Interactions between ion and gas transfer in freshwater teleost fish

Carbonic anhydrase and proton ATPase are co-distributed, being restricted to the apical regions of the gill epithelium of freshwater teleosts. Carbonic anhydrase supplies protons to the apical proton ATPase. Carbonic anhydrase is absent from the basal regions of the gill epithelium. Plasma flowing through the gills has no available carbonic anhydrase activity and plasma CO2/bicarbonate reactions are uncatalyzed. Thus, bicarbonate dehydration in plasma is negligible, and catalyzed bicarbonate dehydration occurs in erythrocytes in blood flowing through the gills. This results in tight coupling of carbon dioxide excretion to oxygen uptake and the evolution of hemoglobins with large Haldane effects but low buffering capacities, typical of many freshwater teleosts. Tight coupling of carbon dioxide and oxygen transfer in these fish also ensures that the Root shift does not impair oxygen uptake at the gills. Under these conditions, there is a selective advantage for hemoglobins with a Root shift. The presence of a Root shift augments oxygen transfer to the tissues in general and the eye and swimbladder in particular.     

Functional Body Capacities under the Conditions of Various Concentrations of Carbon Dioxide and Oxygen

We determined a permissible ratio between carbon dioxide and oxygen concentrations during accidental situations. The experiments (n = 138, 10 h each) on the effect of various concentrations of carbon dioxide and oxygen in the inhaled air were conducted on male volunteers aged 20–40 years subjected to a special medical examination. All experiments were divided into five series: hypercapnia + normoxia, hypercapnia + hyperoxia, hypercapnia + hypoxia, normocapnia + hypoxia, and ambient air (control). The results showed that functional capacities of the body are less impaired under the conditions of hypercapnia combined with hyperoxia. Thus, in accidental situations associated with rapid accumulation of carbon dioxide in the atmosphere of airtight chambers, a synchronous increase in pO₂ to 220–230 torr can provide for the highest work capacity.     

Influence of noradrenaline on the respiratory status of Rana balcanica red cell suspension under normoxia, hypoxia and hypercapnia: alpha 1-receptor involvement.

The effect of normoxia, hypoxia and hypercapnia on the extracellular pH, partial pressure carbon dioxide (pCO2), partial pressure oxygen (pO2) and HCO3- levels after noradrenaline treatment of Rana balcanica erythrocytes, was investigated. Noradrenaline caused a significant reduction of the extracellular pH which may have been due to the activation of red blood cell Na+/H+ exchange. Significant falls in the partial extracellular pressure of CO2 and O2 were evident. The initial reduction in extracellular pCO2 and pO2 was followed by a rise reflecting the desensitization of the Na+/H+ exchange after 15 min of hormone stimulation. Both hypercapnia and hypoxia increased the magnitude of these changes in relation to normoxia, although the greatest changes were observed under hypercapnic conditions. The involvement of alpha 1 receptors in regulating the concentration of respiratory gases after catecholamine stimulation was demonstrated. It is suggested that these responses increased the effectiveness of gas transfer over the respiratory surfaces.     

Ventilation in conscious dogs during acute and chronic hypercapnia.

Minute ventilation was measured in conscious dogs, at rest and during exercise (1 mph), over 60 min immediately following the acute inhalation of 5% carbon dioxide in air and at 2, 4, 7, and 14 days while breathing the same gas mixture in a chamber. The dogs were also studied in the immediate period of air recovery from chronic hypercapnia and 1 day later. Control studies were carried out with the dogs breathing air in the chamber under comparable conditions. A triphasic ventilation change was ovserved in dogs at rest over the 14 days of hypercapnia. After an initial marked increase in ventilation during acute hypercapnia, ventilation returned to control levels by 2 days and then appeared to be elevated above control studies from 4 to 14 days at a time when blood acid-base balance became compensated. When the same dogs were studied during exercise, ventilation was also not different from air control at 2 days of hypercapnia; however during exercise, unlike the resting studies, there was only a tendency for a secondary increase in ventilation at 7 and 14 days of hypercapnia. During the immediate recovery from chronic hypercapnia when the dogs breathed air there was no evidence of hypoventilation either at rest or exercise despite arterial alkalosis. At 24 h of recovery it appeared that dogs while at rest had a slightly reduced ventilatory response to 5% carbon dioxide relative to control studies. The findings provide suggestive evidence that other factors, in addition to acid-base balance, might contribute to the regulation of ventilation during chronic hypercapnia and the recovery from chronic hypercapnia.     

