Central cardiovascular action of neuropeptide Y in conscious rabbits

Creatinine as a Urinary Marker of the Purine Derivatives Excretion in Urine Spot Samples of Lambs Fed Peach Palm Meal

The objective was to evaluate the influence of diets on lambs using different levels of peach palm meal as a replacement for maize (0, 10, 40, 60, and 85% of diet dry matter) on the endogenous creatinine clearance (CC), urine concentration ratio of purine derivatives to creatinine (PDC index), and daily creatinine excretion (DCE) as a marker to estimate purine derivatives (PD) excretion from urinary spot samples collected at different time points (4, 8, 12, 16, 20, 24 h after morning feeding) compared to 24-h total urine collection. The measured parameters were voluntary intake, urinary volume, CC, DCE, the concentration of plasma creatinine, and PD and purine derivatives’ excretion (PDE). Five lambs were allocated to metabolic cages and distributed in a 5 × 5 Latin square. Urine collection was taken daily on days 16 to 19 of each experimental period. The inclusion of peach palm meal linearly reduced the intake of dry matter (g kg BW−0.75, p = 0.005), crude protein (g kg BW−0.75, p = 0.010), metabolizable energy (MJ kg BW−0.75, p = 0.010) and CC (p < 0.0001). It also quadratically affected the urinary volume (p = 0.008) and DCE (p = 0.004). There was a linear decrease for PDC index (p = 0.032) and PDE (p < 0.0001) measured in the 24-h total urine with peach palm meal levels. The different times of spot urine sampling did not affect (p > 0.05) the PDC index and PDE. Peach palm meal decreases the CC thereby compromising the use of a mean value of DCE as a PDE marker in spot urine samples. There is greater accuracy when using different values of DCE obtained for each diet as markers for the PDE in spot urine samples. Unconventional foodstuffs of low palatability affecting the voluntary intake of feed change the renal function.

The role of food intake regulating peptides in cardiovascular regulation

Obesity is a risk factor that worsens cardiovascular events leading to higher morbidity and mortality. However, the exact mechanisms of relation between obesity and cardiovascular events are unclear. Nevertheless, it has been demonstrated that pharmacological therapy for obesity has great potential to improve some cardiovascular problems. Therefore, it is important to determine the common mechanisms regulating both food intake and blood pressure. Several hormones produced by peripheral tissues work together with neuropeptides involved in the regulation of both food intake and blood pressure. Anorexigenic (food intake lowering) hormones such as leptin, glucagon-like peptide-1 and cholecystokinin cooperate with α-melanocyte-stimulating hormone, cocaine- and amphetamine-regulated peptide as well as prolactin-releasing peptide. Curiously their collective actions result in increased sympathetic activity, especially in the kidney, which could be one of the factors responsible for the blood pressure increases seen in obesity. On the other hand, orexigenic (food intake enhancing) peptides, especially ghrelin released from the stomach and acting in the brain, cooperates with orexins, neuropeptide Y, melanin-concentrating hormone and galanin, which leads to decreased sympathetic activity and blood pressure. This paradox should be intensively studied in the future. Moreover, it is important to know that the hypothalamus together with the brainstem seem to be major structures in the regulation of food intake and blood pressure. Thus, the above mentioned regions might be essential brain components in the transmission of peripheral signals to the central effects. In this short review, we summarize the current information on cardiovascular effects of food intake regulating peptides.

