In vitro effect of hydrostatic pressure exposure on hydroxyl radical production in fish red muscle

The effects of hydrostatic pressure on reactive oxygen species (ROS) production have been studied in vitro on fish red muscle fibres. In the eel, Anguilla anguilla, previous studies have shown that hydrostatic pressure acclimatization improves oxidative phosphorylation efficiency together with a supposed concomitant decrease in electron leak and ROS production. In order to test the hypothesis of an electron leak decrease under pressure, hydroxyl radical (HO*) production and oxygen consumption were measured on fish red muscle fibres directly exposed to hydrostatic pressure. Experiments were performed under two conditions--atmospheric pressure and hydrostatic pressure (16.1 MPa)--on eel and trout (which exhibit low- and high-pressure sensitivity, respectively). This work has permitted, first, the validation of an indirect HO* measurement (in vitro) on fish red muscle and the documentation of reference values for fish. Second, at atmospheric pressure, results show higher oxygen consumption for trout (+40%) than for eel which is accompanied by higher HO* production (+90%); in addition, both species present a positive relationship between HO* production and oxygen consumption. Hydrostatic pressure exposure reverses this relationship for eel but not for trout. These preliminary results only partially verify the proposed hypothesis and further experiments are needed.     

Effects of the piezo-tolerance of cultured deep-sea eel cells on survival rates, cell proliferation, and cytoskeletal structures

We investigated the pressure tolerance of deep-sea eel (Simenchelys parasiticus; habitat depth, 366–2,630 m) cells, conger eel (Conger myriaster) cells, and mouse 3T3-L1 cells. Although there were no living mouse 3T3-L1 and conger eel cells after 130 MPa (0.1 MPa = 1 bar) hydrostatic pressurization for 20 min, all deep-sea eel cells remained alive after being subjected to pressures up to 150 MPa for 20 min. Pressurization at 40 MPa for 20 min induced disruption of actin and tubulin filaments with profound cell-shape changes in the mouse and conger eel cells. In the deep-sea eel cells, microtubules and some actin filaments were disrupted after being subjected to hydrostatic pressure of 100 MPa and greater for 20 min. Conger eel cells were sensitive to pressure and did not grow at 10 MPa. Mouse 3T3-L1 cells grew faster under pressure of 5 MPa than at atmospheric pressure and stopped growing at 18 MPa. Deep-sea eel cells were capable of growth in pressures up to 25 MPa and stopped growing at 30 MPa. Deep-sea eel cells required 4 h at 20 MPa to finish the M phase, which was approximately fourfold the time required under atmospheric conditions.     

Effect of supersaturated water on fish in the River Nidelva, southern Norway

Fish mortalities in the River Nidelva, South Norway in 1978, were suspected to be caused by Gas Bubble Disease. In June 1980, the hydrological situation occumng in the Nidelva in 1978 was reconstructed, and the effects were analysed by keeping fish in cages. Examination of the dead fish showed that most were killed by Gas Bubble Disease. The results also showed that brown trout, Salmo trutta , was the least tolerant, and eel, Anguilla anguih , was the most tolerant to dissolved gas supersaturation. Only fish kept near the surface were killed while fish kept at 3 m depth were mildly affected due to hydrostatic pressure compensation. In contrast to the situation in 1978, few of the wild fish were killed during the experiment in 1980.     

Effects of Hydrostatic Pressure on Energy Metabolism and Osmoregulation in Crab and Fish

This review will focus on the effects of hydrostatic pressure on the oxidative metabolism and on the energy production of the eel Anguilla anguilla, in comparison with the results of investigations conducted on the other powerful euryhaline species, the chinese crab Eriocheir sinensis. Anguilla and Eriocheir were chosen as being both aquatic ectotherms with comparable life modes, the eel being however “preadapted” to high pressure while the crab normally never encounters high levels of pressure during its life cycle. Comparison between both species should lead to better knowledge of the biological effects of hydrostatic pressure per se.Experimental evidence suggests that the oxygen consumption ṀO₂ decrease observed in both animal species during exposure to 101 ATA hydrostatic pressure and which follows a transient increase, likely results from a decrease in O₂ use at the cell level. That idea of an alteration of aerobic metabolism during the first hours under pressure is substantiated by a set of experiments on the eel. However, results indicate that, after some days under pressure, the shallow water fish is quite able to acclimate perfectly to high pressure. The hypothesis that pressure induces a state resembling histotoxic hypoxia during the first hours of exposure is put forward and discussed.The second part of the review focuses on some results showing that osmoregulation is also concerned with hydrostatic pressure. Results obtained on the freshwater eel clearly establish the occurrence of a Na⁺ balance impairment at the tissue level induced by a long-term (30 days) exposure to pressure. It is interesting to point out that this impairment occurs at the same time when a new state of energetic metabolism results from adjustments of intertissue coupling of anaerobic and aerobic metabolisms induced by pressure. It is shown that the physiological processes involved in the control of the hydromineral balance in the chinese crab (which never experiences high-pressure exposure in the course of its life cycle) are outstandingly resistant to pressure by comparison with other crustaceans like the crayfish and the shore crab. Disturbances in hydromineral balance and energetic metabolism in the chinese crab are rapidly resorbed and adjusted to a new state of activity.     

