Towards the therapeutic use of intranasal neuropeptide administration in metabolic and cognitive disorders.

The nose provides an effective way for delivering neuropeptides to the central nervous system, bypassing the blood-brain barrier and avoiding systemic side effects. Thereby intranasal neuropeptide administration enables the modulation of central nervous signaling pathways of body weight regulation and cognitive functions. Central nervous control of energy homeostasis is assumed to rely on hypothalamic neuropeptidergic pathways that are triggered by the peripheral adiposity signals insulin and leptin conveying the amount of body fat to the brain. Melanocortins, including alpha-melanocyte stimulating hormone (alpha-MSH), are essential for inducing anorexigenic/catabolic effects, i.e. for inhibiting caloric intake and increasing energy expenditure. Insulin, in addition to its function as an adiposity signal, also influences memory formation. Here we present a series of studies on the intranasal administration of MSH/ACTH4-10, a melanocortin receptor agonist, and of insulin. Prolonged administration of MSH/ACTH4-10 induced weight loss in normal-weight, but not in overweight humans. Intranasal insulin reduced body fat and improved memory functions in the absence of adverse peripheral side effects. Our results may contribute to the future development of therapeutic strategies in disorders like obesity and cognitive impairments that derive from dysfunctions of central nervous neuropeptidergic pathways.

To dip or not to dip: on the physiology of blood pressure decrease during nocturnal sleep in healthy humans.

That sleep is accompanied by a blood pressure decrease is well known; however, the underlying physiology deserves further investigation. The present study examines in healthy subjects 2 main questions: is this dipping actively evoked? and what are the consequences of nondipping for daytime blood pressure? Nocturnal blood pressure was extrinsically elevated in 12 sleeping subjects to mean daytime values by continuously infused phenylephrine. This nondipping significantly lowered morning blood pressure during rest and 3 hours after resuming physical activity compared with a control condition (isotonic saline). Neither muscle sympathetic nerve activity nor sensitivity of alpha-adrenoceptors was reduced. However, the set point for initiation of regulatory responses through the baroreflex was clearly shifted toward lower blood pressure levels. Our results support the hypothesis of an actively regulated central mechanism for blood pressure resetting and set point consolidation of the baroreflex during nighttime sleep. This is suggested by the fact that extrinsically induced nondipping induces sustained decrease in blood pressure during the following morning through an actively lowered baroreflex set point.

Shift of monocyte function toward cellular immunity during sleep.

BACKGROUND: Sleep is considered to strengthen immune defense. We hypothesized that sleep achieves this effect by shifting the balance between types 1 and 2 cytokine activity toward increased type 1 activity, thereby supporting adaptive cellular immune responses. METHODS: We analyzed monocyte-derived type 1 (interleukin 12 [IL-12]) and type 2 (IL-10) cytokines by means of multiparametric flow cytometry in healthy human subjects (n = 11) during a regular sleep-wake cycle and 24 hours of wakefulness. RESULTS: Sleep increased the number of IL-12-producing monocytes and concurrently decreased the number of IL-10-producing monocytes, thereby inducing clear rhythms in these cells, with maximum numbers at 2:20 and 11:30 am, respectively. The rhythms were completely absent during continuous wakefulness. Correlation analyses and supplementary in vitro studies suggest that high prolactin and low cortisol levels are factors contributing to the shift in the IL-12/IL-10 ratio toward increased IL-12 activity during sleep. CONCLUSIONS: Monocyte-derived IL-12 and IL-10 play a critical role for tuning the synapse between antigen-presenting cells and lymphocytes. By preferentially supporting type 1 IL-12 activity, sleep induces a 24-hour oscillation between predominant types 1 and 2 cytokines and, in this way, acts to globally increase the efficacy of adaptive immune responses. Improving sleep could represent a therapeutic option to enhance the success of vaccinations and success in the treatment of diseases (eg, atopic dermatitis and human immunodeficiency virus infection) that are characterized by type 2 cytokine overactivity.

