Nonspecific aggregation in native electrokinetic nanoelectrospray ionization

Abstract

Native mass spectrometry is widely used to determine the stoichiometries and binding constants of noncovalent interactions in solution. One challenge is that multiple analytes in a single electrospray droplet can aggregate during solvent evaporation, which will bias the distribution of oligomeric states observed during gas-phase measurements. Here, measurements of solution flow rates, electrospray currents, droplet size distributions, and nonspecific aggregation are used in conjunction with Poisson statistics to characterize the factors that control nonspecific aggregation during typical native mass spectrometry experiments. Using electrokinetic nanoelectrospray ionization and a 30nA current, low flow rates of less than 10nLmin−1 and initial droplets with mean diameters of ∼60nm were observed. For solutions containing 4μM analyte under these conditions, Poisson statistics and charge-reduction drift tube ion mobility spectrometry both indicate that ∼90% of the desolvated, occupied droplets contain a single analyte. Initial droplet sizes and contributions from nonspecific aggregates both increase with increasing current. Ion mobility mass spectrometry analysis of the ions produced using these conditions without charge reduction exhibit even less nonspecific aggregation (∼2%). All approaches indicate that increasing the ionization current increases the flow rate, droplet size distribution, and extent of nonspecific aggregation. These results provide detailed insights into the role of small initial droplets in the success of native mass spectrometry.