Hubbry Logo
ProstanoidProstanoidMain
Open search
Prostanoid
Community hub
Prostanoid
logo
7 pages, 0 posts
0 subscribers
Be the first to start a discussion here.
Be the first to start a discussion here.
Prostanoid
Prostanoid
Prostanoid
View on Wikipedia
from Wikipedia

In molecular biology, prostanoids are active lipid mediators that regulate inflammatory response. Prostanoids are a subclass of eicosanoids consisting of the prostaglandins (mediators of inflammatory and anaphylactic reactions), the thromboxanes (mediators of vasoconstriction), and the prostacyclins (active in the resolution phase of inflammation).[1] Prostanoids are seen to target NSAIDS which allow for therapeutic potential. Prostanoids are present within areas of the body such as the gastrointestinal tract, urinary tract, respiratory and cardiovascular systems, reproductive tract and vascular system. Prostanoids can even be seen with aid to the water and ion transportation within cells.

History

[edit]

Prostanoids were discovered through biological research studies conducted in the 1930s.[2][3] The first discovery was seen through semen by a Swedish Physiologist Ulf von Euler, who assumed they originated from the prostate. After intensive study throughout the 1960-1970s Sune K. Bergström and Bengt Ingemar Samuelsson and British biochemist Sir John Robert Vane were able to understand the function and chemical formation of Prostanoids: receiving a Nobel Prize for their analysis of prostanoids.

Biosynthesis of prostaglandins

[edit]

Cyclooxygenase (COX) catalyzes the conversion of the free essential fatty acids to prostanoids by a two-step process. In the first step, two molecules of O2 are added as two peroxide linkages and a 5-member carbon ring is forged near the middle of the fatty acid chain. This forms the short-lived, unstable intermediate Prostaglandin G (PGG). One of the peroxide linkages sheds a single oxygen, forming PGH. (See diagrams and more detail at Cyclooxygenase). All other prostanoids originate from PGH (as PGH1, PGH2, or PGH3).

The image at right shows how PGH2 (derived from Arachidonic acid) is converted:

Arachidonic acid is made up of a 20-Carbon unnatural poly unsaturated Omega-fatty acid.[1] Arachidonic acid presents within the phospholipid bi-layer as well as in the plasma membrane of a cell. With Arachidonic acid prostaglandins are formed through synthesis and oxygenation of enzymes. Active lipids in the oxylipin family derive from the synthesis of Cyclooxygenase or Prostaglandins.

The three classes of prostanoids have distinctive rings in the center of the molecule. They differ in their structures and do not share common structure as Thromboxane. The PGH compounds (parents to all the rest) have a 5-carbon ring, bridged by two oxygens (a peroxide.) The derived prostaglandins contain a single, unsaturated 5-carbon ring. In prostacyclins, this ring is conjoined to another oxygen-containing ring. In thromboxanes the ring becomes a 6-member ring with one oxygen.

Production of PGE2 in bacterial and viral infections appear to be stimulated by certain cytokines, e.g., interleukin-1.[4]

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Prostanoid

View on Grokipedia
from Grokipedia
Prostanoids are a family of bioactive mediators derived from the polyunsaturated fatty acid through the action of enzymes, encompassing prostaglandins, prostacyclins, and thromboxanes that function primarily as local hormones in paracrine and . These compounds are synthesized on demand in response to various stimuli, starting with the release of from membrane phospholipids by A₂, followed by its conversion to the unstable intermediate prostaglandin H₂ (PGH₂) via -1 (COX-1) or COX-2, and subsequent transformation into specific prostanoids by terminal synthases such as prostaglandin E synthase or thromboxane synthase. The primary classes of prostanoids include the prostaglandins (such as PGE₂, PGD₂, PGF₂α, and PGI₂ or ) and A₂ (TXA₂), each characterized by distinct ring structures with varying side chains that determine their receptor specificity and biological effects. For instance, PGE₂ is produced via microsomal E synthase-1 (mPGES-1) from PGH₂ and binds to four EP receptor subtypes (EP1–EP4), while PGI₂ acts through the IP receptor and TXA₂ through the TP receptor, enabling targeted cellular responses. These molecules are rapidly metabolized and inactivated, ensuring their actions are spatially and temporally restricted. Prostanoids play critical roles in numerous physiological processes, including the regulation of , sensation, renal blood flow, and cardiovascular , while their dysregulation contributes to pathological conditions such as chronic , , and cancer. In , prostanoids like PGE₂ initially promote , , and immune cell recruitment during the acute phase, but later facilitate resolution by inducing anti-inflammatory cytokines, supporting macrophage switching to pro-resolving states, and promoting the of . Therapeutically, non-steroidal drugs (NSAIDs) inhibit COX enzymes to reduce prostanoid levels, alleviating and , though this can lead to side effects like gastrointestinal ulceration due to loss of protective prostanoids in the gut mucosa.