Quantitative and qualitative evaluation of CART-containing cells in adrenal glands of male rats with hypertension

Adrenal activity is stimulated and secretion of stress hormones is increased during advanced stages of renovascular hypertension. The literature suggests that the neuropeptide, cocaine and amphetamine regulated transcript (CART), might regulate adrenal secretory function and thus could influence its activity. We assessed potential quantitative and qualitative changes in the cells that contained CART in the adrenal glands of rats with renovascular hypertension. The renal arteries of ten rats were subjected to a clipping procedure, i.e., two-kidney one-clip (2K1C) model of arterial hypertension, and after 6 weeks each rat developed stable hypertension. CART was localized using immunohistochemistry. CART was detected in a large population of cells in the medulla, sparse nerve fibers in the cortex and the capsule of the adrenal gland. The population of CART-positive cells in adrenal glands of two kidney-one clip (2K1C) treated rats was greater and their immunoreactivity was increased compared to controls. Similarly, the length, width, area and diameter of CART-immunoreactive cells were significantly greater in the hypertensive rats than in controls. We demonstrated that renovascular hypertension alters the number and immunoreactivity of CART-containing cells in adrenal glands.

Neuropeptide Y acts in the paraventricular nucleus to suppress sympathetic nerve activity and its baroreflex regulation

Neuropeptide Y (NPY), a brain neuromodulator that has been strongly implicated in the regulation of energy balance, also acts centrally to inhibit sympathetic nerve activity (SNA); however, the site and mechanism of action are unknown. In chloralose-anaesthetized female rats, nanoinjection of NPY into the paraventricular nucleus of the hypothalamus (PVN) dose-dependently suppressed lumbar SNA (LSNA) and its baroreflex regulation, and these effects were blocked by prior inhibition of NPY Y1 or Y5 receptors. Moreover, PVN injection of Y1 and Y5 receptor antagonists in otherwise untreated rats increased basal and baroreflex control of LSNA, indicating that endogenous NPY tonically inhibits PVN presympathetic neurons. The sympathoexcitation following blockade of PVN NPY inhibition was eliminated by prior PVN nanoinjection of the melanocortin 3/4 receptor inhibitor SHU9119. Moreover, presympathetic neurons, identified immunohistochemically using cholera toxin b neuronal tract tracing from the rostral ventrolateral medulla (RVLM), express NPY Y1 receptor immunoreactivity, and patch-clamp recordings revealed that both NPY and α-melanocyte-stimulating hormone (α-MSH) inhibit and stimulate, respectively, PVN-RVLM neurons. Collectively, these data suggest that PVN NPY inputs converge with α-MSH to influence presympathetic neurons. Together these results identify endogenous NPY as a novel and potent inhibitory neuromodulator within the PVN that may contribute to changes in SNA that occur in states associated with altered energy balance, such as obesity and pregnancy.

Neuropeptide Y (NPY): genetic variation in the human promoter alters glucocorticoid signaling, yielding increased NPY secretion and stress responses

OBJECTIVES

This study sought to understand whether genetic variation at the Neuropeptide Y (NPY) locus governs secretion and stress responses in vivo as well as NPY gene expression in sympathochromaffin cells.

BACKGROUND

The NPY is a potent pressor peptide co-released with catecholamines during stress by sympathetic axons. Genome-wide linkage on NPY secretion identified a LOD (logarithm of the odds ratio) peak spanning the NPY locus on chromosome 7p15.

METHODS

Our approach began with genomics (linkage and polymorphism determination), extended into NPY genetic control of heritable stress traits in twin pairs, established transcriptional mechanisms in transfected chromaffin cells, and concluded with observations on blood pressure (BP) in the population.

