Yariv Donde

Prostaglandin ep4 antagonists

Prostaglandin antagonists, with their pharmacological effects, are well-known drugs capable of treating widely diffused illnesses, including pain and inflammation disorders. In recent years, a major research focus has been devoted to the identification of agents able to selectively antagonize each receptor with which prostaglandins interact. This review attempts to give a broad overview of molecules capable of selectively blocking the prostaglandin PGE2 EP4 receptor. Further therapeutic applications and uses have also been disccussed, including the first drug candidate to have reached clinical trials within the last few years.

Comparison of Prostaglandin E2 Receptor Subtype 4 Agonist and Sulfasalazine in Mouse Colitis Prevention and Treatment

Prodrugs of 5-aminosalicylic acid (5-ASA), such as sulfasalazine, have been the mainstay for the treatment and maintenance of inflammatory bowel disease (IBD) for decades, which is attributable to their antiadaptive immune activity. However, 5-ASA compromises regeneration of intestinal epithelia and induces apoptosis. The majority of patients eventually undergo colectomy. Agonists for the prostaglandin E2 subtype 4 (EP4) receptor have been shown to protect epithelial barrier against colitis-inducing agents and could be valuable alternatives for sulfasalazine. Here, we compared sulfasalazine and a novel EP4 agonist for their abilities to prevent colitis induction and relieve symptoms of established colitis in a dextran sulfate sodium–indomethacin mouse model. The EP4 agonist dose-dependently alleviated weight loss in colitis mice. Compared with sulfasalazine at 100 mg/kg on the colitis induction model, the EP4 agonist at 0.2 mg/kg was superior in reducing colitis symptoms, preventing increase of innate immune cells, and ameliorating inflammation in colon. In mice with established colitis, sulfasalazine quickly reversed weight loss but with fading efficacy. The EP4 agonist, in contrast, had slow but sustained effects on body weight gain and was more efficacious in epithelial regeneration. Such temporal differences between sulfasalazine and the EP4 agonist actions seemingly led to no additive effect in combination therapy. In conclusion, the EP4 agonist would be more efficacious in the maintenance of remission because of both anti-innate immune responses and epithelial regeneration activity, whereas sulfasalazine would be more suitable for induction of remission because of its rapid onset of antiadaptive inflammation action.

Prostaglandin E2 receptor subtype EP2- and EP4-regulated gene expression profiling in human ciliary smooth muscle cells

Prostanoids are an important class of intraocular pressure (IOP)-lowering antiglaucoma agents that act primarily via increased uveo-scleral aqueous humor outflow through the ciliary body. We have developed two novel PGE(2) analogs that are specific agonists for the PGE(2) receptor subtypes EP2 and EP4, respectively. To identify gene regulatory networks and key players that mediate the physiological effects observed in vivo, we performed genomewide expression studies using human ciliary smooth muscle cells. Quantitative real-time RT-PCR confirmed a largely overlapping gene expression profile subsequent to EP2 and EP4 agonist treatment, with 65 significantly regulated genes identified overall, 5 being specific for the EP2 agonist and 6 specific for the EP4 agonist. We found predicted functional cAMP-response elements in promoter regions of a large fraction of the predominantly upregulated genes, which suggests that the cAMP signaling pathway is the most important intracellular signaling pathway for these agonists in these cells. Several target genes were identified that, as part of complex regulatory networks, are implicated in tissue remodeling processes and osmoregulation (e.g., AREG, LOXL3, BMP2, AQP3) and thus may help elucidate the mechanism of action of these IOP-lowering drugs involving the uveo-scleral outflow path.