Angiotensin II stimulates water and NaCl intake through separate cell signalling pathways in rats.

Angiotensin II (AngII) stimulation of water and NaCl intake is a classic model of the behavioural effects of hormones. In vitro studies indicate that the AngII type 1 (AT(1)) receptor stimulates intracellular pathways that include protein kinase C (PKC) and mitogen-activated protein (MAP) kinase activation. Previous studies support the hypotheses that PKC is involved in AngII-induced water, but not NaCl intake and that MAP kinase plays a role in NaCl consumption, but not water intake, after injection of AngII. The present experiments test these hypotheses in rats using central injections of AngII in the presence or absence of a PKC inhibitor or a MAP kinase inhibitor. Pretreatment with the PKC inhibitor chelerythrine attenuated AngII-induced water intake, but NaCl intake was unaffected. In contrast, pretreatment with U0126, a MAP kinase inhibitor, had no effect on AngII-induced water intake, but attenuated NaCl intake. These data support the working hypotheses and significantly extend our earlier findings and those of others. Perhaps more importantly, these experiments demonstrate the remarkable diversity of peptide receptor systems and add support for the surprising finding that intracellular signalling pathways can have divergent behavioural relevance.

Food restriction alters neuronal morphology in the hypothalamic ventromedial nucleus of male rats.

Several lines of evidence have implicated the hypothalamic ventromedial nucleus (VMH) in the control of caloric homeostasis. For example, the activity of VMH neurons depends on energy availability. We tested the hypothesis that energy balance may involve the remodeling of the dendritic arbor of VMH neurons. We compared two groups of animals: one group had ad libitum access to food, and the other experienced 10-d restricted access to food. As expected, the food-deprived group lost body weight and had reduced levels of glucose, insulin, and leptin. VMH neurons were visualized after Golgi impregnation, and dendrite length was measured. Food deprivation had differential effects on VMH neurons. In particular, within the ventrolateral VMH, for neurons with long primary dendrites (LPDs) that extended in the lateral, but not medial, direction, the LPDs were 31% shorter. These same neurons exhibited a 32% reduction in the number of other dendrites without a change in soma size. In contrast, within the dorsomedial VMH, for neurons with medially, but not laterally, extended LPDs, the soma area was reduced by 28%. However, neurons in the dorsomedial VMH did not display a change in the length or number of dendrites, regardless of LPD direction. Thus, although structural changes during calorie depletion occur in both the dorsomedial and ventrolateral VMH, only the latter exhibits a remodeled dendritic arbor. These results also suggest that the direction of the LPD may be an important marker of neuronal function in the VMH.

Structural and signaling requirements of the human melanocortin 4 receptor for MAP kinase activation.

In addition to its well known stimulation of cAMP production, the human melanocortin type 4 (hMC4) receptor recently has been shown to mediate p44/42 MAPK activation. This finding opens new questions about the structural and signaling mechanisms that connect the receptor to this alternate cell signaling pathway. Point mutants in the hMC4 receptor that have been associated with obesity were constructed and transfected into HEK 293 cells. Functional analyses then were done to determine if these mutations would similarly impact cAMP formation and p44/42 MAPK signaling. Whereas a D90N mutation in the second transmembrane domain and a D298A mutation in the seventh transmembrane domain impaired both cAMP formation and p44/42 MAPK activation, a more conservative D298N mutation retained cAMP formation but abolished p44/42 MAPK activation. The D298N mutation identified, for the first time, differential structural requirements of the hMC4 receptor for activation of the cAMP and p44/42 MAPK pathways. Furthermore, functional characterizations of a series of chimeric receptors combining the hMC4 receptor and the hMC3 subtype, a receptor that does not couple to p44/42 MAPK activation despite stimulating adenylyl cyclase, indicate that the hMC4 cytoplasmic tail is a necessary structural element for p44/42 MAPK signaling. Subsequent investigation of the signaling requirements for p44/42 MAPK activation demonstrated that the adenylyl cyclase inhibitor 2', 5'-dideoxyadenosine blocked agonist-induced p44/42 MAPK activation, but the PKA inhibitor Rp cAMPS did not. Taken together, these data indicate that cAMP is required, but not sufficient for p44/42 MAPK activation and suggest structural elements required for hMC4 receptor signaling.

