Renal responses to plasma volume expansion and hyperosmolality in fasting seal pups

doi:10.1152/ajpregu.00418.2001

Renal responses to plasma volume expansion and hyperosmolality in fasting seal pups

Rudy M. Ortiz¹^,², Charles E. Wade², Daniel P. Costa¹, and C. Leo Ortiz¹

¹ Department of Biology, University of California, Santa Cruz 95064; and ² Neuroendocrinology Laboratory, Division of Life Sciences, National Aeronautics and Space Administration Ames Research Center, Moffett Field, California 94035

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Renal responses were quantified in northern elephant seal (Mirounga angustirostris) pups during their postweaning fast toexamine their excretory capabilities. Pups were infused with eitherisotonic (0.9%; n = 8; Iso) or hypertonic (16.7%; n = 7; Hyper)saline via an indwelling catheter such that each pup received3 mmol NaCl/kg. Diuresis after the infusions was similar in magnitudebetween the two treatments. Osmotic clearance increased by 37%in Iso and 252% in Hyper. Free water clearance was reduced 3.4-foldin Hyper but was not significantly altered in Iso. Glomerularfiltration rate increased 71% in the 24-h period after Hyper,but no net change occurred during the same time after Iso. Natriuresisincreased 3.6-fold in Iso and 5.3-fold in Hyper. Iso decreasedplasma arginine vasopressin (AVP) and cortisol acutely, whereasHyper increased plasma and excreted AVP and cortisol. Iso wasaccompanied by the retention of water and electrolytes, whereasthe Hyper load was excreted within 24 h. Natriuresis is attributedto increased filtration and is independent of an increase in atrialnatriuretic peptide and decreases in ANG II and aldosterone. Fastingpups appear to have well-developed kidneys capable of both extremeconservation and excretion of Na⁺.

aldosterone; cortisol; glomerular filtration rate; kidney; osmoregulation; vasopressin

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

NORTHERN ELEPHANT SEAL (Mirounga angustirostris) (NES) pups naturally endure postweaning fasts of 8-12 wk without any apparentdeleterious effects on water and electrolyte balance (26, 29).During this fasting period, water balance in NES pups is maintainedby the production of metabolically derived water from the oxidationof large fat stores (26). During the transition between nursingand fasting, the kidneys must switch between a state of almostconstant excretion to a condition of chronic conservation of waterand electrolytes to maintain fluid and electrolytehomeostasis.

Under normal conditions, water and electrolyte homeostasis is rigidly maintained through the mediation of a number of hormonalsystems. Arginine vasopressin (AVP) stimulates the resorptionof water from the collecting duct of the kidney (18, 42, 44).In pharmacological doses, AVP may act as a natriuretic factor(6, 43) and, in concert with urea, may stimulate an increasein glomerular filtration rate (GFR; see Refs. 2 and 3).Release of AVP is inhibited by plasma volume expansion (PVE) orstimulated by increased plasma osmolality (hyperosmolality; seeRefs. 25 and 47). The renin-angiotensin-aldosterone system(RAAS) is the primary regulatory pathway by which renal Na⁺ resorption is achieved. Secretion of renin is inhibited by PVEand by an increase in plasma Na⁺ (11, 15). Renin may also be inhibited by atrial natriureticpeptide (ANP), which is stimulated by an increase in atrial pressure,or PVE (23).

In mammals, PVE and hyperosmolality induce a number of renal and hormonal alterations. PVE results in an increased diuresisand natriuresis associated with reduced levels of AVP, plasmarenin activity (PRA) or ANG II, and aldosterone (10, 34, 36,39). During PVE in most species, GFR usually remains constant(21, 34). After elevated dietary Na⁺ intake or hypertonic saline infusion, plasma AVP increases (7,37, 47), whereas ANG II or PRA and aldosterone decrease (13,20, 37). In humans, hyperosmolality is generally associatedwith a lack of a change in GFR and unchanged (12) or decreased(16) urine flow. However, in dogs, GFR and urine flow have beenreported to increase only acutely and moderately (7, 37).Unfortunately, data are limited and inconclusive on the renaland hormonal responses to PVE and hyperosmolality in marine-adaptedmammals (for review, see Ref. 28), which provide an ideal modelfor studies on the responsiveness and adaptation of mammaliankidneys to extremeconditions.

A decrease in urine output during the fast, accompanied by a reduction in excreted urea and an increase in urine osmolality,suggests that AVP may be elevated during this period. Previousstudies in seals suggest that AVP has an antidiuretic role (8,14, 33, 40). However, the antidiuretic function of AVP duringthe fast in NES pups remains inconclusive (29, 30). Aldosteroneand PRA are highly correlated during the fast, with each exhibitinga peak in concentrations after ~5 wk postweaning, suggesting thatRAAS is involved in the conservation of water and electrolytesand that the sensitivity may change over the course of the fast(30). The role of ANP in Na⁺ excretion in any marine mammal has yet to beexamined.

