Sirtuin modulators: targets for metabolic diseases and beyond.

Over the past ten years, sirtuins have emerged as an important class of drug targets. These enzymes play an important role in gene activation and silencing in all organisms from prokaryotes to humans. There is evidence that sirtuin modulation can be beneficial for a wide variety of diseases associated with aging. Among these conditions are diabetes, neurodegenerative diseases, and cancer. Agents that activate some sirtuins may be beneficial, while inhibitors of other sirtuins might represent treatment options. This review covers the chemical activators and inhibitors of the sirtuins that have appeared in the literature through the first half of 2008.

Prospects for pharmacologic inhibition of hepatic glucose production.

Type 2 diabetes is a widespread disease where effective pharmacologic therapies can have a profound beneficial public health impact. Increased hepatic glucose production (HGP) is observed in diabetics and its moderation by currently available agents provides therapeutic benefits. This review describes the challenges associated with the discovery of small molecules that inhibit HGP. Gluconeogenesis, glycogenolysis, liver architecture, and hepatocyte composition are described to provide background information on hepatic function. Current methods of target validation for drug discovery, HGP measurement, diabetes animal models, as well as current drug therapies are covered. In the accompanying review article the new drug targets being probed to produce the next generation of therapies are described. Significant pharmaceutical and academic efforts to pharmacologically inhibit HGP has the opportunity to provide new therapeutics for type 2 diabetics.

Potential drug targets and progress towards pharmacologic inhibition of hepatic glucose production.

A number of therapeutic targets are currently under investigation for inhibition of hepatic glucose production with small molecules. Antagonists of the glucagon receptor, glycogen phosphorylase, 11-beta-hydroxysteroid dehydrogenase-1 and fructose 1,6-bisphosphatase are, or have been, under evaluation in human clinical trials. Other strategies, including glucocorticoid receptor antagonists and carnitine palmitoyltransferase inhibitors, are supported by proof of principle studies in man as well as rodents. Several potential targets including glucose-6-phosphatase, glucose-6-phosphatase translocase, glycogen synthase kinase-3, adenosine receptor 2B antagonists, phosphoenolpyruvate carboxykinase and pyruvate dehydrogenase kinase, have been validated by compounds that are effective in animal models. Other targets like PGC-1a and CREB have initial validation support but no medicinal chemistry has been reported.

New antimitotic agents with activity in multi-drug-resistant cell lines and in vivo efficacy in murine tumor models.

During a screen for compounds that could inhibit cell proliferation, a series of new tubulin-binding compounds was identified with the discovery of oxadiazoline 1 (A-105972). This compound showed good cytotoxic activity against non-multi-drug-resistant and multi-drug-resistant cancer cell lines, but its utility in vivo was limited by a short half-life. Medicinal chemistry efforts led to the discovery of indolyloxazoline 22g (A-259745), which maintained all of the in vitro activity seen with oxadiazoline 1, but also demonstrated a better pharmacokinetic profile, and dose-dependent in vivo activity. Over a 28 day study, indolyloxazoline 22g increased the life span of tumor-implanted mice by up to a factor of 3 upon oral dosing. This compound, and others of its structural class, may prove to be useful in the development of new chemotherapeutic agents to treat human cancers.

Pyrrolidine-3-carboxylic acids as endothelin antagonists. 4. Side chain conformational restriction leads to ET(B) selectivity.

When the dialkylacetamide side chain of the ET(A)-selective antagonist ABT-627 is replaced with a 2,6-dialkylacetanilide, the resultant analogues show a complete reversal of receptor selectivity, preferring ET(B) over ET(A). By optimizing the aniline substitution pattern, as well as the alkoxy group on the 2-aryl substituent, it is possible to prepare antagonists with subnanomolar affinity for ET(B) and with selectivities in excess of 4000-fold. A number of these compounds also show promising pharmacokinetic profiles; a useful balance of properties is found in A-192621 (38). Pharmacology studies with A-192621 serve to reveal the role of the ET(B) receptor in modulating blood pressure; the observed hypertensive response to persistent ET(B) blockade is consistent with previous postulates and indicates that ET(B)-selective antagonists may not be suitable as agents for long-term systemic therapy.

The effects of diminishing albumin binding to some Endothelin receptor antagonists.

As a pharmacological class, Endothelin-A receptor (ET(A)) antagonists are highly bound (>98%) to serum albumin. In the presence of physiological concentrations of albumin, their affinities for ET(A) decrease 10 to 100 fold. We have prepared ET(A) antagonists which exhibit lower degrees of binding to albumin, while maintaining potency and selectivity for the ET(A) receptor. The protein induced IC50 shift is reduced or eliminated in this new series of compounds. The compounds also display altered in vivo and pharmacokinetic profiles which may be consistent with their lower degree of protein binding.

Pyrrolidine-3-carboxylic acids as endothelin antagonists. 3. Discovery of a potent, 2-nonaryl, highly selective ETA antagonist (A-216546).

Previously we have reported the discovery of ABT-627 (1, A-147627, active enantiomer of A-127722), a 2,4-diaryl substituted pyrrolidine-3-carboxylic acid based endothelin receptor-A antagonist. This compound binds to the ETA receptor with an affinity (Ki) of 0. 034 nM and with a 2000-fold selectivity for the ETA receptor versus the ETB receptor. We have expanded our structure-activity studies in this series, in an attempt to further increase the ETA selectivity. When the p-anisyl group of 1 was replaced by an n-pentyl group, the resultant antagonist 3 exhibited substantially increased ETB/ETA activity ratio, but a decreased ETA affinity. Structure-activity studies revealed that substitution and geometry of this alkyl group, and substitution on the benzodioxolyl ring, are important in optimizing this series of highly ETA selective antagonists. In particular, the combination of a (E)-2,2-dimethyl-3-pentenyl group and a 7-methoxy-1,3-benzodioxol-5-yl group provided hydrophobic compound 10b with subnanomolar affinity for human ETA receptor subtype and with an ETB/ETA activity ratio of over 130000. Meanwhile, synthetic efforts en route to olefinic compounds led to the discovery that 2-pyridylethyl (9o) and 2-(2-oxopyrrolidinyl)ethyl (9u) replacement of the p-anisyl group of 1yielded very hydrophilic ETA antagonists with potency and selectivity equal to those of 10b. On the basis of overall superior affinity, high selectivity for the ETA receptor (Ki, 0.46 nM for ETA and 13000 nM for ETB), and good oral bioavailability (48% in rats), A-216546 (10a) was selected as a potential clinical backup for 1.