posted on 2016-08-30, 00:00authored byJakub Ujma, Kevin Giles, Michael Morris, Perdita E. Barran
We
present a new variable temperature (VT), high resolution ion
mobility (IM) drift tube coupled to a commercial mass spectrometer
(MS). Ions are generated in an electrospray ion source with a sampling
cone interface and two stacked ring RF guides which transfer ions
into the mobility analyzer located prior to a quadrupole time-of-flight
mass spectrometer. The drift cell can be operated over a pressure
range of 0.5–3 Torr and a temperature range of 150–520
K with applied fields typically between 3 and 14 V cm–1. This makes the instrument suitable for rotationally averaged collision
cross section (CCS) measurements at low E/N ratios
where ions are near thermal equilibrium with the buffer gas. Fundamental
studies of the effective ion temperatures can be performed at high E/N ratios. An RF ion trap/buncher is located at the beginning
of the drift region, which modulates the continuous ion beam into
spatially narrow packets. Packets of ions then drift in a linear electric
field, which is 50.5 cm long, and are separated according to their
mobility in an inert buffer gas. Post-drift, an ion funnel focuses
the radially spread pulses of ions into the inlet of a commercial
MS platform (Micromass QToF2). We present the novel features of this
instrument and results from VT-IM-MS experiments on a range of model
systemsIMS CCS standards (Agilent ESI Tune Mix), the monomeric
protein Ubiquitin (8.6 kDa), and the tetrameric protein complex Concanavalin
A (103 kDa). We evaluate the performance of the instrument by comparing
ambient DTCCSHe values of model compounds with
those found in the literature. Several effects of temperature on collision
cross sections and resolution are observed. For small rigid molecules,
changes in resolution are consistent with anticipated thermal diffusion
effects. Changes in measured DTCCSHe for these
rigid systems at different temperatures are attributed primarily to
the effect of temperature on the long-range attractive interaction.
Similar effects are seen for protein ions at low temperatures, although
there is also some evidence for structural transitions. By heating
the protein ions, their conformational profiles are significantly
altered. Very high temperatures narrow the conformational space presented
by both Ubiquitin and Concanavalin; it appears that diverse conformational
families are “melted” into more homogeneous populations.
Because of this conformational heterogeneity, the apparent IMS resolution
obtained for proteins at ambient and reduced temperatures is an order
of magnitude lower than the expected diffusion limited resolution
(Rmax). This supports a hypothesis that
the broad DTCCSHe features frequently observed
for proteins do not correspond to interconverting conformers, but
rather to high numbers of intrinsically stable structures.