Splenic respiratory compensation and blood volume in the newt

In the newt Triturus cristatus carnifex , reversible increase in size of the spleen is linked to the respiratory state of the animal: when the newt is exposed to the air, and thus well oxygenated, the spleen hoards erythrocytes; when immersed in still water, in an hypoxic state, the spleen releases erythrocytes into the bloodstream. In chlorobutanol-anaesthetized specimens exposed to the air, the maximum size reached by the spleen diminishes with a rise in temperature up to the disappearance of all congestion at 33°C. The blood volume of newts kept in humid air at 6°C and 18°C after anaesthesia varies from about 6–9 ml per 100 g of body weight, while the red blood cell count and haematocrit value remain stable. In anaesthetized specimens kept in still water at the same temperatures the blood volume is stable, at about 7 ml per 100 g, but the red cell count and haematocrit are notably higher. At 33°C, a critical temperature for the newts, the specimens in still water succumb while those in air present the same blood volume as at 18°C, but have a higher erythrocyte count and haematocrit value.     

Hepatic respiratory compensation and blood volume in the frog (Rana esculenta)

In the frog, Rana esculenta (L.), the liver can change in volume by over 25%, depending on the respiratory conditions of the animal: in well-oxygenated specimens the organ can hoard about half of the total amount of erythrocytes in its sinusoids, and release them into the bloodstream under conditions of hypoxia. This phenomenon can be observed at a temperature of 6°C by comparing the liver volumes and haematic values of chlorobutanol-anaesthetized animals exposed to the air or submerged in still water (a condition which induces hypoxia): the blood volume remains constant, at about 5 ml per 100g of body weight, but red blood cell count and haematocrit value differ by as much as 50%. At 18°C there is an increase in oxygen demand and in anaesthetized animals, which rely totally on cutaneous respiration, the compensatory liver mechanism can no longer be observed, since all the available erythrocytes are already circulating in a blood volume which, depending on respiratory conditions, can vary between about 7 and 8ml/100g. At 30°C, cutaneous respiration alone does not allow the anaesthetized animals to survive long enough to stabilize their haematic parameters.     

The role of the liver in the cutaneous respiratory compensation of the frog (Rana esculenta)

Experiments on anaesthetized specimens of Rana esculenta (L.) demonstrate that at low temperatures (6°C) the liver of the frog-like the spleen of the newt-regulates cutaneous respiration, storing red blood cells when the animal is well oxygenated and releasing these into circulation under conditions of hypoxia. During the shift from the congested to decongested state, the liver is reduced to about two-thirds of its weight, while the erythrocyte concentration and correlated parameters in the bloodstream can increase by more than 50%. At higher temperatures (18°C) this compensatory mechanism becomes inefficient and the liver oversees the survival of the hypoxic organism for a fairly long period of time (about 5 hours) by releasing glucose for anaerobic glycolysis.     

Temperature-dependence of cardiac output and regional blood flow in rainbow trout, Salmo gairdneri Richardson

Cardiac output, blood flow distribution and regional perfusion were determined in free-swimming rainbow trout acclimated to 6, 12 and 18°C, using the indicator dilution and microsphere methods. Cardiac output (ml min⁻¹ kg⁻¹) increased linearly with increasing temperature, while circulation time decreased. Blood flow distribution (% of cardiac output) to the spleen, liver, kidney, gall bladder and gastro-intestinal tract was significantly reduced at 18°C relative to 6°C-acclimated fish. White muscle received the largest fraction of cardiac output, and blood flow distribution to white muscle increased significantly with increasing acclimation temperature. Blood perfusion (ml h⁻¹ g⁻¹) of various organs and red muscle was not influenced by acclimation temperature, while white muscle perfusion increased with increasing temperature. These results demonstrate physiological adaptation of the cardiovascular system of rainbow trout to changes in acclimation temperature.     

