[PDF] Top Down Mass Spectrometry Characterization Of Protein Ligand Complexes Important To Neurodegenerative Diseases eBook

Author : Piriya Wongkongkathep
Publisher :
Page : 170 pages
File Size : 43,49 MB
Release : 2015
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Mass spectrometry (MS) has made significant contributions to protein and proteomics analysis during the past decades from its advantages of speed, sensitivity, specificity, and low sample consumption. While the proteomics field grows rapidly to identify thousands of proteins in a single analysis, "native" mass spectrometry, exploiting the unique features of electrospray ionization (ESI) for delivering large macromolecules to the mass spectrometer, has provided many potential exciting capabilities and applications to structural biology and biochemistry. It can analyze proteins in their native states, i.e., structures present in their native configurations from physiological pH solutions, with minimal sample preparation. In this thesis, I describe the application of native ESI combined with top-down MS using electron capture dissociation (ECD) and ion mobility (IM) to characterize the molecular features of protein-ligand complexes. Binding and structural information can be comprehensively obtained from this experimental platform. Native ESI-MS alone provides molecular mass, stoichiometry, and binding affinity, all from a single analysis. We demonstrate that top-down MS, the fragmentation of intact proteins and protein complexes using MS, offers a powerful capability to elucidate the location of ligand binding on a protein's structure and for probing the surface topology of proteins. Ion mobility mass spectrometry, a recently developed technique that yields information on the structural conformation of molecules, was used to reveal structural changes of proteins upon ligand binding. My thesis focuses on several proteins, including -synuclein (AS), which is a small protein related to Parkinson's disease. AS is natively unfolded at physiological pH, which makes it difficult to study by standard methods such as X-ray crystallography or NMR. Using our mass spectrometry techniques, transition metal binding (copper, cobalt, and manganese) to AS that is associated with accelerating fibril formation was monitored. The binding of a small molecule amyloid inhibitor called molecular tweezer (MT or CLR01) on two model proteins important in neurodegenerative diseases, AS and superoxide dismutase (SOD1), was studied. Tandem mass spectrometry (MS/MS) techniques such as collisionally activated dissociation (CAD) along with ECD were used to characterize the sites of binding of small molecule ligands to proteins. Ion mobility mass spectrometry was implemented to reveal the conformational changes of AS upon metal binding. It was demonstrated that copper can induce the AS protein to collapse into a more compact state, which may provide a hint of the mechanisms behind amyloid fibrillation. Additionally, two new methods to extend the application of top-down MS for protein structure characterization were developed. First, the same molecular tweezer molecule, which has a specificity to bind lysine residues, was used to probe surface residues of proteins. The lysines found to bind to the molecular tweezers identified by top-down MS correlates well with solvent accessibility values, suggesting that the MT compound can be applied as a molecular probe to pinpoint surface active lysine residues. Lastly, supplemental activation methods by ultraviolet and infrared laser irradiation prior to ECD was applied to assist disulfide bond cleavage of complex multiple intermolecular and intramolecular disulfide bond-containing proteins. Backbone bond cleavage from top-down MS was significantly increased when the disulfide bonds were cleaved, allowing more sequence information to be obtained. The new methods described in this thesis extend the applicability of mass spectrometry to provide a more complete picture of a protein's structure.

