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The Bush Lab welcomes Misa! Click here to learn more about Misa.

 

 

Congratulations to Kim Davidson, whose research is featured on the cover of the special issue on “New developments and applications of mass spectrometry methods for studying non-covalent protein interactions”.

Nonspecific Aggregation in Native Electrokinetic Nanoelectrospray Ionization. Kimberly L. Davidson; Derek R. Oberreit; Christopher J. Hogan; Matthew F. Bush. Int. J. Mass Spectrom. 2017, 420, 35–42. (Link | Cover)

Matt Bush presented the following talks at the ACS Fall National Meeting in Washington DC, where he also received the Arthur F. Findeis Award for Achievements by a Young Analytical Scientist.

ANYL 269: Interpreting the collision cross sections of proteins: Insights from ion mobility, unfolding, and folding of ions in the gas phase, as a part of the Analytical Division Award Symposium.

PHYS 322: Effects of charge state on the structures of protein ions: Results from cation-to-anion proton-transfer reactions (CAPTR), as a part of the symposium on Gaseous Ion Chemistry & Surface Reactions.

Interpreting the Collision Cross Sections of Native-Like Protein Ions: Insights from Cation-to-Anion Proton-Transfer Reactions. Kenneth J. Laszlo, Matthew F. Bush. Anal. Chem. 2017, DOI: 10.1021/acs.analchem.7b01474. (Link)

The effects of charge state on structures of native-like cations of serum albumin, streptavidin, avidin, and alcohol dehydrogenase were probed using cation-to-anion proton-transfer reactions (CAPTR), ion mobility, mass spectrometry, and complementary energy-dependent experiments. The CAPTR products all have collision cross-section (Ω) values that are within 5.5% of the original precursor cations. The first CAPTR event for each precursor yields products Continue reading “New Publication: Interpreting the Collision Cross Sections of Native-Like Protein Ions: Insights from Cation-to-Anion Proton-Transfer Reactions”

Structural Dynamics of Native-Like Ions in the Gas Phase: Results from Tandem Ion Mobility of Cytochrome c. Samuel J. Allen, Rachel M. Eaton, Matthew F. Bush. Anal. Chem. 2017, DOI: 10.1021/acs.analchem.7b01234. (Link)

Ion mobility (IM) is a gas-phase separation technique that is used to determine the collision cross sections of native-like ions of proteins and protein complexes, which are in turn used as restraints for modeling the structures of those analytes in solution. Here, we evaluate the stability of native-like ions using tandem IM experiments implemented using structures for lossless ion manipulations (SLIM). In this implementation of tandem IM, ions undergo a first dimension of IM up to a switch that is used to selectively transmit ions of a desired mobility. Selected ions are accumulated in a trap and then released after a delay to initiate the second dimension of IM. For delays ranging from 16 to 33 231 ms, Continue reading “New Publication: Structural Dynamics of Native-Like Ions in the Gas Phase: Results from Tandem Ion Mobility of Cytochrome c”

Effects of Solution Structure on the Folding of Lysozyme Ions in the Gas-Phase. Kenneth J. Laszlo, Eleanor B. Munger, Matthew F. Bush. J. Phys. Chem. B 2017, 121, 2759–2766. (Link)

The fidelity between the structures of proteins in solution and protein ions in the gas phase is critical to experiments that use gas-phase measurements to infer structures in solution. Here we generate ions of lysozyme, a 129-residue protein whose native tertiary structure contains four internal disulfide bonds, from three solutions that preserve varying extents of the original native structure. We then use cation-to-anion proton-transfer reactions (CAPTR) to reduce the charge states of those ions in the gas phase and ion mobility to probe their structures. The collision cross section (Ω) distributions of Continue reading “New Publication: Effects of Solution Structure on the Folding of Lysozyme Ions in the Gas-Phase”

Julia Greenwald, a first year graduate student in the Bush Lab, was recently awarded a National Science Foundation Graduate Research Fellowship! From the NSF:

The NSF Graduate Research Fellowship Program recognizes and supports outstanding graduate students in NSF-supported science, technology, engineering, and mathematics disciplines who are pursuing research-based Master’s and doctoral degrees at accredited United States institutions. (For additional information, click here.)