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Advancement of photodissociation and electron-based tandem mass spectrometry methods for proteome analysisMadsen, James Andrew 12 October 2011 (has links)
The number and types of diagnostic ions obtained by infrared multiphoton dissociation (IRMPD) and collision induced dissociation (CID) were evaluated for supercharged peptide ions created by electrospray ionization of solutions spiked with mnitrobenzyl
alcohol. IRMPD of supercharged peptide ions increased the sequence
coverage compared to that obtained by CID for all charge states investigated.
Multiply charged, N-terminally derivatized peptides were subjected to electron transfer reactions to produce singly charged, radical species. Upon subsequent “soft” CID, highly abundant z-type ions were formed nearly exclusively, which yielded
simplified fragmentation patterns amenable to de novo sequencing methods. Furthermore, the simplified series of z ions were shown to retain labile phosphoric acid moieties.
Infrared multiphoton dissociation (IRMPD) was implemented in a novel dual pressure linear ion trap for rapid “top-down” proteomics. Due to secondary dissociation,
IRMPD yielded product ions in significantly lower charge states as compared to CID, thus facilitating more accurate mass identification and streamlining product ion assignment. This outcome was especially useful for database searching of larger proteins (~29 kDa) as IRMPD substantially improved protein identification and scoring
confidence. Also, IRMPD showed an increased selectivity towards backbone cleavages N-terminal to proline and C-terminal to acidic residues (especially for the lowest
precursor charge states). Ultraviolet photodissociation (UVPD) at 193 nm was implemented on a linear ion trap mass spectrometer for high-throughput proteomic workflows. Upon irradiation by a single 5 ns laser pulse, efficient photodissociation of tryptic peptides was achieved with production of a, b, c, x, y, and z sequence ions, in addition to immonium ions and v and w
side-chain loss ions. The factors that influence the UVPD mass spectra and subsequent in silico database searching via SEQUEST were evaluated. 193 nm ultraviolet photodissociation (UVPD) was employed to sequence singly and multiply charged peptide anions. Upon dissociation by this method, a-/x-type, followed by d and w side-chain loss ions, were the most prolific and abundant sequence
ions, often yielding 100% sequence coverage. LC-MS/UVPD analysis using high pH mobile phases yielded efficient characterization of acidic peptides from mitogen-activated protein kinases. / text
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Ultraviolet photodissociation and electron transfer dissociation for peptides and oligosaccharides in quadrupole ion trap using chemical derivatizationKo, Byoung Joon 20 August 2015 (has links)
Photodissociation methods have been explored for structural analysis of peptides and oligosaccharides. Ultraviolet photodissociation (UVPD) was applied to carboxylated derivatized peptides and reducing end derivatized oligosaccharides which offer selective dissociation and specific fragmentation pathways in comparison to CID. Upon UVPD of the modified peptides at carboxylate comprised of reduced y ions and increased immonium ions. The derivatized oligosaccharides via reductive amination and hydrazide conjugation can undergo highly efficient 355 nm UVPD and offer different fragmentation pathways. Both derivatization methods upon UVPD yielded [superscript 0,2] A-type ions, however reductive amination and hydrazide conjugation produced dominant [superscript 0,1] A and [superscript 2,4] A-type ions, respectively. Ultraviolet photodissociation at 193 nm (ArF laser, 6.4 eV / photon) has been applied to sialylated oligosaccharides and glycans which were analyzed in negative mode due to their acidic condition. Primarily, UVPD provides a greater array of fragment ions including cross-ring cleavages and dual cleavage internal ions in comparison to CID. In addition, the UVPD generates unique fragment ions which arise from site-specific cleavage of the trial substituent of the sialic acid residue. UVPD of doubly deprotonated sialylated oligosaccharides produced mostly singly deprotonated fragment ions, whereas the product ions in the CID spectra were overwhelmingly doubly charged ions, an outcome attributed to the more extensive cleavages of sialic acid residue upon UVPD. Although electron transfer dissociation (ETD) has shown superior capabilities for the characterization of post-translational modifications of peptides due to its non-eragodic property, ETD has intrinsic drawback arising from its significant dependence on the charge state of the selected precursor ion. Precursor ions in low charge states tend to undergo charge reduction, often preferentially relative to production of the informative cand z-type ions. In order to increase charge states of peptides and ETD efficiencies, peptides were derivatized at their carboxylate groups via attachment of amine with fixed charge or hydrophobic group. The carboxylate-derivatized peptides exhibited higher ETD efficiencies relative to underivatized peptides along with greater numbers of diagnostic fragment ions. The carboxylate derivatization strategy in combination with ETD for proteomics applications by the proteolytic digestion, the derivatization, and LC-MS purification was demonstrated with Cytochrome C.