Identification of structural determinants for G protein-independent activation of mitogen-activated protein kinases in the seventh transmembrane domain of the angiotensin II type 1 receptor.

Although the intrareceptor mechanisms whereby the angiotensin II (AngII) type 1 receptor activates phospholipase C (PLC) have been extensively investigated, analogous studies of signaling through mitogen-activated protein kinases (MAPK) have been lacking. We investigated MAPK activation and traditional G(q)/PLC signaling in transfected cells using AngII and the signaling selective agonist [Sar(1),Ile(4),Ile(8)] AngII (SII). SII stimulated MAPK without inositol trisphosphate (IP(3)) production and thereby stabilizes an activated receptor state linked to G protein-independent MAPK signaling. Using receptor mutagenesis, we focused on the seventh transmembrane domain and identified three key residues-Tyr(292), Phe(293), and Thr(287). At least three distinct activated states were revealed: 1) an AngII-stabilized state linked to G(q)/PLC signaling, 2) an AngII-stabilized state connected to G protein-independent MAPK activation, and 3) a SII-stabilized state associated with G protein-independent MAPK signaling. The mutant Y292F failed to exhibit AngII-induced IP(3) turnover yet remained capable of AngII-induced MAPK activation. SII failed to stimulate MAPK in Y292F-transfected cells. Thus, Tyr(292) is a key epitope for activated states 1 and 3 but not required for activated state 2. Although the F293L mutant retained normal AngII responses, it also showed an IP(3) response to SII, indicating that Phe(293) may be involved in constraining the receptor to its inactive state. Mutations of Thr(287) abolished all SII-induced signaling without affecting any AngII responses. Thr(287) therefore represents a key residue for a SII-stabilized activated state. Taken together, the data identified a novel structural requirement (Thr(287)) for the SII-stabilized activated state and redefined the mechanistic roles for Tyr(292) and Phe(293).

Divergent behavioral roles of angiotensin receptor intracellular signaling cascades.

Central injections of angiotensin II (AngII) increase both water and NaCl intake. These effects of AngII occur largely through stimulation of the AngII type 1 (AT(1)) receptor. Stimulation of the AT(1) receptor leads to a number of intracellular events, including phospholipase C (PLC) activation and the subsequent formation of diacylglycerol and inositol trisphosphate (IP(3)), which then activate protein kinase C (PKC) and increase intracellular calcium, respectively. In addition, AT(1) receptor stimulation leads to the activation of MAPK family members. Recent experiments using mutated AT(1) receptor constructs or the AngII analog Sar(1),Ile(4),Ile(8)-AngII (SII) revealed that MAPK activation can occur independent of PLC/PKC/IP(3) activation. The present experiments used in vitro and in vivo approaches to clarify the cellular and behavioral responses to SII. Specifically, SII mimicked AngII stimulation of MAPK in AT(1) receptor-transfected COS-1 cells and rat brain but blocked the effects of AngII in two distinct settings: in vitro stimulation of IP(3) and in vivo increases in water intake. Moreover, SII increased intake of 1.5% NaCl, despite the SII blockade of IP(3) formation and water intake. Examination of brain tissue showed increases in Fos expression in several AngII-sensitive brain areas after injection of AngII, but not SII. The lack of SII-induced IP(3) production, water intake, and Fos expression strongly suggest that the PLC/PKC/IP(3) pathway is required for water intake, but not NaCl consumption stimulated by AngII. Collectively, these results support the hypothesis that divergent intracellular signals from a single receptor type can give rise to separable behavioral phenomena.

