Branchial Na,K-ATPase and osmoregulation in the purple shore crab,Hemigrapsus nudus (Dana)

The purple shore crab, Hemigrapsus nudus, controls its hemolymph osmolality over a wide range of external salinities: it is a strong hyperosmoregulator in 25%, 50% and 75% sea water (SW) and is isosmotic in 100% SW. The role of branchial sodium + potassium-activated, magnesium-requiring adenosine triphosphatase (NA, K-ATPase) in osmoregulation was investigated by assaying enzyme-specific activity (SEA) in gills from crabs acclimated for 14 d in the four sea water media. Assay conditions were characterized for optimal ESA with crude homogenates of gills; ion and cofactor requirements were found to be similar to those of other crustacean Na, K-ATPases. Branchial ESA was highest in crabs acclimated for 2 weeks in 50% SW and was significantly correlated with the osmotic gradient across the body wall in 50%, 75% and 100% SW. Gills 6, 7 and 8 had the highest ESA in all media and possessed approximately 70% of the total branchial Na, K-ATPase activity, but all gills showed significant, approximately twofold increases of ESA in 50% SW compared with values in 100% SW. The time courses of increased branchial Na, K-ATPase ESA and decreased hemolymph osmotic pressure in crabs transferred from 100% SW to 50% SW are consistent with both increased in vivo activity of existing enzyme in the short term and a longer-term synthesis of new enzyme by the gills which is measured by our in vitro assay.     

Prioritization or summation of events? Cardiovascular physiology of postprandial Dungeness crabs in low salinity

Decapod crustaceans commonly forage in estuarine environments. The osmoregulatory mechanisms that allow them to cope with periodic episodes of low salinity have been well documented. There is less information on how ventilatory and cardiovascular mechanisms aid survival in low salinity. Prior experiments have shown that most species exhibit a tachycardia coupled with an increase in ventilation rate and oxygen uptake. However, these previous experiments were conducted on animals that were starved before experimentation in order to avoid increases in metabolism associated with digestive processes. This study investigated how the Dungeness crab Cancer magister balances the demands of physiological systems during feeding and digestion in low salinity. Cardiac and ventilatory parameters increased during feeding. When the crabs were subjected to low salinity after feeding, heart rate increased in 25% seawater (SW) but decreased in 50% SW. Instead of an expected increase in ventilation rate during low-salinity exposure, there was a decrease. Feeding was associated with an increase in sternal artery flow, with subsequent decreases in flows through the sternal and anterolateral arteries in low salinity. When low salinity was administered first, a tachycardia occurred, coupled with decreased stroke volume and cardiac output. There was also an increase in ventilation rate. When crabs were fed in low salinity, heart rate decreased in 50% SW but was maintained in 25% SW. Ventilation rate decreased when crabs fed in 50% and 25% SW. Flow through the sternal artery and anterolateral arteries decreased in low salinity, and except for transient increases while feeding, there were further decreases during digestion. Cardiac and ventilatory parameters were rapidly regained when control conditions were restored. The results suggest that events during low salinity are prioritized. Nevertheless, these alterations in physiological parameters may not be beneficial; although digestive processes did not affect osmoregulatory ability, postprandial crabs did not survive as long as starved crabs in 25% SW. The results show that the digestive state of an animal is important in modulating its physiological responses to environmental perturbations, underscoring the importance of an integrative approach to studying physiological responses at the organismal level.     

Elver Invasion, Population Structure and Growth of Marbled eels Anguilla marmorata in a Tropical River on Réunion Island in the Indian Ocean

