Ultraviolet photodissociation and electron transfer dissociation for peptides and oligosaccharides in quadrupole ion trap using chemical derivatization

Ko, Byoung Joon

20 August 2015

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.

Mass spectrometry

Ultraviolet photodissociation

Electron transfer dissociation

Electrospray ionization

Development of tandem mass spectrometric methods for proteome analysis utilizing photodissociation and ion/ion reactions

Shaw, Jared Bryan

13 September 2013

The utility of 193 nm ultraviolet photodissociation (UVPD) and negative electron transfer dissociation (NETD) for the characterization of peptide anions was systematically evaluated. UVPD outperformed NETD in nearly all metrics; however, both methods provided complementary information to traditional collision induced dissociation (CID) of peptide cations in high throughput analyses. In order to enhance the performance of NETD, activated ion negative electron transfer dissociation (AI-NETD) methods were developed and characterized. The use of low-level infrared photoactivation or collisional activation during the NETD reaction period significantly improved peptide anion sequencing capabilities compared to NETD alone. Tyrosine deprotonation was shown to yield preferential electron detachment upon NETD or UVPD, resulting in N - C[alpha] bond cleavage N-terminal to the tyrosine residue. LC-MS/MS analysis of a tryptic digest of BSA demonstrated that these cleavages were regularly observed under high pH conditions. Transmission mode desorption electrospray ionization (TM-DESI) was coupled with 193 nm UVPD and CID for the rapid analysis and identification of protein digests. Comparative results are presented for TM-DESI-MS/CID and TM-DESI-MS/UVPD analyses of five proteolyzed model proteins. In some cases TM-DESI/UVPD outperformed TM-DESI-MS/CID due to the production of an extensive array of sequence ions and the ability to detect low m/z product ions. 193 nm UVPD was implemented in an Orbitrap mass spectrometer for characterization of intact proteins. Near-complete fragmentation of proteins up to 29 kDa was achieved. The high-energy activation afforded by UVPD exhibited far less precursor ion charge state dependence than conventional methods, and the viability of 193 nm UVPD for high throughput top-down proteomics analyses was demonstrated for the less 30 kDa protein from a fractionated yeast cell lysate. The use of helium instead of nitrogen as the C-trap and HCD cell bath gas and trapping ions in the HCD cell prior to high resolution mass analysis significantly reduced the signal decay rate for large protein ions. As a result, monoclonal IgG1 antibody was isotopically resolved and mass accurately determined. A new high mass record for which accurate mass and isotopic resolution has been achieved (148,706.3391 Da ± 3.1 ppm) was established. / text

Mass spectrometry

Ultraviolet photodissociation

Ion/ion reactions

Bottom-up proteomics

Top-down proteomics

Orbitrap

Development of chromogenic cross-linkers and selective gas-phase dissociation methods to assess protein macromolecular structures by mass spectrometry

Gardner, Myles Winston

05 August 2010

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

Mass spectrometry

Infrared multiphoton dissociation

Cross-linking

Quadrupole ion trap

Photodissociation

Protein cross-linking

Electron transfer dissociation

Ultraviolet photodissociation

Small-interfering RNA

Electrospray ionization tandem mass spectrometry methods for the analysis of DNA and DNA/drug complexes

Smith, Suncerae I.

14 December 2010

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

DNA

DNA/drug

RNA

Tandem mass spectrometry

Collision induced dissociation

Infrared multiphoton dissociation

Ultraviolet photodissociation

Electron transfer dissociation