Vasopressin: physiology, assessment and osmosensation.

Vasopressin (AVP) plays a major role in the regulation of water and sodium homeostasis by its antidiuretic action on the kidney, mediated by V2 receptors. AVP secretion is stimulated by a rise in plasma osmolality, a decline in blood volume or stress. V1a receptors are expressed in vascular smooth muscle cells, but the role of vasopressin in blood pressure regulation is still a matter of debate. AVP may also play a role in some metabolic pathways, including gluconeogenesis, through its action on V1a receptors expressed in the liver. It is now understood that thirst and arginine vasopressin (AVP) release are regulated not only by the classical homeostatic, intero-sensory plasma osmolality negative feedback, but also by novel, extero-sensory, anticipatory signals. AVP measurement is time-consuming, and AVP level in the blood in the physiological range is often below the detection limit of the assays. Recently, an immunoassay has been developed for the measurement of copeptin, a fragment of the pre-provasopressin molecule that is easier to measure. It has been shown to be a good surrogate marker of AVP.

Copeptin, a marker of vasopressin, in abdominal obesity, diabetes and microalbuminuria: the prospective Malmö Diet and Cancer Study cardiovascular cohort.

BACKGROUND: High plasma copeptin (copeptin), the C-terminal fragment of arginine vasopressin pro-hormone, has been associated with the metabolic syndrome (MetS), diabetes mellitus (DM) development and nephropathy. Here we tested whether elevated copeptin level is associated with later development of the MetS, its individual components and microalbuminuria. METHODS: We analysed copeptin at baseline (1991-1994) in the population-based Malmö Diet and Cancer Study cardiovasular cohort and re-examined 2064 subjects 15.8 years later (mean age 72.8 years, 59% women) with oral glucose tolerance test and measurement of MetS and its individual components. RESULTS: After age and sex adjustment, increasing quartiles of copeptin at baseline (the lowest quartile as reference) were associated with MetS (P for trend=0.008), incident abdominal obesity (P for trend=0.002), DM (P for trend=0.001) and microalbuminuria (P for trend=0.002). After additional adjustment for all the MetS components at baseline, increasing copeptin quartiles predicted incident abdominal obesity (odds ratios 1.55, 1.30 and 1.59; P for trend=0.04), DM (odds ratios 1.18, 1.32 and 1.46; P for trend=0.04) and microalbuminuria (odds ratios 1.05, 1.08 and 1.65; P for trend=0.02) but not MetS (P for trend=0.19) at the reexamination. Further, the relationship between copeptin and microalbuminuria was independent of baseline C-reactive protein, incident DM and incident hypertension. CONCLUSION: Copeptin independently predicts DM and abdominal obesity but not the cluster of MetS. Apart from predicting DM and abdominal obesity, elevated copeptin signals increased risk of microalbuminuria. Interestingly, the association between copeptin and later microalbuminuria was independent of both prevalent and incident DM and hypertension. Our findings suggest a relationship between a dysregulated vasopressin system and cardiometabolic risk, which could have implications for risk assessment and novel preventive treatments.

Cyclic AMP is a hepatorenal link influencing natriuresis and contributing to glucagon-induced hyperfiltration in rats.

The effects of glucagon (G) on proximal tubule reabsorption (PTR) and GFR seem to depend on a prior action of this hormone on the liver resulting in the liberation of a mediator and/or of a compound derived from amino acid metabolism. This study investigates in anesthetized rats the possible contribution of cAMP and urea, alone and in combination with a low dose of G, on phosphate excretion (known to depend mostly on PTR) and GFR. After a 60-min control period, cAMP (5 nmol/min x 100 grams of body weight [BW]) or urea (2.5 micromol/min x 100 grams BW) was infused intravenously for 200 min with or without G (1.2 ng/min x 100 grams BW, a physiological dose which, alone, does not influence PTR or GFR). cAMP increased markedly the excretion of phosphate and sodium (+303 and +221%, respectively, P < 0.01 for each) but did not alter GFR. Coinfusion of cAMP and G induced the same tubular effects but also induced a 20% rise in GFR (P < 0.05). Infusion of urea, with or without G, did not induce significant effects on PTR or GFR. After G infusion at increasing doses, the increase in fractional excretion of phosphate was correlated with a simultaneous rise in plasma cAMP concentration and reached a maximum for doubling of plasma cAMP. These results suggest that cAMP, normally released by the liver into the blood under the action of G, (a) is probably an essential hepatorenal link regulating the intensity of PTR, and (b) contributes, in conjunction with specific effects of G on the nephron, to the regulation of GFR.