Reduced GFR and urinary water output and increased resorption of electrolytes, which appears to be attributed to the increasein RAAS, are some of the physiological mechanisms NES pups employto conserve water and electrolytes during the fast. However, theexcretory capabilities of pups during their postweaning fast haveyet to be examined. Therefore, the present study was conductedto provide an understanding of renal responses and hormonal regulationof a marine-adapted mammal when subjected to PVE and hyperosmolality.The objectives of the present study were 1) to quantify changesin renal function associated with PVE and hyperosmolality, 2)to quantify the hormonal responses to PVE and hyperosmolality,and 3) to provide insight to the adaptation of kidney functionin seals as they transition between a state of chronic conservationto acute excretion of water and electrolytes. Because body watermust be tightly regulated during fasting, we hypothesized thatpups will excrete Na⁺ from an isotonic saline load quicker than an equimolar hypertonicsaline load because more water is available for excretion withan isotonic load than with an hypertonic load. Insight into therenal excretory mechanisms in fasting NES pups will further ourknowledge of the ability of these animals to exist in two diverseenvironments and conditions (fasting on land and feeding atsea).

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Animals. Fifteen pups were transported from Año Nuevo State Park (~30 km north of Santa Cruz, CA) to Long Marine Laboratory, Universityof California, Santa Cruz. Eight pups (100 ± 24 kg; 5 males, 3females) were used for an isotonic saline infusion study and seven(109 ± 15 kg; 4 males, 3 females) for an hypertonic saline infusionstudy. Animals were brought to the laboratory one or two at atime over the course of 9 wk during their postweaning fast. Uponarrival at the marine laboratory, pups were weighed using a hanging-loadcell and placed in a sand pit overnight. The next morning, a pupwas sedated with 0.01 ml/kg tiletamine hydrochloride and zolazepamhydrochloride (Telazol; Fort Dodge Animal Health, Fort Dodge,IA), and a 110-cm catheter (5 french) was inserted in the extraduralspinal vein. After the catheterization procedure, pups were allowedto recover for ~22 h before the collection of control data. Thecatheter served as the sole route by which materials were infusedor blood was collected. A three-way stop cock at the exposed endof the catheter facilitated the dosing and flushing of materialsinto the pups and the collection of bloodsamples.

Immediately after the catheterization and every day (4-5 days) until the catheter was removed, each pup received 1 g cefazolinsodium (Fort Dodge Animal Health). The catheterized pup was thenplaced in a 0.8 × 1.6 × 0.8-m metabolic cage with a urine collectionpan underneath attached to a collectionflask.

Isotonic saline infusion. On the day before infusion of sterile, isotonic saline (0.9%; Fisher Scientific), a series of control blood samples was takenin the same manner as on the day of the infusion. Control samplesconsisted of pre- and postdose samples of a sham dosing followedby 15-, 30-, 45-, 60-, 90-, and 120-min and 24-h samples. The24-h sample also served as the preinfusion sample for the isotonicsaline infusion experiment that was initiated at that time. Onthe day of the isotonic saline infusion, pups were infused withsaline at a volume calculated to be ~33% of estimated plasma volume.Plasma volume was estimated by multiplying the averaged hematocrit(Hct) measured for each animal during the control period by theestimated blood volume (13% of body mass; see Ref. 45). Warmed(32°C), sterile saline was drawn into sterile 60-ml syringes,and the syringes were placed on the stop cock for infusion. Afterthe infusion (2 min), a postsample was taken, and subsequent sampleswere obtained at 15, 30, 45, 60, 90, and 120 min and 24 h postinfusion.Infusion time ranged between 40 and 75 min (12-15 ml/min), dependingon the infusion volume. The mean ± SE Na⁺ load was 319 ± 25mmol.

Hypertonic saline infusion. As with the isotonic saline study, animals in the hypertonic saline group served as their own control using the same bloodsampling regime for control and postinfusion periods. Warmed (32°C)sterile saline (16.7%) was drawn in sterile 60-ml syringes, andthe syringes were placed on the stop cock for infusion. Animalswere infused with 1 ml/kg body mass at a rate of 4 ml/min (28± 1 min). The mean ± SE Na⁺ load was 310 ±15.

Blood samples and plasma analyses. All blood samples were obtained from the indwelling catheter into 20-ml syringes. Before the collection of each blood sample,a 3-ml sample was drawn in a 20-ml syringe with 10 ml of sterileisotonic saline to clear the catheter line of any residual bloodthat could potentially contaminate the samples drawn. Blood wastransferred into one prechilled lithium heparin and one prechilledEDTA-treated tube. After 30 s of gentle rocking, duplicate aliquotsof whole blood were removed in capillary tubes and spun in a microcentrifugeto determine Hct (%). The remaining blood was centrifuged for15 min (1,500 g at 4°C), and plasma was collected and frozen at $-$ 20°C for lateranalyses.

