Project description:Faced by an alarming incidence of metabolic diseases including obesity and type 2 diabetes worldwide, there is an urgent need for effective strategies for preventing and treating these common diseases. The nuclear receptor PPARγ (peroxisome proliferator-activated receptor gamma) plays a crucial role in metabolism. We isolated the amorfrutins from edible parts of the plants Glychyrrhiza foetida and Amorpha fruticosa, and identified these natural products as a new chemical class to treat insulin resistance and diabetes by selectively activating PPARγ. In contrast to existing synthetic PPARγ drugs, the amorfrutins display unique properties by separating insulin sensitization from unwanted side effects. In obese mouse models, amorfrutin treatment significantly improved important metabolic and inflammatory parameters. In summary, PPARγ activation by selective amorfrutins derived from edible biomaterial is a promising approach to combat metabolic diseases and other diseases in which PPARγ is involved in.

Project description:The nociceptin/orphanin FQ (N/OFQ)/N/OFQ receptor (NOP) system controls different biological functions including pain and cough reflex. Mixed NOP/opioid receptor agonists elicit similar effects to strong opioids but with reduced side effects. In this work, 31 peptides with the general sequence [Tyr/Dmt1,Xaa5]N/OFQ(1-13)-NH2 were synthesized and pharmacologically characterized for their action at human recombinant NOP/opioid receptors. The best results in terms of NOP versus mu opioid receptor potency were obtained by substituting both Tyr1 and Thr5 at the N-terminal portion of N/OFQ(1-13)-NH2 with the noncanonical amino acid Dmt. [Dmt1,5]N/OFQ(1-13)-NH2 has been identified as the most potent dual NOP/mu receptor peptide agonist so far described. Experimental data have been complemented by in silico studies to shed light on the molecular mechanisms by which the peptide binds the active form of the mu receptor. Finally, the compound exerted antitussive effects in an in vivo model of cough.

Project description:Peroxisome proliferator-activated receptor γ (PPARγ) has received significant attention as a key regulator of glucose and lipid homeostasis. In this study, we synthesized and tested a library of novel 5-benzylidene-thiazolidin-2,4-dione (BTZD) derivatives bearing a substituent on nitrogen of TZD nucleus (compounds 1a-1k, 2i-10i, 3a, 6a, and 8a-10a). Three compounds (1a, 1i, and 3a) exhibited selectivity towards PPARγ and were found to be weak to moderate partial agonists. Surface Plasmon Resonance (SPR) results demonstrated binding affinity of 1a, 1i and 3a towards PPARγ. Furthermore, docking experiments revealed that BTZDs interact with PPARγ through a distinct binding mode, forming primarily hydrophobic contacts with the ligand-binding pocket (LBD) without direct H-bonding interactions to key residues in H12 that are characteristic of full agonists. In addition, 1a, 1i and 3a significantly improved hyperglycemia and hyperlipidaemia in streptozotocin-nicotinamide (STZ-NA)-induced diabetic rats at a dose of 36 mg/kg/day administered orally for 15 days. Histopathological investigations revealed that microscopic architecture of pancreatic and hepatic cells improved in BTZDs-treated diabetic rats. These findings suggested that 1a, 1i and 3a are very promising pharmacological agents by selectively targeting PPARγ for further development in the clinical treatment of type 2 diabetes mellitus.

Project description:From an epidemiological and pathophysiological point of view, Alzheimer's disease (AD) and type 2 diabetes (T2DM) should be considered 'sister' diseases. T2DM significantly increases the risk of developing AD, and the mechanisms of neuronal degeneration themselves worsen peripheral glucose metabolism in multiple ways. The pathophysiological links between the two diseases, particularly cerebral insulin resistance, which causes neuronal degeneration, are so close that AD is sometimes referred to as 'type 3 diabetes'. Although the latest news on the therapeutic front for AD is encouraging, no treatment has been shown to halt disease progression permanently. At best, the treatments slow down the progression; at worst, they are inactive, or cause worrying side effects, preventing their use on a larger scale. Therefore, it appears logical that optimizing the metabolic milieu through preventive or curative measures can also slow down the cerebral degeneration that characterizes AD. Among the different classes of hypoglycaemic drugs, glucagon-like peptide 1 receptor agonists, which are widely used in the treatment of T2DM, were shown to slow down, or even prevent, neuronal degeneration. Data from animal, preclinical, clinical phase II, cohort and large cardiovascular outcomes studies are encouraging. Of course, randomized clinical phase III studies, which are on-going, will be essential to verify this hypothesis. Thus, for once, there is hope for slowing down the neurodegenerative processes associated with diabetes, and that hope is the focus of this review.

