Effect of salinity on the oxygen consumption of larvae of the silversides Odontesthes hatcheri and O. bonariensis (Osteichthyes, Atherinopsidae)

Tsuzuki, Mônica Yumi; Strüssmann, Carlos Augusto; Takashima, Fumio

doi:10.1590/S1516-89132008000300017

Abstracts

Starved larvae of the silversides O. hatcheri (2- and 5-days-old) and Odontesthes bonariensis (5-days-old) were used to compare the oxygen consumption rates at 0, 5, 10, 20 and 30 ppt salinity. Oxygen consumption of O. hatcheri and O. bonariensis was minimal at 0 and 10 ppt, respectively, salinities close to those encountered in areas inhabited by these fishes. In both species, oxygen consumption rates thereafter increased with increasing salinity, and then abruptly decreased at 30 ppt. Lower consumption at extreme salinities might be a result of reduced activity, which in itself was salinity-modulated. Differences in activity may explain the fact that oxygen consumption rates of 5-day-old larvae were higher than 2-day-old larvae, which still possess yolk-sac. In this case, starved larvae incurred in higher metabolic demand due to the continuous swimming in the search for food.

Salinity; respiratory metabolism; euryhaline fish; silversides; Odontesthes hatcheri; Odonthesthes bonariensis

As larvas em inanição de peixe-rei O. hatcheri (2 e 5 dias de idade) e Odontesthes bonariensis (5 dias de idade) foram usadas para comparar as taxas de consumo de oxigênio em salinidades de 0, 5, 10, 20 e 30 ppt. As taxas de consumo de oxigênio de O. hatcheri e O. bonariensis foram mínimas a 0 e 10 ppt, respectivamente, salinidades próximas aquelas encontradas nas áreas onde estes peixes habitam. Em seguida, em ambas as espécies, as taxas de consumo de oxigênio aumentaram com o incremento da salinidade, e abruptamente caíram a 30 ppt. As taxas de consumo mais baixas em salinidades extremas podem ser resultado da atividade reduzida, sendo portanto modulada pela salinidade. Diferenças na atividade possivelmente explicam o fato das taxas de consumo de oxigênio de larvas de 5 dias de idade serem maiores em comparação a larvas de 2 dias, ainda com saco vitelínico. Neste caso, larvas em inanição impõem um maior gasto metabólico devido a natação contínua em busca de alimento.

BIOLOGICAL AND APPLIED SCIENCES

Effect of salinity on the oxygen consumption of larvae of the silversides Odontesthes hatcheri and O. bonariensis (Osteichthyes, Atherinopsidae)

Mônica Yumi Tsuzuki^II,^* * Author for correspondence ; Carlos Augusto Strüssmann^I; Fumio Takashima^I

^IDepartment of Marine Biosciences; Faculty of Marine Science; Tokyo University of Marine Science and Technology (formerly Tokyo University of Fisheries); Tokyo 108-8477; Minato, Konan 4-5-7; Japan

^IILaboratório de Piscicultura Marinha; Departamento de Aqüicultura; CCA; Universidade Federal de Santa Catarina; C.P.: 476; mtsuzuki@cca.ufsc.br; 88040-970; Florianópolis - SC - Brazil

ABSTRACT

Starved larvae of the silversides O. hatcheri (2- and 5-days-old) and Odontesthes bonariensis (5-days-old) were used to compare the oxygen consumption rates at 0, 5, 10, 20 and 30 ppt salinity. Oxygen consumption of O. hatcheri and O. bonariensis was minimal at 0 and 10 ppt, respectively, salinities close to those encountered in areas inhabited by these fishes. In both species, oxygen consumption rates thereafter increased with increasing salinity, and then abruptly decreased at 30 ppt. Lower consumption at extreme salinities might be a result of reduced activity, which in itself was salinity-modulated. Differences in activity may explain the fact that oxygen consumption rates of 5-day-old larvae were higher than 2-day-old larvae, which still possess yolk-sac. In this case, starved larvae incurred in higher metabolic demand due to the continuous swimming in the search for food.

