Endogenous kappa opioids mediate the action of brain angiotensin II to increase blood pressure

The objectives of this study were to determine whether endogenous opioids are operative in modulating the CNS action of angiotensin II (ang II) on blood pressure and to determine whether this is mediated by endogenous mu or kappa opioid receptor agonists. The study design was: unanesthetized Wistar rats, 300-400g, previously instrumented with a cannula in the lateral cerebral ventricle and a catheter in the femoral artery, had ang II, 0.5microg, injected into the lateral cerebral ventricle (ICV). Groups were allocated to receive naloxone, a mu opioid receptor antagonist or MR 2266 a selective kappa opioid receptor antagonist prior to ang II. In other experiments in unanesthetized rats, baroreceptor reflex function was assessed by intravenous injection of phenylephrine or nitroprusside and the interaction of endogenous opioids and ang II ascertained with use of the mu or kappa opioid receptor antagonist . RESULTS: Ang II significantly (p<0.05) increased systolic and diastolic blood pressure. The kappa opioid antagonist, MR 2266, 25microg/kg ICV, significantly (p<0.05) reduced and MR 2266, 50microg/kg ICV, completely prevented the increase in blood pressure produced by ang II. In contrast, the mu opioid receptor antagonist, naloxone, 50microg/kg, ICV, did not significantly attenuate the blood pressure responses to ang II. Ang II induced alteration in baroreceptor function. The effect of ang II on baroreceptor function was significantly antagonized by the kappa opioid receptor antagonist MR 2266. In conclusion, these data indicate that: (a) endogenous opioids modulate the pressor response to intracerebral ang II, (b) this effect is mediated mainly through endogenous kappa opioid agonists and kappa rather than mu opioid receptors, (c) alteration of baroreceptor sensitivity by ang II is modulated by endogenous kappa opioids.     

Mapping of angiotensin II receptor subtype heterogeneity in rat brain.

Angiotensin II (Ang II) exerts a number of central actions on fluid and electrolyte homeostasis, autonomic activity, and neuroendocrine regulation. In order to evaluate likely sites where these actions are mediated, Ang II receptor binding was localized in rat brain by in vitro autoradiography with the aid of the antagonist analogue 125I-[Sar1, Ile8]Ang II. Two subtypes of Ang II receptor have been identified using recently developed peptide and nonpeptide antagonists. In the periphery, the receptor subtypes differ in distribution, second messenger coupling, and function. Brain Ang II receptor subtypes were therefore differentiated into AT-1 (type I) and AT-2 (type II) subtypes by using unlabelled nonpeptide antagonists specific for the two Ang II subtypes. AT-1 binding was determined to be that inhibited by Dup 753 (10 microM) and AT-2 binding to be that inhibited by PD 123177 (10 microM). The reducing agent dithiothreitol (DTT) decreased binding to AT-1 receptors and enhanced binding to AT-2 receptors. Many brain structures, such as the vascular organ of the lamina terminalis, subfornical organ, median preoptic nucleus, area postrema, nucleus of the solitary tract, and dorsal motor nucleus of the vagus, which are known to be related to the central actions of Ang II, contain exclusively AT-1 Ang II receptors. By contrast, the locus coeruleus, ventral and dorsal parts of lateral septum, superior colliculus and subthalamic nucleus, many nuclei of the thalamus, and nuclei of the inferior olive contain predominantly AT-2 Ang II receptors. The detailed binding characteristics of each subtype were determined by competition studies with a series of analogues of angiotensin and antagonists. The pharmacological specificity obtained in rat superior colliculus and the nucleus of the solitary tract agreed well with published data on AT-1 and AT-2 receptors, respectively. There was a high degree of correlation between the distribution of Ang II binding sites with published data on Ang II-immunoreactive fields and on the sites of Ang II-responsive neurons. The present study also reveals pharmacological heterogeneity of brain Ang II receptors. The subtype-specific receptor mapping described here is relevant to understanding the role of angiotensin peptides in the central nervous system and newly discovered central actions of nonpeptide Ang II receptor antagonists.     

