Is urea pulsing in toadfish related to environmental O2 or CO2 levels?

The neurochemical, serotonin (5-hydroxytryptamine; 5-HT) is involved in the regulation of toadfish pulsatile urea excretion as well as the teleost hypoxia response. Thus, the goal of this study was to determine whether environmental conditions that activate branchial chemoreceptors also trigger pulsatile urea excretion in toadfish, since environmental dissolved oxygen levels in a typical toadfish habitat show significant diel fluctuations, often reaching hypoxic conditions at dawn. Toadfish were fitted with arterial, venous and/or buccal catheters and were exposed to various environmental conditions, and/or injected with the O(2) chemoreceptor agonist NaCN or the 5-HT(2) receptor agonist alpha-methyl-5HT. Arterial PO(2), as well as ammonia and urea excretion were monitored. Natural fluctuations in arterial PO(2) levels in toadfish did not correlate with the occurrence of a urea pulse. Chronic exposure (24 h) of toadfish to hyperoxia was without effect on nitrogen excretion, however, exposure to hypoxia caused a significant reduction in the frequency of urea pulses, and exposure to hypercapnia resulted in a reduction in the percentage of nitrogen waste excreted as urea. Of toadfish exposed acutely to hypoxia, 20% pulsed within 1 h, whereas none pulsed after normoxic or hypercapnic treatments. Furthermore, 20% of fish injected intravenously with NaCN pulsed within 1 h of injection, but no fish pulsed after injection of NaCN into the buccal cavity. To test whether environmental conditions affected 5-HT(2) receptors, toadfish were injected with alpha-methyl-5HT, which elicits urea pulses in toadfish. No significant differences in pulse size occurred among the various environmental treatments. Our findings suggest that neither the environmental conditions of hypoxia, hyperoxia or hypercapnia, nor direct branchial chemoreceptor activation by NaCN play a major role in the regulation of pulsatile urea excretion in toadfish.     

Acoustic characteristics and variations in grunt vocalizations in the oyster toadfish <Emphasis Type="Italic">Opsanus tau</Emphasis>

Acoustic communication is critical for reproductive success in the oyster toadfish Opsanus tau. While previous studies have examined the acoustic characteristics, behavioral context, geographical variation, and seasonality of advertisement boatwhistle sound production, there is limited information on the grunt or other non-advertisement vocalizations in this species. This study continuously monitored sound production in toadfish maintained in an outdoor habitat for four months to identify and characterize grunt vocalizations, compare them with boatwhistles, and test for relationships between the incidence of grunt vocalizations, sound characteristics and environmental parameters. Oyster toadfish produced grunts in response to handling, and spontaneous single (70% of all grunts), doublet (10%), and trains of grunts (20%) throughout the May to September study period. Grunt types varied in pulse structure, duration, and frequency components, and were shorter and of lower fundamental frequency than the pulse repetition rate of boatwhistles. Higher water temperatures were correlated with a greater number of grunt emissions, higher fundamental frequencies, and shorter sound durations. The number of grunts per day was also positively correlated with daylength and maximum tidal amplitude differences (previously entrained) associated with full and new moons, thus providing the first demonstration of semilunar vocalization rhythms in the oyster toadfish. These data provide new information on the acoustic repertoire and the environmental factors correlated with sound production in the toadfish, and have important implications for seasonal acoustic communication in this model vocal fish.     

Excretion of ammonia and urea during development in the oyster toadfish,Opsanus tau

The oyster toadfish is one of several teleosts that has been found to produce and excrete large amounts of nitrogenous waste as urea. To clarify the role of urea in the oyster toadfish, urea and ammonia excretion rates were examined in developing fish. Ammonia and urea excretion rates were measured for groups of developing toadfish for three days a week over eight weeks of development. A distinct and significant increase in the excretion rate of urea occurred between the first three weeks (mean = 0.38 mg N/kg‐h) and the fourth through sixth and eighth week of development (mean = 4.68 mg N/kg‐h). This increase of urea excretion occurs at the time of hatching and may be important during development. Preliminary analysis (temperature, pH and salinity) was conducted on water at one toadfish nesting site to provide insight into conditions to which toadfish are exposed.     