Arginine vasopressin gene regulation in the homozygous Brattleboro rat.

The Brattleboro rat, which has an autosomally recessive form of diabetes insipidus, has been reported to have a marked defect in the regulation of arginine vasopressin (AVP) gene expression. However, it is not known whether this is a primary genetic defect or occurs secondary to the urinary water losses which occur in the absence of circulating AVP in the Brattleboro rat. This present study was therefore undertaken to study AVP gene regulation in the Brattleboro rat after chronic AVP treatment by osmotic minipump for 2 wk. In Brattleboro rats without AVP treatment, neither urinary osmolality (Uosm) nor hypothalamic AVP mRNA was significantly changed after 24 h of fluid deprivation (Uosm, 413 +/- 33 to 588 +/- 44, NS; AVP mRNA, 39.33 +/- 2.95 to 46.39 +/- 2.71 pg/micrograms total RNA, NS). In contrast, when Brattleboro rats were treated with AVP for 2 wk, the regulation of AVP gene occurred in response to 24 h of fluid deprivation. In these studies, hypothalamic AVP mRNA was significantly increased compared with the Brattleboro rats still receiving AVP with free access of water (28.9 +/- 3.5 vs. 65.0 +/- 3.3 pg/micrograms total RNA, P less than 0.001). Further studies in Long-Evans rats demonstrate a similar response to a comparable degree of fluid deprivation as Uosm and AVP mRNA were significantly increased after 72 h of fluid deprivation (Uosm, 1,505 +/- 186 to 5,460 +/- 560 mosmol/kg, P less than 0.001; AVP mRNA, 31.7 +/- 3.9 to 77.5 +/- 4.6 pg/micrograms total RNA, P less than 0.001). These results indicate that AVP-replaced homozygous Brattleboro rats can regulate AVP gene expression normally in response to fluid deprivation. This finding indicates that the defect in AVP gene regulation in the Brattleboro rat not receiving AVP replacement is a secondary phenomenon rather than a primary genetic defect.

Characterization of SR 121463A, a highly potent and selective, orally active vasopressin V2 receptor antagonist.

SR 121463A, a potent and selective, orally active, nonpeptide vasopressin V2 receptor antagonist, has been characterized in several in vitro and in vivo models. This compound displayed highly competitive and selective affinity for V2 receptors in rat, bovine and human kidney (0.6 < or = Ki [nM] < or = 4.1). In this latter preparation, SR 121463A potently antagonized arginine vasopressin (AVP)-stimulated adenylyl cyclase activity (Ki = 0.26+/-0.04 nM) without any intrinsic agonistic effect. In autoradiographic experiments performed in rat kidney sections, SR 121463A displaced [3H]AVP labeling especially in the medullo-papillary region and confirmed that it is a suitable tool for mapping V2 receptors. In comparison, the nonpeptide V2 antagonist, OPC-31260, showed much lower affinity for animal and human renal V2 receptors and lower efficacy to inhibit vasopressin-stimulated adenylyl cyclase (Ki in the 10 nanomolar range). Moreover, OPC-31260 exhibited a poor V2 selectivity profile and can be considered as a V2/V1a ligand. In normally hydrated conscious rats, SR 121463A induced powerful aquaresis after intravenous (0.003-0.3 mg/kg) or oral (0.03-10 mg/kg) administration. The effect was dose-dependent and lasted about 6 hours at the dose of 3 mg/kg p.o. OPC-31260 had a similar aquaretic profile but with markedly lower oral efficacy. The action of SR 121463A was purely aquaretic with no changes in urine Na+ and K+ excretions unlike that of known diuretic agents such as furosemide or hydrochlorothiazide. In addition, no antidiuretic properties have been detected with SR 121463A in vasopressin-deficient Brattleboro rats. Thus, SR 121463A is the most potent and selective, orally active V2 antagonist yet described and could be a powerful tool for exploring V2 receptors and the therapeutical usefulness of V2 blocker aquaretic agents in water-retaining diseases.

Antidiuretic action of vasopressin: quantitative aspects and interaction between V1a and V2 receptor-mediated effects.

