Circadian rhythm of plasma sodium is disrupted in spontaneously hypertensive rats fed a high-NaCl diet

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Circadian rhythm of plasma sodium is disrupted in spontaneously hypertensive rats fed a high-NaCl diet

Zhiwu Fang, Scott H. Carlson, Ning Peng, and J. Michael Wyss

Department of Cell Biology, University of Alabama at Birmingham, Birmingham, Alabama 35294-0019

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

High-NaCl diets elevate arterial pressure in NaCl-sensitive individuals, and increases in plasma sodium may trigger this effect.The present study tests the hypotheses that 1) plasma sodium displaysa circadian rhythm in rats, 2) the plasma sodium rhythm is disturbedin spontaneously hypertensive rats (SHR), and 3) excess dietaryNaCl elevates plasma sodium concentration in SHR. The resultsdemonstrate that plasma sodium has a circadian rhythm that isinversely related to the circadian rhythm of arterial pressure.Although the plasma sodium rhythms of SHR and control rats arenearly identical, the plasma sodium concentrations are significantlyhigher in SHR throughout the 24-h cycle. Maintenance on a high-NaCldiet increases plasma sodium concentration similarly in both SHRand control rats, but it blunts the plasma sodium rhythm onlyin SHR. These results demonstrate that in rats, plasma sodiumhas a circadian rhythm and that high-NaCl diets increase plasmasodiumconcentration.

salt; sympathetic activity; mean arterial pressure

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

HYPERTENSION GREATLY INCREASES the risk of cardiovascular disease, including coronary heart disease, stroke, atherosclerosis,and end organ damage. In many individuals, a high-NaCl diet increasesarterial pressure and can exacerbate this damage, but the mechanismlinking NaCl intake to hypertension remains elusive. Several linesof evidence suggest that a high-NaCl diet increases arterial pressureprimarily by increasing blood volume (11, 32), but other studiessuggest that a high-NaCl diet may increase plasma sodium concentration,thereby activating central osmosensitive nuclei and reflexly increasingarterial pressure (3, 23, 24). Clinical studies have notfound a close relationship between the amount of sodium in thediet and plasma sodium concentrations, but these studies havenot considered the potential circadian variation in plasma sodiumconcentration. If such variations are large, the timing of bloodsampling would be critical in studies of plasma sodiumconcentration.

Several rodent models have been developed to examine the mechanisms underlying salt-sensitive hypertension, e.g., spontaneouslyhypertensive rats (SHR), Dahl salt-sensitive rats, DOCA-NaCl treatedrats, and transgenic high renin (mRen) rats (37, 41). In severalof these models renal dysfunction contributes importantly to hypertension,but experimental evidence indicates that overactivity of the sympatheticnervous system also contributes to dietary NaCl-sensitive hypertension(37, 41, 50, 52). Several nuclei in the brain, e.g., theorganum vasculosum of the lamina terminalis (3, 22, 23)and the subfornical organ (2, 3), respond to relativelysmall increases in circulating sodium by reflexively increasingsympathetic nervous system activity, vasopressin release, anddrinking (3, 23, 45). If a high-NaCl diet increases plasmasodium, it could thereby increase sympathetic nervous system activityand arterial pressure. SHR display dietary NaCl-sensitive hypertensionthat has been postulated to result from excess sodium retentionafter exposure to a high-salt diet (13, 15, 48). Only afew studies have analyzed plasma sodium concentration, and nonehave considered whether plasma sodium levels fluctuate over a24-hperiod.

Many biological systems display circadian rhythms that are linked to light-dark cycles. In normotensive Wistar-Kyoto rats(WKY) and SHR, mean arterial pressure (MAP) and heart rate (HR)display circadian rhythms (4, 6, 8), and the MAP rhythmicpattern is modified by changes in dietary NaCl in both strains(5, 8, 14). The current studies test three hypotheses:1) that plasma sodium concentration displays a 24-h rhythm parallelto the MAP rhythm and that the plasma sodium rhythm contributesimportantly to changes in MAP observed throughout the 24-h cycle;2) that the circadian rhythm of plasma sodium is disrupted inSHR fed a basal NaCl diet, potentially contributing to hypertensionin SHR; and 3) that a high-NaCl diet further disrupts the plasmasodium rhythm, which may lead to inappropriately elevated plasmasodium levels and increases in MAP inSHR.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Male WKY and SHR (Harlan Sprague Dawley, Indianapolis, IN) were housed in individual cages in a sound-attenuated room at constanthumidity (60 ± 5%), temperature (24 ± 1°C), and 12:12-h light-darkcycle (lights on at 0600-1800) throughout the experiments. Allrats were allowed ad libitum access to basal (0.6%; diet #8746,Teklad, Madison, WI) or high (diet #5008, Teklad)-NaCl diet andto tap water. All studies were approved by the University of Alabamaat Birmingham's Institutional Animal Use and Care Committee andconducted in accordance with the regulations of the National InstitutesofHealth.

