William J. Guilford

Crystallographic analysis of potent and selective factor Xa inhibitors complexed to bovine trypsin.

Factor Xa is a serine protease which activates thrombin (factor IIa) and plays a key regulatory role in the blood-coagulation cascade. Factor Xa is, therefore, an important target for the design of anti-thrombotics. Both factor Xa and thrombin share sequence and structural homology with trypsin. As part of a factor Xa inhibitor-design program, a number of factor Xa inhibitors were crystallographically studied complexed to bovine trypsin. The structures of one diaryl benzimidazole, one diaryl carbazole and three diaryloxypyridines are described. All five compounds bind to trypsin in an extended conformation, with an amidinoaryl group in the S1 pocket and a second basic/hydrophobic moiety bound in the S4 pocket. These binding modes all bear a resemblance to the reported binding mode of DX-9065a in bovine trypsin and human factor Xa.

Discovery of the Factor Xa Inhibitor, ZK 807834 (CI-1031)

Discoveries that lead to ZK 807834 (CI-1031, 2a), a potent and selective factor Xa (fXa) inhibitor currently in clinical testing as an intravenous antithrombotic, were initiated by the identification of the potent (Z,Z)-isomer of BABCH (1c). A structure-activity relationship (SAR) was established with a series of analogues of BABCH. This SAR database, combined with computer modeling, demonstrated that binding of the second basic group in the S3/S4 pocket provided fXa potency and that a carboxylic acid group on the opposite side of the molecule resulted in selectivity versus thrombin. Simple substitution of a cyclic urea for the unsaturated ketone structure of BABCH gave disappointing results, but discovery of the bisphenoxy-pyridine analogues provided a template that could be readily optimized. The SAR established for this template is described and compared with computer modeling, REDOR NMR and X-ray crystallography studies. Inhibitor binding to fXa was increased by the introduction of a hydroxyl group on the proximal phenylamidine ring and by the introduction of fluorine atoms at C-3 and C-5 of the pyridine ring. Pharmacokinetic parameters were improved by balancing the contributions from the substituents on the distal ring and the central pyridine ring. The optimal combination was a methyl-(2H)-imidazoline group on the distal ring and a sarcosine at C-4 of the pyridine ring. The promising preclinical database for CI-1031 is described. This review relates the SAR leading to the discovery of the clinical candidate, CI-1031 directly to our best understanding of how this potent inhibitor interacts with the fXa active site.

Design, synthesis, and biological activity of novel factor Xa inhibitors: 4-aryloxy substituents of 2,6-diphenoxypyridines.

A novel series of triaryloxypyridines have been designed to inhibit factor Xa, a serine protease strategically located in the coagulation cascade. Inhibitor 5e has a K(I) against factor Xa of 0.12nM and is greater than 8000- and 2000-fold selective over two related serine proteases, thrombin and trypsin, respectively. The 4-position of the central pyridine has been identified as a site that tolerates various substitutions without deleterious effects on potency and selectivity. This suggests that the 4-position of the pyridine ring is an ideal site for chemical modifications to identify inhibitors with improved pharmacokinetic characteristics. This investigation has resulted in inhibitor 5d, which has an oral availability of 6% in dogs. The synthesis, in vitro activity, and in vivo profile of this class of inhibitors is outlined.

Benzimidazole-Based fXa inhibitors with improved thrombin and trypsin selectivity

Optimization of the benzimidazole-based fXa inhibitors for selectivity versus thrombin and trypsin was achieved by substitution on the benzimidazole ring and replacement of the naphthylamidine group. Substitution of a nitro group at the 4-position on the benzimidazole improves both potency against fXa and selectivity versus thrombin. Alternatively, replacement of the naphthylamidine with either a biphenylamidine or propenylbenzamidine not only improves fXa potency and selectivity versus thrombin, but selectivity versus trypsin as well.

Design and synthesis of aminophenol-based factor Xa inhibitors

A novel potent and selective aminophenol scaffold for fXa inhibitors was developed from a previously reported benzimidazole-based naphthylamidine template. The aminophenol template is more synthetically accessible than the benzimidazole template, which simplified the introduction of carboxylic acid groups. Substitution of a propenyl-para-hydroxy-benzamidine group on the aminophenol template produced selective, sub-nanomolar fXa inhibitors. The potency of the inhibitors is partially explained with the aid of a trypsin complex crystal structure.