Key words: Salinity, respiratory metabolism, euryhaline fish, silversides, Odontesthes hatcheri, Odonthesthes bonariensis

RESUMO

As larvas em inanição de peixe-rei O. hatcheri (2 e 5 dias de idade) e Odontesthes bonariensis (5 dias de idade) foram usadas para comparar as taxas de consumo de oxigênio em salinidades de 0, 5, 10, 20 e 30 ppt. As taxas de consumo de oxigênio de O. hatcheri e O. bonariensis foram mínimas a 0 e 10 ppt, respectivamente, salinidades próximas aquelas encontradas nas áreas onde estes peixes habitam. Em seguida, em ambas as espécies, as taxas de consumo de oxigênio aumentaram com o incremento da salinidade, e abruptamente caíram a 30 ppt. As taxas de consumo mais baixas em salinidades extremas podem ser resultado da atividade reduzida, sendo portanto modulada pela salinidade. Diferenças na atividade possivelmente explicam o fato das taxas de consumo de oxigênio de larvas de 5 dias de idade serem maiores em comparação a larvas de 2 dias, ainda com saco vitelínico. Neste caso, larvas em inanição impõem um maior gasto metabólico devido a natação contínua em busca de alimento.

INTRODUCTION

Members of the Atherinopsidae family display various degrees of salinity tolerance and, as a result they have radiated into a wide range of environments (Hubbs et al., 1971; Bamber and Henderson, 1988; Middaugh et al., 1990). One representative of this family, the silverside Odontesthes bonariensis, also known as pejerrey, is an important commercial species naturally found in the temperate and sub-tropical inland waters of South America. Pejerrey has been introduced to several countries as a game fish or as a candidate for freshwater aquaculture (Bonetto and Castello, 1985). The congeneric O. hatcheri, from the fresh waters of Patagonia, is also a potential species for cultivation in temperate areas (Strüssmann et al., 1997). Although O. bonariensis and O. hatcheri are classified as fluvial euryhaline species (Martty, 1992), and are capable of tolerating different salinities (Tsuzuki et al., 2000a,b), the metabolic costs for osmoregulation are not understood in these fishes.

Oxygen consumption has been used as an indirect indicator of metabolism in fish (Cech, 1990), and its measurement at different salinities has been employed in an attempt of assessing the energetic cost of osmoregulation in several species (Farmer and Beamish, 1969; Iwama et al., 1997; Morgan et al., 1997; Kim et al., 1998; Da Silva Rocha et al. , 2005). Respiratory responses at different salinities seem to differ widely among teleost species. Low oxygen consumption rates were obtained at the isosmotic salinity with the nile tilapia Oreochromis niloticus acclimated to various salinities (Farmer and Beamish, 1969), rainbow trout Oncorhynchus mykiss (Walbaum), (Rao, 1968), and sea bream Sparus sarba (Woo and Kelly, 1995). On the other hand, Morgan and Iwama (1991) found low oxygen consumption rates in fresh water, and the consumption increased with the increase in salinity with juvenile rainbow and steelhead trout O. mykiss and fall chinook salmon O. tshawytscha. Ron et al. (1995), studying 20-month fresh and seawater reared mozambique tilapia O. mossambicus from yolk-sac fry, showed that the fish in sea water had significantly lower oxygen consumption rates compared to those reared in fresh water.

The energetic cost of ionic and osmotic regulations seems to play a significant role in growth rates (Boeuf and Payan, 2001). Some studies support the idea of growth enhancement arising from reduced metabolic cost for osmoregulation (Febry and Lutz, 1987; Woo and Kelly, 1995). De Silva and Perera (1976) suggested higher energy/protein requirement in high salinities, an effect that possibly reflects an elevated metabolic cost of osmoregulation in such salinities (Johnson and Katavic, 1986). It has been proposed that energetic cost associated with the ionic and osmotic regulations was minimal in the environment that was natural for a particular species and life-history stage (Morgan and Iwama, 1991).

The metabolic responses during brackish- or seawater acclimation process have never been studied in the atherinidae fish. Therefore, the present trial was to examine the respiratory changes associated with the salinity adaptation in starved larvae of Odontesthes hatcheri and O. bonariensis.

MATERIALS AND METHODS

Source of Materials and Experimental Set Up

Fertilized eggs of Odontesthes bonariensis (approximately the 10^th generation after introduction into Japan) and O. hatcheri (3^rd generation) were obtained by natural spawning of broodstock maintained at the Inland Water Fisheries Experimental Station, Kanagawa Prefecture Fisheries Research Center, Japan.