Rattus norvegicus melanocortin 3 receptor: a corrected sequence.

Examination of the Rattus norvegicus genome reveals differences in the melanocortin 3 receptor (MC3R) compared with the published sequence (accession X70667). To clarify these differences, we used RT-PCR to clone MC3R from Sprague Dawley rats. These efforts revealed a sequence for the rat MC3R consistent with that predicted by the rat genome, but different from the published receptor by three amino acids, all of which were located in the predicted second transmembrane domain (TM2). Analysis of these residues revealed that TM2 of the rat MC3R is more homologous with other species than previously considered. The presently described sequence maps onto chromosome 3 of the rat genome, which shows highly conserved synteny with the mouse chromosome 2 and the human chromosome 20. Transient expression revealed high affinity binding of [125I]-NDP-MSH and a concentration-dependent cAMP response to the synthetic agonist MTII. These data both clarify the sequence of the MC3R and demonstrate the great utility of genomic information recently made available.

Structural determinants for the activation mechanism of the angiotensin II type 1 receptor differ for phosphoinositide hydrolysis and mitogen-activated protein kinase pathways.

While the mechanism whereby the angiotensin II type 1 receptor (AT(1) receptor) activates its classical effector phospholipase C-beta (PLC-beta) has largely been elucidated, there is little consensus on how this receptor activates a more recently identified effector, the p42/44 mitogen-activated protein kinases (p42/44(MAPK)). Using transfected COS-1 cells, we investigated the activation of this signaling pathway at the receptor level itself. Previous mutational studies that relied on phosphoinositide turnover as an index of receptor activation have indicated that key residues in the second and seventh transmembrane domains participate in AT(1) receptor activation mechanisms. Thus, we introduced a variety of mutations-AT(1)[D74N], AT(1)[Y292F], AT(1)[N295S], and AT(1)[AT(2) TM7], which is composed of a chimeric substitution of the AT(1) seventh transmembrane domain with its AT(2) counterpart. These mutations that strongly diminished the receptor's ability to activate PLC-beta had little to no effect on its ability to activate p42/44(MAPK), which not only suggests that p42/44(MAPK) does not exclusively lie downstream of the G-protein G(q)/PLC-beta pathway but also indicates that more than one activation state may exist for the AT(1) receptor. The failure of a protein kinase C inhibitor to block AT(1) receptor activation of p42/44(MAPK) further corroborated evidence that the receptor's activation of p42/44(MAPK) is largely independent of the G(q)/PLC-beta/PKC pathway. Taken together, the experimental evidence strongly suggests that the mechanism whereby the AT(1) receptor activates p42/44(MAPK) is fundamentally different from that for PLC-beta, even at the level of the receptor itself.

Modeling the pathways of energy balance using the N1E-115 murine neuroblastoma cell line.

A good in vitro model within which to investigate molecular interactions between feeding relevant neuropeptide systems has been lacking. Consequently, we began using reverse transcriptase-polymerase chain reaction (RT-PCR) to screen various neuronal cell lines for the presence of feeding relevant neuropeptides and receptors. N1E-115 murine neuroblastoma cells have emerged as an attractive candidate for further analysis because they contain mRNA for a variety of key systems implicated in the regulation of energy homeostasis.

Melanocortin receptor signaling through mitogen-activated protein kinase in vitro and in rat hypothalamus.

