Climate change may affect fish through an interaction of parental and juvenile environments

详细信息    查看全文

• 作者：J. M. Donelson (12) jennifer.donelson@my.jcu.edu.au
  P. L. Munday (1)
  M. I. McCormick (1)
• 关键词：Compensatory growth – Coral reef fish – Food availability – Temperature – Parental effects – Survival
• 刊名：Coral Reefs
• 出版年：2012
• 出版时间：September 2012
• 年：2012
• 卷：31
• 期：3
• 页码：753-762
• 全文大小：483.4 KB
• 参考文献：1. Almany GR, Webster MS (2006) The predation gauntlet: early post-settlement mortality in reef fishes. Coral Reefs 25:19–22
  2. álvarez D, Metcalfe NB (2007) The tradeoff between catch-up growth and escape speed: variation between habitats in the cost of compensation. Oikos 116(1144):1151
  3. Angilletta MJ Jr, Wilson RS, Navas CA, James RS (2003) Tradeoffs and the evolution of thermal reaction norms. Trends Ecol Evol 18:234–240
  4. Arendt J, Wilson DS, Stark E (2001) Scale strength as a cost of rapid growth in sunfish. Oikos 93:95–100
  5. Bergenius MAJ, Meekan MG, Robertson R, McCormick MI (2002) Larval growth predicts recruitment success of a coral reef fish. Oecologia 131:521–525
  6. Booth D, Alquezar R (2002) Food supplementation increases larval growth, condition and survival of Acanthochromis polyacanthus. J Fish Biol 60:1126–1133
  7. Brander K (2009) Impacts of climate change on fisheries. Impacts of climate change on fisheries. J Mar Syst 79:389–402
  8. Bret JR (1971) Energetic responses if salmon to temperature. A study in some thermal relations in the physiological and freshwater ecology of stockeye salmon (Oncorhynchs nerka). Am Zool 11:99–113
  9. Brown NP, Shields RJ, Bromage NR (2006) The influence of water temperature on spawning patterns and egg quality in the Atlantic halibut (Hippoglossus hippoglossus L.). Aquaculture 261:993–1002
  10. Clarke A, Johnston NM (1999) Scaling of metabolic rate with body mass and temperature in teleost fish. J Anim Ecol 68:893–905
  11. Deutsch CA, Tewksbury JJ, Huey RB, Sheldon KS, Ghalambor CK, Haak DC, Martin PR (2008) Impacts of climate warming on terrestrial ectotherms across latitude. Proc Natl Acad Sci USA 105:6668–6672
  12. Donelson JM, McCormick MI, Munday PL (2008) Parental condition affects early life-history of a coral reef fish. J Exp Mar Biol Ecol 360:109–116
  13. Donelson JM, Munday PL, McCormick MI (2009) Parental effects on offspring life histories: when are they important? Biol Lett 5:262–265
  14. Donelson JM, Munday PL, McCormick MI, Pankhurst NW, Pankhurst PM (2010) Effects of elevated water temperature and food availability on the reproductive performance of a coral reef fish. Mar Ecol Prog Ser 401:233–245
  15. Farrell AP (2009) Environment, antecedents and climate change: lessons from the study of temperature physiology and river migration of salmonids. J Exp Biol 212:3771–3780
  16. Forrester GE (1990) Factors influencing the juvenile demography of a coral reef fish. Ecology 71:1666–1681
  17. Gagliano M, McCormick MI (2007) Maternal condition influences phenotypic selection on offspring. J Anim Ecol 76:174–182
  18. Ganachaud AS, Gupta AS, Orr JC, Wijffles SE, Ridgway KR, Hemer MA, Maes C, Steinberg CR, Tribollet AD, Qiu B, Kruger JC (2011) Observed and expected changes to the tropical Pacific Ocean. In: Bell JD, Johnson JE, Hobday AJ (eds) Vulnerability of Tropical Pacific fisheries and aquaculture to climate change. Secretariat of the Pacific Community, Noumea, pp 101–187
  19. Gardiner NM, Munday PL, Nilsson GE (2010) Counter-gradient variation in respiratory performance of coral reef fishes at elevated temperatures. PLoS ONE 5:1–13
  20. Green BS (2008) Maternal effects in fish populations. Adv Mar Biol 54:1–105
  21. Harley CDG, Randall Hughes A, Hultgren KM, Miner BG, Sorte CJB, Thornber CS, Rodriguez LF, Tomanek L, Williams SL (2006) The impacts of climate change in coastal marine systems. Ecol Lett 9:228–241
  22. Hays GC, Richardson AJ, Robinson C (2005) Climate change and marine plankton. Trends Ecol Evol 20:337–344
  23. Hazel JR, Prosser CL (1974) Molecular mechanism of temperature compensation in poikilotherms. Physiol Rev 54:620–677
  24. Hilder ML, Pankhurst NW (2003) Evidence that temperature change cues reproductive development in the spiny damselfish, Acanthochromis polyacanthus. Environ Biol Fish 66:187–196
  25. Hoey AS, McCormick MI (2004) Selective predation for low body condition at the larval-juvenile transition of a coral reef fish. Oecologia 139:23–29
