Adaptive strategies for post-renal handling of urine in birds

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Adaptive strategies for post-renal handling of urine in birds. / Laverty, Gary; Skadhauge, Erik.

I: Comparative Biochemistry and Physiology A, Bind 149, Nr. 3, 2008, s. 246-254.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Laverty, G & Skadhauge, E 2008, 'Adaptive strategies for post-renal handling of urine in birds', Comparative Biochemistry and Physiology A, bind 149, nr. 3, s. 246-254. https://doi.org/10.1016/j.cbpa.2008.01.014

APA

Laverty, G., & Skadhauge, E. (2008). Adaptive strategies for post-renal handling of urine in birds. Comparative Biochemistry and Physiology A, 149(3), 246-254. https://doi.org/10.1016/j.cbpa.2008.01.014

Vancouver

Laverty G, Skadhauge E. Adaptive strategies for post-renal handling of urine in birds. Comparative Biochemistry and Physiology A. 2008;149(3):246-254. https://doi.org/10.1016/j.cbpa.2008.01.014

Author

Laverty, Gary ; Skadhauge, Erik. / Adaptive strategies for post-renal handling of urine in birds. I: Comparative Biochemistry and Physiology A. 2008 ; Bind 149, Nr. 3. s. 246-254.

Bibtex

@article{df75b1f0a1c311ddb6ae000ea68e967b,
title = "Adaptive strategies for post-renal handling of urine in birds",
abstract = "Birds are a diverse vertebrate class in terms of diet and habitat, but they share several common physiological features, including the use of uric acid as the major nitrogenous waste product and the lack of a urinary bladder. Instead, ureteral urine refluxes from the urodeum into the more proximal coprodeum and portions of the hindgut (colon or rectum and ceca). This presents a potential problem in that hyperosmotic ureteral urine in contact with the permeable epithelia of these tissues would counteract renal osmotic work. This review describes and provides examples of different strategies used by avian species to balance renal and post-renal changes in urien composition. The strategies described include: 1. a {"}reptilian{"} mode, with moderate renal concentrating ability, but high rates of post-renal salt and water resorption; 2. the {"}mammalian{"} strategy, in which the coprodeum effectively functions like a mammalian urinary bladder, preserving the osmotic concentrating work of the kidney; 3. an interaction strategy, in which post-renal transport processes are hormonally regulated in order to optimize renal function under varying conditions of salt or water stress; 4. the salt gland strategy seen in marine or estuarine birds with functional salt glands, in which post-renal transport mechanisms are used to conserve urinary water andd to recycle excess NaCl to the nasal salt glands. Finally, we also describe some features of an as-yet unstudied group of birds, the birds of prey. At least some species in this group are relatively good renal concentrators, and would be predicted to have post-renal mechanisms to preserve this work. This new synthesis illustrates the marked diversity of adaptive mechanisms used by avian species to maintain osmotic homeostasis.",
keywords = "Former LIFE faculty, Avian lower intestine, Cloaca, Domestic fowl, Emu (Dromaius novae-hollandiae), Kookaburra (Dacelo gigas), Nasal salt gland, Osmoregulation, Ostrich (Struthio camelus)",
author = "Gary Laverty and Erik Skadhauge",
year = "2008",
doi = "10.1016/j.cbpa.2008.01.014",
language = "English",
volume = "149",
pages = "246--254",
journal = "Comparative biochemistry and physiology. Part A, Molecular & integrative physiology",
issn = "1095-6433",
publisher = "Elsevier",
number = "3",

}

RIS

TY - JOUR

T1 - Adaptive strategies for post-renal handling of urine in birds

AU - Laverty, Gary

AU - Skadhauge, Erik

PY - 2008

Y1 - 2008

N2 - Birds are a diverse vertebrate class in terms of diet and habitat, but they share several common physiological features, including the use of uric acid as the major nitrogenous waste product and the lack of a urinary bladder. Instead, ureteral urine refluxes from the urodeum into the more proximal coprodeum and portions of the hindgut (colon or rectum and ceca). This presents a potential problem in that hyperosmotic ureteral urine in contact with the permeable epithelia of these tissues would counteract renal osmotic work. This review describes and provides examples of different strategies used by avian species to balance renal and post-renal changes in urien composition. The strategies described include: 1. a "reptilian" mode, with moderate renal concentrating ability, but high rates of post-renal salt and water resorption; 2. the "mammalian" strategy, in which the coprodeum effectively functions like a mammalian urinary bladder, preserving the osmotic concentrating work of the kidney; 3. an interaction strategy, in which post-renal transport processes are hormonally regulated in order to optimize renal function under varying conditions of salt or water stress; 4. the salt gland strategy seen in marine or estuarine birds with functional salt glands, in which post-renal transport mechanisms are used to conserve urinary water andd to recycle excess NaCl to the nasal salt glands. Finally, we also describe some features of an as-yet unstudied group of birds, the birds of prey. At least some species in this group are relatively good renal concentrators, and would be predicted to have post-renal mechanisms to preserve this work. This new synthesis illustrates the marked diversity of adaptive mechanisms used by avian species to maintain osmotic homeostasis.

AB - Birds are a diverse vertebrate class in terms of diet and habitat, but they share several common physiological features, including the use of uric acid as the major nitrogenous waste product and the lack of a urinary bladder. Instead, ureteral urine refluxes from the urodeum into the more proximal coprodeum and portions of the hindgut (colon or rectum and ceca). This presents a potential problem in that hyperosmotic ureteral urine in contact with the permeable epithelia of these tissues would counteract renal osmotic work. This review describes and provides examples of different strategies used by avian species to balance renal and post-renal changes in urien composition. The strategies described include: 1. a "reptilian" mode, with moderate renal concentrating ability, but high rates of post-renal salt and water resorption; 2. the "mammalian" strategy, in which the coprodeum effectively functions like a mammalian urinary bladder, preserving the osmotic concentrating work of the kidney; 3. an interaction strategy, in which post-renal transport processes are hormonally regulated in order to optimize renal function under varying conditions of salt or water stress; 4. the salt gland strategy seen in marine or estuarine birds with functional salt glands, in which post-renal transport mechanisms are used to conserve urinary water andd to recycle excess NaCl to the nasal salt glands. Finally, we also describe some features of an as-yet unstudied group of birds, the birds of prey. At least some species in this group are relatively good renal concentrators, and would be predicted to have post-renal mechanisms to preserve this work. This new synthesis illustrates the marked diversity of adaptive mechanisms used by avian species to maintain osmotic homeostasis.

KW - Former LIFE faculty

KW - Avian lower intestine

KW - Cloaca

KW - Domestic fowl

KW - Emu (Dromaius novae-hollandiae)

KW - Kookaburra (Dacelo gigas)

KW - Nasal salt gland

KW - Osmoregulation

KW - Ostrich (Struthio camelus)

U2 - 10.1016/j.cbpa.2008.01.014

DO - 10.1016/j.cbpa.2008.01.014

M3 - Journal article

C2 - 18276178

VL - 149

SP - 246

EP - 254

JO - Comparative biochemistry and physiology. Part A, Molecular & integrative physiology

JF - Comparative biochemistry and physiology. Part A, Molecular & integrative physiology

SN - 1095-6433

IS - 3

ER -

ID: 8104651