Growth, behaviour and colour changes of juvenile King George whiting (<i>Sillaginodes punctata</i>) mediated by light intensities

Meakin, Craig; Qin, Jianguang

doi:10.1080/00288330.2011.608687

Cited by 7 publications

(4 citation statements)

References 54 publications

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“…However, bioluminescent squid ( Euprymna scolopes , Berry, 1913) are able to rapidly (over a few minutes) modulate the intensity of light emitted by their bacterial symbiont ( Vibrio fischeri , Urbanczyk, Higgins, Carson & Dunlap, 2007) in response to changes in downwelling light intensity (Jones & Nishiguchi, ). Interestingly, King George whiting that are reared in low light intensity environments exhibit brighter dorsal and ventral body surfaces than those raised at high light intensities (Meakin & Qin, ), which is the opposite pattern to the findings reported in the current study. Perhaps the discrepancies between these findings are a result of methodological differences (e.g.…”

Section: Discussioncontrasting

confidence: 99%

Testing the role of background matching and self-shadow concealment in explaining countershading coloration in wild-caught rainbowfish

Kelley

Merilaita

2015

Biol J Linn Soc Lond

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Countershading, or dorsal pigmentary darkening (DPD), describes a form of vertically varying coloration, where an animal typically has a dark dorsal surface and a paler ventral side, and is widespread among mammals, birds, reptiles, fishes and insects. DPD is thought to confer concealment from predators and, in terrestrial systems, there is good evidence that the dark–light transition in body coloration acts to conceal the body's shadow. Surprisingly few studies of DPD have been conducted in aquatic environments, and thus it is not known whether the mechanisms of concealment are similar to those that operate in terrestrial habitats. In this study, we determined the role of the light environment and predation risk in determining DPD in wild‐caught populations of a freshwater fish, the western rainbowfish (Melanotaenia australis). We also examined the underlying mechanisms of DPD for concealment by testing the assumptions of background matching and self‐shadow concealment. In a subsequent experiment, we determined whether any observed variation in DPD was maintained when the visual background was manipulated in the laboratory (to induce a change in body coloration). We found that both the amount of downwelling irradiance and the level of predation risk at the collection site affected skin darkness (dorsal, ventral and overall), whereas the ratio of dorsoventral coloration (DPD) was not affected by the parameters considered. The laboratory experiment revealed that fish changed their body coloration to match their visual background, and did so by altering the relative ratio of dorsoventral skin darkness. In contrast with research on terrestrial animals, our findings suggest that the most likely method of achieving crypsis is through background matching, rather than self‐shadow concealment. It is thus possible that differences in the optical characteristics of terrestrial and aquatic environments, and/or variation in the angles at which prey are typically viewed and attacked, have resulted in divergent mechanisms of using DPD to attain crypsis. © 2015 The Linnean Society of London, Biological Journal of the Linnean Society, 2015, 114, 915–928.

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Section: Discussioncontrasting

confidence: 99%

Testing the role of background matching and self-shadow concealment in explaining countershading coloration in wild-caught rainbowfish

Kelley

Merilaita

2015

Biol J Linn Soc Lond

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“…These findings constitute a novel approach to species discrimination. Finally, discrimination of the activity of fishes will be essential for a better understanding of ecosystem functioning and the ecological roles played by fish species (Pulcini et al 2008, Colmenero et al 2010, Meakin and Qin 2011). …”

Section: Discussionmentioning

confidence: 99%

An approach to unraveling the coexistence of snappers (Lutjanidae) using otolith morphology

Sadighzadeh¹,

Otero-Ferrer²,

Lombarte³

et al. 2014

Sci. Mar.

