Does behaviour affect the dispersal of flatback post-hatchlings in the Great Barrier Reef?

Wildermann, Natalie; Critchell, Kay; Fuentes, Mariana M. P. B.; Limpus, Colin J.; Wolanski, Eric; Hamann, Mark

doi:10.1098/rsos.170164

Cited by 26 publications

(29 citation statements)

References 66 publications

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“…This indicates that hatchlings were actively swimming in a constant heading offshore using a strategy known as 'full drift', where the animal maintains its constant heading regardless of the direction of flow (Chapman et al 2011). Directional swimming such as we observed in the nearshore zone has been suggested to be a strategy that helps flatback hatchlings remain in coastal waters, as it prevents them from being carried out to sea (Wildermann et al 2017). The nearshore dispersal pathways of turtle hatchlings are largely unknown and are therefore predicted using models (Hamann et al 2011, Wildermann et al 2017.…”

Section: Discussionmentioning

confidence: 58%

Artificial light disrupts the nearshore dispersal of neonate flatback turtles Natator depressus

Wilson¹,

Thums²,

Pattiaratchi³

et al. 2018

Mar. Ecol. Prog. Ser.

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Section: Discussionmentioning

confidence: 58%

Artificial light disrupts the nearshore dispersal of neonate flatback turtles Natator depressus

Wilson¹,

Thums²,

Pattiaratchi³

et al. 2018

Mar. Ecol. Prog. Ser.

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“…The distribution of floating plastic items is predominantly driven by surface currents, whereas sea turtles can move independently of currents from very young ages (Bentivegna et al 2007, Putman & Mansfield 2015, Wildermann et al 2017). However, the distribution of macro-planktonic organisms, such as jellyfish and salps, the preferred prey on which turtles forage in the open sea, is also governed by currents, so it can be expected that there will always be zones of co-occurrence of marine debris and food for turtles, and hence, these zones will attract the turtles themselves.…”

Section: Risk Exposurementioning

confidence: 99%

“…According to Suaria & Aliani (2014), 62 million macro litter items are currently floating on the surface of the whole Mediterranean basin, temporarily accumulating in certain areas driven by ocean circulation dynamics and anthropogenic activities (Mansui et al 2015). Sea turtles can move independently of currents, even as hatchlings (Bentivegna et al 2007, Putman & Mansfield 2015, Wildermann et al 2017. Moreover, most of the preferred prey for sea turtles while they are in oceanic waters are macro-planktonic organisms, whose distribution is governed by currents.…”

Section: Introductionmentioning

confidence: 99%

Turtles on the trash track: loggerhead turtles exposed to floating plastic in the Mediterranean Sea

Arcangeli¹,

Maffucci²,

Atzori³

et al. 2019

Endang. Species. Res.

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Loggerhead turtles Caretta caretta spend most of their life in large marine areas occupying a variety of habitats where they are exposed to different types of threats. Among these, marine litter poses a risk of entanglement or ingestion. Areas of risk exposure can be identified where the species overlap with litter accumulations, but gathering data on this highly mobile species and marine litter, especially in high sea areas, is challenging. Here we analysed 5 years of sea turtle and marine litter data collected by a network of research bodies along fixed trans-border transects in the Mediterranean Sea. Ferries were used as observation platforms to gather systematic data on a seasonal basis using standard protocols. Loggerhead turtle sightings over time and space were compared in terms of sightings per unit effort, and risk-exposure areas were assessed based on seasonal overlap of species hot spots and high-density plastic areas revealed by kernel analysis. In almost 180 000 km surveyed, 1258 sea turtles were recorded, concentrated mostly in the central Adriatic Sea and Sardinia-Sicilian channels during all seasons, and in the central Tyrrhenian Sea during spring. Plastic comprised the highest fraction of litter items detected. Several areas of higher risk exposure, both permanent and seasonal, were identified, mainly in the Adriatic Sea and during the spring−summer seasons. Records of both species and floating litter were highly variable, underlying the need for continuous long-term monitoring to develop sound conservation and management measures, especially in the identified areas of risk exposure.

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“…Similar strong discontinuity of mtDNA haplotypes characterizes endemic Australian sea lions (Neophoca cinerea) that breed at isolated colonies along the south coast (Campbell, Gales, Lento, & Baker, 2008;Lowther, Harcourt, Goldsworthy, & Stow, 2012). This is thought to be driven by selective pressures for localized foraging strategies, whereas in marine turtles the selective pressures would target nest site selection in time and space, with a need for successful embryonic development and hatchling dispersal into coastal currents at appropriate times (Wildermann et al, 2017).…”

Section: Genetic Population Structurementioning

confidence: 99%

Phylogeography, genetic stocks, and conservation implications for an Australian endemic marine turtle

FitzSimmons

Pittard

McIntyre

et al. 2020

Aquatic Conservation

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Identification of the geographic extent of population boundaries, the distribution of genetic lineages, and the amount of genetic exchange among breeding groups is needed for effective conservation of vulnerable marine migratory species. This is particularly true of the flatback turtle (Natator depressus), which only breeds in Australia but has extensive migrations that can include international waters. This study investigated the phylogeography and genetic structure among 17 flatback turtle rookeries across their range by sequencing an 810 bp portion of the mitochondrial DNA in 889 samples and genotyping 10 microsatellite loci in 598 samples. There was low phylogenetic divergence among haplotypes and evidence of recent population expansion, likely in the late Pleistocene. A predominant haplotype was found across all rookeries, but other haplotype groups were regionally specific. In general, there was agreement in patterns of genetic differentiation in the mitochondrial DNA and microsatellite data, and in some pairwise comparisons a higher mutation rate of microsatellites provided stronger evidence of differentiation. These results suggest natal philopatry operates in the choice of breeding locations for males as well as females. Evidence of genetic connectivity among neighbouring rookeries led to the identification of seven genetic stocks. Geographic boundaries of rookeries used by genetic stocks varied widely (160–1,300 km), highlighting a need for field studies to better understand movement patterns. Hierarchical analysis of molecular variance identified significant genetic differentiation based upon genetic stock, nesting phenology (summer vs. winter nesters), and a west–east discontinuity across Torres Strait. A pattern of isolation by distance was identified, which was most strongly observed in the microsatellite data. In combination with tagging and telemetry studies, these results will allow better quantification of stock‐specific threats along migratory routes and in foraging habitats. Implications of climate change will be stock specific and may depend upon the extent of genetic connectivity between neighbouring stocks.

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Does behaviour affect the dispersal of flatback post-hatchlings in the Great Barrier Reef?

Cited by 26 publications

References 66 publications

Artificial light disrupts the nearshore dispersal of neonate flatback turtles Natator depressus

Artificial light disrupts the nearshore dispersal of neonate flatback turtles Natator depressus

Turtles on the trash track: loggerhead turtles exposed to floating plastic in the Mediterranean Sea

Phylogeography, genetic stocks, and conservation implications for an Australian endemic marine turtle

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