Natriuretic peptides and the acclimation of aglomerular toadfish to hypo-osmotic media

Since the aglomerular toadfish (Opsanus tau) experiences a natriuresis following transfer to 10% seawater, we examined the role of natriuretic peptides in the acclimation of toadfish to hypo-osmotic media. Gel filtration chromatography of acid extracts of toadfish heart and kidney identified a broad peak of atrial natriuretic peptide-like immunoreactivity in both tissues, with maximal immunoreactivity in fractions coeluting with human α-atrial natriuretic peptide. Using a homologous bioassay to measure changes in aortic ring tension, both vasorelaxing and, surprisingly, vasoconstricting bioactivities were identified in gel fractions of heart extract. No significant vasorelaxing activity was identified in kidney extract or fractions. Instead, a potent vasoconstricting activity was observed, with maximal activity in gel fractions with an estimated MW greater than 1000 Da. Levels of atrial natriuretic peptide immunoreactivity in plasma from the caudal vein were very low in seawater toadfish and were unchanged 12 h after transfer of toadfish to 10% seawater. We conclude, that natriuretic peptides are present in the heart and kidney of toadfish. However, atrial natriuretic peptide-like peptides of cardiac origin circulating to the kidney via the caudal vein do not appear responsible for the natriuresis that ensues upon the transfer of toadfish to 10% seawater. In the absence of glomeruli, this tubular natriuresis may be regulated by natriuretic peptides present in the kidney. Accepted: 9 July 1999     

Social hierarchy,shelter use,and avoidance of predatory toadfish (Opsanus tau) by the striped blenny (Chasmodes bosquianus)

This paper describes a three-part examination of the predatory relationship between oyster toadfish (Opsanus tau) and striped blennies (Chasmodes bosquianus). In the first laboratory study, blennies avoided the toadfish when placed in a choice situation. During the second laboratory study, dominant blennies escaped attack significantly more than did subordinates by using a protective shelter. A field study demonstrated that toadfish will attack active but tethered blennies under natural conditions. As predators, toadfish appear to use a mixed strategy. During the day, when they are relatively inactive, they may feed as ambush predators. However, we suggest that at night they move about actively, stalking benthic invertebrates and small fishes. They also feed as scavengers, consuming a variety of foods.     

Field studies on the ureogenic gulf toadfish, in a subtropical bay. II. Nitrogen excretion physiology

In order to examine the in situ nitrogen excretion physiology of gulf toadfish ( Opsanus beta ) (Fam. Batrachoididae), several biochemical and physiological measurements relating to urea synthesis and excretion were measured in samples taken from freshly collected gulf toadfish from a subtidal population in Biscayne Bay, Florida, U.S.A. This indirect appoach was used, instead of direct measurements of nitrogen excretion, because nitrogen excretion patterns of gulf toadfish are altered markedly during the first 24 h of capture disturbance or laboratory confinement. The values obtained for plasma cortisol levels, and the activities of hepatic ornithine-urea cycle enzymes, including glutamine synthetase (and its partitioning between cytosolic and mitochondrial compartments), suggest that gulf toadfish in Biscayne Bay may excrete a substantial portion of their waste nitrogen as urea. Also conducted were correlation analyses of several biotic variables (plasma [cortisol], enzyme activities, plasma [urea], hepatosomatic index, and plasma [Ca⁺⁺]) with several abiotic variables (temperature, salinity, depth and dissolved oxygen), and with collection site and season. Results of these analyses are discussed in the context of hypotheses to explain ureotely in this teleost fish.     