Surgical Procedures

At 9 wk of age, all rats were anesthetized with pentobarbital sodium (55 mg/kg body wt ip) and chronically instrumented withan indwelling Silastic arterial catheter that was advanced intothe abdominal aorta via the left femoral artery. All catheterswere tunneled subcutaneously to the midscapular region, wherethey were exteriorized and secured with dental acrylic. On recoveryfrom anesthesia, rats were returned to their home cage and recoveredfor 3 days before the experiments were initiated. The arterialcatheters were flushed daily with 100 µl of heparinized saline(20 U/ml).

Experimental Protocols

Experiment 1: circadian rhythm of plasma sodium concentration on basal NaCl diet. WKY (n = 8) were maintained on 0.6% NaCl diet throughout the experimental protocol. Beginning 3 days after surgery, bloodsamples (100 µl) were drawn through the femoral arterial catheter,and the plasma was separated by centrifugation and stored at $-$ 20°Cbefore analysis. The red blood cells were resuspended in saline(100 µl) and reinfused into the rat. For nighttime (1800-0600)sampling, a red light was used to avoid exposing the rats to lightcues that might disrupt circadian rhythms. Only one blood samplewas taken from a given animal each day (i.e., there were at least26 h between samplings in a given rat) to prevent any significantchange in hematocrit during the experimental period. Blood sampleswere taken at a randomly assigned hour on each day for 24 days,so that at the conclusion of the experiment there was a totalof eight samples (1 per rat) for each 24h.

After the 24-h plasma sodium concentration rhythm was characterized in WKY, the experimental protocol was repeated in SHR(n = 8); however, samples were taken at 2-h intervals insteadof 1-h intervals (i.e., samples were collected for 12 timepoints).

Experiment 2: circadian rhythm of plasma sodium concentration on high (8%)-NaCl diet. In the second experiment, WKY (n = 32) and SHR (n = 32) were divided into four groups (8 rats/group), and each group was assignedto one of four different time points. These time points (0400,0800, 1400, and 2000) were chosen on the basis of the nadir (0400)and the peak (1400) of the plasma sodium rhythm and one time pointduring which plasma sodium concentration was increasing (0800)and one time point during which plasma sodium concentration wasdeclining (2000). Blood samples were drawn, as described above,at the assigned time points for 2 days while the rats were feda basal (0.6%) NaCl diet. Rats were then placed on a high (8%)-NaCldiet, and blood samples were drawn at the same time points ondays 4 and 5 after initiation of the high-NaCldiet.

MAP and HR. To assess whether the circadian plasma sodium rhythm correlated with the MAP and HR rhythms, simultaneous with the above experiments,parallel groups of WKY (n = 10) and SHR (n = 10) were implantedwith telemetry probes for continuous monitoring of arterial pressureand HR, as described previously (8). WKY and SHR were dividedinto two groups, with one group receiving a basal (0.6%) NaCldiet and the second group receiving a high (8%)-NaCl diet. Thedata collection methods and techniques for analyzing MAP and HRcircadian rhythms are described elsewhere (8).

Analysis of blood samples. The plasma was stored at $-$ 20°C for subsequent analysis of plasma sodium concentrations. Plasma sodium levels were measuredusing flame photometry (Allied Instrumentation Laboratory, Lexington,MA), and each sample was assayed three times during the analysesof that day's samples. The flame photometer was recalibrated afterevery four samples, which resulted in a calculated intra-assayvariation of ± 0.2 meq/l. Hematocrit of all blood samples wasmeasured using the microcapillarytechnique.

Statistical analysis. Within-group and between-group differences in plasma sodium were tested using ANOVA followed by post hoc Newman-Keuls analysisto determine the source of significant main effects or interactions.In all cases, a value of P < 0.05 was considered statisticallysignificant. Results are expressed as means ±SE.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Experiment 1

The 24-h plasma sodium concentration in WKY exhibited a peak that occurred during the daytime period (1200-1600; Fig. 1) witha plasma sodium concentration of 142.8 ± 0.3 meq/l (Fig. 1). Thenadir of the rhythm occurred at night (0400) when plasma sodiumconcentration was 138.4 ± 0.2 meq/l. The circadian sodium rhythmin SHR was similar to that in WKY (Fig. 1). The peak of the rhythmoccurred at 1400 (144.8 ± 0.3 meq/l), and the nadir of plasmasodium concentration occurred at 0400 (140.3 ± 0.4 meq/l). Plasmasodium concentrations in SHR were significantly higher than thoseof WKY at almost every time point measured (Fig. 2), with thegreatest differences occurring at 2200 (142.2 ± 0.2 and 138.7± 0.3 meq/l; Fig. 2).

