Protein–nanoparticle hybrids represent entities characterized by emerging biological properties that can significantly differ from those of the parent components. Herein, bovine serum amine oxidase (i.e., BSAO) was immobilized onto a magnetic nanomaterial constituted of surface active maghemite nanoparticles (i.e., SAMNs, the core), surface-modified with tannic acid (i.e., TA, the shell), to produce a biologically active ternary hybrid (i.e., SAMN@TA@BSAO). In comparison with the native enzyme, the secondary structure of the immobilized BSAO responded to pH variations sensitively, resulting in a shift of its optimum activity from pH 7.2 to 5.0. Conversely, the native enzyme structure was not influenced by pH and its activity was affected at pH 5.0, i.e., in correspondence with the best performances of SAMN@TA@BSAO. Thus, an extensive NMR study was dedicated to the structure–function relationship of native BSAO, confirming that its low activity below pH 6.0 was ascribable to minimal structural modifications not detected by circular dichroism. The generation of cytotoxic products, such as aldehydes and H2O2, by the catalytic activity of SAMN@TA@BSAO on polyamine oxidation is envisaged as smart nanotherapy for tumor cells. The present study supports protein–nanoparticle conjugation as a key for the modulation of biological functions.
Natural polyamines (PAs) are key players in cellular
homeostasis
by regulating cell growth and proliferation. Several observations
highlight that PAs are also implicated in pathways regulating cell
death. Indeed, the PA accumulation cytotoxic effect, maximized with
the use of bovine serum amine oxidase (BSAO) enzyme, represents a
valuable strategy against tumor progression. In the present study,
along with the design, synthesis, and biological evaluation of a series
of new spermine (Spm) analogues (1–23), a mixed
structure-based (SB) and ligand-based (LB) protocol was applied. Binding
modes of BSAO-PA modeled complexes led to clarify electrostatic and
steric features likely affecting the BSAO-PA biochemical kinetics.
LB and SB three-dimensional quantitative structure–activity
relationship (Py-CoMFA and Py-ComBinE) models were developed by means
of the 3d-qsar.com portal,
and their analysis represents a strong basis for future design and
synthesis of PA BSAO substrates for potential application in oxidative
stress-induced chemotherapy.
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