Simon N. Thornton

Thirst and hydration: physiology and consequences of dysfunction.

The constant supply of oxygen and nutriments to cells (especially neurons) is the role of the cardiovascular system. The constant supply of water (and sodium) for cardiovascular function is the role of thirst and sodium appetite and kidney function. This physiological regulation ensures that plasma volume and osmolality are maintained within set limits by initiating behaviour and release of hormones necessary to ingest and conserve water and sodium within the body. This regulation is separated into 2 parts; intracellular and extracellular (blood). An increased osmolality draws water from cells into the blood thus dehydrating specific brain osmoreceptors that stimulate drinking and release of anti diuretic hormone (ADH or vasopressin). ADH reduces water loss via lowered urine volume. Extracellular dehydration (hypovolaemia) stimulates specific vascular receptors that signal brain centres to initiate drinking and ADH release. Baro/volume receptors in the kidney participate in stimulating the release of the enzyme renin that starts a cascade of events to produce angiotensin II (AngII), which initiates also drinking and ADH release. This stimulates also aldosterone release which reduces kidney loss of urine sodium. Both AngII and ADH are vasoactive hormones that could work to reduce blood vessel diameter around the remaining blood. All these events work in concert so that the cardiovascular system can maintain a constant perfusion pressure, especially to the brain. Even if drinking does not take place ADH, AngII and aldosterone are still released. Furthermore, it has been observed that treatment of hypertension, obesity, diabetes and cancer can involve renin-AngII antagonists which could suggest that, in humans at least, there may be dysfunction of the thirst regulatory mechanism.

Sodium Intake and Vascular Stiffness in Hypertension

The relationship between sodium and blood pressure (BP) continues to be the focus of intense research. In humans, the impact of sodium on systolic BP (SBP), diastolic BP (DBP), mean BP, and pulse pressure (PP) is currently thought to be quite similar for the 4 pressures and to occur practically with identical consequences (see reviews1–8). In this review, the effect of sodium on SBP is taken into consideration mainly for a very simple but important reason: in recent years, SBP and PP have become the parameters the most difficult to control in hypertensive subjects, which is the principal goal of most antihypertensive drugs.1 Central (aortic) SBP is a complex parameter that is influenced both by cardiac (stroke volume and ventricular ejection) and vascular (arterial and venous stiffness and wave reflections) factors.1 Stroke volume, the ratio between cardiac output and heart rate, depends not only on cardiac structure and function but also on venous return. Through the extracellular and intravascular spaces and their elastic properties, stroke volume and, hence, SBP are strongly associated with sodium balance, ie, with the relationship between sodium intake and its urinary elimination, and, finally, the traditional pressure-diuresis mechanism.4 This pathway, which mainly affects the venous circulation, requires a low and steady BP, together with a vast storage capacity for salt and water. Another important pathway affects the high-pressure pulsatile arterial system, in which the SBP level is achieved through increased arterial stiffness and disturbed wave reflections. These hemodynamic parameters are strongly influenced by sodium intake, and their anomalies are mostly seen in subjects >50 years old.1,2,5,7,9 Note that, in humans, the volume and elasticity of the arterial space are very low compared with the corresponding values for the venous system.1 We have 2 principal aims for this review. First, how …

Aldosterone increases VEGF-A production in human neutrophils through PI3K, ERK1/2 and p38 pathways.

Aldosterone is now recognised as an important actor in inflammation processes. Neoangiogenesis plays a crucial role in this complex process and immune cells, such as neutrophils, appear to be able to secrete different forms of (pro)angiogenic molecules, especially VEGF-A. The present work was undertaken to investigate whether aldosterone was able to regulate VEGF-A production in human neutrophils. The HL-60 (progranulocytic) cell line and human polymorphonuclear leukocytes were incubated for different time periods with aldosterone. Total cellular RNA extraction, submitted to reverse transcription and real time semi-quantitative PCR, was used to study VEGF-A mRNA expression. Cell supernatants were collected and ELISA tests were performed to analyse VEGF-A protein production. Aldosterone increased VEGF-A mRNA and protein expression in a dose- and time-dependent manner in both cell types. Inhibitors of PI3 kinases, ERK1/2, and to a lesser extent of p38 MAPK, decreased this aldosterone-induced immune cell activation. Western-blot performed with HL-60 cells confirmed that ERK1/2 and p38 MAPK pathways were stimulated by aldosterone. Mineralocorticoid receptors are implicated in this VEGF-A up-regulation because HL-60 cells pre-treated with spironolactone, an aldosterone receptor antagonist, diminished the effects of aldosterone. Aldosterone was also able to increase VEGF-A production of phagocytic cells such as neutrophils. These results suggest that this hormone could play an active role in the neovascularisation process by favouring entry of plasma proteins and fluids into the vascular wall, cell proliferation and tissue rebuilding.

