Effects of rapid transfer from sea water to fresh water on respiratory variables,blood acid-base status and O2 affinity of haemoglobin in Atlantic salmon (Salmo salar L.)

Summary Oxygen consumption, gill ventilation, blood acid-base/ionic status and haemoglobin oxygen affinity were studied in seawater-adapted adult salmon (Salmo salar) during five weeks after transfer into fresh water. Freshwater exposure induced the following changes: Standard oxygen consumption ( ) and ventilatory flow ( ) decreased markedly during the first days after transfer, then decreased more gradually until a new steady-state was achieved at which and were about 80% and 56% of the control values, respectively. The marked increase in oxygen extraction coefficient (Ew _{O 2}) and the marked decrease in the oxygen convection requirement ( ) were associated with a reduction in the partial pressure of carbon dioxide in arterial blood (Pa _{CO 2}), in spite of a decrease of both ventilatory flow and water CO₂ capacitance. These results suggested that transfer into fresh water induced an increase in branchial diffusive conductance. A biphasic pattern was observed in the time-course of the changes in both plasma ion concentration and acid-base status. During the first 10 days, plasma Na⁺, K⁺, and Cl^– concentrations fell abruptly, then more gradually. [Cl^–] decreased more than [Na⁺] resulting in a progressive increase in the [Na⁺]/[Cl^–] ratio. During the second phase of acclimation to fresh water plasma Na⁺, K⁺, and Cl^– concentrations progressively increased. [Cl^–] increased more than [Na⁺], so that [Na⁺]/[Cl^–] ratio decreased. Transfer into fresh water did not significantly change plasma lactate concentration. Upon exposure to fresh water, blood pH increased from 7.94±0.04 to 8.43±0.06 at day 10 and then decreased to 8.08±0.03 at day 34. The increase in blood pH induced by transfer to fresh water initially represented a mixed metabolic/respiratory alkalosis. However, after 15 days Pa _{CO 2} had returned to pretransfer values and the alkalosis was purely metabolic. The metabolic component of the alkalosis was associated with appropriate changes in the plasma strong ion difference (S.I.D.). Blood alkalosis moved the oxygen dissociation curve to the left, so that P₅₀ was decreased by 30% below the value in seawater for the maximal increase in blood pH. This rise in haemoglobin affinity for O₂, associated with a marked increase in blood buffer capacity, are regarded as adaptative processes allowing the salmon to cope with the markedly increased energy expenditure required for upstream migration.     

Ionic and respiratory regulation in rainbow trout during rapid transfer to seawater

Summary Ionic and respiratory parameters of large rainbow trout were measured during freshwater to seawater transfer. Branchial Cl^– efflux increased immediately on transfer and urine excretion of Cl^– increased after 14 h. Branchial Na⁺ efflux however did not start to build up until 4–5 h after transfer and there was no increase in urinary Na⁺ excretion. These differences are discussed.The acid/base balance showed no major changes but arterial fell greatly on transfer but by 5 h had returned to 82% of the normal level. After 24 h arterial had decreased markedly again and this continued to the end of the experiment. On seawater transfer oxygen consumption fell gradually for 5 h and then rapidly increased back to the freshwater value. Possible explanations of these observations are discussed in relation to gill morphology and function during the transfer period.     

Effects of atropine and propranolol on the respiratory, circulatory, and ECG responses to high altitude in man

