Hybridization and Low Genetic Diversity in the Endangered Alabama Red-Bellied Turtle (Pseudemys alabamensis)

Pseudemys alabamensis is one of the most endangered turtle species in the United States due to its small population size and restricted geographic distribution in coastal Alabama and Mississippi. Increased urbanization and climate change impacts in the region further threaten this species. Populations of P. alabamensis are geographically isolated from one another by land and salt water, which could act as barriers to intraspecific gene flow. It is currently unknown how differentiated these isolated populations are from one another or whether they have experienced reductions in population size. Previous work found morphological differences between Alabama and Mississippi populations, suggesting that they may be evolutionarily distinct. Other Pseudemys turtles such as P. concinna and P. floridana occur within the same geographic area as P. alabamensis and are known to hybridize with each other. These more abundant species could further threaten the unique genetic identity of P. alabamensis through introgression. In order to evaluate the endangered status of P. alabamensis and the level of hybridization with other species, we used the mitochondrial (mtDNA) control region and nuclear microsatellite markers to assess genetic variation within and among populations of this species throughout its range and estimate admixture with co-occurring Pseudemys species. Genetic diversity of P. alabamensis was lower than expected at both markers (no variation in mtDNA and excess of homozygosity in microsatellites). We found evidence of genetic differentiation between Alabama and Mississippi populations as well as two populations (Fowl River, Alabama and Biloxi, Mississippi) with low estimated breeding sizes and signs of inbreeding. Finally, we found evidence of admixture of P. alabamensis with P. concinna/P. floridana and Pseudemys peninsularis (a species not native to Alabama or Mississippi). Our results indicate that P. alabamensis is highly endangered throughout its range and threatened by both low population sizes and hybridization. In order to improve the species' chances of survival, focus should be placed on habitat preservation, maintenance of genetic diversity within both Mississippi and Alabama populations, and regular population monitoring activities such as nest surveillance and estimates of recruitment.

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Evolutionary genetics of small populations

10.1093/oso/9780198783398.003.0002 ◽

2017 ◽

Author(s):

Richard Frankham ◽

Jonathan D. Ballou ◽

Katherine Ralls ◽

Mark D. B. Eldridge ◽

Michele R. Dudash ◽

...

Keyword(s):

Genetic Diversity ◽

Population Size ◽

Evolutionary Genetics ◽

Small Population ◽

Small Populations ◽

Effective Population ◽

Genetic Management ◽

Evolutionary Genetic ◽

Loss Of Genetic Diversity ◽

Number Of Individuals

Genetic management of fragmented populations involves the application of evolutionary genetic theory and knowledge to alleviate problems due to inbreeding and loss of genetic diversity in small population fragments. Populations evolve through the effects of mutation, natural selection, chance (genetic drift) and gene flow (migration). Large outbreeding, sexually reproducing populations typically contain substantial genetic diversity, while small populations typically contain reduced levels. Genetic impacts of small population size on inbreeding, loss of genetic diversity and population differentiation are determined by the genetically effective population size, which is usually much smaller than the number of individuals.

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Small population size and low genomic diversity have no effect on fitness in experimental translocations of a wild fish

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2019.1989 ◽

2019 ◽

Vol 286 (1916) ◽

pp. 20191989 ◽

Cited By ~ 1

Author(s):

M. C. Yates ◽

E. Bowles ◽

D. J. Fraser

Keyword(s):

Genetic Diversity ◽

Body Size ◽

Population Size ◽

Brook Trout ◽

Habitat Degradation ◽

Species Conservation ◽

Empirical Work ◽

Genomic Diversity ◽

Effective Population ◽

Isolated Populations

Little empirical work in nature has quantified how wild populations with varying effective population sizes and genetic diversity perform when exposed to a gradient of ecologically important environmental conditions. To achieve this, juvenile brook trout from 12 isolated populations or closed metapopulations that differ substantially in population size and genetic diversity were transplanted to previously fishless ponds spanning a wide gradient of ecologically important variables. We evaluated the effect of genome-wide variation, effective population size ( N e ), pond habitat, and initial body size on two fitness correlates (survival and growth). Genetic variables had no effect on either fitness correlate, which was determined primarily by habitat (pond temperature, depth, and pH) and initial body size. These results suggest that some vertebrate populations with low genomic diversity, low N e , and long-term isolation can represent important sources of variation and are capable of maintaining fitness in, and ultimately persisting and adapting to, changing environments. Our results also reinforce the paramount importance of improving available habitat and slowing habitat degradation for species conservation.