In vivo and in vitro effects of cadmium on selected enzymes in different organs of the fish Barbus conchonius Ham. (rosy barb).

1. Enzyme modulation by cadmium in selected organs of the fish, Barbus conchonius (rosy barb), was investigated in vivo (48 hr exposure to 12.6 mg/l cadmium chloride) and in vitro (10(-6) M cadmium chloride). 2. The acetylcholinesterase (AchE) activity was depressed in the gills but stimulated in the skeletal muscles and brain in vivo. The hepatic, branchial, and renal acid phosphatase (AcP) activity decreased marginally in vivo but it was significantly increased in the gut and ovary. In vitro, except for the liver, the AcP activity was depressed in the selected organs. Collaterally, gut alkaline phosphatase (AlP) was significantly inhibited but a pronounced stimulation was noted in the kidneys and ovary in vivo. In vitro, the AlP activity was conspicuously elevated in the kidneys and gut, and moderately in the gills. 3. Cadmium inhibited the glutamate-oxaloacetate and glutamate-pyruvate transaminases (GOT and GPT) in the liver, gills and kidneys in vivo. In vitro, the GOT and GPT activities were decreased in the liver, gills and kidneys. The lactic dehydrogenase (LDH) was significantly stimulated by Cd in the heart in vivo but in vitro the metal inhibited the enzyme in the gills. 4. Enzymes in the liver, followed by those in the kidneys and gills seem to be most seriously affected by Cd poisoning in this fish.     

Effects of hypercapnia on the buffer capacity and haematological values in Salmo salar (L.)

The effects of high environmental carbon dioxide tension (PCO₂) on buffering status, pH, haematocrit, red blood cell (RBC) count, mean corpuscle volume (MCV), and chloride (Cl^–) distribution in the blood of young salmon were investigated after 30 min and 24 h. An increase in blood buffering capacity was observed after 24 h. As compared to the preacclimation situation, haematocrit, RBC, MCV and Cl^– content of the erythrocytes increased after 30 min but decreased if hypercapnia was sustained for 24 h. However the plasma bicarbonate (HCO₃) content increased over the whole experimental period. Plasma Cl^– content was decreased after 24 h, but the ratio of Cl^– between erythrocytes and plasma increased at the onset of hypercapnia, then remained unchanged during the rest of the investigation period.     

Negative arterial-mixed expired PC02 gradient during acute and chronic hypercapnia.

In resting conscious dogs physiological dead space was calculated using the Bohr equation and measurements of arterial and mixed expired carbon dioxide tension. Whenever dogs inhaled carbon dioxide mixtures (5-10%) that had normal or low oxygen concentrations, the calculated dead space became negative. This paradox was based on the fact that the mixed expired carbon dioxide tension in resting hypercapnic dogs. Under these circumstances carbon dioxide was produced from the lung as measured by gas analyses and blood analyses. By the lung as measured by gas analyses and blood analyses. By reasoning this implies that "alveolar" carbon dioxide tension was higher than pulmonary venous carbon dioxide tension. The negative carbon dioxide gradient persisted at 14 days of chronic hypercapnia and reverted to normal within 10 min of breathing air after chronic hypercapnia. These findings suggest that the exchange of carbon dioxide in the lung cannot be explained solely on the basis of passive diffusion.     