View larger version (15K):
[in this window]
[in a new window]

Fig. 1. The 24-h circadian rhythm of plasma sodium concentration in Wistar-Kyoto (WKY; A; n = 8) and spontaneously hypertensive rats (SHR; B; n = 8) that are on basal NaCl diets. Time reflects clock hours, with lights on at 0600 and off at 1800. * P < 0.05 compared with previous time point.

View larger version (13K):
[in this window]
[in a new window]

Fig. 2. A comparison of plasma sodium rhythms in SHR and WKY on basal NaCl diets. * P < 0.05 compared with WKY at same time point.

In SHR and WKY, the plasma sodium concentration and MAP rhythms were in nearly opposite phases (Fig. 3). In WKY, MAP peakedat 0400 and had a nadir during the daytime (Fig. 3). Thus thepeak plasma sodium concentration occurs close to the MAP nadir,whereas the plasma sodium concentration nadir occurs near theMAP peak. In SHR, peak MAP also occurred at night (0400), whereasthe nadir for MAP occurred at the end of the daylight period (Fig.3).

View larger version (23K):
[in this window]
[in a new window]

Fig. 3. A comparison between plasma sodium and mean arterial pressure (MAP) circadian rhythms in SHR (A) and WKY (B) on basal NaCl diets.

Experiment 2

The effects of high NaCl on the 24-h plasma sodium rhythm in WKY and SHR were analyzed. On the basis of the results of experiment1, plasma sodium concentration was examined at four time points(0400, 0800, 1400, and 2000). During exposure to the basal NaCldiet, both WKY and SHR displayed similar plasma sodium rhythmsas those obtained in experiment 1, and, as in that experiment,circulating sodium levels were significantly elevated in SHR comparedwith WKY at all points (Fig. 4). In WKY, a 4-day exposure to thehigh-NaCl diet significantly increased plasma sodium concentrationat all four time points, but did not appreciably alter the plasmasodium rhythm. In SHR, the high-NaCl diet also elevated the plasmasodium concentration at all time points, but it greatly bluntedthe plasma sodium circadian rhythm, i.e., there was no significantdecrease in plasma sodium concentration between 1400 and 2000and a blunted decrease at 0400 (Fig. 4).

View larger version (15K):
[in this window]
[in a new window]

Fig. 4. Plasma sodium concentrations in WKY and SHR that were fed either a basal NaCl diet or a high-NaCl diet. * P < 0.05 compared with basal diet group from the same strain; # P < 0.05 compared with previous time point in same group.

In WKY fed the high-NaCl diet, peak MAP occurred at 0400, whereas the nadir MAP was at 1400 (Fig. 5). The MAP and plasma sodiumrhythms were essentially opposite in WKY. In SHR on the high-NaCldiet, peak MAP occurred at 0400 and nadir MAP at 1400 (Fig. 5),and the plasma sodium rhythm was inversely related to the MAPrhythm.

View larger version (22K):
[in this window]
[in a new window]

Fig. 5. A comparison between plasma sodium and MAP circadian rhythms of SHR (A) and WKY (B) on high-NaCl diets for 4 days.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Arterial pressure displays a circadian rhythm that is entrained to the light-dark cycle, resulting in the highest arterialpressures during the night when the activity of rats is the greatestand the lowest arterial pressures during the daytime when ratstypically sleep (6, 8). Ingestive behavior follows a similarpattern, i.e., rats primarily consume food during the nighttime(30). Therefore, the present study tests the hypothesis thatplasma sodium concentration displays a 24-h rhythm parallel tothe MAP rhythm and may contribute to changes in MAP observed throughoutthe 24-h cycle. In contrast to our predictions, the plasma sodiumand arterial pressure rhythms are inversely correlated. The secondhypothesis is that the circadian rhythm of plasma sodium is disruptedin SHR fed a basal NaCl diet. The results demonstrate that plasmasodium concentrations are elevated in SHR (compared to WKY) ona basal NaCl diet, but SHR and WKY on the basal NaCl diet displaynearly identical plasma sodium rhythms. The present data alsotest the hypothesis that a high-NaCl diet disrupts the plasmasodium circadian rhythm and may thereby contribute to NaCl sensitivityin SHR. The results demonstrate that a high-NaCl diet elevatesaverage plasma sodium concentration similarly in both SHR andWKY, but the excess dietary NaCl blunts the normal rhythm of plasmasodium concentration only inSHR.

