OBSERVATION AND IMPLICATIONS OF HIGH MASS-TO-CHARGE RATIO IONS FROM ELECTROSPRAY-IONIZATION MASS-SPECTROMETRY

High mass-to-charge ratio ions (> 4000) from electrospray ionization (ESI) have been observed for several proteins, including bovine cytochrome c (M(r) 12,231) and porcine pepsin (M(r) 34,584), by using a quadrupole mass spectrometer with an m/z 45,000 range. The ESI mass spectrum for cytochrome c in an aqueous solution gives a charge state distribution that ranges from 12 + to 2 + , with a broad, low-intensity peak in the mass-to-charge ratio region corresponding to the [M + H]+ ion. The negative ion ESI mass spectrum for pepsin in 1% acetic acid solution shows a charge state distribution ranging from 7 - to 2 -. To observe the [M - H]- ion, harsher desolvation and interface conditions were required. Also observed was the abundant aggregation of the proteins with average charge states substantially lower than observed for their monomeric counterparts. The negative ion ESI mass spectrum for cytochrome c in 1-100 mM NH4OAc solutions showed greater relative abundances for the higher mass-to-charge ratio ions than in acidic solutions, with an [M - H]- ion relative abundance approximately 50% that of the most abundant charge state peak. The observation that protein aggregates are formed with charge states comparable to monomeric species (at lower mass-to-charge ratios) suggests that the high mass-to-charge ratio monomers may be formed by the dissociation of aggregate species. The observation of low charge state and aggregate molecular ions concurrently with highly charged species may serve to support a variation of the charged residue model, originally described by Dole and co-workers (Dole, M., et al. J. Chem. Phys. 1968, 49, 2240; Mack, L. L., et al. J. Chem. Phys. 1970, 52, 4977), which involves the Coulombically driven formation of either very highly solvated molecular ions or lower nanometer-diameter droplets.