Plasma osmolality, urine composition and tissue water content of the toad Bufo viridis Laur. in nature and under controlled laboratory conditions

The compositions of plasma and urine were studied in toads (Bufo viridis) which were collected from three locations in Israel, and compared with toads which were kept under constant laboratory conditions for nearly 2 years. Plasma osmolality was rather constant (over 310 mOsm kg-1 H2O) during the whole year in the active toads. Urea was the most variable osmolyte in the plasma, and accounted for the higher osmolality in southern population. Urine osmolality fluctuated in a circannual fashion both in freshly captured and in the toads under constant laboratory conditions. Water content of the tissues was constant throughout the year, independent of the plasma osmolality. It is concluded that high plasma urea concentration and the excretory system (kidneys and the urinary bladder) are important in sustaining constant plasma osmolality in active toads. Both mechanisms change annually and form the basis for the high terrestriality of this species.     

Volume regulation in salt-acclimated toad (Bufo viridis): the role of urea and the urinary bladder

Body water (weight) was studied in the euryhaline toad Bufo viridis during high salt (500 mOsm NaCl) acclimation. Plasma osmolality was greatly increased upon salt acclimation mainly by urea, and was always hyperosmotic to the ambient solution. Water content was regulated quite efficiently in slowly acclimated undisturbed toads. Repeatedly catheterized toads behaved like osmometers when transferred to hyperosmotic solutions. Total urea loss was greatly reduced in salt acclimated toads, suggesting urine was not voided under these conditions. It is concluded that urea accumulation, inhibition of the urine voiding response and the urine in the bladder are the principal factors involved in volume regulation under conditions of salt acclimation.     

Effects of changes in plasma hepatic-portal and systemic osmolality on plasma concentrations of arginine vasopressin in conscious newborn calves

Systemic plasma concentrations of arginine vasopressin (AVP) were studied in three groups of 10-15 day-old conscious newborn calves. Animals in the first group (control group) and in the second group (systemic-hypertonic-injected group) received respectively isotonic and hypertonic (8 mmol NaCl/kg body weight) saline injection into the right jugular vein. Animals in the third group were fitted with chronic mesenteric and hepatic-portal catheters and received a 1 h-hypertonic saline infusion (2 mmol NaCl/kg body weight) into the main mesenteric vein. In animals in the second group there were parallel increases in systemic plasma concentration of Na+ (from 148.0 +/- 2.6 to 177 +/- 8 mmol/l; P less than 0.01), osmolality (from 289 +/- 2 to 319 +/- 4 mOsmol/kg H2O; P less than 0.01) and systemic plasma concentrations of AVP (from 4.2 +/- 0.4 to 11.1 +/- 0.6 pmol/l; P less than 0.01) 10 min after the injection. There were no significant changes in control animals. Hypertonic saline infusion into the main mesenteric vein in the third group induced an increase in concentration of Na+ (from 147.3 +/- 2.0 to 165.0 +/- 5.0 mmol/l; P less than 0.01) and osmolality (from 288 +/- 5 to 315 +/- 10 mOsmol/kg H2O; P less than 0.01) in hepatic-portal vein plasma but did not alter systemic plasma osmolality or concentrations of Na+ and AVP. This study demonstrates that the relationship between plasma concentrations of AVP and systemic osmolality is operative in the newborn calf but does not support the hypothesis that hepatic portal osmo-receptors sensitive to hyperosmolality influence AVP release.     

Mechanisms of hyperosmotic acclimation in Xenopus laevis (salt,urea or mannitol)

The acclimation of the clawed toad Xenopus laevis to hyperosmotic solutions of NaCl (balanced solution of sea salt), urea or mannitol was studied. The animals could not be acclimated to salt solutions more concentrated centrated than 400 mosm·l^-1. Urea was tolerated till 500 mmol·l^-1. Plasma osmolality was always hyperosmotic to the environmental solution, but with diminished osmotic gradient at the highest tolerated solutions. Plasma urea concentration approached 90 mmol·l^-1, similar in the three solutions of acclimation. Urine volume was very small under all conditions. Serum aldosterone and corticosterone did not differ significantly, although there was a slight tendency towards lower aldosterone in the NaCl solution. In vivo water uptake in tap water acclimated animals was very small, and was higher in the other groups. Only the salt- and urea-acclimated, but not the tap water and mannitol-acclimated groups responded with a clear increase following injection of oxytocin or theophylline. In vitro urea fluxes were similar and invariable in both directions under all conditions. No significant effect of theophylline was observed. Sodium transport measured by the short-circuit technique in vitro was lower in salt- and mannitol-acclimation conditions, and was stimulated significantly under all conditions in response to serosal oxytocin or theopylline. It is concluded that Xenopus laevis can osmoregulate at a limited range of external solutions. It is limited in the increase of its plasma urea concentration; the transport properties of the skin do not change very much upon acclimation, except for the hydroosmotic response to oxytocin.Abbreviations I _sc short circuit current - PD potential difference - SW balanced sea water - TW tap water     

