Compensatory growth in fishes: a response to growth depression
Tóm tắt
Compensatory growth (CG) is a phase of accelerated growth when favourable conditions are restored after a period of growth depression. CG reduces variance in size by causing growth trajectories to converge and is important to fisheries management, aquaculture and life history analysis because it can offset the effects of growth arrests.
Compensatory growth has been demonstrated in both individually housed and grouped fish, typically after growth depression has been induced by complete or partial food deprivation. Partial, full and over‐compensation have all been evoked in fish, although over‐compensation has only been demonstrated when cycles of deprivation and satiation feeding have been imposed. Individually housed fish have shown that CG is partly a response to hyperphagia when rates of food consumption are significantly higher than those in fish that have not experienced growth depression. The severity of the growth depression increases the duration of the hyperphagic phase rather than maximum daily feeding rate. In many studies, growth efficiencies were higher during CG. Changes in metabolic rate and swimming activity have not been demonstrated yet to play a role.
Periods of food deprivation induce changes in the storage reserves, particularly lipids, of fish. Apart from the strong evidence for the restoration of somatic growth trajectories, CG is a response to restore lipid levels. Although several neuro‐peptides, including neuropeptide‐Y, are probably involved in the control of appetite, their role and the role of hormones, such as growth hormone (GH) and insulin‐like growth factor (IGF), in the hyperphagia associated with CG are still unclear.
The advantages of CG probably relate to size dependencies of mortality, fecundity and diet that are characteristic of teleosts. These size dependencies favour a recovery from the effects of growth depression if environmental factors allow. High growth rates may also impose costs, including adverse effects on future development, growth, reproduction and swimming performance. Hyperphagia may lead to riskier behaviour in the presence of predators. CG's evolutionary consequences are largely unexplored. An understanding of why animals grow at rates below their physiological capacity, an evaluation of the costs of rapid growth and the identification of the constraints on growth trajectories represent major challenges for life‐history theory.
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Tài liệu tham khảo
Álvarez D.(2002)Implicaciones del comportamiento y fisiología individuales en el ciclo de vida y dinámica poblacional de la trucha común(Salmo truttaL.).Doctoral Thesis University of Oviedo Spain 109pages.
Aranyakananda P., 1996, Effect of feeding frequency on compensatory growth of Asian sea bass, Lates calcarifer, Arri Newsletter, 3, 11
Beamish F.W.H., 1964, Influence of starvation on standard and routine oxygen consumption, Transactions of the American Fisheries Society, 50, 153
Von Bertalanffy L., 1960, Fundamental Aspects of Normal and Malignant Growth, 137
Björnsson B., 1992, Growth rate and feed conversion factor on young halibut (Hippoglossus hippoglossus L.) fed six different diets, Fiskeridirektoratets Skrifter Ernaering, 5, 25
Brown M.E., 1946, The growth of brown trout (Salmo trutta Linn.) II The growth of two‐year‐old trout at constant temperature of 11.5 °C, Journal of Experimental Biology, 22, 130, 10.1242/jeb.22.3-4.130
Chmilevskii, 1994, Vliyanie ponizhennoj temperatury na on oogenez tilapii Oreochromis mossambicus 2. Vozdejstvie na ryb v vozraste dvadtsati dvukh sutok posle vylupleniya, Voprosy Ikhtiologii, 34, 675
Chmilevskii, 1996, The influence of a low temperature on the oogenesis of tilapia Oreochromis mossambicus 4. Effect on fish 106 days after their hatching, Journal of Ichthyology, 36, 615
Chmilevskii, 1998, The influence of low temperature on the growth of Oreochromis mossambicus, Journal of Ichthyology, 38, 86
Cho, 1976, Influence of level and type of dietary protein and of level of feeding on feed utilization by rainbow trout, Journal of Nutrition, 106, 1547, 10.1093/jn/106.11.1547
Christensen, 1998, Compensatory growth in Mozambique tilapia (Oreochromis mossambicus) fed a sub‐optimal diet, Ribarstvo, 56, 3
Christiansen, 1992, Rapid somatic growth and muscle damage in a salmonid fish, Basic and Applied Myology, 2, 235
Dabrowski, 1986, Does recovery growth occur in larval fish?, Bulletin of the of Japanese Society of Science, 52, 1869
DePedro, 2001, Feed Intake in Fish, 297
From, 1984, A growth model, gastric evacuation and body composition in rainbow trout, Salmo gairdneri Richardson, 1836, Dana, 3, 61
Gerking, 1994, Feeding Ecology of Fish
Gerking, 1979, Relative importance of size and chronological age in the life programme of fishes, Ergebnis Limnologie, 1979, 181
Goddard, 1974, An x‐ray investigation of the effects of starvation and drugs on intestinal motility in the plaice, Pleuronectes platessa L, Icthyologica, 6, 49
Gross, 1987, The evolution of disdromy in fishes, American Fisheries Society of Symposium, 1, 14
Haweet, 1996, Age and growth of ribbon fish Trichiurus japonicus in Kagoshima Bay, Japan, Fisheries Science, 62, 529, 10.2331/fishsci.62.529
Houston, 1999, Models of Adaptive Behaviour.