Hemoglobin polymorphism in fishes. I. Complex phenotypic patterns in the toadfish,Opsanus tau

Hemolysates of erythrocytes from toadfish (Opsanus tau) are complex mixtures containing 13–18 individual hemoglobin components. Polyacrylamide gel electrophoresis shows that hemoglobin is rather evenly distributed among the bands. Seldom does a single component amount to more than 20% of the total hemolysate. An unusually high degree of polymorphism exists in populations of the toadfish. Six major phenotypes occur commonly at Beaufort, North Carolina, and four of the six phenotypes were present in a sample of 11 toadfish from Gloucester Point, Virginia. Six minor phenotypes occur but have not been studied extensively. The genetic explanation of this hemoglobin polymorphism remains obscure.     

A comparative analysis of parvalbumin expression in pinfish (Lagodon rhomboides) and toadfish (Opsanus sp.)

This study examines the role of a myoplasmic protein, parvalbumin, in enhancing muscle relaxation by fishes. Parvalbumin is thought to bind free Ca²⁺ during muscle contraction, thereby reducing intracellular [Ca²⁺] in muscle and speeding muscle relaxation by reducing Ca²⁺ availability to the troponin complex. We hypothesized that parvalbumin expression is ubiquitously expressed in fish muscle and that its expression levels and role in muscle relaxation would depend on the activity level and the thermal environment of a given fish species. Muscle contractile properties and patterns of parvalbumin expression were examined in pinfish (Lagodon rhomboides) and two species of toadfish (gulf toadfish, Opsanus beta, and oyster toadfish, Opsanus tau). Unlike another sparid (sheepshead), the active swimming pinfish does not express parvalbumin in its slow-twitch red muscle. However, both sheepshead and pinfish have relatively high levels of parvalbumin in their myotomal white muscle. Gulf toadfish from the Gulf of Mexico expressed higher levels of parvalbumin and had faster muscle relaxation rates than oyster toadfish from more northern latitudes. The faster muscle of gulf toadfish also expressed relatively more of one parvalbumin isoform, suggesting differences in the binding properties of the two isoforms observed in toadfish swimming muscle. Parvalbumin expression and its role in muscle relaxation appear to vary widely in fishes. There are many control points involved in the calcium transient of contracting muscle, leading to a variety of species-specific solutions to the modulation of muscle relaxation.     

The effects of pretreatment with cytochrome P-450 inducers and preincubation with a cytochrome P-450 effector on the mutagenicity of genotoxic carcinogens mediated by hepatic and renal S9 from two species of marine fish

A series of experiments was designed to characterize the cytochrome P-450-dependent activation of 7 genotoxic carcinogens in the Salmonella preincubation assay by hepatic postmitochondrial fractions (S9) from the oyster toadfish and the Americal eel and by renal S9 from the toadfish. Significant S9-dependent mutagenicity was observed for benzo[a]pyrene (BAP), 2-aminoanthracene (2AA), aflatoxin B1 (AFB1), 7,12-dimethylbenz[a]anthracene (DMBA) and cyclophosphamide (CP) with hepatic S9 from untreated fish (UI S9) of both species and with renal S9 from untreated toadfish, although renal UI S9 was only marginally effective for activating AFB1. Neither UI S9 from toadfish liver or kidney nor that from eel liver consistently affected the direct mutagenicity of ethylene dibromide (EDB) or substantially activated dimethylnitrosamine (DMN). Pretreatment of toadfish with 3-methylcholanthrene (MC) decreased the mutagenicity of 2AA and increased the mutagenicities of BAP, AFB1 and DMBA, whereas, pretreatment of eels with MC increased the mutagenicities of BAP, 2AA and AFB1. Pretreatment of toadfish with Aroclor 1254 (AC) decreased the mutagenicity of AFB1 and increased the mutagenicity of 2AA, whereas, pretreatment of eels with AC increased the mutagenicities of BAP and DMBA. Pretreatment of toadfish with beta-napthoflavone (BNF) effected changes similar to those by pretreatment with MC except that the mutagenicity of AFB1 was not increased. Coincubation with 10(-4) M alpha-napthoflavone (ANF) decreased the mutagenicity of BAP mediated by toadfish MC and BNF S9 and eel AC S9 and decreased the mutagenicity of AFB1 mediated by toadfish MC and BNF S9 and by eel MC S9. Coincubation with ANF increased the mutagenicity of AFB1 mediated by toadfish and eel AC S9 and increased the mutagenicity of 2AA mediated by eel AC S9. Pretreatment of toadfish with MC, BNF and AC decreased the mutagenicity of 2AA mediated by renal S9 and ANF decreased the mutagenicity of 2AA mediated by renal UI and BNF S9. MC pretreatment of toadfish and eels and BNF pretreatment of toadfish induced BAP monooxygenase activity in hepatic microsomes. ANF (10(-4) M) inhibited the BAP monooxygenase activity of MC microsomes from toadfish and eels and of BNF microsomes from toadfish. The conjugation effectors diethyl maleate and salicylamide alone or combined had little or no effect on the mutagenicities of BAP and 2AA mediated by toadfish and eel UI and MC S9.(ABSTRACT TRUNCATED AT 400 WORDS)     