Water temperature during the experiments varied between 19.4 and 20.5ºC. Salinity levels were obtained by mixing dechlorinated tap water to artificial sea water (Vant Hoff, 1903) and adjusted using an optical refractometer (Atago) to the nearest 1 ppt. Oxygen concentration in the rearing containers was maintained near saturation through constant aeration. Until the start of the oxygen consumption measurements, water was exchanged daily by siphoning the bottom of the containers and adding 70% clean water. Water quality was monitored before and throughout the experiment. The unionised ammonia nitrogen (FAN) level was 0.02 ±0.0 mg L^-1 (mean ± standard error). Water pH varied from 7.3 to 7.6. The photoperiod was controlled at 12 h: 12 h darkness.

Oxygen Consumption of Larvae At Different Salinities

Starved larvae of O. hatcheri (2- and 5-days-old) and O. bonariensis (5-days-old) that were incubated and hatched at 0, 5, 10, 20 and 30 ppt were used to estimate the oxygen consumption rates. Four larvae were stocked in each of the stop-flow respirometers (200-mL glass bottles) at the experimental salinities. Fish were allowed to acclimate to the bottles for 12 h, when aeration was provided to maintain dissolved oxygen near saturation. After the acclimation period, 100% of the water was changed with minimum disturbance and the bottles were sealed. The bottles were then kept under constant illumination and isolated from external sources of disturbance. The incubation period of 18 h was determined in pre-trials as the minimum period necessary to detect any difference between the groups before the water dissolved oxygen content dropped to below 50% of the saturation level. Bottles without larvae for each salinity level were used as controls.

Larvae were measured (standard and total lengths) to the nearest 0.01 mm and wet-weighed to the nearest 0.1 mg. The dry weight of the larvae was taken after 24 h at 60ºC. The oxygen concentration was determined by Winklers titration method (Strickland and Parsons, 1972). Oxygen consumption was expressed as weight-specific respiration rate: WSR=1,000 x V x (O_ct- O_ex)/T x W (mL O₂g^-1 fish dry weight h^-1), where O_ct and O_ex are the control and experimental O₂ concentrations (mLO₂ L^-1), respectively, V is the volume of the bottles (L), T is the incubation time (h), and W is the dry weight of the fish (g).

Statistical Analysis

All the treatments were run in triplicate. Differences between the replicates and the treatments were analysed by one-way analysis of variance (ANOVA) with subsequent Tukey test. Statistical significance was assumed at P<0.05.

RESULTS AND DISCUSSION

The oxygen consumption of starved larvae of O. hatcheri increased from 0 to 20 ppt and then decreased at 30 ppt (Table 1). The oxygen consumption of O. bonariensis seemed to follow a sigmoidal distribution starting with high consumption rates.

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Aside from 30 ppt, oxygen consumption by larvae was minimal at 0 and 10 ppt for O. hatcheri and O. bonariensis, respectively (see below comments about consumption at 30 ppt). Studies with other species have also revealed cases where the minimum consumption rates occurred in the hypotonic conditions (Moser and Hettler, 1989; Morgan and Iwama, 1991) such as in O. hatcheri or near isotonic conditions (Rao, 1968; Farmer and Beamish, 1969) such as in O. bonariensis (it was assumed that the osmotic pressure for both species were around 300 mOsm kg^-1; Strüssmann et al. , 1994).

Morgan and Iwama (1991) reviewed the studies on the metabolic responses of several species of fishes from fresh-, brackish-, and saltwater. They concluded that low metabolic rates are most often associated to the water salinity in which the species are most commonly found and, therefore, most physiologically adapted to, at a particular life stage. This seems to be in agreement with the natural environment in which O. hatcheri and O. bonariensis are distributed. Odontesthes hatcheri occurs in rivers that seem to be poor in minerals (Luchini, 1981; Martty, 1992). In contrast, 0 ppt does not seem to be the usual salinity level encountered in the areas inhabited by O. bonariensis. Pampasic lakes are peculiar by the high content of Na, Cl and other elements (Mac Donagh, 1934; Ringuelet et al. , 1967) and this seems to be also the condition of the ground water in this region (Saravia et al., 1987).