Project description:Faced by an alarming incidence of metabolic diseases including obesity and type 2 diabetes worldwide, there is an urgent need for effective strategies for preventing and treating these common diseases. The nuclear receptor PPARM-NM-3 (peroxisome proliferator-activated receptor gamma) plays a crucial role in metabolism. We isolated the amorfrutins from edible parts of the plants Glychyrrhiza foetida and Amorpha fruticosa, and identified these natural products as a new chemical class to treat insulin resistance and diabetes by selectively activating PPARM-NM-3. In contrast to existing synthetic PPARM-NM-3 drugs, the amorfrutins display unique properties by separating insulin sensitization from unwanted side effects. In obese mouse models, amorfrutin treatment significantly improved important metabolic and inflammatory parameters. In summary, PPARM-NM-3 activation by selective amorfrutins derived from edible biomaterial is a promising approach to combat metabolic diseases and other diseases in which PPARM-NM-3 is involved in. GSM701612-GSM701623: Male DIO C57BL/6 mice (age 18 wks), 3 groups (n=4 each after pooling of 8 samples per group). Mice were fed over 3 wks with high fat diet (HFD) without compound (vehicle), HFD with 4 mg/kg/d rosiglitazone or with 100 mg/kg/d amorfrutin 1. Liver RNA extracted. --> 4 biological replicates, vehicle vs. rosiglitazone or amorfrutin 1 GSM702299-GSM702344: Biological replicates (n = 3-4 each) of human primary adipocytes were treated with the following compounds for 24 hours. 10M-BM-5M rosiglitazone, 10M-BM-5M pioglitazone, 30M-BM-5M telmisartan, 10M-BM-5M nTZDpa, 30M-BM-5M amorfrutin 1, 30M-BM-5M amorfrutin 2, 30M-BM-5M amorfrutin 3 or 30M-BM-5M amorfrutin 4 vs. 0.1% DMSO (vehicle)

Project description:Cytopiloyne was identified as a novel polyacetylenic compound. However, its antidiabetic properties are poorly understood. The aim of the present study was to investigate the anti-diabetic effect and mode of action of cytopiloyne on type 2 diabetes (T2D). We first evaluated the therapeutic effect of cytopiloyne on T2D in db/db mice. We found that one dose of cytopiloyne reduced postprandial glucose levels while increasing blood insulin levels. Accordingly, long-term treatment with cytopiloyne reduced postprandial blood glucose levels, increased blood insulin, improved glucose tolerance, suppressed the level of glycosylated hemoglobin A1c (HbA1c), and protected pancreatic islets in db/db mice. Next, we studied the anti-diabetic mechanism of action of cytopiloyne. We showed that cytopiloyne failed to decrease blood glucose in streptozocin- (STZ-)treated mice whose ? cells were already destroyed. Additionally, cytopiloyne dose dependently increased insulin secretion and expression in ? cells. The increase of insulin secretion/expression of cytopiloyne was regulated by protein kinase C ? (PKC ? ) and its activators, calcium, and diacylglycerol (DAG). Overall, our data suggest that cytopiloyne treats T2D via regulation of insulin production involving the calcium/DAG/PKC ? cascade in ? cells. These data thus identify the molecular mechanism of action of cytopiloyne and prove its therapeutic potential in T2D.

Project description:G-protein-coupled receptors (GPCRs) represent an important group of targets for pharmaceutical therapeutics. The completion of the human genome revealed a large number of putative GPCRs. However, the identification of their natural ligands, and especially peptides, suffers from low discovery rates, thus impeding development of therapeutics based on these potential drug targets. We describe the discovery of novel GPCR ligands encrypted in the human proteome. Hundreds of potential peptide ligands were predicted by machine learning algorithms. In vitro screening of selected 33 peptides on a set of 152 GPCRs, including a group of designated orphan receptors, was conducted by intracellular calcium measurements and cAMP assays. The screening revealed eight novel peptides as potential agonists that specifically activated six different receptors in a dose-dependent manner. Most of the peptides showed distinct stimulatory patterns targeted at designated and orphan GPCRs. Further analysis demonstrated a significant in vivo effect for one of the peptides in a mouse inflammation model.

Project description:Amorfrutins are selective PPARγ agonists with potent antidiabetic properties

Project description:Diabetes is a predominant metabolic disease nowadays due to the off-beam lifestyle of diet and reduced physical activity. Complications of the illness include the gene-environment interactions and the downstream genetic and epigenetic consequences, e.g., cardiovascular diseases, tumor progression, retinopathy, nephropathy, neuropathy, polydipsia, polyphagia, polyuria, and weight loss. This review sheds the light on the mechanistic insights of antidiabetic medicinal plants in targeting key organs and tissues involved in regulating blood glucose homeostasis including the pancreas, liver, muscles, adipose tissues, and glucose absorption in the intestine. Diabetes is also involved in modulating major epigenetic pathways such as DNA methylation and histone modification. In this respect, we will discuss the phytochemicals as current and future epigenetic drugs in the treatment of diabetes. In addition, several proteins are common targets for the treatment of diabetes. Some phytochemicals are expected to directly interact with these targets. We lastly uncover modeling studies that predict such plausible interactions. In conclusion, this review article presents the mechanistic insight of phytochemicals in the treatment of diabetes by combining both the cellular systems biology and molecular modeling.

Project description:Pro-vascular differentiation and adhesion of EPCs by S7 and E7 peptides