RESULTS

Systematic polymorphism tabulation at NPY (by re-sequencing across the locus: promoter, 4 exons, exon/intron borders, and untranslated regions; on 2n = 160 chromosomes of diverse biogeographic ancestries) identified 16 variants, of which 5 were common. We then studied healthy twin/sibling pairs (n = 399 individuals), typing 6 polymorphisms spanning the locus. Haplotype and single nucleotide polymorphism analyses indicated that proximal promoter variant ∇-880Δ (2-bp TG/-, Ins/Del, rs3037354) minor/Δ allele was associated with several heritable (h(2)) stress traits: higher NPY secretion (h(2) = 73 ± 4%) as well as greater BP response to environmental (cold) stress, and higher basal systemic vascular resistance. Association of ∇-880Δ and plasma NPY was replicated in an independent sample of 361 healthy young men, with consistent allelic effects; genetic variation at NPY also associated with plasma NPY in another independent series of 2,212 individuals derived from Australia twin pairs. Effects of allele -880Δ to increase NPY expression were directionally coordinate in vivo (on human traits) and in cells (transfected NPY promoter/luciferase reporter activity). Promoter -880Δ interrupts a novel glucocorticoid response element motif, an effect confirmed in chromaffin cells by site-directed mutagenesis on the transfected promoter, with differential glucocorticoid stimulation of the motif as well as alterations in electrophoretic mobility shifts. The same -880Δ allele also conferred risk for hypertension and accounted for approximately 4.5/approximately 2.1 mm Hg systolic BP/diastolic BP in a population sample from BP extremes.

CONCLUSIONS

We conclude that common genetic variation at the NPY locus, especially in proximal promoter ∇-880Δ, disrupts glucocorticoid signaling to influence NPY transcription and secretion, raising systemic vascular resistance and early heritable responses to environmental stress, eventuating in elevated resting BP in the population. The results point to new molecular strategies for probing autonomic control of the human circulation and ultimately susceptibility to and pathogenesis of cardiovascular and neuropsychiatric disease states.

Lack of association between impaired glucose tolerance and appetite regulating hormones in patients with obstructive sleep apnea

STUDY OBJECTIVES

Understanding the etiologic mechanisms underlying impaired glucose tolerance in obstructive sleep apnea (OSA) would assist development of therapies against this comorbidity. We hypothesized that in patients with OSA impaired glucose tolerance (IGT) would be associated with elevated levels of hormones associated with appetite regulation (leptin, ghrelin, neuropeptide Y [NPY] and peptide tyrosine-tyrosine [PYY]).

METHOD

We studied 68 OSA patients (mean AHI 22 events/h) and 37 age and weight matched healthy controls recruited by advertisement. All participants received a standardized evening meal, attended polysomnography and an oral glucose tolerance test (OGTT) on waking. Hormones were measured in blood taken before sleep (22:30) and at the start of the OGTT.

RESULTS

Impaired glucose tolerance was present in 54% of patients and 32% of controls (p = 0.05). The only differences between groups was that leptin was significantly higher at 22:30 in OSA patients compared to controls (9.6 ng/L vs 7.9 ng/L, p = 0.05). OSA patients had marginally elevated plasma NPY levels at 22:30 (56.6 [52, 67] pmol/L vs 51.1[47.3, 61] pmol/L; p = 0.04). No differences in ghrelin, PYY or NPY were observed between patients with IGT and those without. However OSA patients with IGT had significantly higher value of leptin at both 22:30 (10.9 [7.7, 15.9] ng/mL vs 7.4 [5.6, 12.3] ng/mL, p = 0.02) and 07:00 (11.6 [7.6, 16.2] ng/mL vs 6.9 [5.4, 12.6] ng/mL, p = 0.024) than those without. In multivariate analysis the only major association of leptin was body mass index.

CONCLUSION

Clinically significant abnormalities of appetite regulating hormones are not present in OSA. Appetite regulating hormones did not differ in OSA patients with and without impaired glucose tolerance.

Insulin acts in the arcuate nucleus to increase lumbar sympathetic nerve activity and baroreflex function in rats