In order to analyze the respiratory, cardiovascular, and ECG responses to acute hypoxic hypoxia, three experimental series were carried out in a randomized manner on 11 healthy, unacclimatized volunteers at rest during standardized stepwise exposure to 6000 m (PAO2 35.2 +/- 2.9 mmHg/4.7 +/- 0.4 kPa) in a low-pressure chamber a) without (control), b) with propranolol, and c) with atropine combined with propranolol. The results show that hypoxic hyperventilation and alveolar gases are not affected by activation of the sympatho-adrenal axis or by parasympathetic withdrawal. Sympathetic activity, however, increases heart rate, stroke volume (pulse pressure), estimated cardiac output and systolic blood pressure, whereas decreased parasympathetic activity increases heart rate and estimated cardiac output, but lowers stroke volume. The fall in peripheral resistance, observed during progressive hypoxia in all three groups, is thought to be due to hypoxia-induced depression of the vasomotor center. At altitude catecholamine secretion and vagal withdrawal synergistically account in the ECG for the R-R shortening, the relative Q-T lengthening, the elevation of the P wave and the ST-T flattening. Probable direct hypoxic effects on the heart are the increase in P-Q duration and the minor but still significant depression of the T wave. It is concluded that at altitude increased sympatho-adrenal and decreased parasympathetic activity is without effect on hypoxic hyperventilation, but accounts for most of the cardiovascular and ECG changes. Diminution of sympathetic activity and imminent vagotonia arising after acute ascent to 6000 m probably reflect hypoxia of the central nervous system.     

Identification and expression of natriuretic peptide receptor type-A and -B mRNA in freshwater and seawater rainbow trout

Natriuretic peptide receptors mediate the physiological response of natriuretic peptide hormones. One of the natriuretic peptide receptor types is the particulate guanylyl cyclase receptors, of which there are two identified: NPR-A and NPR-B. In fishes, these have been sequenced and characterized in eels, medaka, and dogfish shark (NPR-B only). The euryhaline rainbow trout provides an opportunity to further pursue examination of the system in teleosts. In this study, partial rainbow trout NPR-A-like and NPR-B-like mRNA sequences were identified via PCR and cloning. The sequence information was used in real-time PCR to examine mRNA expression in a variety of tissues of freshwater rainbow trout and rainbow trout acclimated to 35 parts per thousand seawater for a period of 10 days. In the excretory kidney and posterior intestine, real-time PCR analysis showed greater expression of NPR-B in freshwater fish than in those adapted to seawater; otherwise, there was no difference in the expression of the individual receptors in fresh water or seawater. In general, the expression of the NPR-A and NPR-B type receptors was quite low. These findings indicate that NPR-A and NPR-B mRNA expression is minimally altered under the experimental regime used in this study.     

The blood respiratory, haematological, acid-base and ionic status of the Port Jackson shark, Heterodontusportusjacksoni, during recovery from anaesthesia and surgery: a comparison with sampling by direct caudal puncture

The effects of caudal cannulation on the blood physiology of the Port Jackson shark, Heterodontus portusjacksoni, were investigated in sharks given between 4 and 72 h to recover from surgery. Neither the Pa_O2–Pv_O2 difference nor the Ca_O2–Cv_O2 difference of cannulated sharks fluctuated throughout the sampling period. The plasma acidosis exhibited 4 h after surgery was partially compensated after 24 h by a respiratory (hyperventilatory) alkalosis and after 72 h by a marked metabolic alkalosis. Whilst H. portusjacksoni exhibited some cell swelling after surgery the haematological status of cannulated sharks generally varied little throughout the recovery period. In contrast, marked changes in plasma and erythrocyte ion concentrations were indicative of increased branchial and erythrocyte ion permeability. The blood status of H. portusjacksoni given 72 h to recover from surgery was also compared with sharks sampled by caudal puncture. The respiratory and acid-base status of sharks sampled by caudal puncture was comparable to that of cannulated sharks. In contrast, the plasma ion concentrations of the cannulated sharks were markedly elevated and the erythrocyte ion concentrations concomitantly reduced when compared with punctured sharks. The apparent increase in the water and ion permeability of cannulated sharks was reflected by the reduced [Hb] and mean cell haemoglobin concentrations (MCHC). Blood sampling by caudal puncture appeared to reduce the haematological and ionic perturbations that resulted from surgery and thus provided a less invasive and reliable method for obtaining samples from ‘non-disturbed’ elasmobranchs.     

