Conservation genetics of the Mary River turtle (<i>Elusor macrurus</i>) in natural and captive populations

Schmidt, Daniel J.; Espinoza, Thomas; Connell, Marilyn J.; Hughes, Jane

doi:10.1002/aqc.2851

Cited by 13 publications

(14 citation statements)

References 46 publications

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“…With the exception of some studies that present low genetic diversity (value of H e < 0.4; [68–69]), freshwater turtles exhibit high values of genetic diversity (generally H e > 0.6-0.7; see Table 4 in [69] for examples, and [70]) based on microsatellites. Our values could be considered lower ( H e < 0.6) than many other freshwater turtles or even threatened species (see Table 4 in [69] for examples, and [70–71]), and are in agreement with values for wild populations of Elusor macrurus Cann & Legler 1994 (Testudines, Chelidae) an endangered Australian freshwater turtle [72]. The sole genetic study that reports value of genetic diversity for Trachemys spp.…”

Section: Discussionsupporting

confidence: 79%

“…Values of genetic diversity for captive population were slightly higher than wild population as reported for Elusor macrurus [72] and for Dermatemys mawii Gray, 1847 (Testudines, Dermatemydidae) [74]. Because founder individuals of the UMAs (captive population) come from two distinct localities: Pomposu that is within the Grijalva River Sub-Basin and El Espino in the Usumacinta River Sub-Basin (see Fig 1), the genetic pool of those founders could be higher due to the mix of genetic sources.…”

Section: Discussionmentioning

confidence: 78%

“…In this respect, all studies showed very low values of genetic diversity ( H < 0.15; [64–66]). The relatively low value of genetic diversity observed for wild population of T. venusta venusta compared to other turtle species, suggests that this species deserves reinforced attention and probably higher level of protection considering the threshold of 0.54 proposed by Willoughby et al [73] as a value to consider a species as Critically Endangered [72].…”

Section: Discussionmentioning

confidence: 99%

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Genetic diversity, structure, and kinship analysis ofTrachemys venusta venustain Wildlife Management Units and wild populations in south Mexico. Implications for conservation and management

Lesher-Gordillo

Recino-Reyes

M’Rabet

et al. 2020

Preprint

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The Meso-American slider turtle (Trachemys venusta) is a freshwater turtle endemic to Mexico and Central America. Due to the overexploitation of its natural populations, it is in the at risk category formulated by the Official Mexican Standard NOM-059-ECOL-2010. In the state of Tabasco, Management Units for the Conservation of Wildlife (UMA) were created to reduce the impact of overexploitation of freshwater turtles. However, no genetic management plan was considered. This study presents the level of genetic diversity of the founder individuals in order to develop a management plan which will optimize reproduction in the UMA. Genetic diversity was compared between captive (n = 45) and wild (n = 86) individuals using 14 microsatellite molecular markers. Level of genetic diversity could be considered as low (He < 0.6) for a species of turtle and suggests that a higher level of protection is required for this particular species. Furthermore, values were slightly higher for the captive group reflecting the mix of genetic sources (founding individuals from different localities) and demonstrating that the captive population is genetically representative of natural populations. The genetic structure analysis revealed a relationship between captive and wild populations, indicating the influence of the two principal river basins in this region on the population of freshwater turtles. Finally, according to the results obtained from the analysis conducted using Storm and ML-Relate programs, we recommend the use of 19 females and 13 males, generating a potential of 247 dyads with no relationship. These first results of genetic management in a Mexican UMA, demonstrate the importance of molecular approaches at the time of managing and conserving species in captivity.

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Section: Discussionsupporting

confidence: 79%

Section: Discussionmentioning

confidence: 78%

Section: Discussionmentioning

confidence: 99%

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Genetic diversity, structure, and kinship analysis ofTrachemys venusta venustain Wildlife Management Units and wild populations in south Mexico. Implications for conservation and management

Lesher-Gordillo

Recino-Reyes

M’Rabet

et al. 2020

Preprint

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“…Creek runs into the Mary River not far from the mouth, with both drainages having tidal estuarine reaches in the lower sections. The differentiation of the Tinana Creek population from the main stem of the Mary River is also observed in a number of other freshwater species including Mary River Cod, Maccullochella mariensis (Huey, Espinoza & Hughes, 2013), Mary River Turtle, Elusor macrurus (Schmidt et al 2018), freshwater crayfish Cherax dispar (Bentley, Schmidt & Hughes, 2010) and Australian lungfish Neoceratodus fosteri (Hughes et al, 2015).…”

