posted on 2022-08-24, 15:12authored byJakub Ujma, Jacquelyn Jhingree, Emma Norgate, Rosie Upton, Xudong Wang, Florian Benoit, Bruno Bellina, Perdita Barran
The gas phase is an idealized laboratory for the study
of protein
structure, from which it is possible to examine stable and transient
forms of mass-selected ions in the absence of bulk solvent. With ion
mobility–mass spectrometry (IM-MS) apparatus built to operate
at both cryogenic and elevated temperatures, we have examined conformational
transitions that occur to the monomeric proteins: ubiquitin, lysozyme,
and α-synuclein as a function of temperature and in source activation.
We rationalize the experimental observations with a temperature-dependent
framework model and comparison to known conformers. Data from ubiquitin
show unfolding transitions that proceed through diverse and highly
elongated intermediate states, which converge to more compact structures.
These findings contrast with data obtained from lysozymea
protein where (un)-folding plasticity is restricted by four disulfide
linkages, although this is alleviated in its reduced form. For structured
proteins, collision activation of the protein ions in-source enables
subsequent “freezing” or thermal annealing of unfolding
intermediates, whereas disordered proteins restructure substantially
at 250 K even without activation, indicating that cold denaturation
can occur without solvent. These data are presented in the context
of a toy model framework that describes the relative occupancy of
the available conformational space.