Effect of hypotonic shock on cultured pavement cells from freshwater or seawater rainbow trout gills

The effect of hypotonic shock on cultured pavement gill cells from freshwater (FW)- and seawater (SW)-adapted trout was investigated. Exposure to 2/3rd strength Ringer solution produced an increase in cell volume followed by a slow regulatory volume decrease (RVD). The hypotonic challenge also induced a biphasic increase in cytosolic Ca(2+) with an initial peak followed by a sustained plateau. Absence of external Ca(2+) did not modify cell volume under isotonic conditions, but inhibited RVD after hypotonic shock. [Ca(2+)](i) response to hypotonicity was also partially inhibited in Ca-free bathing solutions. Similar results were obtained whether using cultured gill cells prepared from FW or SW fishes. When comparing freshly isolated cells with cultured gill cells, a similar Ca(2+) signalling response to hypotonic shock was observed regardless of the presence or absence of Ca(2+) in the solution. In conclusion, gill pavement cells in primary culture are able to regulate cell volume after a cell swelling and express a RVD response associated with an intracellular calcium increase. A similar response to a hypotonic shock was recorded for cultured gill cells collected from FW and SW trout. Finally, we showed that calcium responses were physiologically relevant as comparable results were observed with freshly isolated cells exposed to hypoosmotic shock.     

Copper exposure impairs intra- and extracellular acid-base regulation during hypercapnia in the fresh water rainbow trout (Oncorhynchus mykiss)

In order to evaluate the impact of water-borne copper on acid-base regulation in fresh water rainbow trout, chronically cannulated fish were exposed to copper (0.6 mg 1⁻¹), hypercapnia (water PCO₂ of 6 mmHg) or a combination of copper and hypercapnia, while a fourth untreated group served as the control. Blood samples obtained at 0 h, 4 h and 24 h were analysed for acid-base status, ion concentrations and respiratory parameters. Tissue samples from caudal skeletal muscle, liver and gill filaments were examined for intracellular acid-base status, ion- and water contents, and copper concentration. Exposure to copper alone elicited a small extracellular metabolic alkalosis, no changes in arterial PO₂, and a minor decrease in plasma ion concentrations. Hypercapnia alone increased arterial PCO₂ from approximately 2 mmHg to 7.2 mmHg, but the extracellular respiratory acidosis present at 4 h was almost completely compensated at 24 h due to an increase in plasma bicarbonate concentration [HCO₃ ⁻] from 8.1 mM to 24.4 mM. Combined exposure to hypercapnia and copper resulted in a slightly larger acidosis at 4 h, and the fish failed to restore extracellular pH at 24 h, because plasma [HCO₃ ⁻] only increased to 16.3 mM. Fish exposed to hypercapnia and copper also showed a delayed recovery of intracellular pH in skeletal muscle, compared to fish exposure to hypercapnia only. Thus, copper exposure impaired both extracellular and intracellular acid-base regulation during hypercapnia. When seen in connection with only minor effects of copper on osmoregulatory and respiratory parameters, the reduced ability to regulate acid-base suggests that acid-base regulation may be one of the most copper-sensitive branchial functions. Accepted: 18 August 1998     

Effects of freshwater to seawater transfer on osmoregulation,acid-base balance and respiration in river migrating whitefish (Coregonus lavaretus)

Osmoregulation, acid-base balance and respiratory parameters were investigated in whitefish following transfer from freshwater to salt water. Whitefish acclimated successfully to 25 ppt brackish water but died after direct transfer to 32 ppt sea water. Transfer to brackish water induced rapid (<6 h) and permanent increases in plasma [Na⁺], [Cl^–], total [Ca] and [Mg]. The extracellular hyperosmolality effected a transient (<3 days) muscle tissue dehydration and red blood cell shrinkage. Exposure to brackish water decreased both the arterial O₂ tension and whole body O₂ uptake. The extracellular acid-base status changed from an initial respiratory acidosis at 1 h towards a pronounced metabolic acidosis at 48 h of brackish water exposure. Red cell pH_i decreased in parallel with extracellular pH_e, but the in vivo pH_i/pH_e was only 0.26, suggesting some selective protection of red cell pH_i. Plasma cortisol concentration and gill Na⁺, K⁺-ATPase activity increased after exposure to high ambient salinity, reflecting the induction of hypo-osmoregulatory mechanisms. The physiological changes in whitefish are discussed in relation to salinity-induced effects in other salmonid fishes.Abbreviations CO₂ solubility in plasma - water O₂ capacitance coefficient - BW brackish water - C _T total CO₂ content in plasma - FW fresh water - Hb hemoglobin - Hct hematocrit - M _b body mass of fish - MCHC mean cellular hemoglobin concentration - PCO₂ carbon dioxide tension - pH _e extracellular pH - pH _i intracellular pH - PO_{2 in} oxygen tension in water flowing in - PO_{2 out} oxygen tension in water flowing out - ppt parts per thousand - RBC red blood cell(s) - SW sea water - V _m water flows through chamber - OV ₂ ml O₂ consumed per kg per hour     

