Copper-flavonoid family of complexes involved in alkaline phosphatase activation

GADDI, GISELA M.; CARO-RAMÍREZ, JANETSI Y.; PARENTE, JULIANA E.; WILLIAMS, PATRICIA A. M.; FERRER, EVELINA G.

BIOMETALS

SPRINGER

Año: 2023

0966-0844

The flavonoid naringenin and a family of naringenin derivative Cu(II) complexes having phenanthroline-based second ligands were selected to study alkaline phosphatase activation. This enzyme plays a critical role in tissue formation, increasing the inorganic phosphate formation, favoring mineralization, and being essential to producing bone mineralization. The effects of those compounds on the function and structure of the enzyme were evaluated by kinetic measurements, fluorescence, FTIR, and UV-Vis spectroscopies. The results showed that naringenin did not affect alkaline phosphatase activity, having a value of the Michaelis–Menten-constant close to the enzyme (Km = 3.07 × 10–6). The binary complex, Cu(II)-naringenin, and the ternary complexCu(II)-naringenin-phenanthroline behaved as an enzyme activator in all the concentrations rangeused in this study. Those complexes increased in c.a. 1.9% the catalytic efficiency concerning enzyme and naringenin. The ternary complex Cu(II)-naringenin bathophenanthroline, provokes an activator mixed effect, dependent on the substrate concentrations. The different kinetic behavior can be correlated with different conformational changes observed under the interaction with ALP. Fluorescence experiments showed a raising of the binding constant with temperature. FTIR determinations showed that the complex with bathophenanthroline modifies the ALP structurebut maintains the helical structure. The other copper complexes provoked a structural unfolding,decreasing the α-helix content. None of them affect the dephosphorylation enzyme ability. Even though the interactions and structural modifications on ALP are different, it is evident that the presence of copper favors enzymatic activity. The observed electrostatic interactions probably benefit the dissociation of the bound phosphate. The results suggest potential biological applications for the studied compounds.