Elevated plasma osmotic concentration stimulates water absorption response in a toad.

The water-seeking behavior (WR) of toads (Bufo viridis) was investigated. Fully hydrated toads that are allowed free choice of wet or dry filter paper voluntarily and spontaneously select to sit on water-soaked paper at a regular frequency during trials. Dehydration of bladder-emptied toads by 14% elicits WR in all animals. Injection of aldosterone or angiotensin-I reduced the dehydration threshold to 7% weight loss. WR frequency increased when plasma osmolality was elevated by injection of NaCl or other solutes (both ionic and non-ionic). Only urea, to which cell membranes are highly permeable, was the exception that did not produce this response. The increase in WR frequency induced by elevated plasma osmolality was augmented by injection of aldosterone or angiotensin-I. In vivo water uptake, measured in a water bath, was increased by an NaCl or oxytocin injection, but not by aldosterone. It is concluded that elevated plasma osmolality induces an increase in WR frequency that is separate and prior to the water uptake process. Different hormones are involved in each step.     

Response of renal inner medullary epithelial cells to osmotic stress

As part of the urinary concentrating mechanism, renal inner medullary epithelial (IME) cells are normally exposed to variable and often very high interstitial levels of NaCl and urea, yet they survive and function. We have been studying the mechanisms involved, using an established cell line (mIMCD3). Acute increase of NaCl or urea from 300 to >500 mOsmol/kg causes cell cycle delay and apoptosis. High NaCl, but not high urea, causes DNA double strand breaks. At 500-600 mOsmol/kg inhibition of DNA replication following high NaCl depends on activation of the tumor suppressor protein, p53, and provides time for DNA repair. If p53 expression is suppressed, cells continue to replicate DNA, and many of those cells die. At higher levels of NaCl (>650 mOsmol/kg) the mitochondria rapidly depolarize and most cells die within a few hours despite a high level of p53 protein (which, however, is less phosphorylated than at 500 mOsmol/kg). Since the levels of NaCl and urea that kill mIMCD3 cells are much lower than those that exist in vivo, we investigated the difference, using early passage mouse IME cells under various conditions. Passage 2 IME cells survive higher levels of NaCl and urea than do mIMCD3 cells, but still not levels as high as in vivo. However, when the osmolality is increased linearly over 20 h, as occurs in vivo, rather than as a single step, cell survival increases to levels close to those found in vivo. We conclude that a more gradual increase in osmolality provides time for accumulation of organic osmolytes and activation of heat shock protein, previously known to be important for cell survival.     

Effects of osmolality and ions on the motility of stripped and testicular sperm of freshwater-and seawater-acclimated tilapia, Oreochromis mossambicus

A significantly higher concentration of testicular spermatozoa was obtained from freshwater Oreochromis mossambicus (9·9×10⁹ spermatozoa ml⁻¹) than seawater O. mossambicus (4·6×10⁹ spermatozoa ml⁻¹). The mean osmolality of the urine of freshwater fish (78·5 mOsmol kg⁻¹) was significantly different from that of seawater fish (304·8 mOsmol kg⁻¹). The mean length of the mid-piece of the spermatozoa together with the tail was more variable in freshwater O. mossambicus (8·80±0·23μm) than in seawater specimens (8·27±0·18 μm). Stripped sperm of freshwater O. mossambicus was highly contaminated by urine which was a good activator of sperm motility in O. mossambicus held in both fresh and sea water. The osmolality for initiation of motility in freshwater O. mossambicus spermatozoa was from 0 to 333 mOsmol kg⁻¹ while for seawater O. mossambicus spermatozoa it was from 0 to 1022 mOsmol kg⁻¹. The optimum osmolality for motility was from 70 to 333 mOsmol kg⁻¹ for freshwater O. mossambicus spermatozoa and from 333 to 645 mOsmol kg⁻¹ for seawater fish. In freshwater O. mossambicus spermatozoa, the presence of 20 mM CaCl₂ increased the permissive osmolality of NaCl from 184 to 645 mOsmol kg⁻¹. For seawater O. mossambicus spermatozoa, solutions of NaCl devoid of CaCl₂ were unable initiate motility, but the addition of 1·5 to 30 mM CaCl₂ to the NaCl solution (0–934 mOsmol kg₁) had a full motility initiating effect.     