Plasma osmolarity, glucose concentration and erythrocyte responses of two Antarctic nototheniid fishes to acute and chronic thermal change

Haematocrit, haemoglobin concentration, plasma osmolarity and plasma glucose concentration of the Antarctic nototheniid fishes Pagothenia borchgrevinki and Trematomus bernacchii were monitored during 24 h periods of exposure to 3 and 6° C. The same haematological variables were also measured in P. borchgrevinki following a 5–6 week period of 4° C acclimation. The first plasma glucose measurements in acutely thermally‐stressed Antarctic nototheniids revealed a delayed hyperglycaemia which related well to the relatively slow stress‐related elevation of plasma cortisol in these species. Plasma osmolarity of both species was unchanged by acute 3° C exposure, but exhibited a delayed and transient increase during acute exposure to 6° C. Haematocrit was unaltered in T. bernacchii during the acute temperature increases but was elevated in the relatively active P. borchgrevinki . Following 5–6 weeks of warm‐acclimation (4° C) the plasma glucose concentration, haematocrit and haemoglobin concentration of P. borchgrevinki were not significantly different from fish at −1° C, but plasma osmolarity decreased toward the level found in temperate‐water teleosts.     

The stress and metabolic responses of juvenile Atlantic cod Gadus morhua L. to an acute thermal challenge

Survival, oxygen consumption (     ), total plasma cortisol and glucose levels and gill heat-shock protein 70 (hsp70) expression were measured in 10 and 50 g juvenile Atlantic cod Gadus morhua during an acute temperature increase (2° C h⁻¹) to their critical thermal maximum. Ninety three per cent of the fish in both size classes survived to 24° C; however, mortality was 100% within 15 min of reaching this temperature. The     for both size classes increased significantly with temperature, reaching peak values at 22° C that were c. 2·8-fold those of control (10° C) fish. Resting plasma cortisol and glucose levels were lower in 10 g as compared to 50 g fish. Plasma glucose levels were highly variable in both size classes, and significant increases were only seen at >22° C for the 10 g fish. In contrast, plasma cortisol showed an exponential increase with temperature starting at 16° C in both size classes, and reached maximum levels at 22° C that were 19-fold (10 g fish) and 35-fold (50 g fish) higher than their respective control groups. Both the constitutive (73 kDa) and inducible (72 kDa) isoforms of hsp70 were detected in both size classes using the widely utilized mouse monoclonal antibody. Expression of these isoforms, however, did not change when Atlantic cod were exposed to elevated temperature, and the 72 kDa isoform was not detected using salmonid-specific antibodies. These results indicate that juvenile Atlantic cod are very sensitive to acute increases in water temperature. In addition, they (1) show that     and plasma cortisol, but not plasma glucose or gill hsp 70 levels, are sensitive indicators of thermal stress in Atlantic cod and (2) support previous reports that the upper critical temperature for this species is 16° C.     

Storage of marine fish erythrocytes in liquid nitrogen

The preservation of erythrocytes from cod ( Gadus morhua ), saithe ( Pollachius virens ) and mackerel ( Scomber scombrus ) at −196° C was studied using dimethyl sulphoxide (DMSO) as a cryoprotectant. Erythrocyte recoveries of greater than 90% were obtained from all species and cod erythrocytes were stored for eighteen months with insignificant lysis. Larger quantities of blood were stored by removal of plasma from citrated blood prior to the addition of DMSO solution, and by storage of pelleted frozen blood in aluminium canisters in liquid nitrogen. Maximum recoveries of washed intact erythrocytes required thawing of pellets in 125% DMSO solution and washing with buffer containing decreasing concentrations of DMSO. Washed erythrocytes kept at 4° for at least two days showed little haemolysis, were morphologically similar to fresh erythrocytes and equally susceptible to the δ-haemolysin of Staphylococcus aureus .     

Temperature comparisons for antibody production in vitro by plaque-forming cells from trout, Salmo gairdneri (Richardson), and mice

Anterior kidney and splenic cells were taken from rainbow trout and splenic cells from BALB/c mice immunized with a T-dependent (sheep red blood cells) or T-independent (DNP-Ficoll) antigen. The cells were incubated at different temperatures in Jerne plaque assays (direct or passive haemolytic plaque assays). The optimum numbers of in vitro plaque-forming cells (PFC) after incubation with homologous complement were directly correlated with normal body temperatures of the respective species. The optimum incubation temperature was 37°C for mouse cells and 10°C for fish cells. Incubation of mouse cells at lower temperatures of 30, 20, 10, 4 or 0°C appeared to yield a direct line reduction in numbers of PFC. Trout cells developed significantly fewer PFC at 4 and 20°C and none at 30°C or above; however, significant numbers still appeared at 0°C. More PFC per million white blood cells were obtained from the anterior kidney; however, related to temperatures, no differences in development of numbers of PFC could be seen between the spleen and anterior kidney cells of trout. When the incubation time was lengthened for both trout and mouse cells held at low temperatures, the numbers of PFC approached those of the cells incubated at the optimum temperatures for 10 h.     

