Air‐breathing fishes in aquaculture. What can we learn from physiology?

Lefevre, Sjannie; Wang, T.; Jensen, Arne; Công, Nguyễn Văn; Hương, Đỗ Thị Thanh; Phương, Nguyễn Thanh; Bayley, Mark

doi:10.1111/jfb.12302

Cited by 59 publications

(36 citation statements)

References 141 publications

(160 reference statements)

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“…5D) was even lower than that measured under resting conditions (Fig. 3 The standard Ṁ O2 values of Alaska blackfish measured in the present study are comparable to previous measurements on Alaska blackfish (Scholander et al, 1953;Crawford, 1971), as well as to values obtained for other air-breathing fishes (Lefevre et al, 2014c). It is interesting that up to 10 h was required for the Alaska blackfish to enter a resting state in the bimodal respirometer, but a similar pattern has been observed in the striped catfish Pangasianodon hypopthalmus (Lefevre et al, 2011).…”

Section: Critical Oxygen Tensionsupporting

confidence: 72%

“…A similar P crit has even been reported for Alaska blackfish at 20°C (Crawford, 1971). The P crit is well above the 1-4 kPa typical of hypoxia-tolerant teleosts (Nilsson and Randall, 2010), but falls within the range of P crit values reported for other air-breathing species (Lefevre et al, 2014c). The effect of temperature acclimation on the P crit of air-breathing fish has, to our knowledge, only been…”

Section: Critical Oxygen Tensionmentioning

confidence: 79%

See 1 more Smart Citation

Air breathing in the Arctic: influence of temperature, hypoxia, activity and restricted air access on respiratory physiology of Alaska blackfish (Dallia pectoralis)

Lefevre

Damsgaard

Pascale

et al. 2014

Journal of Experimental Biology

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The Alaska blackfish (Dallia pectoralis) is an air-breathing fish native to Alaska and the Bering Sea islands, where it inhabits lakes that are ice-covered in the winter, but enters warm and hypoxic waters in the summer to forage and reproduce. To understand the respiratory physiology of this species under these conditions and the selective pressures that maintain the ability to breathe air, we acclimated fish to 5°C and 15°C and used respirometry to measure: standard oxygen uptake (Ṁ O2 ) in normoxia (19.8 kPa P O2 ) and hypoxia (2.5 kPa), with and without access to air; partitioning of standard Ṁ O2 in normoxia and hypoxia; maximum Ṁ O2 and partitioning after exercise; and critical oxygen tension (P crit ). Additionally, the effects of temperature acclimation on haematocrit, haemoglobin oxygen affinity and gill morphology were assessed. Standard Ṁ O2 was higher, but air breathing was not increased, at 15°C or after exercise at both temperatures. Fish acclimated to 5°C or 15°C increased air breathing to compensate and fully maintain standard Ṁ O2 in hypoxia. Fish were able to maintain Ṁ O2 through aquatic respiration when air was denied in normoxia, but when air was denied in hypoxia, standard Ṁ O2 was reduced by ~30-50%. P crit was relatively high (5 kPa) and there were no differences in P crit , gill morphology, haematocrit or haemoglobin oxygen affinity at the two temperatures. Therefore, Alaska blackfish depends on air breathing in hypoxia and additional mechanisms must thus be utilised to survive hypoxic submergence during the winter, such as hypoxia-induced enhancement in the capacities for carrying and binding blood oxygen, behavioural avoidance of hypoxia and suppression of metabolic rate.

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Section: Critical Oxygen Tensionsupporting

confidence: 72%

Section: Critical Oxygen Tensionmentioning

confidence: 79%

Air breathing in the Arctic: influence of temperature, hypoxia, activity and restricted air access on respiratory physiology of Alaska blackfish (Dallia pectoralis)

