Development of dim-light vision in the nocturnal coral reef fish family, Holocentridae

Fogg, Lily; Cortesi, Fabio; Lecchini, David; Gache, Camille; Marshall, N. Justin; Busserolles, Fanny de

doi:10.1101/2022.05.04.490704

Cited by 4 publications

(8 citation statements)

References 109 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Conversely, the top 15 DEGs upregulated in adults were primarily involved in visual perception and aerobic respiration ( Table 2 ). Notably, the DEGs also included several developmental transcription factors (TFs) ( Fogg and de Busserolles, 2022 ). In the larvae, this included upregulation of otx2 and otx5 , while in adults, the TFs, nr2e3 and rorb were upregulated.…”

Section: Resultsmentioning

confidence: 99%

Development of dim-light vision in the nocturnal reef fish family Holocentridae. I: Retinal gene expression

Fogg

Cortesi

Lecchini

et al. 2022

Journal of Experimental Biology

Self Cite

View full text Add to dashboard Cite

Developmental changes to the visual systems of animals are often associated with ecological shifts. Reef fishes experience a change in habitat between larval life in the shallow open ocean to juvenile and adult life on the reef. Some species also change their lifestyle over this period and become nocturnal. While these ecological transitions are well documented, little is known about the ontogeny of nocturnal reef fish vision. Here, we used transcriptomics to investigate visual development in 12 representative species from both subfamilies, Holocentrinae (squirrelfishes) and Myripristinae (soldierfishes), in the nocturnal coral reef fish family, Holocentridae. Results revealed that the visual systems of holocentrids are initially well-adapted to photopic conditions with pre-settlement larvae having high cone opsin gene expression and a broad cone opsin gene repertoire (8 genes). At reef settlement, holocentrids started to invest more in their scotopic visual system and compared to adults, showed upregulation of genes involved in cell differentiation/proliferation. By adulthood, they had well-developed scotopic vision with high rod opsin gene expression, reduced cone opsin gene expression and repertoire (1-4 genes) and upregulated phototransduction genes. Finally, although the two subfamilies shared similar ecologies across development, their visual systems diverged after settlement, with Myripristinae investing more in scotopic vision than Holocentrinae. Hence, both ecology and phylogeny likely determine the development of the holocentrid visual system.

show abstract

Section: Resultsmentioning

confidence: 99%

Development of dim-light vision in the nocturnal reef fish family Holocentridae. I: Retinal gene expression

Fogg

Cortesi

Lecchini

et al. 2022

Journal of Experimental Biology

Self Cite

View full text Add to dashboard Cite

show abstract

“…e ., sws2a, rh2c and lws ). However, visual plasticity was less pronounced in adults, potentially due to ongoing development in settlement larvae (Besson, 2017; Fogg et al, 2022; Shand, 1997). Nevertheless, our findings are intriguing since they indicate that A. triostegus shows opsin gene expression plasticity in both developing and adult fishes, similar to findings in some freshwater fishes [ e .…”

Section: Discussionmentioning

confidence: 99%

“…As found in N. brevirostris , the opsin genes are differentially expressed between life stages in A. triostegus . Ontogenetic changes in opsin gene expression are often related to changes in habitat and diet (Chang et al, 2020; Fogg et al, 2022; Lupše et al, 2021; Shand et al, 2008; Tettamanti et al, 2019). Indeed, A. triostegus larvae rapidly increase expression of the green-sensitive cone opsins ( i .…”

Section: Discussionmentioning

confidence: 99%

“…Since continuous exposure to high-intensity light can cause retinal degeneration (Bernardos et al, 2007; Vera & Migaud, 2009), retinas of fish exposed to 24L were inspected for signs of degeneration prior to analysis. Subsequently, retinal cell densities were estimated from transverse retinal sections as described previously (Fogg et al, 2022; Shand, 1997). Briefly, in Fiji, retinal images were cropped to obtain 100 μm-wide strips, the number of cone outer segments (OS), outer nuclear layer (ONL) nuclei, INL nuclei and GC layer nuclei were counted for three sections per sample using the cell counter plugin and the density of each cell type per 0.01 mm 2 of retina was calculated.…”

