Benzofused hydroxamic acids: useful fragments for the preparation of histone deacetylase inhibitors. Part 2: 7-fluorobenzothiophenes and benzofurans.

In the search for a new class of histone deacetylase inhibitors, we prepared a series of very simple benzofused hydroxamic acids to find an anchoring fragment of minimal molecular weight: they showed very good ligand efficiencies. Following these findings, classical fragment growing work was performed to increase binding energy and selective cytotoxicity. In the second phase of the work, information from the SARs of the benzothiophene series and data available in literature, we explored the in vitro pharmacological properties of the 6-substituted-7-fluoro-benzothiophene hydroxamates and the 5-susbtituted-benzofuran hydroxamates.

Benzofused hydroxamic acids: useful fragments for the preparation of histone deacetylase inhibitors. Part 1: hit identification.

In the search for a new class of histone deacetylase inhibitors, we prepared a series of simple benzofused hydroxamic acids to find an anchoring fragment of minimal molecular weight. These initial hits, all belonging to the benzothiophene class, showed very good ligand efficiencies. Following these findings, a classical fragment growing approach was performed to increase binding affinity and cytotoxicity.

Set-up of a new series of HDAC inhibitors: the 5,11-dihydrodibenzo[b,e]azepin-6-ones as privileged structures.

We report here the strategy used in our research group to find a new class of histone deacetylase (HDAC) inhibitors. A series of 5,11-dihydrodibenzo[b,e]azepine-6-ones alkylated on the amide nitrogen with an alkyl chain bearing an hydroxamic acids moiety at the end, has been designed (based upon the general motif for HDAC inhibitors), synthesized and tested. This allowed us to identify a new series of submicromolar HDAC inhibitors, which showed antiproliferative activity on HCT-116 colon carcinoma cells.

4-N-Hydroxy-4-[1-(sulfonyl)piperidin-4-yl]-butyramides as HDAC inhibitors.

A series of N-substituted 4-alkylpiperidine hydroxamic acids, corresponding to the basic structure of histone deacetylase (HDAC) inhibitors (zinc binding moiety-linker-capping group) has been previously reported by our group. Linker length and aromatic capping group connection were systematically varied to find the optimal geometric parameters. A new series of submicromolar inhibitors was thus identified, which showed antiproliferative activity on HCT-116 colon carcinoma cells. We report here the second part of the strategy used in our research group to find a new class of HDAC inhibitors, namely the SAR study for the compounds bearing a sulfonyl group on the piperidine nitrogen. In the present work, we have considered both sulfonamides and sulfonyl ureas.

Alkyl piperidine and piperazine hydroxamic acids as HDAC inhibitors.

We report here the strategy used in our research group to find a new class of histone deacetylase (HDAC) inhibitors. A series of N-substituted 4-alkylpiperazine and 4-alkylpiperidine hydroxamic acids, corresponding to the basic structure of HDAC inhibitors (zinc binding moiety-linker-capping group) has been designed, prepared, and tested for HDAC inhibition. Linker length and aromatic capping group connection were systematically varied to find the optimal geometric parameters. A new series of submicromolar inhibitors was thus identified, which showed antiproliferative activity on HCT-116 colon carcinoma cells.

hNK2 receptor antagonists. The use of intramolecular hydrogen bonding to increase solubility and membrane permeability.

Starting from in-house capped tripeptide libraries, we have developed two series of compounds as potent antagonists of the hNK(2) receptor with a reduced peptide character. These two series maintained a crucial amide bond, which could not be methylated or substituted with classical isostere without a dramatic loss in binding affinity, very likely due conformational changes. We report here the planning, synthesis and evaluation of molecules belonging to the selected chemical series, which contain a strategically placed hydrogen bond acceptor. The aim of the work was to improve membrane permeability via the formation of an intramolecular hydrogen bonding, and at the same time to maintain the structural characteristics geometry and polarity of the amide linkage so as to retain a relevant binding affinity for the biological target.