Polyploidy induced by hydrostatic pressure in rainbow trout, Salmo gairdneri Richardson

Triploid rainbow trout were produced by hydrostatic pressure applied to eggs 40 min after fertilization. Treatment for 10 min with or without exposure to 2% ether produced high hatching rates. Nuclear measurements from serial section of 40-day-old fry and from blood smears of 5-month-old juveniles showed that the proportion of triploid individuals was 80–90%. Ether treatment alone did not induce triploidy. Attempts to produce tetraploids by hydrostatic pressure treatment of eggs at 8 h after fertilization failed. Parallel results were also obtained with heat shock.     

Avoidance response of two-year-old rainbow trout, Salmo gairdneri Richardson, to air-supersaturated water: hydrostatic compensation

Vertical swimming responses of 2-year-old rainbow trout were tested with air saturated and air supersaturated water in tank experiments. The level of supersaturation varied between 115 and 125% total gas pressure. Control groups offish were kept in tanks with saturated water. No consistent vertical avoidance response was observed in the fish tested, but the mortality of fish restricted to the upper 30 cm of the tanks was significantly greater than fish free to sound to the whole depth of the tanks. It is concluded that the Norwegian stock of rainbow trout do not avoid air-supersaturation at levels from 115 to 125% TGP by active hydrostatic pressure compensation. An incidental type of hydrostatic pressure compensation seemed to be taking place during these experiments, as indicated by different levels of mortality in tanks with different depths. This incidental type of hydrostatic compensation may explain the observed difference in tolerance to supersaturation between wild fish and fish kept in experimental tanks.     

Flow cytometric analysis of the neutrophil respiratory burst of ayu,Plecoglossus altivelis: comparison with other fresh water fish

Neutrophils of vertebrates undergo respiratory burst activity (RBA) as a defense mechanism against bacterial infections. We report here that ayu (Plecoglossus altivelis) have unusually high RBAs even when they are in a healthy condition. Kidney and blood leukocytes were obtained from ayu, rainbow trout (Oncorhynchus mykiss), carp (Cyprinus carpio), eel (Anguilla japonica), and pond smelt (Hypomesus nipponensis). Neutrophil RBA was measured by flow cytometry using dihydrorhodamine after stimulation with phorbol myristate acetate. The amount of RBA of neutrophils from both blood and kidney was significantly higher in ayu than in the other species (e.g. the fluorescence intensity of ayu blood neutrophils was about 3-7 times higher than that from trout and carp, and that of ayu kidney neutrophils was 2-19 times higher than that of rainbow trout, carp, eel, and pond smelt). This unique character of ayu neutrophils was invariable even at different ages, locations, and sex-maturation stages.     

Effects of high-pressure acclimatization on silver eel (Anguilla anguilla, L.) slow muscle contraction

As the spawning migration of the eel is supposed to correspond to a long swimming activity at depth, patterns of slow red muscle contraction have been investigated in European silver eel (Anguilla anguilla L.) exposed for 3 weeks to 10.1 MPa hydrostatic pressure. The results show that pressure-acclimated eels (male and female) show a three-fold decrease in maximum isometric stress of twitch and tetanic contractions while time to peak force, time from peak force to 90% relaxation and ratio of twitch tension to tetanic tension remain unchanged. The observed modifications in slow red muscle mechanical properties do not impede the spawning migration of the eel and are possibly partially compensated by an improvement in the efficiency of oxidative phosphorylation. Effects of changes in membrane fluidity are also discussed.     