Although the central effects of insulin to activate the sympathetic nervous system and enhance baroreflex gain are well known, the specific brain site(s) at which insulin acts has not been identified. We tested the hypotheses that (1) the paraventricular nucleus of the hypothalamus (PVN) and the arcuate nucleus (ArcN) are necessary brain sites and (2) insulin initiates its effects directly in the PVN and/or the ArcN. In α-chloralose anaesthetised female Sprague–Dawley rats, mean arterial pressure (MAP), heart rate (HR) and lumbar sympathetic nerve activity (LSNA) were recorded continuously, and baroreflex gain of HR and LSNA were measured before and during a hyperinsulinaemic–euglycaemic clamp. After 60 min, intravenous infusion of insulin (15 mU kg−1 min−1), but not saline, significantly increased (P < 0.05) basal LSNA (to 228 ± 28% control) and gain of baroreflex control of LSNA (from 3.8 ± 1.1 to 7.4 ± 2.4% control mmHg−1). These effects were reversed (P < 0.05) by local inhibition (bilateral microinjection of musimol) of the PVN (LSNA to 124 ± 8.8% control; LSNA gain to 3.9 ± 1.7% control mmHg−1) or of the ArcN (LSNA in % control: from 100 ± 0 to 198 ± 24 (insulin), then 133 ± 23 (muscimol) LSNA gain in % control mmHg−1: from 3.9 ± 0.3 to 8.9 ± 0.9 (insulin), then 5.1 ± 0.5 (muscimol)). While insulin receptor immunoreactivity was identified in neurons in pre-autonomic PVN subnuclei, microinjection of insulin (0.6, 6 and 60 nU) into the PVN failed to alter LSNA or LSNA gain. However, ArcN insulin increased (P < 0.05) basal LSNA (in % control to 162 ± 19, 0.6 nU; 193 ± 19, 6 nU; and 205 ± 28, 60 nU) and LSNA baroreflex gain (in % control mmHg−1 from 4.3 ± 1.2 to 6.9 ± 1.0, 0.6 nU; 7.7 ± 1.2, 6 nU; and 7.8 ± 1.3, 60 nU). None of the treatments altered MAP, HR, or baroreflex control of HR. Our findings identify the ArcN as the site at which insulin acts to activate the sympathetic nervous system and increase baroreflex gain, via a neural pathway that includes the PVN.

Ghrelin inhibits autonomic function in healthy controls, but has no effect on obese and vagotomized subjects

OBJECTIVE

Ghrelin inhibits sympathetic nervous system (SNS) activity in rodents. We studied the effect of ghrelin on healthy humans, in obesity and in vagotomized subjects.

DESIGN

Randomized, double-blinded, placebo-controlled crossover.

SUBJECTS

Seven lean [mean body mass index (BMI) 23·6 ± 0·9 kg/m(2) ], seven morbidly obese (mean BMI 50·9 ± 4·4 kg/m(2) ) and seven post-gastrectomy subjects (mean BMI 22·0 ± 1·1 kg/m(2) ).

MEASUREMENTS

Subjects were randomized to intravenous ghrelin (5 pmol/kg/min) or saline over 270 min. Subjects had a fixed calorie meal and a free choice buffet during the infusion. Heart rate variability (HRV) was measured. Total power (TP) represents overall autonomic function, low-frequency (LF) power represents sympathetic and parasympathetic activity, and high-frequency (HF) power represents parasympathetic activity. Very low (VLO) frequency represents the frequency band associated with thermogenesis.

RESULTS

Preliminary anova analysis, looking at all three subject groups together, showed that ghrelin had an overall highly significant inhibitory effect on TP (P = 0·001), HF power (P = 0·04), VLO power (P = 0·03) and no effect on LF (P = 0·07). Further subset analysis revealed that ghrelin had a significant effect on TP (P = 0·03), borderline effect on LF power (P = 0·06) and no effect on HF power (P = 0·1) in healthy controls. By contrast in obese subjects, ghrelin had no effect on TP (P = 0·3), LF (P = 0·5) and HF (P = 0·06) and also no effect in the vagotomized subjects on TP (P = 0·7), LF (P = 0·7) and HF (P = 0·9). Ghrelin had no effect on the LF/HF ratio.

CONCLUSIONS

Ghrelin inhibits SNS activity in healthy controls with a moderate effect on parasympathetic nervous system activity but had no effect on obese subjects. Vagotomized subjects also did not respond to ghrelin, suggesting the vagus nerve is important for the effects of peripheral ghrelin on the SNS.