CO2 and the catecholamine content of the adrenal medulla of the rat

In Wistar rats exposed during one hour to mixtures of oxygen and carbon dioxide producing hypoxia, hypercapnia, hyperoxia and hypocapnia, and so on, adrenaline contents of the suprarenals is reduced by high concentration of carbon dioxide (30%), with or without hypoxia. Noradrenaline contents is increased by carbon dioxide (15 to 30%). Hypercapnia is more potent than hypoxia as a suprarenal stimulus.     

Interaction between vagal and chemoreceptors afferents in ventilatory response to transient hypercapnia (awake rabbits).

The ventilatory response to a transient hypercapnia was studied in four awake rabbits maintained in a volume displacement plethysmograph : the increase in inspiratory volume (VI) was associated or not with an increase in inspiratory and expiratory durations (TI and TE). These ventilatory variations were consistent with the activation of the peripheral chemoreceptors by carbon dioxide (short latency of the initial response). After vagal blockade by local anaesthesia, relative ventilatory variations were not significantly different from those previously measured. Central activity seems an important factor reducing inhibitory vagal input and favouring peripheral chemoreceptor afferents.     

In vivo and in vitro effects of cadmium on selected enzymes in different organs of the fish Barbus conchonius ham. (Rosy Barb)

1. Enzyme modulation by cadmium in selected organs of the fish, Barbus conchonius (rosy barb), was investigated in vivo (48 hr exposure to 12.6 mg/1 cadmium chloride) and in vitro (10⁻⁶M cadmium chloride).2. The acetylcholinesterase (AchE) activity was depressed in the gills but stimulated in the skeletal muscles and brain in vivo. The hepatic, branchial, and renal acid phosphatase (AcP) activity decreased marginally in vivo but it was significantly increased in the gut and ovary. In vitro, except for the liver, the AcP activity was depressed in the selected organs. Collaterally, gut alkaline phosphatase (A1P) was significantly inhibited but a pronounced stimulation was noted in the kidneys and ovary in vivo. In vitro, the AIP activity was conspicuously elevated in the kidneys and gut, and moderately in the gills.3. Cadmium inhibited the glutamate-oxaloacetate and glutamate-pyruvate transaminases (GOT and OPT) in the liver, gills and kidneys in vivo. In vitro, the GOT and GPT activities were decreased in the liver, gills and kidneys. The lactic dehydrogenase (LDH) was significantly stimulated by Cd in the heart in vivo but in vitro the metal inhibited the enzyme in the gills.4. Enzymes in the liver, followed by those in the kidneys and gills seem to be most seriously affected by Cd poisoning in this fish.     

Dermal bone in early tetrapods: a palaeophysiological hypothesis of adaptation for terrestrial acidosis

The dermal bone sculpture of early, basal tetrapods of the Permo-Carboniferous is unlike the bone surface of any living vertebrate, and its function has long been obscure. Drawing from physiological studies of extant tetrapods, where dermal bone or other calcified tissues aid in regulating acid-base balance relating to hypercapnia (excess blood carbon dioxide) and/or lactate acidosis, we propose a similar function for these sculptured dermal bones in early tetrapods. Unlike the condition in modern reptiles, which experience hypercapnia when submerged in water, these animals would have experienced hypercapnia on land, owing to likely inefficient means of eliminating carbon dioxide. The different patterns of dermal bone sculpture in these tetrapods largely correlates with levels of terrestriality: sculpture is reduced or lost in stem amniotes that likely had the more efficient lung ventilation mode of costal aspiration, and in small-sized stem amphibians that would have been able to use the skin for gas exchange.     

