Effects of prostaglandin E2 on cells cultured from the rat organum vasculosum laminae terminalis and median preoptic nucleus.

The time course of the induction of enzymes responsible for the formation of prostaglandin E2 (PGE2) after an inflammatory insult, in relation to the concomitant febrile response, suggests that peripherally generated PGE2 is involved in the induction of the early phase of fever, while centrally produced PGE2 exerts pyrogenic capacities during the later stages of fever within the hypothalamic median preoptic nucleus (MnPO). The actions of peripherally derived PGE2 on the brain might occur at the level of the organum vasculosum laminae terminalis (OVLT), which lacks a tight blood-brain barrier and is implicated in fever, while the effects of PGE2 within the MnPO might interfere with glutamatergic neurotransmission within a recently characterized central efferent pathway for the activation of cold-defence reactions. Using the fura-2 ratio imaging technique we, therefore, measured changes of the intracellular Ca(2+)-concentration in primary neuroglial microcultures of rat OVLT and MnPO stimulated with PGE2 and/or glutamate. In cultures from the OVLT, as opposed to those derived from the MnPO, substantial numbers of neurons (8% of 385), astrocytes (19% of 645) and microglial cells (28% of 43) directly responded to PGE2 with a transient increase of intracellular Ca(2+). The most pronounced effect of PGE2 on cells from MnPO microcultures was its modulatory influence on the strength of glutamate-induced Ca(2+)-signals. In 72 out of 512 neurons and in 105 out of 715 astrocytes PGE2 significantly augmented glutamate-induced Ca(2+)-signals. About 30% of these neurons were GABAergic. These observations are in agreement with putative roles of peripheral PGE2 as a directly acting circulating agent at the level of the OVLT, and of central MnPO-intrinsic PGE2 as an enhancer of glutamatergic neurotransmission, which causes disinhibition of thermogenic heat production, a crucial component for the manifestation of fever. In microcultures from both brain sites investigated incubation with PGE2 significantly reduced the lipopolysaccharide-induced release of cytokines (tumor necrosis factor-α and interleukin-6) into the supernatant. PGE2, thus, seems to be involved in a negative feed-back loop to limit the strength of the brain inflammatory process and to play a dual role with pro- as well as anti-inflammatory properties.

Intraperitoneal and subcutaneous injections of the TLR9 agonist ODN 1668 in rats: brain inflammatory responses are related to peripheral IL-6 rather than interferons.

Subcutaneous or intraperitoneal administration of Toll-like receptor (TLR)-9 agonist, ODN 1668 caused moderate fever and anorexia. In comparison to stimulation of other intracellular TLRs, activation of TLR9 did not result in pronounced peripheral induction of interferons, but rather induced interleukin-6. Expression of cytokines (TNFα, IL-1ß) and inducible forms of enzymes for prostaglandin E2 synthesis occurred in the brain, in conjunction with a moderate activation of the transcription factors STAT3 and NF-IL6 in brain endothelial cells. The lack of a septic-like state in ODN 1668-treated rats reinforces the therapeutic value of this drug.

Modulation of K2P 2.1 and K2P 10.1 K(+) channel sensitivity to carvedilol by alternative mRNA translation initiation.

BACKGROUND AND PURPOSE: The ß-receptor antagonist carvedilol blocks a range of ion channels. K2P 2.1 (TREK1) and K2P 10.1 (TREK2) channels are expressed in the heart and regulated by alternative translation initiation (ATI) of their mRNA, producing functionally distinct channel variants. The first objective was to investigate acute effects of carvedilol on human K2P 2.1 and K2P 10.1 channels. Second, we sought to study ATI-dependent modulation of K2P K(+) current sensitivity to carvedilol. EXPERIMENTAL APPROACH: Using standard electrophysiological techniques, we recorded currents from wild-type and mutant K2P 2.1 and K2P 10.1 channels in Xenopus oocytes and HEK 293 cells. KEY RESULTS: Carvedilol concentration-dependently inhibited K2P 2.1 channels (IC50 ,oocytes = 20.3 µM; IC50 , HEK = 1.6 µM) and this inhibition was frequency-independent. When K2P 2.1 isoforms generated by ATI were studied separately in oocytes, the IC50 value for carvedilol inhibition of full-length channels (16.5 µM) was almost 5-fold less than that for the truncated channel variant (IC50 = 79.0 µM). Similarly, the related K2P 10.1 channels were blocked by carvedilol (IC50 ,oocytes = 24.0 µM; IC50 , HEK = 7.6 µM) and subject to ATI-dependent modulation of drug sensitivity. CONCLUSIONS AND IMPLICATIONS: Carvedilol targets K2P 2.1 and K2P 10.1 K(+) channels. This previously unrecognized mechanism supports a general role of cardiac K2P channels as antiarrhythmic drug targets. Furthermore, the work reveals that the sensitivity of the cardiac ion channels K2P 2.1 and K2P 10.1 to block was modulated by alternative mRNA translation initiation.