Oxidative stress in toadfish (Halobactrachus didactylus) cardiac muscle. Acute exposure to vanadate oligomers

Vanadate solutions as ‘metavanadate’ (containing ortho and metavanadate species) and ‘decavanadate’ (containing manly decameric species) (5 mM; 1 mg/kg) were injected intraperitoneously in Halobatrachus didactylus (toadfish), in order to evaluate the contribution of decameric vanadate species to vanadium (V) intoxication on the cardiac tissue. Following short-term exposure (1 and 7 days), different changes on antioxidant enzyme activities—superoxide dismutase (SOD), catalase (CAT), selenium-glutathione peroxidase (Se-GPx), total glutathione peroxidase (GPx), lipid peroxidation and subcellular vanadium distribution were observed in mitochondrial and cytosolic fractions of heart ventricle toadfish. After 1 day of vanadium intoxication, SOD, CAT and Se-GPx activities were decreased up to 25%, by both vanadate solutions, except mitochondrial CAT activity that increased (+23%) upon decavanadate administration. After 7 days of exposure, decavanadate versus metavanadate solutions promoted different effects mainly on cytosolic CAT activity (−56% versus −5%), mitochondrial CAT activity (−10% versus +10%) and total GPx activity (+1% versus −35%), whereas lipid peroxidation products were significantly increased (+82%) upon 500 μM decavanadate intoxication. Accumulation of vanadium in total (0.137±0.011 μg/g) and mitochondrial (0.022±0.001 μg/g) fractions was observed upon 7 days of metavanadate exposure, whereas for decavanadate, the concentration of vanadium increased in cytosolic (0.020±0.005 μg/g) and mitochondrial (0.021±0.009 μg/g) fractions. It is concluded that decameric vanadate species are responsible for a strong increase on lipid peroxidation and a decrease in cytosolic catalase activity thus contributing to oxidative stress responses upon vanadate intoxication, in the toadfish heart.     

Immunohistochemical localization of urea and ammonia transporters in two confamilial fish species, the ureotelic gulf toadfish (Opsanus beta) and the ammoniotelic plainfin midshipman (Porichthys notatus)

This study aims to illustrate potential transport mechanisms behind the divergent approaches to nitrogen excretion seen in the ureotelic toadfish (Opsanus beta) and the ammoniotelic plainfin midshipman (Porichthys notatus). Specifically, we wish to confirm the expression of a urea transporter (UT), which is found in the gill of the toadfish and which is responsible for the unique “pulsing” nature of urea excretion and to localize the transporter within specific gill cells and at specific cellular locations. Additionally, the localization of ammonia transporters (Rhesus glycoproteins; Rhs) within the gill of both the toadfish and midshipman was explored. Toadfish UT (tUT) was found within Na⁺-K⁺-ATPase (NKA)-enriched cells, i.e., ionocytes (probably mitochondria-rich cells), especially along the basolateral membrane and potentially on the apical membrane. In contrast, midshipman UT (pnUT) immunoreactivity did not colocalize with NKA immunoreactivity and was not found along the filaments but instead within the lamellae. The cellular location of Rh proteins was also dissimilar between the two fish species. In toadfish gills, the Rh isoform Rhcg1 was expressed in both NKA-reactive cells and non-reactive cells, whereas Rhbg and Rhcg2 were only expressed in the latter. In contrast, Rhbg, Rhcg1 and Rhcg2 were expressed in both NKA-reactive and non-reactive cells of midshipman gills. In an additional transport epithelium, namely the intestine, the expression of both UTs and Rhs was similar between the two species, with only subtle differences being observed.     

