Deamidation reactions of protonated asparagine and glutamine investigated by ion spectroscopy

Kempkes, Lisanne J. M.; Martens, Jonathan; Grzetic, Josipa; Berden, Giel

doi:10.1002/rcm.7464

Cited by 15 publications

(33 citation statements)

References 38 publications

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“…These structures were then optimized using the DFT protocol and their scaled harmonic spectra were compared with the experimental spectra. The computational procedure is described in more detail elsewhere [25,41,44].…”

Section: Computational Chemistrymentioning

confidence: 99%

“…Structures of the product ions were determined using a combination of mass spectrometry, infrared multiple photon dissociation (IRMPD) spectroscopy and theoretical calculations. IRMPD spectroscopy has previously been used to determine the structures of several protonated peptide precursor ions and fragments [17][18][19][20][21][22], and has proven to be a powerful method to distinguish isomers, (prototropic) tautomers and conformers [18,21,[23][24][25][26][27][28][29][30][31][32][33].…”

Section: Introductionmentioning

confidence: 99%

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Dehydration reactions of protonated dipeptides containing asparagine or glutamine investigated by infrared ion spectroscopy

Kempkes

Martens

Berden

2018

International Journal of Mass Spectrometry

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The role of specific amino acid side-chains in the fragmentation chemistry of gaseous protonated peptides resulting from collisional activation remains incompletely understood. For small peptides containing asparagine and glutamine, a dominant fragmentation channel induced by collisional activations is, in addition to deamidation, the loss of neutral water. Identifying the product ion structures from H2O-loss from four protonated dipeptides containing Asn or Gln using infrared ion spectroscopy, mechanistic details of the dissociation reactions are revealed. Several sequential dissociation reactions have also been investigated and provide additional insights into the fragmentation chemistry. While water loss can in principle occur from the C-terminus, the side chain or the amide bond carbonyl oxygen, in most cases the C-terminus was found to detach H2O, leading to a b2-sequence ion with an oxazolone structure for AlaGln, and bifurcating mechanisms leading to both oxazolone and diketopiperazine species for AlaAsn and AsnAla. In contrast, GlnAla expels water from the amide side chain leading to an imino-substituted prolinyl structure.

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Section: Computational Chemistrymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Dehydration reactions of protonated dipeptides containing asparagine or glutamine investigated by infrared ion spectroscopy

Kempkes

Martens

Berden

2018

International Journal of Mass Spectrometry

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“…Hydrolysis in the ion trap produced hydroxides for spectroscopic studies. The QIT/MS has been modified 37 such that the high-intensity tunable IR beam from FELIX can be directed into the ion packet, resulting in multiphoton dissociation that is appreciable only when the IR frequency is in resonance with an adequately high absorption vibrational mode of the particular mass-selected complex being studied. The FEL produces ∼5 μs long IR pulses with an energy of typically 40 mJ, which are in the form of a sequence of ∼1 ps long − decarboxylation energies as well as possible competitive reaction energies (i.e., ligand elimination) for R = CH 3 (methyl), CH 3 CC (1-propynyl), C 6 H 5 (phenyl), C 6 F 5 (pentafluorophenyl).…”

Section: ■ Experimental Sectionmentioning

confidence: 99%

Synthesis and Hydrolysis of Uranyl, Neptunyl, and Plutonyl Gas-Phase Complexes Exhibiting Discrete Actinide–Carbon Bonds

et al. 2016

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Gas-phase organoactinyl complexes possessing discrete An−C bonds (An = U, Np, Pu) were synthesized in a quadrupole ion trap by endothermic decarboxylation of [AnO 2 (O 2 C−R) 3 ]− anion complexes in which a formally AnO 2 2+ actinyl core is coordinated by three carboxylate ligands, with R = CH 3 (methyl), CH 3 CC (1-propynyl), C 6 H 5 (phenyl), C 6 F 5 (pentafluorophenyl). Decarboxylation and competing ligand loss were studied computationally by density functional theory complementing experiment. Although decarboxylation was computed to be the energetically most favorable process in all cases, reduction from An(VI) to An(V) via neutral ligand loss was often prevalent, particularly for An = Np, Pu, presumably resulting from barriers associated with decarboxylation. Comparative hydrolysis rates of the An−C bonds were experimentally determined, and the chemical properties of these bonds were analyzed by the quantum theory of atoms in molecules. The measured hydrolysis rates differed by up to 3 orders of magnitude: the fastest was for [(CH 3 CC)UO 2 (O 2 C− CCCH 3 ) 2 ]− and the slowest for [(C 6 F 5 )PuO 2 (O 2 C−C 6 F 5 ) 2 ]− . There is a general correlation between hydrolysis exothermicity and hydrolysis rate. Prototypical hydrolysis reaction pathways computed for R = CH 3 (An = U, Np) reveal a mechanism in which an outer-sphere water becomes inner-sphere concomitant with transfer of an H atom to yield an OH ligand and CH 4 , with a net energy release of 170 kJ mol −1 and a transition state barrier of 45 kJ mol −1 for An = U. Infrared multiphoton dissociation spectra of selected complexes were acquired to confirm the predicted structures by agreement between the computed and observed vibrational frequencies. The experiment and theory results provide an evaluation of the comparative propensities for formation of the organoactinyls as a function of actinide and carboxylate and an assessment of the nature and stability toward hydrolysis of the primarily ionic An−C bonds.

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“…Single‐point electronic energies were also obtained at the MP2(full)/6‐31 + G(d,p)//B3LYP/6‐31++G(d,p) level for comparison. The computational procedure is described in more detail elsewhere …”

Section: Experimental and Computational Methodsmentioning

confidence: 99%

w‐Type ions formed by electron transfer dissociation of Cys‐containing peptides investigated by infrared ion spectroscopy

2018

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In mass spectrometry‐based peptide sequencing, electron transfer dissociation (ETD) and electron capture dissociation (ECD) have become well‐established fragmentation methods complementary to collision‐induced dissociation. The dominant fragmentation pathways during ETD and ECD primarily involve the formation of c‐ and z •‐type ions by cleavage of the peptide backbone at the N─Cα bond, although neutral losses from amino acid side chains have also been observed. Residue‐specific neutral side chain losses provide useful information when conducting database searching and de novo sequencing. Here, we use a combination of infrared ion spectroscopy and quantum‐chemical calculations to assign the structures of two ETD‐generated w‐type fragment ions. These ions are spontaneously formed from ETD‐generated z •‐type fragments by neutral loss of 33 Da in peptides containing a cysteine residue. Analysis of the infrared ion spectra confirms that these z •‐ions expel a thiol radical (SH•) and that a vinyl C═C group is formed at the cleavage site. z •‐type fragments containing a Cys residue but not at the cleavage site do not spontaneously expel a thiol radical, but only upon additional collisional activation after ETD.

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Deamidation reactions of protonated asparagine and glutamine investigated by ion spectroscopy

Cited by 15 publications

References 38 publications

Dehydration reactions of protonated dipeptides containing asparagine or glutamine investigated by infrared ion spectroscopy

Dehydration reactions of protonated dipeptides containing asparagine or glutamine investigated by infrared ion spectroscopy

Synthesis and Hydrolysis of Uranyl, Neptunyl, and Plutonyl Gas-Phase Complexes Exhibiting Discrete Actinide–Carbon Bonds

w‐Type ions formed by electron transfer dissociation of Cys‐containing peptides investigated by infrared ion spectroscopy

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