The sex‐determination pattern in crocodilians: A systematic review of three decades of research

González, Edgar J.; Martínez‐López, Marcela; Morales‐Garduza, Marco Antonio; García‐Morales, Rodrigo; Charruau, Pierre; Gallardo-Cruz, J. Alberto

doi:10.1111/1365-2656.13037

Cited by 38 publications

(27 citation statements)

References 54 publications

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“…Very little is known regarding how thermal reaction norms vary across parental genotypes and populations in crocodilians. A systematic review of studies reporting temperatureby-sex reaction norms in crocodilians found evidence for latitudinal variation in the reaction norm of A. mississippiensis (González et al, 2019). In particular, populations appear to vary in the range of male-promoting temperatures, with higher-latitude populations exhibiting a wider range of malepromoting temperatures (González et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…A systematic review of studies reporting temperatureby-sex reaction norms in crocodilians found evidence for latitudinal variation in the reaction norm of A. mississippiensis (González et al, 2019). In particular, populations appear to vary in the range of male-promoting temperatures, with higher-latitude populations exhibiting a wider range of malepromoting temperatures (González et al, 2019). While intriguing, such observations should be interpreted with caution because many of the studies examined were conducted prior to the discovery that the thermosensitive period of this species begins much earlier than previously thought, opening up the possibility that incubation temperatures prior to egg collection may have accounted for a proportion of the observed variation in sex ratios (McCoy et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

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Incubation Temperature and Maternal Resource Provisioning, but Not Contaminant Exposure, Shape Hatchling Phenotypes in a Species with Temperature-Dependent Sex Determination

Bock

Hale

Rainwater

et al. 2021

The Biological Bulletin

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chlorodiphenyldichloroethylene exposure did not generally affect hatchling traits, constant and fluctuating temperatures produced diverse phenotypic effects. Thermal fluctuations led to subtle changes in incubation duration and produced shorter hatchlings with smaller heads when compared to the constant temperature control. Warmer, male-promoting incubation temperatures resulted in larger hatchlings with more residual yolk reserves when compared to cooler, female-promoting temperatures. Together, these findings advance our understanding of how complex environmental factors interact with developing organisms to generate phenotypic variation and raise questions regarding the mechanisms connecting variable thermal conditions to responses in hatchling traits and their evolutionary implications for temperature-dependent sex determination.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Incubation Temperature and Maternal Resource Provisioning, but Not Contaminant Exposure, Shape Hatchling Phenotypes in a Species with Temperature-Dependent Sex Determination

Bock

Hale

Rainwater

et al. 2021

The Biological Bulletin

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“…[ 55 ] In fact, the thermal window producing males is narrow in crocodiles and no constant temperature produces 100% males in most crocodile species. [ 56 ] The same is true for the highly studied leopard geckos Eublepharis macularius . [ 57 ] It was argued that instead of being detrimental, female‐biased adult sex ratios might be in fact advantageous from the point of view of population reproductive potential.…”

Section: Adaptive Values Of Gsd and Esd: Is Esd A Short‐lived Strategy?mentioning

confidence: 85%

Evolution of Sex Determination in Amniotes: Did Stress and Sequential Hermaphroditism Produce Environmental Determination?

et al. 2020

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Frequent independent origins of environmental sex determination (ESD) are assumed within amniotes. However, the phylogenetic distribution of sex-determining modes suggests that ESD is likely very ancient and may be homologous across ESD groups. Sex chromosomes are demonstrated to be old and stable in endothermic (mammals and birds) and many ectothermic (non-avian reptiles) lineages, but they are mostly non-homologous between individual amniote lineages. The phylogenetic pattern may be explained by ancestral ESD with multiple transitions to later evolutionary stable genotypic sex determination. It is pointed out here that amniote ESD shares several key aspects with sequential hermaphroditism of fishes such as a lack of sex differences in genomes, biased population sex ratios, and potentially also molecular mechanism related to general stress responses. Here, it is speculated that ESD evolves via a heterochronic shift of the sensitive period of sex change from the adult to the embryonic stage in a hermaphroditic amniote ancestor. Also see the video abstract here https://youtu.be/q2mjtlCefu4.