These results disprove our hypotheses that in rats plasma NaCl concentration increases during nighttime ingestive periods.Plasma NaCl and MAP rhythms were inversely related. Several mechanismsmay account for the observed NaCl rhythm. First, sympathetic nervoussystem activity exhibits a diurnal rhythm similar to MAP and thusit elevates MAP, inducing pressure natriuresis and diuresis duringthe nighttime and sodium retention during the daytime (16).Second, the plasma sodium rhythm is modified by circulating hormones.The circadian rhythm of plasma sodium is synchronous with therhythms of circulating hormones, such as aldosterone (9, 17,21), vasopressin, and oxytocin (31, 34, 51) and the renin-angiotensinsystem [i.e., angiotensin II (17, 21, 40), angiotensin-convertingenzyme (44, 47), and plasma renin activity (17, 19, 21,26)]. All of these rhythms are inverse to the rhythms of renalhemodynamics and excretion (18, 29, 38, 39). Third, feedingand drinking patterns and the kinetics of gastrointestinal sodiumabsorption likely influence the plasma sodium rhythm. As the ratseat, receptors in the oral/gastric system monitor sodium intakeand modify drinking, eating, and renal nerve activity accordingly(7, 10, 27, 46). The net effect of this is to diluteplasma sodium during the intake of food containing high NaCl.In contrast to these relatively rapid effects, the absorptionof sodium into the blood is more gradual. Much of the sodium fromfood is absorbed into the blood at the level of the small andlarge intestines, and this occurs up to 8 h postprandially. Thus,after late-night eating, the ingested sodium continues to be absorbedduring the daytime for several hours (43); because there islittle water consumption during this period (12), the protractedabsorption of sodium likely contributes to the gradual increasein plasma sodium during the daytime (18, 20, 25, 29, 38,39, 42, 49).

The present results confirm the hypothesis that plasma sodium concentration is elevated in SHR, compared with WKY fed a basaldiet. However, although plasma sodium levels are significantlyhigher in SHR, it is questionable whether this directly contributesto SHR hypertension. When WKY are placed on a high-NaCl diet,their plasma sodium concentration increases to a level above thatof SHR fed the basal NaCl diet, yet WKY display no significantincrease in 24-h MAP. This does not totally exclude the possibilitythat in SHR the elevated plasma sodium concentration contributesto hypertension. SHR lack many of the compensatory mechanismsthat WKY display and thus could be more sensitive to an increasein plasma sodium concentration. But, would a 4- to 5-meq increasein plasma sodium be capable of elevating MAP by 20 mmHg? Thismagnitude of plasma sodium increase is physiologically relevantto the brain, because arginine vasopressin release from the hypothalamusis increased by it (45). Also, an infusion of hypertonic salinethat causes an acute 4 meq/l increase in plasma sodium elevatesarterial pressure by ~20 mmHg in SHR (35). Furthermore, Li etal. (28) demonstrated that, in control rats, a plasma sodiumincrease of $approx$ 4 meq/l did not alter arterial pressure, but in mRenrats, drinking hypertonic saline increased plasma sodium concentrationand arterial pressure. Thus the ability of plasma sodium to affectarterial pressure is related to the underlying genetics of theanimal studied. Whether this increase is relevant to hypertensionin SHR on a basal NaCl diet remains to beelucidated.

The high-NaCl diet elevates plasma sodium concentration in SHR and WKY during the entire day, but the contribution of thisincrease to NaCl-sensitive hypertension in SHR is less clear.The high-NaCl diet causes a similar rise in plasma sodium concentrationin SHR and WKY (~3 meq/l). In contrast, the high-NaCl diet differentiallyaffects the plasma sodium rhythms in the two strains. In SHR therhythm is significantly blunted (the range is reduced by $approx$ 40%),and the large decrease in plasma sodium that normally occurs duringthe early nighttime ( $approx$ 2000) is absent. In WKY, there was no significantreduction in the plasma sodium rhythm, and the early nighttimedecrease in plasma sodium concentration is reduced by <25%. Thusan average daily increase in plasma sodium concentration doesnot inevitably lead to elevated arterial pressure, but the lossof the normal circadian rhythm for plasma sodium may play arole.

It is unclear what accounts for the blunting of the sodium rhythm in SHR, but possibilities include increased ingestive behaviorand/or decreased sodium excretion. The failure of plasma sodiumto decrease during the early wake period in SHR may contributeto the development of NaCl-sensitive hypertension by activatingosmoreceptors at a time when the brain is increasing sympatheticnervous system activity. There are several mechanisms by whichelevated plasma NaCl may contribute to NaCl-sensitive hypertensionin SHR. Our previous studies indicate that in SHR, a high-NaCldiet leads to a decrease in norepinephrine release in the anteriorhypothalamic nucleus (AHA) and that this leads to NaCl-sensitivehypertension (33). Osmo- and/or sodium receptors in the circumventricularorgans of the brain appear to contribute to this decrease in AHAnorepinephrine release (36) in SHR on a high-NaCl diet. Thepresent results indicate that plasma sodium concentration is abnormallyelevated during the early nighttime, thereby potentially activatinga sympathoexcitatory pathway at the same time as other brain mechanisms(e.g., suprachiasmatic nucleus) are increasing sympathetic nervoussystem activity to meet the demands of the wakeperiod.