Author : Ying Zhang
Publisher :
Page : 492 pages
File Size : 34,55 MB
Release : 2015
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Mass spectrometry (MS)-based biophysical approaches are new "tools" for protein characterization owing to its capability to analyze proteins and protein complexes that range in molecular weight from kDa to MDa. Protein characterization requires more than identifying the primary structure. More importantly, protein high order structures (i.e., secondary, tertiary and quaternary structures) are needed for biological studies. MS has become the major tool in studies of protein primary structure and post translational modifications (PTMs) over the past two decades. Because MS has high sensitivity and fast turnaround, more and more biophysical approaches rely on MS to generate information for protein higher order structures. One of the emerging biophysical approaches is MS-based protein footprinting. Protein surface regions can be covalently labeled by chemical reagents in a biologically relevant environment. These chemical labels can be read out by MS through either bottom-up or top-down MS proteomics analysis. The outcome provides protein conformational information. Among various chemical labeling strategies, hydrogen deuterium exchange (HDX) is one of the most commonly used approaches in MS-based protein biophysical studies. HDX-MS is introduced in Chapter 1 by covering the early developments and new applications especially in measuring interaction affinities. Although HDX-MS has been developed for decades, there are still many challenges in protein characterization that require new or improved HDX method development. One such challenge is characterization of protein aggregation. Protein aggregation leads to loss of protein function, and protein aggregates are implicated in several neurodegenerative diseases like Alzheimer's and Parkinson's diseases. A key issue in studies of protein aggregation is real-time monitoring under biologically relevant condition. We developed an HDX-MS-based approach by studying Alzheimer's disease related A[beta] aggregation, and we described this development in Chapter 2. A[beta] proteins are labeled by deuterium in a pulsed way during A[beta] aggregation. The extents of aggregations are monitored by MS as deuterium uptake. This pulsed HDX platform provides peptide-level information about A[beta] aggregation. Ligands (drug candidates) were also evaluated with this platform to determine how the drug candidates affect oligomerization (Chapter 3). Ligand interactions can induce protein conformational changes, which are required in various protein functions like signaling, enzyme activity. Such interactions are fundamental to all biological processes. One of the often used ligands in cells is calcium. Calcium interacts with a variety of calcium-binding proteins, most of which have conserved sequence that form EF-hand motifs to bind calcium. MS-HDX has been an important tool in studies of these typical calcium-binding proteins. Many proteins without an EF-hand motif also require calcium for their function. For example, protein-arginine deiminase (PAD) is an enzyme for arginine citrullination and binds calcium without EF-hand motif. We conducted differential HDX studies on PAD2 protein (Chapter 4). Multiple and cooperative calcium binding of PAD2 are detected by HDX. HDX was further extended by applying protein-ligand titration in an HDX experiment (i.e., Protein-ligand interactions by mass spectrometry, titration and H/D exchange, PLIMSTEX). The calcium binding affinity of each binding site can be elucidated by PLIMSTEX (Chapter 5). Protein aggregation or ligand-binding induced conformational changes can also be detected by MS-HDX. One significant question in MS-based biophysical studies is how to generate structural information for proteins in the absence of a high resolution structure. In a newly developed platform, we combined a traditional structural biology approach, homology modeling, and MS-HDX to generate a structural model for diheme cytochrome c (DHCC) from Heliobacterium (Chapter 6), a protein for which solvent accessibility information from HDX experiment was used as the guide for homology modeling and used to generate a refined structural model of DHCC by using various computational approaches. In summary, we describe in this thesis development and application of several new, refined approaches of HDX and analyze protein aggregation, protein-ligand binding and unknown protein structures. We hope other scientists can apply these approaches to solve complicated and demanding biological problems that are difficult to investigate using traditional biophysical methods.

Author : Michael Nshanian
Publisher :
Page : 175 pages
File Size : 36,5 MB
Release : 2018
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The advent of top-down protein mass spectrometry (MS), or direct analysis of intact proteins forgoing proteolysis, has transformed the field of protein mass spectrometry, ushering in a new era of protein identification and characterization together with a new set of challenges. The analysis of intact proteins and their direct fragmentation in tandem (MS/MS) mode helps overcome the "inference" problem associated with peptide-based bottom-up proteomics; that is, correctly assigning given peptide fragments and their modifications to the intact protein from which they originated. Despite its many advantages, however, the top-down approach requires extensive sample fractionation and suffers from low sensitivity but much progress has been made. From recently-developed cross-linked polyacrylamide gels, from which intact proteins can be more easily recovered, to the discovery of reagents that enhance protein charging in electrospray ionization (ESI), there have been considerable gains in detection and sensitivity, offering the potential for a more complete and accurate characterization of a "proteoform": the full complement of the combinatorial possibilities that could arise from a given gene product. Top-down MS also includes the study of proteins in their native or native-like states. This is especially important in characterizing disease-related proteins, particularly in the context of protein aggregation. Native MS, using electron-capture dissociation (ECD) and ion mobility spectrometry (IMS), enables the study of protein-inhibitor complexes in the gas phase, offering structural insight into stoichiometry, site of inhibitor binding and mechanism of inhibition. In addition, intact analysis and electron-based fragmentation enable the detection of thermally-labile post-translational modifications like phosphorylation, known to play key regulatory roles in shifting proteins towards cytotoxic states. Top-down method developments in protein recovery, separation and supercharging have led to improvements in detection and sensitivity, while top-down MS applications to structural characterization of disease-related proteins have shed more light on the mechanisms of cytotoxic aggregation, offering greater promise of therapeutic development.