Winter skates, Leucoraja ocellata, exposed to 80% and 50% seawater (SW) exhibited rapid and significant weight gains followed by a slight recovery to new steady state levels within 8 days. Skates were acclimated at each salinity (100% SW [N = 16], 80% SW [N = 8], 50% SW [N = 8]), anesthetized (MS222) and bled from the caudal vein. In 100% SW, skate plasma (930mOsm/kg) was slightly hyperosmotic to the external medium (922mOsm/kg). Plasma osmolality decreased with seawater dilution, but became increasingly hyperosmotic to the bathing media. The environmental dilutions resulted in significant, but disproportionate changes in plasma Cl^–, P^–, Na⁺, Ca⁺, Mg⁺, trimethylamine oxide (TMAO) and urea concentrations. Mean corpuscular [Hb] and milliliter RBC water measurements suggest that skate red cells swelled less at each dilution than predicted for a passive erythrocyte osmometer. Concentrations of the major RBC solutes K⁺, urea, TMAO and Cl^– decreased by 8, 25, 5 and 21%, respectively in 80% SW. In 50% SW, K⁺, urea, TMAO and Cl^– concentrations decreased by 9, 47, 36 and 15%, respectively. Quantitatively, the other measured intracellular electrolytes (Mg⁺, Na⁺, P^– and Ca⁺) also exhibited disproportionate changes in concentration. Our results indicate that L. ocellata is a euryhaline elasmobranch that can tolerate significant reduction in the external salinity through the release of both ions and urea from the extracellular compartments while retaining electrolytes at the expense of urea in the intracellular compartment.     

Effects of environmental salinity and temperature on osmoregulatory ability, organic osmolytes, and plasma hormone profiles in the Mozambique tilapia (Oreochromis mossambicus)

The Mozambique tilapia, Oreochromis mossambicus, is capable of surviving a wide range of salinities and temperatures. The present study was undertaken to investigate the influence of environmental salinity and temperature on osmoregulatory ability, organic osmolytes and plasma hormone profiles in the tilapia. Fish were acclimated to fresh water (FW), seawater (SW) or double-strength seawater (200% SW) at 20, 28 or 35 degrees C for 7 days. Plasma osmolality increased significantly as environmental salinity and temperature increased. Marked increases in gill Na(+), K(+)-ATPase activity were observed at all temperatures in the fish acclimated to 200% SW. By contrast, Na(+), K(+)-ATPase activity was not affected by temperature at any salinity. Plasma glucose levels increased significantly with the increase in salinity and temperature. Significant correlations were observed between plasma glucose and osmolality. In brain and kidney, content of myo-inositol increased in parallel with plasma osmolality. In muscle and liver, there were similar increases in glycine and taurine, respectively. Glucose content in liver decreased significantly in the fish in 200% SW. Plasma prolactin levels decreased significantly after acclimation to SW or 200% SW. Plasma levels of cortisol and growth hormone were highly variable, and no consistent effect of salinity or temperature was observed. Although there was no significant difference among fish acclimated to different salinity at 20 degrees C, plasma IGF-I levels at 28 degrees C increased significantly with the increase in salinity. Highest levels of IGF-I were observed in SW fish at 35 degrees C. These results indicate that alterations in gill Na(+), K(+)-ATPase activity and glucose metabolism, the accumulation of organic osmolytes in some organs as well as plasma profiles of osmoregulatory hormones are sensitive to salinity and temperature acclimation in tilapia.     

Plasma and erythrocyte solute properties of juvenile bull sharks, Carcharhinus leucas, acutely exposed to increasing environmental salinity

Plasma and erythrocyte solute properties were examined in freshwater (FW) acclimated juvenile Carcharhinus leucas following acute transfer to 75% seawater (SW), and 100% SW. Blood samples were taken at 0, 12 and 96 h following transfer to 75% SW and 24 and 72 h after transfer to 100% SW. A control group in FW was subjected to the same sampling regime. Upon transfer of C. leucas to 75% and 100% SW, plasma Na⁺, Cl⁻, K⁺, Mg²⁺, Ca²⁺, urea and TMAO concentrations all increased significantly but disproportionately. Plasma Na⁺ and Cl⁻ increased immediately, followed by an increase in plasma urea. Erythrocyte urea and TMAO concentrations increased significantly following transfer to 75% and 100% SW; however, changes in erythrocyte inorganic ion concentrations were insignificant. Haematocrit, haemoglobin and mean cell haematocrit did not differ significantly after transfer to seawater; however, plasma water was slightly reduced after 24 and 72 h in 100% SW. Red blood cell (RBC) water content was elevated 24 h after transfer to 100% SW but returned to FW levels after 72 h. These results demonstrate that the transfer from 75% to 100% SW presents C. leucas with a greater osmoregulatory challenge than transfer from FW to 75% SW, despite the larger concentration gradient in the latter. In summary, C. leucas tolerate rapid and significant increases in salinity by rapidly increasing plasma osmolality to be hyperosmotic to the environment whilst maintaining a tight regulation of their intracellular fluid environment.     