Renal function at steady state in a toad (Bufo viridis) acclimated in hyperosmotic NaCl and urea solutions

Kidney function of the euryhaline toad Bufo viridis was studied in animals acclimated to tap water and solutions of NaCl (230 and 500 mosmol · kg^-1 H₂O) and urea (500 mmol · l^-1) in steady-state conditions. An ureter was eatheterized for continuous urine collection and blood was sampled from an iliac artery. A single injection of ³H-inulin served for estimation of glomerular filtration rate: this was in the range of 15–27 ml · kg^-1 · h^-1 and did not differ significantly in any of the acclimation conditions. Urine flow, on the other hand, varied considerably and was highest in tap water (18.2±3.2 ml · kg^-1 · h^-1; urine/plasma inulin ratio=0.88), lower in 230 mosmol · kg^-1 H₂O NaCl solution (13.5±3.9 ml · kg^-1 · h^-1; u/p inulin ratio=1.73) and lowest in 500 mosmol · kg^-1 H₂O NaCl or urea acclimation solutions (5–7 ml · kg^-1 · h^-1; u/p inulin=3.7–4.2). Clearance of free water was high in the tap water group, lower in 230 mosmol · kg^-1 H₂O NaCl solution, and much lower in the hyperosmotic acclimation conditions. Clearances of both Na⁺ and Cl^- were similar under our experimental conditions, but changed independently in accordance to the composition of the acclimation solution. Potassium clearance was similar in all acclimation conditions, and a constant plasma K⁺ concentration was maintained. Urea clearance was high in tap water and 500 mmol · l^-1 urea acclimation groups and low in the NaCl acclimations. The experiments show that the glomerular filtration rate remains more or less unchanged in all acclimation conditions, and suggest that the different rates of urine flow at steady state must be due mostly to tubular processes. The final composition of the urine is the result of specific and highly selective tubular processes.Abbreviations %T fractional reabsorbance - AVT argine vasotocin - C _{free water} free water clearance - C _osmol osmolyte clearance - GFR glomerular filtration rate - MS-222 methanetricaine sulphonate - U/P urine to plasma inulin ratio - V volume     

Water retention and plasma and urine composition in toads (Bufo viridis Laur.) under burrowing conditions

Summary Osmoregulation in the terrestrial toad,Bufo viridis, was studied under burrowing conditions in the laboratory. The toads can live for over 3 months burrowed in soil containing 9–10% moisture, maintaining constant body volume due to a large increase in the plasma osmolality, contributed mainly by urea. Water content of the tissues remains constant. Relatively large volumes of urine are stored in the urinary bladder during water restriction. The osmolality of the urine does not exceed that of the plasma. Urea uptake across the skin was measured in vitro and was greatly elevated in skins from the burrowed toads. The increase in plasma osmolality enables greater water absorption from the soil under water restricted conditions while the water content of the tissues is maintained constant since cell membranes are highly permeable to urea. It is concluded that the urea accumulating ability and urea tolerance form the basis for both the terrestriality and salt adaptability of this and other amphibian species.     

