SAR-studies of γ-secretase modulators with PPARγ-agonistic and 5-lipoxygenase-inhibitory activity for Alzheimer's disease.

We present the design, synthesis and biological evaluation of compounds containing a 2-(benzylidene)hexanoic acid scaffold as multi-target directed γ-secretase-modulators. Broad structural variations were undertaken to elucidate the structure-activity-relationships at the 5-position of the aromatic core. Compound 13 showed the most potent activity profile with IC50 values of 0.79µM (Aß42), 0.3µM (5-lipoxygenase) and an EC50 value of 4.64µM for PPARγ-activation. This derivative is the first compound exhibiting low micromolar to nanomolar activities for these three targets. Combining γ-secretase-modulation, PPARγ-agonism and inhibition of 5-lipoxygenase in one compound could be a novel disease-modifying multi-target-strategy for Alzheimer's disease to concurrently address the causative amyloid pathology and secondary pathologies like chronic brain inflammation.

Anthranilic acid derivatives as nuclear receptor modulators--development of novel PPAR selective and dual PPAR/FXR ligands.

Nuclear receptors, especially the peroxisome proliferator activated receptors (PPARs) and the farnesoid X receptor (FXR) fulfill crucial roles in metabolic balance. Their activation offers valuable therapeutic potential which has high clinical relevance with the fibrates and glitazones as PPAR agonistic drugs. With growing knowledge about the various functions of nuclear receptors in many disorders, new selective or dual ligands of these pharmaceutical targets are however still required. Here we report the class of anthranilic acid derivatives as novel selective PPAR or dual FXR/PPAR ligands. We identified distinct molecular determinants that govern selectivity for each PPAR subtype or FXR as well as the amplitude of activation of the respective receptors. We thereby discovered several lead compounds for further optimization and developed a highly potent dual PPARα/FXR partial agonist that might have a beneficial synergistic effect on lipid homeostasis by simultaneous activation of two nuclear receptors involved in lipid metabolism.

Fragmentation of GW4064 led to a highly potent partial farnesoid X receptor agonist with improved drug-like properties.

The ligand activated transcription factor farnesoid X receptor (FXR) is a crucial regulator of several metabolic and inflammatory pathways and its activation by agonistic ligands seems a valuable therapeutic approach for many disorders. Most known non-steroidal FXR agonists however, have limitations that hinder their clinical development and novel FXR ligands are required. Evaluation of the co-crystal structures of the widely used FXR agonist GW4064 and related compounds in complex with the FXR ligand binding domain indicated that their disubstituted isoxazole moiety is especially relevant for FXR activation. By investigation of GW4064-fragments missing the aromatic tail, we discovered a highly potent and soluble partial FXR agonist (14, ST-1892) as well as a fluorescent FXR ligand (15) as potential pharmacological tool.

Anthranilic acid derivatives as novel ligands for farnesoid X receptor (FXR).

Nuclear farnesoid X receptor (FXR) has important physiological roles in various metabolic pathways including bile acid, cholesterol and glucose homeostasis. The clinical use of known synthetic non-steroidal FXR ligands is restricted due to toxicity or poor bioavailability. Here we report the development, synthesis, in vitro activity and structure-activity relationship (SAR) of anthranilic acid derivatives as novel FXR ligands. Starting from a virtual screening hit we optimized the scaffold to a series of potent partial FXR agonists with appealing drug-like properties. The most potent derivative exhibited an EC50 value of 1.5±0.2 µM and 37±2% maximum relative FXR activation. We investigated its SAR regarding polar interactions with the receptor by generating derivatives and computational docking.

Nonacidic Farnesoid X Receptor Modulators.

As a cellular bile acid sensor, farnesoid X receptor (FXR) participates in regulation of bile acid, lipid and glucose homeostasis, and liver protection. Clinical results have validated FXR as therapeutic target in hepatic and metabolic diseases. To date, potent FXR agonists share a negatively ionizable function that might compromise their pharmacokinetic distribution and behavior. Here we report the development and characterization of a high-affinity FXR modulator not comprising an acidic residue.

SAR studies on FXR modulators led to the discovery of the first combined FXR antagonistic/TGR5 agonistic compound.

BACKGROUND: Bile acids can serve as signaling molecules by activating the nuclear receptor FXR and the G-protein-coupled receptor TGR5 and both bile acid receptors are prominent experimental drug targets. Results/methodology: In this study we optimized the fatty acid mimetic compound pirinixic acid to a new scaffold with the aim to develop novel FXR modulatory compounds. After a multistep structure-activity optimization process, we discovered FXR agonistic compounds and the first dual FXR antagonistic and TGR5 agonistic compound 79a. CONCLUSION: With this novel dual activity profile on both bile acid receptors 79a might be a valuable pharmalogical tool to further study the bile acid signaling network.

