Lena Sundin

Catecholamine release in heat-stressed Antarctic fish causes proton extrusion by the red cells

Abstract Two species of Antarctic fish were stressed by moving them from seawater at −1 °C to seawater at 10 °C and holding them for a period of 10 min. The active cryopelagic species Pagothenia borchgrevinki maintained heart rate while in the benthic species Trematomus bernacchii there was an increase in heart rate. Blood pressure did not change in either species. Both species released catecholamines into the circulation as a consequence of the stress. P. borchgrevinki released the greater amounts, having mean plasma concentrations of 177 ± 54 nmol · l−1 noradrenaline and 263 ± 131 nmol · l−1 adrenaline at 10 min. Plasma noradrenaline concentrations rose to 47 ± 14 nmol · l−1 and adrenaline to 73 ± 28 nmol · l−1 in T. bernacchii. Blood from P. borchgrevinki was tonometered in the presence of isoprenaline. A fall in extracellular pH suggests the presence of a Na+/H+ antiporter on the red cell membrane, the first demonstration of this in an Antarctic fish. Treatment with the β-adrenergic antagonist drug sotalol inhibited swelling of red blood cells taken from temperature-stressed P. borchgrevinki, suggesting that the antiporter responds to endogenous catecholamines.

Adenosinergic and cholinergic control mechanisms during hypoxia in the epaulette shark (Hemiscyllium ocellatum), with emphasis on branchial circulation.

SUMMARY Coral reef platforms may become hypoxic at night during low tide. One animal in that habitat, the epaulette shark (Hemiscyllium ocellatum), survives hours of severe hypoxia and at least one hour of anoxia. Here, we examine the branchial effects of severe hypoxia (<0.3 mg oxygen l–1 for 20 min in anaesthetized epaulette shark), by measuring ventral and dorsal aortic blood pressure (PVA and PDA), heart rate (fh), and observing gill microcirculation using epi-illumination microscopy. Hypoxia induced a flow of blood in two parallel blood vessels, termed longitudinal vessels, in the outer borders of the free tip of the gill filament. Hypoxia also induced significant falls in fh, PVA and PDA, and a biphasic change in ventilation frequency (increase followed by decrease). Adenosine injection (1μ mol kg–1) also initiated blood flow in the longitudinal vessels, in addition to significant drops in PVA, PDA and fh, and a biphasic response in ventilation frequency (decrease followed by increase) indicating that adenosine influences ventilation. Aminophylline (10 mg kg–1), an A1 and A2 adenosine receptor antagonist, blocked the effects of adenosine injection, and also significantly reduced blood flow in the longitudinal vessels during hypoxia. In the second part of the study, we examined the cholinergic influence on the cardiovascular circulation during severe hypoxia (<0.3 mg l–1) using antagonists against muscarinic (atropine 2 mg kg–1) and nicotinic (tubocurarine 5 mg kg–1) receptors. Injection of acetylcholine (ACh; 1μ mol kg–1) into the ventral aorta caused a marked fall in fh, a large increase in PVA, but small changes in PDA (suggesting increased Rgill). Atropine was able to inhibit the branchial vascular responses to ACh but not the hypoxic bradycardia, suggesting the presence of muscarinic receptors on the heart and gill vasculature, and that the hypoxia induced bradycardia is of non-cholinergic origin. The results suggest that adenosine mediates increases in the arterio–venous circulation in the gill during hypoxia. This may serve to increase blood supply to heart and gill tissue.

The Cardiorespiratory System in Tropical Fishes: Structure, Function, and Control

Publisher Summary The high temperatures of the tropical aquatic environment, often accompanied by hypoxia and hypercarbia/acidosis, have also given rise to a tremendous adaptive radiation in cardiorespiratory strategies designed to enhance survival under these conditions. This chapter presents the structure, function, and control of the respiratory and circulatory systems in these fishes. The chapter focuses on recent advances in the understanding of the control of cardiorespiratory processes in these fish with a brief review of structure and function designed to place discussion of control mechanisms in perspective. The great majority of tropical fishes continue to breathe water like their temperate relatives. Many species of tropical fish have evolved no special mechanisms for dealing with harsh conditions such as hypoxia/anoxia but constantly sense and monitor environmental conditions and migrate to better areas. These migrations are usually short, moving between stagnant areas and areas with higher water flow. The mechanisms involved include regulation of different hemoglobin fractions, adjustment of intra-erythrocytic levels of organophosphates, changes in hematocrit/hemoglobin and metabolic suppression; almost all under catecholaminergic control. The primary adaptations seen in the respiratory organs of water-breathers living in oxygen-poor waters are associated with gill diffusing capacity. Here we see both interspecies and intraspecies adaptations.