Respiratory, circulatory and neuropsychological responses to acute hypoxia in acclimatized and non-acclimatized subjects

Respiratory, circulatory and neuropsychological responses to stepwise, acute exposure at rest to simulated altitude (6,000 m) were compared in ten acclimatized recumbent mountaineers 24 days, SD 11 after descending from Himalayan altitudes of at least 4,000 m with those found in ten non-acclimatized recumbent volunteers. The results showed that hypoxic hyperpnoea and O2 consumption at high altitudes were significantly lower in the mountaineers, their alveolar gases being, however, similar to those of the control group. In the acclimatized subjects the activation of the cardiovascular system was less marked, systolic blood pressure, pulse pressure, heart rate and thus (calculated) cardiac output being always lower than in the controls; diastolic blood pressure and peripheral vascular resistance, however, were maintained throughout in contrast to the vasomotor depression induced by central hypoxia which occurred in the non-acclimatized subjects at and above 4,000 m [alveolar partial pressure of O2 less than 55-50 mmHg (7.3-6.6 kPa)]. It was concluded that in the acclimatized subjects at high altitude arterial vasodilatation and neurobehavioural impairment, which in the non-acclimatized subjects reflect hypoxia of the central nervous system, were prevented; that acclimatization to high altitude resulted in a significant improvement of respiratory efficiency and cardiac economy, and that maintaining diastolic blood pressure (arterial resistance) at and above 4,000 m may represent a useful criterion for assessing hypoxia acclimatization.     

Pre-and post-branchial blood respiratory status during acute hypercapnia or hypoxia in rainbow trout,Oncorhynchus mykiss

Simultaneous venous (pre-branchial) and arterial (post-branchial) extracorporeal blood circulations were utilized to monitor continuously the rapid and progressive effects of acute environmental hypercapnia (water partial pressure of CO₂ 4.8±0.2 torr) or hypoxia (water partial pressure of O₂ 25±2 torr) on oxygen and carbon dioxide tensions and pH in the blood of rainbow trout (Oncorhynchus mykiss). During hypercapnia, the CO₂ tension in the arterial blood increased from 1.7±0.1 to 6.2±0.2 torr within 20 min and this was associated with a decrease of arterial extracellular pH from 7.95±0.03 to 7.38±0.03; the acid-base status of the mixed venous blood changed in a similar fashion. The decrease in blood pH in vivo was greater than in blood equilibrated in vitro with a similar CO₂ tension indicating a significant metabolic component to the acidosis in vivo. Under normocapnic conditions, venous blood CO₂ tension was slightly higher than arterial blood CO₂ tension difference was abolished or reversed during the initial 25 min of hypercapnia indicating that CO₂ was absorbed from the water during this period. Arterial O₂ tension remained constant during hypercapnia; however, venous blood O₂ tension decreased significantly (from 22.0±2.6 to 9.0±1.0 torr) during the initial 10 min. Hypercapnia elicited the release of catecholamines (adrenaline and noradrenaline) into the blood. The adrenaline concentration increased from 6±3 to 418±141 nmol · l^-1 within 25 min; noradrenaline concentration increased from 3±0.5 to 50±21 nmol · l^-1 within 15 min. During hypoxia arterial blood O₂ tension declined progressively from 108.4±9.9 to 12.8±1.7 torr within 30 min. Venous blood O₂ tension initially was stable but then decreased abruptly as catecholamines were released into the circulation. The release of catecholamines occurred concomitantly with a sudden metabolic acidosis in both blood compartments and a rise in CO₂ tension in the mixed venous blood only.Abbreviations CCO₂ plasmatotal carbondioxide - CtO₂ blood oxygen content - PO₂ partial pressure of oxygen - PCO₂ partial pressure of carbon dioxide - PaO₂ arterial bloodPO₂ - PaCO₂ arterial bloodPCO₂ - PvCO₂ venous bloodPCO₂ - PwO₂ waterPO₂ - PwCO₂ waterPCO₂ - Hb haemoglobin - SHbO₂ haemoglobin oxygen saturation - HPLC high-performance liquid chromatography - rbc red blood cell(s) - Hct haematocrit     

