What determines the growth of tropical reef fish larvae in the plankton: food or temperature?

Meekan, Mark; Carleton, John; McKinnon, A. David; Flynn, Kevin J.; Furnas, Miles

doi:10.3354/meps256193

Cited by 132 publications

(129 citation statements)

References 33 publications

(43 reference statements)

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“…This result differs from studies in temperate and other tropical regions where water temperature is thought to be one of the primary determinants of growth rates (Campana and Hurley 1989;Suthers and Sundby 1993;Meekan et al 2003). In tropical NW Australia, Meekan et al (2003) found that water temperature explained 30% of the variation in growth rate of a larval pomacentrid. These contrasting results may be due to the relatively small temporal (seasonal, monthly and diurnal) ranges in temperatures that occur in Punta de San Blas (Table 1).…”

Section: Growthcontrasting

confidence: 55%

“…However, recent work has also shown that in tropical reef fishes larval condition and/or growth are important determinants of survivorship in the planktonic (Bergenius et al 2002;Wilson and Meekan 2002;Meekan et al 2003), as well as in the post-settlement stage (Searcy and Sponaugle 2001;Vigliola and Meekan 2002;McCormick and Hoey 2004).…”

Section: Introductionmentioning

confidence: 99%

“…These may act either directly or indirectly to influence growth rates. For example, water temperature may determine developmental time, growth, swimming performance (Meekan et al 2003;Green and Fisher 2004) and the rate of yolk sac absorption (Fukahara 1990) of young fish. Additionally, some species exhibit an optimal temperature range for development, outside of which mortality and abnormalities increase (Polo et al 1991).…”

Section: Introductionmentioning

confidence: 99%

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Environmental influences on larval duration, growth and magnitude of settlement of a coral reef fish

et al. 2005

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The influence of environmental variables on the planktonic growth, pelagic larval duration and settlement magnitude was examined for the coral reef surgeonfish Acanthurus chirurgus. Newly settled fish were collected daily from patch reefs in the San Blas Archipelago, Caribbean Panama for 3.5 years. Environmental influences on growth were examined at three different life history stages: from 0 to 6 days, 7 to 25 days and from 26 to 50 days after hatching. Larval growth was correlated, using multiple regression techniques, with a combination of factors including solar radiation, rainfall, and along-shore winds. Depending on the life history stage, these accounted for 13-38% of the variation in growth rates when all the months were included in the analyses. Correlations between environmental variables and growth also varied among seasons and were stronger in the dry than in the wet season. During the dry season solar radiation, rainfall and along-shore winds described 57%, 86% and 74% of the variability in growth between 0 and 6 days, 7 and 25 days and 26 and 50 days, respectively. During the wet season rainfall, along-shore winds and temperature only described 38% of the variability in early growth and 27% of growth just before settlement. No significant model was found to describe growth 7-25 days after hatching during the wet season. Rainfall, solar radiation and along-shore winds were negatively correlated with growth up to 25 days after hatching but positively correlated as larvae approached settlement at a mean age of 52 days. Over 65% of the variability in pelagic larval duration was accounted for by a regression model that included solar radiation and along-shore winds. When data sets from wet and dry seasons were analysed separately, alongshore winds accounted for 67% of the change in larval duration in the dry season, and solar radiation accounted for 23% of the variation in larval duration in the wet season. Only 22% of the variability in settlement intensity could be described by solar radiation and temperature, when all months of the year were included in the analysis. Solar radiation and rainfall were included in a regression model that accounted for 40% of the variation in numbers of fish settling during the dry season. This study suggests that the levels of solar radiation, along-shore winds and rainfall during the early larval life can have important effects on the growth, larval duration and consequently, the settlement magnitude of marine fishes. Results also highlight the need to account for seasonality and ontogeny in studies of environmental influences.

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Section: Growthcontrasting

confidence: 55%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Environmental influences on larval duration, growth and magnitude of settlement of a coral reef fish

et al. 2005

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“…This is in agreement with other studies that have shown that shortly after hatching fish larvae dramatically improve their functional morphology, physiology and subsequent behavioral patterns resulting in advanced swimming performance and foraging success (Osse 1990, Porter & Theilacker 1999, Hunt von Herbing & Gallager 2000, Hunt von Herbing 2001. Similarly, increases in feeding were predicted under conditions of rising temperature, which has been shown to boost feeding rates in other studies on marine fish larvae (Houde 1989, Meekan et al 2003. The observed positive effect of temperature on feeding success might be the result of temperature affecting not only the larval physiology and therefore swimming performance but also the physics of the surrounding environment by decreasing its viscosity (Hunt von Herbing 2002).…”

Section: Discussionsupporting

confidence: 80%

Environmental factors influencing larval walleye pollock Theragra chalcogramma feeding in Alaskan waters

Porter

Ciannelli²,

Hillgruber³

et al. 2005

Mar. Ecol. Prog. Ser.