All assays were conducted on commercially available RIA kits validated previously for use with NES plasma (30, 31, 50).Aldosterone (DPC, Los Angeles, CA), cortisol (DPC), ANP (PhoenixPharmaceuticals, Sunnyvale, CA), and AVP (Phoenix Pharmaceuticals)were analyzed from heparinized plasma, and PRA (Dupont-NEN) wasdetermined from EDTA-treated plasma. Before being assayed, ANPand AVP were extracted from the plasma using a C-18 column extractionprocedure, as previously described (50). Percent recovery ofhormone after extraction was determined by calculating the percentrecovery of counts from the extraction of radiolabeled hormonein pooled plasma. Percent recovery for plasma AVP and ANP was84 and 68%, respectively. Final concentrations were not correctedfor incomplete extractions. All samples were run in duplicatein each assay. Hormone assays displayed intra-assay percent coefficientof variation (%CV) of between 4 and 9% and interassay %CV of between5 and 12% (including urinary hormones). Electrolytes (Na⁺, K⁺, and Cl), creatinine, glucose, total proteins, and blood-urea-nitrogen(BUN) were analyzed from heparinized plasma and were measuredon a clinical autoanalyzer (Roche Diagnostics, Somerville, NJ).Osmolality was determined using a freezing-point osmometer (Fiske,Norwood,MA).

Urine analyses. In each study, urine volume in the collection flask was measured and a 3-ml aliquot was filtered and frozen for later analyses.For the isotonic saline study, urine was collected on a 24-h basisafter postcatheterization, control, and the postinfusion periods.Urine collections for the hypertonic saline study were taken ona 24-h basis for the postcatheterization and control periods.However, the following four collections were obtained postinfusion:1) 30-90 min, 2) 120-180 min, 3) 320-450 min, and 4) 14.5-16.5h. A urine sample was collected for each animal at each of thefour postinfusion periods. A cumulative 24-h postinfusion valuefor each parameter measured was then calculated from the fourcollection periods. Therefore, the hypertonic saline study consistedof seven urinary excretion values (postcatheterization, control,1 postinfusion, 2 postinfusion, 3 postinfusion, 4 postinfusion,and cumulative 24 hpostinfusion).

For both the isotonic saline and hypertonic saline studies, urine samples were analyzed for electrolytes (Na⁺, K⁺, and Cl), creatinine, osmolality, total proteins, and BUN using the sametechniques as with the plasma samples. The same commercial assaysused to measure the plasma hormones were used to measure the extractedurinary hormones. The commercial antibodies displayed significantcross-reactivity for the urinary hormones assayed, as indicatedby the significant parallelism between the standards and the dilutedurine pool (Fig. 1). ANP, AVP, and ANG II were extracted in asimilar way as the plasma, with the exception of the volume (0.5ml). Percent recoveries of excreted peptide hormones (ANP, AVP,and ANG II) were between 81 and 86%. Aldosterone and cortisolwere extracted as previously described (32). Percent recoveryof excreted steroid hormones was 93%. As with the plasma extractions,final urinary concentrations were not corrected for by incompleteextractions. For the determination of cAMP and cGMP (Assay Designs,Ann Arbor, MI) concentrations, urine samples were diluted between1:40 and 1:200 before being assayed by enzymaticimmunoassay.

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Fig. 1. Representative estimations of the percentage of cross-reactivity between urinary hormones from northern elephant seals (NES) and the commercial antibodies. A: example of an urinary peptide hormone. B: example of an urinary steroid. B/B_o, bound-to-free ratio.

Calculations. For all variables, excretion values were calculated by multiplying the urinary concentration by urine flow. GFR was estimatedby creatinine clearance. For the calculation of GFR during bothpostcatheterization periods, the plasma creatinine (P_crt) valueused was from the precontrol sample. During the control periods,the P_crt value used was the average of all the samples taken duringthat period. The same was done for the postinfusion period ofthe isotonic saline study. However, because multiple urine collectionswere taken during the hypertonic saline study, the P_crt value(or the mean of the values) used was that corresponding with theperiod of urine collection. When a plasma sample was not takenduring a urine collection period, the mean of the most recentand the 24-h postinfusion sample wasused.

Osmotic clearance (C_osm) was calculated as

C<SUB>osm</SUB>(ml<IT>/</IT>h)<IT>=</IT>U<SUB>osm</SUB>V<IT>/</IT>P<SUB>osm</SUB>

where U_osm and P_osm represent urinary and plasma osmolality, respectively, and V is urine flow. The same conditions usedpreviously to determine the P_crt value for the estimation of GFRwere also applied in the determination of the plasma osmolalityvalue used to estimate C_osm during the postinfusion periods ofthe hypertonic saline study. Free water clearance (C_H₂O)was calculated as the difference between V and C_osm.

