Yong Mi Choi-Sledeski

Synthesis, SAR and in vivo activity of novel thienopyridine sulfonamide pyrrolidinones as factor Xa inhibitors

Thienopyridine sulfonamide pyrrolidinones were found to be potent and selective inhibitors of the coagulation cascade enzyme factor Xa. SAR studies led to several compounds that were selected for further in vivo investigation. These novel aryl binding pocket moieties represent a structural modification to a series of fXa inhibitors. Several compounds proved to be efficacious i.v. antithrombotic agents.

Sulfonamidopyrrolidinone factor Xa inhibitors : Potency and selectivity enhancements via P-1 and P-4 optimization

Sulfonamidopyrrolidinones were previously disclosed as a selective class of factor Xa (fXa) inhibitors, culminating in the identification of RPR120844 as a potent member with efficacy in vivo. Recognizing the usefulness of the central pyrrolidinone template for the presentation of ligands to the S-1 and S-4 subsites of fXa, studies to optimize the P-1 and P-4 groups were initiated. Sulfonamidopyrrolidinones containing 4-hydroxy- and 4-aminobenzamidines were discovered to be effective inhibitors of fXa. X-ray crystallographic experiments in trypsin and molecular modeling studies suggest that our inhibitors bind by insertion of the 4-hydroxybenzamidine moiety into the S-1 subsite of the fXa active site. Of the P-4 groups examined, the pyridylthienyl sulfonamides were found to confer excellent potency and selectivity especially in combination with 4-hydroxybenzamidine. Compound 20b (RPR130737) was shown to be a potent fXa inhibitor (K(i) = 2 nM) with selectivity against structurally related serine proteinases (>1000 times). Preliminary biological evaluation demonstrates the effectiveness of this inhibitor in common assays of thrombosis in vitro (e.g. activated partial thromboplastin time) and in vivo (e.g. rat FeCl(2)-induced carotid artery thrombosis model).

Aminoisoquinolines: design and synthesis of an orally active benzamidine isostere for the inhibition of factor XA.

The design, synthesis and SAR of sulfonamidopyrrolidinone fXa inhibitors incorporating a new benzamidine isostere, namely aminoisoquinolines, is described. These inhibitors have higher Caco-2 cell permeability than comparable benzamidines and attain higher levels of exposure upon oral dosing. The most potent member 14b (fXa Ki=6 nM) is selective against other serine proteases of interest (>600 fold).

Solid-phase parallel synthesis of azarene pyrrolidinones as factor Xa inhibitors.

A focused library (4 x 14) prepared from 4-aminopyridine and 4-, 5-, and 6-azoindole templates was synthesized using 14 polymer supported 4-amido-2,3,5,6-tetrafluorophenyl (TFP) sulfonate esters inputs. Several compounds were identified as factor Xa inhibitors (IC50< or =0.1 microM) helping to establish the SAR among these four series of azarene pyrrolidinones.

A β-tryptase inhibitor with a tropanylamide scaffold to improve in vitro stability and to lower hERG channel binding affinity.

Tropanylamide was investigated as a possible scaffold for β-tryptase inhibitors with a basic benzylamine P1 group and a substituted thiophene P4 group. Comparing to piperidinylamide, the tropanylamide scaffold is much more rigid, which presents less opportunity for the inhibitor to bind with off-target proteins, such as cytochrome P450, SSAO, and hERG potassium channel. The proposed binding mode was further confirmed by an in-house X-ray structure through co-crystallization.

Dimerization of β-tryptase inhibitors, does it work for both basic and neutral P1 groups?

The tetrameric folding of β-tryptase and the pair-wise distribution of its substrate binding sites offer a unique opportunity for development of inhibitors that span two adjacent binding sites. A series of dimeric inhibitors with two basic P1 moieties was discovered using this design strategy and exhibited tight-binder characteristics. Using the same strategy, an attempt was made to design and synthesize dimeric inhibitors with two neutral-P1 groups in hope to exploit the dimeric binding mode to achieve a starting point for further optimization. The unsuccessful attempt, however, demonstrated the important role played by Ala190 in neutral-P1 binding and casted further doubt on the possibility of developing neutral-P1 inhibitors for β-tryptase.

The Design of Competitive, Small-molecule Inhibitors of Coagulation Factor Xa

The last five years have seen an explosion of research into inhibitors of Factor Xa as potential antithrombotic agents. Aventis Pharma was a participant in this effort and its two founder companies have substantially contributed to the discovery of new inhibitors over the years. This review traces the systematic development of the former Rhone-Poulenc Rorer factor Xa program from conception to the realization of potent, orally bioavailable inhibitors with exquisite selectivity against other serine proteases. The work on beta-aminoesters described in Part 1 culminates in the development of FXV673 (Ki = 0.5 nM), an effective anticoagulant for acute indications. Part 2.2 details the de novo design of the pyrrolidinone series of inhibitors (RPR120844), within which a group of efficacious i.v. agents were identified (e.g. RPR130737, Ki = 2 nM). The first active and bioavailable benzamidine isostere i.e. the 1-aminoisoquinoline (RPR208815, Ki = 22 nM) was discovered on the pyrrolidinone scaffold (Part 2.3). Ultimately a variety of benzamidine mimics were explored and incorporated into the ketopiperazine series; the 6-substituted aminoquinazolines were found to be the most potent (Part 3). The azaindole, as represented by RPR200443 (Ki = 4 nM), stands out as imparting favorable pharmacokinetic properties to the sulfonamido-ketopiperazines.