Higher levels of plasma TNF-alpha and neuropeptide Y in hypertensive patients with obstructive sleep apnea syndrome

Resistant hypertension is always fount to be accompanied with obstructive sleep apnea syndrome (OSAS). Previous studies assumed inflammation participated in OSAS and hypertension. The fact that tumor necrosis factor a (TNF-alpha) was related to OSAS, while neuropeptide Y (NPY) was related to hypertension, was widely reported separately. To investigate the involvement of TNF-alpha and NPY simultaneously in hypertension accompanied with OSAS, 417 subjects who underwent the polymonograph and blood pressure measurement were consecutively selected. Plasma TNF-alpha and NPY levels were determined in normotensive with OSAS (n = 113), hypertensive without OSAS (n = 73), hypertensive with OSAS (n = 134), and those of controls (n = 97), respectively. A significant increase of plasma TNF-alpha and NPY were both observed in hypertensive subjects with or without OSAS, the highest level of TNF-alpha and NPY were in hypertension with the OSAS group. TNK-alpha, NPY, and neck circumference contributed to OSAS and hypertension as risk factors in the logistic regression model. Neck circumference was impacted by apnea/hyponea index, mean diastolic blood pressure, and TNF-alpha level, which was indicated via the multiple linear model. The present study indicated a positive interplay between plasma TNF-alpha, NPY, hypertension, and OSAS in the Han population of Xinjiang. Although there is evidence that inflammation plays a role in the pathophysiology of hypertension and OSAS, clear evidence is still lacking, and raises the dilemma of the hen and the egg. Further studies are needed to clarify the role of inflammation in the pathogenesis of hypertension with OSAS, in which neck size should be considered as a linked independent factor.

Possible role of the histaminergic system in autonomic and cardiovascular responses to neuropeptide Y

Previous studies have demonstrated that neuropeptide Y (NPY) affects blood pressure (BP) in anesthetized rats. Here, we examined the effects of the third cerebral ventricular (3CV) injection of various doses of NPY on renal sympathetic nerve activity (RSNA) and BP in anesthetized rats. 3CV injection of NPY suppressed RSNA and BP in a dose-dependent manner. Moreover, suppressing effects of NPY on RSNA and BP were eliminated by lateral cerebral ventricular (LCV) preinjection of thioperamide, an antagonist of histaminergic H3-receptor, not diphenhydramine, an antagonist of histaminergic H1-receptor. In addition, 3CV injection of NPY accelerated gastric vagal nerve activity (GVNA) and inhibited brown adipose tissue sympathetic nerve activity (BAT-SNA) of anesthetized rats, and lowered brown adipose tissue temperature (BAT-T) of conscious rats. Thus, these evidences suggest that central NPY affects autonomic nerves containing RSNA, GVNA or BAT-SNA, and BP by mediating central histaminergic H3-receptors.

Neuropeptide Y and Leptin in Patients with Obstructive Sleep Apnea Syndrome

Neuropeptide Y (NPY) and leptin are two peptides involved in the regulation of body weight, energy balance, and sympathetic tone. This study investigates the independent role of apneas and obesity on NPY and leptin plasma levels in patients with obstructive sleep apnea syndrome (OSAS). To this end we compared their values in 23 obese (body mass index > 30 kg/m2) and 24 nonobese (body mass index < 27 kg/m2) patients with OSAS, and in 19 obese and 18 nonobese control subjects without OSAS. Patients who used continuous positive airway pressure for more than 4 hours/night were reexamined 3 and 12 months later. We found that NPY levels were increased (p < 0.01) in patients with OSAS independently of obesity. Leptin levels were also increased in OSAS but this was mostly associated to obesity. Continuous positive airway pressure treatment reduced NPY levels in all patients and leptin levels only in nonobese patients (p < 0.01). We concluded that NPY and leptin plasma levels are increased in patients with OSAS. Yet, whereas the former appear independent of obesity, the latter are mostly associated with obesity.

