It is currently believed that prostaglandin (PG) of E2 type plays a crucial role in transferring the information received from circulating immune factors to brain parenchymal cells. Although PGE2 is synthesized quite essentially by cells of the blood-brain barrier, the organization and regulation of its receptor subtypes within neuronal elements remain unknown. In this study, intravenous (i.v.) injection of the endotoxin lipopolysaccharide (LPS) or recombinant rat interleukin-1beta (IL-1beta), and intramuscular (i.m.) injection of turpentine were used as different models of systemic immune stimuli. Rats were perfused at various times after the insults (30 min to 24 h), their brains cut and hybridized with full-length rat cRNA probes. Double-labelling procedures were accomplished to determine the cellular phenotype and activity. A very distinct distribution of both EP2 and EP4 receptors was found across the brain under basal conditions; the hybridization signal for the type 2 was detected in the bed nucleus of the stria terminalis (BNST), lateral septum, subfornical organ (SFO), ventromedial hypothalamic nucleus (VMH), central nucleus of the amygdala (CeA), locus coeruleus (LC) and the area postrema (AP), whereas the ventral septal/anterior preoptic area, the magnocellular paraventricular nucleus (PVN), supraoptic nucleus, parabrachial nucleus, LC, the nucleus of the solitary tract (NTS) and the ventrolateral medulla (VLM) exhibited moderate to strong levels for the EP4 mRNA under basal conditions. Upregulation of the genes encoding EP2 and EP4 receptors was detected in selective regions and neuronal populations during systemic inflammatory challenges. The most dramatic one being the robust transcriptional activation of the EP4 subtype within corticotropin-releasing factor (CRF) neurons of the parvocellular PVN following i.v. LPS and IL-1beta injection, and the localized i.m. aggression. These neurons of the endocrine hypothalamus as well as those of numerous autonomic-related nuclei were activated by the proinflammatory cytokine, as they were immunoreactive (ir) to Fos nuclear protein. The EP4 transcript was also present in activated catecholaminergic neurons of the LC, NTS and VLM, although only the A1 cell group exhibited an increase in EP4 transcription in response to circulating IL-1beta. Moreover, the systemic immunogenic insults caused a significant increase in the EP2 mRNA levels in the CeA, SFO, AP and the leptomeninges. These data provide a distinct pattern of EP2 and EP4 expression throughout the rat brain under both basal and immune-challenged conditions, and underlie the possible role of the EP4 subtype in mediating the effects of PGE2 on different autonomic and neuroendocrine functions. The presence of Fos-ir nuclei in various populations of EP4 neurons of IL-1beta-treated animals clearly supports this concept and suggests that the selectivity of the neuronal response during systemic inflammation may depend on the expression of specific PGE2 receptors in key structures of the brain.
Mice are widely used to study arterial disease in humans, and the pathogenesis of arterial diseases is known to be strongly influenced by hemodynamic factors. It is, therefore, of interest to characterize the hemodynamic environment in the mouse arterial tree. Previous measurements have suggested that many relevant hemodynamic variables are similar between the mouse and the human. Here we use a combination of Doppler ultrasound and MRI measurements, coupled with numerical modeling techniques, to characterize the hemodynamic environment in the mouse aortic arch at high spatial resolution. We find that the hemodynamically induced stresses on arterial endothelial cells are much larger in magnitude and more spatially uniform in the mouse than in the human, an effect that can be explained by fluid mechanical scaling principles. This surprising finding seems to be at variance with currently accepted models of the role of hemodynamics in atherogenesis and the known distribution of atheromatous lesions in mice.
Recent studies have demonstrated the feasibility of transplanting fetal mouse cardiomyocytes into the hearts of adult syngeneic mice. However, the function of the transplanted cardiomyocytes and their capacity to survive in fibrous connective tissue were not assessed. In the present study, we evaluated the viability and contractility of transplanted fetal and neonatal rat cardiomyocytes in the connective tissue of the adult rat hindlimb. Purified fetal or neonatal rat cardiomyocytes were cultured. These cells contained sarcomeres, formed junctions composed of desmosomes and fascia adherens, and contracted regularly and spontaneously. A fetal or neonatal cardiomyocyte suspension was injected into the subcutaneous tissue of adult rat hindlimbs. Cyclosporin A (5 mg/kg) was administered subcutaneously daily for the 3-month duration of the study, at which time the animals were killed. The transplanted cardiomyocytes formed 'tissue' in vivo that increased in size for the first 2 weeks and remained the same size at the third week. The tissue derived from the transplanted fetal cardiomyocytes contracted spontaneously at a rate of 73 +/- 12 bpm, and that from the neonatal cardiomyocytes contracted at a rate of 43 +/- 21 bpm. The electrocardiogram was similar to that seen in myocardium with an idioventricular rhythm. Histologically, the tissue appeared to be cardiac muscle with sarcomeres. Angiogenesis occurred in the cardiomyocyte graft. In summary, a cell suspension of cultured fetal and neonatal rat cardiomyocytes transplanted into the adult rat hindlimb formed contractile cardiac tissue in the subcutaneous connective tissue.
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