(1) Vasopressin (VP), or antidiuretic hormone, is secreted in response to either increases in plasma osmolality (very sensitive stimulus) or to decreases in plasma volume (less sensitive stimulus). Its normal plasma level is very low (about 1 pg/ml, i.e. 10(-12) M), close to the detection limit of present immunoassays, and distinct antidiuretic effects are observed after infusion of small undetectable amounts of VP. (2) This antidiuretic action results from three main effects of VP on principal cells of the collecting duct (CD) mediated by occupancy of peritubular V2 receptors. (i) Increase in water permeability along the entire CD (via AQP2). (ii) Increase in urea permeability in only the terminal inner medullary CD (via UT-A1). (iii) Stimulation of sodium reabsorption, mainly in the cortical and outer medullary CD (via ENaC). VP also acts on medullary vasculature (V1a receptors) to reduce blood flow to inner medulla without affecting blood flow to outer medulla. Besides these actions, all concurring to increase urine osmolality in different and additive ways, other VP effects, probably exerted through V1a receptors located on luminal membrane, tend to limit the antidiuretic effects of the hormone. They induce the formation of prostaglandins which reduce V2-dependent cAMP accumulation in these cells and thus partially inhibit all three V2 effects. (3) Because urine is first diluted along the nephron before being concentrated in the medulla, VP is required, not only for urine concentration, but first for re-equilibration of tubular fluid osmolality with plasma osmolality, a step taking place in the renal cortex, and achieved through the reabsorption of large quantities of water (more than what is subsequently reabsorbed in the medulla to concentrate urine). Accordingly, VP effects on urine flow-rate are not linear. Small changes in plasma VP in the low range of urine osmolality will induce wide changes in urinary flow-rate, whereas in the upper range of urine osmolality larger changes in plasma VP induce much more limited further reduction in urine flow-rate. (4) Most likely, the different effects of VP require different levels of VP concentration to occur and are thus recruited successively with progressive rise in VP secretion.

Type 1 angiotensin II receptor subtypes in kidney of normal and salt-sensitive hypertensive rats.

We studied the localization and regulation of the two type 1 angiotensin II receptor subtypes AT(1A) and AT(1B) in different renal zones of the rat kidney by a reverse transcription-polymerase chain reaction amplification method. The yield of the reaction was quantified with an internal standard that was a 63-bp deleted mutant cRNA of the AT(1A) receptor. In kidneys of male Sprague-Dawley rats (n=4), the levels of AT(1A) and AT(1B) receptor mRNAs were highest in the inner stripe of the outer medulla, lowest in the inner medulla, and intermediate in the cortex and outer stripe of the outer medulla. Results (mean+/-SE) expressed in 10(5) molecules per microgram total RNA were for cortex outer stripe, inner stripe, and inner medulla, respectively, 171 +/- 15, 152 +/- 27, 322 +/- 10, and 73 +/- 3 for AT(1A), and 35 +/- 9, 26 +/- 1, 71 +/- 10, and 53 +/- 11 for AT(1B). In sabra rats sensitive (n=6) or resistant (n=6) to salt-induced hypertension and maintained on a normal salt diet, the percentage and level of each receptor subtype mRNA in cortex and outer stripe were similar in the two strains and comparable to those observed in Sprague-Dawley rats. However, AT(1A) of the inner stripe was significantly decreased in salt-resistant compared with salt-sensitive rats (166 +/- 28 and 318 +/- 58 10(5) molecules per microgram total RNA, respectively). These modifications were organ specific because no difference in the level of the receptor mRNAs was observed in the liver of the two Sabra rat strains, whereas a twofold increase in AT(1A) mRNA level but not in AT(1B) mRNA level was apparent in adrenal and in one renal zone, the inner stripe of the outer medulla, of hypertension-prone Sabra rats.

Glucagon receptor gene mutation (Gly40Ser) in human essential hypertension: the PEGASE study.