Fractional excretion (FE) was calculated as

FE(<IT>%</IT>)<IT>=</IT>([U] × V<IT>/</IT>[P]<IT>×</IT>GFR)<IT>×</IT>100<IT>%</IT>

where [U] and [P] represent urinary and plasma concentrations,respectively.

Statistics. Means for plasma values during the postinfusion period were compared with those during the control period by two-way ANOVAadjusted for repeated measures over time. If significant grouptimes time interactions were not observed, means during the postinfusionperiod were compared with preinfusion values by one-way ANOVAadjusted for repeated measures. Urine values were compared byone-way ANOVA adjusted for repeated measures. Means for the controlperiod for isotonic saline and hypertonic saline were comparedby two-way ANOVA adjusted for repeated measures over time to determineif any group effects existed. Fisher's protected least significantdifference test was administered post hoc if significance wasdetermined. Correlations were determined by simple regressionof the means and were considered different at P < 0.05. Means± SE were considered significantly different at P < 0.05. Allstatistical analyses were made using Statview (38).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Among all the parameters measured, a significant group effect during the control period existed for only Hct, plasma ANP,and excreted cAMP. Changes in Hct were reported as the percentchange from baseline to correct for the difference in Hct (isotonicsaline, 52 ± 1% and hypertonic saline, 58 ± 1%; P < 0.01) betweenthe twogroups.

Isotonic saline plasma data. After infusion, Hct and total proteins decreased significantly (Fig. 2). Osmolality (Fig. 2), Na⁺, and creatinine (Table 1) were not altered. BUN (3.1 ± 0.4 and2.8 ± 0.4 mM) and K⁺ (4.1 ± 0.1 and 4.2 ± 0.2 mM) also did not change during the controland infusion periods, respectively. After infusion, AVP decreasedsignificantly and remained reduced (Fig. 3). Cortisol and PRAalso were reduced postinfusion and remained so after 24 h (Fig.3). Aldosterone (895 ± 109 and 862 ± 94 pg/ml) and ANP (11.9 ±3.3 and 9.3 ± 2.2 pg/ml) were not altered during the control andinfusion periods, respectively. However, aldosterone was reduced24 h after infusion (427 ± 62 pg/ml) compared with preinfusionconcentrations by paired t-test.

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Fig. 2. Mean ± SE hematocrit (A), plasma total proteins (B), and plasma osmolality (C) in response to the infusion of either isotonic (0.9%; n = 8) or hypertonic (16.7%; n = 7) saline. $dagger$ Significantly different (P < 0.05) from control.

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Table 1. Plasma data pre- and postinfusion

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Fig. 3. Mean ± SE plasma arginine vasopressin (AVP; A), plasma renin activity (PRA; B), and plasma cortisol (C) in response to infusion of either isotonic or hypertonic saline. Data taken immediately before (pre) and after (post) infusion. $dagger$ Significantly different (P < 0.05) from control. *Significantly different (P < 0.05) from pre.

Hypertonic saline plasma data. After infusion, osmolality, Na⁺, and Cl increased significantly, and Hct, creatinine, and total proteins decreased significantly(Fig. 2 and Table 1). K⁺ was reduced immediately after infusion (3.7 ± 0.2 mM), remainedreduced after the first 15 min postinfusion (3.8 ± 0.1 mM), butreturned to the preinfusion level (4.2 ± 0.1 mM) after 30 min.BUN did not change during the control (2.4 ± 0.1 mM) and infusion(2.5 ± 0.2 mM) periods. After infusion, AVP and cortisol increasedsignificantly, and PRA decreased significantly (Fig. 3). Aldosterone(602 ± 120 and 669 ± 140 pg/ml) and ANP (3.6 ± 1.1 and 2.7 ± 0.2pg/ml) were not altered during the control and infusion periods,respectively. However, aldosterone was reduced 24 h after infusion(366 ± 59 pg/ml) compared with preinfusion concentrations by pairedt-test.

Isotonic saline excretion data. The increase in urine volume after the infusion of isotonic saline accounted for only 30 ± 5% of the infused volume. Correctingfor control excretion values, pups excreted 19 ± 4 and 17 ± 5%of infused Na⁺ and Cl, respectively. Urine volume increased threefold after infusioncompared with control (266 ± 29 and 816 ± 125 ml/day). C_osm waselevated postinfusion; however, GFR and C_H₂Owere not altered (Figs. 4 and 5). Excretion, excretion adjustedfor excreted creatinine, and FE of Na⁺ and Cl increased after infusion (Tables 2 and 3). FE of K⁺ (8.5 ± 1.6 and 9.1 ± 1.2%) and urea FE (FE_urea; 37.6 ± 3.2 and43.6 ± 2.9%) were not different between control and postinfusionperiods, respectively.

