Predicting the fate of a living fossil: how will global warming affect sex determination and hatching phenology in tuatara?

Mitchell, Nicola J.; Kearney, Michael R.; Nelson, Nicola J.; Porter, Warren P.

doi:10.1098/rspb.2008.0438

Cited by 183 publications

(321 citation statements)

References 40 publications

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“…Many populations of species with TSD already exhibit offspring sex ratios skewed towards the sex produced at warmer temperatures, e.g. males in tuatara [3] and females in marine and freshwater turtle populations [4,5]. Future climate change scenarios are predicted to increase these sex ratio biases, with implications for population viability [2,3,6,7].…”

Section: Introductionmentioning

confidence: 99%

“…males in tuatara [3] and females in marine and freshwater turtle populations [4,5]. Future climate change scenarios are predicted to increase these sex ratio biases, with implications for population viability [2,3,6,7]. Potential consequences include a reduction in effective population size (N e ) that will exacerbate the negative effects of inbreeding and increase genetic drift in small populations [8], the inability to find mates leading to reduced fecundity or female infertility [9], and, under more extreme climate projections, the production of single sex cohorts [3,7].…”

Section: Introductionmentioning

confidence: 99%

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Turtle mating patterns buffer against disruptive effects of climate change

et al. 2012

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For organisms with temperature-dependent sex determination (TSD), skewed offspring sex ratios are common. However, climate warming poses the unique threat of producing extreme sex ratio biases that could ultimately lead to population extinctions. In marine turtles, highly female-skewed hatchling sex ratios already occur and predicted increases in global temperatures are expected to exacerbate this trend, unless species can adapt. However, it is not known whether offspring sex ratios persist into adulthood, or whether variation in male mating success intensifies the impact of a shortage of males on effective population size. Here, we use parentage analysis to show that in a rookery of the endangered green turtle (Chelonia mydas), despite an offspring sex ratio of 95 per cent females, there were at least 1.4 reproductive males to every breeding female. Our results suggest that male reproductive intervals may be shorter than the 2 -4 years typical for females, and/or that males move between aggregations of receptive females, an inference supported by our satellite tracking, which shows that male turtles may visit multiple rookeries. We suggest that male mating patterns have the potential to buffer the disruptive effects of climate change on marine turtle populations, many of which are already seriously threatened.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Turtle mating patterns buffer against disruptive effects of climate change

et al. 2012

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“…It is the largest endemic non-avian reptilian and has significant cultural importance for Maori (Sharell 1966; Mot 1997;Ramstad et al 2007). Currently restricted to approximately 35 small islands and the subject of concerted conservation efforts Mlot 1997;Gaze 2001;Parkinson 2002;Mitchell et al 2008), Sphenodon is of great scientific significance because it is the only extant member of the Rhynchocephalia, a group that was diverse and globally distributed during the Mesozoic (Apesteguia & Novas 2003;Evans 2003;Jones 2008;Jones et al 2009). Being the closest living relative (sister group) to Squamata (lizards, snakes, amphisbaenians;Rest et al 2003;Evans 2003), Sphenodon has been the subject of much research and has played an essential role as an outgroup taxon in comparative studies of squamate biology (e.g., Schwenk 1986Schwenk , 2000McBrayer & Reilly 2002;Vitt et al 2003;Herrel et al 2007;Evans 2008; Jones et al in press).…”

Section: Introductionmentioning

confidence: 99%

Bite‐force performance of the last rhynchocephalian (Lepidosauria:Sphenodon)

Jones

Lappin

2009

Journal of the Royal Society of New Zealand

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We present the first empirical measurements of bite-force performance from adult Sphenodon (Rhynchocephalia), the only extant non-squamate lepidosaur. Using raw bite-force data, we calculated maximum bite forces at the anterior and posterior extremes of the lower tooth row: 81.8 N and 163.5 N (female) and 119.1 N and 238.3 N (male). Combining our results with published data from juvenile animals, we calculated scaling coefficients of bite force on linear morphometrics of body and head size as c. 2.7 (anterior) and c. 3.5+ (posterior). These exceed isometric scaling predictions (2.0), yet are similar to those for other non-avian reptiles. This supports previous views that Sphenodon cannot bite as hard as agamidlizards. We discuss the role of bite force in the behavioural ecology of Sphenodon, propose that the lower temporal bar, unique among extant lepidosaurs, does not necessarily constrain bite force, and evaluate possible effects of other morphological characteristics on bite-force performance.Keywords Rhynchocephalia; skull morphology; ontogeny; feeding; tuatara INTRODUCTIONOne of New Zealand's most iconic animals is the tuatara (Sphenodon) (Parkinson 2002). It is the largest endemic non-avian reptilian and has significant cultural importance for Maori (Sharell 1966; Mot 1997;Ramstad et al. 2007). Currently restricted to approximately 35 small islands and the subject of concerted conservation efforts Mlot 1997;Gaze 2001;Parkinson 2002;Mitchell et al. 2008), Sphenodon is of great scientific significance because it is the only extant member of the Rhynchocephalia, a group that was diverse and globally distributed during the Mesozoic (Apesteguia & Novas 2003;Evans 2003;Jones 2008;Jones et al. 2009). Being the closest living relative (sister group) to Squamata (lizards, snakes, amphisbaenians;Rest et al. 2003;Evans 2003), Sphenodon has been the subject of much research and has played an essential role as an outgroup taxon in comparative studies of squamate biology (e.g., Schwenk 1986Schwenk , 2000McBrayer & Reilly 2002;Vitt et al. 2003;Herrel et al. 2007;Evans 2008; Jones et al. in press).There has been a long-standing interest in numerous aspects of Sphenodon biology, including its dietary ecology and social behaviour, as well as the unique morphology of this taxon's feeding apparatus. The diet of Sphenodon is diverse and comprises ants, moths, caterpillars,

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“…In addition, Kearney et al focus on adult ectotherms, which can use their mobility to thermoregulate. In contrast, their eggs are immobile, and thus warming-induced selection on eggs may be greater than on adults (17). Of course, if ''mother knows best,'' mobile moms can potentially use thermal cues to pick the best nest sites, which would represent a cross-generational behavioral buffering (18).…”

Section: Discussionmentioning

confidence: 99%