Section: Methodsmentioning

confidence: 99%

“…However, vision may also be plastic within the lifetime of an individual, such as during its development (Evans & Fernald, 1993; Pankhurst, 1987; Shand, 1997; Shand et al, 2000; Siebeck & Marshall, 2007) and between seasons (Shimmura et al, 2017; Stieb et al, 2016). For example, a shift to a nocturnal lifestyle during ontogeny has been correlated with scotopic remodelling of the retina in reef fishes (Fogg et al, 2022; Shand, 1997). These ontogenetic and seasonal variations are regular, predictable alterations to the light environment that a species will have encountered over many preceding generations, potentially allowing genetic signals to contribute to adaption, such as has been found in killifish (Fuller et al, 2005) and damselfish (Stieb et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Developing and adult reef fish show rapid, reversible light-induced plasticity in their visual system

Fogg

Cortesi

Gache

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

The visual capabilities of fish are optimised for their ecology and light environment over evolutionary time. Similarly, fish vision can adapt to regular changes in light conditions within their lifetime, e.g., ontogenetic or seasonal variation. However, we do not fully understand how vision responds to irregular short-term changes in the light environment, e.g., algal blooms and light pollution. In this study, we investigated the effect of short-term exposure to unnatural light conditions on opsin gene expression and retinal cell densities in larval and adult diurnal reef fish (convict surgeonfish; Acanthurus triostegus). Results revealed phenotypic plasticity in the retina across ontogeny, particularly in the larvae. The most substantial differences at both molecular and cellular levels were found under constant dim light, while constant bright light or simulated artificial light at night had a lesser effect. Under dim light, larvae and adults increased expression of the cone opsin genes, sws2a, rh2c and lws, within a few days and larvae also decreased densities of cones, inner nuclear layer cells and ganglion cells. These changes likely enhanced vision under the altered light conditions. Thus, our study suggests that plasticity mainly comes into play when conditions are extremely different to the species’ natural light environment, i.e., a diurnal fish in ‘constant night’. Finally, in a rescue experiment on adults, shifts in opsin expression were reverted within 24 hours. Overall, our study showed rapid, reversible light-induced changes in the retina of A. triostegus, demonstrating phenotypic plasticity in the visual system of a reef fish throughout life.

show abstract

Diel movement patterns in nominally nocturnal coral reef fishes (Haemulidae and Lutjanidae): Intra vs. Interspecific variation

Collins,

Bellwood,

Morais

et al. 2024

Coral Reefs

View full text Add to dashboard Cite

Movement of animals, habitat connectivity, and nutrient transport are key elements in the ecological functioning of coral reef ecosystems. However, most studies have focused on the diurnal component of these aspects; nocturnal patterns are less known. Our study aims to address this knowledge gap by assessing diel movement patterns in ecologically and commercially important nocturnal coral reef fishes. We evaluate 122-days of acoustic telemetry data from 4 nocturnal species in 2 coral reef fish families (Haemulidae and Lutjanidae) on the Great Barrier Reef. For all species, we found a clear division between daytime resting areas on the reef and a move towards off-reef areas at night. This was highlighted in the low number of detections at night and the high average transitions between receivers at twilight. Over our study period, average nocturnal space use area (minimum convex polygon) of Plectorhincus gibbosus was 328,089 m2, Plectorhincus lineatus 28,828 m2, and Lutjanus carponotatus 20,369 m2. However, results from a Principal Component Analysis revealed that space use, and movement, varied substantially within species; for 3 of the 4 species the main axis of variation correlated with individual-level behaviour. These large differences in individual space use patterns highlight the need for caution when using species averages when considering ecosystem functions. Overall, our preliminary observations provide a glimpse into the large spatial extent, potential habitat connectivity, and intra and interspecific variation in activity patterns among large nocturnal Indo-Pacific reef fishes. This highlights their potential importance in maintaining ecosystem links between coral reefs and adjacent habitats.

show abstract

Development of dim-light vision in the nocturnal coral reef fish family, Holocentridae

Cited by 4 publications

References 109 publications

Development of dim-light vision in the nocturnal reef fish family Holocentridae. I: Retinal gene expression

Development of dim-light vision in the nocturnal reef fish family Holocentridae. I: Retinal gene expression

Developing and adult reef fish show rapid, reversible light-induced plasticity in their visual system

Diel movement patterns in nominally nocturnal coral reef fishes (Haemulidae and Lutjanidae): Intra vs. Interspecific variation

Contact Info

Product

Resources

About