posted on 2024-10-04, 11:35authored byBen Iddon, Christopher A. Hunter
Salt bridges formed by amidines and carboxylic acids
represent
an important class of noncovalent interaction in biomolecular and
supramolecular systems. Isothermal titration calorimetry was used
to study the relationships between the strength of the interaction,
the chemical structures of the components, and the nature of the solvent.
The stability of the 1:1 complex formed in chloroform changed by 2
orders of magnitude depending on the basicity of the amidine and the
acidity of the acid, which is consistent with proton transfer in the
complex. Polar solvents reduce the stabilities of salt bridges formed
with N,N’-dialkylamidines by up to 3 orders
of magnitude, but this dependence on solvent polarity can be eliminated
if the alkyl groups are replaced by protons in the parent amidine.
The enhanced stability of the complex formed by benzamidine is due
to solvation of the NH sites not directly involved in salt bridge
formation, which become significantly more polar when proton transfer
takes place, leading to more favorable interactions with polar solvents
in the bound state. Calculation of H-bond parameters using density
functional theory was used to predict solvent effects on the stabilities
of salt bridges to within 1 kJ mol–1. While H-bonding
interactions are strong in nonpolar solvents, and solvophobic interactions
are strong in polar protic solvents, these interactions are weak in
polar aprotic solvents. In contrast, amidinium–carboxylate
salt bridges are stable in both polar and nonpolar aprotic solvents,
which is attractive for the design of supramolecular systems that
operate in different solvent environments.