Endocrine, osmoregulatory, respiratory and haematological parameters in flounder exposed to the water soluble fraction of crude oil

Flounders Pleuronectes flesus with an implanted vascular catheter were exposed to a 50% dilution of the water soluble fraction (WSF) of Omani crude oil (c. 6ppm total aromatic hydrocarbons) and serial blood samples taken to determine their endocrine status (cortisol, catecholamines and thyroid hormones) and the resultant and/or causal physiological (haematological, ionoregulatory and respiratory) disturbances. This resulted in a progressive increase in plasma cortisol concentrations from 3 h onwards (rising from 18 to 51 ng ml⁻¹ after 48-h exposure), and increased plasma glucose concentrations indicating a generalized stress response. Plasma T3 and T4 concentrations of both control and WSF-exposed groups declined progressively over the experimental period; exposure to the WSF of crude oil further depressed plasma T4 concentrations but not plasma T₃ concentrations relative to those of control fish. Plasma osmolality and sodium and chloride concentrations were stable in WSF-exposed fish, however, plasma potassium concentrations were increased significantly at the 24-and 48-h sampling points. The most profound physiological disturbance in WSF-exposed fish was a dramatic decline in blood oxygen content (CvO₂) (from 2–8 to 0–8 ml 100 ml⁻¹ after 48-h exposure), which is likely to be the cause of the increased plasma noradrenaline concentrations from 3 h onwards. Increased noradrenaline is likely in turn to have been responsible for the significant increase in blood haematocrit and blood haemoglobin at the 3-h sampling point, although the dominant effect in the longer-term was a significant decline in both of these haematological parameters.     

Body temperature and seawater adaptation in farmed Atlantic salmon and rainbow trout during prolonged chilling

The core temperature of the rainbow trout Oncorhynchus mykiss (3·5 kg) dropped to 1·0° C during the first 6 h of chilling at 0·5° C, remained stable until 24 h, and dropped significantly to 0·7° C after 39 h. Blood plasma osmolality increased and muscle moisture content decreased gradually with increasing chilling time. After 39 h of chilling, the rainbow trout experienced 40 mosmol l^-1 higher blood plasma osmolality and 2·8% less muscle moisture content compared with initial values. In the Atlantic salmon Salmo salar (5·3 kg), core temperature dropped to 1·3° C and blood plasma osmolality increased significantly during the first 6 h of chilling at 0·5° C, but remained relatively stable throughout the rest of the experimental period. After 39 h of chilling, the salmon experienced 20 mosmol l^-1 higher blood plasma osmolality and 0·5% less muscle moisture content compared with initial values. In rainbow trout muscle moisture content was inversely related to blood plasma osmolality indicating reduced seawater adaptation with increasing hours of chilling. No such relationship was observed in the Atlantic salmon. Hence, changes in plasma osmolality and muscle moisture in the Atlantic salmon do not indicate osmoregulatory failure since the new levels, once established, were maintained throughout the chilling time.     

The protective effect of some food ingredients on Staphylococcus aureus MF31

The upper limiting temperature of growth of Staphylococcus aureus MF31 in heart infusion broth (HI) was about 44°C but addition of monosodium glutamate (MSG) and soy sauce permitted the organism to grow above this temperature. This effect is similar to that of NaCl. Tomato ketchup, Worcestershire and HP sauces added to HI did not allow growth at the non-permissive temperature of 46°C but death was delayed. Staphylococcus aureus died in unsupplemented chicken meat slurry at 46°C but grew at 48°C in slurry supplemented with 5.8% NaCl and survived incubation for 18 h at 50°C in slurry supplemented with 5.8% NaCl and 5% MSG. Cultures grown at 37°C had a D ₆₀ value of 2 min in 50 mmol/l Tris (pH 7.2) buffer. Cultures grown at 46°C in HI containing 5.8% NaCl had a D ₆₀ value of 8 min in Tris buffer. Addition of 5.8% NaCl plus 5% MSG to the buffer increased the D ₆₀ by a factor of about 7 for both cultures. In storage experiments at room temperature, the culture grown at 37°C and at 46°C plus 5.8% NaCl died at about the same rate in salami. In milk powder, however, the count of 37°C culture decreased from 10⁹/g to 10⁶/g in 5 weeks while the count of 46°C culture remained unchanged. In cottage cheese, freeze-dried rice and macaroni, the 37°C cultures also died more rapidly. It is suggested that cultures grown at 46°C plus 5.8% NaCl may be suitable for experiments with artificially contaminated foods.     