Central depletion of angiotensinogen is associated with elevated AT<Subscript>1</Subscript> receptors in the SFO and PVN

The brain renin-angiotensin system (RAS) is important in fluid balance and blood pressure regulation. In this study, we compared angiotensin (Ang) receptor density in the subfornical organ (SFO) and paraventricular nucleus (PVN) of a) brain angiotensinogen deficient rats (ASrAogen); b) those with high levels of brain Ang II [(mRen2)27]; c) Hannover Sprague Dawley (SD) rats at 48 and 68 wks of age. Since there was no difference between the two ages in any of the three strains, the data from the 48 and 68 wk time points were combined. There was a significantly higher level of AT1 receptors in the SFO and PVN of ASrAogen animals compared to both the SD and (mRen2)27 rats. This suggests that the brain RAS is important in regulating receptor density and that the differences may be explained by lower levels of the peptide locally. These higher levels of receptors suggest that the ASrAogen animals in adulthood and early aging would be more sensitive to either circulating or endogenous brain Ang II than the SD animals of similar age. In contrast, the similar receptor density in the (mRen2)27 and SD rats suggest that previous reports of reduced responses in the (mRen2)27 rats may result from differences in post receptor mechanisms such as intracellular signaling. Moreover, our data reveal that functional assessments are necessary in addition to receptor density levels to understand the consequences of long-term alterations in brain tissue peptides.     

Brain angiotensin II and synaptic transmission.

The renin-angiotensin system is an enzymatic cascade by which angiotensinogen is cleaved by renin and then by angiotensin-converting enzyme to produce angiotensin II (Ang II) and subsequently other angiotensins. Biochemical and neurophysiological studies have documented the presence of the reninangiotensin system and specific Ang II receptors in the brain. Also, circulating Ang II can exert some of its actions, such as blood pressure control and body fluid homeostasis, through stimulation of Ang II receptors in the circumventricular organs that lack a normal blood-brain barrier. In addition to some of the post-synaptic effects of Ang II, recent studies have revealed that Ang II regulates synaptic transmission in several brain regions, especially the nucleus of the solitary tract, hypothalamic paraventricular nucleus, and hippocampus. This review summarizes emerging new evidence on the effect of brain Ang II on glutamatergic and GABAergic synaptic transmission. This previously unrecognized presynaptic action of Ang II is important for the control of neuronal excitability and many physiological functions including autonomic control, hormone secretion, and memory. Future research on the role of brain-derived Ang II and its receptors in synaptic transmission will further enhance our understanding of the cellular mechanisms of Ang II and the relationship between the renin-angiotensin system and brain functions.     

Changes in angiotensin II receptors in dopamine-rich regions of the mouse brain with age and ethanol consumption

The density of angiotensin II (Ang II) receptors was determined in three dopaminergic nerve terminal-rich brain regions (caudate putamen, nucleus accumbens, and ventral pallidum) of mice that were given either water (control) or 20% w/v ethanol (EtOH) to drink for either 2–8 weeks (young) or 46 weeks (old). The receptors were labeled with ¹²⁵I-sarcosine¹, isoleucine⁸ angiotensin II (¹²⁵I-SI Ang II) and measured by quantitative densitometric image analysis (receptor autoradiography) or by saturation binding assays on homogenates of these brain regions. The selective AT₂ receptor subtype antagonist PD 123319 (10 μM) was used to inhibit ¹²⁵I-SI Ang II binding to AT₂ receptors to determine AT₁ receptor density in brain sections. In young control mice the density of Ang II receptor binding sites in the caudate putamen was 407±26 fmol/g, in the nucleus accumbens the density was 346±27 fmol/g, and in the ventral pallidum the density was 317±27 fmol/g. Less than 5% of specific ¹²⁵I-SI Ang II binding was displaced by PD 123319, suggesting that nearly all of the Ang II receptors in these brain regions were the AT₁ subtype. The B_max in homogenates of these three regions in young control mice was 11.0±2.1 fmol/mg protein. The K_D was 0.49±0.13. Ang II receptors in old mouse brains were decreased, respectively, by 32%, 35% and 30% in the caudate putamen, nucleus accumbens and ventral pallidum (p<0.001). Ang II receptors were slightly, but not significantly increased in both young and old EtOH-consuming mice.     