Fever, sickness behavior, and expression of inflammatory genes in the hypothalamus after systemic and localized subcutaneous stimulation of rats with the Toll-like receptor 7 agonist imiquimod.

The Toll-like receptor 7 (TLR7) agonist imiquimod is used for topical treatment of skin cancers. We studied the consequences of injections of imiquimod into a subcutaneous (s.c.) air pouch or of intraperitoneal (i.p.) injections on the manifestation of fever, sickness behavior, and the peripheral and brain-intrinsic induction of a variety of inflammatory molecules. Rats were given imiqimod s.c. or i.p. (1 or 5 mg/kg). Body temperature, motor activity, and food and water intake were recorded by telemetric devices. Peripheral and brain-intrinsic induction of inflammatory mediators was analyzed by real-time polymerase chain reaction (RT-PCR), bioassays, enzyme-linked immunosorbent assays (ELISAs), and immunohistochemistry. Imiquimod is the first TLR-agonist to produce more potent effects with s.c. than i.p. administration. Peripheral induction of interferons (IFNs) and putative circulating pyrogens corresponded to the magnitude of the illness responses. In the brain, an expression of cytokines (TNFα, IL-1ß, and IL-6) and inducible forms of enzymes for prostaglandin E2 synthesis (COX-2 and mPGES) occurred, which was accompanied by a moderate activation of the transcription factors NFκB and STAT3, and a strong activation of the transcription factor NF-IL6, in cells of specific areas with an open blood-brain barrier. These inflammatory responses noted within the brain were more marked after s.c. administration, than i.p. administration of imiquimod. At a dose of 5 mg/kg, imiquimod causes rather moderate brain-inflammatory responses, which are related to peripheral IFN-expression and possibly mediated by brain-intrinsic activation of NF-IL6 and induction of a proinflammatory cocktail. The lack of a septic-like state in imiquimod-treated rats reinforces the therapeutic use of this drug.

Co-expression studies of the orphan carrier protein Slc10a4 and the vesicular carriers VAChT and VMAT2 in the rat central and peripheral nervous system.

The orphan carrier protein Slc10a4 represents a novel member of the so-called "sodium-bile acid co-transporter family," SLC10. Slc10a4 has a close phylogenetic relationship with the liver bile acid carrier Ntcp (Slc10a1), but has no transport activity for bile acids. In a previous study Slc10a4 proved to be predominantly expressed in the rat brain, where it was localized within cholinergic neurons. However, whether this cholinergic expression pattern was exclusive for Slc10a4 and whether this protein might also be expressed in the peripheral nervous system or other peripheral organs, remained unclear. Therefore, in the present study we analyzed the expression of Slc10a4 in neuronal and non-neuronal rat tissues more systematically, employing immunofluorescence co-localization studies of the vesicular acetylcholine transporter VAChT and the vesicular monoamine transporter VMAT2. The Slc10a4 protein was found to be widely expressed throughout structures of the CNS and peripheral nervous system. In addition to cholinergic neurons in the CNS, the retina, the neuromuscular junction and parasympathetic innervations, Slc10a4 was also localized in certain monoaminergic neurons and nerve fibers in the substantia nigra, the spinal cord and sympathetic innervations. Slc10a4 expression was also detected in granules of rat peritoneal and tissue mast cells using immunofluorescence and electron microscopy. Western blot and immunoprecipitation experiments with rat brain vesicle preparations revealed that the Slc10a4 protein was expressed in synaptic vesicles where it co-localized with synaptophysin, VAChT and VMAT2. This vesicular expression pattern was also shown in the rat adrenal pheochromocytoma cell line PC12 by immunofluorescence. Based on the findings of the present study we can speculate about the function of Slc10a4 as follows: (I) Slc10a4 could be a novel vesicular transporter for cholinergic and/or various monoaminergic neurotransmitters in the central and peripheral nervous system or (II) may be involved in the regulation of the synaptic vesicle sorting or exocytosis process.