In both species, the oxygen consumption rates thereafter increased with the increase in salinity and then abruptly decreased at 30 ppt. Swanson (1996) also observed that the oxygen consumption paradoxically decreased at salinities far above that of the seawater in the milkfish (Chanos chanos), and concluded that consumption rates were not necessarily related to the magnitude of the osmotic gradient between the organism and the surrounding water. It was suggested that the low oxygen consumption at extremely high salinities was rather a result of the reduced activity, which in itself was salinity-modulated. This probably explains the results at 30 ppt since fish at this salinity were visibly less active than those at lower salinities. Differences in activity also explain the fact that oxygen consumption rates of 5-day-old starved larvae were higher than those of 2-day-old starved larvae with yolk-sac (Table 1). Starved larvae were probably subjected to high metabolic demand due to the continuous swimming in the search for food (Hunter, 1981).

The present study shows that the oxygen consumption rates are minimal at salinities similar to the ones encountered in the natural habitat of the species, which corroborates with the studies with juveniles and sub-adults that showed that O. hatcheri presents higher survival and growth rates, and better adaptability to fresh water than O. bonariensis (Tsuzuki, 1999; Tsuzuki et al., 2000a,b).

ACKNOWKEDGMENTS

The staff of the Inland Water Fisheries Experimental Station, Kanagawa Prefecture Fisheries Research Center, Japan, is thanked for the support and for providing the materials for this study. We also thank Robert Vassalo-Agius for helping improving the clarity of the manuscript. During this work, Mônica Yumi Tsuzuki was supported by the scholarship and allowances from the Ministry of Education, Science, Sports and Culture of Japan (Monbusho) and Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP), which are gratefully acknowledged.

Received: December 07, 2005;

Revised: November 29, 2006;

Accepted: May 11, 2007.

