Field experiments on depth selection by juvenile plaice Pleuronectes platessa

Gibson, R. N.; Burrows, Michael T.; Robb, Linda

doi:10.3354/meps09034

Cited by 12 publications

(6 citation statements)

References 40 publications

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“…Aside from habitat, bathymetric features, including depth and slope, can influence distributions of marine fishes. Fishes within estuaries often demonstrate depth preferences (Gibson et al ., ), and depth has been shown to influence an individual's predation risk (Ryer et al ., ). Water depth was identified as the most influential variable in the GAM analysis, with juvenile P. lethostigma using deeper waters (>50 cm relative depth) within the VPS array.…”

Section: Discussionmentioning

confidence: 99%

Fine‐scale movements and habitat use of juvenile southern flounder Paralichthys lethostigma in an estuarine seascape

Furey

Dance

Rooker

2013

Journal of Fish Biology

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Habitat use of juvenile southern flounder Paralichthys lethostigma was examined within a shallow estuarine seascape during June and July 2011 using acoustic telemetry. Fine-scale movement and habitat use of P. lethostigma was investigated with an acoustic positioning system placed in a seascape that varied in habitat type, physicochemical conditions and bathymetry. The use of different habitat types was examined with Euclidean distance-based analyses, and generalized additive models were used to determine the relative importance of habitat type relative to physicochemical conditions and bathymetry. Tracks of P. lethostigma ranged in distance between 1477 and 8582 m and speed was 4·2 ± 1·1 m min⁻¹ (mean ± s.e.) for all P. lethostigma combined. Depth, slope and habitat type had the most influence on P. lethostigma occurrence and deep sandy areas with shallow slopes were used most frequently. In addition, depth use by P. lethostigma was influenced by tidal cycles, indicating habitat use varies temporally and is dynamic. Finally, temperatures <30·5° C were used more than warmer waters within the study area. The results successfully identify movements by juvenile P. lethostigma, and indicate that definitions of essential habitats need to account for dynamics in habitat use.

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Section: Discussionmentioning

confidence: 99%

Fine‐scale movements and habitat use of juvenile southern flounder Paralichthys lethostigma in an estuarine seascape

Furey

Dance

Rooker

2013

Journal of Fish Biology

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“…In general, recently metamorphosed juveniles inhabit nursery areas that range from ~0.5-50 m in depth (McCracken, 1963;Gibson et al, 2002;Reum & Essington, 2011;Ryer et al, 2012). But even in rearing estuaries of less than 5 m in depth, there can be spatial segregation between younger and older juveniles (Gibson et al, 2011), as well as between species (Marchand, 1988;Vinagre et al, 2006Vinagre et al, , 2009, depending on slight differences in ecotype and predation pressure (Vinagre et al, 2009;Gibson et al, 2002;Ryer et al, 2012). As flatfishes grow, they expand their ranges into deeper waters, with different species seemingly favouring different depths (Sohn et al, 2016;Fernández-Zapico et al, 2017;Sobocinski et al, 2018;Rau et al, 2019) likely as a result of multiple factors including substrate type (often correlated with prey type, Vinagre et al, 2009;Perry et al, 1994;Fernández-Zapico et al, 2017;Rau et al 2019), complexity of habitat structure (e.g., presence of large rocks, sponges, bryozoan colonies; Ryer et al, 2012), oxygen availability (Sobocinski et al, 2018), temperature (Perry et al, 1994;Vinagre et al, 2009;van Hal et al, 2016;Rau et al, 2019), salinity (Vinagre et al, 2009;Rau et al, 2019) and risk of predation (Hurst et al, 2007;Reum and Essington, 2011;Yeung and Yang, 2018).…”

Section: Flatfish Visual Ecology and Divergence From The Lattice Mosaic Planmentioning