A missense mutation (Gly40Ser) in exon 2 of the glucagon receptor gene (GCG-R) was shown to reduce ligand affinity and impair cAMP response. We conducted a case-control study with a sample of 741 French hypertensive patients with moderate to severe hypertension and 412 normotensive control subjects, who were genotyped for this biallelic variant by use of hybridization with allele-specific oligonucleotides. The Gly40Ser polymorphism was not significantly associated with hypertension in the whole study population, although the frequency of 40Ser carriers in hypertensive subjects was double that in normotensive subjects (3.1% in hypertensives versus 1.5%; P=0.087). However, the separate analysis of both genders revealed that 40Ser allele carriers were significantly more frequent (P=0. 035) among male patients (17/429; 4.0%) than among normotensive male controls (2/242; 0.8%), whereas no significant difference was observed in female subjects (6/312 in hypertensives and 4/170 in normotensives). Further studies are required to interpret the significance of this association.

Regulation by sodium intake of type 1 angiotensin II receptor mRNAs in the kidney of Sabra rats.

OBJECTIVE: To study the relationship between the sensitivity to sodium content of the diet in terms of development of hypertension and the regulation of the expression of type 1 angiotensin II receptor subtypes by such a diet. METHODS: The expression of angiotensin II receptor subtype (AT1A and AT1B) mRNAs was studied by quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) in the four zones of the kidneys of Sabra rats, sensitive or resistant to DOCA salt-induced hypertension (SBH/y and SBN/y, respectively). Rats were fed a high (8%) or normal (0.4%) NaCl diet. As vasopressin is known to be elevated in SBH/y rats and to be involved in DOCA-salt hypertension, we studied an additional group of SBH/y rats, fed a high sodium diet, enriched in water. RESULTS: With the absence of DOCA, SBH/y rats did not develop hypertension. The high sodium diet induced a greater fall in the plasma renin activity in the SBH/y (-95%) than in the SBN/y (-63%). In the cortex (C) and inner stripe (IS), the high sodium diet decreased AT1A and AT1B mRNAs in SBH/y and SBN/y, with a higher magnitude for SBH/y, than for SBN/y (C, -28 versus -20%; IS, -42 versus -20%). The addition of water to the high sodium diet lessened the effect of sodium in the C and IS, although the plasma renin activity (PRA) was not altered. CONCLUSION: A high sodium diet significantly decreases both AT1A and AT1B gene expression in two specific zones of the rat kidney containing the target cells of angiotensin II (C and IS). This down-regulation is organ-specific since it was observed in the kidney and adrenals, but not in the liver. Finally, SBH/y and SBN/y rats differ in the basal level of AT1 mRNA expression in the IS, and in the ability to modulate AT1 mRNA level under sodium intake.

Renal hemodynamic response to intravenous and oral amino acids in animals.

Oral or parenteral application of amino acids leads to marked hyperfiltration and increased of renal plasma flow. Amino acids stimulate the release of glucagon, which increases hepatic production and release of cyclic adenosine monophosphate (cAMP). In the kidney, the combined effect of cAMP and glucagon increases glomerular filtration rate (GFR), possibly by reducing NaCl concentration at the macula densa and depression of the tubuloglomerular feedback. Vasopressin-dependent urea recycling and delivery to the thick ascending limb could similarly reduce NaCl concentration at the macula densa. Beyond that, amino acids may trigger a hepatorenal reflex or directly interfere with renal function. Mechanisms invoked include dopamine from renal nerves, prostaglandins, nitric oxide (NO), and angiotensin II. At this point, it is not clear to which extent the described mechanisms participate in, permit, or fully account for the hyperfiltrative effect of amino acids.

Plasma cAMP: a hepatorenal link influencing proximal reabsorption and renal hemodynamics?

The existence of a hepatorenal link is suggested by several pathophysiological observations (indirect actions of glucagon on the kidney, hepatorenal syndrome), but the nature of this link remains unidentified. We propose that extracellular circulating cyclic AMP could be this link. Cyclic AMP (cAMP) is the intracellular second messenger of glucagon (G) action in the liver, and this organ is known to release cAMP in the blood in relatively large amounts after G administration. On the other hand, the proximal tubule (mainly the pars recta) is known to take up cAMP through the organic acid transport system. We observed that the glucagon-induced rise in phosphate excretion, which requires supraphysiologic concentration of G, was significantly correlated with the simultaneous rise in plasma cAMP and could be mimiked by i.v. infusion of cAMP alone. Moreover, we showed that a significant hyperfiltration (similar to that induced by supraphysiologic G) can be observed if cAMP (mimicking G-induced hepatic release) is coinfused with a much lower, physiologic, amount of G. Taken together, these observations suggest that: (1) cAMP is a hepatorenal link and that plasma cAMP permanently influences the intensity of reabsorption in the pars recta of the proximal tubule; and (2) that cAMP participates, in conjunction with G, to control GFR. Insulin is known to exert an inhibitory influence on G-induced cAMP release by the liver and will thus weaken the indirect (cAMP-mediated) influence of G on renal function. This "pancreato-hepatorenal cascade" may explain the natriuretic effects of G and antinatriuretic effects of insulin, and probably contributes to disturbances observed in some pathophysiological situations such as the edema of liver cirrhosis or hyperfiltration of diabetes.