Perspectives

The present study is the first demonstration that plasma sodium displays a significant circadian rhythm in rats. Althoughthis rhythm is inverse to the arterial pressure and HR rhythms(6, 8), it is synchronous with the rhythms of sodium excretion(23, 35, 44, 45), renal hemodynamics (38, 39), andcirculating antinatriuretic and antidiuretic hormones [e.g., therenin-angiotensin system (17, 19, 21, 40, 44, 47),aldosterone (9, 17, 21), vasopressin, and oxytocin (31,34, 51)]. Taken together, these results suggest that the circadianarterial pressure and endocrine rhythms act in concert to influenceplasma sodium concentration. In SHR compared with WKY on basalNaCl diets, plasma sodium concentration is significantly higher,but the circadian rhythms are similar (1). In contrast, exposureto a high-salt diet increases plasma sodium concentration in bothSHR and WKY but disrupts the normal plasma sodium circadian rhythmonly in SHR. This dysregulation of plasma sodium rhythm may contributeto NaCl-sensitive hypertension inSHR.

	ACKNOWLEDGEMENTS

This work was supported by National Heart, Lung, and Blood Institute Grant HL-37722.

	FOOTNOTES

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: J. M. Wyss, Dept. of Cell Biology, 1670 Univ. Blvd., Birmingham, AL 35294-0019 (E-mail: jmwyss{at}uab.edu).

Received 2 September 1999; accepted in final form 5 January 2000.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1. Anderson, DE, Dietz JR, and Murphy P. Behavioural hypertension in sodium-loaded dogs is accompanied by sustained sodium retention. J Hypertens 5: 99-105, 1987[ISI][Medline].

2. Bains, JS, and Ferguson AV. Paraventricular nucleus neurons projecting to the spinal cord receive excitatory input from the subfornical organ. Am J Physiol Regulatory Integrative Comp Physiol 268: R625-R633, 1995[Abstract/Free Full Text].

3. Bourque, CW, and Oliet SHR Osmoreceptors in the central nervous system. Ann Rev Physiol 59: 601-619, 1997[ISI][Medline].

4. Calhoun, DA, Wyss JM, and Oparil S. High NaCl diet enhances arterial baroreflex in NaCl-sensitive spontaneously hypertensive rats. Hypertension 17: 363-368, 1991[Abstract/Free Full Text].

5. Calhoun, DA, Zhu S, Wyss JM, and Oparil S. Diurnal blood pressure variation and dietary NaCl in spontaneously hypertensive rats. Hypertension 24: 1-8, 1994[Abstract/Free Full Text].

6. Calhoun, DA, Zhu S, Wyss JM, and Oparil S. Diurnal blood pressure variation and dietary NaCl in spontaneously hypertensive subjects. Hypertension 24: 1-8, 1995.

7. Carlson, SH, Beitz A, and Osborn JW. Intragastric hypertonic saline increases vasopressin and central fos immunoreactivity in conscious rats. Am J Physiol Regulatory Integrative Comp Physiol 272: R750-R758, 1997[Abstract/Free Full Text].

8. Carlson, SH, Osborn JW, and Wyss JM. Hepatic denervation chronically elevates arterial pressure in Wistar-Kyoto rats. Hypertension 32: 46-51, 1998[Abstract/Free Full Text].

9. Charloux, A, Gronfier C, Lonsdorfer-Wolf E, Piquard F, and Brandenberger G. Aldosterone release during the sleep-wake cycle in humans. Am J Physiol Endocrinol Metab 276: E43-E49, 1999[Abstract/Free Full Text].

10. Choi-Kwon, S, McCarty R, and Baertschi AJ. Splanchnic control of vasopressin secretion in conscious rats. Am J Physiol Endocrinol Metab 259: E19-E26, 1990[Abstract/Free Full Text].

11. Cowley, AW, Jr. Role of the renal medulla in volume and arterial pressure regulation. Am J Physiol Regulatory Integrative Comp Physiol 273: R1-R15, 1997[Abstract/Free Full Text].

12. Cunningham, JT, Beltz T, Johnson RF, and Johnson AK. The effects of ibotenate lesions of the median preoptic nucleus on experimentally-induced and circadian drinking behavior in rats. Brain Res 580: 325-330, 1992[ISI][Medline].

13. Ely, DL, Folkow B, and Paradise NF. Risks associated with dietary sodium reduction in the spontaneous hypertensive rat model of hypertension. Am J Hypertens 3: 650-660, 1990[ISI][Medline].

14. Fang, Z, Berecek K, and Wyss JM. Dietary NaCl-sensitive hypertension in one-year-old spontaneously hypertensive rats and lifetime captopril-treated Wistar Kyoto rats (Abstract). Hypertension 32: 36, 1999.

