Effect of low dissolved oxygen on the oxygen consumption rate and rhythm of the mudskipper Scartelaos gigas (Pisces, Gobiidae)
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- 作者:Jung-Ah Lee (1)
Jong-Wook Kim (1)
Sung-Yong Oh (1)
Soon-Kil Yi (1)
Il Noh (2)
Atsushi Ishimatsu (3)
Wan-Soo Kim (1) - 关键词:Mudskipper ; Scartelaos gigas ; Rhythm ; Oxygen consumption ; Dissolved oxygen ; Hypoxia
- 刊名:Fisheries Science
- 出版年:2012
- 出版时间:September 2012
- 年:2012
- 卷:78
- 期:5
- 页码:1013-1022
- 全文大小:636KB
- 参考文献:1. MacNae W (1968) A general account of the fauna and flora of mangrove swamps and forests in the Indo-West-Pacific region. Adv Mar Biol 6:73-70 CrossRef
2. Zhang J, Taniguchi T, Takita T, Ali AB (2003) A study on the epidermal structure of / Periophthalmodon and / Periophthalmus mudskippers with reference to their terrestrial adaptation. Ichthyol Res 50:310-17 CrossRef
3. Zhang J, Taniguchi T, Takita T, Ali AB (2000) On the epidermal structure of / Boleophthalmus and / Scartelaos mudskippers with reference to their adaptation to terrestrial life. Ichthyol Res 47:359-66 CrossRef
4. Takita T, Agusnimar, Ali AB (1999) Distribution and habitat requirements of oxudercine gobies (Gobiidae: Oxudercinae) along the Straits of Malacca. Ichthyol Res 46:131-38
5. Clayton DA (1993) Mudskippers. Oceanogr Mar Biol Annu Rev 31:507-77
6. Iwata A, Jeon S-R (1987) First record of four Gobiid fishes from Korea. Kor J Lim 20:1-2
7. Lin P-L, Shao K-T, Chen J-P (1994) Five new records of coastal fishes from western Taiwan. Zool Stud 33:174-76
8. Kim JK, Kim JY, Kim JI, Kim ST, Hwang SD, Seo YI, Sim DS, Chang DS, Choi JI, Park JH, Kim SY, Jeong SJ, Chu EK, Han KH, Oh CW (2005) Population dynamics of mudskippers in the southwestern Korea (in Korean). In: NFRDI (ed) NFRDI Technical Report in 2004. NFRDI, Busan, pp 225-72
9. Park KD, Kim JK, Chang DS, Kim JI, Oh CW (2008) Age and growth of the Mudskipper, / Scartelaos gigas (Perciformes, Gobiidae) from Korea. Anim Cells Syst 12:305-11 CrossRef
10. Kim JK, Baek H-J, Kim J-W, Chang D-S, Kim J-I (2011) Sexual maturity and early life history of the mudskipper / Scartelaos gigas (Pisces, Gobiidae): implications for conservation. Fish Aquat Sci 14:403-10
11. Lee HJ, Martinez CA, Hertzberg KJ, Hamilton AL, Graham JB (2005) Burrow air phase maintenance and respiration by the mudskipper / Scartelaos histophorus (Gobiidae: Oxudercinae). J Exp Biol 208:169-77 CrossRef
12. Ishimatsu A, Hishida Y, Takitia T, Kanda T, Oikawa S, Takeda T, Khoo K-H (1998) Mudskippers store air in their burrows. Nature 391:237-38 CrossRef
13. Chew SF, Lim ALL, Low WP, Lee CGL, Chan KM, Ip YK (1990) Can the mudskipper, / Periophthalmus chrysospilos, tolerate acute environmental hypoxic exposure? Fish Physiol Biochem 8:221-27 CrossRef
14. Ip YK, Chew SF, Low WP (1991) Effects of hypoxia on the mudskipper, / Periophthalmus chrysospilos (Bleeker, 1853). J Fish Biol 38:621-23 CrossRef
15. Chew SF, Ip YK (1992) Tolerance of the mudskipper, / Boleophthalmus boddaerti, to a lack of oxygen. Zool Sci 9:227-30
16. Chew SF, Ip YK (1992) Biochemical adaptations of the mudskipper, / Boleophthalmus boddaerti, to a lack of oxygen. Mar Biol 112:567-71 CrossRef
17. Chew SF, Ip YK (1992) Cyanide detoxification in the mudskipper, / Boleophthalmus boddaerti. J Exp Zool 261:1- CrossRef