Effects of the addition of carbon dioxide on manifestations of acute hypoxia in rats

In pentobarbitalized rats, hypoxia induced by inhalation of O2 8%-N2 92%, produces a transient hyperventilation which is followed by a respiratory depression and an apnea. A cardiovascular collapse is then observed. Correction of the hypocapnia depending on the initial hyperventilation, by inhalation of a gas mixture containing 4% CO2 maintains the hyperventilation and suppresses the cardiovascular collapse. Carbon dioxide activity is both a direct one by stimulation of respiratory centers and an indirect one by increasing the sensitivity of the peripheral arterial chemoreceptors to hypoxia. Four percent carbon dioxide just compensating hypocapnia are sufficient to prevent apnea and vascular collapse. The increase of this concentration up to hypercapnia complicates the interpretation of the results by addition of hypoxic and hypercapnic effects.     

The Challenges of Living in Hypoxic and Hypercapnic Aquatic Environments

Organisms living in coastal waters, and especially estuaries,have long been known to have behavioral or physiological mechanismsthat enable them toexist in water containing low amounts ofoxygen. However, the respiratory consumption of oxygen thatgenerates hypoxia is also responsible for producing significantamounts of carbon dioxide. An elevation of carbon dioxide pressurein water will cause a significant acidosis in most aquatic organisms.Thus, the combination of low oxygen and elevated carbon dioxidethat occurs in estuaries represents a significant environmentalchallenge to organisms living in this habitat. Organisms maymaintain oxygen uptake in declining oxygen conditions by usinga respiratory pigment and/or by making adjustments in the convectiveflow of water and blood past respiratory surfaces (i.e., increasecardiac output and ventilation rate). Severe hypoxia may resultin an organism switching partially or completely to anaerobicbiochemical pathways to sustain metabolic rate. There is alsoevidence to suggest that organisms lower their metabolism duringhypoxic stress. Elevated water CO₂ (hypercapnia) produces anacidosis in the tissues of organisms that breathe it. This acidosismay be wholly or partially compensated (i.e., mechanisms returnpH to pre-exposure levels), or may be uncompensated. Some studieshave examined the effects on organisms of exposure simultaneouslyto hypoxia and hypercapnia. This article reviews some of thespecific adaptations and responses of organisms to low oxygen,to high carbon dioxide, and to the cooccurrence of low oxygenand high carbon dioxide     

Arousal and cardiopulmonary responses to hyperoxic hypercapnia in lambs

Experiments were done to investigate the arousal and cardiopulmonary responses to hyperoxic hypercapnia in 8 lambs. Each lamb was anaesthetized and instrumented for recordings of electrocorticogram, electro-oculogram, nuchal and diaphragm electromyograms and measurements of arterial blood pressure and haemoglobin oxygen saturation. No sooner than 3 days after surgery, measurements were made in quiet sleep and active sleep during control periods when the animal was breathing 21% oxygen and during experimental periods of hyperoxic hypercapnia when the animal was breathing 10% carbon dioxide and 30% oxygen. Hyperoxic hypercapnia was terminated during each epoch by returning the inspired gas mixture to 21% oxygen once the animal aroused from sleep. Arousal occurred from both sleep states during hyperoxic hypercapnia but was delayed in active sleep compared to quiet sleep (active sleep 58 +/- 17 s; quiet sleep 21 +/- 10 s; mean +/- 1SD). There were no significant changes in heart rate or blood pressure during hyperoxic hypercapnia before arousal. However, respiratory rate and diaphragm electrical activity did increase during hyperoxic hypercapnia before arousal. Thus, our data provide evidence that hypercapnia can initiate arousal from sleep in young lambs. The mechanisms responsible for this response are yet to be determined.     