Jacques Benoit lecture: the neuroendocrine view of the angiotensin and apelin systems

The hyperactivity of the brain renin-angiotensin system (RAS) has been implicated in the development and maintenance of hypertension in several types of experimental and genetic hypertension animal models. Among the main bioactive peptides of the brain RAS, angiotensin (Ang) II and Ang III display the same affinity for type 1 and type 2 Ang II receptors. Both peptides, injected intracerebroventricularly, similarly increase arginine vasopressin (AVP) release and blood pressure (BP); however, because Ang II is converted in vivo to Ang III, the identity of the true effector is unknown. We review new insights into the predominant role of brain Ang III in the control of BP, underlining the fact that brain aminopeptidase A (APA), the enzyme generating brain Ang III, may therefore be an interesting candidate target for the treatment of hypertension. This justifies the development of potent systemically active APA inhibitors, such as RB150, as prototypes of a new class of antihypertensive agents for the treatment of certain forms of hypertension. We also searched for a putative angiotensin receptor subtype specific for Ang III and isolated a seven transmembrane-domain G protein-coupled receptor corresponding to the receptor for apelin, a newly-discovered peptide isolated from bovine stomach. Apelin and its receptor are expressed in magnocellular vasopressinergic neurones in the hypothalamus. The central injection of apelin in lactating rats decreases the phasic electrical activity of vasopressinergic neurones and the systemic secretion of AVP, inducing water diuresis. Apelin is therefore a natural inhibitor of the antidiuretic effect of AVP. In addition, systemic administration of apelin decreases BP, improves cardiac contractility and reduces cardiac loading. The development of nonpeptide agonists of the apelin receptor may provide new therapeutic tools for treating water retention, hyponatraemia and cardiovascular diseases. Angiotensins and apelin thus exert opposing but complementary effects, and are thereby determinant for the maintenance of body fluid homeostasis and cardiovascular functions.     

The role of the brain renin-angiotensin system in neurodegenerative disorders

The primary function of the renin-angiotensin system (RAS) is to maintain fluid homeostasis and regulate blood pressure. Several components of the RAS, namely angiotensinogen, angiotensin converting enzyme, angiotensin II and their receptors, are found in the CNS suggesting the possibility of a localized RAS in the brain. Cognitively disabling neurodegenerative disorders such as Alzheimer's disease or vascular dementia show vascular lesions, and the brain RAS has been suggested to contribute to the disease process. The aim of this brief review is to summarize the current state of research in this field with emphasis on RAS-related alterations during the course of neurodegenerative disorders.     

Ang II and Ang IV: Unraveling the Mechanism of Action on Synaptic Plasticity,Memory, and Epilepsy

The central angiotensin system plays a crucial role in cardiovascular regulation. More recently, angiotensin peptides have been implicated in stress, anxiety, depression, cognition, and epilepsy. Angiotensin II (Ang II) exerts its actions through AT₁ and AT₂ receptors, while most actions of its metabolite Ang IV were believed to be independent of AT₁ or AT₂ receptor activation. A specific binding site with high affinity for Ang IV was discovered and denominated “AT₄ receptor”. The beneficiary effects of AT₄ ligands in animal models for cognitive impairment and epileptic seizures initiated the search for their mechanism of action. This proved to be a challenging task, and after 20 years of research, the nature of the “AT₄ receptor” remains controversial. Insulin‐regulated aminopeptidase (IRAP) was first identified as the high‐affinity binding site for AT₄ ligands. Recently, the hepatocyte growth factor receptor c‐MET was also proposed as a receptor for AT₄ ligands. The present review focuses on the effects of Ang II and Ang IV on synaptic transmission and plasticity, learning, memory, and epileptic seizure activity. Possible interactions of Ang IV with the classical AT₁ and AT₂ receptor subtypes are evaluated, and other potential mechanisms by which AT₄ ligands may exert their effects are discussed. Identification of these mechanisms may provide a valuable target in the development in novel drugs for the treatment of cognitive disorders and epilepsy.     