15. Greenberg, S, and Osborn JL. Relationship between sodium balance and renal innervation during hypertension development in the spontaneously hypertensive rat. J Hypertens 12: 1359-1364, 1994[ISI][Medline].

16. Hall, JE, Guyton AC, and Brands MW. Pressure-volume regulation in hypertension. Kidney Int 55: S35-S41, 1996.

17. Hilfenhaus, M. Circadian rhythm of the renin-angiotensin-aldosterone system in the rat. Arch Toxicol 36: 305-316, 1976[ISI][Medline].

18. Hilfenhaus, M, and Herting T. The circadian rhythm of renal excretion in the rat: relationship between electrolyte and corticosteroid excretion. Contrib Nephrol 19: 56-62, 1980[Medline].

19. Ikonomov, OC, Stoynev AG, Shisheva AC, and Tarkolev NT. Effect of constant light and darkness on the circadian rhythms in rats. II. Plasma renin activity and insulin concentration. Acta Physiol Pharmacol Bulg 11: 55-61, 1985[Medline].

20. Janssen, BJ, Tyssen CM, Duindam H, and Rietveld WJ. Suprachiasmatic lesions eliminate 24-h blood pressure variability in rats. Physiol Behav 55: 307-311, 1994[Medline].

21. Jensen, LW, and Pedersen EB. Nocturnal blood pressure and relation to vasoactive hormones and renal function in hypertension and chronic renal failure. Blood Press 6: 332-342, 1997[Medline].

22. Johnson, AK. Role of the periventricular tissue surrounding the anteroventral third ventricle (AV3V) in the regulation of body fluid homeostasis. In: Vasopressin, edited by Schrier RW.. New York: Raven, 1985, p. 319-331.

23. Johnson, AK, and Gross PM. Sensory circumventricular organs and brain homeostatic pathways. FASEB J 7: 678-686, 1993[Abstract].

24. Johnson, AK, and Loewy AD. Circumventricular organs and their role in visceral functions. In: Central Regulation of Autonomic Functions, edited by Loewy AD, and Spyer KM.. New York: Oxford University Press, 1990, p. 247-267.

25. Kafka, MS, Wirz-Justice A, Naber D, Moore RY, and Benedito MA. Circadian rhythms in rat brain neurotransmitter receptors. Fed Proc 42: 2796-2801, 1983[ISI][Medline].

26. Kawasaki, T, Cugini P, Uezono K, Sasaki H, Itoh K, Nishiura M, and Shinkawa K. Circadian variations of total renin, active renin, plasma renin activity and plasma aldosterone in clinically healthy young subjects. Horm Metab Res 22: 636-639, 1990[ISI][Medline].

27. Kraly, FS, Kim Y, Dunham LM, and Tribuzio RA. Drinking after intragastric NaCl without increase in systemic plasma osmolality in rats. Am J Physiol Regulatory Integrative Comp Physiol 269: R1085-R1092, 1995[Abstract/Free Full Text].

28. Li, P, Morris M, Ferrario CM, Barrett C, Ganten D, and Callahan MF. Cardiovascular, endocrine, and body fluid-electrolyte responses to salt loading in mRen-2 transgenic rats. Am J Physiol Heart Circ Physiol 275: H1130-H1137, 1998[Abstract/Free Full Text].

29. Luke, DR, Wasan K, and Vadiei K. Circadian variation in renal function of the obese rat. Renal Physiol Biochem 14: 71-80, 1991[ISI][Medline].

30. Madrid, JA, Sanchez-Vazquez FJ, Lax P, Matas P, Cuenca EM, and Zamora S. Feeding behavior and entrainment limits in the circadian system of the rat. Am J Physiol Regulatory Integrative Comp Physiol 275: R372-R383, 1998[Abstract/Free Full Text].

31. Morawska-Barszczewska, J, Guzek JW, and Kaczorowska-Skora J. Cholecystokinin octapeptide and the daily rhythm of vasopressin and oxytocin release. Exp Clin Endocrinol Diabetes 104: 164-171, 1996[ISI][Medline].

32. Navar, LG. The kidney in blood pressure regulation and development of hypertension. Med Clin North Am 81: 1165-1198, 1997[ISI][Medline].

33. Oparil, S, Chen Y-F, Peng N, and Wyss JM. Anterior hypothalamic norepinephrine, atrial natriuretic peptide and hypertension. Front Neuroendocrinol 17: 212-246, 1996[ISI][Medline].

34. Pasqualetti, P, Festuccia V, Collacciani A, Acitelli P, and Casale R. Circadian rhythm of arginine vasopressin in hepatorenal syndrome. Nephron 78: 33-37, 1998[ISI][Medline].

35. Peng, N, Meng QC, Oparil S, and Wyss JM. Acute saline infusion decreases noradrenaline release in the anterior hypothalamic area. Hypertension 27: 578-583, 1996[Abstract/Free Full Text].