Structure-activity relationships of 6-methyl-benzo[b]thiophene-2-carboxylic acid (1-[(S)-1-benzyl-4-[4-(tetrahydropyran-4-ylmethyl)piperazin-1-yl]butylcarbamoyl]cyclopentyl)amide, potent antagonist of the neurokinin-2 receptor.

As part of a project aimed at the identification of a series of small, orally available antagonists for the hNK(2) receptor, starting from one of our capped dipeptide libraries, we succeeded in the chemical optimization of the first identified leads, finally producing a class of molecules with significant activity in our animal model after iv administration. We herein report the results of further chemical modifications made to reduce the overall peptide character of this series and the consequent improvement of their in vivo antagonist activity. The present work identified 6-methylbenzo[b]thiophene-2-carboxylic acid (1-[(S)-1-benzyl-4-[4-(tetrahydropyran-4-ylmethyl)piperazin-1-yl]butylcarbamoyl]cyclopentyl)amide (10i), endowed with subnanomolar potency in all the in vitro tests and being highly potent and of long duration upon in vivo testing after both iv and id dosing.

Bradykinin receptor antagonists--a review of the patent literature 2005-2008.

BACKGROUND: For > 20 years, pharmaceutical companies and academic centers have been developing bradykinin antagonists. The patent literature on these molecules (up to and including 2004) has been analyzed previously in this journal in two review articles. OBJECTIVE: The aim of this review is to provide an update (from 2005 to early 2009) on the patenting activity in the field of bradykinin antagonists (including patents on their formulation). Where possible, the information from the patents has been supplemented with that from the primary literature, clinical trial databases and company websites in an attempt to give a more complete picture. CONCLUSIONS: In the past 4 years, nearly 50 new patents have been filed on bradykinin antagonists--in the case of several filings, only the original source has been considered in this analysis--the vast majority of these (> 93%) on B1 antagonists. However, despite this large amount of work, only one compound, icatibant--a hydrophilic decapeptide selective for the B2 receptor--has reached the market, although it needs to be administered parenterally.

Fragment-based approach to drug lead discovery: overview and advances in various techniques.

In the last 20 years the advent of new technologies, such as high-throughput screening (HTS) and combinatorial chemistry, has produced new tools for the discovery of biologically active molecules. In the past decade, fragment-based drug discovery has emerged as a more rational and focused approach that concentrates on the quality, rather than the quantity, of hits and leads. The principles behind this strategy are different from those that represented the basis of conventional HTS. The starting point of this approach is always a small chemical entity (typically MW 150-200), a fragment, with low affinity for the selected target. Fragments should satisfy key features such as diversity, reduced structural complexity, aqueous solubility and availability. Because of their small size, they occupy a smaller region of chemical space if compared with classical HTS compounds; hence, fragment libraries provide a good diversity with a relatively low number of compounds. Classical biochemical assays are often not suitable to detect the low binding affinities involved, so some well known biophysical techniques, such as nuclear magnetic resonance and x-ray, have been opportunely modified in order to render them able to perform the task. When selecting fragments suitable for subsequent optimization, a useful parameter has been introduced, the ligand efficiency, which is defined as the free energy of binding divided by the non-hydrogen atom count. Once selected, a fragment must undergo a heavy elaboration to improve binding affinity, at the same time acquiring drug-like properties. There are two main ways to go on at this point. The most common one is the so-called 'fragment evolution', consisting of a stepwise and systematic addition of chemical functionalities to the starting fragment core, together with a continuous feedback for pharmacological and physicochemical properties. The second one, less common but with great potential, is 'fragment linking': when two or more fragment hits are found to bind in adjacent regions of the target protein, they can be linked through appropriate spacers to rapidly produce a single molecule with much higher binding affinity. Two representative case histories are described: Abbott's ABT 518, an MMP (matrix metalloproteinase) inhibitor, and Eli-Lilly's LY-517717, an inhibitor of factor Xa serine protease. In addition, a list of molecules claimed to be derived from fragment approach and currently undergoing clinical trials is presented.