Comparative studies on the memory-enhancing actions of captopril and losartan in mice using inhibitory shock avoidance paradigm

Renin angiotensin system (RAS) in the central nervous system participates in the processing of sensory information, learning and memory processes. Inhibitors of RAS, particularly angiotensin converting enzyme (ACE) inhibitors and angiotensin II (Ang II) receptor antagonists are reported to have potential nootropic effects in various learning and memory paradigms. The neurochemical basis underlying nootropic effect of ACE inhibitors are unclear due to wide range of substrate for this enzyme. In this study, we compared the effect of ACE inhibitor captopril and a selective AT(1)receptor antagonist losartan in a step-up shock avoidance (active avoidance) task. Captopril (5-10 mg/kg) but not losartan (5-10 mg/kg) improved learning in the second trial of the acquisition test. However, both these drugs were equally effective in enhancing retention of memory when administered prior to training. Retention enhancing effect of captopril and losartan were reversed by post-acquisition test administration of L-NAME (15 mg/kg), dizocilpine (0.05 mg/kg) and scopolamine (0.1 mg/kg). On the basis of above observations, it is concluded that decrease in endogenous Ang II activity in the brain might result in improved cognitive performance by enhancing cGMP pathways. However facilitation of acquisition only by captopril may be due to other putative mechanisms.     

High levels of human chymase expression in the pineal and pituitary glands

The brain renin-angiotensin system plays a role in both cardiovascular homeostasis and neurosecretory functions. Since the mechanisms of angiotensin (Ang) II formation in the human brain have not been clarified, the aims of the present study were to determine the presence of human chymase and angiotensin I-converting enzyme (ACE) in human and non-human brains. In the human brain, the total Ang II-forming activity was significantly higher in the pineal and pituitary glands than those in other regions. In other species (rat, bovine and porcine), the level of chymase as well as total Ang II-forming activities in pineal glands were significantly lower than those in human glands. High levels of chymase-like immunoreactivity (ir) were found in the arteriolar endothelial cells, adventitial mesenchymal cells and in parenchymal cells of the human pineal and pituitary glands while ACE-ir was mostly observed in the endothelial cells and occasionally found in parenchymal cells. Our study provides the first evidence that human chymase exists in the pineal and pituitary glands. The remarkable regional and species differences in mechanisms of Ang II formation suggest a specific role of chymase or ACE in the human brain.     

Control of neuropathic pain by immune cells and opioids

Neuropathic pain is a compilation of somatosensory, cognitive and emotional alterations developing following nerve injuries. Such pain often outlasts the initial cause and becomes a disease of its own that challenges its management. The actions of currently used anticonvulsants, antidepressants and opioids are hampered by serious central nervous system adverse effects, which preclude their sufficient dosing and long-term use. Conversely, selective activation of opioid receptors on peripheral sensory neurons has the advantage of pain relieve without central side effects. Considerable number of animal studies supports analgesic effects of exogenously applied opioids acting at peripheral opioid receptors in neuropathic conditions. In contrast to currently highlighted pain-promoting properties of neuroimmune interactions associated with neuropathy, recent findings suggest that opioid peptide-containing immune cells that accumulate at damaged nerves can also locally alleviate pain. Future aims include the exploration of opioid receptor signaling in injured nerves and of leukocytic opioid receptor function in pain modulation, development of approaches selectively delivering opioids and opioid-containing cells to injured tissues and investigation of interactions between exogenous and leukocyte-derived opioids. These efforts should lay a foundation for efficient and safe control of neuropathic pain. This article comprehensively analyzes the consequences of nerve injury on the expression of peripheral opioid receptors and peptides, and the impact of these changes on opioid analgesia, critically discussing positive and negative findings. Further focus is on a dual character of immune responses in the control of painful neuropathies.     