The effects of a glycogen loading regimen on acid-base status and blood lactate concentration before and after a fixed period of high intensity exercise in man

Six healthy male subjects exercised after an overnight fast for a fixed 3 min period at a workload equivalent to 100% of their maximal oxygen uptake ( ) on 3 separate occasions. The first test took place after subjects had consumed a mixed diet (43±3% carbohydrate (CHO), 41±5% fat and 16±3% protein) for 3 days, and was followed 2 h later by prolonged cycling to exhaustion at 77±3% to deplete muscle glycogen stores. Following this, subjects consumed a low CHO diet (4±1% CHO, 63±5% fat and 33±6% protein) for the remainder of the day and for the subsequent 2 days; on the morning of the next day a second high intensity test took place. Finally subjects followed a 3 day high CHO diet (73±7% CHO, 17±6% fat and 10±1% protein) before their last test. Acid-base status and selected metabolites were measured on arterialised-venous blood at rest prior to exercise and at intervals for 15 min following exercise. Prior to exercise, plasma pH and blood lactate concentration were higher (p<0.05) after the high CHO diet when compared with the low CHO diet. Pre-exercise plasma bicarbonate, blood PCO₂ and blood base excess were all higher after the high (p<0.001,p<0.01,p<0.01 respectively) and normal (p<0.05,p<0.05,p<0.05 respectively) CHO diets when compared with the low CHO diet. During the post-exercise period there were no differences in plasma pH or blood base excess between the three experimental situations; plasma bicarbonate was higher (p<0.05) at 2 min post-exercise after the high CHO diet when compared with the low CHO diet; blood PCO₂ was higher throughout the post-exercise period after the high CHO diet when compared with the low CHO diet and at 2 min post-exercise was higher after the normal CHO diet than after the low CHO diet (p<0.5). The post-exercise blood lactate concentration after the high CHO diet was at all times higher than the corresponding values recorded after the normal CHO diet and until 15 min post-exercise was significantly higher than the values recorded after the low CHO diet. The present experiment further substantiates the view that a pattern of dietary and exercise manipulation can significantly influence the acid-base status of the blood and by doing so may influence high intensity exercise performance.     

Does the presence of a seawater gill morphology induced by dietary salt loading affect Cl(-) uptake and acid-base regulation in freshwater rainbow trout Oncorhynchus mykiss

The goal of this study was to determine the effect of the changes in gill morphology induced by dietary salt feeding on several aspects of gill function in rainbow trout Oncorhynchus mykiss maintained in fresh water with specific emphasis on Cl(-) uptake (J(IN)Cl(-)) and acid-base regulation. The addition of 11% NaCl to the diet caused J(IN)Cl(-) to be reduced by c. 45% from 214·4 ± 26·7 to 117·3 ± 17·4 μmol kg(-1) h(-1) (mean ± s.e.). Rates of Cl(-) efflux (J(OUT)Cl(-)), net Cl(-) flux (J(NET)Cl(-)), J(NET) Na(+) and plasma levels of Na(+) or Cl(-) were unaffected by salt feeding. On the basis of significant effect of the salt diet on decreasing the maximal uptake rate of Cl(-)(J(MAX)Cl(-)), it would appear that internal salt loading caused a decrease in the number of functional ion transport proteins involved in Cl(-) uptake (e.g. Cl(-) -HCO(3)(-) exchangers) and decreased the transporting capacity of existing proteins. The acid-base regulating capacity of control fish and salt-loaded fish was assessed by monitoring arterial blood acid-base status [partial pressure of CO(2) (PCO(2)), pH and HCO(3)(-)] during exposure to external hypercapnia (nominally 7·5 mm Hg). Both groups of fish exhibited typical compensatory responses to sustained hypercapnia consisting of the gradual accumulation of plasma HCO(3) (-) and thus metabolic restoration within 24 h of the initial respiratory acidosis elicited by hypercapnia. Overall, the results demonstrate that while Cl(-) uptake capacity is reduced in salt-fed fish, there is no associated alteration in acid-base regulating capability.     