Aldosterone up-regulates MMP-9 and MMP-9/NGAL expression in human neutrophils through p38, ERK1/2 and PI3K pathways

Aldosterone and mineralocorticoid receptors are important regulators of inflammation. During this process, chemokines and extracellular matrix degradation by matrix metalloproteases, such as MMP-9, help leukocytes reaching swiftly and infiltrating the injured tissue, two processes essential for tissue repair. Leukocytes, such as neutrophils, are a rich source of MMP-9 and possess mineralocorticoid receptors (MR). The aim of our study was to investigate whether aldosterone was able to regulate proMMP-9, active MMP-9 and MMP-9/NGAL production in human neutrophils. Here we show that aldosterone increased MMP-9 mRNA in a dose- and time-dependent manner. This hormone up-regulated also dose-dependently proMMP-9 and active MMP-9 protein release as well as the MMP-9/NGAL protein complex. PI3K, p38 and ERK1/2 inhibition diminished these aldosterone-induced neutrophil productions. Furthermore, spironolactone, a MR antagonist, counteracted aldosterone-induced increases of proMMP-9, active MMP-9 and MMP-9/NGAL complex. These findings indicate that aldosterone could participate in tissue repair by modulating neutrophil activity and favoring extracellular matrix degradation.

Increased Microparticle Production and Impaired Microvascular Endothelial Function in Aldosterone-Salt- Treated Rats: Protective Effects of Polyphenols

We aimed to characterize circulating microparticles in association with arterial stiffness, inflammation and endothelial dysfunction in aldosterone-salt-induced hypertension in rats and to investigate the preventive effects of red wine polyphenols. Uninephrectomized male Sprague-Dawley rats were treated with aldosterone-salt (1 µg.h−1), with or without administration of either red wine polyphenols, Provinols™ (20 mg.kg−1.day−1), or spironolactone (30 mg.kg−1.day−1) for 4 weeks. Microparticles, arterial stiffness, nitric oxide (NO) spin trapping, and mesenteric arterial function were measured. Aldosterone-salt rats showed increased microparticle levels, including those originating from platelets, endothelium and erythrocytes. Hypertension resulted in enhanced aortic stiffness accompanied by increased circulating and aortic NO levels and an upregulation of aortic inducible NO-synthase, NFκB, superoxide anions and nitrotyrosine. Flow-induced dilatation was reduced in mesenteric arteries. These effects were prevented by spironolactone. Provinols™ did not reduce arterial stiffness or systolic hypertension but had effects similar to those of spironolactone on endothelial function assessed by flow-mediated vasodilatation, microparticle generation, aortic NO levels and oxidative stress and apoptosis in the vessel wall. Neither the contractile response nor endothelium-dependent relaxation in mesenteric arteries differed between groups. The in vivo effects of Provinols™ were not mediated by mineralocorticoid receptors or changes in shear stress. In conclusion, vascular remodelling and endothelial dysfunction in aldosterone-salt-mediated hypertension are associated with increased circulating microparticles. Polyphenols prevent the enhanced release of microparticles, macrovascular inflammation and oxidative stress, and microvascular endothelial dysfunction independently of blood pressure, shear stress and mineralocorticoid receptor activation in a model of hyperaldosteronism.

The lateral hypothalamus: A site for integration of nutrient and fluid balance

This paper reviews seemingly obligatory relations between nutrient and fluid balance. A relatively novel neuronal pathway involving interplay between acetylcholine and the melanocortins, αMSH and AGRP in the arcuate nucleus (Arc) of the hypothalamus projecting to the lateral hypothalamus (LH) may bridge this gap. In the fasted condition, increased expression of MCH (due to muscarinic-3 receptor stimulation and low melanocortin tone) and neuronal release of MCH (via Orexin signaling) underlies a drive towards positive energy balance, increased B cell capacity to secrete insulin, and this is associated with optimal fluid homeostasis. A hypohydrated state is hypothesized to yield downregulation of leptin signaling (potentially via inhibitory effects of osmotic stress on mTOR), but osmotic stress may prevent MCH expression via the OVLT-SFO complex. If this occurs in an obese state, impaired pancreatic B cell capacity and peripheral insulin insensitivity as a result of hypohydration may underlie cardio-metabolic diseases.