Effects of fresh and seawater ingestion on osmoregulation in Atlantic bottlenose dolphins (Tursiops truncatus)

Bottlenose dolphins (Tursiops truncatus) are marine mammals with body water needs challenged by little access to fresh water and constant exposure to salt water. Osmoregulation has been studied in marine mammals for a century. Research assessing the effects of ingested fresh water or seawater in dolphins, however, has been limited to few animals and sampling times. Nine 16- to 25-h studies were conducted on eight adult dolphins to assess the hourly impact of fresh water, seawater, and seawater with protein ingestion on plasma and urine osmolality, urine flow rate (ufr), urinary and plasma solute concentrations, and solute clearance rates. Fresh water ingestion increased ufr. Fresh water ingestion also decreased plasma and urine osmolality, sodium and chloride urine concentrations, and solute excretion rates. Seawater ingestion resulted in increased ufr, sodium, chloride, and potassium urine concentrations, sodium excretion rates, and urine osmolality. Seawater with protein ingestion was associated with increased ufr, plasma osmolality, sodium excretion, and sodium, chloride, potassium, and urea urine concentrations. In conclusion, bottlenose dolphins appear to maintain water and plasma solute balance after ingesting fresh water or seawater by altering urine osmolality and solute clearance. Ingestion of protein with seawater appears to further push osmoregulation limits and urine solute concentrations in dolphins.     

Urea production and accumulation in the green toad, Bufo viridis

The toad, Bufo viridis , can live for several months without access to free water, absorbing soil-bound water down a water-potential gradient created, mainly, by accumulating urea in its body fluids. We investigated if the retention of urine was sufficient to account for the rate of accumulation or if an increased rate of urea production was needed in order to do so. The basal rate of urea production in unfed animals in the absence of osmotic stress was estimated by two methods; first, analysis of the bathing medium and, secondly, collection and analysis of urine at two-hourly intervals. This was then repeated with animals fed a weight-maintaining diet. Generally similar results were obtained by either method in both fed and unfed animals, although higher urea production rates were found in the former. Although it had been planned to apply the short interval method to toads with free access to water, the control condition for toads transferred to soil, it proved to be impracticable. Some animals did not bathe for almost a day, during which time minute quantities of urine were obtained. Larger volumes were only produced during or after bathing. Consequently, animals which were partially immersed in water were substituted as controls. Total urea content was determined in these and in toads after a week on soil. The calculated increase was compared to that which could be expected from urine retention. It was found that urea accumulated at more than twice the predicted rate. When rates of accumulation were calculated over longer periods, urine retention alone was sufficient to account for them within three weeks on soil, the usual period required for acclimation. We concluded that B. viridis increased its rate of urea production only for a short period, until a favourable water potential gradient was achieved.     

Anuran amphibia which are not acclimable to high salt,tolerate high plasma urea

• 1.1. The capacity of five anuran Amphibians (Bufo viridis B. regularis, Rana ridibunda, Hyla arborea and Pelobates syriacus) to acclimate to NaCl and urea solutions was investigated.
• 2.2. All species could be acclimated to relatively high concentrations of urea solutions, while only Bufo viridis and Hyla arborea could be acclimated to 500 mOsm/kg or higher NaCl solutions.
• 3.3. The plasma urea concentration in B. viridis and H. arborea was elevated to levels over 140 mmol/1.
• 4.4. The sum of plasma sodium and chloride concentrations did not increase over 400 mmol/l in any species.
• 5.5. Urine osmolality, which was normally low, increased, but never exceeded the plasma osmolality.
• 6.6. In the urea acclimation conditions, urine electrolytes diminished, similarly in all species in this study.
• 7.7. It is concluded that anuran Amphibians can tolerate high plasma urea concentrations, but only those species which can elevate it, either through retention or net synthesis, can be acclimated to high salt solutions.

     

Role of urea in the postprandial urine concentration cycle of the insectivorous bat Antrozous pallidus

Insectivorous bats, which feed once daily, produce maximally concentrated urine only after feeding. The role of urea as an osmolyte in this process was investigated in pallid bats (Antrozous pallidus) in the laboratory. Following a 24-h fast, plasma and urine were sampled before and 2 h after feeding in postprandial (PP) animals and before and 2 h after similar treatment without feeding in nonfed (NF) animals. Food consumption by PP animals and handling of NF animals had no effect on blood water content as measured by hematocrit and plasma oncotic pressure. Food consumption increased both plasma osmolality (P(osm)) and plasma urea (P(urea)) by as much as 15%. Food consumption also increased urine osmolality (U(osm)) and urine urea (U(urea)) by 50-100%. Feeding increased U(osm) regardless of changes in P(osm), and elevation of U(osm) resulted primarily from increased U(urea). In NF bats, P(osm) and P(urea) were unchanged, while U(osm) and U(urea) increased by as much as 25%. Again, increased U(osm) resulted primarily from increased U(urea). The PP urine concentration cycle of pallid bats resulted from increased urea excretion in response to apparent rapid urea synthesis. Bats rapidly metabolized protein and excreted urea following feeding when body water was most plentiful.     