Oxidative stress in toadfish (Halobactrachus didactylus) cardiac muscle: Acute exposure to vanadate oligomers

Vanadate solutions as ‘metavanadate’ (containing ortho and metavanadate species) and ‘decavanadate’ (containing manly decameric species) (5 mM; 1 mg/kg) were injected intraperitoneously in Halobatrachus didactylus (toadfish), in order to evaluate the contribution of decameric vanadate species to vanadium (V) intoxication on the cardiac tissue. Following short-term exposure (1 and 7 days), different changes on antioxidant enzyme activities—superoxide dismutase (SOD), catalase (CAT), selenium-glutathione peroxidase (Se-GPx), total glutathione peroxidase (GPx), lipid peroxidation and subcellular vanadium distribution were observed in mitochondrial and cytosolic fractions of heart ventricle toadfish. After 1 day of vanadium intoxication, SOD, CAT and Se-GPx activities were decreased up to 25%, by both vanadate solutions, except mitochondrial CAT activity that increased (+23%) upon decavanadate administration. After 7 days of exposure, decavanadate versus metavanadate solutions promoted different effects mainly on cytosolic CAT activity (−56% versus −5%), mitochondrial CAT activity (−10% versus +10%) and total GPx activity (+1% versus −35%), whereas lipid peroxidation products were significantly increased (+82%) upon 500 μM decavanadate intoxication. Accumulation of vanadium in total (0.137±0.011 μg/g) and mitochondrial (0.022±0.001 μg/g) fractions was observed upon 7 days of metavanadate exposure, whereas for decavanadate, the concentration of vanadium increased in cytosolic (0.020±0.005 μg/g) and mitochondrial (0.021±0.009 μg/g) fractions. It is concluded that decameric vanadate species are responsible for a strong increase on lipid peroxidation and a decrease in cytosolic catalase activity thus contributing to oxidative stress responses upon vanadate intoxication, in the toadfish heart.     

Representation of complex vocalizations in the Lusitanian toadfish auditory system: evidence of fine temporal,frequency and amplitude discrimination

Many fishes rely on their auditory skills to interpret crucial information about predators and prey, and to communicate intraspecifically. Few studies, however, have examined how complex natural sounds are perceived in fishes. We investigated the representation of conspecific mating and agonistic calls in the auditory system of the Lusitanian toadfish Halobatrachus didactylus, and analysed auditory responses to heterospecific signals from ecologically relevant species: a sympatric vocal fish (meagre Argyrosomus regius) and a potential predator (dolphin Tursiops truncatus). Using auditory evoked potential (AEP) recordings, we showed that both sexes can resolve fine features of conspecific calls. The toadfish auditory system was most sensitive to frequencies well represented in the conspecific vocalizations (namely the mating boatwhistle), and revealed a fine representation of duration and pulsed structure of agonistic and mating calls. Stimuli and corresponding AEP amplitudes were highly correlated, indicating an accurate encoding of amplitude modulation. Moreover, Lusitanian toadfish were able to detect T. truncatus foraging sounds and A. regius calls, although at higher amplitudes. We provide strong evidence that the auditory system of a vocal fish, lacking accessory hearing structures, is capable of resolving fine features of complex vocalizations that are probably important for intraspecific communication and other relevant stimuli from the auditory scene.     

Transport physiology of the urinary bladder in teleosts: a suitable model for renal urea handling?

