Hoogsteen (HG) and Watson-Crick (WC) adenine–thymine (A-T) base pairs are fundamental to gene expression and genomic stability. Our research applied density functional theory (DFT) calculations to analyze these base pairs, demonstrating that linking them with ribose or deoxyribose and their immersion in solvents markedly enhances the distinctions in their optical properties. DFT results reveal that N···HN hydrogen bonds in both HG and WC pairs exhibit characteristics of both ionic and covalent bonds, playing a crucial role in their stability. While WC base pairs demonstrate stronger orbital interactions, they also experience greater repulsion than HG pairs. This repulsion offsets the positive interactions to a degree, making the interaction energy of WC pairs slightly lower than that of HG pairs. Furthermore, the distinct conformations of these base pairs result in different vibrational modes, suggesting Raman spectroscopy as an effective method for distinguishing between WC and HG base pairs.