Overview

Definition

Prostanoids constitute a subclass of eicosanoids, a diverse group of bioactive lipid mediators derived from 20-carbon polyunsaturated fatty acids, primarily , through enzymatic oxidation via the (COX) pathway. These molecules are characterized by their cyclic structures, formed during the COX-mediated conversion of into endoperoxide intermediates, which then yield specific prostanoid classes. As potent local signaling agents, prostanoids primarily exert autocrine and paracrine effects rather than endocrine actions, influencing nearby cells and tissues in response to physiological or pathological stimuli. They play essential roles in modulating key processes such as , , , and gastrointestinal integrity, thereby maintaining in various systems. Their short half-lives—often mere minutes—underscore their role as transient regulators produced on demand. In distinction from other eicosanoids, prostanoids specifically encompass the cyclic products of the COX pathway, including prostaglandins, prostacyclins, and thromboxanes, whereas linear eicosanoids like leukotrienes and lipoxins arise from the pathway and serve overlapping yet differentiated functions in and resolution. Prostanoids are ubiquitously produced across multiple tissues, with notable presence and activity in the for mucosal protection, kidneys for renal blood flow regulation, lungs for modulation, heart for cardioprotective effects, reproductive organs for and , and vascular for vasoregulation and control.

Classification

Prostanoids are classified into major groups based on their core structures and the precursors from which they are derived, encompassing prostaglandins, , and . These mediators all feature a 20-carbon backbone derived from essential , typically with a ring formed between carbons 8 and 12, but they differ in ring modifications and substituents that determine their specific identities and biological properties. The primary classes include prostaglandins such as PGD₂, PGE₂, and PGF₂α; (PGI₂); and (TXA₂). Within the prostaglandins, relies on the functional groups attached to the ring. For instance, PGE₂ is characterized by a keto group at carbon 9 (C9) and a hydroxyl group at C11, forming a β-hydroxy configuration that distinguishes it from other subtypes like PGD₂, which has two hydroxyl groups, or PGF₂α, with hydroxyl groups at both C9 and C11. (PGI₂) shares the ring but includes a unique linkage that creates an additional fused five-membered ring, enhancing its stability relative to some analogs. In contrast, A₂ (TXA₂) features a six-membered oxane ring instead of the , along with an ring, making it highly unstable and prone to rapid to the inactive TXB₂. Prostanoids are further subdivided into series based on the number of s in their side chains, reflecting their precursor fatty acids. Series 1 prostanoids, derived from dihomo-γ-linolenic acid, contain one double bond in the ω-chain and are generally associated with reduced inflammatory activity compared to other series. Series 2, the most prevalent in mammals and produced from , have two double bonds (at positions 5-cis and 13-trans) and include the common examples like PGE₂ and TXA₂. Series 3 prostanoids, originating from , feature three double bonds (including an additional 17-cis) and exhibit properties, often competing with series 2 for enzymatic processing.

Biosynthesis

Arachidonic Acid Pathway

The biosynthesis of prostanoids begins with the liberation of from the sn-2 position of glycerophospholipids in cell membranes, a process catalyzed by (PLA2) enzymes. This rate-limiting step is activated by diverse extracellular stimuli, such as hormones (e.g., ), growth factors, cytokines, and physical injury, which often involve increases in intracellular calcium levels or cascades like MAPK signaling. Among the PLA2 isoforms, group IVA cytosolic PLA2 (cPLA2α) plays a central role in stimulus-induced release due to its specificity for arachidonoyl-containing phospholipids and translocation to membranes upon activation. The free arachidonic acid is then metabolized by cyclooxygenase (COX) enzymes, also known as prostaglandin H synthases (PGHS), to form the unstable endoperoxide intermediate prostaglandin G2 (PGG2), followed by conversion to prostaglandin H2 (PGH2), the common precursor for all prostanoids. Two isoforms exist: COX-1 (PGHS-1), which is constitutively expressed in most tissues and maintains basal prostanoid levels for physiological homeostasis, and COX-2 (PGHS-2), which is rapidly induced by inflammatory mediators, mitogens, and stress signals to amplify prostanoid production during pathological conditions. Both isoforms share structural homology, with active sites for cyclooxygenase and peroxidase activities located in distinct but coordinated domains. The COX-catalyzed reaction occurs in two sequential steps at the endoplasmic reticulum or nuclear envelope. In the first step, the cyclooxygenase activity inserts molecular oxygen into arachidonic acid at carbons 9 and 11, forming the cyclic endoperoxide PGG2 with a 15-hydroperoxy group through a radical-initiated abstraction of the C-13 pro-S hydrogen. The second step involves the peroxidase activity, which uses PGG2 or another hydroperoxide as a cosubstrate to reduce the 15-hydroperoxy moiety to a hydroxy group, yielding PGH2. This bis-functional mechanism ensures efficient coupling, though COX-2 exhibits higher peroxidase activity and catalytic turnover compared to COX-1. Arachidonic acid (all-cis-5,8,11,14-eicosatetraenoic acid) is the preferred substrate for COX enzymes due to its optimal chain length and double-bond positioning, which fit the narrow, hydrophobic channel. Alternative omega-3 fatty acids, such as (EPA), can serve as substrates but with lower affinity and efficiency, resulting in series-3 prostanoids (e.g., PGI3) that exhibit reduced potency in biological assays relative to the series-2 counterparts from . This substrate specificity underlies the anti-inflammatory benefits observed with dietary EPA supplementation.