Fertilization environment of the non-copulating marine sculpin, Hemilepidotus gilberti

To clarify the extracellular environment for external fertilization in the non-copulating marine sculpin Hemilepidotus gilberti, sperm motility was measured in NaCl, KCl, mannitol solutions, seawater, and ovarian fluid. Spermatozoa of H. gilberti actively moved in seminal plasma the moment they were removed from the genital papilla. Spermatozoa showed higher motility in NaCl solution at osmolalities between 300–400 mOsmol kg^-1. In KCl and in mannitol solutions, spermatozoa actively moved at osmolalities between 500 and 800 mOsmol kg^-1, and at osmolality 300 mOsmol kg ^-1, respectively. The ovarian fluid was a transparent and viscous gelatinous material, rich in sodium with an osmolality of 340 mOsmol kg^-1. Sperm motility in the ovarian fluid lasted more than 90 min, which was six times longer than in seawater. This sperm motility under conditions isotonic to body fluid is similar to that of copulating marine sculpins rather than to other non-copulating marine fishes. In addition, eggs of H. gilberti could be fertilized in the ovarian fluid. This suggests that external fertilization takes place under physiological conditions similar to the internal conditions of the ovary provided by the ovarian fluid, which isolates the eggs from sea water for several hours after spawning. This manner of fertilization is thought to be one of the evolutionary pre-adaptations allowing copulation among marine sculpins.     

Maximum Urine Concentrating Capability in a Mathematical Model of the Inner Medulla of the Rat Kidney

In a mathematical model of the urine concentrating mechanism of the inner medulla of the rat kidney, a nonlinear optimization technique was used to estimate parameter sets that maximize the urine-to-plasma osmolality ratio (U/P) while maintaining the urine flow rate within a plausible physiologic range. The model, which used a central core formulation, represented loops of Henle turning at all levels of the inner medulla and a composite collecting duct (CD). The parameters varied were: water flow and urea concentration in tubular fluid entering the descending thin limbs and the composite CD at the outer-inner medullary boundary; scaling factors for the number of loops of Henle and CDs as a function of medullary depth; location and increase rate of the urea permeability profile along the CD; and a scaling factor for the maximum rate of NaCl transport from the CD. The optimization algorithm sought to maximize a quantity E that equaled U/P minus a penalty function for insufficient urine flow. Maxima of E were sought by changing parameter values in the direction in parameter space in which E increased. The algorithm attained a maximum E that increased urine osmolality and inner medullary concentrating capability by 37.5% and 80.2%, respectively, above base-case values; the corresponding urine flow rate and the concentrations of NaCl and urea were all within or near reported experimental ranges. Our results predict that urine osmolality is particularly sensitive to three parameters: the urea concentration in tubular fluid entering the CD at the outer-inner medullary boundary, the location and increase rate of the urea permeability profile along the CD, and the rate of decrease of the CD population (and thus of CD surface area) along the cortico-medullary axis.     

Predominant osmotically active organic solutes in rat and rabbit renal medullas

The mechanism that concentrates the urine to an osmolality several times that of systemic plasma results in high concentrations of solutes (particularly NaCl and urea) in extracellular fluid of renal medulla, but not in the labyrinth of the renal cortex. Intracellular and extracellular osmolality must be equal in animals, but the known intracellular levels of Na and K salts and urea in renal medullas are much too low to balance the high extracellular osmolality. The purpose of these studies was to identify the other intracellular osmolytes that must be present. Cortexes and medullas from rabbit and rat kidneys were analyzed by proton nuclear magnetic resonance, mass spectrometry, and chemical assays to determine the identity and amount of organic solutes. Large amounts of glycerophosphorylcholine, betaine, sorbitol, and inositol were found in both species localized almost exclusively to the inner medulla. In rabbits during antidiuresis glycerophosphorylcholine, betaine, and sorbitol were present in the inner medulla, at concentrations of 21.1, 34.8, and 20.8 mumol/g wet weight, respectively, but were not detected in the cortex. Inositol was present in rabbit inner medulla at 10.7 mumol/g wet weight and was also present in the cortex, but at lower concentration. None of the above metabolites was present in measurable amounts in urine or peripheral plasma. The accumulation in the cells of the inner medulla of relatively large amounts of betaine, sorbitol, glycerophosphorylcholine and inositol during antidiuresis suggests that they may play a significant role in the maintenance of intracellular osmotic balance.     

