Advanced SearchSearch Tips
Effect of Salinity on Survival, Oxygen Consumption and Blood Physiology of Korean Rockfish Sebastes schlegelii
facebook(new window)  Pirnt(new window) E-mail(new window) Excel Download
  • Journal title : Ocean and Polar Research
  • Volume 36, Issue 2,  2014, pp.135-143
  • Publisher : Korea Institute of Ocean Science & Technology
  • DOI : 10.4217/OPR.2014.36.2.135
 Title & Authors
Effect of Salinity on Survival, Oxygen Consumption and Blood Physiology of Korean Rockfish Sebastes schlegelii
Oh, Sung-Yong; Kim, Chong-Kwan; Jang, Yo-Soon; Choi, Hee-Jung; Myoung, Jung-Goo;
  PDF(new window)
The effect of salinity on the survival, oxygen consumption and blood physiology of Korean rockfish Sebastes schlegelii (body weight , ) was investigated at nine different salinities of 33.4 (control), 33.1, 32.8, 32.2, 31.0, 28.7, 23.9, 14.5 and 3.8 psu, respectively. Survival and blood physiology were measured at each salinity in two separate trials of 96 and 24 hr duration, respectively. Oxygen consumption rate (OCR) was determined at stepwise salinity exposure ( psu) with an interval of 24 hr for each salinity. No death of fishes were observed in the range of 33.4 to 14.5 psu, but the survival rate was reduced to 26.7% at 3.8 psu after 96 hr. The OCRs were not significantly different in the range 33.4 to 28.7 psu (p > 0.05), but significantly increased until 14.5 psu and then drastically decreased at 3.8 psu compared to the control (p < 0.05). The concentrations of plasma and were significantly lower in fish exposed at 3.8 psu compared to the control (p < 0.05). The results of this study provide evidence that S. schlegelii exposed to concentrations below 23.9 psu show significant physiological responses to tolerate salinity changes under the experimental conditions we established.
Sebastes schlegelii;salinity;survival;oxygen consumption;blood physiology;
 Cited by
염분농도에 따른 치어기 은대구(Anoplopoma fimbria)의 혈액학적 성상, 혈장성분 및 항산화반응의 변화,김준환;박희주;황인기;김도형;오철웅;이정식;강주찬;

한국수산과학회지, 2016. vol.49. 6, pp.830-837 crossref(new window)
Alterations of Hematological Parameters, Plasma Constituents and Antioxidant Responses in the Sablefish Anoplopoma fimbria Depending on Salinity, Korean Journal of Fisheries and Aquatic Sciences, 2016, 49, 6, 830  crossref(new windwow)
강주찬, 진평, 이정식, 신윤경, 조규석 (2000) 날개망둑 치어의 생존, 성장 및 산소 소비율에 미치는 염분의 영향. 한국수산학회지 33:408-412 (Kang J-C, Chin P, Lee J-S, Shin Y-K, Cho K-S (2000) Effects of salinity on survival, growth and oxygen consumption rates of the juvenile gobiid, Favonigobius gymnauchen. J Korean Fish Soc 33(5):408-412 (in Korean))

강주찬, 지정훈, 김성길, 박경수, 박승윤 (2004) 염분 농도에 따른 두줄망둑, Tridentiger trigonocephalus 치어의 내성. 한국환경생물학회지 22:153-158 (Kang J-C, Lee J-H, Kim S-G, Park GS, Park SY (2004) Tolerance of juvenile gobiidae, Tridentiger trigonocephalus exposed to various salinity. Korean J Environ Biol 22:153-158 (in Korean))

김맹진, 정상철, 송춘복 (2004) 염분에 따른 넙치(Paralichthys olivaceus)의 성장과 생존율. 한국어류학회지 16:100-106 (Kim MJ, Chung SC, Song CB (2004) Effects of salinity on growth and survival of olive flounder, Paralichthys olivaceus. Korean J Ichthyol 16:100-106 (in Korean))

김영수, 도용현, 민변화, 임한규, 이복규, 장영진 (2009) 염분 변화 속도를 달리한 담수순화 과정에서 강도다리 Platichthys stellatus의 생리학적 반응. 한국양식학회지 22:28-33 (Kim YS, Do YH, Min BH, Lim HK, Lee BK, Chang YJ (2009) Physiological responses of starry flounder Platichthys stellatus during freshwater acclimation with diffrent speeds in salinity change. J Aquaculture 22:28-33 (in Korean))

오승용, 노충환 (2006) 수온과 광주기에 따른 볼락, Sebastes inermis 치어의 산소 소비율. 한국양식학회지 19:210-215 (Oh S-Y, Noh CH (2006) Effects of water temperature and photoperiod on the oxygen consumption rate of juvenile dark-banded rockfish, Sebastes inermis. J Aquaculture 19:210-215 (in Korean) )

