Potent activity of prostaglandin J2 on prostanoid DP receptors.

IF 4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biological Chemistry Pub Date : 2025-04-18 DOI:10.1016/j.jbc.2025.108523

Kanaho Senoo,Keijo Fukushima,Hitomi Yamamoto,Ayaka Hamaguchi,Akiko Suganami,Harumi Takano,Mayu Yamashita,John W Regan,Yutaka Tamura,Hiromichi Fujino

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引用次数: 0

Abstract

Prostaglandin D2 (PGD2), an anti-inflammatory mediator, is acting through Gs-protein coupled D-type prostanoid (DP) receptors. DP receptors are not extensively distributed; in tissues, they are the least abundant among members of the prostanoid receptor family, whereas their primary ligand PGD2 is the main prostanoid in most tissues. PGD2 is dehydrated or isomerized to a number of metabolites enzymatically or non-enzymatically. To understand why many metabolites of PGD2 are produced via different pathways, regular cell-based experiments, Black/Leff operational model calculations, and in silico simulations were utilized. Here we show, among the 5 metabolites of PGD2, prostaglandin J2 (PGJ2) was the most potent metabolite for DP receptors, particularly in the cAMP signaling pathway. This result was attributed to PGJ2 forming an extra, and/or stronger hydrogen bond by more negatively charged carbonyl in the cyclopentene ring with DP receptors than PGD2. Therefore, when PGD2 is released into the blood, it would activate DP receptors, which are then continuously activated by PGJ2 to sustain the DP receptor/cAMP-mediated signaling pathway. Thus, the anti-inflammatory effects of PGD2 may be taken over/out competed and/or even enhanced by PGJ2. Here, PGJ2 was found to be a standout mediator of cAMP-mediated signaling pathway, that induces more potent and prolonged DP receptor-activities as a biased ligand, possibly for resolving the inflammatory reaction. Moreover, since each metabolite showed different property, these results provide insight into why many metabolites of PGD2 are produced, and the miscellaneous physiological roles induced by the main prostanoid in most tissues through the least abundant DP receptors.

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前列腺素J2对前列腺素DP受体的有效活性。

前列腺素D2 （PGD2）是一种抗炎介质，通过gs蛋白偶联d型前列腺素（DP）受体起作用。DP受体分布不广泛；在组织中，它们是前列腺素受体家族成员中含量最少的，而它们的初级配体PGD2是大多数组织中的主要前列腺素。PGD2被脱水或异构化为酶促或非酶促的代谢物。为了理解为什么PGD2的许多代谢物是通过不同的途径产生的，我们利用了常规的基于细胞的实验、Black/Leff操作模型计算和计算机模拟。在PGD2的5种代谢物中，前列腺素J2 （PGJ2）是DP受体最有效的代谢物，特别是在cAMP信号通路中。这一结果归因于PGJ2与DP受体在环戊烯环上形成了一个额外的，和/或更强的氢键，与PGD2相比，在环戊烯环上有更多带负电荷的羰基。因此，当PGD2被释放到血液中时，它会激活DP受体，然后DP受体被PGJ2持续激活，以维持DP受体/ camp介导的信号通路。因此，PGD2的抗炎作用可能被PGJ2取代/淘汰和/或甚至增强。在这里，PGJ2被发现是camp介导的信号通路的突出介质，它作为偏配体诱导更有效和更持久的DP受体活性，可能用于解决炎症反应。此外，由于每种代谢物表现出不同的特性，这些结果为PGD2的许多代谢物产生的原因以及主要前列腺素通过最不丰富的DP受体在大多数组织中诱导的各种生理作用提供了见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biological Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry

自引率

4.20%

发文量

1233

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