Author :
Publisher :
Page : pages
File Size : 44,70 MB
Release : 2004
Category :
ISBN :
Characterization of macromolecular protein assemblies by collision-induced and surface-induced dissociation: Expanding the role of mass spectrometry in structural biology.
Author : Christopher Michael Jones
Publisher :
Page : 742 pages
File Size : 24,58 MB
Release : 2008
Category :
ISBN :
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 collisions on the fragmentation products of protein assemblies that vary by mass, number of subunits, and protein structural features. Conditions are first established for the preservation of "native" protein quaternary structure and applied to previously characterized systems for proof-of-concept. Native mass spectrometry is subsequently combined with limited proteolysis experiments to characterize the subunit interface of a unique small heat shock protein, HSP18.5 fromArabidopsis 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. 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 masssymmetric 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 are attributed to the rapid deposition of large amounts of internal energy upon collision at a massive surface target, and reflect a dissociation process that precedes subunit unfolding. This provides access to dissociation pathways inaccessible by traditional means of activation. The fragmentation products observed by SID demonstrate promise for expanding the role of mass spectrometry in the field of structural biology.
Author : Jing Yan (Ph. D. in chemistry)
Publisher :
Page : 219 pages
File Size : 32,93 MB
Release : 2017
Category : Chemistry
ISBN :
In the work described in Chapter 4, conformations of globular protein complex ions generated in gas phase ion-ion reactions and solution additive charge reduction are compared. When the conformation of the precursor ions is disrupted by the supercharging or cone activation, the difference in SID fragmentation patterns of ions generated from gas phase ion-ion reactions can be observed, indicating that the conformation of protein complex ions can be preserved in gas phase ion-ion reactions.
Author : Erin M. Panczyk
Publisher :
Page : 210 pages
File Size : 14,50 MB
Release : 2021
Category : Ion mobility spectroscopy
ISBN :
Mass spectrometry-based techniques have emerged as powerful analytical tools to investigate the structure of proteins from the primary to quaternary levels. The advancement of mass spectrometry instrumentation and methods has allowed researchers to go beyond just measuring an analyte’s mass-to-charge ratio, but to also probe gas-phase dissociation behaviors and conformations of peptides, proteins, and protein complexes. The primary structure of a protein refers to the linear sequence of amino acids linked together via peptide bonds. The presence, and the order, of specific amino acids in a peptide can strongly influence how a peptide fragments in the gas-phase. Particular amino acids can direct where along the peptide backbone fragmentation is favored and the structure of the fragment ions formed. One method for probing the structure of peptide fragment ions is infrared multiphoton dissociation (IRMPD) mass spectrometry coupled with theoretical quantum chemical calculations. This approach is used to investigate the role of peptide bond conformation on the structure of b2+ fragment ions formed from proline and dimethylproline-containing peptides (Chapter 3). Additionally, IRMPD is used to study the fragmentation patterns of proline containing pentapeptides into b3+ ions (Chapter 4). Native mass spectrometry (nMS) analyzes the intact structures of proteins and protein complexes and offers complementary information to traditional biophysical methods, such as NMR or cryo-EM. Tandem mass spectrometry, specifically surface-induced dissociation (SID), provides information on protein complex connectivity, stoichiometry, and gas-phase structural rearrangement. SID is utilized to monitor deviation from native structure for protein complexes generated from submicrometer nanoelectrospray capillaries (Chapter 5), as well as to provide insight into connectivity of protein complexes selected by trapped ion mobility spectrometry (Chapter 6). In addition to SID, ion mobility spectrometry provides information on the gas-phase shape or conformation of biomolecules. Here, ion mobility spectrometry is utilized to separate multiple conformers of proline-containing peptides (Chapter 3), compare the collision cross sections of protein complexes generated from submicrometer and micrometer sized nanoelectrospray capillaries (Chapter 5), and select protein complexes and isomeric peptides prior to dissociation on an ultrahigh resolution mass spectrometry platform (Chapter 6). Finally, the development and optimization of Trapped Ion Mobility Spectrometry (TIMS) for native mass spectrometry applications is applied to the widely available timsTOF Pro mass spectrometry platform to promote the dissemination of native ion mobility technology.