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Fig. 4. Mean ± SE glomerular filtration rate (GFR) during postcatheterization (PC), control, and postinfusion (PI) periods of isotonic (0.9%; n = 8) and hypertonic (16.7%; n = 7) studies. Urine samples were collected at intervals between 1) 30 and 90 min, 2) 120 and 180 min, 3) 320 and 450 min, and 4) 14.5 and 16.5 h PI of hypertonic saline. Cumulative, 24-h postinfusion value was calculated from the 4 postinfusion samples. *Significantly different (P < 0.05) from control.

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Fig. 5. Mean ± SE urine flow (U_F; A), osmotic clearance (C_Osm; B), and free water clearance (C_H₂O; C) during the PC, control, and PI periods of the isotonic (0.9%; n = 8) and hypertonic (16.7%; n = 7) studies. See Fig. 4 legend for details. *Significantly different (P < 0.05) from control.

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Table 2. Urinary excretion during the postcatheterization, control, and postinfusion periods in the isotonic study

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Table 3. Fractional excretion of electrolytes and urea

Hypertonic saline excretion data. Urine volume increased fourfold 24 h after infusion compared with control (218 ± 47 and 883 ± 85 ml/day). GFR, urine flowrate, and C_osm increased and C_H₂O decreasedalmost immediately (30-90 postinfusion) and remained elevatedor reduced for the remainder of the collection periods (Figs.4 and 5). When Na⁺ and Cl excretion postinfusion was corrected for control excretion levels,the percentage of Na⁺ and Cl infused that was excreted equaled 97 ± 4 and 94 ± 3%, respectively.Creatinine excretion increased postinfusion (Table 4). Afterinfusion, osmotic and electrolyte excretion increased and remainedelevated, as well as when excretion was adjusted for excretedcreatinine (Table 4). FE of Na⁺ and Cl increased at 120-180 min postinfusion and remained elevated,whereas FE_urea was increased at periods 120-180 min postinfusionand at 320-450 min postinfusion compared with control (Table 3).Excretion of all measured hormones was increased at 30-90 minpostinfusion and remained elevated (Table 5). AVP, aldosterone,and cortisol excretion remained elevated when excretion was adjustedfor excreted creatinine (Table 5).

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Table 4. Urinary excretion during the postcatheterization, control, and postinfusion periods during the hypertonic study

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Table 5. Hormone excretion during the postcatheterization, control and postinfusion periods in the hypertonic study

Correlated excretion data. Means from both isotonic saline and hypertonic saline studies for excreted AVP were significantly and positively correlatedwith osmotic excretion and significantly and negatively correlatedwith C_H₂O (Fig. 6). Means of excreted cAMP forisotonic saline were significantly greater than those for hypertonicsaline and therefore were not included in the regression betweenexcreted AVP and excreted cAMP (Fig. 6). Means of excreted aldosteronefor hypertonic saline were positively and significantly correlatedwith both excreted ANG II (excreted aldosterone = $-$ 9 + 71 excretedANG II; R = 0.885; P < 0.002) and excreted cortisol (excretedaldosterone = 42 + 6 excreted cortisol; R = 0.979; P < 0.0001).Means of FE_urea for hypertonic saline were positively and significantlycorrelated with both excreted aldosterone (FE_urea = 20 + 0.1 excretedaldosterone; R = 0.702; P < 0.01) and excreted cortisol (FE_urea= 22 + 0.6 excreted cortisol; R = 0.794; P < 0.01). No relationshipsbetween excreted AVP and urea were observed.

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Fig. 6. Correlations between the means ± SE of excreted AVP and excreted cAMP (A), free C_H₂O (B), and osmotic excretion (C) from both the isotonic and hypertonic studies. Regression was considered significant at P < 0.05.

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

In general, the renal responses to PVE and hyperosmolality in humans and other terrestrial mammals have been well identified.Unfortunately, such is not the case for marine-adapted mammals.A better understanding of osmoregulation in these mammals couldprovide valuable insight on the evolution of renal function inmammals as they transitioned from an Na⁺-depleted, terrestrial habitat to a salt-rich, marine environment.Pups in both the isotonic saline and hypertonic saline studiesreceived equivalent mass-specific amounts of Na⁺, with the underlying difference being the volume of water associatedwith this Na⁺ load. The stark contrasts in the renal and hormonal responsesobserved between isotonic saline and hypertonic saline suggestthat the renal handling of Na⁺ depends on the volume of water associated with the salt load.Infusion of isotonic saline induced a condition of water and electrolyteretention. However, pups infused with hypertonic saline excretedexcess Na⁺ within 24 h, suggesting that these marine mammals are highlysensitive to excess Na⁺, although they have adapted well to living in an Na⁺-richenvironment.

