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Mass Spectrometry: Toward Elucidating the Biosignature of Coccidioidomycosis and Insights into Surface Induced Dissociation of Biologically Relevant CarbohydratesVanSchoiack, Andrew D. January 2015 (has links)
Mass spectrometry (MS) has proven itself to be indispensable for the analysis of biomolecules and molecular systems. This research has three goals: (1) expand on prior work toward the discovery of novel diagnostic targets for Valley Fever, (2) evaluate current mass spectrometry based proteomics for the discovery of non-host protein in complex host biological samples, and (3) investigate the potential for two gas phase techniques, surface induced dissociation, and ion mobility for the analysis of carbohydrate based molecules. Mass spectrometry has allowed for great advances in the identification of proteins in biological samples through implementing liquid chromatography tandem mass spectrometry and bioinformatics techniques known as proteomics. Proteomics techniques were used to elucidate a portion of the biosignature of Valley Fever (VF), a disease of great importance in the arid regions of the western United States. Current diagnostics for this fungal lung disease are remarkably unreliable which creates a need for an unfailing diagnostic method. Using a new generation of instrumentation along with directed methods, four previously discovered VF marker proteins were evaluated for their presence in mouse plasma, lung homogenate and bronchoalveolar lavage fluid samples. Due to inconclusive data, discovery proteomics approaches were then used to identify possible diagnostic targets in both human and mouse bronchoalveolar lavage fluid. In human bronchoalveolar lavage fluid, one potential target was discovered in five out of eight VF positive samples, and two further identifications of VF in negative samples. Mouse bronchoalveolar lavage fluid also showed the presence of this protein. Multiple-reaction monitoring based validation, using two-dimensional online separations for the presence of either the newly discovered protein or the four previously discovered proteins, was inconclusive. Emerging from the difficulties observed by the author and colleagues in identifying infectious agent proteins in complex host biological samples, an investigation of the feasibility of undertaking such endeavors was performed. One of the main complications thwarting the discovery of infectious agent proteins is the dynamic range of protein concentration in the host biological sample. This issue was resolved by using commercially available mass spectrometry and a two-dimensional liquid chromatographic separations platform. This enhanced separation combined with cost-effective protein normalization techniques, identified non-host proteins with good sequence coverage and spectral counts. Combining antibody-based depletion of highly abundant plasma proteins in bronchoalveolar lavage fluid, with at least a three fraction sample analysis enabled detection of a low abundant non-host protein (2pmol in 50μg host protein) with high sequence coverage. Glycosylation, an abundant post-translational modification of protein composed of carbohydrate oligomers may hold within its structure more biologically relevant information than the DNA that encoded the protein on which the glycan resides. The analysis of glycosylation plays a critical role in understanding biology. Carbohydrate based moieties pose many distinct challenges to their analysis; two of which are isobaric fundamental units and complex branching chemistry. Mass spectrometry provides a way of overcoming some of these challenges. To examine the complex biomolecules, a gas phase ion separation technique, known as ion mobility, and a non-traditional ion activation technique, surface-induced dissociation, were used. Surface-induced dissociation provides analogous fragmentation patterns to those generated via collision-induced dissociation (CID); however, much more extensive fragmentation can be achieved in a single tandem MS experiment. Using the gas-phase separations power of ion mobility showed that multiple conformations were adopted by relatively simple oligosaccharides. Ion mobility was also successfully used to determine fragment ion lineage of isobaric fragment ions, through inline separation between two differential fragmentation experiments.
