Aptamers are valuable for the discovery and application of new principals and designs of nucleic acid-ligand interactions. This study investigated the thermodynamics and conformational changes associated with the binding between streptavidin (SA) and its DNA aptamer under various temperatures and salt concentrations. The binding was enthalpy-driven with a large entropy cost. The binding association constant (Ka) was independent of the salt concentrations; however, enthalpy increased in conjunction with the salt concentration. The spectroscopic studies indicated that each SA tetramer bound a maximum of 2 aptamer molecules. The binding was accompanied with substantial conformational changes, which were insensitive to the variation of salt concentrations. These non-classical results indicate the prominent involvement of the binding-site hydration water molecules in SA-aptamer binding. We propose a salt-bridge swap model to explain the salt-independent Kd values. To maximize binding affinity, the electrostatic interactions within the proteins and those within the aptamer-Na+ counter ions exchange their partners, resulting in the observed structural changes and the possible release of hydration water molecules.