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Advanced Techniques in Mass Spectrometry for Qualitative and Quantitative Protein CharacterizationDykstra, Andrew Boissy 01 August 2011 (has links)
Though mass spectrometry has earned a central role in the field of proteomics due to its versatility in a wide range of experiments, challenges and complications are still encountered when using mass spectrometry to characterize protein structures, post-translational modifications (PTMs), and abundances. In this dissertation, analytical methods utilizing mass spectrometry have been developed to address challenges associated with both qualitative and quantitative protein characterization. The effectiveness of using multiple pepsin-like proteases, both separately and in mixtures, combined with online proteolysis using a special triaxial probe has been demonstrated on an amyloid beta peptide related to the onset of Alzheimer’s disease. These findings have broad implications in protein structural characterization studies using hydrogen-deuterium exchange mass spectrometry. A wider range of proteases (Lys-C, Glu-C, and trypsin) and multiple fragmentation methods (collisionally activated dissociation, electron transfer dissociation, and decision tree) have been utilized in the discovery-based PTM characterization of extracellular cellulosome proteins of the bioenergy-relevent organism Clostridium thermocellum, resulting in the identification of 85 previously unknown modification sites in 28 cellulosome proteins. These modifications may contribute to the structure and/or function of the cellulosome protein complex. By using peptide internal standards and a triple quadrupole mass spectrometer operating in selected reaction monitoring mode, a method has been developed for the absolute quantitation of the Clostridium thermocellum cellulosome protein machine in samples ranging in complexity from purified cellulosome samples to whole cell lysates as an alternative to a previously-developed enzyme-linked immunosorbent assay method of cellulosome quantitation. The precision of the cellulosome mass concentration in technical replicates is better than 5% relative standard deviation for all samples, indicating high precision of cellulosome mass concentration for this method. Though methods and results presented in this dissertation have implications in the study of Alzheimer’s disease and bioenergy research, more broadly this dissertation focuses on development of methods to contend with some of the more complex challenges associated with protein characterization currently presented to the field of proteomics.
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The Study of Inter and Intramolecular Interactions in Gas Phase Protein Ions by Electron Transfer DissociationBrowne, Shaynah J 01 January 2012 (has links) (PDF)
Mass spectrometry (MS) is emerging as an important tool for studying protein and protein complexes. When applying this tool, it is important to understand and investigate whether some of the intramolecular and intermolecular interactions of proteins in solution and are maintained in the gas phase. To investigate if some of these interactions are maintained in the gas phase, we develop and use a method in which the electron-transfer dissociation (ETD) spectra of native proteins are compared with spectra from ETD followed by low amplitude collisional induced dissociation (CID). From these experiments, we find that some intramolecular interactions from solution are maintained in the gas phase for ubiquitin and beta-2-microglobulin (β2m). However, using these approaches, cytochrome c’s structure in the gas phase appears to be quite different than its structure in solution. We also investigated if ETD spectra of intact protein complexes reflect contact site information in these complexes
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Analysis of RNA: Peptide Heteroconjugates by Electron Induced Dissociation Mass SpectrometryKrivos, Kady L. 19 April 2011 (has links)
No description available.