Hypoosmotic volume regulation in the sea anemone metridium senile

1. The anemone Metridium senile survives salinities from seawater (950 mOsm) to 55% SW (520 mOsm) for at least two weeks. Animals exposed to 40% SW (380 mOsm) die within three days.2. The tissue amino acid content of M. senile acclimated to 950 mOsm, 807 mOsm, 665 mOsm and 520 mOsm for two weeks is respectively, 444, 382, 331 and 251 μmol/g dry wt. A decrease in the concentration of taurine accounts for nearly all of the decrease in the free amino acid pool.3. Tissue hydration increases in M. senile acclimated to dilute seawater, but the increase was not proportional to the change in ambient salinity, indicating that the anemones partially regulate volume in dilute media.4. Mathematical analyses of changes in tissue hydration as a function of ambient salinity in M. senile, Haliplanella lineata, and Diadumene leucolena suggest that the effectiveness of volume regulation increases in individuals of these species acclimated to progressively more dilute media. The volume regulatory capability of Bunodosoma cavernata does not change in dilute media.     

TEP on the tide in killifish (<Emphasis Type="Italic">Fundulus heteroclitus</Emphasis>): effects of progressively changing salinity and prior acclimation to intermediate or cycling salinity

Transepithelial potentials (TEP) were measured in killifish, acclimated to freshwater (FW), seawater (SW), 33% SW or cycling salinities relevant to tidal cycles in an estuary, and subsequently subjected to salinity changes in progressive or random order. Random compared to progressive salinity changes in an upward or downward direction in FW- and SW-acclimated fish, respectively, did not greatly influence responses to salinity change. Fish acclimated to SW or 33% SW as well as those acclimated to cycling salinities behaved similarly (TEP more positive than +15 mV in 100% SW, decreasing to ~0 mV at 20–40% SW, and more negative than −30 mV in FW). In contrast, FW-acclimated fish displayed a less pronounced TEP response to salinity (0 mV in FW through 20% SW, increasing thereafter to values more positive than +10 mV at 100% SW). We conclude that when evaluated under estuarine tidal conditions, the killifish gill exhibits adaptive electrical characteristics, opposing Na⁺ loss at low salinity and favouring Na⁺ extrusion at high salinity, changes explained at least in part by the Cl⁻ to Na⁺ permeability ratio. Thus animals living in the estuaries can move to lower and higher salinities for short periods with little physiological disturbance, but this ability is lost after acclimation to FW.     

Diatom Cell Size,Coloniality and Motility: Trade-Offs between Temperature,Salinity and Nutrient Supply with Climate Change

Reduction in body size has been proposed as a universal response of organisms, both to warming and to decreased salinity. However, it is still controversial if size reduction is caused by temperature or salinity on their own, or if other factors interfere as well. We used natural benthic diatom communities to explore how “body size” (cells and colonies) and motility change along temperature (2–26°C) and salinity (0.5–7.8) gradients in the brackish Baltic Sea. Fourth-corner analysis confirmed that small cell and colony sizes were associated with high temperature in summer. Average community cell volume decreased linearly with 2.2% per °C. However, cells were larger with artificial warming when nutrient concentrations were high in the cold season. Average community cell volume increased by 5.2% per °C of artificial warming from 0 to 8.5°C and simultaneously there was a selection for motility, which probably helped to optimize growth rates by trade-offs between nutrient supply and irradiation. Along the Baltic Sea salinity gradient cell size decreased with decreasing salinity, apparently mediated by nutrient stoichiometry. Altogether, our results suggest that climate change in this century may polarize seasonality by creating two new niches, with elevated temperature at high nutrient concentrations in the cold season (increasing cell size) and elevated temperature at low nutrient concentrations in the warm season (decreasing cell size). Higher temperature in summer and lower salinity by increased land-runoff are expected to decrease the average cell size of primary producers, which is likely to affect the transfer of energy to higher trophic levels.     