Bamber, R. N. and Henderson, P. A. (1988), Pre-adaptive plasticity in atherinids and the estuarine seat of teleost evolution. J. Fish Biol., 33, 17-23.
Boeuf, G. and Payan, P. (2001), How should salinity influence fish growth? Comp. Biochem. Physiol., 130, 411-423.
Bonetto, A. A. and Castello, H. B. (1985), Pesca y piscicultura en aguas continentales de America Latina Secretaria General de la Organizacion de los Estados Americanos (OEA), Washington D.C., USA. (in Spanish).
Cech, J. J. (1990), Respirometry. In- Methods for fish biology, eds. C. B. Schreck and P. B. Moyle. American Fisheries Society, Bethesda, Maryland, pp. 335-365.
Da Silva Rocha, A. J., Gomes, V., Van Ngan, P., Passo, M. J. de A. C. R. and Fúria, R. R. (2005), Metabolic demand and growth of juveniles of Centropomus parallelus as function of salinity. J. Exp. Mar. Biol. Ecol., 316, 157 165.
De Silva, S. S. and Perera, P. A. B. (1976), Studies on the young grey mullet, Mugil cephalus L. I. Effects of salinity on food intake, growth and food conversion. Aquaculture, 7, 327-338.
Farmer, G. J. and Beamish, F. W. H. (1969), Oxygen consumption of Tilapia nilotica in relation to swimming speed and salinity. J. Fish. Res. Bd. Can., 26, 2807-2821.
Febry, R. and Lutz, P. (1987), Energy partitioning in fish: the activity-related cost of osmoregulation in euryhaline cichlid. J. Exp. Biol, 128, 63-85.
Hubbs, C., Sharp, H. B. and Schneider, J. F. (1971), Developmental rates of Menidia audens with notes on salt tolerance. Trans. Am. Fish. Soc, 100, 603-610.
Hunter, J. R. (1981), Feeding ecology and predation of marine fish larvae. In-Marine fish larvae, morphology, ecology, and relation to fisheries, ed. R. Lasker. Washington Sea Grant Program, Seattle, USA, pp. 33-77.
Iwama, G. K., Takemura, A. and Takano, K. (1997), Oxygen consumption rates of tilapia in fresh water, sea water, and hypersaline sea water. J. Fish Biol., 51, 886-894.
Johnson, D. W. and Katavic, I. (1986), Survival and growth of sea bass (Dicentrachus labrax) larvae as influenced by temperature, salinity and delayed initial feeding. Aquaculture, 52, 11-19.
Kim, W. S., Kim, J. M., Kim, M. S., Park, C. W. and Huh, H. T. (1998), Effects of sudden changes in salinity on endogenous rhythms of the spotted sea bass Lateolabrax sp. Mar. Biol., 131, 219-225.
Luchini, L. (1981), Estudios ecológicos en la cuenca del rio Limay (Argentina). Revista de la Associación de Ciencias Naturales del Litoral, 12, 44-58 (in Spanish).
Mac Donagh, E. J. (1934), Nuevos conceptos sobre la distribuición geográfica de los peces Argentinos baseado en expediciones del Museo de La Plata. Rev. Mus. La Plata, 34, 21-188 (in Spanish).
Martty, H. (1992), Manual del pejerrey (nomenclatura-reproducción-pesca) Albatroz, Buenos Aires (in Spanish).
Middaugh, D. P., Hemmer, M. J., Shenker, J. M and Takita, T. (1990), Laboratory culture of jacksmelt, Atherinopsis californiensis, and topsmelt, Atherinopsis affinis (pisces: Atherinidae), with a description of larvae. Calif. Fish and Game, 76, 4-13.
Morgan, J. D. and Iwama, G. K. (1991), Effects of salinity on growth, metabolism, and ion regulation in juvenile rainbow and steelhead trout (Oncorhynchus mykiss) and fall chinook salmon (Oncorhynchus tshawytscha). Can. J. Fish. Aquat. Sci., 48, 2083-2094.
Morgan, J. D., Sakamoto, T., Grau, E. G. and Iwama, G. K. (1997), Physiological and respiratory responses of the mozambique tilapia (Oreochromis mossambicus) to salinity acclimation. Comp. Biochem. Physiol., 117A, 391-398.
Moser, M. L. and Hettler, W. F. (1989), Routine metabolism of juvenile spot, Leiostomus xanthurus (Lacépède), as a function of temperature, salinity and weight. J. Fish Biol., 35, 703-707.
Rao, G. (1968), Oxygen consumption of rainbow trout in relation to activity and salinity. Can. J. Zool., 46, 781-786.
Ringuelet, R. A., Salibián, A., Clavérie, E. and Ilhero, S. (1967), Limnologia química de las lagunas pampasicas (Provincia de Buenos Aires). Physis, 74, 201-221 (in Spanish).
Ron, B., Shimoda, S. K., Iwama, G. K. and Grau, E. G. (1995), Relationships among ration, salinity, 17 α-methyltestosterone and growth in the euryhaline tilapia, Oreochromis mossambicus. Aquaculture, 135, 185-193.
Saravia, J. R., Benavidez, R., Canziani, O., Ferreiro, V. and Hernandez, M. A. (1987), Lineamentos generales y regionales para um plan maestro de ordenamiento hídrico del territorio bonaerense Convenio MOSP Nación, Provincia de Buenos Aires (in Spanish).
Strickand, J. D. H. and Parsons, T. R. (1972), A practical handbook of seawater analysis. Bull. Fish. Res. Bd Can., 167, 21-26.
Strüssmann, C. A., Akaba, T., Ijima, K., Yamaguchi, K., Yoshizaki, G. and Takashima, F. (1997), Spontaneous hybridization in the laboratory and genetic markers for the identification of hybrids between two atherinid species, Odontesthes bonariensis (Valenciennes, 1835) and Patagonina hatcheri (Eigenmann, 1909). Aquac. Res., 28, 291-300.
Strüssmann, C. A., Renard, P., Ling, H. and Takashima, F. (1994), Motility of pejerrey Odontesthes bonariensis spermatozoa. Fisheries Sci., 60, 9-13.
Swanson, C. (1996), Early development of milkfish: effects of salinity on embryonic and larval metabolism, yolk absorption and growth. J. Fish Biol., 48, 405-421.
Tsuzuki, M. Y. (1999), Effects of salinity on viability, physiology and stress induced responses in the pejerrey Odontesthes bonariensis and O. hatcheri PhD Thesis, Tokyo University of Fisheries, Tokyo, Japan.
Tsuzuki, M. Y., Aikawa, H., Strüssmann, C. A. and Takashima, F. (2000a), Comparative survival and growth of embryos, larvae, and juveniles of pejerrey Odontesthes bonariensis and O. hatcheri at different salinities. J. Appl. Ichthyol. , 16, 126-130.
Tsuzuki, M. Y., Aikawa, H., Strüssmann, C. A. and Takashima, F. (2000b), Physiological responses to salinity increases in the freshwater silversides Odontesthes bonariensis and O. hatcheri (Pisces, Atherinidae). Rev. Bras. Oceanogr (Braz. J. Oceanogr.), 48, 81-85.
Vant Hoff, J. H. (1903), Physical chemistry in the service of the sciences University of Chicago Press, Chicago.
Woo, N. Y. S. and Kelly, S. P. (1995), Effects of salinity and nutritional status on growth and metabolism of Sparus sarba in a closed seawater system. Aquaculture, 135, 229-238.