Two-substrate kinetic analysis: a novel approach linking ion and acid-base transport at the gills of freshwater trout,Oncorhynchus mykiss

Summary The novel application of a two-substrate model (Florini and Vestling 1957) from enzymology to transport kinetics at the gills of freshwater trout indicated that Na⁺/acidic equivalent and Cl^-/basic equivalent flux rates are normally limited by the availability of the internal acidic and basic counterions, as well as by external Na⁺ and Cl^- levels. Adult rainbow trout fitted with dorsal aortic and bladder catheters were chronically infused (10–16 h) with isosmotic HCl to induce a persistent metabolic acidosis. Acid-base neutral infusions of isosmotic NaCl and non-infused controls were also performed. Results were compared to previous data on metabolic alkalosis in trout induced by either isosmotic NaHCO₃ infusion or recovery from environmental hyperoxia (Goss and Wood 1990a, b). Metabolic acidosis resulted in a marked stimulation of Na⁺ influx, no change in Cl^- influx, positive Na⁺ balance, negative Cl^- balance, and net H⁺ excretion at the gills. Metabolic alkalosis caused a marked inhibition of Na⁺ influx and stimulation of Cl^- influx, negative Na⁺ balance, positive Cl^- balance, and net H⁺ uptake (=base excretion). Mean gill intracellular pH qualitatively followed extracellular pH. Classical one-substrate Michaelis-Menten analysis of kinetic data indicated that changes in Na⁺ and Cl^- transport during acid-base disturbance are achieved by large increases and decreases in J_max, and by increases in K_m. However, one-substrate analysis considers only external substrate concentration and cannot account for transport limitations by the internal substrate. The kinetic data were fitted successfully to a two-substrate model, using extracellular acid-base data as a measure of internal HCO ₃ ^- and H⁺ availability. This analysis indicated that true J_max values for Na⁺/acidic equivalent and Cl^-/basic equivalent transport are 4–5 times higher than apparent J_max values by one-substrate analysis. Flux rates are limited by the availability of the internal counterions; transport K_m values for HCO ₃ ^- and H⁺ are far above their normal internal concentrations. Therefore, small changes in acid-base status will have large effects on transport rates, and on apparent J_max values, without alterations in the number of transport sites. This system provides an automatic, negative feedback control for clearance or retention of acidic/basic equivalents when acid-base status is changing.Abbreviations Amm total ammonia in water - DMO 55-dimethyl-24-oxyzolidine-dione - J_in unidirectional inward ion movement across the gill - J_out unidirectional outward ion movement across the gill - J_net net transfer of ions (sum of J_in and J_out) across the gill - J_max maximal transport rate for ion - K_m inverse of affinity of transporter for ion - PIO₂ partial pressure of oxygen in inspired water - P_aCO₂ partial pressure of carbon dixide in arterial blood - TAlk titratable alkalinity of the water - PEG polyethylene glycol - NEN New England Nuclear     

The effects of experimentally altered gill chloride cell surface area on acid-base regulation in rainbow trout during metabolic alkalosis