QUANTIFICATION OF THE PHYSIOLOGICAL RESPONSES OF THE EUROPEAN FLAT OYSTER OSTREA EDULIS L. TO TEMPERATURE AND SALINITY

Physiological stress was quantified in specimens of the Europeanflat oyster Ostrea edulis, acclimated to a matrix of temperature(5–25°C) and salinity (16–34%o) conditions,using the Scope for Growth (SFG) index. Variations in the indexwere interpreted from the responses of its components, absorptionefficiency, filtration rate, respiration and ammonia excretionrates, to external conditions. Mean SFG values were most influencedby acclimation temperature but significant differences werefound between animals at different salinities over the rangetested. There was a severe reduction in SFG when high temperaturewas combined with reduced salinity (     

Differential design for hopping in two species of wallabies

We explored molecular and morphological alteration in gill mitochondria-rich (MR) cells of Mozambique tilapia, Oreochromis mossambicus, acclimated to deionized freshwater (DFW), freshwater (FW), 1/3-diluted seawater (1/3 SW) and seawater (SW). Scanning electron microscopic observations revealed that the apical membrane of MR cells appeared as a flat or slightly projecting disk in DFW and FW, being larger in DFW than in FW. In contrast, the apical membrane typically formed a pit structure in 1/3 SW and SW. The mRNA expression levels of Na(+)/H(+) exchanger-3 (NHE3) and Na(+)/Cl(-) cotransporter (NCC) in the gills were increased with decreasing environmental salinity, whereas Na(+)/K(+)/2Cl(-) cotransporter-1a (NKCC1a) expression was upregulated by increasing salinity. Immunofluorescence staining showed that the MR cell population of DFW- and FW-acclimated tilapia consisted mostly of MR cells with apical NHE3 and those with apical-NCC; MR cells with basolateral NKCC1a dominated in SW-acclimated tilapia. These results indicated that apical-NHE3 and apical-NCC MR cells were ion-absorbing cells, and that basolateral-NKCC1a MR cells were ion-secreting cells. In fish acclimated to 1/3 SW, both ion-absorbing and secreting cells existed in the gills, suggesting that fish in near-isotonic water were equipped with mechanisms of both hyper- and hypoosmoregulation to prepare for environmental salinity changes.     

Exchange diffusion effect and euryhalinity in teleosts

The sea water (SW)-adapted euryhaline Platichthys flesus, and the marine Serranus exchange about 50% of their internal sodium with the external sodium per hour. This rate of exchange decreases with decreasing salinity of the adaptation medium. When the flounder is transferred from SW to FW an instantaneous 90% reduction of the Na and Cl outflux is observed. About 30 min later a second, progressive, reduction occurs. The outflux reductions appear to result from two types of regulatory mechanisms reducing gill permeability and preventing excessive salt loss. The first reduction corresponds to independent "Na- and Cl-free effects" as shown by transfers to artificial media containing either Na or Cl with an impermeant co-ion. The pattern of simultaneous rapid variations of Na influx and outflux for a range of salinity changes in flounder adapted to SW, 1/2 SW, or 1/4 SW has been studied. The data are compatible with the hypothesis of an exchange diffusion mechanism characterized by a coupling of both unidirectional fluxes. The affinity of the exchange diffusion carrier for sodium has been measured (Km approximately equal to 400 mM). The delayed reduction would result from a progressive diminution of the quantity of carrier available but without modification of its affinity for sodium. When the stenohaline marine perch is transferred from SW to FW, a 40% reduction of the outflux is observed. But it is not the result of an exchange diffusion effect as it is related to the external osmolarity change and not to the NaCl concentration change. Furthermore no delayed reduction is observed after transfer into FW. This transfer is accompanied by a heavy loss of electrolytes resulting in a rapid decline of the plasma electrolyte level and death. A comparative survey of the relative importance of these regulatory mechanisms has been made.     

Acclimation of S aurata to various salinities alters energy metabolism of osmoregulatory and nonosmoregulatory organs

