The Water Absorption Response: A Behavioral Assay for Physiological Processes in Terrestrial Amphibians

Hillyard, Stanley D.; Hoff, Karin; Propper, Catherine R.

doi:10.1086/515900

Cited by 64 publications

(34 citation statements)

References 4 publications

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“…The tissue electrolyte content was diluted in nonperfused skin, indicating the circulation removed water as it was absorbed to prevent diminution of the osmotic gradient across the epidermis. Water absorption by anurans occurs in conjunction with a behavior, termed the water absorption response (16,26), during which the skin is pressed to a moist surface and there is a large increase in blood flow to the absorbing area of the seat patch (33,34), in conjunction with the insertion of AQPs into the apical membranes of the FRC layer of the skin (27). A better understanding of adaptations for semiterrestrial vs. semiaquatic species will require an understanding of all three parameters from a physiological and phylogenetic perspective.…”

Section: Possible Expression Of New-type Aqps In the Ventral Pelvic Smentioning

confidence: 99%

The water-absorption region of ventral skin of several semiterrestrial and aquatic anuran amphibians identified by aquaporins

Ogushi

Tsuzuki

Sato

et al. 2010

American Journal of Physiology-Regulatory, Integrative and Comp

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Regions of specialization for water absorption across the skin of Bufonid and Ranid anurans were identified by immunohistochemistry and Western blot analysis, using antibodies raised against arginine vasotocin (AVT)-stimulated aquaporins (AQPs) that are specific to absorbing regions of Hyla japonica. In Bufo marinus, labeling for Hyla urinary bladder-type AQP (AQP-h2), which is also localized in the urinary bladder, occurred in the ventral surface of the hindlimb, pelvic, and pectoral regions. AQP-h2 was not detected in any skin regions of Rana catesbeiana, Rana japonica, or Rana nigromaculata. Hyla ventral skin-type AQP (AQP-h3), which is found in the ventral skin but not the bladder of H. japonica, was localized in the hindlimb, pelvic, and pectoral skins of Bufo marinus, in addition to AQP-h2. AQP-h3 was also localized in ventral skin of the hindlimb of all three Rana species and also in the pelvic region of R. catesbiana. Messenger RNA for AQP-x3, a homolog of AQP-h3, could be identified by RT-PCR from the hindlimb, pectoral, and pelvic regions of the ventral skin of Xenopus laevis, although AVT had no effect on water permeability. In contrast, 10 Ϫ8 M AVT-stimulated water permeability and translocation of AQP-h2 and AQP-h3 into the apical membrane of epithelial cells in regions of the skin of species where they had been localized by immunohistochemistry and Western blot analysis. Finally, water permeability of the hindlimb skin of B. marinus and all the Rana species was stimulated by hydrins 1 and 2 to a similar level as seen for AVT. The present data demonstrate species differences in the occurrence, distribution, and regulation of AQPs in regions of skin specialized for rapid water absorption that can be associated with habitat and also phylogeny. hindlimb skin; arginine vasotocin; immunohistochemistry; water permeability; frogs MANY ADULT ANURAN AMPHIBIANS do not drink through their mouth. Rather, they absorb water across their skin and form dilute urine that is stored in their urinary bladder and can be reabsorbed when foraging away from a hydration source (4, 5). Hillman et al. (14) refer to this water balance strategy as semiterrestrial to distinguish it from terrestrial species that are completely independent of water. The semiterrestrial classification applies to tree frogs in the family Hylidae and toads in the family Bufonidae that have been traditionally classified as arboreal and terrestrial, respectively, in that both have large urinary bladder capacity and specializations for rapidly rehydrating when water is available. Specifically, they utilize an area of skin in the posteroventral region of the body that is specialized for rapid water absorption from shallow water sources or moist substrates. This region, termed the pelvic patch or seat patch, extends laterally to the ventral surface of the hindlimbs and shows a pattern of elevations and grooves termed verrucae hydrophilicae (14). The seat patch is also an area where capillaries form intimate contact with the basement membrane that underli...