Jobling, 1994, Fish Bioenergetics
Jobling, 1996, Interindividual variations in feeding and growth in rainbow trout during restricted feeding and in subsequent period of compensatory growth, Journal of Fish Biology, 49, 658, 10.1111/j.1095-8649.1996.tb00062.x
Johal, 1986, Phenomenon of growth compensation in Cyprinus carpio, Indian Journal of Ecology, 13, 350
Kindschi, 1988, Effect of intermittent feeding on growth of rainbow trout, Salmo gairdneri Richardson, Aquaculture and Fisheries Management, 19, 213
Koppe, 1993, Fish Ecotoxicology and Ecophysiology, 263
Lagardere, 1989, Influence of feeding conditions and temperature on growth rate and otolith increment deposition of larval Dover sole (Solea solea L.), Rapports Process: Verbaux Reunion Conseil International Pour l'Exploration de la Mer, 191, 390
Le Bail, 1993, Aquaculture, Fundamental and Applied Research, 137
Leamy, 1985, Directional selection and developmental stability: evidence from fluctuating asymmetric of morphometric characters in rats, Growth, 49, 8
Love, 1970, The Chemical Biology of Fishes
Love, 1980, The Chemical Biology of Fishes
Lovell, 1979, Factors affecting voluntary food consumption of the channel catfish, Proceedings of Annual Conference S.E. Association of Fisheries and Wildlife Agency, 33, 563
Mackas, 1985, Plankton patchiness: biology in the physical vernacular, Bulletin of the of Marine Science, 37, 652
Metcalfe N.B., 2001, Compensation for a bad start: grow now, pay later, Trends in Ecology and Evolution, 16, 255, 10.1016/S0169-5347(01)02124-3
Metcalfe N.B., 2002, Seasonal variation in catch‐up growth reveals state‐dependent somatic allocations in salmon, Evolutionary Ecology Research, 4, 871
Mommsen T.P., 1998, The Physiology of Fishes, 65
Nicieza A.G.(1993)Estrategias de desarrollo y reproducción en el Salmón AtlánticoSalmo salarL.PhD Thesis University of Oviedo 206 pages.
Nicieza A.G.andBraña F.(1993b)Compensatory growth and optimum size in one‐year‐old smolts of Atlantic salmon (Salmo salar). In:Production of Juvenile Atlantic Salmon Salmo salar in Natural Waters(edsR.J.Gibson andR.E. Cutting) Canadian Special Publications in Fisheries and Aquatic SciencesNo.118 225–237.
Peter R.E., 1979, Fish Physiology, 121
Raikova‐Petrova G.N., 1998, Growth self‐regulation: a reason for the variability of fish condition indices, International Revue of Hydrobiology, 83, 599
Reinhardt U.G., 1998, Predation risk as an opportunity for compensatory growth in juvenile coho salmon?, North Pacific Anadromous Fish Commission Bulletin, 1, 403
Ricker W.E., 1975, Computation and interpretation of biological statistics of fish populations, Bulletin of the of the Fisheries Research Board of Canada, 191, 1
Riska B., 1986, Some models for development, growth, and morphometric correlation, Evolution, 46, 1303, 10.2307/2408955
Riska B., 1984, A genetic‐analysis of targeted growth in mice, Genetics, 107, 79, 10.1093/genetics/107.1.79
Roff D.A., 1992, The Evolution of Life Histories: Theory and Analysis
Rueda F.M., 1998, Effect of fasting and refeeding on growth and body composition of red porgy, Pagrus pagrus L, Aquaculture Research, 29, 447
Russell N.R.(1991)The dynamics of appetite and growth control in the minnow(Phoxinus phoxinusL.).PhD Thesis University of Wales 224 pages.
Ryan W.J., 1990, Compensatory growth in cattle and sheep, Nutritional Abstract Review of Series B, 60, 653
Sibly R.M., 1986, Physiological Ecology of Animals
Sogard S.M., 1997, Size‐selective mortality in the juvenile stage of teleost fishes: a review, Bulletin of the of Marine Science, 60, 1129
Tandon K.K., 1983, Study on age and growth of Tor putitora (Hamilton) as evidenced by scales, Indian Journal of Fisheries, 30, 171
Tandon K.K., 1983, Occurrence of the phenomenon of growth compensation in Indian major carps, Indian Journal of Fisheries, 30, 180
Thorpe J.E., 1986, Age at first maturity in Atlantic Salmon, Salmo salar: freshwater period influences and conflicts with smolting, Canadian Special Publication of the of Fisheries and Aquatic Science, 89, 7
Toledo M.M.(1996)Ciclos de vida y estrategias reproductivas de la trucha común (Salmo truttaL.).PhD Thesis University of Oviedo 203pages.
Underwood A.J., 1997, Experiments in Ecology – Their Logical Design and Analysis Using Analysis Of Variance
Weatherley A.H., 1987, The Biology of Fish Growth
Westerman M.E., 1988, The RNA‐DNA ratio: measurement of nucleic acids in larval Sciaenops ocellatus, Contributions in Marine Science, 30, 117
Wootton R.J., 1982, Reproductive Physiology of Fish, 201
Wootton R.J., 1998, Ecology of Teleost Fishes
Zivkov M.T., 1982, On the effect and nature of growth compensation of fish, Vestnik Ceskoslovenske Spolecnosti Zoologicke, 46, 142
Zivkov M.T., 1991, Growth compensation of pike‐perch, Stizostedion lucioperca (L.), in the Batak and Ovcharitsa dams, Comptes Rendus de l'Acadamie Bulgare des Science, 44, 45