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Implementation of an In-line Surface-induced Dissociation Device in a Quadrupole Time-of-flight Instrument and Its PerformanceGalhena, Asiri S. January 2008 (has links)
The focus of this dissertation is the introduction of surface-induced dissociation (SID) into a commercially available quadrupole time-of-flight mass spectrometer as an alternative ion fragmentation method. The performance of the SID device was characterized and its applications were demonstrated by dissociating peptides, proteins, inorganic salt clusters and non-covalent protein complexes. The SID setup allowed direct comparison of SID with conventional collision-induced dissociation (CID) on the same instrument, taking advantage of the characteristics of Q-TOF instrumentation, including extended mass range, high sensitivity and resolution. With the SID setup installed, no significant reduction of the ion transmission was evident. SID fragmentation patterns of peptides are, in general, similar to CID, with slight differences in the relative intensities of immonium ions, backbone cleavage b- versus y- type ions, and y- versus y-NH3 ions. This suggests enhanced accessibility to high energy/secondary fragmentation channels with SID. SID studies on cesium iodide clusters (CsI) also revealed that SID deposits more internal energy.The utility of mass spectrometric methods to probe the gas phase cyclization process was studied with [D-Ala2]-Leucine Enkephalin amide. This peptide showed prominent formation of the [M-NH3]+ ion which is believed to be the linear b5 ion with a C-terminal oxazolone structure. Other fragments in the spectra indicate that the linear b5 ion undergoes cyclization, subsequent ring opening and further dissociation to rearranged fragments that cannot be explained by the initial sequence. The similarities between the cyclic and b5-ion from the linear peptide indicated the formation of a heterogeneous ion population and this is further supported by gas-phase H/D exchange experiments. An ion funnel interface to improve ion transmission at high pressures was tested in a custom built quadrupole-surface-quadrupole instrument. The ion transmission efficiency for selected bio-molecules such as YGGFLR, insulin chain-B, ubiquitin and cytochrome c showed to approach almost 90%, with the funnel interface installed. The ion transmission efficiency was effected by several factors including: the size of the analyte, the DC gradient, the RF frequency, and the RF amplitude. The higher fragmentation efficiencies for SID in the presence of the funnel interface indicated higher internal energy deposition for the funnel interface.
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Identification and Validation of Protein Biomarkers for Invasive Aspergillosis; Development of Surface-Induced Dissociation Device and Paper Spray Ionization Source for Protein Complex StudiesHuang, Chengsi January 2014 (has links)
The research described in this dissertation is divided into two sections. The first section focuses on mass spectrometry-based bottom-up proteomics application to identify fungal protein biomarkers of invasive aspergillosis infection. The second part focuses on instrument development to improve current ionization and dissociation technologies for characterizing topology and substructure of protein complexes. Part I of this dissertation describes the identification and validation of protein biomarkers for Invasive Aspergillosis (IA), a fatal pulmonary infection. Aspergillus fumigatus, the organism responsible for this disease, is an opportunistic fungus. Immunocompromised individuals can suffer from IA due to impaired immune response. The current diagnostic tools are time-consuming and have variable sensitivity and specificity. Hence, treatments for IA are often administered too late. The goal of this research is to use mass spectrometry to identify and validate novel fungal protein biomarkers for IA. To tackle this challenge, several systems were studied. Commercial Aspergillus antigen was used for method development, and to serve as standards for spiking and comparison. Mouse models of different disease manifestations were used in the initial study to compare proteomic differences in carefully controlled disease states. Although it was not successful in providing candidate biomarkers, the mouse samples provided host response protein data. Human patient samples yielded the most promising results. Several Aspergillus proteins have been identified and validated from patient bronchoalveolar lavage fluid, and could have the potential to be later used on a diagnostic platform. Part II describes two instrument development projects: incorporation of a surface-induced dissociation device into a commercial ion mobility time-of-flight mass spectrometer, and the development of a paper spray ionization source. Protein complexes are often studied using collision-induced dissociation (CID), which does not provide enough substructure information. Surface-induced dissociation (SID) allows access to higher energy fragmentation pathways, which generates more useful substructure information. Its potential is demonstrated with three systems here-- one metal cluster and two protein complexes. All systems show that SID can provide more useful structural information than CID under similar conditions. The development of a paper spray (PS) source for protein complex ionization provides another way to study protein complexes. Chapter 9 shows that this ionization method can also be applied to protein complexes. Under the same conditions as its nanospray counterpart, similar mass spectra can be obtained using PS. This exciting result is the first demonstrations that PS can be used for protein complexes while maintaining each protein complex's native structure and conformation.