Effects of repeated injections of fibroblast-stimulating lipopeptide-1 on fever, formation of cytokines, and on the responsiveness to endotoxin in guinea-pigs.

AIMS: We investigated, whether the Toll-like receptors (TLRs)-2/6-agonist fibroblast-stimulating lipopeptide-1 (FSL-1), like the TLR-4 agonist lipopolysaccharide (LPS), induces a state of tolerance. We further tested the influence of repeated pre-treatment with FSL-1 on the animals' responsiveness to LPS. METHODS: Abdominal temperature was recorded in unrestrained guinea-pigs with intra-abdominally implanted radiotransmitters. Circulating concentrations of tumour necrosis factor (TNF) and interleukin-6 (IL-6) were measured with specific bioassays. We tested the effects of intra-arterial (i.a.) or intraperitoneal (i.p.) injections of 100 microg kg(-1) FSL-1, repeated five times at intervals of 3 days. The animals' responses to i.a. or i.p. injections of 10 microg kg(-1) LPS were determined another 3 days later and compared to those of naïve guinea-pigs. RESULTS: The FSL-1-induced TNF peak was significantly attenuated starting with the third i.a. administration, while fever was unimpaired and the IL-6-peak just tended to decrease. Fever and IL-6 in response to i.a. injections of LPS were identical in both groups, while circulating TNF was higher in naïve compared to FSL-1 pre-treated animals. The effects of repeated i.p. injections of FSL-1 were more pronounced resulting in attenuation of fever as well as circulating TNF and IL-6, the strongest reduction observed after the third stimulation with FSL-1. Repeated i.p. pre-treatment with FSL-1 induced hyporesponsiveness to i.p. administration of LPS compared to naïve animals with regard to fever and especially with regard to LPS-induced formation of cytokines. CONCLUSIONS: There is a development of tolerance to FSL-1 and cross-tolerance between FSL-1 and LPS depending on the route of administration of the respective TLR-2/6 and TLR-4 agonists.

Cloning and molecular characterization of the orphan carrier protein Slc10a4: expression in cholinergic neurons of the rat central nervous system.

We report on the cloning and molecular characterization of the rat carrier Slc10a4 and its cellular localization in the CNS by immunohistochemistry. Slc10a4 is the rat counterpart of the human orphan carrier SLC10A4, which was recently reported to be highly expressed in brain and placenta. Both carriers belong to the solute carrier family SLC10, formerly named the "sodium/bile acid cotransporter family." So SLC10A4/Slc10a4 has a phylogenetic relationship to the Na+/taurocholate cotransporting polypeptide Ntcp (Slc10a1) and the apical sodium-dependent bile acid transporter Asbt (Slc10a2). The rat Slc10a4 protein consists of 437 amino acids and exhibits a seven transmembrane domain topology with N(exo)/C(cyt)trans-orientation of the N- and C-terminal ends. Expression of the Slc10a4 protein was detected in motor regions of the spinal cord and rhombencephalon, as well as in mesopontine cholinergic neurons, the medial habenula, cholinergic areas of the forebrain, and the gut myenteric plexus. Co-localization studies with the cholinergic marker proteins choline acetyltransferase (ChAT), vesicular acetylcholine transporter (VAChT), and high-affinity choline transporter (CHT1) demonstrated expression of Slc10a4 in cholinergic neurons. Despite its close phylogenetic relationship to Ntcp, Slc10a4 showed no transport activity for the Ntcp substrates taurocholate, estrone-3-sulfate, dehydroepiandrosterone sulfate, and pregnenolone sulfate when expressed in HEK293 cells or Xenopus laevis oocytes. Slc10a4 also did not transport choline, which is a substrate of CHT1. Although the functional properties of Slc10a4 could not be elucidated in this study, Slc10a4 is regarded as a new marker protein for cholinergic neurons in the rat CNS.

Fever and circulating cytokines induced by double-stranded RNA in guinea pigs: dependence on the route of administration and effects of repeated injections.