Estradiol and progesterone modulation of angiotensin II receptors in the arcuate nucleus of ovariectomized and lactating rats

The expression of angiotensin II (Ang II) receptors in the brain is modulated by estradiol and progesterone. Considering that Ang II plays a critical role in controlling prolactin secretion and that neurons in the arcuate nucleus (ARC) are the main regulator of this function, the present study aimed to evaluate ARC Ang II receptor binding in 2 experimental models with different estradiol and progesterone plasma levels. Animals were divided into 4 groups: ovariectomy (OVX) plus oil vehicle, OVX plus estradiol and progesterone replacement, lactating rats on day 7 postpartum, and lactating rats on day 20. Animals were killed by decapitation, and the brains were removed. Ang II receptors were quantified by autoradiography in ARC. Trunk blood samples were collected, and plasma estradiol and progesterone were measured by radioimmunoassay. Treatment of OVX rats with estradiol and progesterone increased Ang II receptor binding when compared to OVX vehicle-treated animals. Plasma estradiol (r = +0.77) and progesterone (r = +0.87) were highly correlated with Ang II receptors in ovariectomized animals. Lactating rats (day 20) showed a significant decrease in Ang II receptor binding and plasma progesterone when compared to lactating rats (day 7), however, no difference was seen in plasma estradiol. Plasma levels of progesterone (r = +0.81), but not estradiol (r = +0.32), were highly correlated with Ang II receptors in lactating rats. In conclusion, present results show that ARC Ang II receptors decreases on day 20 of lactation compared to day 7 and are highly correlated with plasma progesterone, indicating a pivotal role for progesterone in this regulation.     

Stimulation of area postrema by vasopressin and angiotensin II modulates neuronal activity in the nucleus tractus solitarius

There is an abundance of evidence suggesting that the area postrema (AP) is involved in the central actions of argininevasopressin (AVP) and angiotensin II (Ang II) on cardiovascular regulation. Furthermore, recent studies have shown that activation of the AP facililates the response of nucleus tractus solitarius (NTS) neurons to tractus stimulation. In the present study, using the perfused rabbit brain slice preparation, we examined the response of NTS neurons when AVP and Ang II were microinjected onto the AP. Spontaneous or solitary tract stimulation-induced neuronal activity was recorded extracellularly from the medial NTS before, during and after AVP or Ang II application. An increase or decrease in activity by more than 30% of the baseline value was considered excitatory or inhibitory. The effects of AVP were studied in 57 NTS cells, 14 of which were spontaneously active and 43 were driven by tract stimulation. Of the cells with evoked activity, 49% were excited, 19% were inhibited, and 32% did not respond. The percentage of cells responding to AVP was similar in spontaneously active cells. The effects of Ang II were tested in 85 cells including 54 with evoked activity and 31 with spontaneous activity. In NTS cells with evoked activity, AP application of Ang II caused inhibition in 37%, excitation in 7%, while 56% did not respond. The proportion of cells responding to Ang II was similar in spontaneously active cells. These results suggest that AVP may act on the AP to increase the excitatory response of NTS neurons while the actions of Ang II result in an inhibitory influence.     

Forced swimming test increases superoxide anion positive cells and angiotensin II positive cells in the cerebrum and cerebellum of the rat

