Interactions of Li<sup>+</sup> ions with NCS1: A potential mechanism of Li<sup>+</sup> neuroprotective action against psychotic disorders. Article

Alam, Md Shofiul, Cedeño, Jonathan, Reyes, Michael A et al. (2024). Interactions of Li<sup>+</sup> ions with NCS1: A potential mechanism of Li<sup>+</sup> neuroprotective action against psychotic disorders. . JOURNAL OF INORGANIC BIOCHEMISTRY, 262 112762. 10.1016/j.jinorgbio.2024.112762

cited authors

  • Alam, Md Shofiul; Cedeño, Jonathan; Reyes, Michael A; Scavuzzo, Sebastian; Miksovska, Jaroslava

abstract

  • Li+ based drugs have been used for the treatment of psychiatric disorders due to their mood stabilizing role for decades. Recently, several studies reported the protective effect of Li+ against severe neuropathologies such as Parkinson's, Alzheimer's, and Huntington's disease. Surprisingly, despite a broad range of Li+ effects on neurological conditions, little is known about its molecular mechanism. In this study, we propose that neuronal calcium sensor 1 (NCS1), can be an effective molecular target for Li+ action. Here we show that the EF-hands in ApoNCS1 have submillimolar affinity for Li+ with Kd = 223 ± 19 μM. Li+ binding to ApoNCS1 quenches Trp emission intensity, suggesting distinct Trp sidechains environment in Li+NCS1 compared to ApoNCS1 and Ca2+NCS1. Li+ association also stabilizes the protein α-helical structure, in a similar way to Ca2+. Li+ association does not promote NCS1 dimerization. Association of Li+ increases NCS1 affinity for the D2R receptor binding peptide, in a similar way to Ca2+, however, the affinity of NCS1 for chlorpromazine is reduced with respect to Ca2+NCS1, possibly due to a decrease in solvent exposed hydrophobic area on the NCS1 surface in the presence of Li+. MD simulation data suggests that Li+ ions are coordinated by four oxygens from Asp and Glu sidechains and one carbonyl oxygen, in a similar way as reported previously for Li+ binding to DREAM. Overall, the data shows that Li+ binds to EF-hands of NCS1 and Li+NCS1 interactions may be involved in the potential neuroprotective role of Li+ against psychotic disorders.

publication date

  • October 1, 2024

published in

Digital Object Identifier (DOI)

Medium

  • Print-Electronic

start page

  • 112762

volume

  • 262