18. Chew SF, Ip YK (1993) Respiration in the muscle mitochondria of the mudskipper / Boleophthalmus boddaerti. Comp Biochem Physiol 104B:681-88
19. Mattias AT, Rantin FT, Fernandes MN (1998) Gill respiratory parameters during progressive hypoxia in the facultative air-breathing fish, / Hypostomus regani (Loricariidae). Comp Biochem Physiol 120A:311-15
20. Aguilar NM, Ishimatsu A, Ogawa K, Huat KK (2000) Aerial ventilatory responses of the mudskipper, / Periophthalmodon schlosseri, to altered aerial and aquatic respiratory gas concentrations. Comp Biochem Physiol 127A:285-92
21. Oliveira RD, Lopes JM, Sanches JR, Kalinin AL, Glass ML, Rantin FT (2004) Cardiorespiratory responses of the facultative air-breathing fish jeju, / Hoplerythrinus unitaeniatus (Teleostei, Erythrinidae), exposed to graded ambient hypoxia. Comp Biochem Physiol 139A:479-85
22. Jucá-Chagas R (2004) Air breathing of the neotropical fishes / Lepidosiren paradoxa, / Hoplerythrinus unitaeniatus and / Hoplosternum littorale during aquatic hypoxia. Comp Biochem Physiol 139A:49-3
23. Fritsche R (1990) Effects of hypoxia on blood pressure and heart rate in three marine teleosts. Fish Physiol Biochem 8:85-2 CrossRef
24. Heath AG (1995) Water pollution and fish physiology. CRC Press, New York
25. Koga H, Noguchi T, Nakatake K (1989) Studies on artificial propagation of mud skipper / Boleophthalmus pectinirostris (Linnaeus)—I. Rearing of adult mud skipper (in Japanese with English abstract). Bull Saga Prefect Ariake Fish Exp Stn 11:1-
26. Ryu B-S, Kim I-S, Choi Y (1995) Ecology and life history of / Boleophthalmus pectinirostris in Korea (in Korean with English abstract). J Korean Fish Soc 28:316-24
27. Kim WS, Jeon JK, Lee SH, Huh HT (1996) Effects of pentachlorophenol (PCP) on the oxygen consumption rate of the river puffer fish, / Takifugu obscurus. Mar Ecol Prog Ser 143:9-4 CrossRef
28. Kim WS, Yoon SJ, Moon HT, Lee TW (2002) Effects of water temperature changes on the endogenous and exogenous rhythms of oxygen consumption in glass eels / Anguilla japonica. Mar Ecol Prog Ser 243:209-16 CrossRef
29. Yoon SJ, Kim JK, Myung JG, Kim WS (2003) Comparison of oxygen consumption patterns between wild and cultured black rockfish / Sebastes schlegeli. Fish Sci 69:43-9 CrossRef
30. Dowse HB, Ringo JM (1989) The search for hidden periodicities in biological time series revisited. J Theor Biol 139:487-15 CrossRef
31. Ip YK, Low WP (1990) Lactate production in the gills of the mudskipper / Periophthalmodon schlosseri exposed to hypoxia. J Exp Zool 253:99-01 CrossRef
32. Chew SF, Ip YK (1990) Differences in the responses of two mudskippers, / Boleophthalmus boddaerti and / Periophthalmus chrysospilos, to change in salinity. J Exp Zool 256:227-31 CrossRef
33. Gordon MS, Ng NW, Yip AYW (1978) Aspects of the physiology of terrestrial life in amphibious fishes III. The Chinese mudskipper / Periophthalmus cantonensis. J Exp Biol 72:57-5
34. Sloman KA (2011) Behavioral responses to the environment/Behavioral responses to hypoxia. In: Anthony PF (ed) Encyclopedia of fish physiology. Elsevier, New York, pp 765-71 CrossRef
35. Kim WS, Huh HT, Huh SH, Lee TW (2001) Effect of salinity on endogenous rhythm of the Manila clam / Ruditapes philippinarum (Bivalvia: Veneridae). Mar Biol 138:157-62 CrossRef
36. Kim WS, Huh HT, Je JG, Han KN (2003) Evidence of two-clock control of endogenous rhythm in the Washington clam, / Saxidomus purpuratus. Mar Biol 142:305-09
