chemokines and glycosaminoglycans (GAGs) are thought to be essential for the in vivo activity of these proteins. The interactions between the distinctive chemokine lymphotactin and a model GAG were hence probed. As with the structural studies, additional protein constructs were considered either to represent the minimum model of fold, one distinct fold of the metamorphic protein or designed to diminish its GAG binding propensity. The ability of each construct to bind GAGs, the stoichiometry of the interactions and conformations adopted by the resulting complexes in addition to aggregation occurring upon the introduction of the GAG is considered. Finally, the similarities, with respect to structure and function, between the chemokine superfamily of proteins and the human β-defensin subfamily of antimicrobial peptides are considered. The tendency of human β-defensins 2 and 3 to bind a model GAG is examined; the stoichiometry of binding and conformations adopted and aggregation occurring here are considered and compared with that of chemokines.

572

Comprehensive stereochemical sequencing of carbohydrates and characterisation of their binding partners using hyphenated mass spectrometry methods

Gray, Christopher

January 2016

Glycans and their conjugates form the largest and most diverse class of biological molecules found within nature. These glycosides are vital for numerous cellular functions including recognition events, protein stabilisation and energy storage, to name a few. Additionally, abnormalities within these structures are associated with a wide range of disease states. As a result, robust analytical techniques capable of in depth characterisation of carbohydrates and their binding partners are required. Currently, liquid chromatography coupled with tandem mass spectrometry (MS2) is the 'gold standard' for characterising these species. However there are inherent challenges for 'sequencing' carbohydrates given that most structures are diastereomeric. As a result MS alone is insufficient to fully elucidate all stereochemical and often regiochemical information and alternative analytical techniques have inherent issues meaning that they are not suitable for medium/high throughput analysis. To facilitate elucidation of these structures, ion mobility spectrometry (IMS) has been used in-line with MS2. IMS of mono- and di-saccharide product ions generate by collision-induced dissociation (CID) of various glycans and their conjugates enables unambiguous identification of the monomer and the regio-/stereo-chemistry of the glycosidic bond, independent of the precursor structure. Also, given the prominence of glycans in biological recognition events, high-throughput techniques capable of elucidating and characterising carbohydrate to glycan-binding protein (GBP) interactions are highly sought after. Historically, (micro)array strategies are employed to screen large numbers of biological interactions, with detection conventionally achieved with fluorescent tagging. The major disadvantage of this approach is the requirement of a labelling step to facilitate detection of glycan-GBP binding. MS offers the ability to unambiguously identify GBPs when combined with routine bottom-up proteomics strategies, namely on-chip proteolysis followed by mass fingerprinting and MS2 analysis and subsequent comparison to protein databases. It is anticipated that these methodologies developed throughout these studies, both for carbohydrate sequencing and the characterisation of glycan-binding proteins, will greatly add to the Glycomics toolbox.

540

Mass spectrometry methods for characterising the dynamic behaviour of proteins and protein complexes

Beveridge, Rebecca

January 2016

Research into the relationship between the structure and function of proteins has been ongoing now for several decades. More recently, there has been an explosion in the investigation of the dynamic properties of proteins, and how their dynamic propensity relates to their function. This new direction in protein research requires new techniques to analyse protein dynamics, since most traditional techniques are biased towards a fixed tertiary structure. Mass spectrometry (MS) is emerging as a powerful tool to probe protein dynamics since it can provide information on interconverting conformations and has no preference towards the folded state. Furthermore, its low sample consumption, rapid data acquisition and low data processing positions MS as an attractive tool in protein structure research. The hybrid technique of ion mobility-mass spectrometry provides further insight into the range of conformations adopted by proteins and protein complexes, by providing information on the size in terms of rotationally averaged collision cross section. The work presented in this thesis considers proteins with a range of structural characteristics. We use ion mobility mass spectrometry to investigate proteins of different extents of disorder, protein complexes with dynamic entities and a system that undergoes structural rearrangement upon ligand binding. First, a framework of mass spectrometry experiments is described which allows identification of the extent of structure and disorder within proteins. This framework is tested on a range of different systems throughout the thesis. Differences in the gas-phase properties of two conformationally dynamic proteins which behave similarly in solution are investigated and from this research we postulate a new ionisation mechanism for partially folded proteins. The dynamic propensity of C-terminal p27 is investigated and compared to two permutants which allows us to delineate how the location of charged residues in a primary sequence affects the structure of a protein. We monitor the 'folding-upon-binding' behaviour of p27 upon association with its binding partners, and how this differs with the order of charged residues in the linear sequence. Finally, we describe the structural rearrangement of Fdc1 upon the binding of its cofactor; a prenylated FMN molecule. This thesis demonstrates the suitability of ion mobility-mass spectrometry for the investigation of dynamic properties of proteins and protein complexes.