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Eumops floridanus (Chiroptera: Molossidae)

Mammalian Species ◽

10.1093/mspecies/seab012 ◽

2021 ◽

Vol 53 (1009) ◽

pp. 125-133

Author(s):

Jessica M Vannatta ◽

Jeffery A Gore ◽

Verity L Mathis ◽

Brian D Carver

Keyword(s):

United States ◽

Population Size ◽

The United States ◽

Small Population ◽

Species Level ◽

Small Population Size ◽

Restricted Distribution ◽

Dead Trees ◽

Fish And Wildlife Service

Abstract Eumops floridanus (Allen, 1932) is a molossid commonly called the Florida bonneted bat or the Florida mastiff bat. Eumops floridanus is the largest species of bat in Florida and is one of 16 species in the genus Eumops. With one of the smallest distributions of any bat in the United States, it is endemic to southern peninsular Florida where it roosts in cavities of live and dead trees and man-made structures. Eumops floridanus was formerly classified as a subspecies of E. glaucinus but has been elevated to species level based on morphology. Due primarily to its restricted distribution, small population size, and the continued loss of habitat, E. floridanus is federally listed as “Endangered” (EN) by the United States Fish and Wildlife Service.

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Quantifying the relationship between genetic diversity and population size suggests natural selection cannot explain Lewontin's paradox

eLife ◽

10.7554/elife.67509 ◽

2021 ◽

Vol 10 ◽

Author(s):

Vince Buffalo

Keyword(s):

Genetic Diversity ◽

Population Size ◽

Phylogenetic Signal ◽

Neutral Theory ◽

Negative Relationship ◽

Abundant Species ◽

Census Size ◽

Population Sizes ◽

The Relationship ◽

Linked Selection

Neutral theory predicts that genetic diversity increases with population size, yet observed levels of diversity across metazoans vary only two orders of magnitude while population sizes vary over several. This unexpectedly narrow range of diversity is known as Lewontin’s Paradox of Variation (1974). While some have suggested selection constrains diversity, tests of this hypothesis seem to fall short. Here, I revisit Lewontin’s Paradox to assess whether current models of linked selection are capable of reducing diversity to this extent. To quantify the discrepancy between pairwise diversity and census population sizes across species, I combine previously-published estimates of pairwise diversity from 172 metazoan taxa with newly derived estimates of census sizes. Using phylogenetic comparative methods, I show this relationship is significant accounting for phylogeny, but with high phylogenetic signal and evidence that some lineages experience shifts in the evolutionary rate of diversity deep in the past. Additionally, I find a negative relationship between recombination map length and census size, suggesting abundant species have less recombination and experience greater reductions in diversity due to linked selection. However, I show that even assuming strong and abundant selection, models of linked selection are unlikely to explain the observed relationship between diversity and census sizes across species.

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Genetics of reintroduced populations of the narrowly endemic thistle, Cirsium pitcheri (Asteraceae)

Botany ◽

10.1139/cjb-2012-0232 ◽

2013 ◽

Vol 91 (5) ◽

pp. 301-308 ◽

Cited By ~ 12

Author(s):

Jeremie B. Fant ◽

Andrea Kramer ◽

Eileen Sirkin ◽

Kayri Havens

Keyword(s):

Genetic Diversity ◽

Population Size ◽

Empirical Studies ◽

Small Population ◽

Native Plant ◽

Effective Population ◽

Term Survival ◽

Inbreeding Coefficients ◽

Native Populations ◽

Population Sizes

The aim of any reintroduction is to provide sufficient genetic variability to buffer against changing selection pressures and ensure long-term survival. To date, few empirical studies have compared levels of genetic diversity in reintroduced and native plant populations. Using microsatellite markers, we measured the genetic diversity within reintroduced and native populations of the threatened Cirsium pitcher (Eaton) Torrey and Gray. We found that the use of local mixed source was successful in establishing populations with significantly higher genetic diversity (P < 0.005) than the native populations (allelic richness is 3.39 in reintroduced and 1.84 in native populations). However, the reintroduced populations had significantly higher inbreeding coefficients (P < 0.002) (FIS is 0.405 and 0.213 in reintroduced and in native populations, respectively), despite having multiple genetic founders, population sizes equivalent to native populations and a positive growth rate. These results may be due to inbreeding or the Wahlund effect, driven by genetic substructuring. This suggests that the small population size of these reintroduced populations may lead to genetic issues in the future, given the low number of flowering individuals each year. This highlights the importance of considering not only the number of source individuals but the effective population size of the reintroduction.