36. Peng N, Wei CC, Oparil S, and Wyss JM. The organism vasculosum of the lamina terminalis regulates noradrenaline release in the anterior hypothalamic nucleus in response to increases in plasma NaCl. Neuroscience In press.

37. Pinto, YM, Paul M, and Ganten D. Lessons from rat models of hypertension: from Goldblatt to genetic engineering. Cardiovasc Res 39: 77-88, 1998[Abstract/Free Full Text].

38. Pons, M, Schnecko A, Witte K, Lemmer B, Waterhouse JM, and Cambar J. Circadian rhythms in renal function in hypertensive TGR(mRen-2)27 rats and their normotensive controls. Am J Physiol Regulatory Integrative Comp Physiol 271: R1002-R1008, 1996[Abstract/Free Full Text].

39. Pons, M, Tranchot J, L'Azou B, and Cambar J. Circadian rhythms of renal hemodynamics in unanesthetized, unrestrained rats. Chronobiol Int 11: 301-308, 1994[ISI][Medline].

40. Portaluppi, F, Vergnani L, Manfredini R, and Fersini C. Endocrine mechanisms of blood pressure rhythms. Ann NY Acad Sci 783: 113-131, 1996[Abstract].

41. Sanders, PW. Salt-sensitive hypertension: lessons from animal models. Am J Kidney Dis 28: 775-782, 1996[ISI][Medline].

42. Sano, H, Hayashi H, Makino M, Takezawa H, Hirai M, Saito H, and Ebihara Effects of suprachiasmatic lesions on circadian rhythms of blood pressure, heart rate and locomotor activity in the rat. Jpn Circ J 59: 565-573, 1995[Medline].

43. Sawamoto, T, Haruta S, Kurosaki Y, Higaki K, and Kimura T. Prediction of the plasma concentration profiles of orally administered drugs in rats on the basis of gastrointestinal transit kinetics and absorbability. J Pharm Pharmacol 49: 450-457, 1997[ISI][Medline].

44. Stepien, M, Witte K, and Lemmer B. Chronobiologic evaluation of angiotensin-converting enzyme activity in serum and lung tissue from normotensive and spontaneously hypertensive rats. Chronobiol Int 10: 331-337, 1993[ISI][Medline].

45. Thrasher, TN. Circumventricular organs, thirst, and vasopressin secretion. In: Vasopressin, edited by Schrier RW.. New York: Raven, 1985, p. 311-318.

46. Thrasher, TN, Keil LC, and Ramsay DJ. Drinking, oropharyngeal signals, and inhibition of vasopressin secretion in dogs. Am J Physiol Regulatory Integrative Comp Physiol 253: R509-R515, 1987[Abstract/Free Full Text].

47. Veglio, F, Pietrandrea R, Ossola M, Vignani A, and Angeli A. Circadian rhythm of the angiotensin converting enzyme (ACE) activity in serum of healthy adult subjects. Chronobiologia 14: 21-25, 1987[ISI][Medline].

48. Volpe, M, Rubattu S, Ganten D, Enea I, Russo R, Lembo G, Mirante A, Condorelli G, and Trimarco B. Dietary salt excess unmasks blunted aldosterone suppression and sodium retention in the stroke-prone phenotype of the spontaneously hypertensive rat. J Hypertens 11: 793-798, 1993[ISI][Medline].

49. Witte, K, Schnecko A, Buijs RM, van der Vliet J, Scalbert E, Delagrange P, Guardiola-Lemaitre B, and Lemmer B. Effects of SCN lesions on circadian blood pressure rhythm in normotensive and transgenic hypertensive rats. Chronobiol Int 15: 135-145, 1998[ISI][Medline].

50. Wyss, JM, and Carlson SH. The role of the central nervous system in hypertension. Curr Hyperten Rep 3: 246-253, 1999.

51. Yasin, SA, Costa A, Besser GM, Hucks D, Grossman A, and Forsling ML. Melatonin and its analogs inhibit the basal and stimulated release of hypothalamic vasopressin and oxytocin in vitro. Endocrinology 132: 1329-1336, 1993[Abstract].

52. Yo, Y, Nagano M, Moriguchi A, Nakamura F, Kobayashi R, Okuda N, Kamitani A, Nakamura Y, Kamide K, Fujisawa T, Higaki J, Mikami H, and Ogihara T. Predominance of nocturnal sympathetic nervous activity in salt-sensitive normotensive subjects. Am J Hypertens 9: 726-731, 1996[ISI][Medline].