Section: Population Structure and Dispersalmentioning

confidence: 75%

Peer Review #2 of "Patterns of genetic structuring at the northern limits of the Australian smelt (Retropinna semoni) cryptic species complex (v0.1)"

2018

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Freshwater fishes often exhibit high genetic population structure due to the prevalence of dispersal barriers (e.g., waterfalls) whereas population structure in diadromous fishes tends to be weaker and driven by natal homing behaviour and/or isolation by distance. The Australian smelt (Retropinnidae: Retropinna semoni) is a native fish with a broad distribution spanning inland and coastal drainages of southeastern Australia. Previous studies have demonstrated variability in population genetic structure and movement behaviour (potamodromy, facultative diadromy, estuarine residence) across the southern part of its geographic range. Some of this variability may be explained by the existence of multiple cryptic species. Here, we examined genetic structure of populations towards the northern extent of the species' distribution, using ten microsatellite loci and sequences of the mitochondrial cyt b gene. We tested the hypothesis that genetic connectivity among rivers should be low due to a lack of dispersal via the marine environment, but high within rivers due to dispersal. We investigated populations corresponding with two putative cryptic species, SEQ-North (SEQ-N), and SEQ-South (SEQ-S) lineages occurring in south east Queensland drainages. These two groups formed monophyletic clades in the mtDNA gene tree and among river phylogeographic structure was also evident within each clade. In agreement with our hypothesis, highly significant overall F ST values suggested that both groups exhibit very low dispersal among rivers (SEQ-S F ST = 0.13; SEQ-N F ST = 0.27). Microsatellite data indicated that connectivity among sites within rivers was also limited, suggesting dispersal may not homogenise populations at the within-river scale. Northern groups in the Australian smelt cryptic species complex exhibit comparatively higher among-river population structure and smaller geographic ranges than southern groups. These properties make northern Australian smelt populations potentially susceptible to future conservation threats, and we define eight genetically distinct management units along south east Queensland to guide future conservation management. The present findings at least can assist managers to plan for effective conservation and management

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“…Few attempts have been made to breed reptiles for conservation purposes (Hua et al, 2017;Schmidt, Espinoza, Connell, & Hughes, 2018), especially compared with the efforts devoted to endangered mammals (Nuss & Warneke, 2010;Smucny et al, 2004;Zhang, Swaisgood, & Zhang, 2004). Nonetheless, unlike many larger-bodied vertebrate species, most reptiles are well-suited to captive breeding and reintroduction programs given their small body size, relatively high fecundity, and low maintenance requirements (Shine, 2005;Hua et al, 2017;Schmidt et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Impacts of maternal characteristics and temperature on juvenile survival in the crocodile lizard: Implications for conservation

Luo

Yang

et al. 2019

Zoo Biology

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Captive breeding is an important conservation measure that may restore and enhance wild populations of rare and endangered species. Multiple anthropogenic hazards have brought the crocodile lizard, Shinisaurus crocodilurus, to the brink of extinction. We initiated a captive breeding program and quantified female reproductive traits, including reproductive timing, litter size, litter mass, and neonate size. To identify the internal and external factors affecting female reproductive function, we then analyzed how maternal age is related to body size, temperature, and female reproductive traits. We found that larger female crocodile lizards produced more offspring than smaller ones, as both litter size and litter mass were positively related to maternal body size. In contrast, neonate size was independent of maternal body size. Maternal reproductive output varied among different age groups. Young and old females had significantly smaller living litter size and mass than middle‐aged females. Among captive females, one‐third exhibited early parturition in autumn and winter instead of the following spring, a pattern probably associated with higher ambient temperatures in captivity. Although female reproductive output and neonatal body size did not differ between early‐ and normal‐parturition females, offspring from the former group died earlier than those from the latter. Our study highlights the danger of climate change in hastening parturition, a phenomenon that could significantly hamper neonate survival and impede population recruitment.

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Conservation genetics of the Mary River turtle (Elusor macrurus) in natural and captive populations

Cited by 13 publications

References 46 publications

Genetic diversity, structure, and kinship analysis ofTrachemys venusta venustain Wildlife Management Units and wild populations in south Mexico. Implications for conservation and management

Genetic diversity, structure, and kinship analysis ofTrachemys venusta venustain Wildlife Management Units and wild populations in south Mexico. Implications for conservation and management

Peer Review #2 of "Patterns of genetic structuring at the northern limits of the Australian smelt (Retropinna semoni) cryptic species complex (v0.1)"

Impacts of maternal characteristics and temperature on juvenile survival in the crocodile lizard: Implications for conservation

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