Differential effects of hydrocortisone on sympathetic and hemodynamic responses to sympathoexcitatory manoeuvres in men.

Aim of the present study was to investigate the influence of hydrocortisone on muscle sympathetic nerve activity (MSNA) and hemodynamic parameters during different sympathoexcitatory manoeuvres in humans. The study focuses on the interaction of the hypothalamo-pituitary-adrenal system and the sympathetic nervous system. Hydrocortisone 100 mg or placebo was administered intravenously to eight young healthy subjects in a double-blind crossover design. After 6 h, blood pressure, heart rate and MSNA from the peroneal nerve were recorded at rest, during an arithmetic stress task, an apnea and a cold pressor test. Hydrocortisone treatment increased serum cortisol levels to the upper physiological range and suppressed basal levels of adrenocorticotropin. During mental stress, MSNA, heart rate and blood pressure levels were elevated independently of hydrocortisone pre-treatment. However, hydrocortisone induced a sustained increase in basal heart rate throughout the whole experiment. A stronger increase in diastolic blood pressure was observed during apnea and cold pressor test in the hydrocortisone experiments. MSNA or plasma catecholamines at rest or during the manoeuvres were not affected by hydrocortisone. The observed hydrocortisone effects may be due to an increased responsiveness of adrenergic receptors towards catecholamines or a central modulation of the baroreflex involving parasympathetic mechanisms. Further studies are needed to confirm that the increase in MSNA during mental stress does not depend on a concomitant activation of the hypothalamo-pituitary-adrenal system.

Sleep-like concentrations of growth hormone and cortisol modulate type1 and type2 in-vitro cytokine production in human T cells.

Slow wave sleep (SWS) is characterized by maximum release of growth hormone (GH) and minimum release of cortisol. We hypothesized that this hormonal pattern during SWS leads, in addition to generally increased T cell cytokine production, to a shift towards type1 cytokines. To test this hypothesis, blood was sampled from 8 humans during SWS, and whole blood cultures were activated in-vitro with ionomycin and phorbol-myrestate-acetate (PMA) in the absence and presence of GH neutralizing antibody (Ab) or physiological concentrations of cortisol. Production of interferon-gamma (IFN-gamma), interleukin-2 (IL-2), IL-4, and tumor necrosis factor-alpha (TNF-alpha) was measured using multiparametric flow cytometry. GH Ab decreased IFN-gamma+CD4+ cells but had no effect on other cytokines. Cortisol alone and in combination with GH Ab decreased CD4+ and CD8+ cells producing IFN-gamma, TNF-alpha and IL-2. Simultaneously, these two reactants reduced IL-4+CD4+ cells, so that the ratio of IFN-gamma/IL4 producing CD4+ cells indicated an unexpected shift towards type1 dominance. Results support the view that release of GH by increasing particularly production of IFN-gamma can contribute to the shift in type1/type2 balance towards type1 activity characterizing SWS. Suppression of cortisol during this sleep period enhances both type1 and type2 activity. Yet, our finding of predominant type1 activity after cortisol administration, rules out any relevance of this suppression for the shift towards type1 activity during SWS.

Manipulating central nervous mechanisms of food intake and body weight regulation by intranasal administration of neuropeptides in man.

Maintaining a stable body weight set-point is assumed to rely on a homeostatic central nervous system (CNS) regulation of body fat with the particular involvement of hypothalamic pathways. The peripheral adiposity signals insulin and leptin convey information on the amount of energy stored as body fat to the arcuate nucleus of the hypothalamus, where anabolic/orexigenic and catabolic/anorexigenic pathways interact to regulate food intake and energy expenditure. One of the most prominent orexigenic messengers is neuropeptide Y (NPY), whereas melanocortins, including alpha-melanocyte-stimulating hormone (alpha-MSH), are essential for inducing anorexigenic effects. The melanocortin receptor 4 (MC4-R) plays the most important role in mediating catabolic effects of alpha-MSH. In this review, we present a series of own studies on NPY, insulin and MSH/ACTH4-10, an MC4-R agonist. The studies were all based on the intranasal route of administration which enables a direct access of the peptides to hypothalamic functions. NPY acutely attenuated electrocortical signs of meal-related satiety. Prolonged intranasal administration of insulin as well as of MSH induced weight loss in healthy human subjects. However, overweight subjects did not lose body fat after MSH administration. The results corroborate in humans the significance of all three messengers for the central nervous regulation of adiposity and might contribute to the future development of medical strategies against body-weight-related disorders.