This article has been cited by other articles:

J. M. Adams, C. J. Madden, A. F. Sved, and S. D. Stocker
Increased Dietary Salt Enhances Sympathoexcitatory and Sympathoinhibitory Responses From the Rostral Ventrolateral Medulla
Hypertension, August 1, 2007; 50(2): 354 - 359.
[Abstract] [Full Text] [PDF]

V. L. Brooks, K. L. Freeman, and Y. Qi
Time course of synergistic interaction between DOCA and salt on blood pressure: roles of vasopressin and hepatic osmoreceptors
Am J Physiol Regulatory Integrative Comp Physiol, December 1, 2006; 291(6): R1825 - R1834.
[Abstract] [Full Text] [PDF]

T. L. O'Donaughy and V. L. Brooks
Deoxycorticosterone Acetate-Salt Rats: Hypertension and Sympathoexcitation Driven by Increased NaCl Levels
Hypertension, April 1, 2006; 47(4): 680 - 685.
[Abstract] [Full Text] [PDF]

V. L. Brooks, Y. Qi, and T. L. O'Donaughy
Increased osmolality of conscious water-deprived rats supports arterial pressure and sympathetic activity via a brain action
Am J Physiol Regulatory Integrative Comp Physiol, May 1, 2005; 288(5): R1248 - R1255.
[Abstract] [Full Text] [PDF]

P. Meneton, X. Jeunemaitre, H. E. de Wardener, and G. A. Macgregor
Links Between Dietary Salt Intake, Renal Salt Handling, Blood Pressure, and Cardiovascular Diseases
Physiol Rev, April 1, 2005; 85(2): 679 - 715.
[Abstract] [Full Text] [PDF]

B. S. Huang, B. N. Van Vliet, and F. H. H. Leenen
Increases in CSF [Na+] precede the increases in blood pressure in Dahl S rats and SHR on a high-salt diet
Am J Physiol Heart Circ Physiol, September 1, 2004; 287(3): H1160 - H1166.
[Abstract] [Full Text] [PDF]

V. L. Brooks, K. L. Freeman, and K. A. Clow
Excitatory amino acids in rostral ventrolateral medulla support blood pressure during water deprivation in rats
Am J Physiol Heart Circ Physiol, May 1, 2004; 286(5): H1642 - H1648.
[Abstract] [Full Text] [PDF]

N. Peng, J. T. Clark, C.-C. Wei, and J. M. Wyss
Estrogen Depletion Increases Blood Pressure and Hypothalamic Norepinephrine in Middle-Aged Spontaneously Hypertensive Rats
Hypertension, May 1, 2003; 41(5): 1164 - 1167.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in ISI Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via ISI Web of Science (18)

Citing Articles via Google Scholar

Google Scholar

Articles by Fang, Z.

Articles by Wyss, J. M.

Search for Related Content

PubMed

PubMed Citation

Articles by Fang, Z.

Articles by Wyss, J. M.

				V. L. Brooks, K. L. Freeman, and Y. Qi Time course of synergistic interaction between DOCA and salt on blood pressure: roles of vasopressin and hepatic osmoreceptors Am J Physiol Regulatory Integrative Comp Physiol, December 1, 2006; 291(6): R1825 - R1834. [Abstract] [Full Text] [PDF]

				T. L. O'Donaughy and V. L. Brooks Deoxycorticosterone Acetate-Salt Rats: Hypertension and Sympathoexcitation Driven by Increased NaCl Levels Hypertension, April 1, 2006; 47(4): 680 - 685. [Abstract] [Full Text] [PDF]

				V. L. Brooks, Y. Qi, and T. L. O'Donaughy Increased osmolality of conscious water-deprived rats supports arterial pressure and sympathetic activity via a brain action Am J Physiol Regulatory Integrative Comp Physiol, May 1, 2005; 288(5): R1248 - R1255. [Abstract] [Full Text] [PDF]

				P. Meneton, X. Jeunemaitre, H. E. de Wardener, and G. A. Macgregor Links Between Dietary Salt Intake, Renal Salt Handling, Blood Pressure, and Cardiovascular Diseases Physiol Rev, April 1, 2005; 85(2): 679 - 715. [Abstract] [Full Text] [PDF]

				B. S. Huang, B. N. Van Vliet, and F. H. H. Leenen Increases in CSF [Na+] precede the increases in blood pressure in Dahl S rats and SHR on a high-salt diet Am J Physiol Heart Circ Physiol, September 1, 2004; 287(3): H1160 - H1166. [Abstract] [Full Text] [PDF]

				V. L. Brooks, K. L. Freeman, and K. A. Clow Excitatory amino acids in rostral ventrolateral medulla support blood pressure during water deprivation in rats Am J Physiol Heart Circ Physiol, May 1, 2004; 286(5): H1642 - H1648. [Abstract] [Full Text] [PDF]

				N. Peng, J. T. Clark, C.-C. Wei, and J. M. Wyss Estrogen Depletion Increases Blood Pressure and Hypothalamic Norepinephrine in Middle-Aged Spontaneously Hypertensive Rats Hypertension, May 1, 2003; 41(5): 1164 - 1167. [Abstract] [Full Text] [PDF]