540

A study of ion-molecule reactions in a dynamic reaction cell to improve elemental analysis with inductively coupled plasma-mass spectrometry

Jones, Deanna M. Rago,

January 2007

Thesis (Ph. D.)--Ohio State University, 2007. / Title from first page of PDF file. Includes bibliographical references (p. 489-516).

Investigation of large protein and multimeric protein complex structures with mass spectrometry techniques

Pacholarz, Kamila Jolanta

January 2015

The biophysical properties, biological activity and function of macromolecular systems are highly dependent on their structure. Structure-activity relationships of proteins and their binding partners are critical for drug discovery, biochemical and medical research. While the gas-phase environment might present as an unusual venue from which to explore protein structure, for over the past two decades, nano-electrospray ionization (nESI) coupled to mass spectrometry (MS) has been recognized as having great potential for analysis of protein structure and protein non-covalent complexes. In conjunction with related technique of ion mobility (IM), mass spectrometry (IM-MS) provides insights into protein native-like conformations and any structural changes in may undergo upon ligand binding or alternations induced via physical parameters such as temperature, pressure or solution conditions. As most proteins tend to exist as multiple domains; from the distribution of oligomeric states in the Protein Data Base (PDB) 86% of proteins exist as oligomers; the work presented in this thesis focuses on application of MS techniques to probe the tertiary and quaternary structure of various large and multimeric protein complexes, their dynamics and/or conformational changes. Wherever relevant, the gas-phase studies reported here are complemented by other techniques, such as hydrogen deuterium exchange MS (HDX), molecular modelling (MD) and analytical ultracentrifugation (AUC). Firstly, the dynamics of intact monoclonal antibodies (mAbs) and their fragments are explored with IM-MS. Variations observed in conformational landscapes occupied by two mAb isotypes are rationalized by differences in disulfide linkages and non-covalent interactions between the antibody peptide chains. Moreover, mAb intrinsic flexibility is compared to other multimeric protein complexes in terms of collision cross section distribution span. Secondly, variable temperature MS (VT-MS) and variable temperature IM-MS (IM-MS) are used to probe unfolding and dissociation of four standard multimeric protein complexes (TTR, avidin, conA and SAP) as a function of the of analysis environment temperature. VT-MS is found to allow for decoupling of their melting temperature (Tm) from the protein complex dissociation temperature (TGPD). Whereas, VT-IM-MS is used to investigate structural changes of these protein complexes at elevated temperatures and provide insights into the thermally induced dissociation (TID) mechanism, as well as strength of the non-covalent interactions between subunits. Thirdly, VT-(IM)-MS methodology is applied to study behaviour of three mAbs: IgG1, IgG4 and an engineered IgG4 of increased thermal stability. Such analysis shows to be promising for comparative thermal stability studies for proteins of therapeutic interest. Lastly, the structure of ATP-phosphoribosyltransferase (MtATPPRT), an enzyme catalysing the first step of the biosynthesis of L-histidine in Mycobacterium tuberculosis, is explored. Conformational changes occurring upon feedback allosteric inhibition by L-histidine are probed with MS, IM-MS, HDX-MS and AUC. Reported results serve as the basis for IM-MS/HDX-MS based screening method to be used for screening of a library of novel and promising anti-tuberculosis agents.

572