Enzymatic Regulation

The biosynthesis of individual prostanoids from the common intermediate (PGH2) is mediated by specific terminal synthases that exhibit distinct enzymatic activities and regulatory controls. Prostaglandin D synthase (PGDS) catalyzes the isomerization of PGH2 to (PGD2), with two main isoforms: hematopoietic PGDS (H-PGDS), predominant in immune cells such as mast cells and Th2 lymphocytes, and lipocalin-type PGDS (L-PGDS), expressed in the and other tissues. Prostaglandin E synthase (PGES) converts PGH2 to (PGE2), while prostaglandin F synthase (PGFS) produces prostaglandin F2α (PGF2α) through reduction of PGH2. synthase (PGIS) isomerizes PGH2 to prostacyclin (PGI2), and thromboxane synthase (TXAS) transforms PGH2 into (TXA2). These enzymes ensure the tissue-specific diversification of prostanoids, with their expression and activity tightly regulated to match physiological demands. Regulation of these synthases occurs through multiple mechanisms, including tissue-specific expression patterns that direct prostanoid profiles in different cellular contexts. For instance, endothelial cells preferentially express PGIS, favoring PGI2 production to promote and inhibit platelet aggregation, whereas platelets predominantly express TXAS, leading to TXA2 synthesis that supports and . Synthase expression is further modulated by proinflammatory cytokines, such as interleukin-1 (IL-1), which induce COX-2 and coordinate with downstream synthases like PGIS in vascular tissues during . Feedback inhibition also plays a role; for example, elevated PGE2 can suppress mPGES-1 activity in neuroinflammatory settings, preventing excessive production. Subcellular localization influences efficiency: microsomal synthases (e.g., mPGES-1, PGIS) are associated with the , facilitating close coupling with COX enzymes, while cytosolic forms like cPGES operate in the . Particular emphasis falls on the isoform variations of PGES, which include three distinct enzymes: microsomal PGES-1 (mPGES-1), microsomal PGES-2 (mPGES-2), and cytosolic PGES (cPGES). mPGES-1 is inducible, with low basal expression that surges in response to proinflammatory stimuli like IL-1β and tumor factor-α (TNF-α), coupling primarily with COX-2 to drive PGE2 production during , as seen in and other conditions. In contrast, cPGES and mPGES-2 are constitutively expressed across tissues, supporting basal PGE2 levels; cPGES pairs with COX-1 for immediate responses, while mPGES-2 associates with both COX isoforms but shows less inducibility. This isoform-specific regulation allows for fine-tuned PGE2 output, with mPGES-1 models demonstrating reduced inflammatory PGE2 without disrupting homeostatic levels.

Receptors and Signaling

Receptor Types

Prostanoid receptors constitute a subfamily of G protein-coupled receptors (GPCRs) within the rhodopsin-like (class A) family, featuring seven transmembrane-spanning domains that facilitate ligand binding and . These receptors are classified into five primary types—DP, EP, FP, IP, and TP—based on their preferred endogenous ligands: prostaglandin D₂ (PGD₂) for DP receptors, prostaglandin E₂ (PGE₂) for EP receptors, prostaglandin F₂α (PGF₂α) for FP receptors, (PGI₂) for IP receptors, and thromboxane A₂ (TXA₂) for TP receptors. The EP and DP classes include multiple subtypes, each exhibiting distinct coupling profiles and tissue expression patterns that contribute to their specialized roles in prostanoid signaling. The following table summarizes the main receptor classes, their subtypes, primary ligands, G protein couplings, and representative tissue distributions:
Receptor ClassSubtypesPrimary LigandG Protein CouplingTissue Distribution Examples
DPDP₁, DP₂ (also known as CRTH2)PGD₂DP₁: ; DP₂: GᵢDP₁: , platelets, ; DP₂: , , Th₂ lymphocytes
EPEP₁, EP₂, EP₃, EP₄PGE₂EP₁: ; EP₂: ; EP₃: Gᵢ; EP₄: EP₁: , , ; EP₂/EP₄: immune cells (e.g., macrophages, dendritic cells, T cells), ; EP₃: , , , platelets
FPNone (single isoform with splice variants)PGF₂α, , heart, , uterine and vascular
IPNone (single isoform)PGI₂, vascular , platelets, dorsal root ganglia
TPTPα, TPβ (splice variants)TXA₂, PGH₂, G₁₂/₁₃Platelets, , , vascular , airways
These receptors display high selectivity for their ligands, with dissociation constants (Kᵢ) typically in the low nanomolar range (e.g., PGE₂ Kᵢ ≈ 1–20 nM for EP subtypes; PGI₂ analogs Kᵢ ≈ 10 nM for IP). is generally minimal, though certain synthetic analogs exhibit broader affinities; for instance, , a stable PGI₂ analog, binds potently to both IP (Kᵢ ≈ 3–11 nM) and EP₁ (Kᵢ ≈ 1–11 nM) receptors, with weaker interaction at EP₃ (Kᵢ ≈ 56 nM). This selectivity profile underscores the structural conservation of ligand-binding pockets across the family while allowing for nuanced pharmacological targeting.