Cinnamic acids and mono-substituted benzoic acids as useful capping groups for the preparation of hNK2 receptor antagonists.

NK(2) antagonists have been reported to be potentially useful for the treatment of a number of chronic diseases, such as asthma, irritable bowel syndrome, cystitis, and depression. Starting from an in-house prepared library of capped dipeptides, we have identified a series of molecules with subnanomolar binding affinity for the hNK(2) receptor. These molecules are composed by three well-defined regions: a planar aromatic acyl system as N-terminal capping group, a rigid and quite lipophilic core, and a flexible and relatively hydrophilic C-terminal capping group. Here we report how we were able to manipulate the N-terminal capping group to obtain significant in vivo activity after i.v. and i.d. administration.

alpha,alpha-Cyclopentaneglycine dipeptides capped with biaryls as tachykinin NK(2) receptor antagonists.

The NK(2) receptor belongs to the family of tachykinin neurotransmitters. It has been reported to be involved in several pathological conditions, and selective antagonists are potentially useful drugs for the treatment of asthma, irritable bowel syndrome, cystitis, and depression. Starting from in-house capped dipeptide libraries, we were able to identify a number of molecules with sub-nanomolar binding affinity for the hNK(2) receptor. All were characterized by a rigid core structure with a strong constraint induced by an alpha,alpha-cyclopentaneglycine fragment. Herein we report the further elaboration of three initial basic structures. The planar benzothiophene group was substituted with a series of biphenyl and heterobiphenyl moieties that are well tolerated in terms of receptor affinity. The new compounds also maintained good antagonist potency in an in vitro functional assay, and a number of them showed significant in vivo activity after intravenous administration in our guinea pig model.

Fragment-based drug design: combining philosophy with technology.

Fragment-based drug design began more than ten years ago and has been steadily gaining in popularity. This review discusses how fragments have been used to choose druggable targets, and what parameters need to be evaluated if a fragment hit is to be considered a suitable ligand for development. Examples of fragment-based screening from the recent literature are reviewed to highlight the various approaches used, along with the possible application of additional techniques to fragment screening against immobilized targets. Finally, mention is made of two different areas, multi-target drug discovery and selective tumor cell targeting, where fragment-based approaches may play an important role in the future.

alpha,alpha-Cyclic aminoacids as useful scaffolds for the preparation of hNK(2) receptor antagonists.

MEN 15596 is a small molecule, potent and selective antagonist of NK(2) receptor, possessing high affinity and potency at the guinea-pig and human receptors whose pharmacological characterization has been recently published. Here we report how the corresponding class of compounds was derived from a tri-peptide library and the first optimization round to improve both in vitro activity and physicochemical properties.

Design and synthesis of novel sulfonamide-containing bradykinin hB2 receptor antagonists. 2. Synthesis and structure-activity relationships of alpha,alpha-cycloalkylglycine sulfonamides.

Recently we reported on the design and synthesis of a novel class of selective nonpeptide bradykinin (BK) B2 receptor antagonists (J. Med. Chem. 2006, 3602-3613). This work led to the discovery of MEN 15442, an antagonist with subnanomolar affinity for the human B2 receptor (hB2R), which also displayed significant and prolonged activity in vivo (for up to 210 min) against BK-induced bronchoconstriction in the guinea-pig at a dose of 300 nmol/kg (it), while demonstrating only a slight effect on BK-induced hypotension. Here we describe the further optimization of this series of compounds aimed at maximizing the effect on bronchoconstriction and minimizing the effect on hypotension, with a view to developing topically delivered drugs for airway diseases. The work led to the discovery of MEN 16132, a compound which, after intratracheal or aerosol administration, inhibited, in a dose-dependent manner, BK-induced bronchoconstricton in the airways, while showing minimal systemic activity. This compound was selected as a preclinical candidate for the topical treatment of airway diseases involving kinin B2 receptor stimulation.

A structure-guided approach to an orthogonal estrogen-receptor-based gene switch activated by ligands suitable for in vivo studies.