Effect of starvation and sea-water acclimation on the concentration of free l-histidine and related dipeptides in the muscle of eel,rainbow trout and Japanese dace

• 1.1. During the starvation of the eel (200 days), the rainbow trout (62 days) and the Japanese dace (75 days), white muscle free l-histidine decreased rapidly in every species, while carnosine and anserine levels in the eel and trout, respectively, exhibited relatively smaller percentage changes.
• 2.2. Accompanying sea-water acclimation, l-histidine in skeletal muscle of the ell and trout increased 2- and 5-fold, respectively, but in dace muscle no significant chenge occured. The concentration of carnosine in the eel and anserine in the trout remained almost at constant levels even in sea-water.

     

Hydrostatic pressure and adrenergic drugs (agonists and antagonists): effects and interactions in fish

Cardiac responses to alpha and beta adrenergic drugs have been studied in the eel firstly at atmospheric pressure (1 ATA), secondly at 101 ATA per se hydrostatic pressure. The exposure of treated eels for 1 hr at 101 ATA cancels the propranolol effect, increases the clonidine effect and induces paradoxal effects (reversal effect) of isoproterenol, phentolamine and phenylephrine. The highly significant interaction (P less than 0.001) between drugs and HP at 101 ATA is discussed and interpreted as effects of hydrostatic pressure inducing a change in receptor function.     

Diploid gynogenesis induced by hydrostatic pressure in rainbow trout, Salmo gairdneri Richardson

Diploid gynogenetic fry of rainbow trout, Salmo gairdneri , were produced by treating eggs activated by UV-irradiated sperm with hydrostatic pressure. Treatments for l0 min at 40 min after activation with 55 000 kPa (8000 psi) pressure resulted in high hatching rates and yields of heterozygous diploid gynogenomes of up to 81%. Attempts to produce homo-zygous diploid gynogenomes by the suppression of the first mitotic division ofthe eggs failed. Ether treatment alone did not induce diploid gynogenesis.     

Production of androgenetic diploid rainbow trout

Haploid androgenesis was induced in rainbow trout (Salmo gairdneri) when eggs were irradiated with 60Co gamma radiation prior to fertilization. Diploidy was restored to the androgenetic haploid zygotes by suppression of first cleavage division using hydrostatic pressure. Peak survival in the androgenetic diploid lots (32.5-38.9 percent of control) occurred when a pressure shock of 9000 pounds per square inch lasting from one to three minutes was applied to the eggs 345 minutes post-fertilization. Chromosomal analysis confirmed diploidy in the androgenetic individuals and suggested that YY rainbow trout are viable to at least the "eyed stage" of development. Inheritance patterns at two loci confirmed all-paternal inheritance. The relatively high yields of completely homozygous androgenetic rainbow trout and the potential for the use of androgenesis in the production of inbred lines and in genetic studies indicate that androgenesis may become a valuable tool in fish research and breeding.     

The oxidation of tricarboxylic acid cycle intermediates, with particular reference to isocitrate, by intact mitochondria isolated from the liver of the American eel, Anguilla rostrata leSueur.

The oxidation of exogenously added substrates has been studied in intact liver mitochondria isolated from the American eel, Anguilla rostrata. These data, coupled to determinations of the activity and localization of critical tricarboxylic acid (TCA) cycle enzymes, have been used to propose a pathway for the eel liver TCA cycle. (1) Isocitric, α-ketoglutaric, succinic, and malic acids are oxidized at essentially equivalent rates by eel mitochondria, with normal ADP:O and respiratory control ratios. No oxidation of citric, oxaloacetic, or pyruvic acids was detected when added alone or with malate, although oxaloacetic acid + pyruvic acid was oxidized but at a much reduced rate. (2) Radioactively labeled isocitrate was incorporated into at least α-ketoglutaric, succinic, and malic acids, indicating the eel liver TCA cycle is normal between isocitrate and malate. (3) No activity of the NAD-linked isocitrate dehydrogenase (IDH) could be detected, but NADP-IDH activities were higher in the mitochondria than cytosolic fractions. An active NADPH:NAD transhydrogenase was localized to the mitochondrial compartment. (4) These data suggest an important role for the NADP-IDH:transhydrogenase enzyme couple in eel liver TCA cycle function, and a pathway incorporating these ideas is proposed.     