The lack of significant differences (with the exceptions of Hct, plasma ANP, and excreted cAMP) in renal and hormonal parameters(i.e., GFR, urine flow, AVP, etc.) between the control periodsof the isotonic saline and hypertonic saline groups reveals thatthe two groups of animals were in essentially the same state ofrenal development. However, pronounced differences in responseto the infusion of equimolar quantities of Na⁺ as either an isotonic or hypertonic solution were observed (Table6). The infusion of hypertonic saline induced a diuresis similarin magnitude to that induced by the infusion of isotonic saline.Although the two stimuli resulted in similar ends, the means bywhich they were achieved were mechanistically dissimilar. Hypertonicsaline resulted in a twofold increase in GFR and C_osm and an almostfivefold decrease in C_H₂O compared with isotonicsaline postinfusion. Pups infused with hypertonic saline excreted97 ± 4% of infused Na⁺ and 94 ± 3% of infused Cl within the first 24 h postinfusion. However, pups infused withisotonic saline only excreted 19 ± 4 and 17 ± 5% of Na⁺ and Cl, respectively, and 30 ± 5% of water within the first 24 h. Althoughinfusion of isotonic saline resulted in retention of water andelectrolytes, infusion of hypertonic saline did not induce retentionof either electrolytes or water. In contrast, dogs switched toa high-salt diet exhibited a decrease in urine output in the first24 h along with retention of Na⁺ and water (20). Fasting pups appear to retain Na⁺ and Cl when sufficient water is made available for subsequent and delayedexcretion. The retained Na⁺ is probably stored interstitially as previously suggested (12),since plasma Na⁺ was not elevated. Retention of Na⁺ and water may closely resemble a condition comparable to whenthe animals are naturally feeding. Thus retention of water andelectrolytes may be a mechanism by which marine-adapted animalsavoid dehydration in a hyperosmotic environment.

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Table 6. Summary of renal and hormonal changes

Hypertonic saline resulted in an osmotic diuresis associated with an increase in GFR, despite a decrease in C_H₂Othat was comparable in magnitude to the increase in C_osm. Beforethe infusion of hypertonic saline, urinary excretion of wateraccounted for ~0.3% of filtration. After infusion, this valuewas only increased to 0.5%, suggesting that the efficiency inrenal water resorption was only reduced by 0.2% in spite of thenearly fourfold increase in urine flow. To achieve an efficiencyof renal water resorption after the infusion comparable to thatbefore infusion, C_H₂O had to be reduced in magnitudesimilar to that of the increase in C_osm. The net result was thatthe water required to maintain fluid homeostasis and support theincreased filtration rate and subsequent natriuresis was recycledat nearly the same efficiency as before the infusion. Althoughthe increase in urine output was statistically significant, thisincrease only accounted for ~2% of the pups' total body waterpool (27), suggesting that the net loss of water to accomplishthis diuresis was not physiologically significant. Therefore,seal pups can excrete excess Na⁺ rapidly (within 24 h) and efficiently without retention and atthe expense of a small amount (2%) of body water, which does notappear to negatively impact the hydration state of the animal.Dogs provided with a high-Na⁺ diet that was more than two times the mass-specific salt loadthan that infused in the present study decreased urine volumeand retained water and Na⁺ after the 1st day of treatment (20), indicating a stark contrastin renal handling of excess Na⁺ between a terrestrial and marine mammal. This contrast in renalhandling of Na⁺ may reflect the differences in the adaptation to the environmentsin which terrestrial and marine mammals haveevolved.

Increasing GFR reduces the transit time of Na⁺ in the filtrate through the proximal tubule and thus reduces the resorptionof Na⁺. A number of factors such as blood pressure, AVP, and cortisol(stress) may have contributed to the observed GFR-induced natriuresisafter the infusion of hypertonic saline. Although not quantifiedin the present study, an increase in blood pressure may have ledto the observed elevation in GFR and produced a pressure natriuresis.Unfortunately, the measurement of blood pressure was not technicallyfeasible in the present study; however, an elevation in mean arterialpressure (MAP) after Na⁺ loading in dogs has been observed (i.e., Ref. 7). If the increasein GFR is directly related to an elevation in MAP in the presentstudy, then this increase in pressure was most likely inducedby hypernatremia and not PVE. Both isotonic saline and hypertonicsaline resulted in PVE and natriuresis, but the natriuresis wasmore pronounced in hypertonic saline, and only hypertonic salineinduced an increase in GFR and a state of hypernatremia. Therefore,the hypertonic saline-induced natriuresis was the consequenceof increased filtration likely associated with a pressure natriuresis.An increase in GFR in response to an Na⁺ insult is not common in terrestrial mammals (12). The mechanismsinvolved with the isotonic saline-induced natriuresis are notas evident and warrant furtherinvestigation.