Physiological effects of saline waters on zander

Rapid transfer of zander Stizostedion lucioperca to hypoosmotic brackish water (mean osmolality 230 mOsmol kg–1 , c. 8 psu) significantly increased plasma chloride concentrations after 24 h compared to those transferred to fresh water, although plasma osmolality was not significantly affected. After 6 days, plasma osmolality was slightly elevated but stable plasma glucose and cortisol concentrations and blood haematocrit and haemoglobin suggest a lack of hormonal stress responses and resultant secondary effects. Rapid transfer of zander to a more saline environment, hyperosmotic to plasma (mean osmolality 462 mOsmol kg^‐1, c. 16 psu) induced a greater increase in plasma osmolality and chloride concentrations within 24 h, with a further rise after 6 days exposure, but all fish maintained a state of hypo‐osmoregulation both 24 h and 6 days after transfer. The initial osmotic disturbance (at 24 h) was accompanied by increased plasma glucose, blood haematocrit and haemoglobin and a decreased mean cell haemoglobin concentration (MCHC), suggesting an adrenergic stress response, but these parameters fully recovered within 6 days of exposure to this hyperosmotic environment with MCHC rising to exceed the level in freshwater fish. Zander did not survive rapid transfer to more hyperosmotic conditions (750 or 1001 mOsmol kg^‐1, 26‐35 psu), but they did survive exposure to simulated‘tidal cycles’ of rising and declining salinity, peaking after 6 h at c. 29 or 33 psu. Although osmotic disturbance was apparent after 6 h exposure and other physiological parameters suggested both adrenergic and corticosteroid components of a stress response, rapid recovery was apparent after return to fresh water. The results indicate that the zander, a non‐indigenous species in the U.K., has a high level of osmotic tolerance and a degree of hypo‐osmoregulation in saline environments not found in most stenohaline freshwater teleosts. This osmoregulatory ability could enable invasion of new U.K. river systems by using inshore marine environments of low salinity as saltwater bridges.     

Utilization of osmoprotective compounds by hybridoma cells exposed to hyperosmotic stress

A search was undertaken for osmoprotective compounds for mouse hybridoma cell line 6H11 grown in culture. When the osmolality of the growth medium was increased above the normal osmolality of 330 mOsmol/kg, growth rates were decreased in a dose-dependent fashion, reaching zero when the osmolality of the medium reached approx. 435 mOsmol/kg through the addition of KCl (60 mM), or 510 mOsmol/kg through the addition of NaCl (100 mM), or sucrose (175 mM). For NaCl or sucrose-stressed cultures, the inclusion of glycine betaine, sarcosine, proline, glycine, or asparagine in the growth medium gave a moderate to strong osmoprotective effect, measured as the ability of these compounds to enhance cell growth rates under hyperosmotic conditions. Inclusion of dimethylglycine may also give a strong osmoprotective effect under these stress conditions.In KCl-stressed cell cultures, addition of glycine betaine, sarcosine, or dimethylglycine gave strong osmoprotective effects. Of 38 compounds tested during NaCl stress, 7 gave weak osmoprotective effects and 25 gave no osmoprotective effect. The osmoprotective compounds accumulated inside the stressed cells. Accumulation was completed after 4 to 8 h, reaching intracellular concentrations of approx. 0.27 pmol/cell, or 0.15 M, in NaCl stressed cells (100 mM NaCl added).Glycine betaine, dimethylglycine, and sarcosine accumulation was observed only when these protectants were included in the medium. For all osmoprotectants, a growth medium concentration between 5 and 30 mM gave the maximal protective effect, with the exception of dimethylglycine, for which the optimum concentration was approx. 65 mM. Osmoprotective effects obtained with glycine, sarcosine, dimethylglycine, and glycine betaine, indicate that the more methylated compounds are the most effective protectants.The cellular content of glycine betaine and the glycine betaine uptake rate increased with medium osmolality in a linear fashion. Glycine betaine uptake was described by a model comprising a saturable component obeying Michaelis-Menten kinetics and a nonsaturable component. K(m) and V(max) for glycine betaine uptake were determined at 420 mOsmol/kg (50 mM NaCl added) and 510 mOsmol/kg (100 mM NaCl added). A K(m) value of approx. 2.5 mM was obtained at both medium osmolalities, while V(max) increased from 0.010 pmol/cell . h to 0.018 pmol/cell . h as the osmolality of the growth medium was increased, indicating an effect of medium osmolality on the maximal rate of transport rather than on the affinity of the transporters for glycine betaine. Hybridoma cells were not able to utilize the glycine betaine precursors choline or glycine betaine aldehyde for osmoprotection, suggesting that the cells lack part, or all, of the choline-glycine betaine pathway or the appropriate uptake mechanism.The uptake rate for glycine in NaCl-stressed hybridoma cells was approx. four times higher than the uptake rate for glycine betaine. Furthermore, if equimolar amounts of glycine betaine, glycine, sarcosine, and proline were simultaneously added to NaCl-stressed cell cultures, the intracellular concentrations of glycine, proline, and sarcosine were significantly higher than the concentration of glycine betaine.A 40% increase in hybridoma cell volume was observed when the growth medium osmolality was increased from 300 to 520 mOsmol/kg. (c) 1994 John Wiley & Sons, Inc.     