Identification and characterisation of a prototype for a new class of competitive PPARγ antagonists.

Understanding of the physiological role of peroxisome proliferator-activated receptor gamma (PPARγ) offers new opportunities for the treatment of cancers, immune disorders and inflammatory diseases. In contrast to PPARγ agonists, few PPARγ antagonists have been studied, though they do exert immunomodulatory effects. Currently, no therapeutically useful PPARγ antagonist is commercially available. The aim of this study was to identify and kinetically characterise a new competitive PPARγ antagonist for therapeutic use. A PPARγ-dependent transactivation assay was used to kinetically characterise (E)-2-(5-((4-methoxy-2-(trifluoromethyl)quinolin-6-yl)methoxy)-2-((4-(trifluoromethyl)benzyl)oxy)-benzylidene)-hexanoic acid (MTTB) in kidney, T and monocytic cell lines. Cytotoxic effects were analysed and intracellular accumulation of MTTB was assessed by tandem mass spectrometry (LC-MS/MS). Potential interactions of MTTB with the PPARγ protein were suggested by molecular docking analysis. In contrast to non-competitive, irreversible inhibition caused by 2-chloro-5-nitrobenzanilide (GW9662), MTTB exhibited competitive antagonism against rosiglitazone in HEK293T and Jurkat T cells, with IC50 values in HEK293T cells of 4.3µM and 1.6µM, using the PPARγ ligand binding domain (PPARγ-LBD) and the full PPARγ protein, respectively. In all cell lines used, however, MTTB showed much higher intracellular accumulation than GW9662. MTTB alone exhibited weak partial agonistic effects and low cytotoxicity. Molecular docking of MTTB with the PPARγ-LBD supported direct interaction with the nuclear receptor. MTTB is a promising prototype for a new class of competitive PPARγ antagonists. It has weak partial agonistic and clear competitive antagonistic characteristics associated with rapid cellular uptake. Compared to commercially available PPARγ modulators, this offers the possibility of dose regulation of PPARγ and immune responses.

Novel prostaglandin receptor modulators--part II: EP receptor modulators; a patent review (2002 - 2012).

INTRODUCTION: Prostaglandins and their G-protein-coupled receptors play numerous physiological and pathophysiological roles, especially in inflammation and its resolution. The variety of effects mediated by prostanoids makes prostanoid receptors valuable drug targets and the research on prostaglandin receptor modulators is intensive. The physiological and pathophysiological effects of prostaglandin E(2) are especially complex and numerous. The four subtypes of EP receptor have gained a lot of industrial and academic interest, in particular EP(2) and EP(4) for various indications. AREAS COVERED: Evaluation of the patent activity over the last decade (2002 - 2012) illustrates several potent compounds targeting the distinct prostaglandin E(2) receptors. Many novel methods for the use of EP receptor modulators have been developed, in addition to the classical indications for agents modulating the arachidonic acid cascade such as pain and inflammation. EXPERT OPINION: Several EP targeting agents with good potency and selectivity have been developed but their pharmacological use and utility has not yet been satisfactorily investigated. More research is necessary, and clinical use of these agents might therefore take some more time.

Novel prostaglandin receptor modulators: a patent review (2002 - 2012) - part I: non-EP receptor modulators.

INTRODUCTION: Prostaglandins and their G-protein coupled receptors play numerous physiological and pathophysiological roles especially in inflammation and its resolution. The variety of physiological effects mediated by prostanoids makes prostanoid receptors valuable drug targets and the research on prostaglandin receptor modulators is intensive. Prostaglandin receptor targeting drugs might be beneficial for the treatment of inflammatory, allergic, respiratory and cardiovascular disorders as well as treatment of pain but several novel fields of use such as cancer and ophthalmic diseases have also been found apart from these classical indications. AREAS COVERED: Evaluation of the patent activity over the last decade (2002 - 2012) illustrates many potent and selective modulators of the distinct prostanoid receptors and some novel methods for their use besides the classical indications. By now, some prostaglandin receptor antagonists already have reached clinical development. EXPERT OPINION: Though the structural diversity of compounds targeting prostanoid receptors is not really large, several highly potent agents with favorable properties have been developed. The clinical potential of FP, IP, TP and DP modulators remains to be investigated, while first very promising clinical results are available as far as CRTH2 is concerned.