Your search keyword '"Prostaglandin D2 physiology"' showing total 8 results

1. The role of mast cell in inflammation.

Author

Yamazaki A, Nakamura T, Omori K, and Murata T

Subjects

Animals, Capillary Permeability physiology, Histamine physiology, Mice, Neovascularization, Pathologic physiopathology, Prostaglandin D2 physiology, Inflammation physiopathology, Mast Cells physiology

Published

2017

2. [Role of cutaneous prostaglandin D2 production on scratching dermatitis in mice].

Author

Arai I

Subjects

Animals, Dermatitis, Atopic diagnosis, Dermatitis, Atopic psychology, Drug Design, Mice, Prostaglandin D2 biosynthesis, Pruritus diagnosis, Pruritus psychology, Receptors, Prostaglandin agonists, Receptors, Prostaglandin physiology, Behavior, Animal physiology, Dermatitis, Atopic drug therapy, Dermatitis, Atopic etiology, Prostaglandin D2 physiology, Pruritus drug therapy, Pruritus etiology

Published

2006

3. [Prostaglandin D2 in allergy: PGD2 has dual receptor systems].

Author

Hirai H

Subjects

Animals, Humans, Mice, Hypersensitivity physiopathology, Prostaglandin D2 physiology, Receptors, Immunologic, Receptors, Prostaglandin physiology

Abstract

Allergic inflammations feature an accumulation of T helper 2 (Th2) cells, eosinophils, and basophils into the inflamed sites and are often triggered by antigen-IgE mediated activation of mast cells that secret a variety of mediators. Therefore, the mast cell is known as a conductor cell in allergic inflammations. Prostaglandin (PG) D(2) is the major prostanoid secreted from the activated mast cell and has long been implicated in allergic diseases. The involvement of PGD(2) in allergic inflammation has been corroborated by several studies. Two PGD(2) receptors are known as the DP receptor and CRTH2. CRTH2 differs from DP in its signal pathways: CRTH2 is coupled with Gi-type G protein and DP is coupled with Gs-type G protein. It was reported that DP-deficient mice subjected to ovalbumin-induced asthma model systems showed suppressed allergic reactions. Functions of CRTH2 in vivo have not been clear, but CRTH2 mediates PGD(2)-dependent cell migration and the activation of Th2 cells, eosinophils, and basophils. Therefore, the CRTH2 signal seems to promote allergic disease. The findings from these in vivo and vitro studies suggest that PGD(2) secreted from activated mast cells may be involved in the formation and/or maintenance of allergic inflammations through its dual receptor systems.

Published

2004

4. [PGD(2)/L-PGDS system in hypertension and renal injury].

Author

Uehara Y

Subjects

Animals, Diabetes Mellitus physiopathology, Humans, Lipocalins, Rats, Hypertension physiopathology, Intramolecular Oxidoreductases physiology, Kidney Diseases physiopathology, Prostaglandin D2 physiology

Abstract

Prostaglandin D(2) (PGD(2)) and its metabolites bind to the intracellular PPARs to regulate vasoactive substances involved in vascular remodeling through regulation of mRNAs transcription as well as through receptor-mediated mechanisms. PGD(2) decreases inducible NO, PAI-1, endothelin, and VCAM expression through inhibition to NF kappa B, STAT, or AP-1 transcription factors, which are regulated by cytokines/immune system. Moreover, transfer of L-PGDS (PGD(2) synthase) into the intracellular space of EC or SMC increases intracellular PGD(2), thereby decreasing these substances. PGD(2) attenuates in vivo organ injury mediated by cytokines and the immune system. The pretreatment with PGD(2) attenuates the liver damage and hemodynamic collapse following LPS. Dahl salt-sensitive rats, with decreased PGD(2) in the outer medulla of the kidney, are prone to hypertensive kidney injury. Serum L-PGDS level is increased in renal dysfunction through a decrease in glomerular filtration. L-PGDS in urine may be derived from a failure of tubular reabsorption or from in situ synthesis. Urinary L-PGDS excretion markedly increases in the early stage of kidney injury, and urinary L-PGDS is a useful predictor of the forthcoming renal injury. Indeed, urinary L-PGDS precedes clinically overt proteinuria or other parameters indicating renal dysfunction in hypertension, primary renal diseases, and diabetes in humans. PGD(2)/L-PGDS system is a Cinderella of vascular biology.

Published

2004

5. [The roles of the prostanoids played in the body].

Author

Ushikubi F and Narumiya S

Subjects

Animals, Asthma etiology, Dinoprostone physiology, Drug Design, Epoprostenol physiology, Fever etiology, Humans, Inflammation Mediators, Myocardial Reperfusion Injury prevention & control, Platelet Activation, Prostaglandin D2 physiology, Receptors, Prostaglandin physiology, Thrombosis etiology, Prostaglandins physiology

Abstract

The actions of prostanoids in various physiological and pathophysiological conditions have been examined using mice lacking the prostanoid receptors. PGD2 was found to be a mediator of allergic asthma. Prostaglandin (PG) I2 worked not only as a mediator of inflammation but also as an antithrombotic and cardio-protective agent. Several important actions of PGE2 are brought out via the PGE2-receptor subtype EP3; PGE2 participated in the regulation of platelet function, and it worked as a mediator of febrile responses to both endogenous and exogenous pyrogens. These novel findings on the roles of the prostanoids would contribute to the development of drugs targeting the prostanoid receptors.

