Gill remodeling in fish - a new fashion or an ancient secret?

doi:10.1242/jeb.000281

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First published online June 29, 2007
Journal of Experimental Biology 210, 2403-2409 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.000281

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Commentary

Gill remodeling in fish – a new fashion or an ancient secret?

Göran E. Nilsson

Physiology Programme, Department of Molecular Biosciences, University of Oslo, PO Box 1041, N-0316 Oslo, Norway

e-mail: g.e.nilsson{at}imbv.uio.no

Accepted 6 March 2007

While a large respiratory surface area is good for gas exchange,it also poses several problems, including energetically unfavorablefluxes of water and ions. As a result, fishes appear to havea respiratory surface area that is matched to their oxygen demands.When faced with changes in their need for oxygen uptake, e.g.through altered physical activity or altered ambient oxygenlevels, fishes have long been known to make two different adjustments: (1)to change the water flow over the gills or (2) to change theblood flow inside the gills. It has recently become clear thatat least some teleosts have a third option: to reversibly remodelthe gill morphology. Studies have shown that the lamellae ofcrucian carp Carassius carassius gills are embedded in a cellmass during normoxic conditions or at low temperature, whilemuch of this cell mass dies off in hypoxia and at higher temperatures, therebyexposing a much larger respiratory surface area. Gill remodelinghas subsequently been seen in two more cyprinids and in themangrove killifish Kryptolebias marmoratus. In the latter caseit appears to be an adaptation to periods of air exposure. Gillremodeling in response to changing respiratory requirementscould be an ancient mechanism, occurring in many more teleoststhan presently known. It is tempting to suggest that gill remodeling hasbeen overlooked in many fishes, either because it is relativelysubtle in some species, or because fishes are often kept atthe warmer end of their temperature range where they need fullyprotruding lamellae.

Key words: crucian carp, hypoxia, respiration

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