The transport physiology of the urinary bladder of both the freshwater rainbow trout (Oncorhychus mykiss) and the marine gulf toadfish (Opsanus beta) was characterized with respect to urea, and the suitability of the urinary bladder as a model for renal urea handling was investigated. Through the use of the in vitro urinary bladder sac preparation urea handling was characterized under control conditions and in the presence of pharmacological agents traditionally used to characterize urea transport such as urea analogues (thiourea, acetamide), urea transport blockers (phloretin, amiloride), and hormonal stimulation (arginine vasotocin; AVT). Na(+)-dependence and temperature sensitivity were also investigated. Under control conditions, the in vitro trout bladder behaved as in vivo, demonstrating significant net reabsorption of Na(+), Cl(-), water, glucose, and urea. Bladder urea reabsorption was not affected by pharmacological agents and, in contrast to renal urea reabsorption, was not correlated to Na(+). However, the trout bladder showed a threefold greater urea permeability compared to artificial lipid bilayers, a prolonged phase transition with a lowered E(a) between 5 degrees C and 14 degrees C, and differential handling of urea and analogues, all suggesting the presence of a urea transport mechanism. The in vitro toadfish bladder did not behave as in vivo, showing significant net reabsorption of Na(+) but not of Cl(-), urea, or water. As in the trout bladder, pharmacological agents were ineffective. The toadfish bladder showed no differential transport of urea and analogues, consistent with a low permeability storage organ and intermittent urination. Our results, therefore, suggest the possibility of a urea transport mechanism in the urinary bladder of the rainbow trout but not the gulf toadfish. While the bladders may not be suitable models for renal urea handling, the habit of intermittent urination by ureotelic tetrapods and toadfish seems to have selected for a low permeability storage function in the urinary bladder.     

Maintaining osmotic balance with an aglomerular kidney

The gulf toadfish, Opsanus beta, is a marine teleost fish with an aglomerular kidney that is highly specialized to conserve water. Despite this adaptation, toadfish have the ability to survive when in dilute hypoosmotic seawater environments. The objectives of this study were to determine the joint role of the kidney and intestine in maintaining osmotic and ionic balance and to investigate whether toadfish take advantage of their urea production ability and use urea as an osmolyte. Toadfish were gradually acclimated to different salinities (0.5, 2.5, 5, 10, 15, 22, 33, 50 and 70 ppt (1.5%, 7.5%, 15%, 30%, 45%, 67%, 100%, 151% and 212% seawater)) and muscle tissue, urine, blood and intestinal fluids were analyzed for ion and in some cases urea concentration. The renal and intestinal ionoregulatory processes of toadfish responded to changes in salinity and when gradually acclimated, toadfish maintain a relatively constant plasma osmolality at environmental salinities of 5 to 50 ppt. However, at salinities lower (2.5 ppt) or higher (70 ppt) than this range, a significant deviation from resting plasma and urine osmolality as well as changes in muscle water content was measured, suggesting osmoregulatory difficulties at these salinities. The renal system compensates for dilute seawater by reducing Na+ reabsorption by the bladder, which allowed excess water to be excreted. In the case of hypersalinity, Na+ reabsorption was increased, which resulted in a conservation of water and the concentration of Mg2+, Cl-, SO(4)2- and urea. A similar pattern was observed within the gastrointestinal system. Notably, Mg2+, HCO3- and SO4(2-) were the dominant ions in the intestinal fluid under control and hypersaline conditions due to the absorption of Na+, Cl- and water. When exposed to dilute seawater conditions, the absorption of Na+ was greatly reduced which likely increased water elimination. As a result of decreased environmental levels and a reduction in drinking rate, Mg2+ and SO4(2-) in intestinal fluids under hypoosmotic conditions were greatly reduced. While urea did play a minor role in renal osmoregulation, toadfish appear to preferentially regulate Na+ and to some extend Cl- in urine and intestinal fluids.     