AIMS: The aim of this study was to characterize the properties of synthetic double-stranded RNA to induce fever and circulating cytokines in guinea pigs with special emphasis on the route of administration and on a putative development of tolerance to this pyrogen. METHODS: Changes in abdominal temperature were recorded in unrestrained animals by use of intra-abdominally implanted radiotransmitters. Circulating concentrations of tumour necrosis factor-alpha (TNF-alpha) and interleukin-6 (IL-6) were measured by use of specific bioassays. RESULTS: The pyrogenic effect of double-stranded RNA at a dose of 500 microg kg(-1) depended on the route of its administration. Intra-arterial (i.a.) or intraperitoneal injections of double-stranded RNA induced pronounced fevers and strong elevations of circulating TNF-alpha and IL-6. Intramuscular injections of the synthetic pyrogen caused rather moderate febrile and cytokine responses. Administration of synthetic RNA into artificial subcutaneously implanted Teflon chambers had no pyrogenic and cytokine-inducing effects. I.a. injections of double-stranded RNA, repeated five times at intervals of 3 days, resulted in fevers of similar shape and duration and similar cytokine response patterns. However, the strength of fever and cytokine formation was significantly reduced, although not abolished, in response to the repeated injections compared with the first injection, indicating a partial development of tolerance. CONCLUSIONS: The modulation of the strength of RNA-induced fever, dependent on the route of administration, or the state of partial tolerance to this pyrogen, may thus be related to the formation of pyrogenic cytokines.

Heat acclimation affects the neuromodulatory role of AngII and nitric oxide during combined heat and hypohydration stress.

We studied the effect of heat acclimation on the neuromodulatory role of angiotensin (AngII) and nitric oxide during combined heat (39 degrees C) and hypohydration (water deprivation, -10% body weight) stress. Rats were divided into control (C), short (2d-STHA) or long (30d-LTHA) acclimation (34 degrees C) groups. AngII, 7-nitroindazole (7NI)-nNOS blocker, or both were centrally administered (5 mul, bolus) under light chloroform anesthesia prior to each experimental paradigms: (1) In vivo: measurements of skin-vasodilatation (VTsh) and salivation-cooling (STsh) thresholds, and heat endurance in conscious heat/hypohydrated stressed rats; (2) expression of AT(1) and AT(2) AngII receptors and nNOS were measured in the hypothalamus (Western blot); (3) transcript levels of the coding genes were measured using real-time PCR. A synthesis of the results shows a biphasic acclimatory profile of VTsh, STsh, and transcript levels of all studied genes, with transient up/down-regulatory changes on STHA. AngII affected the physiological integrative outcome primarily during euhydration, although AT membranal changes (except in LTHA) were confined to hypohydration. 7NI had an impact during hypohydration. Evidence is provided that AngII and 7NI modulate thermoregulation primarily via AT(1) and AT(2) receptors, with predominance of AT(2) signaling following LTHA and/or hypohydration, opposing a drop in AT(1)-mediated thresholds. The final shaping of AngII signaling depends on cross-talk between nNOS and AngII receptors at both molecular and protein levels. Hypohydration induces transcriptional responses but desensitizes AngII receptors signaling, attenuating their effect on VTsh and STsh, and abolishing the beneficial thermoregulatory effects achieved by heat acclimation. nNOS, AngII receptor-independent pathway is also implicated.

Nitric oxide and angiotensin II: neuromodulation of thermoregulation during combined heat and hypohydration stress.

We investigated the central role of nitric oxide and AngII on thermoregulation in rats (Rattus norvegicus, Sabra strain,) undergoing heat-stress in euhydration or hypohydration (water deprivation, -10% b.wgt). Experimental rats received AngII (100 pm), 7-nitroindazole-an antagonist of neuronal nitric oxide synthase (7NI-100 nm), or AngII+7NI in a 5-microl bolus intracerebroventricularly (i.c.v.) under light chloroform anesthesia; untreated control rats received saline or DMSO (5%). We used three experimental paradigms: (1) heat defense responses [salivation (STsh), vasodilatation (VTsh) temperature thresholds and heat-endurance] in conscious, heat-stressed (39 degrees C) rats; (2) Western immunoblotting to detect AngII AT(1) and AT(2) receptors and nNOS protein expression; (3) real-time PCR to measure gene transcripts. In the in vivo experiment, 7NI decreased thermoregulatory thresholds, namely, NO had a reciprocal effect that was more pronounced during hypohydration (e.g. euhydration: STsh: -0.7+/-0.01 degrees C, hypohydration: -0.9+/-0.18 degrees C, p<0.05). AngII decreased STsh by 0.9+/-0.18 degrees C (p<0.05) upon euhydration but increased it in hypohydration (+1.7+/-0.28 degrees C, p<0.05). A novel finding was the involvement of AT(2) receptors in thermoregulation, which was more pronounced upon hypohydration. The response to NO was mediated via AT(1) and AT(2) receptors signaling, as well as independently. A synthesis of the results from all experimental paradigms suggests (1) a dominant influence (decrease) of NO on AT(1) receptors, thereby changing AT(1)/AT(2) receptor ratio and their signaling pathway; primarily upon hypohydration; (2) an influence of AngII (increase) on receptor density, more pronounced during hypohydration, at both gene transcription and translation levels; and (3) an effect of AngII on nNOS protein levels, implying a mutual effect of AngII and NO.