Published

2002

6. [Inflammation-allergy and prostanoids. (2). The role of prostanoids in allergic inflammation].

Author

Tanaka H and Nagai H

Subjects

Animals, Asthma etiology, Bronchial Hyperreactivity etiology, Cytokines metabolism, Humans, Hypersensitivity, Immediate etiology, Mast Cells physiology, Prostaglandin D2 physiology, Hypersensitivity etiology, Inflammation etiology, Prostaglandins physiology

Abstract

Allergic inflammation is orchestrated by mainly antigen-specific CD4+ T cells, eosinophils and mast cells, which is a characteristic feature of bronchial asthma, rhinitis and atopic dermatitis. Prostanoids are one of the arachidonic metabolites, which are produced by a variety of inflammatory cells upon stimulation and are thought to be involved in the pathogenesis of diseases as well as the regulation of homeostasis. We investigated the role of a prostanoid, prostaglandin D2 (PGD2), in the pathogenesis of allergic bronchial asthma using its receptor, DP, gene-deficient mice. We found that the disruption of the DP gene attenuated the allergen-induced airway eosinophilic inflammation, Th2 type cytokine production and bronchial hyperresponsiveness to cholinergic stimuli, suggesting that PGD2 is an important mediator of allergic asthma. In contrast, the treatment of non-steroidal anti-inflammatory agents, which are known to be inhibitors of cyclooxygenases, did not inhibit or instead exaggerated these responses in asthmatics or experimental animal models, indicating that there are regulatory prostanoids in allergic inflammation. Recently, strategies of gene manipulation such as the "knockout" or "transgenic" techniques are important means to understand the role of a certain functional molecule. These approaches and the development of their antagonists/inhibitors could help us to understand the function of prostanoids in the pathophysiology of allergic disorders.

Published

2001

7. [Molecular and neuroanatomical mechanisms of sleep-wakefulness regulation by prostaglandins D2 and E2].

Author

Onoe H

Subjects

Animals, Brain physiology, Dinoprostone physiology, Prostaglandin D2 physiology, Sleep physiology, Wakefulness physiology

Abstract

Prostaglandin (PG) s D2 and E2 are the major arachidonic acid metabolites in the mammalian brain. PGD synthase, the enzyme that produces PGD2 in the brain, is mainly localized in the arachnoid membrane and choroid plexus. It is secreted into the cerebrospinal fluid and circulates in the brain through the ventricular system. PGD2 induces sleep by acting on the surface of the ventro-medial region of the rostral basal forebrain, the signal of which is probably transmitted into the brain parenchyma by adenosine via adenosine A2a receptors. Fos expression experiments suggest that PGD2 inhibits histaminergic arousal neurons of the tuberomammillary nucleus (TMN) in the posterior hypothalamus by activating inhibitory neurons in the ventrolateral preoptic area (VLPO). However, PGE2 causes wakefulness by activating arousal neurons in the TMN via AMPA type excitatory amino acid receptors. Therefore, PGD2, acting as a sleep-inducer, and PGE2, acting as a wakefulness-promoter, jointly regulate the generation of sleep and wakefulness in the mammalian brain.

Published

1998

8. [New aspects on prostaglandin D synthases].

Author

Urade Y

Subjects

Animals, Binding Sites, Biological Transport, Carrier Proteins, Central Nervous System enzymology, Glutathione metabolism, Glutathione Transferase, Humans, Immune System enzymology, Lipocalins, Prostaglandin D2 physiology, Tretinoin metabolism, Intramolecular Oxidoreductases classification, Intramolecular Oxidoreductases pharmacology, Intramolecular Oxidoreductases physiology

Abstract

Prostaglandin (PG) D2 is a major prostanoid produced in the central nervous system and mast cells, acting as a neuromodulator and an allergic and inflammatory mediator. PGD2 is readily dehydrated to produce PGs of the J series, such as PGJ2, delta 12-PGJ2, and 15-deoxy-delta 12, 14-PGJ2. We identified two distinct types of PGD synthase: one is glutathione independent, the lipocalin-type enzyme; and the other is glutathione-dependent, the hematopoietic enzyme. Lipocalin-type PGD synthase is localized in the central nervous system and genital organs, dominantly produced in the leptomeninges of the brain and pigmented epithelium of the retina, and is actively secreted as beta-trace into the cerebrospinal fluid and interphotoreceptor matrix, respectively. Since the enzyme binds all-trans- or 9-cis-retinoic acid with Kd of about 100 nM, it is considered to be a bifunctional protein acting as a PGD2-producing enzyme and an extracellular retinoid-transporter. Alternatively, we recently cloned the cDNA for hematopoietic PGD synthase, crystallized the recombinant enzyme, and determined the three-dimensional structure. The enzyme is the first member of the sigma class glutathione S-transferase (GST) from vertebrates and possesses a prominent cleft as the active site, which is never seen among other members of the GST family.

Published

1997