The Influence of Hypoxia on the Concentrations of Cyclic Nucleotides in the Rat Brain

Abstract: In order to study the influence of hypoxia on cyclic nucleotides in the brain, we reduced arterial Po, for 15–30 min in lightly anaesthetised and artificially ventilated rats to obtain values ranging from about 45 to about 10 mm Hg. In an additional group (arterial Po₂ 18–22 mm Hg), the tissue hypoxia was aggravated by moderate arterial hypotension (mean arterial blood pressure about 80 mm Hg). In all animals, electrocortical activity was recorded. Cyclic GMP concentrations in cerebral cortex were unchanged in all groups but one. In that group, in which tissue hypoxia was severe enough to induce a suppression-burst EEG pattern and a measurable reduction in the adenylate energy charge, cyclic GMP concentrations were slightly increased ( p < 0.05). Cyclic AMP concentrations remained unaltered at all degrees of hypoxia studied. It is concluded that changes in cyclic nucleotides in brain tissue occur first at such severe degrees of hypoxia of the duration studied that function and metabolism are profoundly altered.     

Respiration of the carp, Cyprinus carpio L., at 10 and 20° C and the effects of hypoxia

Oxygen consumption of carp acclimated at 10 and 20° C has been measured under routine conditions. Some complications and precautions necessary in continuous flow respirometry are discussed. Routine V o₂ at different levels of hypoxia have been determined. Individual variation leads to scatter in the data and different methods of plotting the relationship between V o₂ and P o₂ are proposed; attention is drawn to differences between inlet (or ambient) P o₂ and inspired P o₂. Using certain criteria a 'critical' oxygen tension of about 95 mm Hg was found at 20° C; Q ₁₀ values are about 2 at normoxia and some suggestions of an increase near to the critical oxygen tension were found. Blood samples from the dorsal aorta showed rising Pa,o₂ of 16 mm Hg which increased to 70–80 mm Hg when P _insp was 90 and they then fall as the inspired oxygen is lowered. During periods of deep hypoxia (25 mm Hg) blood lactate concentration increases steadily and indicates an increasing dependence on anaerobic mechanisms.     

The effect of progressive hypoxia on swimming activity and schooling in Atlantic herring

Schools of herring exposed to progressive hypoxia show a peak in velocity during severe hypoxia, at 15–34% oxygen saturation, followed by a decrease in swimming speed until school disruption occurred. The observed increase in swimming speed during severe hypoxia reveals a graded response, since the lower the fish's swimming speed prior to severe hypoxia ( U ₉₅₋₅₀, the speed at oxygen saturations between 95 and 50%), the greater the relative increase in swimming speed. The oxygen saturations at which both peak velocity and school disruption occurred were lower for fish with lowest U ₉₅₋₅₀, suggesting that the fish with the slowest speed U ₉₅₋₅₀ reach their critical P_O2 (at which there is respiratory distress) last, i.e. at lower oxygen saturation. At a functional level, it is suggested that herring encountering hypoxia increase their speed in order to find more favourable conditions, and the magnitude of this increase is modulated by their respiratory distress. It is also hypothesised that the observed increase in speed may be related to an increase in the rate of position shifting within the school. Since the oxygen saturation at which the response to hypoxia occurs and the magnitude of the response are related to the fish's preferred speed prior to severe hypoxia, it is suggested that such a preferred speed should be measured in experiments testing the effect of hypoxia on fish behaviour.     

Arterial Po2, acid-base status, and red cell nucleoside triphosphates in rainbow trout transferred from fresh water to 20‰ sea water

Transfer of rainbow trout from fresh water to 20‰ sea water decreased dorsal aortic Po₂ from 90 to 60 mmHg within 1 h. Arterial Po₂ was depressed for 24 h before it returned to control values. The internal hypoxia rapidly reduced the red cell nucleoside triphosphate content, suggesting prompt regulation of blood O₂ affinity. The extracellular acid-base status changed towards a small mixed metabolic and respiratory acidosis.     

