Native Ambient Mass Spectrometry Imaging of Ligand-Bound and Metal-Bound Proteins in Rat Brain

Label-free spatial mapping of the noncovalent interactions of proteins in their tissue environment has the potential to revolutionize life sciences research by providing opportunities for the interrogation of disease progression, drug interactions, and structural and molecular biology more broadly. Here, we demonstrate mass spectrometry imaging of endogenous intact noncovalent protein-ligand complexes in rat brain. The spatial distributions of a range of ligand-bound and metal-bound proteins were mapped in thin tissue sections by use of nanospray-desorption electrospray ionization. Proteins were identified directly from the tissue by top-down mass spectrometry. Three GDP-binding proteins (ADP ribosylation factor ARF3, ARF1, and GTPase Ran) were detected, identified, and imaged in their ligand-bound form. The nature of the ligand was confirmed by multiple rounds of tandem mass spectrometry. In addition, the metal-binding proteins parvalbumin-a and carbonic anhydrase 2 were detected, identified, and imaged in their native form, i.e., parvalbumin-alpha + 2Ca(2+) and carbonic anhydrase + Zn2+. GTPase Ran was detected with both GDP and Mg2+ bound. Several natively monomeric proteins displaying distinct spatial distributions were also identified by top-down mass spectrometry. Protein mass spectrometry imaging was achieved at a spatial resolution of 200 mu m.

Automated summary

This study demonstrates the use of mass spectrometry imaging to map the noncovalent interactions of proteins in the tissue environment of rat brain. By directly identifying proteins from tissue using nanospray-desorption electrospray ionization, the spatial distributions of ligand-bound and metal-bound proteins were mapped. Additionally, the nature of the ligand was confirmed through multiple rounds of tandem mass spectrometry. The study also identified several natively monomeric proteins displaying distinct spatial distributions.