Correlating structure and ligand affinity in drug discovery: a cautionary tale involving second shell residues.

A high-resolution crystallographic structure determination of a protein-ligand complex is generally accepted as the 'gold standard' for structure-based drug design, yet the relationship between structure and affinity is neither obvious nor straightforward. Here we analyze the interactions of a series of serine proteinase inhibitors with trypsin variants onto which the ligand-binding site of factor Xa has been grafted. Despite conservative mutations of only two residues not immediately in contact with ligands (second shell residues), significant differences in the affinity profiles of the variants are observed.

Use of IHC and newly designed matriptase inhibitors to elucidate the role of matriptase in pancreatic ductal adenocarcinoma.

Matriptase, also known as MT-SP1, is a type II transmembrane serine protease strongly implicated in both the development and progression of a variety of epithelial cancers. Evidence comes from studies of its expression in human cancers and from mouse models of spontaneous cancer. Matriptase is considered to be a major activator of two key stimulators of invasive growth, namely hepatocyte growth factor/scatter factor and urokinase-type plasminogen activator.

Incorporation of neutral C-terminal residues in 3-amidinophenylalanine-derived matriptase inhibitors.

A novel series of matriptase inhibitors based on previously identified tribasic 3-amidinophenylalanine derivatives was prepared. The C-terminal basic group was replaced by neutral residues to reduce the hydrophilicity of the inhibitors. The most potent compound 22 inhibits matriptase with a K(i) value of 0.

Modification of the N-terminal sulfonyl residue in 3-amidinophenylalanine-based matriptase inhibitors.

Replacement of the N-terminal beta-alanyl-amide moiety in previously identified matriptase inhibitors by non-charged aryl groups caused a slightly decreased potency and partially reduced selectivity, especially towards thrombin. However, some of these analogues are still potent matriptase inhibitors with K(i)-values <10nM. In contrast, improved activity was observed for newly designed tribasic analogues, especially for compound 21, which inhibits matriptase with an K(i)-value of 80pM.

Highly potent and selective substrate analogue factor Xa inhibitors containing D-homophenylalanine analogues as P3 residue: part 2.

A series of highly potent substrate-analogue factor Xa inhibitors containing D-homophenylalanine analogues as the P3 residue has been identified by systematic optimization of a previously described inhibitor structure. An initial lead, benzylsulfonyl-D-hPhe-Gly-4-amidinobenzylamide (3), inhibits fXa with an inhibition constant of 6.0 nM.