Homeostatic regulation of acetazolamide-sensitive esterase activity in the bluegill sunfish, Lepomis macrochirus, following acute cold shock

Acetazolamide-sensitive esterase activity was elevated in branchial homogenates of control juvenile bluegill sunfish, Lepomis macrochirus , acclimated at 20° C but decreased rapidly within 9 h following an acute hypothermal shock to 8° C. After 2 weeks at 8° C, shocked-fish enzyme activity was similar to control fish. At 20° C acclimation temperature, specific activity of bluegills was similar in swimbladder, liver, kidney, gill, spleen, and gonad homogenates and was significantly higher (α=0.05 level) in whole blood homogenates. The pH optima for enzymes extracted from fish acclimated at 20° and 8° C were 7.29 and 8.00, respectively. Polyacrylamide gel electrophoresis (PAGE) demonstrated two distinct forms of acetazolamide-sensitive esterase activity present in both 20° and 8° C acclimated fish. Specific activity for homogenates from both 20° and 8° C acclimated fish differed significantly when assayed at 20° C, suggesting both qualitative and quantitative changes in acetazolamide-sensitive esterase. It is postulated that relatively rapid alterations in esterase activity promote survival in bluegill following acute cold shock through the central role of enzymes in the regulation of plasma ion concentrations and acid/base equilibria.     

Temperature-induced changes of survival, development and yolk partitioning in Chondrostoma nasus

Fertilized Chondrostoma nasus eggs were incubated at 10, 13, 16 and 19° C until full resorption of the yolk sac. High survival was observed at 10–16° C (89–92% at the onset of external feeding), whereas at 19) C survival was depressed (76%). The time at which 5, 50 and 95% of individuals had hatched, filled the swim bladder, ingested the first food and fully resorbed the yolk sac was determined. An increase in temperature accelerated development and made it more synchronous. Within the period from fertilization to hatching embryonic development was theoretically arrested (t_{0 dev}) at 8·8° C, and growth was arrested (t_0gr) at 8·86° C. For the whole endogenous feeding period (from fertilization to full yolk resorption) the amount of matter transformed into tissue was temperature independent between 10° and 19° C. Respiration increased exponentially with age; the respiration increase was faster at higher temperatures, but, in general, metabolic expenditures of C. nasus were low. As a consequence, the efficiency of utilizing yolk energy for growth was high as compared with other fish species (57% during the whole endogenous feeding period); it was temperature independent. However, time was used less efficiently at low temperatures, increasing a risk of predation. Within the endogenous feeding period a shift from lower to higher temperatures for optimal yolk utilization efficiency was observed. The temperatures optimal for survival and energetic performance seem to be 13–16° C for egg incubation and 15–18° C for rearing of yolk-feeding larvae. Chondrostoma nasus is a potential candidate for aquaculture for restocking purposes.     

Cardiovascular and splenic responses to exercise in humans.

To investigate splenic erythrocyte volume after exercise and the effect on hematocrit- and hemoglobin-based plasma volume equations, nine men cycled at an intensity of 60% maximal O(2) uptake for 5-, 10-, or 15-min duration, followed by an incremental ride to exhaustion. The reduction in spleen volume, calculated using (99m)Tc-labeled erythrocytes, was not significantly different among the three submaximal rides (5 min = 28%, 10 min = 30%, 15 min = 36%; P = 0.26). The incremental ride to exhaustion resulted in a 56% reduction in spleen volume, which recovered to baseline levels within 20 min. Plasma catecholamines were inversely related to spleen volume after exercise (r = 0.70-0.84; P < 0.0001). There were no differences in red cell or total blood volume pre- to postexercise; however, a significant reduction in plasma volume was observed (18.9%; P < 0.01). There was no difference between the iodinated albumin and the hematocrit and hemoglobin methods of assessing plasma volume changes. These results suggest that the spleen regulates its volume in response to an intensity-dependent signal, and plasma catecholamines appear partially responsible. Splenic release of erythrocytes has no effect on indirect measures of plasma volume.     