Possible role of the thick ascending limb and of the urine concentrating mechanism in the protein-induced increase in GFR and kidney mass.

The mechanisms by which high protein intake increases filtration rate and kidney hypertrophy in health and may be detrimental to the kidney in chronic renal failure are not well understood. We studied the kidneys of Sprague Dawley rats fed high (HP) and low (LP) isocaloric protein diets (32% and 10% casein, respectively) for 4 weeks. HP induced significant increases in kidney mass, GFR, and maximum urine concentrating ability (UMax). Kidney hypertrophy was characterized by (1) a selective increase in thickness of the inner stripe of the outer medulla (IS, +54%, P less than 0.001) while total kidney height (from cortex to papillary tip) increased only by 18%; (2) a considerable hypertrophy of the thick ascending limbs (TAL) in the IS (+43% epithelium volume/unit tubular length) but not in the outer stripe nor in the cortex; and (3), an increase in heterogeneity of glomerular volume between superficial and deep nephrons (P less than 0.05). these morphologic changes parallel those we previously reported in rats fed a normal protein diet (25% casein) but in which the operation of the urine concentrating mechanism was chronically stimulated by ADH infusion or by reduction in water intake. In contrast, normal kidney growth with age or kidney hypertrophy induced by uninephrectomy were not accompanied by preferential enlargement of IS structures.(ABSTRACT TRUNCATED AT 250 WORDS)

Possible involvement of vasopressin and urine concentrating process in the progression of chronic renal failure.

This paper reviews experimental findings which support the concept that vasopressin (VP) and the process of urine concentration may be involved in the progression of chronic renal failure (CRF). The influence of dietary protein intake on the progression of CRF may also involve VP and the operation of the concentrating process. VP receptors have been identified in glomeruli and VP is able to constrict mesangial cells as does angiotensin II. Acute VP infusion increases the glomerular transcapillary hydraulic pressure difference, and chronic VP infusion increases GFR. In rats with CRF (induced by 5/6 nephrectomy), VP levels were found elevated. In rats with 5/6 nephrectomy, we increased experimentally water intake in order to decrease circulating VP levels, urine concentration, and free water reabsorption. Several indices of progression of CRF, including proteinuria, hypertension and glomerulosclerosis, were significantly reduced, thus suggesting a contribution of VP in progression. Lowering protein intake in CRF could be beneficial because proteins, but not carbohydrates or lipids, produce metabolic end products (mainly urea, ammonia, protons, etc.) that are excreted by the kidney, and concentrated in the urine. In healthy subjects (man or rat), high protein (HP) intake favors urine concentration and causes changes in kidney function and morphology very similar to those induced by chronic VP infusion or water restriction. These changes involve an increase in transport activity of the thick ascending limb (where the initial active step of the concentrating process takes place) and may affect filtration rate and/or glomerular hemodynamics secondarily, by decreasing salt concentration at the macula densa and depressing tubuloglomerular feedback.(ABSTRACT TRUNCATED AT 250 WORDS)

Vasopressin and urinary concentrating activity in diabetes mellitus.