Signal Transduction Pathways

Prostanoid receptors are G protein-coupled receptors (GPCRs) that transduce signals from their respective ligands through coupling to heterotrimeric G proteins, activating downstream effectors that modulate cellular responses. These receptors, including the EP, DP, FP, IP, and TP subtypes, exhibit specificity in G protein coupling, leading to diverse intracellular signaling cascades. The primary G protein subtypes involved include Gs, which stimulates adenylyl cyclase to increase cyclic AMP (cAMP) levels, primarily coupled to the EP2, EP4, IP, and DP1 receptors; Gi, which inhibits adenylyl cyclase to decrease cAMP, associated with the EP3 and DP2 receptors; Gq, which activates phospholipase C (PLC) to generate inositol trisphosphate (IP3) and mobilize intracellular Ca²⁺, linked to the EP1, FP, and TP receptors; and G12/13, which activates Rho GTPases, mainly for the TP receptor and to some extent the FP receptor. Common signaling pathways downstream of these couplings include the cAMP/ (PKA) axis, activated via Gs-coupled receptors such as the IP receptor for (PGI2), leading to PKA-mediated of targets; and Ca²⁺ mobilization via /PLC/IP3, as seen with the TP receptor for (TXA2), resulting in Ca²⁺-dependent activation of effectors like . Additionally, β-arrestin-mediated non-canonical signaling occurs independently of G proteins, facilitating scaffold-dependent activation of pathways such as MAPK/ERK in certain contexts. Crosstalk between pathways enhances signaling complexity, for instance, EP receptor activation can lead to MAPK/ERK through β-arrestin or of other kinases, while receptor dimerization, such as between EP1 and or IP and TPα, modulates binding and effector coupling. Desensitization of prostanoid receptors involves by G protein-coupled receptor kinases (GRKs), such as GRK2 for DP1 and GRK5/6 for TP, which promotes β-arrestin binding and clathrin-mediated internalization, thereby terminating signaling and enabling receptor trafficking.

Physiological Functions

Inflammation and Immunity

Prostanoids play a pivotal role in orchestrating inflammatory responses, with certain members exhibiting predominantly pro-inflammatory effects that amplify acute . Prostaglandin E2 (PGE2), acting through its EP2 and EP4 receptors, promotes and increases , contributing to the classic signs of such as redness and swelling. Additionally, PGE2 via the EP3 receptor in the induces fever by elevating the thermoregulatory set point, a key component of the systemic inflammatory response. sensitization is another pro-inflammatory action of PGE2, mediated by EP1 and EP3 receptors on sensory neurons, which lowers the threshold for activation. Prostaglandin D2 (PGD2), through its DP1 receptor, further enhances , particularly in allergic , facilitating at sites of injury. In contrast, prostanoids also contribute to the resolution phase of , shifting the response toward outcomes. PGD2, signaling via the DP1 receptor, supports resolution of certain responses, such as neutrophilic , by attenuating leukocyte , inhibiting production, and promoting T to restore . (PGI2), acting through the IP receptor, inhibits pro- production in macrophages and other immune cells, thereby suppressing the amplification of cascades. These resolution-promoting actions highlight the dual nature of prostanoids in temporally regulating . Prostanoids exert significant modulation on immune cell functions, influencing both innate and adaptive immunity. Thromboxane A2 (TXA2), via its TP receptor, activates neutrophils, enhancing their , , and release of to bolster early inflammatory defense. Conversely, PGE2 suppresses T-cell proliferation by inhibiting IL-2 production and receptor expression, thereby limiting adaptive immune expansion during inflammation. PGE2 also impairs dendritic cell maturation, promoting an "exhausted" phenotype that favors Th2 and regulatory T-cell responses over pro-inflammatory Th1 immunity. The balance between pro- and anti-inflammatory prostanoids is dynamically regulated during , often through the induction of (COX-2) in response to inflammatory stimuli. In acute , COX-2 upregulation initially favors pro-inflammatory prostanoids like PGE2 and TXA2 to mount a robust response, but as progresses, it supports the production of resolution mediators such as PGD2 and PGI2, preventing chronicity. This enzymatic shift ensures a controlled inflammatory process, with dysregulation potentially leading to persistent immune activation.

Cardiovascular Regulation

Prostanoids play a critical role in regulating vascular tone through opposing actions on smooth muscle relaxation and contraction. Prostacyclin (PGI₂), acting via the IP receptor, is a potent vasodilator produced by endothelial cells that relaxes vascular smooth muscle by increasing cyclic AMP levels, thereby promoting blood flow and reducing vascular resistance. PGI₂ also serves as the most effective endogenous inhibitor of platelet aggregation, preventing thrombus formation by suppressing platelet activation and adhesion to the endothelium. Complementing this, prostaglandin E₂ (PGE₂), through its EP₂ and EP₄ receptors, enhances endothelial barrier function and integrity, which helps maintain vascular homeostasis and supports anti-thrombotic properties by stabilizing the endothelial lining against inflammatory or shear stress-induced damage. In contrast, thromboxane A₂ (TXA₂), synthesized primarily by platelets via the TP receptor, exerts vasoconstrictive effects that counteract , leading to increased vascular tone and potential for or . TXA₂ promotes platelet , aggregation, and clot formation by stimulating calcium and shape change in platelets, facilitating but risking excessive if unregulated. This pro-thrombotic action is essential for rapid response to vascular injury but must be balanced to avoid pathological clotting. Prostanoids also influence cardiac function, with prostaglandin F₂α (PGF₂α) acting via receptor to enhance , providing positive inotropic effects that increase force of ventricular contractions in response to hemodynamic demands. Additionally, PGE₂ contributes to cardioprotection during ischemia, as seen in preconditioning protocols where it reduces infarct size and improves recovery from ischemia-reperfusion injury by modulating cytokine production and preserving endothelial function in the coronary vasculature. The homeostatic balance between endothelial-derived PGI₂ and platelet-derived TXA₂ is pivotal for preventing excessive clotting and maintaining vascular patency, with PGI₂'s vasodilatory and anti-aggregatory effects dominating under normal conditions to inhibit TXA₂-induced and . This dynamic interplay ensures appropriate without promoting chronic vascular occlusion, underscoring the endothelium's role in modulating prostanoid signaling for cardiovascular stability.