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STUDIES OF ION DISSOCIATION KINETICS AND MECHANISMS BY SURFACE-INDUCED DISSOCIATION AND INFRARED MULTI-PHOTON DISSOCIATION/SOFT-LANDINGYoon, Sung Hwan January 2010 (has links)
This dissertation presents dissociation mechanism and dissociation kinetics studies of gas-phase ions using mass spectrometry (MS). Dissociation of a gas-phase ion is related to its fundamental properties such as composition and structure. However, the detailed processes, internal energy deposition during ion activation as well as the mechanism of dissociation, are not fully known. In the present work, ion structural studies from which mechanisms can be inferred were performed using infrared multiphoton dissociation (IRMPD) spectroscopy, soft-landing, IR spectroscopy, and quantum chemical calculations. Kinetics studies involved instrument modification to add surface-induced dissociation (SID) capability and peak shape analysis. Structural studies were performed to determine dissociation mechanisms. The b₂⁺ ion from AGG is an oxazolone structure as indicated by the IRMPD spectrum and quantum chemical calculations. Protonated 4-ethoxymethylene-2-phenyl-2-oxazolin-5- one is also an oxazolone-type structure, while protonated cyclo-AG is a diketopiperazine structure. Soft-landing experiments were carried out to corroborate IRMPD results. Soft-landed protonated cyclo-AG and protonated 4-ethoxymethylene-2-phenyl-2- oxazolin-5-one underwent neutralization and retained their structures. The soft-landed b₂⁺ ion of AGG showed evidence of ring opening and conversion into a linear structure. The modified matrix-assisted laser desorption/ionization (MALDI) time-of-flight (TOF) mass spectrometers with SID capability were used to study fast dissociation kinetics (sub-microsecond dissociation). Silicon nanoparticle assisted laser desorption/ionization (SPALDI) allows the study of small molecule dissociation kinetics for ions without the matrix interference observed in MALDI. Well characterized systems, such as, N(CH₃)₄⁺, N(CD₃)₄⁺, and substituted benzylpyridinium ions were used to confirm reliability of the peak shape analysis. Obtained dissociation rates, of submicrosecond order, are consistent with the known dissociation theories. Dissociation of fullerenes, C₆₀ and C₇₀, was also investigated with the SID method using a fluorocarbon self-assembled monolayer (FSAM) surface. Fullerene ions produced C(2n)⁺ fragments ion in the kinetic energy range of 150-300 eV. At higher than 400 eV, mass spectra showed additional small fragment ions composed of odd numbers of C units. Energy resolved MS/MS curves support parallel dissociation at high SID energies while peak shape analysis explains sequential dissociation at about 150 eV range. Instrument modification of a MALDI-TOF mass spectrometer with SID capability allowed successful studies of fast unimolecular dissociation kinetics of small ions and fullerenes.
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Real-Time Virus Analysis Via Image Charge Detection Surface Induced Dissociation Tandem Mass SpectrometryCall, Seth T. 11 August 2009 (has links) (PDF)
This thesis reports on the development of a novel mass spectrometer combining image charge detection with surface induced dissociation for real-time analysis of intact viruses. Protonated viruses produced using electrospray are accelerated and subsequently impact on a solid surface. Capsid peptides released during the impact are analyzed using time-of-flight mass spectrometry. Image charge detection is used to measure the mass and charge states of structurally intact, electrosprayed viruses prior to impact. Since virus capsids are composed of loosely-bound proteins, collision of viruses with surfaces at moderate impact energies could release intact proteins. The masses and numbers of different protein types combined with the mass of the intact virus represent a unique signature useful for accurate, real-time virus identification. The progress of instrumentation developed thus far is reported. Techniques were developed for electrospraying intact viruses, including electrospray capillaries with small tips and methods for achieving complete desolvation. Significant reduction of low-frequency and other noise was achieved in the image charge detector as well as determination of accurate methods for mass and charge measurement. Improved focusing and transmission efficiency was achieved via an aerodynamic lens. Suitable surfaces were also obtained including conductive diamond and fluorinated self-assembled monolayer (SAM) surfaces.