*

Author for correspondence

Publication Dates

Publication in this collection
16 July 2008
Date of issue
June 2008

History

Received
07 Dec 2005
Reviewed
29 Nov 2006
Accepted
11 May 2007

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Bamber, R. N. and Henderson, P. A. (1988), Pre-adaptive plasticity in atherinids and the estuarine seat of teleost evolution. J. Fish Biol., 33, 17-23.

[2] Boeuf, G. and Payan, P. (2001), How should salinity influence fish growth? Comp. Biochem. Physiol., 130, 411-423.

[3] Bonetto, A. A. and Castello, H. B. (1985), Pesca y piscicultura en aguas continentales de America Latina Secretaria General de la Organizacion de los Estados Americanos (OEA), Washington D.C., USA. (in Spanish).

[4] Cech, J. J. (1990), Respirometry. In- Methods for fish biology, eds. C. B. Schreck and P. B. Moyle. American Fisheries Society, Bethesda, Maryland, pp. 335-365.

[5] Da Silva Rocha, A. J., Gomes, V., Van Ngan, P., Passo, M. J. de A. C. R. and Fúria, R. R. (2005), Metabolic demand and growth of juveniles of Centropomus parallelus as function of salinity. J. Exp. Mar. Biol. Ecol., 316, 157 165.

[6] De Silva, S. S. and Perera, P. A. B. (1976), Studies on the young grey mullet, Mugil cephalus L. I. Effects of salinity on food intake, growth and food conversion. Aquaculture, 7, 327-338.

[7] Farmer, G. J. and Beamish, F. W. H. (1969), Oxygen consumption of Tilapia nilotica in relation to swimming speed and salinity. J. Fish. Res. Bd. Can., 26, 2807-2821.

[8] Febry, R. and Lutz, P. (1987), Energy partitioning in fish: the activity-related cost of osmoregulation in euryhaline cichlid. J. Exp. Biol, 128, 63-85.

[9] Hubbs, C., Sharp, H. B. and Schneider, J. F. (1971), Developmental rates of Menidia audens with notes on salt tolerance. Trans. Am. Fish. Soc, 100, 603-610.

[10] Hunter, J. R. (1981), Feeding ecology and predation of marine fish larvae. In-Marine fish larvae, morphology, ecology, and relation to fisheries, ed. R. Lasker. Washington Sea Grant Program, Seattle, USA, pp. 33-77.

[11] Iwama, G. K., Takemura, A. and Takano, K. (1997), Oxygen consumption rates of tilapia in fresh water, sea water, and hypersaline sea water. J. Fish Biol., 51, 886-894.

[12] Johnson, D. W. and Katavic, I. (1986), Survival and growth of sea bass (Dicentrachus labrax) larvae as influenced by temperature, salinity and delayed initial feeding. Aquaculture, 52, 11-19.

[13] Kim, W. S., Kim, J. M., Kim, M. S., Park, C. W. and Huh, H. T. (1998), Effects of sudden changes in salinity on endogenous rhythms of the spotted sea bass Lateolabrax sp. Mar. Biol., 131, 219-225.

[14] Luchini, L. (1981), Estudios ecológicos en la cuenca del rio Limay (Argentina). Revista de la Associación de Ciencias Naturales del Litoral, 12, 44-58 (in Spanish).

[15] Mac Donagh, E. J. (1934), Nuevos conceptos sobre la distribuición geográfica de los peces Argentinos baseado en expediciones del Museo de La Plata. Rev. Mus. La Plata, 34, 21-188 (in Spanish).

[16] Martty, H. (1992), Manual del pejerrey (nomenclatura-reproducción-pesca) Albatroz, Buenos Aires (in Spanish).

[17] Middaugh, D. P., Hemmer, M. J., Shenker, J. M and Takita, T. (1990), Laboratory culture of jacksmelt, Atherinopsis californiensis, and topsmelt, Atherinopsis affinis (pisces: Atherinidae), with a description of larvae. Calif. Fish and Game, 76, 4-13.