Metabolism and Inactivation

Degradation Mechanisms

Prostanoids are primarily inactivated through enzymatic oxidation by 15-hydroxyprostaglandin dehydrogenase (15-PGDH), which catalyzes the rate-limiting first step in their degradation by converting the 15-hydroxyl group to a 15-keto group, thereby forming biologically inactive metabolites. This enzyme specifically targets prostaglandins such as PGE2 and PGD2, oxidizing them to 15-keto-PGE2 and 15-keto-PGD2, which exhibit markedly reduced receptor affinity and signaling activity. The resulting 15-keto metabolites are further dehydrogenated and undergo side-chain shortening, ensuring termination of prostanoid-mediated effects like and . Unstable prostanoids such as (TXA2) and (PGI2) undergo rapid non-enzymatic hydrolysis to inactive forms, independent of 15-PGDH. TXA2, with a half-life of approximately 30 seconds in physiological conditions, spontaneously hydrolyzes to thromboxane B2 (TXB2), which lacks platelet-aggregating and vasoconstrictive properties. Similarly, PGI2 hydrolyzes quickly to the stable but inactive 6-keto-prostaglandin F (6-keto-PGF), preventing prolonged anti-thrombotic and vasodilatory actions. Additional degradation pathways involve peroxisomal β-oxidation for shortening the carboxyl side chain of prostanoids after initial oxidation, a process critical for their complete catabolism in vivo. For PGD2, an alternative route includes conjugation with glutathione, forming glutathione adducts that facilitate detoxification and excretion, particularly for its cyclopentenone derivatives like 15-deoxy-Δ12,14-prostaglandin J2. These mechanisms collectively limit prostanoid bioavailability by rapidly converting active lipids to inert products. The enzyme 15-PGDH is highly expressed in tissues with high prostanoid flux, such as the and intestine, enabling efficient local clearance to prevent excessive signaling. In the , this distribution supports rapid inactivation of prostanoids involved in , while in the intestine, it maintains mucosal by degrading PGE2-driven proliferative signals.

Excretion and Clearance

Following enzymatic inactivation, prostanoid metabolites, such as 15-keto derivatives of PGE2 and PGF2α, are primarily transported from renal and hepatic cells into the tubular lumen or canaliculi via organic anion transporters (OATs). In the , human OAT1 (SLC22A6), OAT3 (SLC22A8), and OAT4 (SLC22A11) facilitate the basolateral and apical of these anionic metabolites across epithelia, enabling their delivery to the . Similarly, hepatic OATs and related uptake transporters, including OATP1B1 and OATP1B3, contribute to the hepatic handling and biliary export of conjugated prostanoid metabolites. Urinary excretion represents the predominant elimination pathway for metabolites of PGE2 and PGF2α, reflecting their rapid renal clearance after systemic circulation. Major urinary metabolites include 11α-hydroxy-9,15-dioxo-2,3,18,19-tetranorprost-5-ene-1,20-dioic acid (PGE-MUM) from PGE2 and 11,15-dioxo-9α-hydroxy-2,3,18,19-tetranorprost-5-ene-1,20-dioic acid (tetranor-PGFM) from PGF2α, both of which are excreted primarily via the kidneys. Another key example is 11β-PGF2α, a stable derived from PGD2 via AKR1C3-mediated reduction, which serves as a urinary for systemic prostanoid production and . Over 80-90% of prostanoid metabolites are typically cleared renally, with complete elimination occurring within several hours post-production due to efficient tubular secretion. Biliary and subsequent fecal elimination provides an alternative route for more lipophilic prostanoid metabolites, particularly those undergoing phase II conjugation in the liver. These metabolites are often conjugated with or groups by UDP-glucuronosyltransferases (UGTs) or sulfotransferases (SULTs), enhancing their solubility for canalicular efflux via multidrug resistance-associated proteins (MRPs), such as MRP2 and MRP3. In animal models, such as rats administered tritium-labeled prostaglandins, biliary accounts for 20-50% of the total dose for certain PGE2 and PGF2α analogs, with the remainder via feces after . This pathway is especially relevant for metabolites resistant to rapid renal filtration. Prostanoids exhibit extremely short biological half-lives to ensure localized signaling, with PGE2 having a circulatory of approximately 30 seconds to 1.5 minutes before inactivation and . Their metabolites, however, persist longer systemically, with half-lives of 5-10 minutes, allowing for measurable urinary accumulation over 1-2 hours following production. This differential persistence underscores the tight temporal control of prostanoid activity, where rapid clearance prevents prolonged effects on physiological processes like and vascular tone.