Intranasal insulin reduces body fat in men but not in women.

Insulin acts in the central nervous system to reduce food intake and body weight and is considered a major adiposity signal. After intranasal administration, insulin enters the cerebrospinal fluid compartment and alters brain functions in the absence of substantial absorption into the blood stream. Here we report the effects of 8 weeks of intranasal administration of insulin (4 x 40 IU/day) or placebo to two groups of healthy human subjects (12 men and 8 women in each group). The insulin-treated men lost 1.28 kg body wt and 1.38 kg of body fat, and their waist circumference decreased by 1.63 cm. Plasma leptin levels dropped by an average of 27%. In contrast, the insulin-treated women did not lose body fat and gained 1.04 kg body wt due to a rise in extracellular water. Our results provide a strong, first confirmation in humans that insulin acts as a negative feedback signal in the regulation of adiposity and point to a differential sensitivity to the catabolic effects of insulin based on sex.

Intranasal atrial natriuretic peptide acts as central nervous inhibitor of the hypothalamo-pituitary-adrenal stress system in humans.

Increased hypothalamo-pituitary-adrenal activity contributes to morbidity in widespread metabolic and psychiatric diseases. Inhibition of hypercortisolism represents a promising therapeutic strategy in these conditions, which currently cannot be used. Here, we tested the hypothesis that atrial natriuretic peptide (ANP) administered intranasally is a safe and feasible inhibitor of pituitary-adrenal activity at the central nervous level. Thirty minutes after intranasal administration of ANP (1 mg) and placebo, pituitary-adrenal activity was stimulated in 18 healthy men by two tests: 1) a standard insulin-hypoglycemia test and 2) CRH combined with vasopressin (VP), respectively. ACTH, cortisol, VP, blood pressure, heart rate, and measures of fluid balance were also recorded. Pretreatment with ANP suppressed cortisol (P < 0.01) and ACTH (P < 0.05) secretory responses to insulin-induced hypoglycemia to about half of that seen after placebo, but pituitary-adrenal activity was not suppressed by CRH/VP injection (P > 0.7). Indicators of fluid balance, cardiovascular parameters, and self-report measures were not influenced by the treatment. Results indicate a strong inhibition of stimulated pituitary-adrenal activity after intranasal administration of ANP. The absence of an effect on CRH/VP-induced pituitary-adrenal responses suggests a direct action of the peptide on the central nervous system inhibiting stimulated hypothalamo-pituitary-adrenal activity at the hypothalamic level.

Improvement of sleep and pituitary-adrenal inhibition after subchronic intranasal vasopressin treatment in elderly humans.

Subchronic intranasal treatment with argininevasopressin (AVP) has been shown to exert a strong ameliorating effect on sleep and slow wave sleep (SWS) deficits in elderly. However, AVP is also a potent stimulus of the pituitary-adrenal stress system, which is usually inhibited during early, SWS-rich sleep. A disinhibition of pituitary-adrenal activity during sleep is correlated with aging and is considered a pathologic factor contributing to various age-related diseases. Here, we examined whether the beneficial effect of prolonged intranasal AVP administration on sleep in aged would be associated with a concomitant decrease in pituitary-adrenal inhibition and effects on other neuroendocrine features of sleep. Twenty-six healthy elderly (mean 72.9 yr) with mild sleep complaints were investigated in a placebo controlled double-blind study. One group was treated daily each morning and evening with intranasal AVP (2 x 20 IU) for 10 weeks, the other received placebo. During polysomnographical recordings taken at the beginning and end of the treatment period, blood was sampled every 15 min. Intranasal AVP increased SWS on average by +21.5 min (p<0.02). The effect persisted on the night after acute withdrawal of the peptide treatment with no rebound occurring. Notably, rather than increasing pituitary-adrenal activity, AVP decreased the early sleep cortisol nadir on average by 0.5 microg/dl (p<0.05). AVP did not induce any measurable changes in fluid balance or cardiovascular activity. Overall, results indicate a promoting effect of AVP on SWS in aged accompanied by a beneficial rather than impairing influence on the neuroendocrine pattern of sleep.