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“…For each species remaining, we searched using “incubat*” and the species name to try and find additional studies reporting hatching success at extremely warm temperatures, but no additional estimates were found. Because crocodilians were underrepresented in our data set ( n = 0 species), we used literature reviewed by González et al (2019) to add additional studies. For two species ( Alligator mississippiensis and Caiman crocodilus ), hatching success was not provided for each temperature within the OTR but was described generally (e.g., hatching success was “greater than 90%” at all temperatures).…”

Section: A Quantitative Review Of Reptile Embryo Heat Tolerancementioning

confidence: 99%

“…Both can increase nest temperatures in detrimental ways (Dayananda & Webb, 2017; Hall & Warner, 2018; Tiatragul, Hall, & Warner, 2020). Historically, reptiles have served as a primary model in studies of thermal developmental plasticity (Warner, Du, & Georges, 2018; While et al, 2018), which has resulted in a large body of literature (reviewed by González et al, 2019; Howard, Bell, & Pike, 2014; Noble, Stenhouse, & Schwanz, 2018; Pezaro, Doody, & Thompson, 2017; Refsnider, Clifton, & Vazquez, 2019; Warner et al, 2018; While et al, 2018) upon which researchers can draw to predict species responses to rising temperatures; however, there are currently no standard assays for measuring heat stress of reptile embryos (unlike post‐hatching stages; Angilletta, Zelic, Adrian, Hurliman, & Smith, 2013). Such methods are critical to understand the evolution and ecology of embryo heat tolerance and predict responses to global change.…”

Section: Introductionmentioning

confidence: 99%

Heat tolerance of reptile embryos: Current knowledge, methodological considerations, and future directions

Hall

Sun

2020

J Exp Zool Pt A

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Aspects of global change result in warming temperatures that threaten biodiversity across the planet. Eggs of non‐avian, oviparous reptiles (henceforth “reptiles”) are particularly vulnerable to warming due to a lack of parental care during incubation and limited ability to behaviorally thermoregulate. Because warming temperatures will cause increases in both mean and variance of nest temperatures, it is crucial to consider embryo responses to both chronic and acute heat stress. Although many studies have considered embryo survival across constant incubation temperatures (i.e., chronic stress) and in response to brief exposure to extreme temperatures (i.e., acute stress), there are no standard metrics or terminology for determining heat stress of embryos. This impedes comparisons across studies and species and hinders our ability to predict how species will respond to global change. In this review, we compare various methods that have been used to assess embryonic heat tolerance in reptiles and provide new terminology and metrics for quantifying embryo responses to both chronic and acute heat stress. We apply these recommendations to data from the literature to assess chronic heat tolerance in 16 squamates, 16 turtles, five crocodilians, and the tuatara and acute heat tolerance for nine squamates and one turtle. Our results indicate that there is relatively large variation in chronic and acute heat tolerance across species, and we outline directions for future research, calling for more studies that assess embryo responses to acute thermal stress, integrate embryo responses to chronic and acute temperatures in predictive models, and identify mechanisms that determine heat tolerance.

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The sex‐determination pattern in crocodilians: A systematic review of three decades of research

Cited by 38 publications

References 54 publications

Incubation Temperature and Maternal Resource Provisioning, but Not Contaminant Exposure, Shape Hatchling Phenotypes in a Species with Temperature-Dependent Sex Determination

Incubation Temperature and Maternal Resource Provisioning, but Not Contaminant Exposure, Shape Hatchling Phenotypes in a Species with Temperature-Dependent Sex Determination

Evolution of Sex Determination in Amniotes: Did Stress and Sequential Hermaphroditism Produce Environmental Determination?

Heat tolerance of reptile embryos: Current knowledge, methodological considerations, and future directions

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