이정열, 김덕배 (2005) 급격한 염분변화에 따른 황복의 산소 소비와 질소 배설. 한국양식학회지 18:45-51 (Lee J-Y, Kim D-B (2005) The optimum salinity and the effects of the rapid salinity change on oxygen consumption and nitrogen excretion in river puffer, Takifugu obscrus. J Aquaculture 18:45-51 (in Korean))

임한규, 정민환, 한형균, 이종하, 장영진 (2004) 수온, 염분 및 광주기에 따른 잡종 striped bass(Morone chrysops ${\time}$ M. saxatilis)의 산소소비. 한국양식학회지 17:258-261 (Lim HK, Jeong MH, Han H-K, Lee JH, Chang YJ (2004) Oxygen consumption of hybrid striped bass (Morone chrysops () M. saxatilis ()) exposed to different temperature, salinity and photoperiod. J Aquaculture 17:258-261 (in Korean))

임한규, 한형균, 이종하, 정민환, 허준욱 (2005) 단계적 염분 변화가 striped bass 잡종(Morone chrysops ${\time}$ M. saxatilis)의 생리적 반응에 미치는 영향. 한국어류학회지 17:43-48 (Lim HK, Han H-K, Lee J-H, Jeong MH, Hur JW (2005) Effects of gradual change of salinity on physiological response in hybrid striped bass (Morone chrysops ${\time}$ M. saxatilis). J Aquaculture 17:43-48 (in Korean) )

장영진, 민병화, 장해진, 허준욱 (2002) 해수사육에서 담수사육으로, 담수사육에서 해수사육으로 전환된 감성돔 치어, Acanthopagrus schlegeli의 혈액 생리학적 비교. 한국수산학회지 35:595-600 (Chang YJ, Min BH, Chang HJ, Hur JW (2002) Comparison of blood physiology in juvenile black seabream (Acanthopagrus schlegeli) reared in converted freshwater from seawater and seawater from freshwater. J Korean Fish Soc 35:595-600 (in Korean)) crossref(new window)

한형균, 강덕영, 전창영, 장영진 (2003) 염분 변화에 따른 농어, Lateolabrax japonicus 유어의 생리 반응과 성장 차이. 한국양식학회지 16:31-36 (Han H-K, Kang D-Y, Jun C-Y, Chang Y-J (2003) Effect of salinity change on physiological response and growth of yearling sea bass, Lateolabrax japonicus. J Aquaculture 16:31-36 (in Korean))

허준욱, 이정열, 김용호, 박인석, 장영진 (2006) 양식 넙치, Paralichthys olivaceus의 혈액학적 변화 및 생존율에 미치는 염분의 영향. 한국환경생물학회지 24:380-386 (Hur JW, Lee JY, Kim YH, Park I-S, Chang YJ (2006) Effects of salinity on hematological changes and survival of cultured olive flounder, Paralichthys olivaceus. Korean J Environ Biol 24:380-386 (in Korean))

허준욱, 이복규, 장영진, 이종관, 임영수, 이종하, 박철환, 김병기 (2002) 사육수의 저염분 변화에 따른 넙치 (Paralichthys olivaceus)의 스트레스 반응. 한국양식학회지 15:69-75 (Hur J-W, Lee B-K, Chang Y-J, Lee J-K, Lim Y-S, Lee J-H, Park C-H, Kim B-K (2002) Stress responses of olive flounder Paralichthys olivaceus to hyposalinity. J Aquaculture 15:69-75 (in Korean))

허준욱, 장영진, 이복규, 이정열 (2003) 저염분에서 사육한 양식 넙치(Paralichthys olivaceus)의 생리적 반응, 생존율 및 성장. 한국어류학회지 15:77-86 (Hur JW, Chang YJ, Lee BK, Lee JY (2003) Effects of hypo-salinity on physiological response, survival and growth of cultured olive flounder (Paralichthys olivaceus). Korean J Ichthyol 15:77-86 (in Korean))

Abud EOA (1992) Effects of salinity and weight on routine metabolism in the juvenile croacker, Micropogonias furnieri (Desmarest 1823). J Fish Biol 40:471-472 crossref(new window)

Altinok I, Grizzle JM (2003) Effect of low salinities on oxygen consumption of selected euryhaline and stenohaline freshwater fish. J World Aquacult Soc 34:113-117 crossref(new window)

Arnason T, Magnadottir B, Bjornsson B, Steinarsson A, Bjornsson BT (2013) Effects of salinity and temperature on growth, plasma ions, cortisol and immune parameters of juvenile Atlantic cod (Gadus morhua). Aquaculture 380-383:70-79 crossref(new window)

Boeuf G, Payan P (2001) How should salinity influence fish growth? Comp Biochem Physiol 130C:411-423