Growth hormone-releasing hormone facilitates hypoglycemia-induced release of cortisol.

Early sleep in humans is characterized by a distinct suppression of pituitary-adrenal activity coinciding with enhanced activity of the somatotropic axis. Here, we tested in awake humans the hypothesis of an inhibiting influence of hypothalamic growth hormone-releasing hormone (GHRH) on pituitary-adrenal activity. For this purpose, pituitary-adrenal activity was stimulated in 10 men through a standard insulin-hypoglycemia-test (IHT) and in another 10 men through combined administration of CRH/vasopressin. Stimulation was performed in each man on three conditions following pretreatment with Placebo and GHRH administered intravenously (50 microg) or intranasally (300 microg) 1 h before. GH, ACTH and cortisol as well as blood pressure and heart rate were measured repeatedly. Contrary to expectations, pretreatment with GHRH did not suppress but enhanced secretion of cortisol upon insulin-induced hypoglycemia regardless of the route of GHRH pretreatment (p<0.05). In contrast, GHRH did not facilitate cortisol release after stimulation with CRH/vasopressin. Changes in ACTH remained inconsistent. Plasma levels of GH increased significantly after i.v. GHRH application, but remained unchanged after the intranasal administration. Blood pressure and heart rate were not influenced by the treatments. Results indicate facilitating effects of GHRH mediated at a suprapituitary (i.e. hypothalamic) level as suggested by restriction of the effect to the hypoglycemia-induced cortisol release with no effects after pituitary stimulation with CRH/vasopressin.

Systemic immune parameters and sleep after ultra-low dose administration of IL-2 in healthy men.

A somnogenic function is suspected for various cytokines. Foregoing experiments in humans indicated a selective increase in the production of interleukin-2 (IL-2) during sleep as compared with nocturnal wakefulness. Here, we examined whether conversely, IL-2 exerts a promoting influence on sleep. Also, the effects of IL-2 administered at ultra-low doses on systemic immune and endocrine parameters were assessed. Eighteen healthy men participated in three night sessions, receiving subcutaneously at 19:00 h either placebo or recombinant human IL-2 at doses of 1000 and 10,000 IU/kg bw. Polysomnographical recordings were obtained between 23:00 and 07:00 h. Blood was collected repeatedly to determine (i) white blood cell (WBC) counts including the enumeration of monocytes, natural killer (NK) cells, and lymphocyte subsets, (ii) serum concentrations of IL-2, soluble IL-2 receptor (sIL-2r), IL-4, IL-6, and interferon-gamma (IFN-gamma), and (iii) concentrations of adrenocorticotropin (ACTH), cortisol, thyreotropin (TSH), and growth hormone (GH). Changes after 1000 IU/kg bw IL-2 generally remained non-significant. However, distinct effects occurred after 10,000 IU/kg bw IL-2, inducing serum IL-2 concentrations selectively activating the high affinity IL-2 receptor. At this dose, IL-2 reduced the number of circulating lymphocytes (including all major subtypes) and NK cells, while counts of monocytes and neutrophils were increased. IL-4 release was stimulated and IFN-gamma concentration reduced after IL-2. Also, IL-2 increased the TSH concentration. There were no hints at a sleep promoting effect of IL-2. Immune changes suggest that nocturnal IL-2 administration induces a shift towards Th2 mediated defense.