The central melanocortin system has emerged as a potential regulator of food intake. This action of melanocortins appears to occur through intrahypothalamic, melanocortin-containing projections, including those from the arcuate to the paraventricular nucleus (PVN). Although the complexity of feeding behavior and the long duration of the effects of melanocortins on food intake suggest changes in gene expression, the mechanism by which such changes occur has been elusive. In the present report, we describe experiments using in vitro and in vivo approaches to demonstrate melanocortin-induced phosphorylation (activation) of members of the mitogen-activated protein kinase (MAPK) family of transcription factors. First, application of the melanocortin agonist MTII to COS-1 cells resulted in an increase in phosphorylated MAPK after the cells were transfected with the melanocortin type 4 receptor (MC4-R), but not the type 3 receptor. Formation of cAMP, however, was observed when either receptor subtype was transfected. Subsequent experiments revealed that the effect of MTII on MAPK activation in MC4-R-transfected cells was dose-dependent and was maximal after 10 min of MTII exposure. Second, central injections of MTII increased the number of phospho-MAPK-immunoreactive cells in the rat PVN compared to vehicle-injected animals. When coupled with immunohistochemical identification of PVN neurons containing oxytocin, a clear segregation was apparent, allowing for a precise anatomical description of the pattern of activated MAPK within the PVN. These data are the first to suggest a differential coupling of MC4-R and may describe a mechanism through which the long-term and persistent behavioral actions of melanocortins are mediated.

Salt appetite: a neurohormonal viewpoint.

Sodium is a key component of virtually every mammalian physiological function. As such, many animals have evolved specialized mechanisms for detecting and ameliorating deficits in body sodium, including the development of a robust salt appetite, where normally aversive concentrations of salt are readily consumed during periods of sodium deprivation. Here, we review research spanning more than half a century focusing on the condition and detection of sodium deprivation, the important and unique function of taste in sodium homeostasis, as well as the neurohormonal interactions leading to behaviors aimed at the reversal of sodium deficits. Based on the present literature, we propose a model for the interaction of forebrain and brainstem systems for the mediating circuitry giving rise to salt appetite and discuss the remarkable parallel between what is known about the neurohormonal interactions that regulate salt appetite and those involved in energy homeostasis.

Angiotensin II receptor signalling.

Angiotensin II plays a key role in the regulation of body fluid homeostasis. To correct body fluid deficits that occur during hypovolaemia, an animal needs to ingest both water and electrolytes. Thus, it is not surprising that angiotensin II, which is synthesized in response to hypovolaemia, acts centrally to increase both water and NaCl intake. Here, we review findings relating to the properties of angiotensin II receptors that give rise to changes in behaviour. Data are described to suggest that divergent signal transduction pathways are responsible for separable behavioural responses to angiotensin II, and a hypothesis is proposed to explain how this divergence may map onto neural circuits in the brain.

Vessel-specific regulation of angiotensin II receptor subtypes during ovine development.

Umbilical and systemic responses to angiotensin II differ in term fetal sheep, and peripheral vascular responses are attenuated or absent before and after birth. These observations may reflect developmental differences in angiotensin II receptor (AT) subtypes in vascular smooth muscle (VSM). Studies of AT subtype ontogeny and regulation are generally limited to the aorta, which may not be extrapolated to other arteries, and neither is completely described during ovine development. We therefore characterized VSM AT subtype expression and regulation throughout an extended period of development in umbilical and carotid artery and aorta from fetal (85-146 d gestation), postnatal (5-23 d), and adult sheep, measuring AT(1) and AT(2) mRNA and protein and performing immunohistochemistry. Parallel increases in umbilical AT(1) mRNA and protein began early in gestation and continued to term, and although AT(2) mRNA was unchanged, protein levels decreased >90% at term. Fetal carotid AT(1) mRNA was <40% of adult values and unchanged before birth; however, AT(1) protein rose >2-fold at term. After birth, AT(1) mRNA increased to 85% of adult values and was associated with another 2-fold rise in protein. In contrast, carotid AT(2) mRNA and protein fell in parallel throughout development and were barely detectable in the newborn and the adult. Immunostaining was consistent with observations in both arteries. A third pattern occurred in aortic VSM. The ontogeny of AT subtype expression and regulation is vessel specific, with changes in umbilical VSM beginning very early in development. Although the mechanisms that regulate mRNA and protein expression are unclear, these changes parallel differences in VSM maturation and function and local blood flow.