[18] Morgan, J. D. and Iwama, G. K. (1991), Effects of salinity on growth, metabolism, and ion regulation in juvenile rainbow and steelhead trout (Oncorhynchus mykiss) and fall chinook salmon (Oncorhynchus tshawytscha). Can. J. Fish. Aquat. Sci., 48, 2083-2094.

[19] Morgan, J. D., Sakamoto, T., Grau, E. G. and Iwama, G. K. (1997), Physiological and respiratory responses of the mozambique tilapia (Oreochromis mossambicus) to salinity acclimation. Comp. Biochem. Physiol., 117A, 391-398.

[20] Moser, M. L. and Hettler, W. F. (1989), Routine metabolism of juvenile spot, Leiostomus xanthurus (Lacépède), as a function of temperature, salinity and weight. J. Fish Biol., 35, 703-707.

[21] Rao, G. (1968), Oxygen consumption of rainbow trout in relation to activity and salinity. Can. J. Zool., 46, 781-786.

[22] Ringuelet, R. A., Salibián, A., Clavérie, E. and Ilhero, S. (1967), Limnologia química de las lagunas pampasicas (Provincia de Buenos Aires). Physis, 74, 201-221 (in Spanish).

[23] Ron, B., Shimoda, S. K., Iwama, G. K. and Grau, E. G. (1995), Relationships among ration, salinity, 17 α-methyltestosterone and growth in the euryhaline tilapia, Oreochromis mossambicus. Aquaculture, 135, 185-193.

[24] Saravia, J. R., Benavidez, R., Canziani, O., Ferreiro, V. and Hernandez, M. A. (1987), Lineamentos generales y regionales para um plan maestro de ordenamiento hídrico del territorio bonaerense Convenio MOSP Nación, Provincia de Buenos Aires (in Spanish).

[25] Strickand, J. D. H. and Parsons, T. R. (1972), A practical handbook of seawater analysis. Bull. Fish. Res. Bd Can., 167, 21-26.

[26] Strüssmann, C. A., Akaba, T., Ijima, K., Yamaguchi, K., Yoshizaki, G. and Takashima, F. (1997), Spontaneous hybridization in the laboratory and genetic markers for the identification of hybrids between two atherinid species, Odontesthes bonariensis (Valenciennes, 1835) and Patagonina hatcheri (Eigenmann, 1909). Aquac. Res., 28, 291-300.

[27] Strüssmann, C. A., Renard, P., Ling, H. and Takashima, F. (1994), Motility of pejerrey Odontesthes bonariensis spermatozoa. Fisheries Sci., 60, 9-13.

[28] Swanson, C. (1996), Early development of milkfish: effects of salinity on embryonic and larval metabolism, yolk absorption and growth. J. Fish Biol., 48, 405-421.

[29] Tsuzuki, M. Y. (1999), Effects of salinity on viability, physiology and stress induced responses in the pejerrey Odontesthes bonariensis and O. hatcheri PhD Thesis, Tokyo University of Fisheries, Tokyo, Japan.

[30] Tsuzuki, M. Y., Aikawa, H., Strüssmann, C. A. and Takashima, F. (2000a), Comparative survival and growth of embryos, larvae, and juveniles of pejerrey Odontesthes bonariensis and O. hatcheri at different salinities. J. Appl. Ichthyol. , 16, 126-130.

[31] Tsuzuki, M. Y., Aikawa, H., Strüssmann, C. A. and Takashima, F. (2000b), Physiological responses to salinity increases in the freshwater silversides Odontesthes bonariensis and O. hatcheri (Pisces, Atherinidae). Rev. Bras. Oceanogr (Braz. J. Oceanogr.), 48, 81-85.

[32] Vant Hoff, J. H. (1903), Physical chemistry in the service of the sciences University of Chicago Press, Chicago.

[33] Woo, N. Y. S. and Kelly, S. P. (1995), Effects of salinity and nutritional status on growth and metabolism of Sparus sarba in a closed seawater system. Aquaculture, 135, 229-238.

Brasil

Brasil

Effect of salinity on the oxygen consumption of larvae of the silversides Odontesthes hatcheri and O. bonariensis (Osteichthyes, Atherinopsidae)

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