BRAIN EXTRACELLULAR POTASSIUM AND ENERGY METABOLISM DURING ISCHEMIA IN JUVENILE RATS AFTER EXPOSURE TO HYPOXIA FOR 24 h

Abstract— The ischemia-induced change of brain extracellular potassium concentration [K⁺]_e and brain energy metabolism was studied following decapitation of normal 7-dav-old rats and 7-day-old rats exposed to a simulated altitude of 6000 m ( p O₂= 70 mm Hg) for 24 h. Initially there was in both groups a slow rate of rise of [K ⁺]_e followed by a faster rise until a steep increase occurred. In the group exposed to hypoxia the initial rate of rise was lower and the duration until the steep increase twice as long as in the normal group. Energy consumption expressed as Δ# P and the rates of lactate accumulation were similar in the two groups in the first minute following decapitation. After 2 min the Δ# P and the rate of lactate accumulation was higher in the group exposed to hypoxia. These findings are explained by a doubling of the glucose concentration in the brain of the rats exposed to hypoxia, permitting anaerobic glycolysis to maintain ATP regeneration for a longer time during ischemia.     

MECHANISMS ACTIVATING GLYCOLYSIS IN THE BRAIN IN ARTERIAL HYPOXIA

Abstract— In order to study regulatory steps responsible for the activation of anaerobic glycolysis in the brain during hypoxia, cerebral concentrations of carbohydrate substrates and organic phosphates were measured in rats after reduction of the arterial P_O2 to 23-25 mm Hg for 2, 5 and 15 min. The results demonstrated a progressive accumulation of lactate as well as of pyruvate and malate in the absence of changes in ATP, A DP, AMP, citrate and ammonia. The pattern of substrate changes obtained indicate that hypoxia is accompanied by activation of pyruvate kinase and of hexokinase, but not of phosphofructokinase. There was a progressive fall in intracellular pH and a moderate increase in the calculated cytoplasmic NADH/NAD⁺ ratio. The changes in pyruvate and in the NADH/NAD⁺ ratio may be responsible for the observed increase in the malate concentration.     

Control of ventilatory movements in the aquatic insect Corydalus comutus: central effect of hypoxia

ABSTRACT. The influence of hypoxia and hypercapnia on the ventilatory rhythm of the hellgrammite Corydalus cornutus L. (Megaloptera) was studied. In intact animals the frequency of rhythmic retractions and protractions of abdominal gills is increased by hypoxia (10% O₂, 90% N₂) but no ventilatory response is elicited by hypercapnia (1–5% CO₂, 20% O₂, 75–79% N₂).
The ventilatory motor pattern was examined by recording extracellularly from the gill retractor muscle or its efferent nerve. In response to hypoxia (8% 0₂, 92% N₂), there are decreases in the cycle-time, the interspike interval, and the burst length of the gill retractor motorneuron. In addition, previously quiescent motorneurons associated with gill protraction are recruited.
Individual ganglia or small groups of abdominal ganglia can be isolated both from the central ganglionic chain and from the periphery by selective cutting of roots and connectives. When exposed to hypoxia, preparations that include the first abdominal ganglion show characteristic changes in the ventilatory motor pattern similar to those in intact animals. Thus sensitivity to oxygen appears to be located centrally and not peripherally. In small animals (head width < 7 mm), abdominal ganglia 2–3 and 2–7 respond characteristically to hypoxia, but in larger animals (head width > 9 mm), chains of ganglia lacking abdominal ganglion 1 fail to respond. In larger animals oxygen sensitivity may thus be concentrated in abdominal ganglion 1, whereas in smaller animals the ability to initiate a ventilatory response to hypoxia is distributed among the abdominal ganglia.     

Tolerance, behaviour and oxygen consumption in the sand goby, Pomatoschistus minutus (Pallas), exposed to hypoxia

Behavioural and metabolic reactions of Pomatoschistus minutus (Pallas) exposed to various degrees of hypoxia were studied. At 15°C and 20‰ mortality was 50% at 15.2% oxygen saturation. Avoidance and oxygen saturation showed a linear inverse relationship. At levels lower than 60% saturation increased activity occurred; avoidance was significant at 30% saturation. Active, routine and standard MO₂ correlated linearly with weight at 6 and 15°C (salinity = 19‰). During hypoxia at 15°C routine MO₂ rose significantly at 60–50% and 40–30% saturation expressed either as MO₂ during longer periods at night or MO₂ at shorter intervals during the day. Standard MO₂ was unaffected by hypoxia at 15°C. Haemoglobin concentration was significantly increased when P. minutus was acclimatized to 35% saturation.     