Author : Carter Lantz
Publisher :
Page : 0 pages
File Size : 47,92 MB
Release : 2022
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Mass spectrometry (MS) has been found to be a useful technique for the study of various compounds. Fundamentally, MS is a way to measure the masses of compounds for the purpose of identifying and quantifying those compounds. Protein mass spectrometry, where proteins are the analyte of interest, has been found to return relevant information on those proteins including the mass, the identity and location of modifications, and even aspects of protein higher-order structure. The work here aims to develop mass spectrometry methods for the study of proteins and to use those methods to investigate amyloid proteins common in neurodegenerative diseases. Herein, it is described how ClipsMS, a program that assigns internal fragments resulting from top-down mass spectrometry (TD-MS), can be utilized to increase the sequence coverage of proteins and locate modifications. This work also illustrates how native TD-MS of large protein complexes with high-energy C-trap dissociation (HCD) can release covalent fragments that reveal aspects of higher-order structure. Furthermore, it is described how TD-MS of proteins with electron capture dissociation (ECD) on an orbitrap-based mass spectrometer can return relevant information on proteins including sequence information, the location of modifications, and higher-order structure information on protein complexes. In this work, MS techniques were also utilized to characterize neurodegenerative disease protein monomers and oligomers. The research conducted reveals the location of phosphorylation sites on commonly phosphorylated amyloid proteins and that phosphorylation compacts the gas-phase structure of those proteins. It is possible that structure alteration due to phosphorylation could modulate the aggregation potential of amyloid proteins. In addition, it was found that CLR01, a molecular tweezer compound that has been found to inhibit amyloid protein aggregation, directly interacts with the N-terminus of multiple proteoforms of the amyloid protein [alpha]-synuclein and that the molecule compacts the gas-phase structure of the protein. It is possible that compaction of the N-terminal region of [alpha]-synuclein by CLR01 could prevent monomers from interacting with one another and forming oligomers and fibrils of the protein. Lastly, MS was utilized to determine size information and aggregation interface information for various amyloid protein oligomers. Characterization of these small aggregates could provide information on how they become toxic in brain neurons. The data presented here aims to further mass spectrometry methods for the characterization of proteins and to use those methods to reveal protein aggregation mechanisms and discover possible therapies for neurodegenerative diseases.

Author : Michael B. Cammarata
Publisher :
Page : 322 pages
File Size : 38,9 MB
Release : 2016
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The dissertation will discuss the advancement of informative structural biology techniques utilizing a top-down centric workflow with 193nm ultraviolet photodissociation (UVPD) mass spectrometry. Native electrospray ionization is used to transport proteins to the gas phase in a native-like state, then UVPD is used for structural characterization to reveal ligand binding sites within a protein-ligand complex as well as detect conformational changes based upon the suppression or enhancement of backbone cleavages. Conformational changes induced by ligand exchange or removal and single amino acid mutations as well as combinations of the two (ligands and mutations) are investigated. The rich fragmentation patterns of UVPD are also used for structural characterization of crosslinked proteins. Typically these crosslinking experiments are performed by bottom-up mass spectrometry with has significant shortcomings. The main drawback is the need for proteolysis which cuts proteins into small peptides, thus increasing the complexity of the samples and its subsequent analysis. Additionally this proteolysis step loses the post-translation modification information or amino acid mutations that may be driving a specific protein-protein interaction. Top-down methods avoid protein digestion and thus are used to directly evaluate the protein interactions or protein complexes. These two methodologies will bring the mass spectrometry and structural biology community a step closer to the realization of high-throughput structural biology for proteins and their interactions with other proteins and small molecules.