The effect of pressure on fetal and neonatal liver mitochondrial membranes

The effects of pressure on late fetal and neonatal rat liver mitochondria have been investigated. High hydrostatic pressure, as produced by isopycnic centrifugation in sucrose and glycogen gradients, altered the mitochondrial membranes of 1- and 7-day-old rats. Most of the mitochondrial enzymes, chosen for their known submitochondrial location, had a trimodal distribution in the sucrose gradients. In the glycogen gradients, a shift of the mitochondria to a lower density was noticed. Fetal liver mitochondria were resistant to the hydrostatic pressure exerted during isopycnic centrifugation experiments under different conditions such as sucrose and glycogen density gradients. The submitochondrial compartment tracer enzymes exhibited an unimodal distribution. Experimental temperatures set at 15 degrees C had a protective effect from hydrostatic pressure alterations in the neonatal liver mitochondria, whereas no effects were noticeable in the fetal mitochondria. Experiments in a hydraulic compression chamber showed that outer membranes of fetal mitochondria were more fragile and the inner membranes more resistant to compression than in the early stages after birth.     

Interactions between vascular actions of detergent and catecholamines in perfused gills of European eel, Anguilla anguilla L. and brown trout, Salmo trutta L.

Noradrenaline induced vasodilation in isolated perfused eel or trout gills was inhibited by propranolol, aβ-adrenergic blocking agent. The noradrenaline effect was much reduced in gills of fish which had been kept in 1 mg/l solutions of the detergent LAS (linear alkylate sulphonate; 12C chain length). LAS produced concentration-dependent vasodilation, which was inhibited by propranolol, in eel and trout gills. Noradrenaline produced additional vasodilation in eel and trout gills which had been dilated by 2.10⁻⁸ m LAS but had no effect on trout gills perfused with 2.10⁻⁷ m LAS. Gills from trout which had been kept in 0.1 mg l^-1 LAS responded to noradrenaline normally but the propranolol inhibition appeared to be potentiated.     

The occurrence and distribution of peptide- or 5-HT-containing nerves in the swimbladder of four different species of teleosts (Gadus morhua,Ctenolabrus rupestris,Anguilla anguilla,Salmo gairdneri)

Summary The innervation of the swimbladder in four different teleost species has been studied by the use of immunohistochemical methods. The teleosts examined belong to two different groups regarding their swimbladder morphology: physoclists (the cod, Gadus morhua and the goldsinny wrasse, Ctenolabrus rupestris) and physostomes (the eel, Anguilla anguilla and the rainbow trout, Salmo gairdneri). Vasoactive intestinal polypeptide-like immunoreactivity was demonstrated in nerves of the swimbladder walls of all four species, and in the gas glands of the cod and the goldsinny wrasse. Substance P-like immunoreactivity was shown in swimbladders of the cod, eel and rainbow trout but not the goldsinny wrasse. Immunoreactivity to met-enkephalin antiserum was revealed in the swimbladder walls of the eel and the goldsinny wrasse, while neurotensin-like immunoreactivity was present in the goldsinny wrasse and rainbow trout swimbladders. Neurotensin-like immunoreactivity was also seen in the gas gland of the goldsinny wrasse. 5-Hydroxytryptamine immunoreactivity was found in endocrine cells in the pneumatic duct of the eel and in the swimbladder walls of the goldsinny wrasse and the rainbow trout. In conclusion, all teleosts examined showed a very close resemblance in the peptidergic/tryptaminergic innervation of the swimbladder to that of the gut, inasmuch as the immunoreactivity present in the swimbladders always occurred in the gut of the same species.     

Genome incompatibility between rainbow trout (<Emphasis Type="Italic">Oncorhynchus mykiss</Emphasis>) and sea trout (<Emphasis Type="Italic">Salmo trutta</Emphasis>) and induction of the interspecies gynogenesis

Rainbow trout (Oncorhynchus mykiss Walbaum) and sea trout (Salmo trutta Linnaeus, 1758) show large karyotypic differences and their hybrid offspring is not viable due to unstable karyotype and chromosome fragmentation. However, gametes from these two species were used to induce gynogenetic development. Rainbow trout eggs activated by UV-irradiated sea trout sperm were subjected to high hydrostatic pressure (HHP) shock to prevent release of the 2nd polar body (early shock) or to inhibit the first cleavage (late shock) in order to produce diploid meiotic gynogenotes and gynogenetic doubled haploids (DHs), respectively. Cytogenetic analysis proved fish that development was induced by the sea trout spermatozoa were rainbow trout. In turn, molecular examination confirmed homozygosity of the gynogenetic DHs. Presumed appearance of the recessive alleles resulted in lower survival of the gynogenetic DH larvae (~25%) when compared to survival of the heterozygous (meiotic) gynogenotes (c. 50%). Our results proved that genomic incompatibilities between studied trout species result in the hybrid unviability. However, artificial gynogenesis including activation of rainbow trout eggs with UV-irradiated sea trout spermatozoa was successfully induced. As both species are unable to cross, application of the UV-irradiated sea trout spermatozoa to activate rainbow trout development assures only maternal inheritance with no contamination by the residues of the paternal chromosomes.     

