Abstract
Alpha-fetoprotein (AFP) is a major embryo- and tumor-associated protein capable of binding and transporting a variety of hydrophobic ligands, including estrogens. AFP has been shown to inhibit estrogen receptor (ER)-positive tumor growth, which can be attributed to its estrogen-binding ability. Despite AFP having long been investigated, its three-dimensional (3D) structure has not been experimentally resolved and molecular mechanisms underlying AFP–ligand interaction remains obscure. In our study, we constructed a homology-based 3D model of human AFP (HAFP) with the purpose of molecular docking of ERα ligands, three agonists (17β-estradiol, estrone and diethylstilbestrol), and three antagonists (tamoxifen, afimoxifene and endoxifen) into the obtained structure. Based on the ligand-docked scoring functions, we identified three putative estrogen- and antiestrogen-binding sites with different ligand binding affinities. Two high-affinity binding sites were located (i) in a tunnel formed within HAFP subdomains IB and IIA and (ii) on the opposite side of the molecule in a groove originating from a cavity formed between domains I and III, while (iii) the third low-affinity binding site was found at the bottom of the cavity. Here, 100 ns molecular dynamics (MD) simulation allowed us to study their geometries and showed that HAFP–estrogen interactions were caused by van der Waals forces, while both hydrophobic and electrostatic interactions were almost equally involved in HAFP–antiestrogen binding. Molecular mechanics/Generalized Born surface area (MM/GBSA) rescoring method exploited for estimation of binding free energies (ΔGbind) showed that antiestrogens have higher affinities to HAFP as compared to estrogens. We performed in silico point substitutions of amino acid residues to confirm their roles in HAFP–ligand interactions and showed that Thr132, Leu138, His170, Phe172, Ser217, Gln221, His266, His316, Lys453, and Asp478 residues, along with two disulfide bonds (Cys224–Cys270 and Cys269–Cys277), have key roles in both HAFP–estrogen and HAFP–antiestrogen binding. Data obtained in our study contribute to understanding mechanisms underlying protein–ligand interactions and anticancer therapy strategies based on ERα-binding ligands.
Highlights
Alpha-fetoprotein (AFP) is a major mammalian embryo-specific and tumor-associated protein recognized as a “golden standard” among cancer biomarkers used in clinical practice [1]
Ramachandran maps generated by PROCHECK program verified proper stereo-chemical and conformational properties of amino acid residues in the modeled human AFP (HAFP) structure (Figure S1A)
Based on analysis of ligand-docked scoring functions followed by molecular dynamics (MD) simulation-based ∆Gbind energy calculation by mechanics/Generalized Born surface area (MM/GBSA) rescoring method, we found that the three most potent binding sites differed by their ligand binding affinities
Summary
Alpha-fetoprotein (AFP) is a major mammalian embryo-specific and tumor-associated protein recognized as a “golden standard” among cancer biomarkers used in clinical practice [1]. Biological roles of AFP during embryonic development and tumor growth have long been investigated; they are still not fully understood [5]. Experimental data evidence capability of both native and recombinant AFP to regulate cell proliferation and immune response [6,7,8], as well as to bind and transport a variety of hydrophobic ligands, such as estrogens, fatty acids, and drugs, suggesting that these functions have a role during embryo- and carcinogenesis [9,10,11]. AFP has been reported to inhibit estrogen receptor (ER)-positive human MCF-7 and MTW9A rat mammary cancer growth, which is associated with the interaction between AFP and 17β-estradiol [12,13]. High HAFP concentrations in the maternal blood serum during second and third trimesters of pregnancy correlate with reduced ER-positive breast cancer risk [15]
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