AVP release is inhibited by an increase in baroreceptor stimulation, which could reflect an increase in blood pressure, andis stimulated by an increase in plasma osmolality (41, 48).The volume of isotonic saline infused was sufficient to producePVE, as indicated by reductions in Hct and total proteins, whichwere sustained for at least 24 h. PVE was associated with a sustainedreduction in plasma AVP without a change in plasma osmolality,suggesting that AVP in these animals responds to volume expansionand most likely increased blood pressure, similar to terrestrialmammals (46, 47). Pups infused with hypertonic saline exhibiteda sustained increase in plasma osmolality and plasma AVP, suggestingan osmoreceptor-mediated response to increase AVP as in othermammals (41, 47, 48). The positive correlations betweenmean plasma AVP and plasma osmolality and Hct further corroboratethe presence of baro- and osmoreceptor-mediated mechanisms ofAVP modulation in NES pups. Also, in pharmacological doses, AVPhas been shown to produce natriuresis (43), suggesting thatAVP may have contributed to the natriuresis observed after theinfusion of hypertonicsaline.

Resorption of free water from the collecting duct is primarily mediated by the AVP-cAMP cascade in mammals (18, 19, 42).After the infusion of hypertonic saline, the increase in excretedAVP was significantly and positively correlated with an increasein excreted cAMP and osmotic excretion and significantly and negativelycorrelated with C_H₂O (or increased free waterresorption), providing the most conclusive data of an antidiureticfunction of AVP in any marine mammal. The resorption of free waterfrom renal collecting ducts in NES pups is most likely mediatedvia an AVP-cAMP mechanism as in terrestrial mammals (18, 42,44). Therefore, the maintenance of relatively low and unchangedAVP concentrations during the fast observed previously (30)suggests that the tubular resorption of water in fasting NES pupsis highly sensitive to AVP under normalconditions.

Both isotonic saline and hypertonic saline also resulted in an increase in FE of Na⁺ and Cl, with hypertonic saline exhibiting threefold greater excretionsof both electrolytes. However, the natriuresis observed afterboth stimuli was not associated with an increase in excreted ANP(or ANP adjusted for excreted creatinine in the case of hypertonicsaline) and/or reduced ANG II and aldosterone. Although Na⁺ loading generally increases ANP (i.e., Ref. 7), neither stimuliresulted in an increase in circulating or excreted ANP or excretedcGMP. The suppression of ANG II has been identified as a meansby which natriuresis is achieved after Na⁺ loading (37, 39). However, excreted ANG II and excreted ANGII adjusted for excreted creatinine were not reduced despite sustaineddecreases in PRA, suggesting dynamic alterations in the renin-catalyzedconversion of angiotensinogen to ANG I in the current model. Therefore,the observed natriuresis in hypertonic saline was likely the resultof a sustained increase in GFR and was independent of any hormonalcascade, which is a unique response among mammals. The moderatenatriuresis induced after isotonic saline was also independentof increased ANP or reduced ANGII.

The adrenal steroids, aldosterone and cortisol, are altered in response to PVE and elevated dietary Na⁺ intake in terrestrial mammals. Infusion of isotonic saline (10,39) and elevated dietary Na⁺ intake (9, 12, 13, 20) reduce circulating aldosterone,with the decrease occurring within 30 and 180 min in some cases(9, 10, 39). Plasma and excreted cortisol remained unaffectedafter the infusion of isotonic saline (10), whereas plasma cortisoldecreased after increased dietary Na⁺ intake (13). In both isotonic saline and hypertonic saline,plasma aldosterone was not reduced until 24 h postinfusion, indicatingthe latency in the adrenal-glomerulosa response to PVE and hypernatremiain fasting pups. However, plasma cortisol decreased immediatelyafter isotonic saline-induced PVE and increased immediately afterhyperosmolality, indicating an increased responsiveness of theadrenal fasciculata. Regions of the adrenal gland responded differentiallyto PVE and hyperosmolality in the present study, suggesting independentmechanisms of regulation in response to alterations in plasmavolume and osmolality in fastingpups.

Ironically, hypertonic saline resulted in an increase in excreted aldosterone adjusted for excreted creatinine, suggestingan increase in adrenal secretion. The sustained increase in plasmacortisol and the significant and positive correlation betweenthe means of excreted aldosterone and excreted cortisol suggestthat the infusion of hypertonic saline may have induced a neuroendocrinestress response (1), which may have masked any signal to inhibitaldosterone secretion. If excessive Na⁺ intake can be interpreted as an environmental stressor to theseanimals, then it is highly unlikely that these marine mammalsvoluntarily drink sea water, and large amounts of incidentallyingested salts would be effectively and efficiently excreted inshort order, as discussed previously. Therefore, hypernatremiaresulting from the infusion of hypertonic saline may have induceda stress response, which may have played a pivotal role in potentiatingthe subsequent natriuresis via an increase in blood pressure andthus GFR (4).

