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Preclinical Validation of PPARg Acetylation Inhibitors for Diabetes Prevention and Treatment

$476,180R01FY2021DKNIH

University Of Oklahoma Hlth Sciences Ctr, Oklahoma City OK

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Linked publications & trials

Abstract

PROJECT SUMMARY This proposal aims to leverage basic discoveries in interdisciplinary fields to develop a novel and safer therapy for pandemic type 2 diabetes (T2D). Obesity-linked insulin resistance is the key driving force for T2D and other metabolic disorders. Despite the wide use of commonly used anti-diabetic drugs for T2D treatment, the prevalence of T2D continues to soar with an annual cost over $300 billion in the US. The transcription factor peroxisome proliferator-activated receptor ? (PPAR?) is an important therapeutic target for insulin sensitization and its full agonist TZD drugs are by far the most potent insulin-sensitizing drugs. However, TZD drugs are associated with adverse side effects including heart failure and weight gain, as TZD-induced full agonism of PPAR? activates not only the expression of genes responsible for insulin sensitizing but also of those genes associated with side effects, thereby severely hampering the clinical use of TZDs. Recent studies have indicated that PPAR? posttranslational modifications (PTMs) may lead to the selective activation of PPAR? target genes that results in the decoupling of the beneficial effects on insulin sensitizing from the TZD- related adverse effects. Our team recently discovered that deacetylation at K268 and K293 in PPAR? by the NAD+-dependent deacetylase SirT1 plays a key role in such decoupling. Excitingly, the PIs have developed a novel class of PPAR? agonist, TPMD, that bound to PPAR? to specifically inhibit PPAR? acetylation. Importantly, TPMD improved insulin sensitivity and increased white-to-brown adipocyte conversion (browning) and energy expenditure without causing TZD-associated side effects in both genetic and diary obesity mouse models. In this application, the team led by the two PIs with complementary expertise in diabetes drug discovery and PPAR? biology will use TPMD as the starting molecule to identify the first-in-class inhibitor of PPAR? acetylation that exert potent insulin-sensitizing and browning activities and better safety and pharmacokinetic (PK) properties. In Aim 1, they will employ structure-based design through iterative and parallel medicinal chemistry to identify TPMD analogs with improved potency of inhibiting PPAR? acetylation. In Aim 2, the lead analogs will be proceeded to the standardized core in vitro ADMET assays and in vivo pharmacokinetics studies to select those with the most favorable pharmacological properties. In Aim 3, the lead candidates will be tested rigorously for their in vivo efficacy and safety in obesity and genetic mouse models. The PIs will adopt their ?standardized? metabolic characterizations and assessments of TZD-associated adverse side effects. The proposed studies will produce first-in-class PPAR? acetylation inhibitors that have improved insulin-sensitizing potency, safety, and PK profiles. Thus, completion of this research will be well-poised for further clinical development to curtail the current epidemics of insulin resistance and T2D.

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