Resolving heterogeneous macromolecular assemblies by Orbitrap-based single-particle charge detection mass spectrometry

Abstract: We demonstrate single-particle charge detection mass spectrometry on an Orbitrap for the analysis of megadalton biomolecular assemblies. We establish that the signal amplitudes of individual ions scale linearly with their charge, which can be used to resolve mixed ion populations, determine charge states and thus also determine the masses of individual ions. This enables the ultrasensitive analysis of heterogeneous protein assemblies including immunoglobulin oligomers, ribosomes, proteinaceous nanocontainers a… Show more

“…For fragile complexes, the result of this is that the achievable mass resolution may be too low for precisely dening the binding of small ligands. Recent publications by the Kelleher 48 and Heck 49 laboratories have demonstrated the use of charge detection MS of noncovalent complexes on Orbitrap instruments. In these experiments, small numbers of ions were allowed in the trap, allowing highly repeatable mass measurement of individual ions.…”

Higher-order structural characterisation of native proteins and complexes by top-down mass spectrometry

“…For fragile complexes, the result of this is that the achievable mass resolution may be too low for precisely dening the binding of small ligands. Recent publications by the Kelleher 48 and Heck 49 laboratories have demonstrated the use of charge detection MS of noncovalent complexes on Orbitrap instruments. In these experiments, small numbers of ions were allowed in the trap, allowing highly repeatable mass measurement of individual ions.…”

Higher-order structural characterisation of native proteins and complexes by top-down mass spectrometry

“…In terms of the development of MS approaches, the introduction of charge detection (CD) [66] is fundamentally changing data processing and improving the assignment of large protein complexes [67][68][69]. The rationale behind this approach is that peaks in nMS, which are often broad and overlap, render charge state assignment ambiguous.…”

Connecting ‘multi-omics’ approaches to endogenous protein complexes

“…Proteins can be ionized by ESI [27,65,80,81] or MALDI‐MS [75,82–84] and then analyzed by QQQ [27,65,81], Q‐TOF [71–75], linear trap quadrupole (LTQ)‐Orbitrap [74,85–87], or FT‐ICR [83,88–92] mass analyzers. Recently, the ability of Orbitrap MS to assign charge states and masses to proteins and their fragment ions has been demonstrated; this is based on the relationship between the cumulative ion intensity and acquisition time of individual ions [93–95]. Fragmentation can be achieved by collision‐induced dissociation [27,65,74,83,91], higher‐energy C‐trap dissociation [86,96], infrared multiphoton dissociation [83,90], ultraviolet photodissociation [97], electron capture dissociation [83,90,92], electron‐transfer dissociation [84], or in‐source decay [75].…”

Sample preparation and fractionation techniques for intact proteins for mass spectrometric analysis