Effects of angiotensin II and bladder condition on hydration behavior and water uptake in the toad,Bufo woodhousei

• 1.1. Water absorption response (WR) behavior and water weight gain were examined in hydrated toads, Bufo woodhousei, treated with angiotensin II (All) or with a control Ringer's solution. The effects of urinary bladder condition (ad lib. bladder urine or empty bladder) were examined concurrently.
• 2.2. Toads treated with All (100μg/100g body weight), spent more time in WR posture and absorbed more water than Ringer's-injected toads.
• 3.3. Toads with empty bladders maintained WR posture for longer periods of time and gained more weight than toads whose bladders were not emptied.
• 4.4. The effects of All and bladder urine on water absorption by B. woodhousei appear to be separate and additive.

     

Some effects of dehydration on internal distributions of water and solutes in Xenopus laevis

• 1.1. In relation to body weight changes resulting from evaporative water losses of up to 37% of initial body weight:
  • 1.1.(a) Plasma chloride and potassium concentrations increased in proportion to total body water losses.
  • 1.2.(b) Plasma urea concentrations increased at greater rates than expected from the sum of basal synthesis and dehydration.
  • 1.3.(c) Plasma sodium concentrations initially increased less rapidly than expected from total body water losses, but by losses of 30% of initial body weight closely approximated predicted concentrations.
  • 1.4.(d) Plasma volumes decreased slightly faster than expected, while hematocrits increased as expected.
• 2.2. Skeletal muscles and the ventricular muscles of the heart retained water to greater degrees than expected. Dehydration did not elicit net shifts in Na⁺ K⁺, Cl⁻ or amino acids between the intracellular and extracellular compartments in either skeletal muscle or ventricle.

     

Evaporative water loss and uptake in juvenile and adult Salamandra salamandra (L.) (Amphibia: Urodela)

• 1.1. Both juveniles and adults of this rare salamander were studied.
• 2.2. The rate of evaporative water loss increased with temperature and at lower humidities.
• 3.3. At all four temperatures and three humidities studied, adults lost water at a lower rate than juveniles.
• 4.4. Aggregating juveniles reduced water loss especially at lower moisture.
• 5.5. The rate of water uptake was greater in juveniles than in adults.
• 6.6. Juveniles were capable of absorbing moisture from moist soil even at 40% saturated soil.

     

Seasonal variation in the rate of evaporative water loss in the kangaroo rat,Dipodomys panamintinus

• 1.1. Evaporative water loss was measured as a function of temperature, season and grouping in the kangaroo rat, Dipodomys panamintinus for a one year period.
• 2.2. Three groups of Panamint kangaroo rats were set up and studied during the various changes in season. The three groups were designated as field, exposed and control. These groups revealed the effects of acclimatization, captive acclimatization and laboratory acclimatization respectively.
• 3.3. There is a highly significant difference in the rate of evaporative water loss in the Field Panamint kangaroo rats during the Fall, Winter and Spring.
• 4.4. In general, the quantity of water loss via evaporation was higher in the female Panamint kangaroo rats.
• 5.5. Water loss via evaporation in the control and exposed groups was least affected by seasonal change.
• 6.6. In comparison to the other two groups, the field male and female Panimint kangaroo rats possessed the highest slope (rate) and mean (quantity) for all seasons.
• 7.7. The combined effect of both grouping and season affects both the rate and quantity of evaporative water loss in the Panamint kangaroo rat.

     

Changes in high-energy phosphate metabolism in the water scorpion,Ranatra chinensis,under cold water-warm water stress

• 1.1. To evaluate changes in high-energy phosphate metabolism in the water scorpion (Ranatra chinensis) under restraint and cold water-warm water stresses, in vivo [³¹P]NMR spectra were obtained.
• 2.2. Under restraint stress, arginine phosphate (Arg-P) decreased by 10% after 1 hr and remained at that level thereafter, while β-ATP showed negligible changes over 6 hr.
• 3.3. As the water temperature gradually increased or decreased, the relative concentration of Arg-P decreased due to enzyme regulation.
• 4.4. Repeated cold water-warm water stress, which consisted of repeated 15 min exposures to cold water (5°C) followed by 15 min exposures to warm water (30°C) caused distinct decreases in Arg-P and β-ATP concentration. These decreases were dependent on the frequency of exposure.
• 5.5. Phosphomonoesters (PME) increased not only with restraint stress but also with cold water-warm water stress.
• 6.6. The effect of cold water-warm water stress on high-energy phosphate metabolism was greater than that of restraint stress.