Clinical Significance

Therapeutic Applications

Prostanoids and their pathways are targeted therapeutically through inhibitors of their biosynthesis, as well as agonists and antagonists of specific receptors. (COX) inhibitors, particularly nonsteroidal drugs (NSAIDs) such as ibuprofen, act by non-selectively blocking COX-1 and COX-2 enzymes, thereby reducing the production of all prostanoids and alleviating pain and inflammation associated with conditions like and musculoskeletal injuries. Selective COX-2 inhibitors, exemplified by celecoxib, preferentially target the inducible COX-2 isoform to minimize gastrointestinal side effects while effectively managing chronic inflammatory conditions such as . Prostanoid agonists mimic endogenous ligands to activate specific receptors for targeted therapies. Misoprostol, a synthetic PGE1 analog, is widely used to prevent and treat gastric ulcers, particularly those induced by NSAIDs, by enhancing mucosal protection and reducing acid secretion. Iloprost, a stable PGI2 analog, is administered via inhalation or infusion to treat pulmonary arterial hypertension by promoting vasodilation and inhibiting platelet aggregation, improving exercise capacity and survival rates in affected patients. Latanoprost, a PGF2α analog, serves as a first-line topical treatment for glaucoma and ocular hypertension by increasing uveoscleral outflow to lower intraocular pressure. Receptor antagonists and agonists provide more selective modulation of prostanoid signaling. Thromboxane prostanoid (TP) receptor antagonists, such as ifetroban, block platelet activation and vascular constriction to prevent , showing cardioprotective effects in preclinical models of ischemic . EP4 receptor agonists, like ONO-4819.CD, promote formation and accelerate healing by stimulating activity and callus mineralization in animal models of bone repair. Additionally, microsomal prostaglandin E synthase-1 (mPGES-1) inhibitors, such as ISC 27864, have completed phase II clinical trials for osteoarthritis, showing potential analgesic effects by selectively blocking PGE2 production without the cardiovascular risks associated with traditional NSAIDs in preclinical and early clinical data.

Pathological Roles

Dysregulated prostanoid signaling contributes to various pathologies through imbalances in their production or receptor activation, often exacerbating inflammation, vascular dysfunction, and tissue remodeling. In inflammatory conditions, elevated levels of prostaglandin E2 (PGE2), primarily via cyclooxygenase-2 (COX-2) induction and EP4 receptor activation, drive rheumatoid arthritis progression by promoting synovial inflammation and joint destruction, as evidenced by increased matrix metalloproteinase expression and bone erosion in affected tissues. Similarly, excess prostaglandin D2 (PGD2) acting through the DP2 receptor (also known as CRTH2) amplifies allergic asthma by recruiting Th2 cells, eosinophils, and type 2 innate lymphoid cells, leading to heightened airway inflammation, mucus hypersecretion, and bronchial hyperresponsiveness, with PGD2 levels rising up to 150-fold post-allergen challenge in bronchoalveolar lavage fluid. In cardiovascular diseases, (TXA2) overproduction enhances platelet activation and , accelerating by increasing leukocyte adhesion via upregulation and lesion formation, as demonstrated in apolipoprotein E-deficient mice where TP receptor deletion reduced plaque areas by 58-70%. Conversely, (PGI2) deficiency, through impaired IP receptor signaling, promotes salt-sensitive and cardiac , with IP receptor knockout mice showing elevations to 157 mm Hg on high-salt diets compared to 137 mm Hg in wild-type controls, alongside increased heart-to-body weight ratios and deposition. Beyond these, PGE2 contributes to cancer progression by stimulating via EP2 receptor-mediated upregulation of (VEGF) and 2 (FGF2), enhancing endothelial cell motility and tumor vascularization in models like mammary and colorectal carcinomas. F2α (PGF2α) excess induces through excessive uterine contractions and , resulting in myometrial ischemia and pain, with plasma and endometrial levels significantly higher in affected women during compared to controls. Recent studies from 2023 highlight prostanoid imbalances in pulmonary arterial hypertension (PAH), where reduced IP receptor activation contrasts with elevated TP receptor signaling, promoting , vascular smooth muscle proliferation, and via dominance over . In , dysregulated prostaglandins amplify the by enhancing pro-inflammatory production, with elevated PGE2 and related mediators correlating with severe immune dysregulation and multi-organ injury through COX pathway overactivation.

History

Discovery

In the 1930s, Swedish physiologist Ulf von Euler identified a biologically active substance in human semen that caused potent contraction of and in experimental animals. He named this factor "prostaglandin," assuming it originated from the prostate gland, though subsequent studies revealed its primary source as the . Von Euler's discovery was based on extracts from seminal fluid tested via bioassays, including contractions in isolated strips, which provided a sensitive measure of the substance's activity. During the 1950s and 1960s, advanced the field by isolating and characterizing specific prostaglandins from sheep vesicular (prostate) glands, which served as a rich source due to high concentrations. By 1960, Bergström and his collaborators had purified prostaglandin E (PGE) and prostaglandin F (PGF), determining their structures as 20-carbon unsaturated hydroxy acids through techniques like countercurrent distribution, , and . These efforts confirmed multiple related compounds rather than a single entity, with PGE exhibiting vasodilatory and smooth muscle-stimulating effects measured again via rabbit intestinal bioassays. Early research viewed prostaglandins as circulating hormones due to their endocrine-like potency, but by the mid-1960s, they were recognized as local mediators acting near their site of synthesis, influencing nearby tissues without systemic transport. This shift clarified their role as paracrine signals, distinct from traditional hormones.