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Summary:The sagittae otolith morphology of marine fishes has been used in many ecomorphological studies to explain certain ecological adaptations of species to habitat. Our study compares the sagittal otolith shapes of ten species of snappers (Family Lutjanidae) inhabiting the Persian Gulf. We used a morphometric analysis of the otolith measurements (length, height, perimeter, area and weight) and of the ratio between the area of the sulcus acusticus and the area of the otolith (S:O). The otolith contour was also analysed using wavelets as a mathematical descriptor. Morphological variations in the otoliths were associated with the morphology and external colouration of snappers as well as ecological traits. An analysis of the interspecific S:O ratio suggested that the highest ratios occurred in snappers inhabiting shallower waters. A categorical multivariate analysis, including morphological, ecological and otolith size factors, showed that the species adapted to dim light conditions had a greater otolith perimeter. An analysis of variance of the otolith contour revealed zones with a higher interspecific variability, although only the antero-dorsal zone showed differing patterns. Although the otolith patterns appear to have a phylogenetic component, they might also be related to diel activity rhythms or to the light conditions in the habitat. The results of the study showed that variation in otolith morphology can be used to explain the coexistence of sympatric species.Keywords: otolith; morphology; biodiversity; functional ecology; snappers; Lutjanidae.Una aproximación a la comprensión de la coexistencia de pargos (Lutjanidae) a partir de la morfología del otolito Resumen: La morfología del otolito sagitta de peces marinos se ha empleado en estudios de ecomorfología al objeto de explicar las adaptaciones ecológicas de las especies al hábitat. Nuestro estudio compara la forma del otolito de diez especies de pargos (familia Lutjanidae) del Golfo Pérsico. El análisis morfológico se realizó a partir de medidas del otolito (longitud, anchura, perímetro, área y peso) y la proporción entre el área del sulcus acusticus y del otolito (S:O). También se analizaron los contornos de los otolitos mediante descriptores matemáticos denominados wavelets. Las variaciones morfológicas en los otolitos se asociaron a la morfología y la coloración externa de los pargos, así como a diversos caracteres ecológicos. Las especies con valores más elevados en la proporción S:O habitan en aguas someras. El análisis multivariante categórico de factores, ecológicos y morfológicos del otolito (forma y tamaño), puso de manifiesto que las especies adaptadas a condiciones tenues de luz presentan el perímetro del otolito más grande. El análisis de varianza del contorno del otolito reveló la presencia de zonas con gran variabilidad inter-específica, si bien solo la parte antero-dorsal permitió distinguir patrones claros de variación. Aunque dichos patrones parecen tener un componente filogenético, también estarían relacionados con el ritmo de activ...

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“…In long‐term 30‐day studies on Sillaginodes punctata juveniles, when the fish was exposed to different light levels (25, 500 and 1000 lx), no statistically significant difference was found in growth rate, survival, condition factor, body colour and behaviour changes (Meakin & Qin 2012).…”

Section: Growthmentioning

confidence: 98%

Effect of illumination on fish and amphibian: development, growth, physiological and biochemical processes

Ruchin

2020

Reviews in Aquaculture

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Being one of the main environmental factors, the light factor influences many aspects of animal life. Photoperiod, light intensity (illumination) and wavelength are the primary periodic factors. There is a review that discusses the role of illumination on various life processes of aquatic anamnia vertebrates (fish and amphibians). The effect of light on the development, growth, respiration, consumption and efficiency of food conversion, hormone release, reproduction and behaviour of fish and amphibians has been studied. Illumination influences differently a significant number of physiological and biochemical processes and reactions of anamnia vertebrates at various development stages. The obtained results show that the nature of exposure to light is species-specific and corresponds to the ecological niche of species. Illumination influences both positively and negatively the development, growth and other physiological processes of fish and amphibians. Illumination plays a special role during the first feeding of fish in the environment and aquaculture. There are positive and negative behavioural responses of fish to light. However, it is not always possible to distinguish fish species with only a negative or only a positive reaction to light. The quality of the reaction can be influenced by the stage of development of eggs or larvae, age characteristics, feeding status, season, time, the physiological state of fish, morbidity, etc. A promising area of research is the study of the influence of light on the hormonal status of the body and reproduction of fish. Also, the light pollution and its influence on the physiology of anamnia vertebrates are important.

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Growth, behaviour and colour changes of juvenile King George whiting (Sillaginodes punctata) mediated by light intensities

Cited by 7 publications

References 54 publications

Testing the role of background matching and self-shadow concealment in explaining countershading coloration in wild-caught rainbowfish

Testing the role of background matching and self-shadow concealment in explaining countershading coloration in wild-caught rainbowfish

An approach to unraveling the coexistence of snappers (Lutjanidae) using otolith morphology

Effect of illumination on fish and amphibian: development, growth, physiological and biochemical processes

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