     

Body temperature,oxygen consumption,evaporative water loss and heart rate in the fennec

ab]

• 1.1. Fennecs show marked diurnal variations of body temperature and heart rate.
• 2.2. Basal metabolic rate (0.358 ml/ghr) is 39% lower than predicted by body mass, minimal conductance is reduced for 23%.
• 3.3. Fennecs have a wide thermoneutral zone (23.4–32.0°C) and a low rate of evaporative water loss.
• 4.4. Basal heart rate is considerably reduced. Oxygen pulse increases with decreasing ambient temperature. The higher oxygen demands below thermal neutrality, however, are met primarily by a rise in heart rate.
• 5.5. Newborn fennecs show a metabolic response to cold from the first day of life.

     

Sea-water tolerance in freshwater-resident arctic charr (Salvelinus alpinus)

• 1.1. Freshwater-resident Arctic charr acclimated for 2 months at 8°C, 15% were divided into four experimental groups in July and exposed to 1 and 8°C in 15 and 34% salinity.
• 2.2. Only slight changes in gill Na-K-ATPase activity, blood plasma osmolality and blood plasma concentrations of Cl⁻ and Mg²⁺ were found for the fish exposed to 1 or 8°C in brackish water.
• 3.3. When exposed to sea-water at 8°C, an increase in osmolality and in concentrations of Cl⁻ and Mg²⁺ took place during the first 2–3 days, after which it levelled off.
• 4.4. If exposed to sea-water at 1°C, however, marked increases were found for all parameters measured and all the fish were dead within 5 days of exposure.
• 5.5. These results show that freshwater-resident Arctic charr—if acclimated to brackish water—can survive in sea-water during summer if the environmental temperature is not too low.

     

Comparative studies of sodium transport and its relation to hydrostatic pressure in deep and shallow water gammarid crustaceans from Lake Baikal

• 1.1. Freshwater gammarids from 900–1400 m depths lose Na at 1 atm, 4°C, while related shallow water gammarids are near neutral Na balance.
• 2.2. Na⁺ influx rates are similar at 1 atm, 4°C, for abyssal and shallow water gammarids of similar weight.
• 3.3. Na⁺ efflux is faster for abyssal gammarids than for comparable shallow water gammarids.
• 4.4. Compressing abyssal gammarids to 90–140 atm increases Na⁺ influx rates enough to restore neutral Na balance, while in shallow water crustaceans, compression decreases Na⁺ influx.
• 5.5. Na⁺ influx rates in Baikalian gammarids vary with the 0.55 power of weight.
• 6.6. The equation F_{ma × t} = 1.3 × W^0.55 μEq/hr/animal applies to freshwater crustaceans over the weight range from 0.03 to 35 g.

     

Water fluxes and urine production in blue crabs (Callinectes sapidus) as a function of environmental salinity

• 1.1. Water efflux and urine production rates were measured in blue crabs acclimated to several salinities.
• 2.2. In 100% seawater the mean rate of water efflux (31.3 ml/100g hr⁻¹) was significantly greater than that in 50% seawater (18.9 ml/100 g hr⁻¹.
• 3.3. Water efflux was directly related to body weight.
• 4.4. The mean urine production rate was significantly greater in crabs acclimated to 50% and 30% seawater (0.17 and 0.18 ml/100g hr⁻¹) than in animals conditioned to 100% seawater (0.09 ml/100 g hr⁻¹).
• 5.5. The difference between theoretical net water fluxes for crabs exposed to 100% seawater and 50% seawater was similar to the difference in urine output in the same salinities, demonstrating the importance of the antennal gland in volume regulation.

     

Metabolism in malleefowl (Leipoa ocellata)

• 1.1. Malleefowl Leipoa ocellata have a lower than predicted metabolic rate, a finding common to many arid adapted avian species.
• 2.2. Evaporative water loss was as expected by allometric analysis. However, in the wild this species probably reduces its evaporative water loss because their water turnover rate is extremely low.
• 3.3. Malleefowl coped with temperatures up to 40°C well, but above this temperature they become highly agitated.

