Effect of high salinity acclimation on glucose homeostasis in Mozambique tilapia (Oreochromis mossambicus)

1. When stressed with high-salinity exposure, cell volume is restored in ventricles of Modiolus demissus demissus by a rapid accumulation of intracellular free amino acids. 2. Although the total amino acid pool increases and remains at a constant high level thereafter, the pattern and time course of accumulation is different for each major amino acid (glycine, alanine, taurine, and proline). 3. Initially, cell volume is restored by a rapid accumulation of alanine, but later its concentration decreases while glycine and taurine accumulate. Although at first not detected, the proline concentration increases, peaks and subsequently disappears again. 4. Isolated ventricles recover normal activity after large environmental salinity increases. 5. During recovery the intracellular free amino acid changes in isolated ventricles are similar to the initial pattern of accumulation in whole animals, i.e., alanine, and to a lesser extent, proline and glycine accumulate. 6. Finally, isolated ventricles undergo a period of decreased oxygen consumption on exposure to an increased salinity. 7. These results suggest that the initial stages of high-salinity acclimation in molluscs depends upon the synthesis of amino acids via a known anaerobic biochemical pathway. Note: Contribution No. 33 from the Tallahassee, Sopchoppy and Gulf Coast Marine Biological Association.

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clc-2c is regulated by salinity, prolactin and extracellular osmolality in tilapia gill

Journal of Molecular Endocrinology ◽

10.1530/jme-17-0144 ◽

2017 ◽

Vol 59 (4) ◽

pp. 391-402 ◽

Cited By ~ 2

Author(s):

Jason P Breves ◽

Paige L K Keith ◽

Bethany L Hunt ◽

K Keano Pavlosky ◽

Mayu Inokuchi ◽

...

Keyword(s):

Danio Rerio ◽

External Environment ◽

Oreochromis Mossambicus ◽

Local Effect ◽

Intrinsic Factors ◽

Mozambique Tilapia ◽

Regulatory Link ◽

Gill Filaments ◽

Ovine Prolactin ◽

First Time

Teleosts inhabiting fresh water (FW) depend upon ion-absorptive ionocytes to counteract diffusive ion losses to the external environment. A Clc Cl−channel family member, Clc-2c, was identified as a conduit for basolateral Cl−transport by Na+/Cl−cotransporter 2 (Ncc2)-expressing ionocytes in stenohaline zebrafish (Danio rerio). It is unresolved whether Clc-2c/clc-2cis expressed in euryhaline species and how extrinsic and/or intrinsic factors modulate branchialclc-2cmRNA. Here, we investigated whether environmental salinity, prolactin (Prl) and osmotic conditions modulateclc-2cexpression in euryhaline Mozambique tilapia (Oreochromis mossambicus). Branchialclc-2candncc2mRNAs were enhanced in tilapia transferred from seawater (SW) to FW, whereas both mRNAs were attenuated upon transfer from FW to SW. Next, we injected hypophysectomized tilapia with ovine prolactin (oPrl) and observed a marked increase inclc-2cfrom saline-injected controls. To determine whether Prl regulatesclc-2cin a gill-autonomous fashion, we incubated gill filaments in the presence of homologous tilapia Prls (tPrl177and tPrl188). By 24 h, tPrl188stimulatedclc-2cexpression ~5-fold from controls. Finally, filaments incubated in media ranging from 280 to 450 mosmol/kg for 3 and 6 h revealed that extracellular osmolality exerts a local effect onclc-2cexpression;clc-2cwas diminished by hyperosmotic conditions (450 mosmol/kg) compared with isosmotic controls (330 mosmol/kg). Our collective results suggest that hormonal and osmotic control of branchialclc-2ccontributes to the FW adaptability of Mozambique tilapia. Moreover, we identify for the first time a regulatory link between Prl and a Clc Cl−channel in a vertebrate.

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