Major Developments

Following the initial discovery and naming of prostaglandins in the 1930s, major developments in prostanoid research accelerated in the mid-20th century with advances in structural elucidation and biosynthetic pathways. In 1962, and colleagues at the isolated and determined the chemical structures of the first prostaglandins, including PGE1 and PGF1α, from sheep glands, revealing their ring core derived from fatty acids. This breakthrough, achieved through chromatographic separation and , enabled the synthesis of pure compounds and shifted prostanoids from bioassay-based observations to molecular understanding. By 1964, independent studies by Bergström's group and David van Dorp's team at demonstrated that prostanoids are biosynthesized from via enzymatic oxygenation, marking the identification of the pathway. Bergström et al. showed that vesicular gland homogenates convert [14C]-arachidonic acid to PGE2, establishing essential fatty acids as precursors and linking prostanoid formation to . This discovery explained dietary influences on prostanoid levels and laid the foundation for understanding their regulation in physiological processes. A pivotal advance came in 1971 when at the revealed that aspirin and other non-steroidal drugs (NSAIDs) inhibit prostanoid synthesis by blocking (COX-1), the enzyme catalyzing conversion to PGH2. Using techniques on isolated tissues, Vane demonstrated that indomethacin prevented release in response to stimuli, unifying the , , and effects of these drugs under a single mechanism. This finding revolutionized and spurred the development of COX-targeted therapies. The 1970s expanded the prostanoid family beyond classical prostaglandins. In 1975, Bengt Samuelsson's team at Karolinska identified thromboxanes, potent platelet aggregators derived from PGH2 endoperoxides, with (TXA2) characterized as a short-lived oxane ring compound promoting and . This was achieved through extraction from platelets and structural analysis via gas chromatography-mass spectrometry, highlighting prostanoids' dual roles in . Shortly after, in 1976, , Ryszard Gryglewski, and at the Wellcome Foundation discovered (PGI2) in vascular , a stable metabolite of PGH2 that inhibits platelet aggregation and induces , counterbalancing TXA2. Isolated from aortic rings and identified by and UV , PGI2's elucidation explained endothelial protection against . The 1982 Nobel Prize in Physiology or Medicine, awarded to Bergström, Samuelsson, and Vane, recognized these contributions, catalyzing further into prostanoid signaling. In the 1990s, advanced the field with the cloning of prostanoid receptors as G-protein-coupled receptors (GPCRs). The first, the thromboxane A2 receptor (TP), was cloned in 1991 by Masayuki Hirata and Shuh Narumiya from a placental cDNA library (and a partial clone from human megakaryocytic leukemia cells) with functional expression in COS-7 cells, confirming its seven-transmembrane structure and coupling to proteins for activation. Subsequent cloning of EP, DP, , IP, and other subtypes between 1993 and 1997 enabled targeted pharmacological studies and revealed tissue-specific signaling. The identification of a second COX isoform, COX-2, in 1991 by William Xie, Daniel Simmons, and colleagues provided insights into inducible prostanoid production. Through differential screening of a from phorbol ester-stimulated chicken embryo fibroblasts, they cloned COX-2 as a mitogen-inducible distinct from constitutive COX-1, with higher expression in and cancer. This discovery facilitated the development of selective COX-2 inhibitors like celecoxib (approved 1999), reducing gastrointestinal side effects of traditional NSAIDs while targeting pathological prostanoid overproduction. Recent decades have emphasized prostanoids' roles in resolution of and tissue repair, moving beyond their pro-inflammatory connotations. Studies since the , including Charles Serhan's work on , have shown that lipoxin A4 (derived from via transcellular metabolism involving prostanoid intermediates) actively terminates , with preclinical models demonstrating enhanced clearance of neutrophils. Additionally, prostanoid receptor agonists like (approved 2002 for ) and (1988 for gastric ulcers) exemplify therapeutic translation, while ongoing research explores EP4 agonists for pain relief based on PGE2's anabolic effects on . More recently, as of 2025, studies have highlighted PGE2's role in reversing aged muscle dysfunction, enhancing regeneration and strength. These developments underscore prostanoids' therapeutic potential in chronic diseases, supported by high-impact trials establishing efficacy and safety profiles.

