posted on 2016-05-06, 00:00authored byTimothy
M. Allison, Michael Landreh, Justin L. P. Benesch, Carol V. Robinson
Ion mobility mass spectrometry of
integral membrane proteins provides
valuable insights into their architecture and stability. Here we show
that, due to their lower charge, the average mobility of native-like
membrane protein ions is approximately 30% lower than that of soluble
proteins of similar mass. This has implications for drift time measurements,
made on traveling wave ion mobility mass spectrometers, which have
to be calibrated to extract collision cross sections (Ω). Common
calibration strategies employ unfolded or native-like soluble protein
standards with masses and mobilities comparable to the protein of
interest. We compare Ω values for membrane proteins, derived
from standard calibration protocols using soluble proteins, to values
measured using an RF-confined drift tube. Our results demonstrate
that, while common calibration methods underestimate Ω for native-like
or unfolded membrane protein complexes, higher mass soluble calibration
standards consistently yield more accurate Ω values. These findings
enable us to obtain directly structural information for highly charge-reduced
complexes by traveling wave ion mobility mass spectrometry.