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This study examines potential interactions among the environmental variables likely to affect larval walleye pollock Theragra chalcogramma feeding in the sea. Walleye pollock larvae were sampled from Shelikof Strait, Gulf of Alaska, and from the eastern Bering Sea, with corresponding environmental data. Variables used in our study were time spent feeding, seawater temperature, light, prey density, wind speed and standard length of the larvae. We applied an additivity test to detect the presence of potential interactions among these variables and adopted an expansion of generalized additive models (GAMs) that allowed the inclusion of interaction terms in a non-parametric regression analysis. After testing all possible 2-way interactions among these variables, we found 4 significant terms: (1) time feeding-standard length, (2) temperature-light, (3) light -wind speed and (4) prey density-standard length. The most influential interaction term was the light -wind speed interaction, which caused a decrease of the model-generalized cross-validation (GCV, whereby lower values indicate more parsimonious models) from 0.0402 (for a model with all variables but no interaction term) to 0.0290 (for a model with all variables and this interaction), and an increase of the model explained variance by 7% (R 2 = 0.89 versus 0.82). This result indicates that the effect of wind speed (turbulence) on larval walleye pollock feeding is dependent upon the amount of light available. This may be due to vertical movements in the water column by both walleye pollock larvae and their prey in response to turbulence. KEY WORDS: Larval fish feeding · Walleye pollock larvae · Generalized additive models Resale or republication not permitted without written consent of the publisher

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“…Higher metabolic rates mean that fish have higher basal energy demands at higher temperatures. Larval growth rates also increase with temperature for both temperate (Blaxter 1991;Benoît et al 2000) and tropical species (McCormick and Molony 1995;Meekan et al 2003;Green and Fisher 2004), with temperature explaining up to 89% of variation in growth rates among cohorts of some species (Sponaugle and Cowen 1996). Thermal reaction norms of growth in larval fish tend to be approximately linear until the lethal upper thermal limit is reached, at least in the majority of species studied to date (Sponaugle and Cowen 1996;Rombough 1997).…”

Section: Effects On Larvaementioning

confidence: 99%

Effects of climate change on fish reproduction and early life history stages

Pankhurst

Munday

2011

Mar. Freshwater Res.

542

405

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Abstract. Seasonal change in temperature has a profound effect on reproduction in fish. Increasing temperatures cue reproductive development in spring-spawning species, and falling temperatures stimulate reproduction in autumnspawners. Elevated temperatures truncate spring spawning, and delay autumn spawning. Temperature increases will affect reproduction, but the nature of these effects will depend on the period and amplitude of the increase and range from phaseshifting of spawning to complete inhibition of reproduction. This latter effect will be most marked in species that are constrained in their capacity to shift geographic range. Studies from a range of taxa, habitats and temperature ranges all show inhibitory effects of elevated temperature albeit about different environmental set points. The effects are generated through the endocrine system, particularly through the inhibition of ovarian oestrogen production. Larval fishes are usually more sensitive than adults to environmental fluctuations, and might be especially vulnerable to climate change. In addition to direct effects on embryonic duration and egg survival, temperature also influences size at hatching, developmental rate, pelagic larval duration and survival. A companion effect of marine climate change is ocean acidification, which may pose a significant threat through its capacity to alter larval behaviour and impair sensory capabilities. This in turn impacts on population replenishment and connectivity patterns of marine fishes.

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What determines the growth of tropical reef fish larvae in the plankton: food or temperature?

Cited by 132 publications

References 33 publications

Environmental influences on larval duration, growth and magnitude of settlement of a coral reef fish

Environmental influences on larval duration, growth and magnitude of settlement of a coral reef fish

Environmental factors influencing larval walleye pollock Theragra chalcogramma feeding in Alaskan waters

Effects of climate change on fish reproduction and early life history stages

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