Situations of stress are capable of inducing depression and oxidative stress in the brain. Previous reports have shown that angiotensin II (Ang II) induces the production of superoxide anion (O(2)(-)), and impairment of endothelial function in cerebral microvessels in vivo. Substances that reduce angiotensin functions may be important in the treatment of depression. These data suggest a role for both Ang II and O(2)(-) in depression; thus, the aim of this study was to determine the effect of forced swimming test (FST), a model of stress/depression, on the cellular expression of Ang II and O(2)(-) in the central nervous system. To induce stress/depression, rats were subjected to FST daily (30 min) for 15 days. Unstressed animals were used as controls. Motor activity was automatically analyzed daily before swimming. Cerebrum and cerebellum frozen sections were studied for O(2)(-) by a histochemical method and for Ang II producing cells by a polyclonal antibody. In the FST group, struggle time, total horizontal activity, ambulatory movements, and vertical movements, were significantly decreased when the data from the 1st and 15th day were compared. Food intake and body weight gain also decreased when unstressed and FST rats were compared at the 15th day. Increased number of cerebrum and cerebellum O(2)(-), and Ang II positive cells, were observed in FST rats. Significant correlation was found between O(2)(-) positive cells and Ang II positive cell in the cerebrum. These results suggest that stress/depression situations could be involved in the increase of Ang II and oxidative stress in the central nervous system, with possible implications in the depressive condition.     

Elevated salt appetite and brain binding of angiotensin II in mineralocorticoid-treated rats

Angiotensin II (Ang II) and aldosterone levels increase with sodium deficiency, promoting sodium conservation and arousing a salt appetite in rats. The mechanism(s), by which these two hormones interact to produce salt appetite is not known. The experiments reported here tested the possibility that increased mineralocorticoids change the number and/or affinity of Ang receptors in the brain. Rats were given a series of deoxycorticosterone acetate (DOCA) injections (500 micrograms/day, s.c., for 4 days) which are known to produce a salt appetite when given in conjunction with an intracerebroventricular injection of Ang. The binding of 125I-Ang II to membranes prepared from the septal-anteroventral third ventricular region was then examined. DOCA treatment resulted in a significant increase in the number of Ang binding sites (Bmax) with no change in binding affinity (Kd). The binding of 125I-Ang II was then investigated in membranes prepared from 12 other brain regions as well as the pituitary and adrenal gland, showing that the increase in binding capacity occurred in only a few specific brain regions. A third experiment verified that the DOCA treatment used here was sufficient to arouse a salt appetite when combined with a single intracerebroventricular injection of Ang II. The mechanism that underlies the production of salt appetite by aldosterone and Ang II may at least partially consist of mineralocorticoid-induced increases in the number of Ang receptors in discrete brain regions.     

Neurobiological mechanisms involved in nicotine dependence and reward: Participation of the endogenous opioid system

Nicotine is the primary component of tobacco that maintains the smoking habit and develops addiction. The adaptive changes of nicotinic acetylcholine receptors produced by repeated exposure to nicotine play a crucial role in the establishment of dependence. However, other neurochemical systems also participate in the addictive effects of nicotine including glutamate, cannabinoids, GABA and opioids. This review will cover the involvement of these neurotransmitters in nicotine addictive properties, with a special emphasis on the endogenous opioid system. Thus, endogenous enkephalins and beta-endorphins acting on mu-opioid receptors are involved in nicotine-rewarding effects, whereas opioid peptides derived from prodynorphin participate in nicotine aversive responses. An up-regulation of mu-opioid receptors has been reported after chronic nicotine treatment that could counteract the development of nicotine tolerance, whereas the down-regulation induced on kappa-opioid receptors seems to facilitate nicotine tolerance. Endogenous enkephalins acting on mu-opioid receptors also play a role in the development of physical dependence to nicotine. In agreement with these actions of the endogenous opioid system, the opioid antagonist naltrexone has shown to be effective for smoking cessation in certain sub-populations of smokers.     