The effect of infusion of hypertonic saline on glomerular filtration rate and arginine vasotocin, prolactin and aldosterone in the domestic chicken

Domestic fowl were infused for 60 min with isotonic saline followed by 90 min with hypertonic saline. Plasma electrolyte concentrations, osmolality and haematocrit were measured. Urine electrolyte excretion rates, osmolar output and urine flow rates were also monitored. From these results fractional excretions of electrolytes were calculated. The renal function markers inulin and ρ-amino hippuric acid were infused to enable the measurement of glomerular filtration rate and plasma clearance of ρ-amino hippuric acid, respectively. Plasma samples were also taken to assay for the hormones prolactin, aldosterone and arginine vasotocin. Plasma electrolytes and osmolality, fractional excretion of electrolytes and osmolar output all increased, while haematocrit decreased, throughout the experiment. However, no significant change was found in urine flow rate and little change was seen in glomerular filtration rate. The clearance of ρ-amino hippuric acid, which provides an indication of renal plasma flow, increased during hypertonic saline infusion. Plasma concentrations of aldosterone and prolactin decreased during the experiment and plasma concentrations of arginine vasotocin increased. Infusion of hypertonic saline had no consistent effect on glomerular filtration rate, which may be due to conflicting influences of expansion of the extracellular fluid volume and increased plasma osmolality. Accepted: 19 January 1998     

Culture-induced changes in osmolality of tobacco cell suspensions using four exogenous sugars

Suspension cultures of tobacco cells were grown in B5 media supplemented with sucrose, glucose, mannitol and sorbitol as exogenous sugars to examine culture-induced changes in the osmolality of the medium. Osmolality decreases were greatest in sucrose and glucose media during the 14 days in culture, and in glucose media were essentially linear, presumably reflecting the use of this sugar as a food source. Osmolality decreases occurred during the first week of culture in mannitol- and sorbitol-supplemented media, but later stabilized. Fresh weight of cultured cells in sucrose- and glucose-supplemented media increased by <200% during 14 days in culture, whereas cultured cells in mannitol- and sorbitol-supplemented media increased by only 39 and 48%, respectively. Cells transferred to the original liquid medium (B5 medium with 3% sucrose and 3% glucose) grew vigorously if they had been cultured in sucrose- and glucose-supplemented media; however, cells grown in mannitol- and sorbitol-supplemented media needed to be subcultured several times to recover their normal growth rate. By subculturing cells into increasingly higher conditions of sugars, cells tolerant to 560 mOsmol kg-1 H2O were obtained. The high osmolality-adapted cells increased by 140% in fresh weight in 8% glucose-supplemented medium. Glucose was best suited for producing the high osmolality required because sucrose concentrations at 10% sucrose and above resulted in cell death. To limit the decrease of osmolality in these suspension cultures requires changing the medium every 3 days to maintain osmolality above the 530 mOsmol kg-1 H2O needed to co-culture these as feeder cells with gametic and zygotic cells. This revised version was published online in June 2006 with corrections to the Cover Date.