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Low Neutral Genetic Diversity in an Isolated Greater Sage Grouse (Centrocercus Urophasianus) Population in Northwest Wyoming

The UW National Parks Service Research Station Annual Reports ◽

10.13001/uwnpsrc.2012.3943 ◽

2012 ◽

Vol 35 ◽

pp. 119-133

Author(s):

Sarah Schulwitz ◽

Jeff Johnson ◽

Bryan Bedrosian

Keyword(s):

Genetic Diversity ◽

Habitat Fragmentation ◽

Population Size ◽

Centrocercus Urophasianus ◽

Small Population ◽

Suitable Habitat ◽

Sage Grouse ◽

Asymmetric Dispersal ◽

Anthropogenic Habitat ◽

Neutral Genetic Diversity

Habitat loss is well recognized as an immediate threat to biodiversity. Depending on the dispersal capabilities of the species, increased habitat fragmentation often results in reduced functional connectivity and gene flow followed by population decline and a higher likelihood of eventual extinction. Knowledge of the degree of connectivity between populations is therefore crucial for better management of small populations in a changing landscape. A small population of greater sage-grouse (Centrocercus urophasianus) exists in northwest Wyoming within the Jackson Hole valley, including Grand Teton National Park and the National Elk Refuge. To what degree the Jackson population is isolated is not known as natural dispersal barriers in the form of mountains and anthropogenic habitat fragmentation may limit the populationâs connectivity to adjacent populations. Using 16 microsatellite loci and 300 greater sage-grouse samples collected throughout Wyoming and southeast Montana, significant population differentiation was found to exist among populations. Results indicated that the Jackson population was isolated relative to the other sampled populations, including Pinedale, its closest neighboring large population to the south. The one exception was a small population immediately to the east of Jackson, in which asymmetric dispersal from Jackson into Gros Ventre was detected. Both Jackson and Gros Ventre populations exhibited significantly reduced levels of neutral genetic diversity relative to other sampled populations. More work is warranted to determine the timing at which Jackson and Gros Ventre populations had become isolated and whether it was primarily due to recent habitat fragmentation or more historic processes. Due to its small population size, continual monitoring of the population is recommended with the goal of at least maintaining current population size and, if possible, increasing suitable habitat and population size to levels recorded in the past.

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Genetic Diversity Within and Among Populations of Shorea Robusta Roxb. Ex Gaertn. In Bangladesh and Its Implications for Conservation

Bangladesh Journal of Botany ◽

10.3329/bjb.v50i2.54098 ◽

2021 ◽

Vol 50 (2) ◽

pp. 405-412

Author(s):

Pragga Saha Sharmi ◽

Md Abul Kashem ◽

Rifat Samad ◽

Mohammad Zabed Hossain

Keyword(s):

Genetic Diversity ◽

Population Size ◽

Isolation By Distance ◽

Genetic Erosion ◽

Mantel Test ◽

Small Population ◽

Deciduous Forests ◽

Shorea Robusta ◽

Low Genetic Diversity ◽

Geographical Regions

Fragmentation and reduction of natural population size render threats to the conservation of forest resources through depletion of genetic diversity. Hence, information on genetic structure of Sal (Shorea robusta Roxb. ex Gaertn.) populations is relevant for proper management and conservation of the tropical deciduous forests. The present study focused on assessing the genetic diversity of the populations of Sal which was the dominant tree species of the deciduous forests of Bangladesh. Plant leaf samples were collected from the three populations of Sal distributed in the three geographical regions including Madhupur tract in the districts Tangail and Gazipur and that of the districts of Cumilla and Dinajpur. DNA band profiles were generated using eight ISSR primers for a total of 13 samples taken from the three populations. Statistical analysis was done using PopGen 32 and GenAlEx 6.5 softwares. Principal coordinate analysis done on the DNA band profiles revealed that Sal populations of Madhupur tract and Cumilla positioned nearby while Dinajpur showed maximum genetic distance with that of Cumilla. Mantel test showed significant (p=0.05) correlation between genetic and geographic distances indicating “Isolation by Distance”. Data of the present study indicated higher genetic polymorphism (68.87%) in the Sal population of Madhupur tract compared to other two populations. Small population size of Sal of Dinajpur forest might be related with its low genetic diversity. Data of the present study suggest immediate attention for the conservation of Sal forests in Bangladesh before further genetic erosion occurs. Bangladesh J. Bot. 50(2): 405-412, 2021 (June)

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Genomic consequences of colonisation, migration and genetic drift in barn owl insular populations of the eastern Mediterranean

10.1101/2021.06.10.447833 ◽

2021 ◽

Author(s):

Ana Paula Machado ◽

Alexandros Topaloudis ◽

Tristan Cumer ◽

Eléonore Lavanchy ◽

Vasileios Bontzorlos ◽

...