In diabetes mellitus (DM), the high urine flow rate suggests that urinary concentrating capacity is impaired. However, several studies have shown that vasopressin is elevated in DM and the consequences of this elevation have not yet been characterized. This study reevaluated renal function and water handling in male Wistar rats with Streptozotocin-induced DM, and in control rats. During five weeks after induction of DM, urine was collected in metabolic cages and a blood sample was drawn during the third week. Control rats (CONT) were studied in parallel. On week 3, urine flow rate was tenfold higher in DM than in CONT rats and urinary osmolality was reduced by half along with a markedly higher osmolar excretion (DM/CONT = 5.87), due for a large part to glucose but also to urea (DM/CONT = 2.49). Glucose represented 52% of total osmoles (90.3 +/- 6.5 mmol/d out of 172 +/- 14 mosm/d). Free water reabsorption was markedly higher in DM rats compared to CONT (326 +/- 24 vs 81 +/- 5 ml/d). In other rats treated in the same way, urinary excretion of vasopressin was found to be markedly elevated (15.1 +/- 4.1 vs 1.44 +/- 0.23 ng/d). In DM rats, glucose concentration in urine was 17 fold higher than in plasma, and urea concentration 14 fold higher. Both urine flow rate and free water reabsorption were positively correlated with the sum of glucose and urea excretions (r = 0.967 and 0.653, respectively) thus demonstrating that the urinary concentrating activity of the kidney increased in proportion to the increased load of these two organic solutes. These results suggest that vasopressin elevation in DM contributes to increase urinary concentrating activity and thus to limit water requirements induced by the metabolic derangements of DM. The possible deleterious consequences of sustained high level of vasopressin in DM are discussed.

Influence of plasma amino acid level on vasopressin secretion.

OBJECTIVES: Vasopressin (VP) is known to be elevated in patients with diabetes mellitus (DM). While the influence of acute hyperglycemia has been ruled out, the mechanism or the osmotically active compound responsible for the increase in VP secretion is still not elucidated. Because the plasma level of several amino acids (AAs) is increased in DM, we evaluated whether AAs could represent an effective osmotic stimulus for VP secretion. RESEARCH DESIGN AND METHODS: In a cross-over study, eight healthy volunteers randomly received an infusion of isotonic saline (control) or mixed AA solution, i.v., at a low or a high rate (2 or 4.5 mg/min/kg BW, respectively). Plasma VP (P(VP)) was measured for two hours before and three hours during AA or control infusion. RESULTS: AA infusion induced a dose-dependent elevation in plasma AA concentration but did not alter P(VP). However, effective plasma osmolality (P(osm)) (osmolality minus urea concentration) remained unchanged because a concommittant fall in plasma sodium concentration (P(Na)), likely due to sodium-linked uptake of AA in peripheral cells, compensated for the rise in plasma AA. CONCLUSION: The stability of effective P(osm) may explain the lack of change observed in P(VP). Because sodium is a very efficient stimulus for VP secretion, it may be assumed that the fall in P(Na) occurring during AA infusion should have reduced VP secretion and thus P(VP). In this setting, the stability of P(VP) suggests that AAs induced an increase in VP secretion which counterbalanced the fall attributable to the decrease in P(Na). In conclusion, in acute experiments, AAs seem to represent an effective stimulus for VP secretion, almost equally potent as sodium. Further studies are needed to evaluate their contribution to the high P(VP) seen in the chronic setting of DM.

Contribution of vasopressin to progression of chronic renal failure: study in Brattleboro rats.

We have previously shown that a chronic reduction in plasma vasopressin level slowed the progression of chronic renal failure (CRF) in Sprague Dawley rats. The aim of the present study was to determine the respective contribution of pressor (V1) and antidiuretic (V2) effects of vasopressin on progression. Male homozygous Brattleboro rats with hereditary central diabetes insipidus were submitted to 5/6 nephrectomy. They were divided into three groups, two of which received chronic i.p. infusion of AVP (V1 + V2 effects) or dDAVP (V2 effects). The third group served as control (CONT). The doses of AVP and dDAVP were chosen so as to produce urine osmolality similar to that observed in 5/6 Nx Sprague Dawley rats. All rats ate the same amount of food and drank water ad libitum. Renal function was studied for 13 weeks. All three groups showed a marked hypertension. Rats infused with dDAVP, but not those infused with AVP, had a higher creatininemia, anemia and urinary protein excretion than CONT rats. In the dDAVP but not the AVP group, fractional excretion of urea was markedly decreased and plasma urea concentration rose much more than that of creatinine. These results show that V2 but not V1 effects play a major role in the deleterious influence of vasopressin on progression, at least in Brattleboro rats. The more severe progression seen in dDAVP rats could indirectly result from the V2-mediated effects on the collecting duct resulting in a decreased efficiency of urea excretion, an increased intrarenal urea recycling, and a rise in plasma urea concentration. Both the toxic effects of urea and the recently demonstrated V2-mediated increase in glomerular hemodynamics might be involved in the deleterious influence of V2 agonism.