Astrocytes in sensory circumventricular organs of the rat brain express functional binding sites for endothelin.

Sensory circumventricular organs bordering the anterior third cerebral ventricle, the subfornical organ and the organum vasculosum laminae terminalis, lack blood-brain barrier characteristics and are therefore accessible to circulating peptides like endothelins. Astrocytes of the rat subfornical organ and organum vasculosum laminae terminalis additionally showed immunocytochemical localization of endothelin-1/endothelin-3-like peptides, possibly acting as circumventricular organ-intrinsic modulators. Employing [125I]endothelin-1 as radioligand, quantitative autoradiography demonstrated specific binding sites throughout the rat organum vasculosum laminae terminalis and subfornical organ, and competitive displacement studies revealed expression of both ET(A) and ET(B) receptor subtypes for either circumventricular organ. ET(B) receptor binding prevailed for the whole brain and ET(A) receptors could be labelled in the peripheral vascular system. To characterize endothelin-specific receptors in astrocytes of both circumventricular organs, alterations in the intracellular calcium concentration due to endothelin-1/endothelin-3 stimulation were studied in primary culture of subfornical organ and organum vasculosum laminae terminalis cells obtained from early postnatal rat pups. Endothelin-1 and endothelin-3 induced Ca(2+) transients in 9-13% of either subfornical organ or organum vasculosum laminae terminalis astrocytes, respectively, and some glial cells (subfornical organ: 2%, organum vasculosum laminae terminalis: 5%) responded to both endothelin analogues. The antagonistic action of BQ123 specific for ET(A) receptors (74% of all astrocytes tested), and the pronounced responsiveness to the ET(B) receptor agonist [4Ala]ET-1 (subfornical organ: 27%, organum vasculosum laminae terminalis: 35%) demonstrated glial expression of both endothelin receptor subtypes. Agonist-induced elevations in the intracellular calcium concentration proved to be independent of extracellular Ca(2+). In summary, the results indicate that endothelin(s) interact(s) with circumventricular organ astrocytes. Competitive receptor binding techniques using brain tissue sections as well as a fura-2 loaded primary cell culture system of the subfornical organ and organum vasculosum laminae terminalis demonstrate glial expression of functional ET(A) and ET(B) receptors, with calcium as intracellular messenger emerging primarily from intracellular stores. Endothelin(s) of both circulating and circumventricular organ-intrinsic origin may afferently transfer information important for cardiovascular homeostasis to circumventricular organs serving as "windows to the brain".

Heat acclimation and hypohydration: involvement of central angiotensin II receptors in thermoregulation.

This investigation attempted to confirm the involvement of central ANG II-ergic signals in thermoregulation. Experiments were conducted on rats undergoing short (STHA)- and long (LTHA)-term heat acclimation, with and without superimposed hypohydration. Vasodilatation (VTsh) and salivation (STsh) temperature thresholds, tail blood flow, and heat endurance were measured in conscious rats during heat stress (40 degrees C) before and after losartan (Los), an ANG II AT(1)-selective receptor antagonist, administration either to the lateral ventricle or intravenously. Heat acclimation alone resulted in decreased VTsh. STsh decreased during STHA and resumed the preacclimation value, together with markedly increased heat endurance on LTHA. Hypohydration did not affect this biphasic response, although STsh was elevated in all groups. The enhanced heat endurance attained by LTHA was blunted. Neither Los treatment affected the nonacclimated rats. In the heat-acclimated, euhydrated rats, intracerebroventricular Los resulted in decreased VTsh, whereas intravenous Los resulted in elevated STsh. Both intracerebroventricular and intravenous Los led to markedly enhanced heat endurance of the LTHA hypohydrated rats. It is concluded that the LTHA group showed a loss of the benefits acquired by acclimation on hypohydration, whereas the STHA rats, which show an accelerated autonomic excitability in that phase, gained some benefit. It is suggested that ANG II modulates thermoregulation in conditions of chronic adjustments. Central ANG II signals may lead to VTsh upshift, whereas circumventricular structures, activated via circulating ANG II, decrease STsh. On hypohydration these responses seem to be desensitized.