confidence: 99%

“…But even in rearing estuaries of less than 5 m in depth, there can be spatial segregation F I G U R E 1 0 Spatial analysis of single cone distributions from the same mosaics shown in Figure 9. Presentation of data as in Figure 9 [Color figure can be viewed at wileyonlinelibrary.com] between younger and older juveniles (Gibson, Burrows, & Robb, 2011), as well as between species (Marchand, 1988;Vinagre et al, 2006; Vinagre, Maia, Reis-Santos, Costa, & Cabral, 2009), depending on slight differences in ecotype and predation pressure (Gibson et al, 2002;Ryer et al, 2012;Vinagre et al, 2009) Perry, Stocker, & Fargo, 1994;Fernández-Zapico et al, 2017;Rau et al, 2019), complexity of habitat structure (e.g., presence of large rocks, sponges, bryozoan colonies; Ryer et al, 2012), oxygen availability (Sobocinski et al, 2018), temperature (Perry et al, 1994;Rau et al, 2019; van Hal, van Kooten, & Rijnsdorp, 2016;Vinagre et al, 2009), salinity (Rau et al, 2019;Vinagre et al, 2009), and risk of predation (Hurst, Ryer, Ramsey, & Haines, 2007;Reum & Essington, 2011;Yeung & Yang, 2018). Different flatfish species also vary in their displacement behavior (remaining primarily on the bottom or frequently swimming in the water column; Hurst et al, 2007;Vollen & Albert, 2008), camouflage capabilities (active mimicry by changing skin pattern or digging into the substrate; Ryer, Stoner, & Titgen, 2004;Ryer, Lemke, Boersma, & Levas, 2008), and prey spectrum (consuming more demersal species, like amphipods or polychaete worms, or pelagic species, such as mysids, euphausids and fish; Martell & McClelland, 1994).…”

Section: Flatfish Visual Ecology and Divergence From The Lattice Mosa...mentioning

confidence: 99%

Straying from the flatfish retinal plan: Cone photoreceptor patterning in the common sole (Solea solea) and the Senegalese sole (Solea senegalensis)

Frau

Flamarique

Keeley

et al. 2020

J of Comparative Neurology

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The retinas of non-mammalian vertebrates have cone photoreceptor mosaics that are often organized as highly patterned lattice-like distributions. In fishes, the two main lattice-like patterns are composed of double cones and single cones that are either assembled as interdigitized squares or as alternating rows. The functional significance of such orderly patterning is unknown. Here, the cone mosaics in two species of Soleidae flatfishes, the common sole and the Senegalese sole, were characterized and compared to those from other fishes to explore variability in cone patterning and how it may relate to visual function..The cone mosaics of the common sole and the Senegalese sole consisted of single, double and triple cones in formations that differed from the traditional square mosaic pattern reported for other flatfishes in that no evidence of higher order periodicity was present. Furthermore, mean regularity indices for single and double cones were conspicuously lower than those of other fishes with "typical" square and row mosaics, but comparable to those of goldfish, a species with lattice-like periodicity in its cone mosaic. Opsin transcripts detected by qPCR (sws1, sws2, rh2.3, rh2.4, lws, and rh1) were uniformly expressed

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“…Numerous studies have explored the biodiversity and geochemistry of the natural environment of Loch Linnhe. Examples include the planktonic ecosystem (Heath 1995), rocky reef fish populations (Magill and Sayer 2002;Magill and Sayer 2004), sandy bay flatfish (Gibson et al 2011), macrofaunal populations (Sayer and Poonian 2007) and rare brown algae (Yang et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Macroalgal vegetation on a north European artificial reef (Loch Linnhe, Scotland): biodiversity, community types and role of abiotic factors

et al. 2020

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Very little is known about the marine macroalgae of artificial reefs-especially in the North Atlantic-despite the growing number and extent of man-made structures in the sea, and even though seaweed communities have paramount importance as primary producers, but also as feeding, reproductive and nursery grounds in coastal ecosystems. This paper explores the macroalgal diversity of a large system of artificial reefs in Loch Linnhe, on the west coast of Scotland, in a quantitative and qualitative study based on diving surveys and correlates the observations with the prevalent abiotic factors. The study was conducted in order to test the hypothesis that artificial reefs can enhance seaweed habitats-in particular, for kelps-and that there is a clear correlation with substrate type. While the reef is home to a large range of biota and abundance of earlysuccessional species of turf and bushy macroalgae, totalling 56 taxa and with Delesseria sanguinea as the dominant species, canopy-forming perennial kelp species are conspicuously relatively rare. Macroalgal vegetation is explored in correlation with reef geometry/geography and depth. Statistical analysis shows benthic communities were strongly affected by substrate type, with turf algae and invertebrates dominating the artificial reefs, while bushy algae dominate the natural ones. Common macroinvertebrates associated with the phytobenthic communities are assessed qualitatively.

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Field experiments on depth selection by juvenile plaice Pleuronectes platessa

Cited by 12 publications

References 40 publications

Fine‐scale movements and habitat use of juvenile southern flounder Paralichthys lethostigma in an estuarine seascape

Fine‐scale movements and habitat use of juvenile southern flounder Paralichthys lethostigma in an estuarine seascape

Straying from the flatfish retinal plan: Cone photoreceptor patterning in the common sole (Solea solea) and the Senegalese sole (Solea senegalensis)

Macroalgal vegetation on a north European artificial reef (Loch Linnhe, Scotland): biodiversity, community types and role of abiotic factors

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