Effect of high hydrostatic pressure on the bacterial mechanosensitive channel MscS

We have investigated the effect of high hydrostatic pressure on MscS, the bacterial mechanosensitive channel of small conductance. Pressure affected channel kinetics but not conductance. At negative pipette voltages (corresponding to membrane depolarization in the inside-out patch configuration used in our experiments) the channel exhibited a reversible reduction in activity with increasing hydrostatic pressure between 0 and 900 atm (90 MPa) at 23°C. The reduced activity was characterized by a significant reduction in the channel opening probability resulting from a shortening of the channel openings with increasing pressure. Thus high hydrostatic pressure generally favoured channel closing. Cooling the patch by approximately 10°C, intended to order the bilayer component of the patch by an amount similar to that caused by 50 MPa at 23°C, had relatively little effect. This implies that pressure does not affect channel kinetics via bilayer order. Accordingly we postulate that lateral compression of the bilayer, under high hydrostatic pressure, is responsible. These observations also have implications for our understanding of the adaptation of mechanosensitive channels in deep-sea bacteria.A Proceeding of the 28th Annual Meeting of the Australian Society for Biophysics.     

Advancing provision of multi-species fish passage: Behaviour of adult European eel (Anguilla anguilla) and brown trout (Salmo trutta) in response to accelerating flow

The behavioural response of downstream moving European eel (Anguilla anguilla) and brown trout (Salmo trutta) to velocity gradients created by orifice weirs placed in a flume were studied. The aim was to identify interspecific variation and test two hypotheses: (1) a more abrupt velocity gradient would induce a higher avoidance response and over a greater distance, and (2) fish would acclimate to the velocity gradient by incrementally sampling conditions closer to the orifice until successful passage occurred. European eel moved along the channel floor and walls, responding after physical contact with the weir. Brown trout moved downstream head first and switched orientation at the velocity gradient without contacting the structure. Brown trout spent longer than European eel immediately upstream of a channel floor orifice, although time to pass was similar; but less time at a mid-column orifice despite taking longer to pass. The mid-column orifice delayed both species longer. European eel passed orifices head first on initial encounter with no rejections, whereas brown trout passed tail first. Positions where brown trout first switched orientation and closest point to the orifice reached during initial approach occurred closer to a channel floor than mid-column treatment. Brown trout did not appear to acclimate to the velocity gradient by sampling successively closer to the orifice. Interspecific variation in behaviour remains a key challenge in developing multi-species fish passes.     

Effects of hydrostatic pressure on the ultrastructure and leakage of internal substances in the yeast Saccharomyces cerevisiae

The structural damage to and leakage of internal substances from Saccharomyces cerevisiae 0–39 cells induced by hydrostatic pressure were investigated. By scanning electron microscopy, yeast cells treated at room temperature with pressuresbellw 400 MPa for 10 min showed a slight alteration in outer shape. Transmission electron microscopy, however, showed that the inner structure of the cell began to be affected, especially the nuclear membrane, when treated with hydrostatic pressure around 100 MPa at room temperature for 10 min; at more than 400–600 MPa, further alterations appeared in the mitochondria and cytoplasm. Furthermore, when high pressure treatment was carried out at — 20° C, the inner structure of the cells was severely damaged even at 200 MPa, and almost all of the nuclear membrane disappeared, although the fluorescent nucleus in the cytoplasm was visible by 4,6-diamidino-2-phenylindole (DAPI) staining. The structural damage of pressure-treated cells was accompanied by the leakage of internal substances. The efflux of UV-absorbing substances including amino acid pools, peptides, and metal ions increased with increase in pressure up to 600 MPa. In particular, amounts of individual metal ion release varied with the magnitude of hydrostatic pressures over 300 MPa, which suggests that the ions can be removed from the yeast cells separately by hydrostatic pressure treatment. Correspondence to: S. Shimada