[Influence of moderate body weight excess on the nycthemeral pattern of blood pressure, renal function and sodium and water excretion in patients with essential hypertension]. / Effet d'un excès de poids sur les variations nycthémérales de la pression artérielle, de la fonction rénale et de l'excrétion sodée chez des patients hypertendus.

Obesity is a risk factor for arterial hypertension. We studied the relationships between the body mass index (BMI) and the nycthemeral pattern of blood pressure (BP), renal function and sodium and water excretion (EX) in a group of 25 moderately hypertensive untreated men (41 +/- 2 y, 80 +/- 3 kg). Subjects were given a high sodium diet (6 g NaCl added to their usual diet, daily EX=200 mmol). On the 7th day, BP was monitored during 24 h and urine collected in 2 fractions (day=D, 8:00-22:00 and night=N, 22:00-8:00). Subjects were a posteriori divided into 2 groups according to the median BMI (26 kg/m2): Group 1, n=12, BMI 23.2 +/- 0.6 (mean +/- SEM) and Group 2, n=13, BMI 29.2 +/- 0.5 kg/m2. No difference was observed between the two groups for age, 24 h urine and sodium EX, or systolic and diastolic BP. However, heart rate was significantly higher during N in Group 2 (66 +/- 2 vs 57 +/- 2 b/min, p=0.012). Na and water EX were significantly higher during D than during N in Group 1, but lower during D than during N in Group 2. Creatinine clearance was higher in Group 2 than in Group 1 especially during N (D+29%, p=0.013; N+49%, p<0.001). In Group 2, subjects concentrated their urine more than in Group 1, as evaluated from the urine/plasma creatinine ratio (+49%, p=0.019). This ratio was positively correlated to BMI during D (r=0.561, p=0.004) but not during N. These results show that the glomerular hyperfiltration associated with overweight is more intense at night and that moderately overweight hypertensives have a reduced sodium and water EX during the day and a compensatory larger EX at night. The reduced diurnal EX goes along with an increased urine concentration. The nocturnal rise in EX is concomittant with a rise in heart rate. Given the growing health problems linked to obesity and hypertension, these results open a new field for the understanding of the difficulty to excrete sodium in this condition.

[Impaired urinary flow rate during the day: a new factor possibly involved in hypertension and in the lack of nocturnal dipping]. / Débit urinaire trop bas le jour mais élevé la nuit: un nouveau facteur pouvant contribuer à l'HTA et à l'absence de dipping nocturne.

UNLABELLED: Previous studies suggest that a low urinary flow rate may reduce the capacity of the kidney to excrete sodium and could thus favour hypertension. In the present study, we evaluated the relationships between urinary flow rate (V) during day (D) and night (N), blood pressure (BP), and the day-night BP difference (delta in % of day BP) in 65 diabetic patients (glycosuria < 90 mmol/24 h) (35 F and 30 M, age 59 +/- 2 y) hospitalized for a 24 h urine collection and mean ambulatory blood pressure recording (AMBP). Urine was collected as two separate samples during D (8:00 am to 10:00 pm) and N (10:00 pm to 8:00 am). V, sodium excretion (NaEx) and mean systolic and diastolic BP (SBP and DBP, respectively) were calculated for the two periods. Patients were a posteriori classified according to the D/N ratio of V, and the mean values of 3 tertiles (T1, T2, T3, n = 22, 22, and 21 subjects) were calculated and compared by ANOVA (see table; *: p < 0.05; **: p < 0.01; ***: p < 0.001). [table: see text] Although total 24 h urine volume was similar in the three tertiles (1,670, 1,927 and 2,007 mL, NS), the fraction of urine excreted during D and N differed widely, with parallel differences in NaEx. With lower V during the day, BP tended to be higher and the fall in nocturnal BP to be reduced. CONCLUSIONS: This study shows the advantages of separate day and night urine collections in relation with AMBP. For a similar total diuresis, some subjects exhibit a too low urine flow rate and too low NaEx during the day, and a compensatory rise during the night. This low diurnal diuresis is associated with a higher blood pressure and a lower nocturnal fall (= nocturnal pressure diuresis). The factors responsible for a too low diuresis during the day need further investigation.