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1.
Dokl Biol Sci ; 478(1): 37-39, 2018 Jan.
Article in English | MEDLINE | ID: mdl-29536406

ABSTRACT

The article reports data on the dynamics of blood parameters and parameters of protein, fat, and water-salt metabolism in female starlet × beluga hybrids kept under artificial conditions in the period of reproductive cycle. Gonad maturation in female hybrids in the artificial environment causes clear changes in the biochemistry of blood and of urine.


Subject(s)
Fishes/blood , Hybridization, Genetic , Reproduction , Animals , Female , Fish Proteins/metabolism , Fisheries , Fishes/genetics , Fishes/physiology , Fishes/urine , Osmolar Concentration , Ovary/growth & development
2.
Article in English | MEDLINE | ID: mdl-18835584

ABSTRACT

The basic physiology of water balance and kidney function was characterized in two species of African lungfish, Protopterus dolloi and Protopterus annectens. Diffusive water efflux rate constants were low (0.13 h(-1)-0.38 h(-1) in various series) relative to values in freshwater teleost fish. Efflux rate constants increased approximately 3-fold after feeding in both species, and were greatly decreased after 8 months terrestrialization (P. dolloi only tested). Urine flow rates (UFR, 3.9-5.2 mL kg(-1) h(-1)) and glomerular filtration rates (GFR, 6.6-9.3 mL kg(-1) h(-1)) were quite high relative to values in most freshwater teleosts. However urinary ion excretion rates were low, with net re-absorption of >99% Na(+), >98% Cl(-), and >78% Ca(2+) from the primary filtrate, comparable to teleosts. Net water re-absorption was significantly greater in P. dolloi (56%) than in P. annectens (23%). We conclude that renal function in lungfish is similar to that in other primitive freshwater fish, but there is an interesting dichotomy between diffusive and osmotic permeabilities. Aquatic lungfish have low diffusive water permeability, an important pre-adaptation to life on land, and in accord with greatly reduced gill areas and low metabolic rates. However osmotic permeability is high, 4-12 times greater than diffusive permeability. A role for aquaporins in this dichotomy is speculated.


Subject(s)
Fishes/physiology , Kidney/physiology , Water-Electrolyte Balance , Adaptation, Physiological , Animals , Body Water/metabolism , Calcium/urine , Chlorides/urine , Diffusion , Fishes/urine , Fresh Water , Glomerular Filtration Rate , Kidney/metabolism , Kinetics , Osmosis , Permeability , Sodium/urine , Tritium , Urodynamics
3.
J Comp Physiol B ; 174(7): 555-64, 2004 Oct.
Article in English | MEDLINE | ID: mdl-15316727

ABSTRACT

This study aimed to elucidate the role of urea synthesis in the slender African lungfish Protopterus dolloi in detoxifying ammonia after feeding. There were significant increases in the rate of ammonia excretion in P. dolloi between hours 6 and 15 after feeding. Simultaneously, there were significant increases in urea excretion rates between hours 3 and 18. Consequently, the percentage of total nitrogen (N) excreted as urea N increased to approximately 60% between hours 12 and 21 post-feeding. Hence, after feeding, the normally ammonotelic P. dolloi became ureotelic. Approximately 41% of the N intake from food was excreted within 24 h by P. dolloi, 55% of which was in the form of urea N. At hour 12 post-feeding, the accumulation of urea N was greater than the accumulation of ammonia N in various tissues, which indicates that feeding led to an increase in the rate of urea synthesis. This is contrary to results reported previously on the infusion of ammonia into the peritoneal cavity of the marine dogfish shark, in which a significant portion of the exogenous ammonia was excreted as ammonia. In contrast, feeding is more likely to induce urea synthesis, which is energy intensive, because feeding provides an ample supply of energy resources and leads to the production of ammonia intracellularly in the liver. The capacity of P. dolloi to synthesize urea effectively prevented a postprandial surge in the plasma ammonia level as reported elsewhere for other non-ureogenic teleosts. However, there was a significant increase in the glutamine content in the brain at hour 24, indicating that the brain had to defend against ammonia toxicity after feeding.


Subject(s)
Ammonia/urine , Fishes/physiology , Postprandial Period , Urea/metabolism , Animals , Brain/metabolism , Diuresis , Fishes/metabolism , Fishes/urine , Glutamine/metabolism , Time Factors , Urea/urine
5.
J Exp Zool ; 199(3): 449-58, 1977 Mar.
Article in English | MEDLINE | ID: mdl-557530

ABSTRACT

Renal clearance experiments were performed on unanesthetized winter flounder from which bladder urine was collected continuously and caudal vein blood was sampled periodically; renal tissue was also obtained terminally for comparison of test organic acid content in vivo and after incubation in vitro. Urine flow rates and inulin U/P (urine to plasma concentration) ratios were relatively constant for a given fish and averaged 1.0 ml/hr X kg fish and 2.6, respectively. In contrast, U/P ratios for all three test acids cycled from minima of near 100 to maxima of over 1000 roughly every 24 hr when plasma concentrations of unbound acid were below 1 micron; correction of plasma protein binding was required in the case of chlorphenol red, but not PAH or Diodrast. Both in vivo and in vitro the organic acid content of renal tissue was intermediate between plasma and urine concentrations. These results demonstrate that kidneys of intact flounder exhibit the remarkable concentrative capacity for exogenous organic acids previously observed with isolated tubules and suggest that the tubular urine concentration is established in two steps by cell transport first at the peritubular and second at the luminal membrane. The anterior kidney position and the magnitude of maximal PAH and Diodrast clearances, about 1000 ml/hr X kg flounder, are consistent with most of the cardiac output returning to the heart through the renal portal circulation; a regulatory shunt bypassing the peritubular capillaries is proposed to explain cycling of organic acid clearances to minimal values.


Subject(s)
Fishes/urine , Kidney/physiology , Phenolphthaleins/urine , Phenolsulfonphthalein/urine , Animals , Fishes/blood , Iodopyracet/blood , Iodopyracet/urine , Phenolsulfonphthalein/analogs & derivatives , p-Aminohippuric Acid/blood , p-Aminohippuric Acid/urine
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