Brown AC, Terwillinger NB (1999) Developmental changes in oxygen uptake in Cancer magister (Dana) in response to changes in salinity and temperature. J Exp Mar Biol Ecol 241:179-192 crossref(new window)

Dalla Via J, Villani P, Gasteiger E, Niederstatter H (1998) Oxygen consumption in sea bass fingerling Dicentrachus labrax exposed to acute salinity and temperature changes: metabolic basis for maximum stocking density estimations. Aquaculture 169:303-313 crossref(new window)

Herrera M, Vargas-Chacoff L, Hachero I, Ruiz-Jarabo I, Rodiles A, Navas JI, Mancera JM (2009) Osmoregulatory changes in wedge sole (Dicologoglossa cuneata Moreau, 1881) after acclimation to different environmental salinities. Aquac Res 40:762-771 crossref(new window)

Imanpoor MR, Najafi E, Kabir M (2012) Effects of different salinity and temperature on the growth, survival, haematocrit and blood chemistry of goldfish (Carassius auratus). Aquac Res 43:332-338 crossref(new window)

Imsland AK, Gustavsson A, Gunnarsson S, Foss A, Arnason J, Arnarson I, Jonsson AF, Smaradottir H, Thorarensen H (2008) Effects of reduced salinities on growth, feed conversion efficiency and blood physiology of juvenile Atlantic halibut (Hippoglossus hippoglossus L.). Aquaculture 274:254-259 crossref(new window)

Iwama GK, Takemura A, Takano K (1997) Oxygen consumption rates of tilapia in freshwater, seawater, and hypersaline sea water. J Fish Biol 51:886-894 crossref(new window)

Jobling M (1982) A study of some factors affecting rates of oxygen consumption of plaice, Pleuronectes platessa L. J Fish Biol 20:501-516 crossref(new window)

Kirsch R, Meister MF (1982) Progressive processing of ingested water in the gut of seawater teleosts. J Exp Biol 98:67-81

Kirsch R, Humbert W, Simoneaux V (1985) The gut as an osmoregulatory organ, comparative aspects and special references to fishes. In: Gilles R, Gilles-Baillien M (eds) Transport Processes, Ion and Osmoregulation. Springer Verlag, Berlin, pp 265-277

Laycock J, Wish P (1983) Essential Endocrinology. 2nd. Oxford University Press, Oxford, 371 p

Martin TJ (1990) Osmoregulatory in three species of Ambassidae (Osteichthyes: Perciformes) from estuaries in Natai. S Afr J Zool 25:229-234 crossref(new window)

Mayer-Gostan N, Wendelaar Bonga SE, Balm P (1987) Mechanisms of hormone action on gill transport. Academic Press, San Diego, pp 211-238

Morgan JD, Iwama GK (1998) Salinity effects on oxygen consumption, gill Na^{+}$, K^{+}$-ATPase and ion regulation in juvenile coho salmon. J Fish Biol 53:1110-1119

Mosser ML, Hettler WF (1989) Routine metabolism of juvenile spot, Leiostomus xanthurus. J Fish Biol 35:703-707 crossref(new window)

Partridge GJ, Jenkins GI (2002) The effect of salinity on growth and survival of juvenile black bream (Acanthopagrus butcheri). Aquaculture 210:219-230 crossref(new window)

Perez-Robles J, Re AD, Giffard-Mena I, Diaz F (2012) Interactive effects of salinity on oxygen consumption, ammonium excretion, osmoregulation and Na^{+}$/K^{+}$-ATPase expression in the bullseye puffer (Sphoeroides annulatus, Jenyns 1842). Aquac Res 43:1372-1383 crossref(new window)

Salvato B, Cuomo V, Muro RD, Beltramini M (2001) Effects of environmental parameters on the oxygen consumption of four marine invertebrates: a comparative factorial study. Mar Biol 138:659-668 crossref(new window)

Schreck CB (1982) Stress and rearing of salmonids. Aquaculture 28:241-249 crossref(new window)

Tam WH, Birkett L, Makaran R, Payson PD, Whitney DK, Yu CKC (1987) Modification of carbohydrate metabolism and liver vitellogenic function in brook trout (Salvelinus fontinalis) by exposure to low pH. Can J Fish Aquat Sci 44:630-635 crossref(new window)

Wedemeyer GA (1996) Physiology of fish in intensive culture systems. Chapman & Hall, New York, 232 p

Wedemeyer GA, Yasutake WT (1977) Clinical methods for the assessment of the effects of environmental stress on fish health. Federal Government Series, U.S. Fish and Wildlife Service Technical paper 89, 18 p

Woo NYS, Fung ACY (1981) Studies on the biology of red sea bream. 2. Salinity adaptation. Comp Biochem Physiol 69A:237-242