  26. Holmes TH, McCormick MI (2009) Influence of prey body characteristics and performance on predator selection. Oecologia 159:401–413
  27. Houde ED (1989) Comparative growth, mortality and energetics of marine fish larvae: temperature and implied latitudinal effects. Fish Bull 87:471–495
  28. Jobling M (1996) Temperature and growth: modulation of growth rate via temperature change. In: Wood CM, McDonald DG (eds) Global warming: implications for freshwater and marine fish. Cambridge University Press, Cambridge, pp 225–253
  29. Johansen JL, Jones GP (2011) Increasing ocean temperature reduces the metabolic performance and swimming ability of coral reef damselfishes. Global Change Biol 17:2971–2979
  30. Johnsson JI, Bohlin T (2006) The cost of catching up: increased winter mortality following structural growth compensation in the wild. Proc R Soc Lond B Biol Sci 273:1281–1286
  31. Jones GP (1986) Food availability affects growth in a coral reef fish. Oecologia 70:136–139
  32. Kerrigan BA (1997) Variability in larval development of the tropical reef fish Pomacentrus amboinensis (Pomacentridae): the parental legacy. Mar Biol 127:395–402
  33. King HR, Pankhurst NW, Watts M (2007) Reproductive sensitivity to elevated water temperatures in female Atlantic salmon is heightened at certain stages of vitellogenesis. J Fish Biol 70:90–205
  34. Lough J (2007) Climate and climate change on the Great Barrier Reef. In: Johnson JE, Marshall PA (eds) Climate change and the Great Barrier Reef: a vulnerability assessment. Great Barrier Reef Marine Park Authority, Townsville, pp 15–50
  35. Manning NJ, Kime DE (1985) The effect of temperature on testicular steroid production in the rainbow trout, Salmo gairdneri, in vivo and in vitro. Gen Comp Endocrinol 57:377–382
  36. Marshall DJ, Cook CN, Emlet RB (2006) Offspring size effects mediate competitive interactions in a colonial marine invertebrate. Ecology 87:214–225
  37. McCormick MI (2003) Consumption of coral propagules after mass spawning enhances larval quality of damselfish through maternal effects. Oecologia 136:37–45
  38. McKinnon AD, Duggan S, Carleton JH, B?ttger-Schnack R (2008) Summer planktonic copepod communities of Australia’s North West Cape (Indian Ocean) during the 1997–99 El Ni?o/La Ni?a. J Plankton Res 30(839):855
  39. Meekan MG, Fortier L (1996) Selection for fast growth during the larval life of Atlantic cod Gadus morhua on the Scotian Shelf. Mar Ecol Prog Ser 137:25–37
  40. Meekan MG, Carleton JH, McKinnin KF, Furnas M (2003) What determines the growth of tropical reef fish larvae in the plankton: food or temperature? Mar Ecol Prog Ser 256:193–204
  41. Metcalfe NB, Monaghan P (2001) Compensation for a bad start: grow now, pay later? Trend Ecol Evol 16:254–260
  42. Morgan IJ, Metcalfe NB (2001) Deferred costs of compensatory growth after autumnal food shortage in juvenile salmon. Proc R Soc Lond B Biol Sci 268:295–301
  43. Munday PL, Leis JM, Lough JM, Paris CB, Kingsford MJ, Berumen ML, Lambrechts J (2009) Climate change and coral reef connectivity. Coral Reefs 28:379–395
  44. Nilsson GE, Crawley N, Lunde IG, Munday PI (2009) Elevated temperature reduces the respiratory scope of coral reef fishes. Global Change Biol 15:1405–1412
  45. Nilsson GE, ?stlund-Nilsson S, Munday PL (2010) Effects of elevated temperature on coral reef fishes: loss of hypoxia tolerance and inability to acclimate. Comp Biochem Physiol Part A 156:389–393
  46. Pankhurst NW, Porter MJR (2003) Cold and dark warm and light: variations on the theme of environmental control of reproduction. Fish Physiol Biochem 28:385–389
  47. Pankhurst NW, Thomas PM (1998) Maintenance at elevated temperature delays the steroidogenic and ovulatory responsiveness of rainbow trout Oncorhynchus mykiss to luteinizing hormone releasing hormone analogue. Aquaculture 166:163–177
  48. Pankhurst NW, Purser GJ, Van Der Kraak G, Thomas PM, Forteath GNR (1996) Effect of holding temperature on ovulation, egg fertility, plasma levels or reproductive hormones and in vitro ovarian steroidogenesis in the rainbow trout Oncorhynchus mykiss. Aquaculture 146:277–290
  49. Poloczanska ES, Babcock RC, Butler A, Hobday A, Hoegh-Guldberg O, Kunz TJ, Matear R, Milton DA, Okey TA, Richardson AJ (2007) Climate change and Australian marine life. Oceanogr Mar Biol Annu Rev 45:407–478
  50. P?rtner HO, Farrell AP (2008) Physiology and climate change. Science 322:690–692