Melanocortin receptors mediate the excitatory effects of blood-borne murine leptin on hypothalamic paraventricular neurons in rat

The central pathways and mediators involved in sympathoexcitatory responses to circulating leptin are not well understood, although the arcuate-paraventricular nucleus (ARC-PVN) pathway likely plays a critical role. In urethane-anesthetized rats, ipsilateral intracarotid artery (ICA) injection of murine leptin (100 microg/kg) activated most PVN neurons tested. These responses were reduced by intracerebroventricular injection of the melanocortin subtype 3 and 4 receptor (MC3/4-R) antagonist SHU-9119 (0.6 nmol). The MC3/4-R agonist MTII (0.6 nmol icv) activated PVN neurons. Some PVN neurons that were excited by ICA leptin were inhibited by local application of neuropeptide Y (NPY, 2.5 ng). ICA leptin (100 microg/kg) excited presympathetic rostral ventrolateral medulla neurons and renal sympathetic nerve activity without significant change in blood pressure or heart rate; these effects were mimicked by intracerebroventricular injection of MTII (0.6 nmol). These data provide in vivo electrophysiological evidence to support the hypothesis that circulating leptin activates the sympathetic nervous system by stimulating the release of alpha-melanocyte-stimulating hormone in the vicinity of PVN neurons that are inhibited by the orexogenic peptide NPY.

Neural regulation of blood pressure by leptin and the related peptides

Recent biological advances make it possible to discover new peptides associated with obesity. Leptin, neuropeptide Y, corticotrophin-releasing factor (CRF), alpha-melanocyte stimulating hormone (alpha-MSH), and cocaine- and amphetamine-regulated transcript (CART) peptides are known to participate in appetite and feeding behavior. Various lines of evidence suggest that these peptides participate not only in feeding behavior but also in cardiovascular and sympathetic regulations. Both leptin and ghrelin are secreted from the peripheral tissue; then they reach the brain to modulate sympathetic activity. These two peptides seem to play important roles to transmit peripheral metabolic information to the brain, and to convert it to cardiovascular and sympathetic information. Leptin activates neurons containing alpha-melanocyte stimulating hormone and cocaine- and amphetamine-regulated transcript peptides, resulting in increases in sympathetic activity and blood pressure. Cardiovascular action of alpha-melanocyte stimulating hormone is mediated through melanocortin-4 receptor, and agouti-related protein (AGRP) plays a role as an endogenous melanocortin-4 receptor antagonist. In contrast, ghrelin and neuropeptide Y in the brain suppress sympathetic activity and decrease blood pressure. Depressor and sympathoinhibitory effects of central neuropeptide Y are inhibited by leptin. Furthermore, central ghrelin modulates baroreflex control of renal sympathetic nerve activity and heart rate. Thus, leptin and the related peptides, which participate in appetite and feeding behavior, seem to function together to regulate cardiovascular system and sympathetic nerve activity, and may play a key role in the association between obesity and hypertension.

Cardiovascular effects of leptin and orexins

Leptin, the product of the ob gene, is a satiety factor secreted mainly in adipose tissue and is part of a signaling mechanism regulating the content of body fat. It acts on leptin receptors, most of which are located in the hypothalamus, a region of the brain known to control body homeostasis. The fastest and strongest hypothalamic response to leptin in ob/ob mice occurs in the paraventricular nucleus, which is involved in neuroendocrine and autonomic functions. On the other hand, orexins (orexin-A and -B) or hypocretins (hypocretin-1 and -2) were recently discovered in the hypothalamus, in which a number of neuropeptides are known to stimulate or suppress food intake. These substances are considered important for the regulation of appetite and energy homeostasis. Orexins were initially thought to function in the hypothalamic regulation of feeding behavior, but orexin-containing fibers and their receptors are also distributed in parts of the brain closely associated with the regulation of cardiovascular and autonomic functions. Functional studies have shown that these peptides are involved in cardiovascular and sympathetic regulation. The objective of this article is to summarize evidence on the effects of leptin and orexins on cardiovascular function in vivo and in vitro and to discuss the pathophysiological relevance of these peptides and possible interactions.