A strategy to obtain a fully orthogonal estrogen-receptor-based gene switch responsive to molecules with acceptable pharmacological properties is presented. From a series of tetrahydrofluorenones active on the wild-type estrogen receptor (ER) an inactive analogue is chosen as a new lead compound. Coevolution of receptor mutants and ligands leads to an ER-based gene switch suitable for studies in animal models.

Design and synthesis of novel sulfonamide-containing bradykinin hB2 receptor antagonists. 1. Synthesis and SAR of alpha,alpha-dimethylglycine sulfonamides.

We recently published the extensive in vivo pharmacological characterization of MEN 16132 (J. Pharmacol. Exp. Ther. 2005, 616-623; Eur. J. Pharmacol. 2005, 528, 7), a member of the sulfonamide-containing human B(2) receptor (hB(2)R) antagonists. Here we report, in detail, how this family of compounds was designed, synthesized, and optimized to provide a group of products with subnanomolar affinity for the hB(2)R and high in vivo potency after topical administration to the respiratory tract. The series was designed on the basis of indications from the X-ray structures of the key structural motifs A and B present in known antagonists and is characterized by the presence of an alpha,alpha-dialkyl amino acid. The first lead (17) of the series was submitted to extensive chemical work to elucidate the structural requirements to increase hB(2) receptor affinity and antagonist potency in bioassays expressing the human B(2) receptor (hB(2)R). The following structural features were selected: a 2,4-dimethylquinoline moiety and a piperazine linker acylated with a basic amino acid. The representative lead compound 68 inhibited the specific binding of [(3)H]BK to hB(2)R with a pKi of 9.4 and antagonized the BK-induced inositolphosphate (IP) accumulation in recombinant cell systems expressing the hB(2)R with a pA(2) of 9.1. Moreover, compound 68 when administered (300 nmol/kg) intratracheally in the anesthetized guinea pig, was able to significantly inhibit BK-induced bronchoconstriction for up to 120 min after its administration, while having a lower and shorter lasting effect on hypotension.

A functionally orthogonal estrogen receptor-based transcription switch specifically induced by a nonsteroid synthetic ligand.

It is highly desirable to design ligand-dependent transcription regulation systems based on transactivators unresponsive to endogenous ligands but induced by synthetic small molecules unable to activate endogenous receptors. Using molecular modeling and yeast selection, we identified an estrogen receptor ligand binding domain double mutant (L384M, M421G) with decreased affinity to estradiol and enhanced binding to compounds inactive on estrogen receptors. Nonresponsiveness to estrogen was achieved by additionally adding the G521R substitution while introducing an "antagonistic-type" side chain in the compound, as in 4-hydroxytamoxifen. The triple-substituted ligand binding domain is insensitive to physiological concentrations of estradiol and has nanomolar affinity for the ligand. In this binary system, both receptor and ligand are, therefore, reciprocally specific. The mutated variant in the context of a chimeric transcription factor provides tight, ligand-dependent regulation of reporter gene expression.

Generation of a new class of hNK(2) receptor ligands using the 'fragment approach'.

The so called 'fragment approach' was applied in the search for new leads as selective hNK(2) antagonists. A first round of structural space exploration through the use of bond rigidity as scaffold to support the fragments, afforded 27a as 200 nM hNK(2) ligand. Further refinement gave MEN 14933 as a 16 nM hNK(2) ligand, selective versus hNK(1), of a novel class. Conformational analysis was used to study results and plan future work.

Small molecule antagonists of the tachykinin NK 2 receptor.

The NK(2) receptor (member of the tachykinin receptor family) is mainly located in the smooth muscle of the urinary, respiratory and gastrointestinal tracts, with limited presence in the CNS. This has raised interest in tachykinin NK(2) receptor antagonists for the treatment of urological disorders, asthma. This review outlines progress done after 1998 in the field of NK(2) small molecule antagonists, both acting on the NK(1)/NK(2), NK(2)/NK(3), NK(1)/NK(2)/NK(3) receptors and selective for the NK(2) one.