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Development of chromogenic cross-linkers and selective gas-phase dissociation methods to assess protein macromolecular structures by mass spectrometryGardner, Myles Winston 05 August 2010 (has links)
Selective gas-phase dissociation strategies have been developed for the characterization of cross-linked peptides and proteins in quadrupole ion trap mass spectrometers. An infrared chromogenic cross-linker (IRCX) containing a phosphotriester afforded rapid differentiation of cross-linked peptides from unmodified ones in proteolytic digests of cross-linked proteins by selective infrared multiphoton dissociation (IRMPD). Only the cross-linked peptides containing the chromogenic phosphate underwent IRMPD and unmodified peptides were not affected by IR irradiation. IRMPD of IRCX-cross-linked peptides yielded uncross-linked y-ion sequence tags of the constituent peptides due to secondary dissociation of all primary product ions which contained the chromophore, thus allowing successful de novo sequencing of the cross-linked peptides.
Peptides cross-linked via a two-step conjugation strategy through the formation of a bis-arylhydrazone (BAH) bond were selectively dissociated by ultraviolet radiation at 355 nm. The BAH-cross-linked peptides could be distinguished from not only unmodified peptides but also dead-end modified peptides based on the selectivity of ultraviolet photodissociation. In a complementary approach, electron transfer dissociation of BAH-cross-linked peptides resulted in preferential cleavage of the hydrazone bond which produced two modified peptides. These modified peptides were subsequently interrogated by CID which allowed for the original site of cross-linking to be pinpointed.
IRMPD was implemented in a dual pressure linear ion trap to demonstrate successful photodissociation of peptides having modest absorptivities. Peptides were observed to efficiently dissociation by IR irradiation exclusively in the low pressure cell whereas no dissociation was observed in the high pressure cell due to extensive collisional cooling. IRMPD provided greater sequence coverage of the peptides than CID and yielded product ion mass spectra which were predominantly composed of singly charged product ions which simplified spectral interpretation. IRMPD was further applied for the sequencing of small-interfering RNA. Complete sequence coverage was obtained and the results were compared to CID. / text
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Electrospray ionization tandem mass spectrometry methods for the analysis of DNA and DNA/drug complexesSmith, Suncerae I. 14 December 2010 (has links)
Many anticancer therapies are based on the interaction of small molecule drugs with nucleic acids, particularly DNA. Electrospray ionization tandem mass spectrometry has established itself as an irreplaceable tool for the characterization of DNA adducts produced by alkylating agents, carcinogens, and antitumor drugs, in addition to the characterization of nucleic acid post-transcriptional modifications.
ESI-MS was used to assess the non-covalent binding of a novel series of intercalating anthrapyrazoles to duplexes containing different sequences. Relative binding affinities paralleled the shift in melting point of the DNA duplexes measured from a previous study. Upon collisionally induced dissociation of the duplex/anthrapyrazole complexes, different binding strengths were discerned based on the fragmentation patterns. In addition, the interactions of a new series of sulfur-containing acridine ligands, some that functioned as alklyating mustards, with duplex DNA were also evaluated. Non-covalent and covalent binding of each ligand was determined, and the site of adduction (G > A) was revealed for the covalent modifications. The distribution of cross-linked products and mono-adducts by
psoralen analogs was also monitored by both LC-UV and IRMPD-MS methods. Reactions at 5’-TA sites were favored over 5’-AT sites. The sites of interstrand cross-linking were determined by fragmentation of the duplex/psoralen complexes by infrared multiphoton dissociation (IRMPD).
Ultraviolet photodissociation (UVPD) at 193 nm caused efficient charge reduction of deprotonated oligodeoxynucleotides via electron detachment. Subsequent CID of the charge-reduced oligodeoxynucleotides formed upon electron detachment, in a net process called electron photodetachment dissociation (EPD), resulted in a diverse array of abundant sequence ions which allowed the modification site(s) of three modified oligodeoxynucleotides to be pinpointed to a more specific location than by conventional CID.