To evaluate the role of the gill chloride cells in regulating metabolic alkalosis in rainbow trout (Oncorhynchus mykiss), the surface area of branchial chloride cells was altered experimentally using combined cortisol/ovine growth hormone injections. Long-term (10-day) treatment of fish with cortisol/ovine growth hormone caused an increase in the two-dimensional chloride cell fractional surface area when compared to uninjected fish (from 8.4 to 29.7%). This was the combined result of an increase in the size of individual cells (from 34.6 to 59.2 m²) and increased numbers of cells (from 2368 to 5006 cells · mm^-2). Metabolic alkalosis was induced by intra-arterial infusion of 140 mmol · l^-1 NaHCO₃; control fish were infused with 140 mmol · l^-1 NaCl. Blood pH and plasma [HCO₃ ^-] increased in both the untreated and the cortisol/ovine growth hormone-treated fish. However, the increases in pH (from 8.05 to 8.53) and [HCO₃ ^-] (from 5.9 to 22.2 mmol · l^-1) in the untreated fish were significantly greater than in the cortisol/ovine growth hormone-treated fish (pH increased from 7.78 to 8.11; [HCO₃ ^-] increased from 5.5 to 13.9 mmol · l^-1). In all fish, NaHCO₃ infusion elicited an increase in the rate of branchial basic equivalent excretion (acidic equivalent uptake) which, in turn, was caused by decreases and increases in branchial Na⁺ uptake and Cl^- uptake, respectively. In the untreated fish, there was a pronounced increase (75%) in chloride cell surface area during NaHCO₃ infusion. The attenuation of the metabolic alkalosis during HCO₃ ^- infusion in the cortical/ovine growth hormone-treated fish was caused, at least in part, by an enhancement of branchial basic equivalent excretion. In these fish that already displayed a proliferation of chloride cells, there was no further increase in chloride cell surface area. The changes in Na⁺ influx and Cl^- influx were quantitatively similar during NaHCO₃ infusion in both groups. This suggests that the greater rate of base excretion in the cortisol/ovine growth hormone-treated fish was caused by a greater percentage of Cl^- uptake being coupled to HCO₃ ^- excretion and less to Cl^- excretion (Cl^- exchange diffusion).Abbreviations Amm total ammonia - bw body weight - CC chloride cell - CCFA chloride cell fractional area - cort/oGH cortisol/ovine growth hormone - dpm disintegrations per minute - J ^Amm net flux of total ammonia - J _in unidirectional influx - J _inCl^- chloride ion uptake - J _inNa⁺ sodium ion uptake - J _netH⁺ net acidic equivalent flux - J ^TA net flux of titrable alkalinity - MS 222 ethyl-m-aminobenzoate - oGH ovine growth hormone - PVC pavement cell - SEM scanning electron microscope - TA titrable alkalinity     

Anion uptake and acid-base and ionic effects during isolated and combined exposure to hypercapnia and nitrite in the freshwater crayfish, Astacus astacus

Nitrite influx into crayfish showed saturation kinetics, supporting a carrier-mediated uptake. Addition of 4,4′-diisothiocyanatostilbene-2,2′-disulfonate (DIDS: at 10⁻⁵, 10⁻⁴ and 10⁻³M) and bumetanide (at 10⁻⁵ M and 10⁻⁴ M) to the ambient water did not significantly affect nitrite influx. Rather than suggesting that neither Cl⁻/HCO₃ ⁻ exchange nor K⁺/Na⁺/2Cl⁻ cotransport were involved in the transport, this may reflect that the gill cuticle has a low permeability to the pharmacological agents, or that the sensitivity of the transport mechanism to the inhibitors is low. Nitrite accumulation in the haemolymph was significantly decreased during hypercapnic conditions compared to normocapnic conditions. This supports the idea that an acid–base regulatory decrease in Cl⁻(influx)/HCO₃ ⁻ (efflux) induced by hypercapnia should decrease NO₂ ⁻ uptake if NO₂ ⁻ and Cl⁻ share this uptake route. The respiratory acidosis caused by exposure to hypercapnia alone was partially compensated by HCO₃ ⁻ accumulation in the haemolymph. Combined exposure to hypercapnia and nitrite improved pH recovery, mainly by augmenting the [HCO₃ ⁻] increase, but also by decreasing haemolymph PCO₂. Exposure to nitrite in normocapnic water induced an initial increase in haemolymph [HCO₃ ⁻] and later also a decrease in PCO₂. Thus, the improved acid-base compensation during combined hypercapnia and nitrite exposure was an amplification of this nitriteinduced response. Haemolymph base excess rose much more than haemolymph [Ca], suggesting that transfer of acid-base equivalents between animal and water was more important than H⁺ buffering by exoskeletal CaCO₃ in mediating the increase in haemolymph [HCO₃ ⁻]. Accepted: 27 June 2000     