References

  1. https://pmc.ncbi.nlm.nih.gov/articles/PMC2674745/
  2. https://pmc.ncbi.nlm.nih.gov/articles/PMC8312722/
  3. https://www.sciencedirect.com/topics/neuroscience/prostanoid
  4. https://pubmed.ncbi.nlm.nih.gov/18276980/
  5. https://pmc.ncbi.nlm.nih.gov/articles/PMC3859365/
  6. https://www.ahajournals.org/doi/10.1161/ATVBAHA.119.313234
  7. https://themedicalbiochemistrypage.org/eicosanoid-metabolism-prostaglandins-thromboxanes-leukotrienes-and-lipoxins/
  8. https://basicmedicalkey.com/22-lipids-the-eicosanoids-prostaglandins-leukotrienes-and-thromboxanes/
  9. https://journals.physiology.org/doi/full/10.1152/physrev.1999.79.4.1193
  10. https://www.ahajournals.org/doi/10.1161/atvbaha.123.320045
  11. https://chem.libretexts.org/Courses/Nassau_Community_College/Organic_Chemistry_I_and_II/25%3A_Lipids/25.5%3A_Prostaglandins_and_other_Eicosanoids
  12. https://www.sciencedirect.com/topics/medicine-and-dentistry/eicosanoid-biosynthesis
  13. https://www.sciencedirect.com/topics/pharmacology-toxicology-and-pharmaceutical-science/thromboxane-synthase
  14. https://pmc.ncbi.nlm.nih.gov/articles/PMC3307725/
  15. https://pmc.ncbi.nlm.nih.gov/articles/PMC6483111/
  16. https://doi.org/10.1016/j.bbalip.2018.08.010
  17. https://www.nature.com/articles/s41392-020-00443-w
  18. https://pmc.ncbi.nlm.nih.gov/articles/PMC6052663/
  19. https://www.ahajournals.org/doi/10.1161/ATVBAHA.110.207449
  20. https://pmc.ncbi.nlm.nih.gov/articles/PMC3081099/
  21. https://pmc.ncbi.nlm.nih.gov/articles/PMC1174970/
  22. https://www.guidetopharmacology.org/GRAC/FamilyIntroductionForward?familyId=58
  23. https://pubmed.ncbi.nlm.nih.gov/11264472/
  24. https://pmc.ncbi.nlm.nih.gov/articles/PMC209534/
  25. https://www.rndsystems.com/products/iloprost_2038
  26. https://www.sciencedirect.com/science/article/abs/pii/S001429991001232X
  27. https://pmc.ncbi.nlm.nih.gov/articles/PMC7991060/
  28. https://pmc.ncbi.nlm.nih.gov/articles/PMC2734959/
  29. https://pmc.ncbi.nlm.nih.gov/articles/PMC2857774/
  30. https://pmc.ncbi.nlm.nih.gov/articles/PMC11983541/
  31. https://pmc.ncbi.nlm.nih.gov/articles/PMC3249979/
  32. https://pubmed.ncbi.nlm.nih.gov/215463/
  33. https://pmc.ncbi.nlm.nih.gov/articles/PMC1974901/
  34. https://pubmed.ncbi.nlm.nih.gov/30969639/
  35. https://pubmed.ncbi.nlm.nih.gov/27015081/
  36. https://pmc.ncbi.nlm.nih.gov/articles/PMC3095374/
  37. https://www.ahajournals.org/doi/10.1161/01.cir.0000128046.54681.97
  38. https://www.mdpi.com/1422-0067/22/21/11644
  39. https://www.researchgate.net/publication/22772196_A_possible_role_of_thromboxane_A2_TXA2_and_prostacyclin_PGI2_in_circulation
  40. https://www.pnas.org/doi/10.1073/pnas.0603235103
  41. https://pmc.ncbi.nlm.nih.gov/articles/PMC4481126/
  42. https://pmc.ncbi.nlm.nih.gov/articles/PMC6556106/
  43. https://pubmed.ncbi.nlm.nih.gov/7000774/
  44. https://pubmed.ncbi.nlm.nih.gov/1885782/
  45. https://pubmed.ncbi.nlm.nih.gov/36370807/
  46. https://www.pnas.org/doi/10.1073/pnas.0406142101
  47. https://aacrjournals.org/cancerpreventionresearch/article/1/4/241/46421/NAD-Dependent-15-Hydroxyprostaglandin
  48. https://pubmed.ncbi.nlm.nih.gov/11907186/
  49. https://pmc.ncbi.nlm.nih.gov/articles/PMC4281586/
  50. https://pmc.ncbi.nlm.nih.gov/articles/PMC9414732/
  51. https://hmdb.ca/metabolites/HMDB0010199
  52. https://www.jlr.org/content/60/6/1164.full.pdf
  53. https://pmc.ncbi.nlm.nih.gov/articles/PMC10821610/
  54. https://doi.org/10.1016/0090-6980(87)90023-2
  55. https://www.ogmagazine.org.au/16/2-16/prostaglandins/
  56. https://www.ncbi.nlm.nih.gov/books/NBK547742/
  57. https://www.ncbi.nlm.nih.gov/books/NBK539873/
  58. https://www.nejm.org/doi/full/10.1056/NEJMoa020204
  59. https://www.ncbi.nlm.nih.gov/books/NBK540978/
  60. https://pubmed.ncbi.nlm.nih.gov/7716179/
  61. https://www.tandfonline.com/doi/full/10.1517/13543780902893051
  62. https://www.sciencedirect.com/science/article/abs/pii/S1043661821005612
  63. https://www.jci.org/articles/view/15528
  64. https://respiratory-research.biomedcentral.com/articles/10.1186/s12931-018-0893-x
  65. https://pmc.ncbi.nlm.nih.gov/articles/PMC516261/
  66. https://www.cell.com/cell-metabolism/fulltext/S1550-4131(05)00233-0
  67. https://pmc.ncbi.nlm.nih.gov/articles/PMC7760298/
  68. https://www.mdpi.com/1660-4601/17/4/1191
  69. https://respiratory-research.biomedcentral.com/articles/10.1186/s12931-023-02559-3
  70. https://bpspubs.onlinelibrary.wiley.com/doi/10.1111/bph.15206
  71. https://www.nobelprize.org/prizes/medicine/1970/euler/lecture/
  72. https://www.nobelprize.org/uploads/2018/06/bergstrom-lecture.pdf
  73. https://www.nobelprize.org/prizes/medicine/1982/ceremony-speech/
  74. https://pubmed.ncbi.nlm.nih.gov/14201168/
  75. https://www.nature.com/articles/newbio231232a0
  76. https://www.cell.com/cell-stem-cell/fulltext/S1934-5909(25)00192-4
Add your contribution
Related Hubs
User Avatar
No comments yet.