The occurrence of aerial respiration in Rhinelepis strigosa during progressive hypoxia

Rhinelepis strigosa did not surface for air breathing in normoxic or moderate hypoxic water. This species initiated air breathing when the P _io₂ in the water reached 22 ± 1 mmHg. Once begun, the air-breathing frequency increased with decreasing P _io₂. Aquatic oxygen consumption was 21·0 ± 1·9ml O₂ kg⁻¹h⁻¹ in normoxic water, and was almost constant during progressive hypoxia until the P _io₂ reached 23·9 mmHg, considered the critical oxygen tension (P_co₂). Gill ventilation increased until close to the P _co₂ (7·9-fold) as a consequence of a greater increase in ventilatory volume than in breathing frequency. Gill oxygen extraction was 42 ± 5% and decreased with hypoxia, but under severe hypoxia returned to values characteristic of normoxic. The critical threshold for air breathing was coincident with the P_co₂ during aquatic respiration. This suggests that the air-breathing response is evoked by the aquatic oxygen tension at which the respiratory mechanisms fail to compensate for environmental hypoxia, and the gill O₂ uptake becomes insufficient to meet O₂ requirements.     

Effects of Fructose-1,6-Bisphosphate on Glutamate Release and ATP Loss from Rat Brain Slices During Hypoxia

Abstract: Fructose-1,6-bisphosphate (FBP), an intermediate of glucose metabolism, is neuroprotective in brain hypoxia or ischemia. Because the mechanisms for this protection are not clear, we examined the effects of FBP on two important events in brain ischemia, i.e., loss of ATP and release of the excitatory neurotransmitter glutamate. Glutamate release from cortical brain slices was measured fluorometrically (glutamate dehydrogenase)-catalyzed conversion of glutamate to α-ketoglutarate) during hypoxia (Po₂ 15 mm Hg) or hypoxia plus 100 µ M cyanide. FBP (3.5 m M , with glucose 20 m M ) reduced glutamate release during hypoxia by 55% and during hypoxia/cyanide by 46% ( p < 0.005), and prevented a significant fall in [ATP]. [ATP] was maintained in oxygenated glucose-free conditions with 20 but not 3.5 m M FBP, and fell to <20% of normal with hypoxia. Despite the drop in [ATP], 3.5 or 20 m M FBP without glucose decreased hypoxia-evoked glutamate release. We conclude (1) FBP present without glucose preserves normal [ATP] only when oxygen is available, suggesting limited uptake and metabolism; and (2) FBP decreases hypoxia-evoked glutamate release by processes independent of [ATP]. These results suggest protective actions of FBP that are separate from augmentation of anaerobic energy production, as previously proposed.     

Hypoxia Enhances [3H]Noradrenaline Release Evoked by Nicotinic Receptor Activation from the Human Neuroblastoma SH-SY5Y

Abstract: We have used the human sympathetic neuronal line SH-SY5Y to investigate the effects of hypoxia on noradrenaline (NA) release evoked by either raised [K⁺]_o (100 m M ) or the nicotinic acetylcholine receptor (nAChR) agonist dimethylphenylpiperazinium iodide (DMPP). NA release was monitored by loading cells with [³H]NA and collecting effluent fractions from perfused cells kept in a sealed perifusion chamber. Cells were challenged twice with either stimulus and release was expressed as that evoked by the second challenge as a fraction of that evoked by the first. K⁺-evoked release was unaffected by hypoxia (P o ₂≅ 30–38 mm Hg), but release evoked by DMPP was significantly increased. For both stimuli, replacement of Ca²⁺_o with 1 m M EGTA abolished NA release. K⁺-evoked release was also dramatically reduced in the presence of 200 µ M Cd²⁺ to block voltage-gated Ca²⁺ channels, but DMPP-evoked release was less affected. In hypoxia, DMPP-evoked Cd²⁺-resistant NA release was dramatically increased. Our findings indicate that hypoxia increases NA release evoked from SH-SY5Y cells in response to nAChR activation by increasing Ca²⁺ influx through the nAChR pore, or by activating an unidentified Cd²⁺-resistant Ca²⁺-influx pathway. As acetylcholine is the endogenous transmitter at sympathetic ganglia, these findings may have important implications for sympathetic activity under hypoxic conditions.     

