The clinical syndromes of thromboembolism are evoked by an excessive stimulation of the
coagulation cascade. In this context, the serine protease thrombin plays a key role. Considerable
efforts have therefore been devoted to the discovery of safe, orally active inhibitors of this
enzyme. On the basis of the X-ray crystal structure of the peptidelike thrombin inhibitor NAPAP
complexed with bovine thrombin, we have designed a new structural class of nonpeptidic
inhibitors employing a 1,2,5-trisubstituted benzimidazole as the central scaffold. Supported
by a series of X-ray structure analyses, we optimized the activity of these compounds. Thrombin
inhibition in the lower nanomolar range could be achieved although the binding energy mainly
results from nonpolar, hydrophobic interactions. To improve in vivo potency, we increased the
overall hydrophilicity of the molecules by introducing carboxylate groups. The very polar
compound 24 (BIBR 953) exhibited the most favorable activity profile in vivo. This zwitterionic
molecule was converted into the double-prodrug 31 (BIBR 1048), which showed strong oral
activity in different animal species. On the basis of these results, 31 was chosen for clinical
development.
Telomerase, the ribonucleoprotein enzyme maintaining the telomeres of eukaryotic chromosomes, is active in most human cancers and in germline cells but, with few exceptions, not in normal human somatic tissues. Telomere maintenance is essential to the replicative potential of malignant cells and the inhibition of telomerase can lead to telomere shortening and cessation of unrestrained proliferation. We describe novel chemical compounds which selectively inhibit telomerase in vitro and in vivo. Treatment of cancer cells with these inhibitors leads to progressive telomere shortening, with no acute cytotoxicity, but a proliferation arrest after a characteristic lag period with hallmarks of senescence, including morphological, mitotic and chromosomal aberrations and altered patterns of gene expression. Telomerase inhibition and telomere shortening also result in a marked reduction of the tumorigenic potential of drug-treated tumour cells in a mouse xenograft model. This model was also used to demonstrate in vivo efficacy with no adverse side effects and uncomplicated oral administration of the inhibitor. These findings indicate that potent and selective, non-nucleosidic telomerase inhibitors can be designed as novel cancer treatment modalities.
Telomerase, a ribonucleoprotein acting as a reverse transcriptase, has been identified as a target for cancer drug discovery. The synthetic, non-nucleosidic compound, BIBR1532, is a potent and selective telomerase inhibitor capable of inducing senescence in human cancer cells (1). In the present study, the mode of drug action was characterized. BIBR1532 inhibits the native and recombinant human telomerase, comprising the human telomerase reverse transcriptase and human telomerase RNA components, with similar potency primarily by interfering with the processivity of the enzyme. Enzyme-kinetic experiments show that BIBR1532 is a mixed-type non-competitive inhibitor and suggest a drug binding site distinct from the sites for deoxyribonucleotides and the DNA primer, respectively. Thus, BIBR1532 defines a novel class of telomerase inhibitor with mechanistic similarities to non-nucleosidic inhibitors of HIV1 reverse transcriptase.
The structural data reveal the molecular basis for a desired unselective inhibition of the two key components of the blood coagulation cascade. The 4-(1-methyl-benzimidazole-2-yl)-methylamino-benzamidine moieties of the inhibitors are able to fill both the small solvent accessible as well as the larger hydrophobic S2 pockets of factor Xa and thrombin, respectively. Distal fragments of the inhibitors are identified which fit into both the cation hole/aromatic box of factor Xa and the hydrophobic aryl binding site of thrombin. Thus, binding constants in the medium-to-low nanomolar range are obtained against both enzymes.
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