Central action of nitric oxide in the saltwater-acclimated duck: modulation of extrarenal sodium excretion and vasotocin release.

Hypothalamic nuclei close to the third ventricle (VIII) represent key structures in avian osmoregulation concerned with the control of salt gland activity and release of the antidiuretic hormone [Arg8]vasotocin (AVT). Nitric oxide (NO) acting as a paracrine transmitter in the hypothalamus has been shown to contribute to the maintenance of salt and fluid balance in mammals. The saltwater-acclimated duck was used in the present study as a well-characterized osmoregulatory model to investigate the role of central NO in hypothalamic perception or integration of osmoregulatory signals in marine birds. During osmotically induced steady-state salt gland secretion, the VIII of conscious ducks was microperfused with artificial cerebrospinal fluid (aCSF) alone, aCSF containing the NO-donor SNAP or the peptide [Val5]angiotensin II (ANGII) and alterations in salt gland activity, arterial pressure and the release of AVT were continuously monitored. No changes occurred during intracerebroventricular microperfusion with aCSF. Central application of ANGII, a known inhibitory hypothalamic transmitter in the control of salt gland function, markedly blocked salt gland osmolal excretion. Central stimulation with the NO-donor SNAP significantly reduced osmolal excretion from 0.41+/-0.02 to 0. 22+/-0.04 mosmol/min. Both ANGII and SNAP caused a rise in plasma AVT at either slightly elevated (ANGII) or constant (SNAP) arterial pressure. Employing NADPH-diaphorase histochemistry in the duck hypothalamus to localize sites of NO synthesis, periventricular neurons, nerve fibers in close association to the VIII and also parvocellular neurons of the paraventricular nucleus could be labeled. These data suggest a modulatory role for hypothalamic NO within the central osmoregulatory circuitry controlling salt gland function and AVT release in marine birds.

Functional receptors in the avian kidney for C-type natriuretic peptide.

Renal actions of avian-specific C-type natriuretic peptide (chCNP) were investigated in the conscious Pekin duck. Under conditions of steady-state renal water and salt elimination, systemic chCNP administration (6 and 30 pmol/min x kg BW for 20 min) dose dependently induced transient natriuresis and diuresis. Mean arterial pressure and heart rate remained constant throughout the experiment. Employing receptor autoradiography, binding sites specific for [125I]BH-chCNP could be localized at high density in glomeruli of both reptilian- and mammalian-type nephrons, and arterioles of the avian kidney. The distal tubular zone revealed [125I]BH-chCNP binding sites at medium, the medullary cone area at low density. Using an enriched kidney membrane fraction, competitive displacement studies with [125I]BH-chCNP as radioligand and various unlabeled peptide analogs (chANP, chCNP, rANP, rBNP, frANP, rANP(4-23)) allowed the discrimination of high-affinity (IC50 values 10(-10)-10(-9) M) and low-affinity (IC50 values 10(-8)-10(-7) M) binding sites different from typical mammalian receptor subtypes. Intracellular cyclic GMP formation could be demonstrated immunocytochemically for both types of glomeruli and cells of the distal tubular zone in fixed tissue sections after in vivo application of chCNP (0.8 nmol/min x kg BW; 5 min). The results obtained by combination of physiological in vivo studies and in vitro receptor analysis indicate an important role for chCNP in the modulation of avian kidney function.

Differential regulation of angiotensinogen and AT1A receptor mRNA within the rat subfornical organ during dehydration.