N-methyl-D-aspartate receptors mediate chemoreflexes in the shorthorn sculpin Myoxocephalus scorpius.

SUMMARY Glutamate microinjected into the vagal sensory area in the medulla produces cardiorespiratory responses mimicking oxygen chemoreflexes in fish. Here we directly investigate whether these reflexes are dependent on the ionotropic N-methyl-D-aspartate (NMDA) glutamate receptor. Fish were equipped with opercular, branchial and snout cannulae for measurements of cardiorespiratory parameters and drug injections. Oxygen chemoreceptor reflexes were evoked by rapid hypoxia, NaCN added into the blood (internal, 0.3 ml, 50 μgml–1) and the mouth (external, 0.5 ml, 1 mg ml–1), before and after systemic administration of the NMDA receptor antagonist MK801 (3 mg kg–1). Hypoxia produced an MK801-sensitive increase in blood pressure and ventilation frequency, whereas the marked bradycardia and the increased ventilation amplitude were NMDA receptor-independent. The fish appeared more responsive to externally applied cyanide, but the injections and MK801 treatment did not distinguish whether external or internal oxygen receptors were differently involved in the hypoxic responses. In addition, using single-labelling immunohistochemistry on sections from the medulla and ganglion nodosum, the presence of glutamate and NMDA receptors in the vagal oxygen chemoreceptor pathway was established. In conclusion, these results suggest that NMDA receptors are putative central control mechanisms that process oxygen chemoreceptor information in fish.

Identification of central mechanisms vital for breathing in the channel catfish, Ictalurus punctatus.

To investigate central respiratory control mechanisms in channel catfish, microinjections of kainic acid (causing chemical lesion of neurons) or kynurenic acid (an antagonist of N-methyl-D-aspartate (NMDA), kainate and alpha-amino-3-OH-5-methyl-4-isooxazole-propionic-acid (AMPA) receptors) were made into the general visceral nucleus (nGV) of the medulla in anaesthetised spontaneously breathing animals. Kainic acid abolished the ventilatory movements, indicating that neurons in the nGV are crucial for maintaining normal breathing. Kynurenic acid did not affect normal breathing, but abolished the ventilatory responses to hypoxia, showing that ionotropic glutamate receptors in the nGV are vital for the production of oxygen chemoreceptor activated respiratory reflexes. In addition, immunohistochemistry of brain slices showed that interneurons and nerve fibres in the nGV display NMDA-immunoreactivity, which corroborates the physiological experiments. The results of this study suggest that neurons and glutamatergic pathways in the nGV are essential for ventilatory functions and hypoxic reflexes in channel catfish.

Effects of afferent input on the breathing pattern continuum in the tambaqui (Colossoma macropomum)

This study used a decerebrate and artificially-ventilated preparation to examine the roles of various afferent inputs in breathing pattern formation in the tambaqui (Colossoma macropomum). Three general breathing patterns were observed: (1) regular breathing; (2) frequency cycling and (3) episodic breathing. Under normoxic, normocapnic conditions, 50% of control fish exhibited regular continuous breathing and 50% exhibited frequency cycling. Denervation of the gills and oro-branchial cavity promoted frequency cycling. Central denervation of the glossopharyngeal and vagus nerves produced episodic breathing. Regardless of the denervation state, hyperoxia produced either frequency cycling or episodic breathing while hypoxia and hypercarbia shifted the pattern to frequency cycling and continuous breathing. We suggest that these breathing patterns represent a continuum from continuous to episodic breathing with waxing and waning occupying an intermediate stage. The data further suggest that breathing pattern is influenced by both specific afferent input from chemoreceptors and generalised afferent input while chemoreceptors specific for producing changes in breathing pattern may exist in fish.

Branchial and circulatory responses to serotonin and rapid ambient water acidification in rainbow trout