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Native mass spectrometry protein structural characterization via surface induced dissociation: instrumentation and applicationsYan, Jing 12 December 2017 (has links)
No description available.
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Expanding the Role of Gas-Phase Methods in Structural Biology: Characterization of Protein Quaternary Structure and Dynamics by Tandem Mass Spectrometry and Ion MobilityBlackwell, Anne January 2012 (has links)
This dissertation presents efforts to expand the role of mass spectrometry (MS) in structural biology. Determination of quaternary structure of a protein complex has been hindered by limited fragmentation from collision-induced dissociation (CID). As an alternative, surface-induced dissociation (SID) was implemented for a quadrupole - time-of-flight instrument in the Wysocki laboratory. This research tested the hypothesis that SID should produce fragmentation reflective of subunit organization. Furthermore, ion mobility (IM) was used to prove the direct relationship between precursor conformation and observed dissociation patterns, and the relationship between activation and product ion conformation. The structure and dynamics of a dimeric small heat shock protein (sHSP) with no solved structure was investigated. The importance of N- and C-terminal domains for dimerization was determined, and the dimers were shown to exchange subunits. From exchange kinetics it is proposed that subunit exchange is unrelated to heat shock activity. SID was used to elucidate the subunit architecture of heterogeneous protein assemblies, including one previously solved protein structure and two formerly uncharacterized proteins. The heterohexamer toyocamycin nitrile hydratase dissociated into trimers, revealing the hexamer to be a dimer of trimers. The bacterial ribonuclease toxin:antitoxin tetramer was shown to have an antitoxin dimer at its core, with flanking individual toxin subunits. The examples presented here are the first clear proof that SID results can clearly indicate the substructure of a protein assembly.IM was used to study the conformation of precursor and product ions. A greater understanding of the relationship between precursor conformation and observed dissociation patterns was developed. Different charge states of a dodecameric sHSP were found to have significantly different conformations, which were directly reflected in SID spectra. IM comparison of CID and SID product ions showed that the same charge state of a product ion from either method has the same CCS. This suggests the product ion conformation is dependent upon ion charge state, and independent of activation method and collision energy. The cause and effect relationship between precursor conformation and MS/MS patterns, and activation and product ion conformation were clearly illustrated. Together, this body of research expands the role of MS for structural biology.
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Characterization of Macromolecular Protein Assemblies by Collision-Induced and Surface-Induced Dissociation: Expanding the Role of Mass Spectrometry in Structural BiologyJones, Christopher Michael January 2008 (has links)
This dissertation presents an investigation into the structure of macromolecular protein assemblies by mass spectrometry. The experiments described within are designed to systematically assess the analytical utility of surface-induced dissociation (SID) tandem mass spectrometry in the characterization of multi-subunit protein complexes. This is accomplished by studying the effects of ion-surface collision on the fragmentation products of protein assemblies that vary by mass, number of subunits, and protein structural features. The dissociation energetics and mechanisms of protein complexes are considered by examining the influence of ion internal energy and sub-oligomeric protein structure on the dissociation process. Conditions are first established for the preservation of “native” protein quaternary structure and applied to previously characterized systems for proof-ofconcept. These conditions are subsequently extended to determine the molecular weight and subunit stoichiometry of several small heat shock proteins. Native mass spectrometry is then combined with limited proteolysis experiments to characterize the subunit interface of a unique small heat shock protein, Hsp18.5 from Arabidopsis thaliana, identifying regions of the protein essential for preservation of the native dimer. The dissociation of non-covalent protein assemblies is then explored on a quadrupole time-of-flight (Q-TOF) mass spectrometer, modified for the study of