Author : Mowei Zhou
Publisher :
Page : 242 pages
File Size : 16,90 MB
Release : 2013
Category :
ISBN :
Abstract: There is a growing interest in application of mass spectrometry as a high throughput technique for quaternary structure studies of protein complexes. One way to study protein complexes by mass spectrometry is to specifically label peptides segments that carry critical structural information, and after protein digestion subsequently identify the labeled peptides using liquid chromatography - mass spectrometry. A chemical crosslinker forms covalent bonds at specific amino acid sidechains that are in proximity in the protein structure. This approach is used to probe the binding interface of LexA/RecA proteins in Escherichia coli (Chapter 3). In contrast, intact noncovalent protein complexes can be directly transferred into the gas phase, while retaining memory of their solution structures. Accurate molecular weight measurement by mass spectrometry can be used for stoichiometry determination of protein-protein and protein-ligand systems, as manifested by the two examples of stoichiometry determination of differently treated adiponectin oligomers (Chapter 4), and the silver binding properties of the N-terminal region of a bacterial protein CusB (Chapter 5).
Author : Alyssa Quencer Stiving
Publisher :
Page : 347 pages
File Size : 36,38 MB
Release : 2020
Category : Mass spectrometry
ISBN :
Ultimately, the work outlined within this dissertation demonstrates the development of SID, IM, and UVPD instrumentation and methods, expanding the tools available within native MS to perform more in-depth characterization of peptide, protein, and protein complex structures.
Author : Thomas Walzthöni
Publisher :
Page : 173 pages
File Size : 11,27 MB
Release : 2013
Category :
ISBN :
Author : Alexandre A. Shvartsburg
Publisher : CRC Press
Page : 322 pages
File Size : 41,4 MB
Release : 2008-12-24
Category : Science
ISBN : 9781420051070
Over the last decade, scientific and engineering interests have been shifting from conventional ion mobility spectrometry (IMS) to field asymmetric waveform ion mobility spectrometry (FAIMS). Differential Ion Mobility Spectrometry: Nonlinear Ion Transport and Fundamentals of FAIMS explores this new analytical technology that separates and characterizes ions by the difference between their mobility in gases at high and low electric fields. It also covers the novel topics of higher-order differential IMS and IMS with alignment of dipole direction. The book relates the fundamentals of FAIMS and other nonlinear IMS methods to the physics of gas-phase ion transport. It begins with the basics of ion diffusion and mobility in gases, covering the main attributes of conventional IMS that are relevant to all IMS approaches. Building on this foundation, the author reviews diverse high-field transport phenomena that underlie differential IMS. He discusses the conceptual implementation and first-principles optimization of FAIMS as a filtering technique, emphasizing the dependence of FAIMS performance metrics on instrumental parameters and properties of ion species. He also explores ion reactions in FAIMS caused by field heating and the effects of inhomogeneous electric field in curved FAIMS gaps. Written by an accomplished scientist in the field, this state-of-the-art book supplies the foundation to understand the new technology of nonlinear IMS methods.
Author : Royston Samuel Quintyn
Publisher :
Page : pages
File Size : 43,78 MB
Release : 2015
Category :
ISBN :
By monitoring the surface induced dissociation (SID) products as a function of increasing collision energy or from sub-complexes initially produced from SID of the native complexes (in SID-IM-SID experiments), we were able to gain a fundamental mechanistic insight into the assembly of several tetrameric protein complexes. In addition, the SID collision energies associated with appearance of the SID fragments may be used as a means of characterizing the relative strengths of the inter-subunit contacts. The coupling of IM with collision-induced dissociation (CID) and SID allowed us to identify and characterize the structures of the conformational intermediates present during the unfolding of several complexes, and thus illustrates its capability to probe the folding mechanisms of protein complexes.
Author : M. Chance
Publisher : John Wiley & Sons
Page : 325 pages
File Size : 29,15 MB
Release : 2008-09-22
Category : Science
ISBN : 0470258861
Presents a wide variety of mass spectrometry methods used to explore structural mechanisms, protein dynamics and interactions between proteins. Preliminary chapters cover mass spectrometry methods for examining proteins and are then followed by chapters devoted to presenting very practical, how-to methods in a detailed way. Includes footprinting and plistex specifically, setting this book apart from the competition.