Effects of graded hypoxia on Atlantic salmon infected with amoebic gill disease

Atlantic salmon Salmo salar with amoebic gill disease (AGD) were exposed to a graded hypoxia (135–40 mmHg water P O₂) and blood samples analysed for respiratory gases and pH at 119, 79·5 and 40 mmHg water P O₂. There were no differences in the rate of oxygen uptake between infected and control fish. However, arterial P O₂, and pH were significantly lower in the infected fish whereas P CO₂ was significantly higher in infected fish compared with controls prior to hypoxia and at 119 mmHg water P O₂. At 79·5 and 40 mmHg water P O₂ saturation, there were no significant differences in blood P O₂ or pH although blood P CO₂ was elevated in AGD affected fish at 50% hypoxia (79·5 mmHg water P O₂). The elevated levels of P CO₂ in fish affected by AGD resulted in a persistent respiratory acidosis even during hypoxic challenge. These data suggest that even though the fish were severely affected by AGD, the presence of AGD while impairing gas transfer under normoxic conditions, did not contribute to respiratory failure during hypoxia.     

Swimming alters responses to hypoxia in the Adriatic sturgeon Acipenser naccarii

When the Adriatic sturgeon Acipenser naccarii was exposed to progressive hypoxia under static conditions, it exhibited a linear decline in O₂ uptake, behaving as an 'oxyconformer'. When, however, it was allowed to swim at a low sustained speed, it could regulate O₂ uptake down to a mean ± s . e . critical ( P _crit) of 4·9 ± 0·5 kPa ( n = 6). At moderate levels of hypoxia, static fish exhibited significant reductions in arterial blood O₂ content, and increases in plasma lactate, which were not observed in swimming animals.     

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.     

Effects of thermal stress on respiratory responses to hypoxia of a South American Prochilodontid fish, Prochilodus scrofa

Oxygen consumption (o₂) and respiratory variables were measured in the Prochilodontid fish, Prochilodus scrofa exposed to graded hypoxia after changes in temperature. The measurements were performed on fish acclimated to 25°C and in four further groups also acclimated to 25°C and then changed to 15, 20, 30 and 35°C. An increase in o₂ occurred with rising temperature, but at each temperature o₂ was kept constant over a wide range of O₂ tensions of inspired water ( Pi o₂). The critical oxygen tensions ( Pc o₂) were Pi o₂= 22 mmHg for 25°C acclimated specimens and after transfer from 25°C to 15, 20, 30 and 35°C the Pc o₂ changed to Pi o₂= 28, 22, 24 and 45 mmHg, respectively. Gill ventilation ( _G ) increased or decreased following the changes in o₂ as the temperature changed and was the result of an accentuated increase in breath frequency. During hypoxia the increases in _G were characterized by larger increases in breath volume. Oxygen extraction was kept almost constant at about 63% regardless of temperature and ambient oxygen tensions in normoxia and moderate hypoxia ( P o₂∼70 mmHg). P. scrofa showed high tolerance to hypoxia after abrupt changes in temperature although its survival upon transfer to 35°C could become limited by the capacity of ventilatory mechanisms to alleviate hypoxic stress.     

Free Fatty Acid Composition of Human and Rat Peripheral Nerve

Abstract: The free fatty acid (FFA) composition of peripheral nerve resembles that of erythrocytes but the composition of both is different from that of brain and other tissues. Approximately 75% of FFAs of nerve and erythrocytes are saturated and <5% are polyunsaturated whereas in brain and other tissues, 30-45% of FFAs are saturated and 25-50% are polyunsaturated. Approximately 10-15% of the total FFA of nerve have very long chain lengths [C₂₄, C₂₆, C₂₈, and C₃₀]. The presence of these very long-chain FFAs in endoneurium cannot be accounted for by the retention of erythrocytes or by lipid degradation. During Wallerian degeneration a significant increase of 18:1, associated with a decrease of saturated FFAs, was found in rat sciatic endoneurium, but normal values were approached when fiber regeneration was well under way. The FFA composition with chain length ≥C₂₆ were not, however, significantly altered with degeneration or repair of nerves. The metabolic significance of this striking difference between nerve and brain FFA composition is unknown but may reflect different functional properties.     

