On the Mechanism of Theta Capillary Nanoelectrospray Ionization for the Formation of Highly Charged Protein Ions Directly from Native Solutions.

Theta capillary nanoelectrospray ionization (θ-nanoESI) can be used to "supercharge" protein ions directly from solution for detection by mass spectrometry (MS). In native top-down MS, the extent of protein charging is low. Given that ions with more charge fragment more readily, increasing charge can enhance the extent of sequence information obtained by top-down MS. For θ-nanoESI, dual-channeled nanoESI emitters are used to mix two solutions in low to sub-µs prior to MS. The mechanism for θ-nanoESI mixing has been reported to primarily occur: (i) in a single shared Taylor cone and in the droplets formed from the Taylor cone or (ii) by the fusion of droplets formed from two separate Taylor cones. Using θ-nanoESI-ion mobility MS, native protein solutions were rapidly mixed with denaturing supercharging solutions to form protein ions in significantly higher charge states and with more elongated structures than those formed by premixing the solutions prior to nanoESI-MS. If θ-nanoESI mixing occurred in the Taylor cone and in the droplets resulting from the single Taylor cone, then the extent of protein charging and unfolding should be comparable to or less than that obtained by premixing solutions. Thus, these data are consistent with mixing occurring via droplet fusion rather than in the Taylor cone prior to ESI droplet formation. These data also suggest that highly charged protein ions can be formed by the near-complete mixing of each solution. The presence of supercharging additives in premixed solutions can suppress volatile electrolyte evaporation, limiting the extent of protein charging compared to when the additive is delivered via one channel of a θ-nanoESI emitter. In θ-nanoESI, the formation of two Taylor cones can presumably result in substantial electrolyte evaporation from the ESI droplets containing native-like proteins prior to droplet fusion, thereby enhancing ion charging.

Supercharging protein ions in native mass spectrometry using theta capillary nanoelectrospray ionization mass spectrometry and cyclic alkylcarbonates.

Theta nanoelectrospray ionization of protein ions formed from aqueous buffer solutions that are mixed with denaturing solutions containing cyclic alkylcarbonates (e.g., vinyl ethylene carbonate; VEC) results in a significant increase in the extent of ion charging compared to native mass spectrometry. For six proteins, the extent of ion charging can be significantly higher than that obtained using denaturing solutions and alternative native "supercharging" methods. In theta nanoelectrospray supercharging, the extent of charging scales with protein mass in agreement with an analytical scaling relationship for ions with elongated structures. Theta nanoelectrospray supercharging of non-covalent complexes from native solutions results in essentially the complete loss of protein-ligand and protein-protein interactions. Based on circular dichroism spectroscopy, VEC can effectively denature proteins in buffered solutions. These data provide evidence that enrichment of VEC in theta nanoelectrospray ionization generated droplets can denature proteins on the timescale of droplet desolvation and ion formation. This approach can be used to form highly charged protein ions from native solutions containing biological buffers, including some that are considered incompatible with native MS. Forming some protein ions in the highest reported charge states directly from native solutions is no longer a challenge in obtaining primary structural information using tandem mass spectrometry.