  51. P?rtner HO, Knust R (2007) Climate change affects marine fishes through the oxygen limitation of thermal tolerance. Science 315:95–97
  52. Richardson AJ (2008) In hot water: zooplankton and climate change. ICES J Mar Sci 65:279–295
  53. Rombough PJ (1997) The effects of temperature on embryonic and larval development. In: Wood CM, McDonald DG (eds) Global warming: implications for freshwater and marine fish. Cambridge University Press, Cambridge, pp 177–223
  54. Rost B, Zondervan I, Wolf-Gladrow D (2008) Sensitivity of phytoplankton to future changes in ocean carbonate chemistry: current knowledge, contradictions and research directions. Mar Ecol Prog Ser 373:227–237
  55. Rothlisberg PC, Jackson CJ (1982) Temporal and spatial variation of plankton abundance in the Gulf of Carpentaria, Australia 1975–1977. J Plankton Res 4:19–40
  56. Sale PF, Ferrell DJ (1988) Early survivorship of juvenile coral-reef fishes. Coral Reefs 7:117–124
  57. Sarmiento JL, Slater R, Barber R, Bopp L, Doney SC, Hirst AC, Kleypas J, Matear R, Mikolajewicz U, Monfray P, Soldatov V, Spall SA, Stouffer R (2004) Response of ocean ecosystems to climate warming. Global Biochem Cycles 18:1–19
  58. Sponaugle S, Grorud-Colvert K, Pinkard D (2006) Temperature-mediated variation in early life history traits and recruitment success of the coral reef fish Thalassoma bifasciatum in the Florida Keys. Mar Ecol Prog Ser 308:1–15
  59. Tewksbury JJ, Huey RB, Deutsch CA (2008) Putting heat on tropical animals. Science 320:1296–1297
  60. Van Der Kraak G, Pankhurst NW (1997) Temperature effects on the reproductive performance of fish. In: Wood CM, McDonald DG (eds) Global warming: implications for freshwater and marine fish. Cambridge University Press, Cambridge, pp 159–176
  61. van der Sman J, Phillips NE, Pfister CA (2009) Relative effects of maternal and juvenile food availability for a marine snail. Ecology 90:3119–3125
  62. Wilson DT, Meekan MG (2002) Growth-related advantages for survival to the point of replenishment in the coral reef fish Stegastes partitus (Pomacentridae). Mar Ecol Prog Ser 231:247–260
  63. Wright SJ, Muller-Landau HC, Schipper J (2009) The future of tropical species on warmer planet. Conserv Biol 23:1418–1426
• 作者单位：1. ARC Centre of Excellence for Coral Reef Studies and School of Marine and Tropical Biology, James Cook University, Townsville, QLD 4811, Australia2. Climate Adaptation Flagship CSIRO, Hobart, TAS 7001, Australia
• ISSN：1432-0975

文摘

Changes to tropical sea surface temperature and plankton communities are expected to occur over the next 100 years due to climate change. There is a limited understanding of how these environmental changes are likely to impact coral reef fishes, especially in terms of population replenishment through the quality of progeny produced. The present study investigated the effect that elevated sea water temperature and changes to food availability may have on the production of offspring by the reef fish Acanthochromis polyacanthus (Pomacentridae), as well as the performance of progeny in environments of varying food availability. An orthogonal design of three water temperatures and two food availabilities (high and low ration) was used, with water temperatures being the current-day average for the collection location (28.5 °C), +1.5 °C (30.0 °C) and +3.0 °C (31.5 °C), representing likely temperatures by 2100. Generally, an increase in the water temperature for adults resulted in a reduction in the size, weight and amount of yolk possessed by newly hatched offspring. Offspring whose parents were maintained under elevated temperature (30.0 °C high ration) had lower survival than offspring produced by parents at the current-day temperature (28.5 °C high ration) at 15 days post-hatching, but only when juveniles were reared under conditions of low food availability. In contrast, by 30 days post-hatching, the growth and condition of these offspring produced by parents held under elevated temperature (30.0 °C high ration) were the best of all treatment groups in all levels of juvenile food availability. This result illustrates the potential for initial parental effects to be modified by compensatory growth early in life (within 1 month) and that parental effects are not necessarily long lasting. These findings suggest that the performance of juvenile reef fish in future ocean conditions may not only depend on initial parental effects, but the interaction between their parentally mediated phenotype and their present food availability.