Myocardial oxygen supply during hypocapnia and hypercapnia in the dog

It has been postulated that a coronary vasoconstriction during hypocapnia might be opposed by a compensating coronary vasodilatation due to impaired myocardial oxygen supply. The present study was performed first to examine whether a maximal decline in coronary sinus (CS) oxygen content was reached during hypocapnia. During hypercapnia a myocardial "over perfusion" has been demonstrated. The second purpose of the present study was to examine whether a myocardial "over perfusion" is essential to maintain a sufficient myocardial tissue oxygen supply during hypercapnia. Closed-chest dogs were anesthetized with pentobarbital and hypocapnia was induced by hyperventilation. Nitrogen gas and carbon dioxide could both be added to the inspiratory gas to create arterial hypoxemia (arterial SO2 65%) and hypercapnia, respectively. Arterial hypoxemia during hypocapnia increased myocardial blood flow (MBF) by 50%, while CS SO2 decreased significantly. The decrease in CS SO2 demonstrates a reserve capacity of myocardial oxygen extraction during hypocapnia, thereby ruling out any major coronary vasoconstriction during hypocapnia. Hypercapnia during normoxemia increased MBF, myocardial oxygen delivery, and CS SO2 substantially, but this was not observed when hypercapnia was created during arterial hypoxemia. From the present results we conclude that hypocapnia does not cause any major coronary vasoconstriction, while hypercapnia results in a myocardial "over perfusion," which is a luxury perfusion not essential to maintain sufficient myocardial oxygen supply during hypercapnia.     

Effect of diacarb on the carbonic anhydrase activity in the blood and gastric mucosa and pepsinogen concentration in the gastric mucosa of the rat

It was established that the activity of blood and gastric mucosa carboanhydrase increased after the introduction of food irritant (milk) into the stomach, as well as after the subcutaneous injection of histamine. This was accompanied by the increase of pepsinogen content in the gastric mucosa. When introduced into the stomach before the food irritant or histamine, acetazolamide inhibited blood and gastric mucosa carboanhydrase and reduced the content of pepsinogen in the gastric mucosa. Oral administration of acetazolamide for 5 days resulted in a more remarkable inhibition of blood and gastric mucosa carboanhydrase and in a drastically reduced content of pepsinogen in the gastric mucosa. The rate of pepsinogen biosynthesis by the gastric mucosa seems to depend on the activity of carboanhydrase in blood and in the gastric mucosa.     

Carbonic anhydrase of blue-green alga Spirulina platensis]

Carboanhydrase (carbonate-hydroliase EC 4.2.1.1.) is found in the extract of Spirulina platensis cells. A linear dependency of the enzyme activity on the protein concentration; pH optimum is found to be 8.0. Specific activity of carboanhydrase is 3 muM/min-mg of protein under the concentration of CO2 of 4-10(-3) M, appearing Michelis constant being 4.9-10(-3) M. The enzyme was stabilized with 10 mM of cisteine, its activity was inhibited by 50% with sulphanylamide (1-10(-5) M), acetazolamide (8--10(-7) M) and Cl- ions (5-10(-2) M). The activity of carboanhydrase, as well as the rate of NaH14CO3 fixation, depended on the pH value of cultural medium.     

Studies on the reticulo-endothelial system of the dogfish,Scyliorhinus canicula

Summary Clearance and subsequent localisation of a range of materials, including colloidal carbon, latex beads, sheep erythrocytes, bacteria and dextran were followed in the lesser spotted dogfish, Scyliorhinus canicula. It was found that two populations of peripheral blood leucocytes — monocytes and thrombocytes, but not granulocytes — were involved in clearance of the circulation. In the case of carbon, this material was cleared from the plasma after 12 h, and both the colloid-containing thrombocytes and monocytes disappeared from circulation by 8 weeks post injection. Upon injection of some of the materials, and particularly bacteria, a settling out of monocytes containing phagocytosed material was seen in the secondary lamellae and cavernous bodies of the gills. Large clumps of monocytes were found in the gills as early as 30 min post injection and these increased in size for up to one week, after which they gradually dispersed. The lining cells of the cavernous body, known as CB cells, were also responsible for the sequestration of carbon, latex beads and probably erythrocytes, but dextran and bacteria were not internalised. The origin, functions and phylogenetic significance of the CB cells are discussed.