     

Correlation of water translocation,cuticle dehydration and post-ecdysial sclerotization by the american cockroach

• 1.1. Haemolymph volume decreases during the initial 16 hr post-ecdysial period, increases after water ingestion and subsequently drops until the inter-ecdysial level is reached.
• 2.2. Total body water follows a similar pattern, but the changes are not as pronounced.
• 3.3. Tissue water is inversely proportional to the total body water.
• 4.4. Soluble cuticle protein declines throughout the initial 16 hr period while both β-glucosidase and alkaline phosphatase activity is lost within 6 hr after ecdysis.
• 5.5. Dehydration of the cuticle also occurs during the immediate 6 hr post-ecdysial period.
• 6.6. These data suggest that the formation of the protein-insoluble matrix is linked with water loss.
• 7.7. Water removal may decrease the distance between molecules allowing specific reactions to take place.

     

Heart rates of adult red-spotted newts,Notophthalmus viridescens in air and submerged in normoxic and hypoxic water at different temperatures

• 1.1. Heart rates of adult aquatic red-spotted newts can be conveniently recorded using an impedance pneumograph.
• 2.2. Heart rates decrease linearly with decreasing temperature.
• 3.3. Submergence in normoxic and hypoxic water at 10°, 15°, and 20°C results in bradycardia which is more pronounced in hypoxic water.
• 4.4. At 5°C one newt exhibited the above pattern, but bradycardia was not exhibited by the other newt during normoxic submergence.
• 5.5. Diminishing heart rates are probably due to oxygen deficiency, not immersion alone.
• 6.6. Recovery from bradycardia in air is rapid and not linked with resumption of aerial breathing.

     

Renal response to hypoxia in carp,Cyprinus carpio: Changes in glomerular filtration rate,urine and blood properties and plasma catecholamines of carp exposed to hypoxic conditions

• 1.1. Changes in glomerular nitration rate (GFR), urine and blood properties and plasma catecholamines of carp were investigated during and following hypoxia.
• 2.2. GFR and urine flow decreased with increased urinary concentrations of bio-components, except protein, in the course of hypoxia.
• 3.3. Decreases in blood pH, and increases in haematocrit value and plasma K⁺, Ca²⁺, Mg²⁺, inorganic phosphate (P_i), ammonia, lactic acid and catecholamines (CAs) were observed as hypoxia progressed.
• 4.4. Increased GFR and urine flow, and higher values for urinary components, except protein, compared with those of the control were found in the initial post-stress stage.
• 5.5. The possible significance of increased plasma CAs in relation to changes in renal function in hypoxic carp is discussed.

     

Physically modeling operative temperatures and evaporation rates in amphibians

• (1)We designed a physical model that simulates the thermal and evaporative properties of live Western toads (Bufo boreas).
• (2)In controlled tests, the model tracked the body temperature of live toads with an average error of 0.3±0.03 °C (test range=4–30 °C).
• (3)It estimated the evaporative water loss of live toads with an average error of 0.35–0.65  g/h, or about 14% (test range=0.7–9 g/h).
• (4)Data collected with this physical model should provide an effective way for biologists to better understand habitat selection in toads and other amphibians

     

Serum ions concentration and atpase activity in gills,kidney and oesophagus of european sea bass (Dicentrarchus labrax,pisces, perciformes) during acclimation trials to fresh water

• 1.1. Kidney, oesophagus and gill Na⁺-K⁺ ATPase activity and serum Na⁺, K⁺ and Cl⁻ concentrations are evaluated in European sea bass during experimental acclimation to fresh water.
• 2.2. Kidney and oesophagus ATPase increase in low salinity and reach a maximum in fresh water.
• 3.3. Gill ATPase decreases during the acclimation trials and rises again to normal values after a 3-week stay in fresh water.
• 4.4. Na⁺ and K⁺ serum concentrations decrease during the trials and increase back after a 3-week stay in fresh water.
• 5.5. The correlations between enzymatic activities, serum ion concentrations, morphological changes and environmental salinity are discussed.

     

Comparative water balance in two species of Liomys (Rodentia: Heteromyidae)

• 1.1. Water metabolism in Liomys irroratus and L. pictus was studied by measuring water loss and gain by several routes.
• 2.2. Urine concentrations and fecal water contents were similar in the two species; L. pictus experiences significantly higher evaporative water loss than does L. irroratus.
• 3.3. Observed differences in water loss between the two species are largely a function of parameters related to weight-specific metabolic rate; the differential water losses are offset by differences in metabolic water production and ease of obtaining free water, so that the two species appear equally capable of attaining water balance.
• 4.4. The physiological characteristics of these two species are discussed relative to their respective ecological distributions and to a current hypothesis about the evolution of Liomys.