In humans and rats, AVP stimulates urea transporters (UTs) to enhance urea resorption into the renal medulla and thus decreasesFE_urea (3, 17). Glucocorticoids have been shown to downregulatevasopressin-regulated UTs, resulting in an increase in FE_urea(17). In aldosterone-induced volume-expanded rats fed a high-saltdiet, urea excretion increased associated with a decrease in UT-A1and UT-A3, suggesting a possible correlation between hypernatremiaand urea excretion (49). For 3-6 h after the infusion of hypertonicsaline, FE_urea was elevated in the presence of increased excretedAVP and cortisol, suggesting that cortisol may have inhibitedurea resorption and thus increased FE_urea. However, after isotonicsaline, FE_urea was not significantly altered, and neither wasexcreted AVP nor cortisol altered. The potential interactionsbetween AVP and adrenal steroids in renal urea handling in marinemammals warrants furtherinvestigation.

In summary, the renal responses to PVE and hyperosmolality in fasting NES pups appear to be different from those typicallyassociated with such stimuli in humans and other terrestrial mammals.Both PVE and hyperosmolality induced an osmotic diuresis and natriuresis.Under natural fasting conditions, the conservation of Na⁺ appears to be the result of a reduced GFR and an increase inRAAS (30). However, natriuresis in response to hyperosmolalitywas achieved by an immediate and sustained elevation in GFR andindependent of an increase in ANP and decreases in ANG II andaldosterone. Infusion of isotonic saline resulted in the retentionof water and electrolytes; however, excessive Na⁺ is excreted rapidly and efficiently without retention and atthe expense of a small amount of body water. The present studyprovides the most conclusive evidence that the secretion of AVPis regulated by both volume (pressure) and osmolality and thatAVP has an antidiuretic role in marine mammals, which has beena point of contention for decades (22, 29, 40). The variableresponses of adrenal steroids to both isotonic and hypertonicsaline infusions indicate that the adrenal gland in fasting NESpups, and possibly all marine mammals, possesses dynamic, osmoregulatoryfunctions, and suggest that the gland is differentially modulated,possibly by neural factors undefined by the present study. Elephantseal pups possess a refined kidney that is capable of exquisiteregulation of Na⁺ during conditions of both chronic conservation during the fastand acute excretion during excessive Na⁺intake.

Perspectives

Whether the origin of pinnipeds (seals and sea lions) is monophyletic or diphyletic remains debatable (5, 24). However,the belief that the original ancestor was a terrestrial, arctoidcarnivore (ursid or mustelid) is widely accepted (5, 35).Unfortunately, direct comparisons of renal responses to PVE andhyperosmolality cannot be made between elephant seals and bearsor mustelids, since such data do not exist for these terrestrialmammals. Therefore, let us assume that present-day dogs possessthe renal physiology representative of these ancestral carnivores;then it would appear that renal responses to hypernatremia havediverged over the past 15 million years (the approximate timein which the earliest phocid seals emerged in the fossil record;see Ref. 35), since the responses to excessive Na⁺ are quite different between dogs and elephant seal pups. Ancestralcarnivores probably possessed kidneys designed for exquisite conservationof Na⁺, since they inhabited an Na⁺-depleted environment. However, the transition to a marine environmentmost likely necessitated the evolution of a kidney capable ofextreme Na⁺ excretion. Thus the transition of terrestrial mammals to a marineenvironment may have been initially accompanied by drinking behavior;however, marine mammals adapted to their new habitat by evolvingan efficient and rapid mechanism by which excessive Na⁺ isexcreted.

	ACKNOWLEDGEMENTS

We thank A. Bigelow, A. Galarza, G. Guron, J. Lauzze, B. Litz, D. Noren, A. Ramirez, J. Ramirez, and T. Sierra for assistancethroughout the study. We thank G. Strachan and the Año Nuevorangers for allowing us access to the animals and for assistancein thefield.

	FOOTNOTES

This research was supported by National Institute of General Medical Sciences Grant GM-58903-01 (C. L. Ortiz), National Aeronauticsand Space Administration (NASA) grants 121-10-50 and 121-40-10(C. E. Wade), NASA Graduate Student Research Program NGT-2-52230(R. M. Ortiz), the California Space Grant Consortium, a Grant-in-Aidof Research from Sigma Xi, the American Museum of Natural History,Dr. Earl H. Myers and Ethel M. Myers Marine Biology Trust, andFriends of Long Marine Lab. Research was conducted under NationalMarine Fisheries Service marine mammal permit no. 836 to C. L.Ortiz and University of California Santa Cruz Chancellor's AnimalResearch Committee permit Orti89.08 to C. L. Ortiz and R. M.Ortiz.

This research was conducted in partial fulfillment of the requirements for the doctorate degree in biology for R. M.Ortiz.

Address for reprint requests and other correspondence: R. M. Ortiz: (E-mail: rortiz{at}mail.arc.nasa.gov).

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.Section 1734 solely to indicate thisfact.

10.1152/ajpregu.00418.2001

Received 18 July 2001; accepted in final form 13 November 2001.

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