Central cardiovascular action of urotensin II in conscious rats

OBJECTIVE

To examine the central cardiovascular action of urotensin II in conscious rats.

METHODS

Intracerebroventricular (ICV) injections of urotensin II (1 and 10 nmol) were carried out in conscious Wistar rats. The effects of intravenous (i.v.) urotensin II (10 nmol) were also determined.

RESULTS

The ICV injection of urotensin II at a dose of 1 nmol did not alter the arterial pressure or heart rate significantly, while 10 nmol urotensin II increased the arterial pressure and heart rate. The mean arterial pressure at 5 min of ICV urotensin II was 121 +/- 4 mmHg, which was significantly higher than that obtained by ICV injection of artificial cerebrospinal fluid (107 +/- 3 mmHg, P <0.05). In addition, significant increases in heart rate were observed 5-15 min after ICV urotensin II. Pre-treatment with pentolinium (5 mg/kg, i.v.) significantly attenuated the increases in mean arterial pressure (20 +/- 3 versus 8 +/- 2 mmHg, P <0.01) and heart rate (78 +/- 18 versus 7 +/- 5 beats/min, P <0.05) induced by ICV urotensin II. On the other hand, i.v. injection of urotensin II (10 nmol) elicited a depressor response associated with tachycardia; mean arterial pressure 5 min after injection was significantly lower in the urotensin II-injected rats (89 +/- 5 mmHg) than in the control rats (102 +/- 2 mmHg, P <0.05), and the heart rate was significantly higher in the former (402 +/- 11 versus 360 +/- 9 beats/min, respectively, P <0.05).

CONCLUSIONS

Central urotensin II produces pressor and tachycardic responses through sympathetic activation, while peripheral urotensin II exerts a vasodilation-mediated depressor response in conscious rats.

Central alpha-melanocyte-stimulating hormone acts at melanocortin-4 receptor to activate sympathetic nervous system in conscious rabbits

Intracerebroventricular injection of alpha-melanocyte-stimulating hormone (alpha-MSH) elicited increases in arterial pressure and renal sympathetic nerve activity in conscious rabbits. Pretreatment with intracerebroventricular injection of agouti-related protein, an endogenous melanocortin-3 and 4 receptor antagonist, prevented cardiovascular and sympathetic responses to alpha-MSH. Pretreatment with intracerebroventricular injection of JKC-363, a synthetic specific melanocortin-4 receptor antagonist, also prevented cardiovascular and sympathetic responses to alpha-MSH. In contrast, intravenous alpha-MSH (1 nmol) failed to cause any cardiovascular responses. These results suggest that intracerebroventricularly administered alpha-MSH acts at the melanocortin-4 receptor in the brain and activates sympathetic outflow, resulting in an increase in arterial pressure.

Cardiovascular and sympathetic effects of leptin

Several studies have shown the association between obesity and hypertension. The pathophysiologic mechanisms of obesity-related hypertension remain unknown. Clinical and experimental studies have shown that obesity is associated with enhanced sympathetic nervous activity. Thus, sympathetic nerve activation seems to play a major role in obesity-associated hypertension. However, the factors responsible for this sympathoactivation have not been identified. Leptin is an adipocyte-derived hormone that promotes weight loss by reducing appetite and food intake and by increasing energy expenditure through sympathetic stimulation to brown adipose tissue. Leptin also produces sympathoactivation to kidneys, hindlimb, and adrenal glands, indicating that the obesity-associated increase in sympathetic nerve activity could be due in part to these sympathetic effects of leptin. However, obesity is associated with leptin resistance, since high circulating levels of leptin were observed in obese subjects. Recent evidences indicate that this leptin resistance could be selective with preservation of sympathetic effects despite the loss of metabolic action of leptin. This suggests divergent central pathways underlying metabolic and sympathetic effects of leptin. Several neuropeptides have emerged as potent candidate mediators of leptin action in the central nervous system, including the melanocortin system, neuropeptide Y, and cortico-trophin releasing factor. A detailed understanding of the multitude and complexity of integrated neuronal circuits and neuropeptide-containing pathways in leptin action will help in understanding the pathogenesis of obesity and related disorders.