The present study describes the differential rostro-caudal patterning of angiotensinogen (AoGen) and AT1A receptor mRNAs in the rat SFO using specific and validated oligodeoxynucleotide probes for in situ hybridization. Highest levels of AoGen-specific gene expression were observed in the rostral region of the SFO with gradually decreasing intensity towards the caudal region of this sensory circumventricular organ lacking blood-brain barrier function. AoGen-related hybridization signals proved to be specifically prominent above cells in lateral aspects of the SFO, surrounding septal venules. Maximal expression of the AT1A receptor-specific gene, on the other hand, could be detected in the neuron-enriched, ventro-medial core region and dorsal annulus of the SFO, with low-intensity hybridization signals in its rostral and caudal parts. Water deprivation for 48 h, leading to extracellular hypertonic hypovolemia with elevated circulating AngII concentrations within the physiological range, caused a significant increase in AoGen-specific hybridization signals in the rostral and medial SFO regions. AT1A receptor gene expression and AngII receptor binding were markedly stimulated in the medial and caudal regions of the SFO (core and annulus) as compared to euhydrated animals. These data indicate, that mild dehydration differentially up-regulates AoGen- and AT1A receptor-specific mRNA formation as well as AT1 receptor binding in distinct regions of the SFO, and supports the involvement of different cellular subgroups in the expression of two major components of the central nervous renin-angiotensin system in this sensory circumventricular organ.

The lamina terminalis and its role in fluid and electrolyte homeostasis.

The lamina terminalis, which forms most of the anterior wall of the third ventricle, consists of the median preoptic nucleus and two circumventricular organs (CVOs), the subfornical organ and organum vasculosum of the lamina terminalis. These latter two regions lack a blood-brain barrier and, unlike other regions of the brain, are influenced by the hormonal and ionic composition of the blood. The CVOs of the lamina terminalis are rich in receptors for a number of circulating peptides and the subfornical organ and the OVLT are clearly established as the prime cerebral targets for circulating angiotensin II, atrial natriuretic peptide (AVP) and relaxin to influence central nervous system pathways regulating body fluid homeostasis. Together with the median preoptic nucleus, these two CVOs also detect changes and relay neural signals relating to the tonicity of body fluids and play important roles in osmoregulatory fluid intake and excretion. The neural circuitry of the lamina terminalis involves both afferent and efferent connections to several other regions of the brain, and neurons within the individual components of lamina terminalis are reciprocally connected with each other. This neural circuitry subserves the influence that the lamina terminalis exerts on vasopressin secretion, thirst, the appetite for salt, renal sodium excretion and renin secretion by the kidney. Copyright 1999 Harcourt Publishers Ltd.

In vivo and in vitro induction of c-fos in avian exocrine salt gland cells.

Osmotic stress in ducklings (Anas platyrhynchos) results in salt secretion and adaptive cell proliferation and differentiation in the nasal glands. We investigated whether osmotic stress in vivo or muscarinic ACh receptor activation in vitro changed the expression levels of the cellular protooncogene products Fos and Jun, which may play a role in the initiation of the adaptive processes. Using Fos- and Jun-specific polyclonal antisera in Western blot experiments, we demonstrated that Jun is constitutively expressed in nasal gland tissue, whereas Fos is not detectable in tissue from unstressed (naive) animals. Under conditions of osmotic stress imposed by replacing the drinking water of the animals with a 1% NaCl solution, Jun protein remains constant in nasal gland tissue, whereas Fos protein is transiently upregulated. Treatment of cultured nasal gland tissue with muscarinic agonists results in a transcriptionally regulated expression of Fos in an atropine-sensitive manner. Immunohistochemical experiments show that Fos accumulation occurs in the nuclei of the secretory cells. These results indicate that the activation of the c-fos gene induced by muscarinic ACh receptor-mediated signaling pathways may play an important role in the initiation of adaptive growth and differentiation processes in nasal glands of osmotically stressed ducklings.

Differential stimulation of c-fos expression in hypothalamic nuclei of the rat brain during short-term heat acclimation and mild dehydration.

