Functional and molecular characterization of prostaglandin E2 dilatory receptors in the rat craniovascular system in relevance to migraine.

INTRODUCTION: Migraine pain is thought to involve an increase in trigeminal nerve terminal activity around large cerebral and meningeal arteries, leading to vasodilatation. Because prostaglandin E(2) (PGE(2)) is elevated in cephalic venous blood during migraine attacks, and is also capable of inducing headache in healthy volunteers, we hypothesize that PGE(2) dilatory receptors, EP(2) and EP(4), mediate the response. MATERIALS AND METHODS: By the use of specific agonists and antagonists, the dilatory effect of PGE(2) was characterized in rat cranial arteries by use of in vivo and in vitro methods. Furthermore, EP(2) and EP(4) quantitative messenger RNA (mRNA) receptor expression was studied in the rat craniovascular system. RESULTS: Our results suggest that EP(4), and to a lesser degree EP(2), receptors mediate the dilatory effect of PGE(2) in the craniovascular system in rats. Thus, antagonism of these receptors might be of therapeutic relevance in migraine.

The human placenta--an alternative for studying foetal exposure.

Pregnant women are daily exposed to a wide selection of foreign substances. Sources are as different as lifestyle factors (smoking, daily care products, alcohol consumption, etc.), maternal medication or occupational/environmental exposures. The placenta provides the link between mother and foetus, and though its main task is to act as a barrier and transport nutrients and oxygen to the foetus, many foreign compounds are transported across the placenta to some degree and may therefore influence the unborn child. Foetal exposures to environmental and medicinal products may have impact on the growth of the foetus (e.g. cigarette smoke) and development of the foetal organs (e.g. methylmercury and thalidomide). The scope of this review is to give insight to the placental anatomy, development and function. Furthermore, the compounds physical properties and the transfer mechanism across the placental barrier are evaluated. In order to determine the actual foetal risk from exposure to a chemical many studies regarding the topic are necessary, including means of transportation, toxicological targets and effects. For this purpose several in vivo and in vitro models including the placental perfusion system are models of choice.

Biglycan potentially regulates angiogenesis during fracture repair by altering expression and function of endostatin.

The small proteoglycan biglycan (Bgn) is highly expressed in the organic matrix of bone and plays a role in bone formation. Previous work implicated Bgn in vessel growth during bone healing [1]. By infusing barium sulfate (BaSO4) into WT and Bgn-deficient mice we discovered the positive effect of Bgn in modulating angiogenesis during fracture healing. Using micro-computed tomography angiography we found significant differences in the vessel size and volume among other parameters. To further understand the mechanistic basis for this, we explored the relationship between Bgn and the anti-angiogenic protein endostatin. Immunohistochemistry (IHC) showed co-localization of Bgn and endostatin in regions of bone formation, with increased endostatin staining in Bgn-KO compared to WT at 14days post-fracture. To further elucidate the relationship between Bgn and endostatin, an endothelial cell tube formation assay was used. This study showed that endothelial cells treated with endostatin had significantly decreased vessel length and vessel branches compared to untreated cells, while cells treated with endostatin and Bgn at a 1:1M ratio had vessel length and vessel branches comparable to untreated cells. This indicated that Bgn was able to mitigate the inhibitory effect of endostatin on endothelial cell growth. In summary, these results suggest that Bgn is needed for proper blood vessel formation during fracture healing, and one mechanism by which Bgn impacts angiogenesis is through inhibition of endostatin.

Prostaglandin E2 receptor expression in the rat trigeminal-vascular system and other brain structures involved in pain.

Prostaglandin E(2) (PGE(2)) is considered to be a key mediator in migraine pathophysiology. PGE(2) acts via four receptors (EP(1)-EP(4)) but their distribution in the brain districts implicated in migraine has yet to be delineated. We quantified amount of mRNA and protein expression for the EP receptors in both peripheral and central structures involved in pain transmission and perception in migraine: dura mater, cerebral arteries, trigeminal ganglion, trigeminal nucleus caudalis, periaqueductal grey, thalamus, hypothalamus, cortex, pituitary gland, hippocampus and cerebellum. In the trigeminal-vascular system (TVS) we found highest expression of EP(1) and EP(2) protein in the trigeminal nucleus caudalis. EP(3) and EP(4) mRNA expression were highest in the trigeminal ganglion. Within intracranial structures EP(1) mRNA and protein expression were significantly higher in pituitary gland and cerebellum than in dorsal root ganglia (peripheral control), whereas the EP(2) mRNA and protein were highly abundant in the pituitary gland. EP(3) mRNA was mainly found in thalamus and hypothalamus. The most robust mRNA and protein expression for EP(4) receptor was seen in the dorsal root ganglion. In conclusion, all four receptors are located in areas implicated in migraine supporting the possible involvement of PGE(2) in this disease.

Pharmacological and expression profile of the prostaglandin I(2) receptor in the rat craniovascular system.

Activation of the trigeminal nerve terminals around cerebral and meningeal arteries is thought to be an important patho-mechanism in migraine. Vasodilatation of the cranial arteries may also play a role in increasing nociception. Prostaglandin I(2) (PGI(2)) is capable of inducing a headache in healthy volunteers, a response that is likely to be mediated by the prostaglandin I(2) receptor (IP). This study investigates the functional and molecular characteristics of the IP receptor in the rat craniovascular system. In the closed cranial window model, iloprost, an IP receptor agonist, dilated the rat middle meningeal artery (MMA) (E(max)=170%±16%; pED(50)=6.5±0.2) but not the rat cerebral artery (CA) in vivo. The specific antagonist of the IP receptor, CAY10441, significantly blocked the iloprost-induced response dose-dependently, with the highest dose attenuating iloprost (1µgkg(-1)) induced dilatations by 70% (p<0.05). CAY10441 did not have any effect on the prostaglandin E(2)-induced vasodilatory response, thus suggesting no interaction with EP(2) and EP(4) receptors. IP receptor mRNA transcripts and protein were present in meningeal as well as in cerebral rat vasculature, and localized the IP receptor protein to the smooth vasculature of the cranial arteries (MMA, MCA and basilar artery). Together, these results demonstrate that the IP receptor mediates the dilatory effect of PGI(2) in the cranial vasculature in rats. Antagonism of this receptor might be of therapeutic relevance in acute migraine treatment.

IL-20 is an arteriogenic cytokine that remodels collateral networks and improves functions of ischemic hind limbs.

Successful therapeutic angiogenesis for the treatment of ischemic disorders relies on selection of optimal proangiogenic or arteriogenic agents that are able to promote establishment of functional collateral networks. Here, we show that IL-20, a pleiotropic inflammatory cytokine, displays an imperative effect on vascular remodeling. Stimulation of both large and microvascular endothelial cells with IL-20 leads to activation of receptor-dependent multiple intracellular signaling components, including increased phosphorylation levels of JAK2/STAT5, Erk1/2, and Akt; activation of small GTP-binding proteins Rac and Rho; and intracellular release of calcium. Surprisingly, IL-20 significantly promotes endothelial cell tube formation without affecting their proliferation and motility. These findings suggest that the vascular function of IL-20 involves endothelial cell organization, vessel maturation, and remodeling. Consistent with this notion, delivery of IL-20 to the ischemic muscle tissue significantly improves arteriogenesis and blood perfusion in a rat hind-limb model. Our findings provide mechanistic insights on vascular functions of IL-20 and define therapeutic implication of this cytokine for the treatment of ischemic disorders.