Although the branchial and cardiovascular effects of serotonin (5-hydroxytryptamine) have only partially been characterized, a physiological role for serotonin in the cardiorespiratory responses of fish to environmental changes such as reduced Ph has been suggested. Therefore, we have characterized and compared the effects of serotonin and a rapid reduction of Ph in the ambient water (from pH 8.8 to pH 4.0) on ventral and dorsal aortic blood pressures, heart rate, cardiac output, and arterial pH in rainbow trout, Onchorhynchus mykiss. In addition, the circulation in the branchial microvasculature was observed using in vivo epi-illumination microscopy. The fall in water Ph and injection of serotonin (100 nmol/kg) both increased the branchial resistance and reduced the efferent filamental artery (EFA) blood velocity. Nevertheless, quantitatively, the responses to the two stimuli were different. Although acid exposure caused a much more profound increase in branchial resistance compared with serotonin, the blood flow in the observable distal portion of the EFA was only reduced by 60% in acid water, while it stopped with serotonin. Regardless of the marked branchial resistance elevation, a constriction of the efferent filamental vasculature could not be seen during acid exposure, as occasionally was the case with serotonin. While methysergide completely abolished the serotonin-induced branchial events, it only modestly suppressed the acid-induced reduction of EFA blood velocity. In contrast, all of the systemic changes induced by serotonin and acidic water were insensitive to methysergide. In conclusion, acidic water and injected serotonin elevate the branchial resistance, but the involvement of a serotonergic component in the acidic response appears negligible.

Effect of anoxia on the electroretinogram of three anoxia-tolerant vertebrates

To survive anoxia, neural ATP levels have to be defended. Reducing electrical activity, which accounts for 50% or more of neural energy consumption, should be beneficial for anoxic survival. The retina is a hypoxia sensitive part of the central nervous system. Here, we quantify the in vivo retinal light response (electroretinogram; ERG) in three vertebrates that exhibit varying degrees of anoxia tolerance: freshwater turtle (Trachemys scripta), epaulette shark (Hemiscyllium ocellatum) and leopard frog (Rana pipiens). A virtually total suppression of ERG in anoxia, probably resulting in functional blindness, has previously been seen in the extremely anoxia-tolerant crucian carp (Carassius carassius). Surprisingly, the equally anoxia-tolerant turtle, which strongly depresses brain and whole-body metabolism during anoxia, exhibited a relatively modest anoxic reduction in ERG: the combined amplitude of turtle ERG waves was reduced by approximately 50% after 2 h. In contrast, the shark b-wave amplitude practically disappeared after 30 min of severe hypoxia, and the frog b-wave was decreased by approximately 75% after 40 min in anoxia. The specific A(1) adenosine receptor antagonist CPT significantly delayed the suppression of turtle ERG, while the hypoxic shark ERG was unaffected by the non-specific adenosine receptor antagonist aminophylline, suggesting adenosinergic involvement in turtle but not in shark.

Involvement of non-NMDA receptors in central mediation of chemoreflexes in the shorthorn sculpin, Myoxocephalus scorpius.

NMDA receptors mediate hypoxia-induced ventilatory frequency and blood pressure increases in fish. Here we continue to resolve whether non-NMDA receptors participate in chemoreflexes. Shorthorn sculpins, instrumented for cardiorespiratory measurements, were kept unrestrained or positioned in a stereotaxic frame. Chemoreflexes were elicited (hypoxia/NaCN-induced) before/after administration of either the specific AMPA receptor antagonist, GYKI52466 (systemically), or the specific kainate receptor antagonist, UBP293 (microinjections into fourth ventricle). Immunohistochemistry was performed on medullary cross-sections to identify non-NMDA receptor subunits in the chemoreflex-pathway. Kainate receptors mediate the chemoreflex-mediated increase in ventilation amplitude, since the response was abolished by UBP293. GYKI52466 attenuated the ventilatory frequency increase, and induced more regular breathing patterns and higher heart rate in both normoxic and hypoxic conditions, suggesting that AMPA receptors also partake in cardiorespiratory control. This together with immunohistochemical findings of both AMPA and kainate receptor subunits in the chemoreflex-pathway, show that non-NMDA receptors play a role in both chemoreflex-activation and normoxic cardiorespiratory regulation in fish.

Brainstem mechanisms controlling cardiovascular reflexes in channel catfish

Microinjections of kynurenic acid and kainic acid into the general visceral nucleus (nGV), homologous to the mammalian nucleus tractus solitarius of the medulla, in anesthestized, spontaneously breathing catfish were used to identify central areas and mechanisms controlling resting normoxic heart rate and blood pressure and the cardiovascular responses to hypoxia. Kynurenic acid, an antagonist of ionotropic glutamate receptors, significantly reduced resting normoxic heart rate but did not block the bradycardia associated with aquatic hypoxia. Kainic acid (an excitotoxic glutamatergic receptor agonist) also significantly reduced normoxic heart rate, but blocked the hypoxia-induced bradycardia. Neither kynurenic acid nor kainic acid microinjections affected blood pressure in normoxia or hypoxia. The results of this study indicate that glutamatergic receptors in the nGV are involved in the maintenance of resting heart rate and the destruction of these neurons with kainic acid abolishes the bradycardia associated with aquatic hypoxia.