The impact of different environmental salinities on the energy metabolism of gills, kidney, liver, and brain was assessed in gilthead sea bream (Sparus aurata) acclimated to brackish water [BW, 12 parts/thousand (ppt)], seawater (SW, 38 ppt) and hyper saline water (HSW, 55 ppt) for 14 days. Plasma osmolality and levels of sodium and chloride presented a clear direct relationship with environmental salinities. A general activation of energy metabolism was observed under different osmotic conditions. In liver, an enhancement of glycogenolytic and glycolytic potential was observed in fish acclimated to BW and HSW compared with those in SW. In plasma, an increased availability of glucose, lactate, and protein was observed in parallel with the increase in salinity. In gills, an increased Na+-K+-ATPase activity, a clear decrease in the capacity for use of exogenous glucose and the pentose phosphate pathway, as well as an increased glycolytic potential were observed in parallel with the increased salinity. In kidney, Na+-K+-ATPase activity and lactate levels increased in HSW, whereas the capacity for the use of exogenous glucose decreased in BW- and HSW- acclimated fish compared with SW-acclimated fish. In brain, fish acclimated to BW or HSW displayed an enhancement in their potential for glycogenolysis, use of exogenous glucose, and glycolysis compared with SW-acclimated fish. Also in brain, lactate and ATP levels decreased in parallel with the increase in salinity. The data are discussed in the context of energy expenditure associated with osmotic acclimation to different environmental salinities in fish euryhaline species.     

Water temperature affects osmoregulatory responses in gilthead sea bream (Sparus aurata L.)

Sea bream (Sparus aurata Linneaus) was acclimated to three salinity concentrations, viz. 5 (LSW), 38 (SW) and 55psμ (HSW) and three water temperatures regimes (12, 19 and 26 °C) for five weeks. Osmoregulatory capacity parameters (plasma osmolality, sodium, chloride, cortisol, and branchial and renal Na⁺,K⁺-ATPase activities) were also assessed. Salinity and temperature affected all of the parameters tested. Our results indicate that environmental temperature modulates capacity in sea bream, independent of environmental salinity, and set points of plasma osmolality and ion concentrations depend on both ambient salinity and temperature. Acclimation to extreme salinity resulted in stress, indicated by elevated basal plasma cortisol levels. Response to salinity was affected by ambient temperature. A comparison between branchial and renal Na⁺,K⁺-ATPase activities appears instrumental in explaining salinity and temperature responses. Sea bream regulate branchial enzyme copy numbers (V_max) in hyperosmotic media (SW and HSW) to deal with ambient temperature effects on activity; combinations of high temperatures and salinity may exceed the adaptive capacity of sea bream. Salinity compromises the branchial enzyme capacity (compared to basal activity at a set salinity) when temperature is elevated and the scope for temperature adaptation becomes smaller at increasing salinity. Renal Na⁺,K⁺-ATPase capacity appears fixed and activity appears to be determined by temperature.     

The effects of acclimation on the salinity tolerance of grass carp, Ctenopharyngodon idella (Cuv. and Val.)

Grass carp acclimated to 3, 5, 7, and 9% salinities were tested for salinity tolerance. The upper tolerance limit (LS₅₀) for 3 and 5%, and 7% acclimated fish were 14.2 and 14.0%, respectively. Fish acclimated to 9% had a 50% mortality at an estimated salinity of 16.0%, for 24 h exposure. Weight losses for the 3 and 5% acclimated fish were significantly lower than for those acclimated to 9%.     

Changes to chloride and rodlet cells in gills, kidney and intestine of Dicentrarchus labrax (L.) exposed to reduced salinities

The effect of osmotic shock was investigated mainly in the chloride cells (CCs) and rodlet cells (RCs) of gills, and RCs of intestine and kidney of the European sea bass Dicentrarchus labrax obtained from a farm in the northern Adriatic Sea. During the experiment, fish were abruptly transferred from sea water to a salinity of 15 (15 SW) or to fresh water (FW). Numeric variation and ultrastructural changes of both cell types were evaluated at 24, 48 and 96 h after the transfer to lower salinity levels, using light and transmission electron microscopy (TEM). Exposure to FW produced a significant increase ( P < 0·05) in the number of branchial CCs and RCs within 96 and 24 h, respectively. Following osmotic challenge (either transfer to 15 SW or FW), kidney and intestine showed an evident increase in RC numbers. The cellular damage detected by TEM was the same for each sampling time (24, 48 and 96 h), but appeared more severe in fish exposed to FW (higher osmotic shock) than in those exposed to 15 SW. In RCs cytoplasmic vacuolizations, autophagosomes and autophagolysosomes with myelinoid bodies, dissolution and shrinkage of the typical inclusions were documented. Nevertheless, CCs showed vacuolization of endoplasmic reticulum and cytoplasmic dissolution and maintained the apical crypt typical of seawater acclimated fish. Renal tubular cells and intestinal epithelial cells showed similar changes to those reported for CCs and RCs.     