THE EFFECT OF HYPERCAPNIA UPON INTRACELLULAR pH IN THE BRAIN, EVALUATED BY THE BICARBONATE- CARBONIC ACID METHOD AND FROM THE CREATINE PHOSPHOKINASE EQUILIBRIUM

Abstract— Abstract-Intracellular pH in the brain was evaluated by the bicarbonate-carbonic acid method and from the creatine phosphokinase equilibrium, in rats exposed to 6–40 % CO₂ for 45 min. There was a very good agreement between the two methods, indicating that the creatine phosphokinase equilibrium in vivo shows the pH dependence predicted from previous in vitro studies. The stepwise increase in the tissue CO₂ tension from 45 to 265 mm Hg resulted in a lowering of the intracellular pH from 7.04 to 6.68. The regulation of intracellular pH in hypercapnia was far better than that which can be predicted from physicochemical buffering alone, and calculations indicate that the intracellular buffer base concentration increased by more than 10 mequiv./kg at the maximal P_co2 values encountered.     

Changes in thyroid function and gonadotrophin activity during sexual development in ducks Anas sp. (Aves: Anatidae)

Age-related changes in plasma iodohormone concentrations in male and female Aylesbury and Khaki Campbell ducklings were determined between the second week after hatching and sexual maturity.
In both sexes and strains the concentration of total thyroxine (T₄) and the free thyroxine index (FT₄1) were low during the first 6–8 weeks after hatching. A marked increase in the T₄ and FT₄1 occurred when the ducklings were nine weeks old; T₄ progressively increased over the following four weeks and remained high thereafter. The T₄ concentration in both sexes was directly related to age.
Concentrations of total tri-iodothyronine (T₃) were more variable than T₄ but were highest before sexual maturation and inversely age-related. An age-related decline in free tri-iodothyronine index (FT₃1) was observed during the first nine weeks.
The possibility that these maturational changes in thyroid function may reflect changes in gonadal activity was assessed by measuring the concentration of luteinizing hormone (LH) in the same plasma samples. Although plasma LH increased with age, in all cases the increase occurred after changes in the thyroid hormones were observed. Moreover, the maturational pattern of LH was related to sex and strain whereas thyroid function was unaffected by sex or strain.
These results demonstrate reciprocal changes in plasma T₃ and T₄ levels in ducks during sexual development, although the stimuli responsible and physiological significance are uncertain.     

The effects of acute hypoxia and hypercapnia on oxygen consumption of the freshwater European eel

When exposed to hypoxia, eels Anguilla anguilla were able to regulate and maintain Vo₂ down to a water oxygen tension ( Pwo₂ ) of about 25 mmHg, a value far below those reported in other studies. When exposed to hypercapnia, eels showed a depression in Vo₂ as water carbon dioxide tension ( Pwco₂ ) increased. Faced with combined hypoxia-hypercapnia, eels showed an increase in their sensitivity to hypoxia, and the critical oxygen tension increased to 40–45 mmHg. The possible mechanisms underlying these responses were discussed, and the implications of such findings for extensive culture of eels were highlighted.     

A comparative study of blood oxygen transport in turbot and sea bass: effect of chronic hypoxia

A comparative study of blood oxygen binding and carrying capacities of turbot Scophthalmus maximus and sea bass Dicentrarchus labrax , two fish species differing in their demand for oxygen, was carried out under three levels of chronic hypoxia ( P o ₂ = 93, 65 and 40 mmHg) for 40 days. Blood O₂ affinity in normoxia was moderately high in both species ( P ₅₀ was c . 12–13 mmHg at pH 7·7). The Bohr factor was significantly lower in turbot (−0·52) than in sea bass (−0·85). In both species, blood O₂ affinity was not significantly affected by oxygen depletion whatever its level and duration. In turbot, however, P ₅₀ appeared to slightly decrease at the two more severe levels of hypoxia. In both species, blood O₂ carrying capacity was not affected by hypoxia and remained twice as high in sea bass than in turbot.