How Does Mg$^{2+}_{(aq)}$ Interact with ATP$_{(aq)}$? Biomolecular Structure through the Lens of Liquid-Jet Photoelectron Spectroscopy

Abstract: Site-specific information on how adenosine triphosphate in the aqueous phase (ATP${(aq)}$) interacts with magnesium (Mg$^{2+}{(aq)}$) is a prerequisite to understanding its complex biochemistry. To gather such information, we apply liquid-jet photoelectron spectroscopy (LJ-PES) assisted by electronic-structure calculations to study ATP${(aq)}$ solutions with and without dissolved Mg$^{2+}$. Valence photoemission data reveal spectral changes in the phosphate and adenine features of ATP${(aq)}$ due to interactions with the divalent cation. Chemical shifts in Mg 2p, Mg 2s, P 2p, and P 2s core-level spectra as a function of the Mg$^{2+}$/ATP concentration ratio are correlated to the formation of [MgATP]$^{-2}_{(aq)}$ and Mg$2$ATP${(aq)}$ complexes, demonstrating the element-sensitivity of the technique to Mg$^{2+}$-phosphate interactions. In addition, we report and compare P 2s data from ATP${(aq)}$ and adenosine mono- and di-phosphate (AMP${(aq)}$ and ADP${(aq)}$, respectively) solutions, probing the electronic structure of the phosphate chain and the local environment of individual phosphate units in ATP${(aq)}$. Finally, we have recorded intermolecular Coulombic decay (ICD) spectra initiated by ionization of Mg 1s electrons to probe ligand exchange in the Mg$^{2+}$-ATP$_{(aq)}$ coordination environment, demonstrating the unique capabilities of ICD for revealing structural information. Our results provide an overview of the electronic structure of ATP${(aq)}$ and Mg$^{2+}$-ATP${(aq)}$ moieties relevant to phosphorylation and dephosphorylation reactions that are central to bioenergetics in living organisms.