Abstract
The interaction behavior of Fe3+ with transferrin and apotransferrin (iron-free form) was investigated in this study using affinity capillary electrophoresis. Change in the mass and charge of protein upon binding to the metal ion in the capillary tube led to variation in its migration time and was used to measure the noncovalent binding interactions by fast screening method. Acetanilide was used as the electroosmotic flow (EOF) marker to avoid possible errors due to the change in EOF during the experiment. The binding results were calculated from the mobility ratios of protein (Ri) and EOF marker (Rf) using the formula (Ri − Rf)/Rf or ∆R/Rf. For more comprehensive understanding, the kinetics of the interaction was studied and binding constants were calculated. Results showed that the Fe3+ displayed insignificant interaction with both proteins at lower metal ion concentrations (5–25 μmol/mL). However, transferrin exhibited significant interactions with the metal ion at 50 and 100 μmol/mL (ΔR/Rf = 0.0114 and 0.0201, resp.) concentrations and apotransferrin showed strong binding interactions (ΔR/Rf = −0.0254 and 0.0205, resp.) at relatively higher Fe3+ concentrations of 100 and 250 μmol/mL. The binding constants of 18.968 mmol−1 and −13.603 mmol−1 were recorded for Fe3+ interaction with transferrin and apotransferrin, respectively, showing significant interactions. Different binding patterns of Fe3+ with both proteins might be attributed to the fact that the iron-binding sites in transferrin have already been occupied, which was not the case in apotransferrin. The present study may be used as a reference for the investigation of protein-metal ion, drug-protein, drug-metal ion, and enzyme-metal ion interactions and may be helpful to provide preliminary insight into the new metal-based drug development.
Highlights
Iron is essential for biological systems as it plays an important role as a cofactor in several important biological processes, including respiration and DNA replication
Protein adsorption on the inner surface of the capillary tube often reduces the precision of binding results
Binding of protein analyte with the inner capillary surface may lead to alteration in the electrophoretic mobility during electrophoretic run [31, 32]
Summary
Iron is essential for biological systems as it plays an important role as a cofactor in several important biological processes, including respiration and DNA replication. It is insoluble and toxic in the free iron (III) ion form. In the process of iron transportation, iron-bound transferrin (holofrom) interacts with transferrin receptors at the cell surface and gets transported to endosomes, where iron is released due to acidic pH. Iron-free transferrin (apofrom) gets back to the cell surface and dissociates from the receptor [1,2,3]. Iron (III) ion preferably binds to the hard functional groups, including aspartate, glutamate, tyrosine, and histidine amino acid residues [4]. The iron ion of low oxidation state (Fe2+) favorably interacts with moieties containing borderline acid groups such as porphyrin residue in hemoglobin. The iron ion of low oxidation state (Fe2+) favorably interacts with moieties containing borderline acid groups such as porphyrin residue in hemoglobin. e hard and soft acid and base (HSAB) principle can explain the mechanism of metal ionligand complexation reactions in a qualitative manner and provide information regarding the stability of their
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