Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions

Intestinal HCO3- secretion and the excretion of resultant CaCO3 precipitates have become a recognized characteristic of seawater osmoregulation in teleosts; however, this is the first report of this osmoregulatory strategy outside of teleosts and also includes evidence for its use in green turtles,...

Full description

Bibliographic Details
Main Author: Taylor, Josi R.
Format: Others
Published: Scholarly Repository 2009
Subjects:
Online Access:http://scholarlyrepository.miami.edu/oa_dissertations/263
id ndltd-UMIAMI-oai-scholarlyrepository.miami.edu-oa_dissertations-1262
record_format oai_dc
spelling ndltd-UMIAMI-oai-scholarlyrepository.miami.edu-oa_dissertations-12622011-12-13T15:39:09Z Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions Taylor, Josi R. Intestinal HCO3- secretion and the excretion of resultant CaCO3 precipitates have become a recognized characteristic of seawater osmoregulation in teleosts; however, this is the first report of this osmoregulatory strategy outside of teleosts and also includes evidence for its use in green turtles, Chelonia mydas. Furthermore, the effects of feeding on intestinal HCO3- secretion were newly investigated in teleosts. Intestinal base secretion via apical Cl-/HCO3- exchange was found to increase following feeding, at a magnitude sufficient to offset the "alkaline tide" commonly associated with digestion. Intestinal HCO3- secretion in marine teleosts draws HCO3- from both endogenous (via hydration of intracellular CO2) and serosal (blood) sources, of which serosal HCO3- was found to contribute a greater proportion to the elevated postprandial intestinal base secretion measured in gulf toadfish, Opsanus beta. The mechanism by which this serosal HCO3- crosses the basolateral membrane for subsequent secretion into the intestinal lumen was confirmed in toadfish to be a basolateral Na+/HCO3- co-transporter, tfNBCe1. Furthermore, the isolated intestinal tissue was found to have a high metabolic rate in both control and postprandial toadfish, with respect to that of the whole animal, and shows a considerable specific dynamic action (SDA) response to feeding. Overall, this dissertation provides evidence for the widespread use of intestinal HCO3- secretion as a strategy of marine osmoregulation across aquatic taxa, and also for its newly recognized involvement in postprandial acid-base balance. 2009-06-23 text application/pdf http://scholarlyrepository.miami.edu/oa_dissertations/263 Open Access Dissertations Scholarly Repository Salt-water Balance Acid-base Balance Sodium Transport Sea Turtle Crab Hagfish Lamprey Shark Chimaera Sturgeon Toadfish
collection NDLTD
format Others
sources NDLTD
topic Salt-water Balance
Acid-base Balance
Sodium Transport
Sea Turtle
Crab
Hagfish
Lamprey
Shark
Chimaera
Sturgeon
Toadfish
spellingShingle Salt-water Balance
Acid-base Balance
Sodium Transport
Sea Turtle
Crab
Hagfish
Lamprey
Shark
Chimaera
Sturgeon
Toadfish
Taylor, Josi R.
Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions
description Intestinal HCO3- secretion and the excretion of resultant CaCO3 precipitates have become a recognized characteristic of seawater osmoregulation in teleosts; however, this is the first report of this osmoregulatory strategy outside of teleosts and also includes evidence for its use in green turtles, Chelonia mydas. Furthermore, the effects of feeding on intestinal HCO3- secretion were newly investigated in teleosts. Intestinal base secretion via apical Cl-/HCO3- exchange was found to increase following feeding, at a magnitude sufficient to offset the "alkaline tide" commonly associated with digestion. Intestinal HCO3- secretion in marine teleosts draws HCO3- from both endogenous (via hydration of intracellular CO2) and serosal (blood) sources, of which serosal HCO3- was found to contribute a greater proportion to the elevated postprandial intestinal base secretion measured in gulf toadfish, Opsanus beta. The mechanism by which this serosal HCO3- crosses the basolateral membrane for subsequent secretion into the intestinal lumen was confirmed in toadfish to be a basolateral Na+/HCO3- co-transporter, tfNBCe1. Furthermore, the isolated intestinal tissue was found to have a high metabolic rate in both control and postprandial toadfish, with respect to that of the whole animal, and shows a considerable specific dynamic action (SDA) response to feeding. Overall, this dissertation provides evidence for the widespread use of intestinal HCO3- secretion as a strategy of marine osmoregulation across aquatic taxa, and also for its newly recognized involvement in postprandial acid-base balance.
author Taylor, Josi R.
author_facet Taylor, Josi R.
author_sort Taylor, Josi R.
title Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions
title_short Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions
title_full Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions
title_fullStr Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions
title_full_unstemmed Intestinal HCO3- Secretion in Fish: A Widespread Mechanism with Newly Recognized Physiological Functions
title_sort intestinal hco3- secretion in fish: a widespread mechanism with newly recognized physiological functions
publisher Scholarly Repository
publishDate 2009
url http://scholarlyrepository.miami.edu/oa_dissertations/263
work_keys_str_mv AT taylorjosir intestinalhco3secretioninfishawidespreadmechanismwithnewlyrecognizedphysiologicalfunctions
_version_ 1716389542950338560