Individual, temporal, and population-level variations in circulating 11-ketotestosterone and 17β-estradiol concentrations in the oyster toadfish Opsanus tau

Sex steroid hormones are important for reproduction in all vertebrates, but few studies examine inter-individual, temporal, and population-level variations, as well as environmental influences on circulating steroid levels within the same species. In this study we analyzed plasma 11-ketotoestosterone (11-KT) and 17β-estradiol (E₂) levels in the oyster toadfish to test for 1) individual and temporal variations by serially sampling the same individuals during the reproductive and post-reproductive period, 2) variations in steroid levels among toadfish obtained from different sources or maintained under different holding conditions, and 3) correlations with environmental parameters. Results from serial sampling showed marked inter-individual variations in male 11-KT levels in two separate groups of toadfish, but no temporal differences from June to September. Females also showed inter-individual variations in E₂ concentrations, but most had elevated levels late in the reproductive season coincident with oocyte growth prior to winter quiescence. E₂ concentration, but not 11-KT, was positively correlated with water temperature, and negatively correlated with daylength and lunar phase. Maricultured toadfish held under constant conditions had elevated levels of E₂ and 11-KT that should be considered when using these fish for experimentation. This study provides important comparative information on the relationship between individual variations in steroid levels, and how they relate to physiological and environmental correlates in a model marine teleost.     

Adaptive responses of aglomerular toadfish to dilute sea water

Plasma and urine of toadfish (Opsanus tau) in sea water and 10% sea water were analyzed to assess responses of an aglomerular fish to hypoosmotic challenge. Following transfer to 10% sea water, plasma osmotic pressure decreased slowly from 318 to 241 mmol · kg H₂O⁻¹, over a period of 10–15 days. Urine osmotic pressure decreased in parallel from 299 to 207 mmol · kg H₂O⁻¹, leaving urine/plasma ratios of osmotic pressure essentially unchanged. In contrast, the volume and composition of urine changed rapidly following transfer to 10% sea water. Urine flow rate increased 110% from 3.0 to 6.3 μl · 100g⁻¹ · h⁻¹ and Na⁺ excretion increased 346%, while excretion of Mg²⁻ and SO₄ ²⁻ decreased 81% and 90%, respectively. Excretion rates for Cl⁻ were low in seawater toadfish and decreased further in 10% sea water. An unknown sulfur-containing anion, present in the urine of seawater toadfish, contributed significantly to the composition and ionic balance in urine of toadfish in 10% sea water. These results suggest that the inability to produce strongly dilute urine obliges toadfish to lose salt in order to excrete water, in hypoosmotic media. The decrease in plasma osmotic pressure may be both a strategy to reduce osmotic and ionic gradients in dilute media and a consequence of the kidney's inability to excrete water without salt. Accepted: 22 August 1996     

The toadfish serotonin 2A (5-HT(2A)) receptor: molecular characterization and its potential role in urea excretion

Based on early pharmacological work, the serotonin 2A (5-HT(2A)) receptor subtype is believed to be involved in the regulation of toadfish pulsatile urea excretion. The goal of the following study was to characterize the toadfish 5-HT(2A) receptor at a molecular level, to determine the tissues in which this receptor is predominantly expressed and to further investigate the pharmacological specificity of toadfish pulsatile urea excretion by examining the effect of ketanserin, a 5-HT(2A) receptor antagonist, on resting rates of pulsatile urea excretion. The full-length toadfish 5-HT(2A) receptor encodes a 496 amino acid sequence and shares 57-80% sequence identity to 5-HT(2A) receptors of other organisms, with 100% conservation among important ligand-binding residues. Toadfish 5-HT(2A) receptor mRNA expression was highest in the swim bladder and gonad, followed by the whole brain. All other tissues tested (esophagus, stomach, anterior intestine, posterior intestine, rectum, liver, kidney, heart, muscle and gill) had mRNA expression levels that were significantly less than whole brain. Toadfish 5-HT(2A) receptor mRNA expression within the brain was highest in the hindbrain, telencephalon and midbrain/diencephalon regions. Treatment with the 5-HT(2A) receptor antagonist, ketanserin, resulted in a significant decrease in the pulsatile component of spontaneous urea excretion due to a reduction in urea pulse size with no significant change in pulse frequency. These results lend further support for the 5-HT(2A) receptor in the regulation of pulsatile urea excretion in toadfish.