Fatty Acids Impair Endothelium-Dependent Vasorelaxation: A Link Between Obesity and Arterial Stiffness in Very Old Zucker Rats

To analyze age-related interactions between obesity, its associated metabolic disorders, and macrocirculation, we studied large artery stiffness and fatty acid responsiveness in lean and obese Zucker rats, aged 25 (adult) and 80 weeks (very old). Systolic arterial pressure was higher in old obese than in old lean rats (178 ± 10 vs 134 ± 8 mmHg, respectively). Carotid elastic modulus-wall stress curves showed increased age-dependent arterial stiffening, which was greater in obese animals. Old obese exhibited endothelial dysfunction with increased systemic oxidative stress. Adult obese had elevated plasma free fatty acid levels (1,866 ± 177 vs 310 ± 34 μg/μL in lean animals). In old obese, linoleate and palmitate increased contractility to phenylephrine and reduced relaxation to acetylcholine. Thus, obesity at 25 weeks appears to trigger accelerated arterial aging observed at 80 weeks. The early increase in free fatty acids may be a key effector in the severe arterial stiffness of the aged obese Zucker model.

Effects of short term forced oral breathing in rat pups on weight gain, hydration and stress

Nasal obstruction is a risk factor in sleep-disordered breathing with a negative impact on the quality of life in humans. We investigated hydration changes produced by short term reversible, bilateral, nasal obstruction in young developing rat pups. Physiological parameters of growth (weight gain and gastric content weight) and dehydration were analyzed during two periods; during nasal obstruction at post-natal day 8 (days 9, 11 and 13), plus 7 and 90 days after recovery of nasal breathing (day 15 and adulthood). Body weight gain in oral breathing rat pups was slower compared to controls. Gastric weight was decreased significantly only in oral breathing rat pups on days 9 and 11 while plasma osmolality and vasopressin levels increased (indicators of dehydration). There were no differences between controls and treated rat pups by day 15, or at adulthood. Short term nasal obstruction-induced forced oral breathing, decreased gastric content which had a negative impact on growth and blood glucose concentration in the short term for female rat pups. Plasma corticosterone levels increased during the dehydration but were normal in males by 90 days. This could be a model for blocked nose syndrome in the newborn. Possible long term consequences on development are discussed.

Mother–pup interactions during a short olfactory deprivation period in young rats

The effects of short-term bilateral naris occlusion (inducing olfactory deprivation) on mother-pup interactions, suckling behavior and hormonal status during post-natal development in Wistar rats were studied. Bilateral naris occlusion was performed on 8-day-old rat pups and its effects were evaluated at Day 9 and at Day 15. The narins opened spontaneously between Day 12 and 14. Olfactory-deprived pups exhibited a greater level of corticosterone at both ages versus untreated or sham animals. Olfactory deprivation via naris occlusion, in young rats, alters mother-pup interactions with a decrease in the duration of mother-pup retrieving and an increase in pup licking. Olfactory-deprived pups showed also a lower mean duration of nursing and a decrease in nipple attachment, which appeared related to difficulties in finding the nipple. Olfactory-deprived pups had difficulty recognizing their nest. These behavioral alterations were accompanied by a diminution in milk ingested and growth retardation associated with a reduced level of thyroxin at both 9 and 15 days of age.

Prolonged ozone exposure effects behaviour, hormones and respiratory muscles in young female rats

This study evaluated behavioural and physiological (hormonal status, muscle structure) affects of prolonged ozone exposure in young females rats. Female Wistar rats were exposed at 0.12ppm of ozone during 6h per day for 15days. Prolonged ozone exposure, though not continuous, produced remarkable behavioural disturbances with an increase in drinking, grooming and resting, and a reduction of rearing, jumping-play and locomotor activities. Besides, ozone exposure was accompanied by increased plasma levels of corticosterone and free triiodothyronine (FT3). Expression of myosin heavy chain (MHC) was significantly affected in three of the five muscles studied. MHC 2B decreased significantly to the benefit of MHC 2A in diaphragm compared to control. MHC 2X increased in Anterior Digastric and decreased in Masseter Superficialis under ozone, to the benefit of MHC 2B in Masseter Superficialis. The plasma corticosterone level increase suggested that prolonged exposure to ozone was stressful. This increase could explain also the increased levels of FT3. Modified respiratory behaviour and hormonal changes both appear to be at the origin of the observed muscular adaptation.