Respiratory and acid-base disturbances in rainbow trout blood during exposure to chloramine-T under hypoxia and hyperoxia

Rainbow trout Oncorhynchus mykiss were exposed acutely to chloramine-T at a therapeutic concentration (9mg l⁻¹) under moderately hypoxic (water P o₂: l00 mmHg) or hyperoxic (water P o₂: 430mmHg) conditions and arterial blood gas tensions ( P ao₂ and P aco₂) and pH were monitored using an extracorporeal circulation. Hypoxia, alone, resulted in an increased ventilation frequency, a decrease in both arterial P co₂ and P o₂ and an increase in arterial pH. There was no effect of chloramine-T exposure on the measured variables as compared with pre-exposure (hypoxia baseline) values. Hyperoxia, alone, resulted in a decrease in ventilation frequency, an increase in arterial P co₂ and P o₂, and a decrease in arterial pH. Chloramine-T exposure under these conditions caused a significant increase in ventilation frequency, but no significant effect on arterial blood gases or pH as compared with the hyperoxia baseline values. Despite the increase in ventilation caused by chloramine-T during hyperoxia, there was no reduction in P co₂ or increase in P o₂. Although these results were of little pathological significance, this study suggests that chloramine-T, although stimulating ventilation, was impairing the diffusion of co₂ across the gill probably by the secretion of branchial mucus and enhancing the gill boundary layer.     

The impact of environmental degradation on reproduction of the black-chinned tilapia Sarotherodon melanotheron from various coastal marine,estuarine and freshwater habitats

There is growing evidence that climate change has greatly altered environmental conditions in many aquatic ecosystems over the last decades, leading to changes in fish distribution and life history traits. Recent works conducted in Senegalese and Gambian coastal marine, estuarine and freshwater ecosystems have shown important changes in the intensity, frequency and breeding timing of wild population of Sarotherodon melanotheron in response to changes in salinity regimes. In addition to salinity, this study investigates the potential influences of other environmental factors that have received less attention on the reproduction of S. melanotheron from three different aquatic ecosystems in Senegal. The results demonstrate that day-length and temperature affect sexual maturity in both males and females from Guiers Lake and Hann Bay, but no such effects were found in upstream of the Saloum Estuary, where the spawning activity seems to be under the synergetic control of rainfall and salinity that apparently predominate over all the other ambient factors. This study demonstrated for the first time that aside from photoperiod and temperature, rainfall also influences fish reproduction in Hann Bay probably through its effects on water quality. Furthermore, our results confirm previous findings that changes in salinity regimes resulting from seasonal variations in precipitation and evaporation are the ultimate causes of temporal changes in the reproductive activity of the species in this estuary.     

Uptake and accumulation of zinc in juvenile rainbow trout,Salmo gairdneri

Synopsis The toxicity of zinc to rainbow trout was determined and the 72 h median lethal concentration was found to be 2.00 mg l^–1 in freshwater, hardness 7.50 mg l^–1 as calcium. An insignificant increase in zinc concentration of internal tissues occurred in fish exposed to 1.52 mg l^–1 in freshwater for 72 h. However, there was a significant uptake of zinc by gills and the body surface. Fish exposed to 10 mg l^–1 zinc for 72 h in two-thirds sea water showed significant zinc uptake by liver, rectum and muscle, when compared to control fish. Drinking rate decreased from 1.43 to 0.26 ml kg^–1 h^–1 when zinc sulphate was added to freshwater. Trout adapted to two-thirds sea water showed no decrease in drinking, about 7 ml kg^–1 h^–1 when zinc was added to the water.