Activation of central nervous structures involved in the perception and integration of thermo- and osmoregulatory signals was investigated in the Sabra rat. Male rats were either non-treated (C-E), water-deprived for 24 h (C-D), short-term acclimated to 34 degrees C for two days (STHA-E) or subjected to both stimuli (STHA-D). Immunoreactivity for c-Fos protein (Fos-IR) as marker for neuronal activation was quantified in (extra-)hypothalamic structures: organum vasculosum laminae terminalis (OVLT); subfornical organ (SFO); medial (MPA), ventromedial preoptic (VMPO) and lateral hypothalamic (LHA) areas; median preoptic (MnPO), magnocellular supraoptic (SON) and paraventricular (mPVN) nuclei; limbic lateral septal (LS) and thalamic paraventricular (PV) nuclei. Compared to C-E rats, dehydration markedly increased Fos-IR exclusively in neurons of the OVLT, SFO and MnPO known to be involved in osmoreception, in the mPVN and SON, and to a minor extent in the VMPO. The VMPO, MPA, LHA and LS-important (extra-)hypothalamic sites for the perception and integration within the thermoregulatory control circuit-exhibited intense elevation of Fos-IR upon short-term heat acclimation. Of all (extra-)hypothalamic structures involved in central osmoregulation, only the MnPO revealed heat-induced Fos-IR in numerous cells located preferentially in its rostral component. Thus, the MnPO proved to be activated during both thermal and osmotic stimulations applied separately. Subjected to the combined stress (STHA-D), most brain structures investigated showed striking Fos-IR due to thermally enhanced osmotic stimulation, with additive effects demonstrated in the MnPO. The data support differential central activation of c-fos expression due to thermal or osmotic stimulations, with the MnPO acting as putative integrative center for both autonomic control circuits.

Angiotensin II-induced calcium signalling in neurons and astrocytes of rat circumventricular organs.

The subfornical organ and organum vasculosum laminae terminalis represent neuroglial circumventricular organ structures bordering the anterior third cerebral ventricle. Owing to the absence of the blood-brain barrier, the cellular elements of the subfornical organ and the organum vasculosum laminae terminalis can be reached by circulating messenger molecules transferring afferent information. As demonstrated for the control of extracellular fluid composition, the circulating hormone angiotensin II acts on these sensory circumventricular organs to induce drinking, elevated peripheral resistance and neurohypophyseal hormone release via interaction with membrane-spanning receptor proteins. To characterize the cell-specific distribution of angiotensin II receptors within the circumventricular organs, primary cell cultures derived from the subfornical organ or organum vasculosum laminae terminalis of five- to six-day-old rat pups were used to measure alterations in intracellular calcium at the single cell level. Neurons and astrocytes were identified by immunocytochemical staining for specific marker proteins. Bath application of angiotensin II (10(-10)-10(-6) M) dose-dependently induced calcium transients in neurons (19.6%) and astrocytes (15.7%), and angiotensin II threshold concentrations to elicit intracellular calcium signalling proved to be one order of magnitude higher in astrocytes as compared to neurons (10(-9) M). At angiotensin II concentrations higher than 10(-7) M, pronounced desensitization of the angiotensin II receptor occurred. Employing the angiotensin II receptor antagonists losartan (DUP-753; AT1-receptor) and PD-123319 (AT2-receptor), exclusive expression of the AT1 receptor subtype coupled to intracellular calcium concentration signalling could be demonstrated for neurons and astrocytes. In all cells examined, the angiotensin II-evoked increase in intracellular calcium concentrations could be fully suppressed in the absence of extracellular calcium. Co-activation by angiotensin II and other agents (vasopressin, its fragment 8-arginine-vasopressin(4-9), oxytocin, endothelin) was indicated for subfornical organ neurons and organum vasculosum laminae terminalis astrocytes.

Functional receptors for atrial natriuretic peptide in the rat mammary gland during lactation.

The present study was undertaken: 1) to localize and characterize atrial natriuretic peptide (ANP) receptors in the rat mammary gland; and 2) to elucidate ANP-induced cellular formation of cyclic GMP (cGMP) and alterations in alveolar morphology during both early and late lactation. Receptor autoradiography, employing rat-specific [125I]ANP as radioligand, demonstrated binding sites in the secretory tissue and larger blood vessels of the mammary gland. Binding of [125I]rANP to membrane fractions was completely displaced by unlabeled ANP and brain natriuretic peptide. C-type natriuretic peptide and cANP(4-23) revealed limited competition with radiolabeled ANP only during early lactation, indicating a more heterogeneous receptor population at that time. Systemically administered ANP induced cGMP formation in the alveolar epithelium, as shown with immunohistochemistry, and increased mammary tissue cGMP concentrations in vivo throughout the lactation period. Image analysis revealed enlargement of alveolar (but not epithelial) cell area after ANP stimulation in late lactation, suggesting altered alveolar filling or myoepithelial cell relaxation. These results indicate that ANP induces biological effects in the rat mammary gland through specific ANP-A receptor interaction with subsequent intracellular cGMP formation. ANP may therefore play a regulatory role in the control of mammary gland blood supply and secretory function.