Effects of salinity on solute clearance from the freshwater bivalve, Dreissena polymorpha Pallas

Clearance of polyethylene glycol (PEG), inulin, or dextran that had been injected into the hemolymph of the mussel, Dreissena polymorpha, was measured in animals acclimated to pondwater (PW) or 10% seawater (SW). In addition, we measured the clearance of PEG from mussels acutely transferred into 10% SW and following return to PW after acclimation to 10% SW. Clearance values calculated for PW-acclimated mussels ranged from 2.0 to 3.3 ml (g dry tissue ċ h)^-1 and declined to 0.28 ml (g dry tissue ċ h)^-1 in 10% SW-acclimated animals. Transferring mussels into 10% SW resulted in a reduction in PEG clearance from the blood, coincident with the reduction of osmotic gradient. When 10% SW-acclimated mussels were returned to PW the clearance of PEG increased to rates observed in PW-acclimated animals within 1 h. The PEG clearance remained constant during the re-acclimation to PW even though the osmotic gradient declined from about 100 to 30 mosmol kg^-1. Clearance of the solutes used in this study was likely to be a measurement of renal filtration rate. The clearance values appeared to be maximal when the animals were in PW. The limited capacity to increase clearance in the face of an osmotic challenge may be a critical factor in restricting D. polymorpha to freshwater or lower salinity environments with small ranges in salinity.     

Effects of temperature,salinity and aerial exposure on predation and lysosomal stability of the dogwhelk Thais (Nucella) lapillus (L.)

The ingestion and absorption rate of standard length Thais lapillus (L.) stepwise-acclimated to constant temperature-salinity conditions and preying on Mytilus edulis (L.) varied directly with environmental salinity at 10, 15 and 20°C. Dogwhelk ingestion and absorption rates indicate that cold torpor existed at 5°C and heat stress was evident at 20°C. The feeding cycle duration was significantly longer for dogwhelks acclimated to 20%. S than in those acclimated to 30%. S at 10°C even though no significant difference existed between the two groups of snails in the drilling and ingestion or postfeeding phases of the cycle. Ingestive conditioning of dogwhelks to mussels occurred; the duration of the drilling and ingestion and total feeding cycle declined as a function of the number of mussels consumed by a snail. Dogwhelks of all sizes prey on a wide length range of mussels and there is also a high degree of variability in the ingestion rate of snails as a function of their size. A prominent feature of the lack of a relationship between dogwhelk ingestion rate and snail size was that the percentage of nonfeeding snails increased at low salinity and temperature extremes. Digestive-tubule cell lysosomal stability was tested as an index of digestive capability and animal condition; in stepwise-acclimated dogwhelks, it correlated well with their ingestion and absorption rates. The ingestion rate of dogwhelks acclimated to 30%. S and subjected to a 30?17.5?30%. S semidiurnal pattern of fluctuating salinity for 21 days was significantly lower than for snails maintained at 30%. S; however, snails acclimated to 17.5%. S and exposed to the same pattern of fluctuating salinity fed at a higher rate than snails maintained at 17.5%. S. Aerial exposure of snails maintained at 30%. S and 10°C water temperature resulted in an ingestion rate 2.1 times faster than for snails constantly submerged suggesting that tidal emersion is not always stressful to intertidal carnivores. The postfeeding phase of the feeding cycle was shortened in dogwhelks subjected to aerial exposure. Although significant variation occurred in digestive-tubule cell lysosomal stability during the first cycle of fluctuating salinity, the variability had declined significantly by Day 21. This observation suggests that digestive tubule lysosomal stability becomes adapted to a fluctuating osmotic environment, although the initial changes in lysosomal stability are probably related to intralysosomal protein catabolism and production of amino acids for intracellular osmoregulation. Variations in the osmotic environment of T. lapillus have resulted in unexpected outcomes with respect to their ingestion rate under conditions of fluctuating salinity and aerial exposure.     

