Abstract
Cysteine residues play a crucial role in maintaining the structural and functional integrity of proteins, but they are highly susceptible to oxidative modifications. These modifications can contribute to disorders such as Alzheimer's disease (AD). In tau protein, the SKCGS sequence, especially the cysteine residue at position C-322, is particularly vulnerable to oxidative stress (OS). This vulnerability promotes tau fibrillation and aggregation, both in vitro and in vivo. This study evaluated the antioxidative effects of cinnamaldehyde (Cin), phenylethyl alcohol (PEA), and the common crude spices (cinnamon, rose, saffron, and cardamom) on the SKCGS peptide of the tau protein (in solution and aroma forms), with a focus on their ability to prevent oxidative damage. We adopted a novel approach using aromatherapy that utilizes the aromatic and volatile properties of natural compounds. By combining biochemical assessments with molecular docking studies, we aimed to provide a comprehensive understanding of the protective mechanisms of the natural phytoaromatic compounds used in this study. The antioxidative potential of these compounds was assessed using the DPPH assay; thiol levels measured via DTNB and mBBr assays; and binding interactions evaluated through molecular docking. The DPPH assay confirmed the antioxidative activity of all tested compounds. DTNB and mBBr assays showed that the phytoaromatic compounds significantly preserved free thiol content in the SKCGS peptide under oxidative conditions (p < 0.05). Molecular docking predicted favorable binding interactions between the phytoaromatic compounds and the cysteine residue in the SKCGS sequence, suggesting a protective mechanism against OS. The data presented provided strong evidence supporting the idea that phytoaromatic compounds could be promising candidates for developing innovative treatment approaches for AD. The encouraging results from this study justify further exploration of phytoaromatic compounds as therapeutic agents for AD. This research opens up new avenues for creating effective treatments to address one of the most significant challenges in neurodegenerative medicine.