Lefevre

Damsgaard

Pascale

et al. 2014

Journal of Experimental Biology

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“…It might also be a consequence of a low HCO 3 − /Cl − -exchanger activity, augmenting HCO 3 − retention, which would be consistent with the proposed low Cl − permeability of the gill of P. hypophthalmus, as indicated by a low uptake rate of nitrite (Lefevre et al, 2011c). Both characteristics contrast with those of other air-breathing fishes (Graham, 1997;Lefevre et al, 2014;Tamura and Moriyama, 1976). Other mechanisms may contribute to the high regulatory capacity for pH e regulation in P. hypophthalmus, such as H + /Na + exchange, greater renal or intestinal contribution in acid-base regulation, the ability to excrete CO 2 across the air-breathing organ etc.…”

Section: Results and Discussion Acid-base Regulation During Hypercapniacontrasting

confidence: 48%

High capacity for extracellular acid-base regulation in the air-breathing fishPangasianodon hypophthalmus

Damsgaard

Gam

Tuong

et al. 2015

Journal of Experimental Biology

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The evolution of accessory air-breathing structures is typically associated with reduction of the gills, although branchial ion transport remains pivotal for acid-base and ion regulation. Therefore, airbreathing fishes are believed to have a low capacity for extracellular pH regulation during a respiratory acidosis. In the present study, we investigated acid-base regulation during hypercapnia in the airbreathing fish Pangasianodon hypophthalmus in normoxic and hypoxic water at 28-30°C. Contrary to previous studies, we show that this air-breathing fish has a pronounced ability to regulate extracellular pH (pH e ) during hypercapnia, with complete metabolic compensation of pH e within 72 h of exposure to hypoxic hypercapnia with CO 2 levels above 34 mmHg. The high capacity for pH e regulation relies on a pronounced ability to increase levels of HCO 3 − in the plasma. Our study illustrates the diversity in the physiology of air-breathing fishes, such that generalizations across phylogenies may be difficult.

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“…Thus, at PO 2 tensions above 60 mmHg we saw an increased gill ventilation, stemming mainly from increased V amp , as was the case with lactate and NaCN injections (Figs 2 and 4) 10, 21, 37 . Hypoxia impairs growth in this species 38, 39 , in part from elevated energetic costs of air-breathing 40 , but the present data suggest that increased gill ventilation in moderate hypoxia might also contribute to the increased energetic costs. In more severe hypoxia (P w O 2 < 40 mmHg), gill ventilation started to decline as air-breathing rose (Fig.…”

Section: Discussionmentioning

confidence: 45%

Lactate provides a strong pH-independent ventilatory signal in the facultative air-breathing teleost Pangasianodon hypophthalmus

Thomsen

Wang

Milsom

et al. 2017

Sci Rep

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Fish regulate ventilation primarily by sensing O2-levels in the water and arterial blood. It is well established that this sensory process involves several steps, but the underlying mechanisms remain frustratingly elusive. Here we examine the effect of increasing lactate ions at constant pH on ventilation in a teleost; specifically the facultative air-breathing catfish Pangasianodon hypophthalmus. At lactate levels within the physiological range obtained by Na-Lactate injections (3.5 ± 0.8 to 10.9 ± 0.7 mmol L−1), gill ventilation increased in a dose-dependent manner to levels comparable to those elicited by NaCN injections (2.0 µmol kg−1), which induces a hypoxic response and higher than those observed in any level of ambient hypoxia (lowest PO2 = 20 mmHg). High lactate concentrations also stimulated air-breathing. Denervation of the first gill arch reduced the ventilatory response to lactate suggesting that part of the sensory mechanism for lactate is located at the first gill arch. However, since a residual response remained after this denervation, the other gill arches or extrabranchial locations must also be important for lactate sensing. We propose that lactate plays a role as a signalling molecule in the hypoxic ventilatory response in fish.

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Air‐breathing fishes in aquaculture. What can we learn from physiology?

Cited by 59 publications

References 141 publications

Air breathing in the Arctic: influence of temperature, hypoxia, activity and restricted air access on respiratory physiology of Alaska blackfish (Dallia pectoralis)

Air breathing in the Arctic: influence of temperature, hypoxia, activity and restricted air access on respiratory physiology of Alaska blackfish (Dallia pectoralis)

High capacity for extracellular acid-base regulation in the air-breathing fishPangasianodon hypophthalmus

Lactate provides a strong pH-independent ventilatory signal in the facultative air-breathing teleost Pangasianodon hypophthalmus

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