     

Effects of water stress on hemolymph volume,osmotic potential and chemical composition in Megetra cancellata

• 1.1. Rates of water loss in Megetra cancellata were very high compared to those reported for other xeric arthropods.
• 2.2. Hemolymph weight in hydrated animals was 43.0% of the total body weight while it was 24.7% in desiccated animals that had lost 16.1% of their body weight as water.
• 3.3. Hemolymph osmotic potential increased from 417 to 447 mOsm/kg in desiccated beetles, but osmotic regulation was evident.
• 4.4. Total hemolymph protein mass and concentration decreased in desiccated beetles while amino acid concentrations remained constant (at about 70 mM).
• 5.5. Na⁺ and −PO₄ concentrations increased in desiccated beetles.
• 6.6. Cl⁻ and K⁺ concentrations in desiccated beetles were equal to those in undesiccated beetles.

     

Fluxes of dissolved amino acids between sea water and Echinaster

• 1.1. Measurement of free amino acid (primary amine) influx and efflux into the starfish, Echinaster, were accomplished utilizing improved methods of sea water purification and analysis.
• 2.2. Specimens placed in amino acid depleted sea water (5 × 10⁻⁸ M) demonstrated net release as measured with the fluorescamine method. Similarly, specimens placed in the same water to which amino acid mixtures had been reintroduced to normal levels demonstrated net uptake.
• 3.3. A mathematical model indicated an equilibrium amino acid concentration (when influx equals efflux) of 5.26 × 10⁻⁷ M, or about one fourth the level of natural sea water.
• 4.4. Since at normal environmental levels (20.65 × 10⁻⁷ M) net flux is inward by a ratio of nearly 4-1, it is concluded that the previous suggestions of some workers that such would not be the case for marine invertebrates are no longer valid.
• 5.5. The net uptake of amino acid from environmental levels would account for 5.67% of the measured total respiration if all were being metabolized.
• 6.6. This figure appears to be in line with the previously developed hypothesis that the epidermis largely obtains its nutrition directly from the environment. However, the real benefit of the uptake mechanism may be to prevent loss of the body amino acid pools.

     

Electrolyte changes,cell volume regulation and hormonal influences during acclimation of rainbow trout (Salmo gairdnerii) to salt water

• 1.1. Rainbow trout were acclimated to salt water (1.5, 2.0 or 3.0%, which means 40, 60 or 85% concentrated sea-water) and the electrolyte, glucose and cortisol concentrations of the plasma as well as the extra- and intracellular muscle space, the muscle electrolyte concentrations and the ATPase activity were analysed.
• 2.2. Plasma osmolality, Na⁺, Ca²⁺ and Mg²⁺ concentrations of the plasma had a maximum at 24 hr after the start of acclimation when acclimated to 3.0% salt water. Plasma osmolality, Na⁺ and Mg²⁺ concentrations were significantly higher during the whole acclimation time when exposed to 3.0% salt water.
• 3.3. Variations and regulations of ECS and ICS were clearly demonstrated. The intracellular electrolyte concentrations were also maximal at 24 hr.
• 4.4. The plasma glucose level was just slightly elevated, but the cortisol level clearly indicated a stress response at 24 hr.
• 5.5. The activity of gill Na-K-ATPase increased during the acclimation time.
• 6.6. The regulatory processes in trout during acclimation to salt water are compared with those occurring in tilapia and carp.

     

Metabolic responses of Cassin's Finches (Carpodacus cassinii) to temperature

• 1.1. The thermal neutral zone of Cassin's Finches extends from 22 to 37.5°C.
• 2.2. Standard metabolism (40.1 Wm⁻² or 7.6kcal bird⁻¹ day⁻¹) of the 28 g birds was 89% of the value predicted for passerines measured at night.
• 3.3. At temperatures below the zone of thermal neutrality metabolism is described by the relation, Wm⁻² = 1.55–74.5°C. The coefficient of heat transfer (1.55Wm⁻²°C⁻¹) is only 58% of the value predicted for birds of this size, indicating excellent insulation.
• 4.4. At temperatures above thermal neutralzfsity metabolism is described by the relation, Wm⁻² = 2.75–62.6°C.
• 5.5. Under conditions of heat stress (44.5°C; P_H2O = 8.6 Torr) Cassin's Finches were able to dissipate up to 208% of their metabolic heat production by evaporative water loss. Maximal rate of water loss was 56 mg g⁻¹ hr⁻¹.
• 6.6. At 20°C resting fasted finches lost a mean of 4.94 ± 1.5 SD mg H₂O g⁻¹hr⁻¹.