Thermoacclimatory changes in blood oxygen binding properties and gill secondary lamellar structure ofSalmo gairdneri

Summary The blood oxygen binding properties and gill secondary lamellar structure of rainbow trout acclimated to several temperatures were studied. The blood oxygen carrying capacity decreased as acclimation temperature increased from 2 to 15 °C; the decrease was probably caused by an increase in plasma volume. Also the blood oxygen affinity decreased as the acclimation temperature increased from 2 to 15 °C. This change had no effect on the oxygen loading in gills, since the efferent arterial oxygen tension was adequate for approximately 100% erythrocytic O₂ saturation at all acclimation temperatures, but facilitated the oxygen unloading in tissues. At the highest acclimation temperature (18 °C) the oxygen loading in gills was facilitated by the changes in the secondary lamellar structure; the proportion of erythrocytes in the secondary lamellar capillaries was higher than at the other acclimation temperatures (2 and 10 °C).     

Generation of a membrane-bound, oligomerized pre-pore complex is necessary for pore formation by Clostridium septicum alpha toxin

Low-temperature inhibition of the cytolytic activity of alpha toxin has facilitated the identification of an important step in the cytolytic mechanism of this toxin. When alpha toxin-dependent haemolysis was measured on erythrocytes at various temperatures it was clear that at temperatures ≤15°C the haemolysis rate was significantly inhibited with little or no haemolysis occurring at 4°C. Alpha toxin appeared to bind to and oligomerize on erythrocyte membranes with similar kinetics at 4°C and 37°C. The slight differences in these two processes at 4°C and 37°C could not account for the loss of cytolytic activity at low temperature. At 4°C alpha toxin neither stimulated potassium release from erythrocytes nor formed pores in planar membranes. In contrast, at temperatures ≥25°C both processes proceeded rapidly. Pores that were opened in osmotically stabilized erythrocytes could not be closed by low temperature. Therefore, low temperature appeared to prevent the oligomerized complex from forming a pore in the membrane. These data support the hypothesis that alpha toxin oligomerizes into a membrane-bound, pre-pore complex prior to formation of a pore in a lipid bilayer.     

Comparisons of blood viscosity between amphibians and mammals at 3°C and 38°C

(1) The range of temperature exposure of endotherms is narrow compared to ectotherms that can experience daily and seasonal temperature fluxes. (2) Comparison of the blood viscosity of amphibians (bullfrog, Woodhouse's toad, and marine toad) and mammals (horse, dog, and rat) at 3°C and 38°C was undertaken to determine if the effect of temperature on blood viscosity was diminished in amphibians relative to mammals. (3) Mammals did not consistently show greater changes in blood viscosity, plasma viscosity, or relative viscosity with decreasing temperatures relative to the amphibians in this study. (4) These data do not support our hypothesis that blood viscosity of amphibians is less affected by temperature than mammalian blood.     

Hepatic respiratory compensation and haematological changes in the cave cyprinid, Phreatichthys andruzzii

In several ectotherms, including all members of the Osteichthyes studied so far, the spleen is capable of storing and releasing erythrocytes according to the animal's respiratory needs. The tropical cave cyprinid Phreatichthys andruzzii uses its liver rather than the spleen as the site of accumulation in the respiratory compensation process, like the amphibian Rana esculenta. The reversible process of erythrocyte accumulation in the liver is very evident in animals anaesthetized with chlorobutanol; MS-222, an anaesthetic widely used in lower vertebrates alters all the haematological parameters and is not suitable for studies on blood and respiration. The hepatic respiratory compensation mechanism is as efficient as the splenic one: in animals kept at 18 °C for 24 h the mean liver weight percentage was 70% higher than in specimens kept at 28 °C (2.43% of the body weight compared to 1.39%, in groups of six specimens) while mean red blood cell counts fell from 2.49 to 1.60 · 10¹² per l, in agreement with the haematocrit value and haemoglobin concentration; mean corpuscular volume remained constant (at about 177 fl). Accepted: 15 April 1997