The rectal gland and euryhalinity in elasmobranch fish

Good, Jonathan

Unknown Date

1) Both the partially euryhaline Scyliorhinus canicula and the fully euryhaline Carcharhinus leucas significantly modify plasma concentrations of urea and chloride (Cl-) (and sodium (Na+)) in response to changes in environmental salinity, in order to maintain overall plasma osmolality slightly hyper- or isosmotic to the environment. C. leucas has a greater capacity for urea retention in dilute environments. In S. canicula all of these changes occur within 12 hours of transfer, with the notable exception of increasing plasma urea in response to acute transfer to elevated salinity. 2) A new technique, 51Cr-labelled erythrocytes, was developed to assess blood volume in elasmobranch fish. S. canicula displays significant haemodilution and concentration during chronic acclimation to decreased and increased environmental salinity respectively. Significant changes in blood volume were seen within 6 hours of acute salinity transfer. 3) In vivo secretion rates were measured in the rectal gland of S. canicula during both chronic and acute salinity transfer. Significant changes in Cl- clearance occur during acute transfer, as plasma Na+ and Cl- levels are modified, but do not persist in chronically acclimated animals. This is achieved through modifications in the volume and Cl- concentration of the secretory fluid. 4) C. leucas is able to significantly alter the abundance and/or recruitment of Na+, K+-ATPase in both the rectal gland and the kidney during chronic acclimation to salinity transfer. This is presumably in response to increased requirements for NaCl secretion in SW and osmolyte retention in FW respectively. S. canicula do not significantly alter abundance and/or recruitment of Na+, K+-ATPase in the principle osmoregulatory organs following chronic acclimation to salinity transfer. 5) Chronically SW acclimated C. leucas modify the proportion of ouabain-sensitive oxygen consumption in the tissues of the rectal gland in response to the secretory endocrine stimulus C-type natriuretic peptide (CNP). No such modification occurred in the rectal glands of FW acclimated C. leucas. This represents a change in the sensitivity and response to endocrine control factors during chronic acclimation to salinity transfer in this species. No such modification was seen the in the proportion of ouabain-sensitive oxygen consumption in the rectal glands of chronically acclimated S. canicula in response to CNP. These results were discussed in relation to the capacity for modification of osmoregulatory organs in partially and fully euryhaline elasmobranchs.

270500 Zoology

rectal gland

euryhalinity

elasmobranch fish

environmental salinity

urea retention

blood volume

Functional characterization of renal ammonia transport and acid-base regulation in teleost and elasmobranch fishes

Lawrence, Michael J.

January 2014

Teleost fishes incorporate renal ammonia excretion as part of a greater acid-base regulatory system. However, the transport mechanisms employed by the renal epithelium to excrete ammonia are relatively unknown. I hypothesized that, under metabolic acidosis, increased renal ammonia excretion would be the product of tubular secretion and involve a Na+/NH4+ exchange metabolon mediated through Rhesus (Rh) glycoproteins. To induce metabolic acidosis, goldfish (Carassius auratus) were exposed to a low pH environment (pH 4.0; 48-h). There was a clear signal of metabolic acidosis: a reduction in both plasma [HCO3-] and blood pH with no influence on plasma PCO2. Goldfish demonstrated an elevation in total plasma [ammonia] with a reduction in PNH3 under acidosis. Metabolic acidosis induced higher rates of urinary excretion of acidic equivalents in the form of both NH4+ and titratable acidity-HCO3- (TA-HCO3-) excretion. Urinary Na+ excretion was not affected by acidosis and urine [Na+] did not correlate with urinary [ammonia]. Alanine aminotransferase activity in the kidney was higher in acidotic goldfish. Glomerular filtration rate and urine flow rate were not affected by acidosis. Increased renal NH4+ excretion was due to increased secretion, and not increased filtration, of ammonia. There was a corresponding elevation in Rhcg1b mRNA expression but no change in renal Na+ reabsorption. My data support a secretion-based mechanism of teleost renal ammonia transport. This system is Na+ independent and is likely mediated by Rh glycoproteins and H+ ATPase, involving a parallel H+/NH3 secretion mechanism. To investigate effects of metabolic acidosis on elasmobranch fish, Pacific spiny dogfish (Squalus acanthias suckleyi) were infused with an acidic saline (125 mM HCl/375 mM NaCl; 3 ml/kg/h; 24-h). The results are preliminary, with no marked effects of HCl infusion on plasma acid-base or N-status, but increased branchial NHE2 and lower renal NHE3 protein expressions. These data are summarized in an Appendix. / Thesis / Master of Science (MSc)

Ammonia

Renal ammonia transport

Kidney

Sodium

Rhesus glycoproteins

Acid-base regulation

Teleost fish

Elasmobranch fish

Comparative and Evolutionary Physiology

Systems and Integrative Physiology

Biology

Cellular and Molecular Physiology

Metabolic Acidosis

Gills

Amino acid metabolism

H+ ATPase