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Section: Possible Expression Of New-type Aqps In the Ventral Pelvic Smentioning

confidence: 99%

The water-absorption region of ventral skin of several semiterrestrial and aquatic anuran amphibians identified by aquaporins

Ogushi

Tsuzuki

Sato

et al. 2010

American Journal of Physiology-Regulatory, Integrative and Comp

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“…The relative importance of these stimuli varies among different classes of vertebrates or among species in different habitats. Thirst motivates oral drinking behavior in terrestrial animals, but it induces cutaneous drinking behavior in amphibians [34]. Angiotensin II is more intimately related to extracellular dehydration because hypovolemia invariably stimulates renin secretion in all of the species examined, while an increase in plasma osmolarity generally inhibits renin secretion in most species examined [35].…”

Section: Thirst Mechanismsmentioning

confidence: 99%

“…Furthermore, angiotensin II seems to induce a sensation of thirst in amphibians. Hillyard and his colleagues [34,47] showed that angiotensin II stimulates water drive in the terrestrial toad, Bufo punctatus; it then induces hind limb abduction to bring a specialized portion of the ventral skin to a moist surface, the so-called "cutaneous drinking behavior." Therefore, it seems that angiotensin II in-Japanese Journal of Physiology Vol.…”

Section: Thirst Mechanismsmentioning

confidence: 99%

“…In the quail, hypovolemic stimulus increased plasma angiotensin II concentration (Table 3), and the inhibition of angiotensin II formation by SQ14225 inhibited hemorrhage-induced drinking. Hemorrhage did not induce oral drinking in the frog [45], but increased plasma angiotensin II and vasotocin after hemorrhage may induce cutaneous drinking behavior [34] and increase cutaneous uptake of water and Na ϩ [44].…”

Section: Thirst Mechanismsmentioning

confidence: 99%

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Comparative Physiology of Body Fluid Regulation in Vertebrates with Special Reference to Thirst Regulation

Takei

2000

Jpn.J.Physiol

104

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Vertebrates live in diverse habitats that range from inland fresh waters to the seas and to dry land. It is indeed surprising that most of the animals including freshwater fish, seawater fish, and even desert dwellers maintain similar ionic composition and osmolarity of their plasma. Even with the similarity, however, the mechanisms regulating body fluid balance differ greatly among animals living in different habitats. The study of body fluid regulation has a long history of research, over 100 years in mammals [1]. The intense

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“…This chamber also allowed us to evaluate the effect of different immersion levels on BCF and water absorption from deionised water (DI) and salt solutions. Because the toads were conscious and unrestrained, we were able to observe whether the time course for behaviours associated with water absorption (Hillyard et al, 1998) corresponded to the physiological response to water contact (increase in BCF).…”

Section: Introductionmentioning

confidence: 99%

Cardiovascular and behavioural changes during water absorption in toads, Bufo alvarius and Bufo marinus

Viborg

Wang

Hillyard

2006

Journal of Experimental Biology

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SUMMARY Blood cell flux (BCF) in the pelvic skin of Bufo marinus was lower than Bufo alvarius when toads rehydrated from deionised water (DI) or 50 mmol l–1 NaCl (NaCl). Despite the lower BCF in B. marinus, water absorption was not different between the species when toads rehydrated from DI or NaCl. When fluid contact was limited to the pelvic skin, water uptake from NaCl was lower than from DI, but became greater than uptake from DI as the immersion level increased. Hydrophobic beeswax coating the lateral sides reduced absorption from NaCl but not from DI. Toads settled into water absorption response posture well after maximal BCF was attained in both DI and NaCl, indicating that the behavioural response requires neural integration beyond the increase in BCF. Water exposure increased BCF in hydrated B. alvarius with empty bladders but not in those with stored bladder water. Hydrated B. marinus with an empty bladder did not increase BCF when given water. Handling stress depressed BCF but increased central arterial flow (CAF), measured using a flow probe around the dorsal aorta. In undisturbed toads, CAF increased with the same time course as BCF while heart rate remained relatively constant, suggesting redistribution of blood flow.

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The Water Absorption Response: A Behavioral Assay for Physiological Processes in Terrestrial Amphibians

Cited by 64 publications

References 4 publications

The water-absorption region of ventral skin of several semiterrestrial and aquatic anuran amphibians identified by aquaporins

The water-absorption region of ventral skin of several semiterrestrial and aquatic anuran amphibians identified by aquaporins

Comparative Physiology of Body Fluid Regulation in Vertebrates with Special Reference to Thirst Regulation

Cardiovascular and behavioural changes during water absorption in toads, Bufo alvarius and Bufo marinus

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