ion-surface collisions. This instrument allows ions to be dissociated through collisions with a surface or more conventional collisions with gas atoms. The dissociation of protein complexes is explored by both activation methods beginning with specific and non-specific dimers with masses less than 40 kDa. These studies are extended to larger assemblies with as many as 14 subunits weighing over 800 kDa, and are applied to both homo- and hetero-oligomeric protein complexes. Activation of a protein complex with “n” subunits through multiple collisions with inert gas atoms results in asymmetric dissociation into a highly charged monomer and complementary (n-1)-mer regardless of protein size or subunit architecture. This process is known to occur through an unfolding of the ejected subunit, and limits the amount of structural insight that can be gleaned from such studies. Collision at a surface however, results in more charge and mass symmetric fragmentation, and in some instances reflects the substructure of the protein assembly under investigation. The differences observed between the CID and SID of protein complexes is attributed to the rapid deposition of large amounts of internal energy deposited upon collision at a more massive target such as a surface. The ion activation time-frame and energy transfer efficiency are proposed to induce dissociation on a time-scale that precedes subunit unfolding providing access to dissociation pathways that are inaccessible by traditional means of activation. The systems studied here represent the largest ions fragmented via surface collisions within a mass spectrometer, and the fragmentation products observed by SID demonstrate its promise for expanding the role of mass spectrometry in the field of structural biology.
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Instrumentation and Kinetic Studies of Surface-Induced Dissociation in a Time-of-Flight Mass SpectrometerMajuwana Gamage, Chaminda January 2006 (has links)
The surface-induced dissociation (SID) method is introduced into a Bruker matrix-assisted laser desorption/ionization time-of-flight mass spectrometer (MALDI TOF MS) as an efficient ion fragmentation method. Ion trajectory calculations using the SIMION 7.0 ion optics program are performed and results are combined with simple unimolecular decay calculations in order to study the kinetics of the SID processes. In this instrument, the observation time frame for SID fragments lies in the submicrosecond region, allowing the specific detection of submicrosecond fragmentation channels. MALDI-produced protonated peptides in the mass range of 700 - 1500 Da and radical ions produced by laser irradiation of fullerenes C60 and C70 are fragmented at a gold surface coated with a self-assembled monolayer of alkanethiol to obtain TOF SID TOF mass spectra. For the SID of peptides in the hyperthermal energy regime, a fragmentation time frame of tens to a few hundreds of nanoseconds was calculated for the observed fast fragmentation channels (Chapters 3 and 4). Theoretical and experimental peak shape comparisons assuming unimolecular decay kinetics indicated a log rate constant in the range 6 - 7 (Chapter 4). Energy and mass resolved kinetic studies are also carried out. The contribution of special structural features to peptide fragmentation and the possibility of different fragmentation mechanisms such as sequential and parallel pathways are investigated. The results indicate a unimolecular decay process for observed fast peptide fragments ruling out a surface-shattering mechanism. Fullerene ions, especially C60+., showed a fragmentation behavior producing C2n+. fragments with an even number of C units at collision energies in the range of 100 - 400 eV (Chapter 5). At around 400 eV, additional small fragments appeared that are apart by only a single C unit. According to the calculated fragmentation times and the theoretical and experimental peak shape comparisons assuming unimolecular decay kinetics, both these processes may be approximated by parallel fast unimolecular decay processes with fragmentation time frames of tens to hundreds of nanoseconds although the poor theoretical and experimental peak shape matching for example in the decay of C60+. to C19+. may suggest deviations from a one-step unimolecular decay process.
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Characterization of Peptides, Proteins, and Protein Complexes using Infrared Multiphoton Dissociation Spectroscopy, Ion Mobility Spectrometry, and Surface-induced Dissociation Mass SpectrometryPanczyk, Erin Michelle 01 October 2021 (has links)
No description available.
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