Author : Bifan Chen
Publisher :
Page : 215 pages
File Size : 48,70 MB
Release : 2019
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The study of proteins is critical for understanding cellular functions at the molecular level. Top-down mass spectrometry (MS) has emerged as a premier tool for global and comprehensive analysis of proteoforms. The top-down approach retains intact mass information, providing a "bird's-eye" view of the proteome and allowing for identification of novel proteoforms, in-depth sequence characterization, and quantification of disease associated post-translational modifications (PTMs). However, many technical challenges still exist. The research described here involves analytical development in top-down MS, particularly in the areas of enrichment, separation, and characterization of samples ranging from standard proteins and complex lysates, to large therapeutic biomolecules. Chapter 1 provides an introduction and review of recent advances in different aspects of top-down proteomics. Chapters 2 and 3 are related to the study of intact phosphoproteins. Specifically, chapter 2 describes the use of functionalized nanoparticles for enrichment and the subsequent coupling of online liquid chromatography (LC)-MS for characterizing endogenous phosphoproteins from complex cell lysates. Chapter 3 investigates how phosphorylation moieties might influence the efficiency of electron capture dissociation (ECD). Chapters 4 and 5 focus on the development of hydrophobic interaction chromatography (HIC) that could be coupled online directly with MS and its applications to therapeutic molecules (monoclonal antibodies). Chapter 6 describes a middle-down approach to obtain multi-attribute of both cysteine and lysine conjugated antibody-drug conjugates, which overcomes some current challenges using HIC-MS and the top-down approach. Overall, these analytical developments expand the toolbox of the top-down approach and generally facilitate the analysis of intact proteins.

Author : Laura M Cole
Publisher : Humana
Page : 0 pages
File Size : 30,30 MB
Release : 2024-07-07
Category : Science
ISBN : 9781071633212

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This second edition details new and updated chapters on key methodologies and breakthroughs in the mass spectrometry imaging (MSI) field. Chapters guide readers through nano-Desorption Electrospray Ionisation (nDESI), Matrix Assisted Laser Desorption Ionisation-2 (MALDI-2), Laser Ablation - Inductively Coupled Plasma-Mass Spectrometry (LA-ICP-MS) ,Imaging Mass Cytometry (IMC) with a variety of diverse samples including eye tissue, crop analysis, 3D cell culture models, and counterfeit goods analysis. Written in the format of the highly successful Methods in Molecular Biology series, each chapter includes an introduction to the topic, lists necessary materials and reagents, includes tips on troubleshooting and known pitfalls, and step-by-step, readily reproducible protocols. Authoritative and cutting-edge, Imaging Mass Spectrometry: Methods and Protocols, Second Edition aims to be a useful and practical guide to new researchersand experts looking to expand their knowledge.

Author : Cláudio M. Gomes
Publisher : CRC Press
Page : 302 pages
File Size : 36,66 MB
Release : 2016-04-19
Category : Medical
ISBN : 1439809658

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The role of metal ions in protein folding and structure is a critical topic to a range of scientists in numerous fields, particularly those working in structural biology and bioinorganic chemistry, those studying protein folding and disease, and those involved in the molecular and cellular aspects of metals in biological systems. Protein Folding an

Author : John R. Griffiths
Publisher : John Wiley & Sons
Page : 414 pages
File Size : 44,68 MB
Release : 2016-11-07
Category : Science
ISBN : 1119045851

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Covers all major modifications, including phosphorylation, glycosylation, acetylation, ubiquitination, sulfonation and and glycation Discussion of the chemistry behind each modification, along with key methods and references Contributions from some of the leading researchers in the field A valuable reference source for all laboratories undertaking proteomics, mass spectrometry and post-translational modification research

Author : Giuseppe Paglia
Publisher : Humana
Page : 0 pages
File Size : 44,36 MB
Release : 2019-11-15
Category : Science
ISBN : 9781071600290

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This book focuses on ion mobility-mass spectrometry (IM-MS) and informatics approaches to improve traditional analysis of molecules by providing fundamentals and protocols for exploiting the potential of state-of-the-art IM-MS technology for the most common analytical applications. The chapters have been organized into four parts, each dealing with a particular set of IM-MS applications: 1) metabolomics and lipidomics; 2) proteomics and glycomics; 3) imaging and ambient ionization IM-MS; and 4) bioinformatic solutions for analyzing IM-MS data and deriving CCS values. Written for the highly successful Methods in Molecular Biology series, chapters include introductions to their respective topics, lists of the necessary materials and reagents, step-by-step, readily reproducible laboratory protocols, and tips on troubleshooting and avoiding known pitfalls. Authoritative and practical, Ion Mobility-Mass Spectrometry: Methods and Protocols serves as an ideal resource for scientists delving into the technique's unprecedented analytical advantages, enabling novel qualitative and quantitative applications for the analysis of complex biological samples.