Basal and potassium-evoked release of angiotensin II from the rat hypothalamus

Although the protein components of the renin-angiotensin system have been localized in the brain, it remains to be established whether or not angiotensin II (Ang II) is generated locally and secreted into the interstitial fluid of the brain. We have addressed this issue in vitro by perifusing explants of the rat hypothalamo-neurohypophysial system (HNS) (5 explants per chamber, 37°C) with Krebs solution at a rate of 1 ml/min. The release of Ang II immunoreactivity (Ang II-ir) and arginine vasopressin immunoreactivity (AVP-ir) in the medium was measured 3–5 h after HNS dissection and again after addition of potassium (K⁺) to the perifusate. Samples of the fluid perifusing the HNS were collected for 30-min intervals and concentrated using Sep-Pak C₁₈ cartridges. Release of Ang II-ir was significantly increased during perfusion with 70 mM K⁺ (from 29 ± 14pg/30min to80 ± 17pg/30min, P < 0.01). This increase coincided with a dramatic rise in the release of AVP-ir (from50 ± 35pg/30min to values above2000pg/30min). The associated release of Ang II-ir in response to depolarization by K⁺ is consistent with the hypothesis that Ang II can be secreted by neuronal elements of the brain, possibly via a regulated pathway.     

Neurobiological mechanisms involved in nicotine dependence and reward: Participation of the endogenous opioid system

Nicotine is the primary component of tobacco that maintains the smoking habit and develops addiction. The adaptive changes of nicotinic acetylcholine receptors produced by repeated exposure to nicotine play a crucial role in the establishment of dependence. However, other neurochemical systems also participate in the addictive effects of nicotine including glutamate, cannabinoids, GABA and opioids. This review will cover the involvement of these neurotransmitters in nicotine addictive properties, with a special emphasis on the endogenous opioid system. Thus, endogenous enkephalins and beta-endorphins acting on mu-opioid receptors are involved in nicotine-rewarding effects, whereas opioid peptides derived from prodynorphin participate in nicotine aversive responses. An up-regulation of mu-opioid receptors has been reported after chronic nicotine treatment that could counteract the development of nicotine tolerance, whereas the down-regulation induced on kappa-opioid receptors seems to facilitate nicotine tolerance. Endogenous enkephalins acting on mu-opioid receptors also play a role in the development of physical dependence to nicotine. In agreement with these actions of the endogenous opioid system, the opioid antagonist naltrexone has shown to be effective for smoking cessation in certain sub-populations of smokers.     

Naloxone alters the local metabolic rate for glucose in discrete brain regions associated with opiate withdrawal

The current 2-deoxy-d-[1-¹⁴C]glucose investigation was performed to test the hypothesis that endogenous opioids influence basal synaptic activity within discrete brain regions. To examine this hypothesis, the effects of naloxone (1.0 mg/kg s.c.) on local cerebral metabolic rate for glucose (LCMR_glu) in 84 brain regions were compared to saline controls. The specificity of naloxone's effects for opioid receptors was assessed by the coadministration of the opiate agonist morphine in a separate group. In naloxone-treated rats, there was a significant decrease in LCMR_glu in the locus coeruleus (LC) and an increase in the central nucleus of the amygdala (CAMY), supporting a tonic influence of endogenous opioids on these regions. These metabolic changes were reversed by coadministered morphine, indicating that naloxone's metabolic actions are specific for opioid receptors. Based on the role of the LC and CAMY in opiate withdrawal, the present results suggest a subthreshold naloxone precipitated withdrawal from endogenous opioids. Although morphine administered alone significantly reduced LCMR_glu in 16 brain regions, these did not include the LC or the CAMY. These results identify brain regions in which synaptic activity is under tonic modulation by endogenous opioids.     

Amastatin potentiation of drinking induced by blood-borne angiotensin: evidence for mediation by endogenous brain angiotensin

Angiotensinergic synapses in the central nervous system (CNS) have been proposed to be involved in drinking induced by both intracerebroventricular (i.c.v.) and peripheral administration of angiotensins. In the present studies, we tested this hypothesis with i.c.v. application of amastatin, an aminopeptidase A inhibitor, to block peptide degradation. Potentiation of i.c.v. angiotensin II (Ang II)-induced drinking responses was observed when amastatin and Ang II were administered. Amastatin did not potentiate drinking to carbachol which demonstrates that the enhancement is specific to peptides. Centrally administered amastatin also potentiated drinking following systematic administration of Asn¹ angiotensin II. (Asn¹ Ang II). The results are consistent with the hypothesis that CNS angiotensin synapses are involved in the dipsogenic response that results from elevated levels of circulating angiotensin.