37. Gibson RN (1992) Tidally-synchronised behaviour in marine fishes. In: Ali MA (ed) Rhythms in fishes. Plenum, New York, pp 63-1 CrossRef
38. Schwassmann HO (1971) Biological rhythms. In: Hoar WS, Randall DJ (eds) Fish Physiology. Academic, New York, pp 371-28
39. Nishikawa M, Ishibashi T (1975) Entrainment of the activity rhythm by the cycle of feeding in the mud-skipper, / Periophthalmus cantonensis. Zool Mag (Tokyo) 84:184-89
40. Kavaliers M (1981) Period lengthening and disruption of socially facilitated circadian activity rhythms of goldfish by lithium. Physiol Behav 27:625-28 CrossRef
41. Spieler RE, Noeske TA (1984) Effects of photoperiod and feeding schedule on diel variations of locomotor activity, cortisol, and thyroxine in goldfish. Trans Am Fish Soc 113:528-39 CrossRef
42. Davis JC (1975) Minimal dissolved oxygen requirements of aquatic life with emphasis on Canadian species: a review. J Fish Res Board Can 32:2295-332 CrossRef
43. Beamish FWH (1964) Respiration of fishes with special emphasis on standard oxygen consumption. III. Influence of oxygen. Can J Zool 42:355-66 CrossRef
44. Lee KS, Ishimatsu A, Jeon JK (2005) Cardiorespiratory regulation in the Japanese amberjack ( / Seriola quinqueradiata) exposed to acute hypoxia (in Korean with English abstract). J Korean Fish Soc 38:106-11
45. Peyraud-Waitzenegger M, Soulier P (1989) Ventilator and circulatory adjustments in the European eel ( / Anguilla anguilla L.) exposed to short term hypoxia. Exp Biol 48:107-22 - 作者单位:Jung-Ah Lee (1)
Jong-Wook Kim (1)
Sung-Yong Oh (1)
Soon-Kil Yi (1)
Il Noh (2)
Atsushi Ishimatsu (3)
Wan-Soo Kim (1)
1. Marine Ecosystem Research Division, Korea Institute of Ocean Science & Technology, Ansan P.O. Box 29, Seoul, 425-600, Korea
2. Division of Marine Environmental and Bioscience, Korea Maritime University, 727 Taejong-ro, Yeongdo-Gu, Busan, 606-791, Korea
3. Institute for East China Sea Research, Nagasaki University, 1551-7 Tairamachi, Nagasaki, 851-2213, Japan
文摘
The mudskipper Scartelaos gigas is expected to experience repeated severe hypoxia in its environment. Hence, we conducted experiments on the oxygen consumption rate (OCR) and OCR rhythm of S.?gigas at low graded dissolved oxygen (DO) levels, without access to atmospheric air, to estimate its tolerance to hypoxia. A dominant circadian OCR rhythm was observed at the control DO level of 6.96-.78?mg?O2/l. This rhythm was unchanged until 2.06?mg?O2/l, even though the amplitude of the peak was somewhat diminished at 2.06-.87?mg?O2/l. The OCR rhythm amplitude was greatly diminished and the rhythm period was also greatly changed at 1.23-.05?mg?O2/l. Nevertheless, the mean OCR (0.11?ml?O2/g WW/h) at 1.23-.05?mg O2/l was similar to that of control (0.12?ml O2/g?WW/h). Thus, the weakness and period change of the OCR rhythm kept the metabolic rate level similar to control. These results suggest that S.?gigas does not have normal metabolic activity at 1.23-.05?mg O2/l but barely manages to endure this DO level as a pre-emergency state. This species could be inhibited under a longer maintenance period at DO level of 1.23-.05?mg?O2/l or still lower. It can be concluded that S.?gigas is quite tolerant to low DO environment and may have a specific strategy for such tolerance.