Keyword(s):

Genetic Diversity ◽

Gene Flow ◽

Stochastic Processes ◽

Genetic Drift ◽

Eastern Mediterranean ◽

Genomic Analysis ◽

Barn Owl ◽

Small Population ◽

Isolated Populations ◽

Insular Populations

The study of insular populations was key in the development of evolutionary theory. The successful colonisation of an island depends on the geographic context, and specific characteristics of the organism and the island, but also on stochastic processes. As a result, apparently identical islands may harbour populations with contrasting histories. Here, we use whole genome sequences of 65 barn owls to investigate the patterns of inbreeding and genetic diversity of insular populations in the eastern Mediterranean Sea. We focus on Crete and Cyprus, islands with similar size, climate and distance to mainland, that provide natural replicates for a comparative analysis of the impacts of microevolutionary processes on isolated populations. We show that barn owl populations from each island have a separate origin, Crete being genetically more similar to other Greek islands and mainland Greece, and Cyprus more similar to the Levant. Further, our data show that their respective demographic histories following colonisation were also distinct. On the one hand, Crete harbours a small population and maintains very low levels of gene flow with neighbouring populations. This has resulted in low genetic diversity, strong genetic drift, increased relatedness in the population and remote inbreeding. Cyprus, on the other hand, appears to maintain enough gene flow with the mainland to avoid such an outcome. Our work provides a comparative population genomic analysis of the effects of neutral processes on a classical island-mainland model system. It provides empirical evidence for the role of stochastic processes in determining the fate of diverging isolated populations.

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Conservation biology of threatened Mediterranean chasmophytes: The case of Asperula naufraga endemic to Zakynthos island (Ionian islands, Greece)

PLoS ONE ◽

10.1371/journal.pone.0246706 ◽

2021 ◽

Vol 16 (2) ◽

pp. e0246706 ◽

Cited By ~ 1

Author(s):

Anna-Thalassini Valli ◽

Vassiliki Lila Koumandou ◽

Gregoris Iatrou ◽

Marios Andreou ◽

Vasileios Papasotiropoulos ◽

...

Keyword(s):

Genetic Diversity ◽

Population Size ◽

Extinction Risk ◽

Conservation Status ◽

Small Population ◽

Ex Situ ◽

Current Conservation ◽

Ionian Islands ◽

Small Population Size ◽

Area Of Occupancy

Asperula naufraga is a rare and threatened obligate chasmophyte, endemic to Zakynthos island (Ionian islands, Greece). In this study, we provide a combined approach (including monitoring of demographic and reproductive parameters and study of genetic diversity) to assess the current conservation status of the species and to estimate its future extinction risk. The five subpopulations of A. naufraga were monitored for five years (2014–2018). Population size markedly fluctuated between 68–130 mature individuals during the monitoring period. The extent of occurrence (EOO) was estimated at 28.7 km2 and the area of occupancy (AOO) was 8 km2. Stage-structure recordings were similar for all subpopulations, characterized by high proportions of adult and senescent individuals, following a common pattern, which has been observed in other cliff-dwelling plants. Preliminary genetic analysis with SSRs markers revealed low heterozygosity within subpopulations and significant departure from H-W equilibrium, which combined with small population size suggest increased threat of genetic diversity loss. Our results indicate that the species should be placed in the Critically Endangered (CR) IUCN threat category, while according to Population Viability Analysis results its extinction risk increases to 47.8% in the next 50 years. The small population size combined with large fluctuations in its size, low recruitment and low genetic diversity, indicate the need of undertaking effective in situ and ex situ conservation measures.

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Population extinctions driven by climate change, population size, and time since observation may make rare species databases inaccurate

10.1101/506006 ◽

2018 ◽

Author(s):

Thomas Kaye ◽

Matt A Bahm ◽

Andrea S Thorpe ◽

Erin C Gray ◽

Ian Pfingsten ◽

...

Keyword(s):

Climate Change ◽

Population Size ◽

Rare Species ◽

Biological Diversity ◽

Extinction Risk ◽

Climate Change Impacts ◽

Small Population ◽

Population Extinction ◽

Population Sizes ◽

Potential Signal

Loss of biological diversity through population extinctions is a global phenomenon that threatens many ecosystems. Managers often rely on databases of rare species locations to plan land use actions and conserve at-risk taxa, so it is crucial that the information they contain is accurate and dependable. However, climate change, small population sizes, and long gaps between surveys may be leading to undetected extinctions of many populations. We used repeated survey records for a rare but widespread orchid, Cypripedium fasciculatum (clustered lady's slipper), to model population extinction risk based on elevation, population size, and time between observations. Population size was negatively associated with extinction, while elevation and time between observations interacted such that low elevation populations were most vulnerable to extinction, but only over larger time spans. We interpret population losses at low elevations as a potential signal of climate change impacts. We used this model to estimate the probability of persistence of populations across California and Oregon, and found that 31%-56% of the 2415 populations reported in databases from this region are likely extinct. Managers should be aware that the number of populations of rare species in their databases is potentially an overestimate, and consider resurveying these populations to document their presence and condition, with priority given to older reports of small populations, especially those at low elevations or in other areas with high climate vulnerability.

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