Electron transfer dissociation (ETD) caused efficient charge reduction of multi-protonated oligonucleotides. Subsequent CAD of the charge-reduced oligonucleotides formed upon electron transfer, in a net process termed electron transfer collision activated dissociation (ETcaD), resulted in rich backbone fragmentation, with a marked decrease in the abundance of base loss ions and internal fragments. ETcaD of an oligonucleotide duplex resulted in specific backbone cleavages, with conservation of weaker non-covalent bonds. In addition, IRMPD and UVPD were used to activate charge-reduced oligonucleotides formed upon electron transfer. ET-IRMPD afforded tunable characterization of the modified DNA and RNA, allowing for modified bases to be directly analyzed. ET-UVPD promoted higher energy backbone fragmentation pathways and created the most diverse MS/MS spectra. The numerous products generated by the hybrid MS/MS techniques (ETcaD, ET-IRMPD, and ET-UVPD) resulted in specific and extensive backbone cleavages which allowed for the modification sites of multiple oligonucleotides to be pinpointed. / text
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Combined tandem mass spectrometry and ion mobility spectrometry in proteome analysesChawner, Ross January 2013 (has links)
Proteomic studies aim to identify, quantify and characterise the full complement of proteins in a cell or organism under a defined set of conditions, and are important to our understanding of cellular mechanisms. However, such studies represent a major analytical challenge. A typical proteome analysis involves enzyme-mediated digestion of complex protein mixtures to yield an even more complex mixture of peptides. Combined reverse-phase liquid chromatography and tandem mass spectrometry is then traditionally utilised to ascertain sequence information from the characteristic peptide sequences. Analytical data derived for the peptides are employed as search terms in database searching of protein sequences derived from gene sequences. The extreme complexity of the peptide mixtures analysed means that additional novel approaches are required to fully interrogate the vast number of tandem mass spectra generated, assigning peptide identity and thereby helping to address demanding biological questions. The research reported here aims to further our understanding of both gas phase peptide/peptide fragment ion structure and peptide fragmentation behaviour using a combination of tandem mass spectrometry and ion mobility measurement.To facilitate the determination of peptide ion collision cross section, a novel standard, QCAL-IM, produced using the QconCAT strategy, has been developed to enable calibration of drift time in Travelling Wave Ion Mobility instruments. The standard facilitates empirical determination of the rotationally averaged collision cross section of any peptide/peptide fragment ion that lies within the calibration range encompassed. QCAL-IM was subsequently utilised to determine the collision cross section of a range of peptide ions produced by Lys-C and Lys-N proteolysis of ‘standard’ proteins. Data produced allowed the effect upon gas phase ion conformation through changing the location of the basic residue lysine within a peptide sequence to be assessed.The fragmentation behaviour of peptide ions produced by a variety of digestion regimes during both collision-induced dissociation (CID) and electron transfer dissociation (ETD) has also been extensively studied. The proteases trypsin and Lys-C are those typically utilised during proteomic studies and peptides produced by each have either the basic residues arginine or lysine at their carboxy-terminus. Secondary enzymatic treatment with the exoprotease carboxypeptidase B cleaves these basic residues from the C-terminus. Tandem mass spectrometric analysis of both tryptic/Lys-C peptides and their CBPB truncated analogue highlights that the dominant fragment ion series observed during both CID and ETD is determined, at least in part, by the location of such basic residues.Finally, studies were undertaken to investigate the factors which may promote/inhibit scrambling of peptide fragment ion sequence, which has recently been shown to take place during CID. The effect of modifying the gas phase basicity of the N-terminal amino acid residue is studied through a combination of derivatisation and synthesis of alternative peptide sequences. Increasing the gas phase basicity is shown to inhibit the observed sequence scrambling while promoting concomitant rearrangement/retention of a carboxyl oxygen at the C-terminus to give enhanced formation of bn+H2O product ion species.
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