Chronic central infusion of orexin-A increases arterial pressure in rats

We determined the cardiovascular responses as well as food and water intakes to chronic intracerebroventricular administration of orexin-A and orexin-B for 14 days in conscious rats. Chronic intracerebroventricular infusion of orexin-A (50 pmol/h) elicited a significant increase in systolic blood pressure on the third day (+15.6 +/- 2.9 mm Hg), and during the continuous intracerebroventricular infusion of orexin-A the blood pressure returned to the baseline levels at day 14. In contrast, chronic intracerebroventricular infusion of orexin-B (50 pmol/h) failed to change systolic blood pressure during the 14 days of experimental periods. Chronic intracerebroventricular infusions of neither orexin-A nor orexin-B changed urinary catecholamine excretions, food and water intakes, and urine volumes at 7 and 14 days of infusion periods. Mean arterial pressure directly measured at 14 days did not differ among the groups of orexin-A, orexin-B, and artificial cerebrospinal fluid treatments. Both intravenous injections of pentolinium (5 mg/kg), a ganglion blocking agent, and CV-11974 (0.05 mg/kg), an AT(1) receptor antagonist, decreased arterial pressure; however, these responses were not different among the groups. These results suggest that central orexin-A participates in the short-term regulation of blood pressure; however, the contributions of central orexins to the long-term regulations of blood pressure, sympathetic nervous system, and appetite may be little.

Leptin signaling pathways in the central nervous system: interactions between neuropeptide Y and melanocortins

No other hormone has drawn more attention than leptin in recent studies on the control of appetite, body weight and obesity. This hormone is produced by adipose tissue and enters the brain via a saturable specific transport mechanism. Leptin acts in the hypothalamus to modulate food intake and heat production as well as several other neuroendocrine pathways. The mechanisms through which leptin exerts its central nervous effects are now better understood. Proopiomelanocortin- and neuropeptide Y-containing neurons in the hypothalamus have emerged as potent candidate mediators of leptin action. These two neuropeptides have been shown to exert opposing effects using different pathways. Recently, Cowley et al. (2001) described a new circuit in the regulation of neuronal activity by leptin with an interaction between these two pathways. These data add complexity to the mechanisms by which leptin achieves its effects in the central nervous system, but they also offer potential mechanisms to explain the phenomenon of leptin resistance observed in obesity.

Altered leptin signaling is sufficient, but not required, for hypotension associated with caloric restriction

Caloric restriction of mammals leads to decreases in blood pressure and heart rate. Although relevant clinically, the mechanisms involved, in terms of hormones and signaling pathways invoked, are currently not known. Circumstantial evidence suggests that leptin signaling may be involved with the bradycardia and hypotension associated with caloric restriction. This hypothesis was specifically tested using leptin-deficient mice (ob/ob) or leptin-receptor rats (Koletsky). Ob/ob mice were hypertensive during the light cycle relative to littermate controls (108 +/- 2 vs. 100 +/- 2 mmHg, respectively). Both ob/ob mice and wild-type mice exhibited hypotension and bradycardia on initiation of a 50% caloric restriction regime, suggesting that the loss of leptin during caloric restriction is not required to explain the cardiovascular effects. Blood pressure in Koletsky rats did not drop in response to caloric restriction during the light cycle, whereas blood pressure in littermate control rats significantly dropped. These data suggest that at least two pathways are involved with cardiovascular effects of caloric restriction: one dependent on leptin signaling and the other independent of the leptin axis.