Effect of blood withdrawal and angiotensin II on prolactin release in the tilapia,Oreochromis mossambicus

Repeated blood withdrawal (5% of estimated blood volume at 0, 1, 4, 8, 24, 48 and 76 h) from tilapia acclimated to fresh water (FW) resulted in a marked increase in plasma levels of prolactin (PRL) during the first 8 h, reaching a peak above 300 ng/ml after 4 h. The increase in plasma PRL levels was significant except for the level after 72 h. A slight but significant decrease in plasma osmolality was observed at all time points after the blood withdrawal. Repeated blood withdrawal from fish acclimated to seawater (SW) resulted in a marked increase in plasma osmolality after 4 and 8 h. A significant increase was observed in plasma growth hormone (GH) in the fish in SW until the end of the experiment, but there was no change in plasma PRL. Plasma levels of cortisol were significantly higher in the fish in SW than in those in FW during the first 24 h. Blood withdrawal resulted in a significant reduction in hematocrit values in both FW- and SW-adapted fish, suggesting hemodilution. In a separate experiment, a single blood withdrawal (20% of total blood) stimulated drinking after 5 h, regardless of whether the fish were held in FW or SW. Plasma PRL level was also elevated following a single blood withdrawal in the fish acclimated to FW, but not in the fish in SW. Intraperitoneal injection of ANG II (1.0 microg/g) into the fish in FW significantly increased plasma PRL levels after 1 h. Activation of the renin-angiotensin system after blood withdrawal and the dipsogenic action of angiotensin II (ANG II) are well established in fish. The reduction in plasma osmolality after repeated blood withdrawal in FW and the increased osmolality in SW suggest that blood volume is restored, at least in part, by drinking environmental water. These results suggest that the marked increase in PRL concentration after blood withdrawal from the fish in FW is due, at least in part, to a facilitative effect between ANG II and reduced plasma osmolality.     

Contribution of Na/Na and Cl/Cl exchanges to sodium and chloride fluxes in the crabGoniopsis cruentata

Summary Sodium or chloride efflux and transepithelial potentials (TEP) were measured in crabs exposed to seawater concentrations ranging from 150 to 25% SW. In crabs acclimated to 150% SW the Na⁺ efflux (3.8 mmol/h·100 g) was significantly higher than the Cl^– efflux (2.1 mmol/h·100 g), but both fluxes decreased to about 0.6 mmol/h·100 g in crabs from 50 or 25% SW. The TEP varied linearly from –1 mV (blood negative) in 150% SW, to –11 mV in 25% SW. In 150 and 100% SW the calculated components of the ion fluxes (i.e., diffusive, urinary, active uptake or extrusion) added up to less than one-half of the isotopically measured values. In 50 and 25% SW the measured effluxes were fully accounted for by their calculated components. In crabs transferred from 150% SW to low-Na 150% SW (=TRIS ASW), the Na⁺ efflux decreased abruptly, from 3.7 to 0.6 mmol/h; the Cl^– efflux decreased much less, from 1.9 to 1.5 mmol/h. A large fraction of the Na⁺ (or Cl^–) fluxes in crabs from concentrated SW meets the criteria for exchange diffusion, which decreases or disappears as the external concentration of each ion is lowered. This suggests that changes of the permeability to ions, in response to alterations of environmental salinity, may not constitute an important adaptive strategy in this species.Abbreviations SW seawater - TEP transepithelial potential - TRIS ASW artificial seawater 150%     

Osmotic and ionic haemolymph concentrations in the Baltic Sea amphipod Gammarus oceanicus in relation to water salinity

The aim of this work was to determine the osmotic and ionic (Na(+), K(+), Ca(2+), Mg(2+) and Cl(-)) haemolymph concentrations in Gammarus oceanicus at different salinity levels. Being a species of marine origin it inhabits brackish waters of the Baltic Sea. G. oceanicus specimens were collected in January 2003 from the Gulf of Gdansk (salinity 7 psu). The animals were gradually acclimated to eight different salinity levels (5, 7, 14, 20, 25, 30, 35 and 41 psu) at a temperature of 5 degrees C and 100% oxygen saturation. The haemolymph osmolalities correlated positively with external salinity, from 545.4+/-17.3 mOsm in 5 psu to 1185.9+/-34.6 mOsm in 41 psu. G. oceanicus hyperregulated within the 5-31.5 psu range; above 31.5 psu it hyporegulated its body fluids in comparison to the external medium. At 31.5 psu (1017 mOsm) the haemolymph concentration of G. oceanicus was isoosmotic with the habitat. The haemolymph concentrations of all the studied ions, except K(+), correlated positively with their concentrations at the various salinity.