Matrix metalloproteinase-7 (MMP-7) has emerged as a protein
playing
important roles in both physiological and pathophysiological processes.
Despite the growing interest in MMP-7 as a potential therapeutic target
for diseases including cancer and fibrosis, potent and selective MMP-7
inhibitors have yet to be identified. Compound 1, previously
reported by Edman and co-workers, binds to the S1′ subsite
of MMP-7, exhibiting moderate inhibitory activity and selectivity.
To achieve both higher inhibitory activity and selectivity, we conceived
hybridizing 1 with short peptides. The initially designed
compound 6, which was a hybrid molecule between 1 and a tripeptide (Ala-Leu-Met) derived from an MMP-2-inhibitory
peptide (APP-IP), showed enhanced MMP-7-inhibitory activity. Subsequent
optimization of the peptide moiety led to the development of compound 18 with remarkable potency for MMP-7 and selectivity over
other MMP subtypes.
Present computational lead (drug)-optimization is lacking in thermodynamic tactics. To examine whether calculation of binding free-energy change (ΔG) is effective for the lead-optimization process, binding ΔGs of 7-azaindole derivatives to the ATP binding site of glycogen synthase kinase-3β (GSK-3β) were calculated. The result was a significant correlation coefficient of r = 0.895 between calculated and observed ΔGs. This indicates that calculated ΔG reflects the inhibitory activities of 7-azaindole derivatives. In addition to quantitative estimation of activity, ΔG calculation characterizes the thermodynamic behavior of 7-azaindole derivatives, providing also useful information for inhibitor optimization on affinity to water molecules.
The human sodium-glucose co-transporter 2 (hSGLT2) is a transporter responsible for reabsorption of glucose in the proximal convoluted tubule of the kidney. hSGLT2 inhibitors, including luseogliflozin, have been developed as drugs for type 2 diabetes mellitus. Only luseogliflozin contains a thiosugar ring in its chemical structure, while other hSGLT2 inhibitors contain glucose rings. Consequently, we focused on the binding interactions of hSGLT2 with sugars and thiosugars. We first revealed that the binding affinities of thiosugars are stronger than those of sugars through molecular dynamics simulations of Vibrio parahaemolyticus, sodium-galactose co-transporter, and human hSGLT2. We then demonstrated that Na(+) dissociates from the protein to the cytoplasmic solution more slowly in the thiosugar system than in the sugar system. These differences between sugars and thiosugars are discussed on the basis of the different binding modes due to the atom at the 5-position of the sugar and thiosugar rings. Finally, as a result of Na(+) dissociation, we suggest that the dissociation of thiosugars is slower than that of sugars.
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