Abstract
Island populations may have a higher extinction risk due to reduced genetic diversity and need to be managed effectively in order to reduce the risk of biodiversity loss. The Eurasian red squirrels (Sciurus vulgaris) in the south of England only survive on three islands (the Isle of Wight, Brownsea and Furzey islands), with the Isle of Wight harbouring the largest population in the region. Fourteen microsatellites were used to determine the genetic structure of red squirrel populations on the Isle of Wight, as well as their relatedness to other populations of the species. Our results demonstrated that squirrels on these islands were less genetically diverse than those in Continental mainland populations, as would be expected. It also confirmed previous results from mitochondrial DNA which indicated that the squirrels on the Isle of Wight were relatively closely related to Brownsea island squirrels in the south of England. Importantly, our findings showed that genetic mixing between squirrels in the east and west of the Isle of Wight was very limited. Given the potential deleterious effects of small population size on genetic health, landscape management to encourage dispersal of squirrels between these populations should be a priority.
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Introduction
Island populations are often characterised by small population size, strong genetic differentiation and high genetic drift (Nei et al. 1975; Frankham 1997). Such populations may have higher extinction risks because of their low genetic diversity, due to founder effect and bottleneck events, which can cause inbreeding depression and limit their adaptive potential (Reed and Frankham 2003; Frankham 2005). As the Eurasian red squirrel (Sciurus vulgaris) in the south of the UK has been confined to islands and increasingly isolated woodland fragments, for around half a century (Lloyd 1983), these genetic factors are of particular concern (Hardouin et al. 2019).
The decline of the Eurasian red squirrel in the UK, following the introduction of its invasive congener, the Eastern grey squirrel Sciurus carolinensis, is well documented (e.g. Shorten 1953; Lloyd 1983; Kenward and Holm 1989; Gurnell and Pepper 1993; Gurnell et al. 2004) and the need to conserve remaining populations of the native species has been amplified by the establishment of S. carolinensis in parts of continental Europe (Bertolino et al. 2008, 2014). In the UK, the remaining strongholds for the native squirrel are found in large isolated woodlands in the north of England and southern Scotland, as well as still extensive, contiguous areas in northern Scotland. In the south of the country, the only remaining populations survive in parts of Wales (Ogden et al. 2005) and on three islands off the south coast of England (Brownsea and Furzey islands and the Isle of Wight—Rushton et al 1999; Hardouin et al 2019). Mitochondrial (mt) DNA analyses have revealed that red squirrels on the three islands have relatively low genetic diversity, appear more closely related to other British squirrels than to red squirrels from elsewhere in Europe, and tantalisingly, appeared to have private haplotypes indicating the potential presence of distinct genetic lineages on the islands (Hardouin et al. 2019).
With an estimated 3300 squirrels, the Isle of Wight (38,016 ha with over 3600 ha of woodland), harbours by far the largest population of red squirrels in the south of the country (Pope and Grogan 2003) with much smaller populations remaining on Brownsea and Furzey islands (Thain and Hodder 2015). As the islands are relatively safe from invasion by S. carolinensis, there is considerable justification for ensuring effective conservation management (including genetic diversity) of the red squirrel in these island strongholds. This arboreal specialist has maintained its presence on the Isle of Wight despite severe fragmentation of the woodland, especially in the south of the island (Rushton et al. 1999).
As habitat fragmentation has long been recognised as one of the main factors leading to biodiversity loss (e.g. Fahrig 2003), effective management requires understanding the impacts of habitat loss and fragmentation on species of conservation concern (Mortelliti et al. 2011). Studies of populations of red squirrels in fragmented landscapes have shown that woodland patch size, distance to other woodlands and dispersal corridors are all important to their distribution (Van Apeldorn et al. 1994), and that habitat quality strongly affects female space use (Verbeylen et al. 2009). It has also been recognised that fragmentation of woodlands affects the genetic population structure of red squirrels in Germany (Wiegand and Schröpfer 1997) and Belgium (Wauters et al. 1994). So, a lack of mixing between isolated populations might be expected to deleteriously affect the squirrels on the island and the ability of squirrels to disperse between patches is therefore crucial.
In common with most terrestrial mammals, dispersal of tree squirrels tends to occur by movement of juveniles from their natal ranges (Bosch and Lurz 2012) with distances of under 1 km typically recorded for red squirrels (e.g. Wauters et al. 2010), although much longer distances have been observed in low density forest habitats (Hämäläinen et al. 2019). In the highly modified landscape of the Isle of Wight, with only 12% of the island being afforested (Watts et al. 2016), such dispersal may be constrained. Past modelling of the persistence of squirrel populations on the island has emphasised the need for large and interconnected woods with management to enhance landscape features for dispersal and local population persistence (Rushton et al. 1999).
Hämäläinen et al. (2019) suggested that while movement patterns of dispersing red squirrels may be strongly influenced by landscape structure, they speculated that there may be little impact on gene flow in the forest landscape of Finland. In fragmented landscapes, this is likely to be true up to certain thresholds of habitat loss as postulated by Andren (1994) and provided that landscape features do not introduce impenetrable barriers (Trizio et al. 2005).
Building on previous research (Hardouin et al. 2019), this study therefore focuses on the following aims in order to inform both local and regional conservation strategies for this charismatic rodent: (i) to characterise the genetic structure and diversity of the red squirrel population on the Isle of Wight in order to determine whether there is evidence that the fragmented woodlands impede gene flow, (ii) to determine whether microsatellite analyses support conclusions from mtDNA on the relatedness of the island squirrels to other island and mainland populations.
Materials and methods
Samples
The sampling scheme used to obtain DNA for Brownsea red squirrels is described in Hardouin et al. (2019). Arran red squirrel tissue samples were collected opportunistically from road kills. Ear tissue samples from the Isle of Wight were collected between 2013 and 2018 as part of the Wight Squirrel Project monitoring program (see Simpson et al. 2013a for sampling scheme). The general public from all around the island were encouraged to report red squirrel deaths and the carcasses were sampled for the DNA extraction. Samples from Germany originate from wildlife rescue centres and zoological gardens in Bavaria and Baden-Wuerttemberg, southern Germany (Fig. 1).
Microsatellite genotyping
Microsatellites described in Todd et al. 2000 and Hale et al. 2001a were tested and 161 red squirrel samples were successfully genotyped for 15 markers. The 5’ end of the forward primers was labelled with either HEX or FAM dyes. All reactions were carried out in 13 µl volumes using 10 ng of DNA template. Primer pairs were mixed in 7 pools and reactions were performed using the QIAGEN multiplex PCR kit. PCR conditions were as follow: 94 °C for 5 min, then 35 cycles of denaturation (94 °C for 30 s), annealing (for 30 s at 52 °C or to 54 °C depending on primer pool), and then amplification (72 °C for 1 min), followed by a final elongation at 72 °C for 10 min.
Microsatellite analysis
Calculation of the observed and expected heterozygosity, and the average number of alleles per locus was performed with GENETIX (Belkhir et al. 2004) for each population. The Hardy–Weinberg equilibrium and Fst were tested using Arlequin (Excoffier and Lischer 2010). Allelic richness was calculated using the PopGenReport (Adamack and Gruber 2014). Fis was investigated using diveRsity and 1000 bootstraps were used to infer the 95% confidence intervals (Keenan et al. 2013). Then discriminant analysis of principal components (DAPC) (Jombart et al. 2010) was used to assess the population structure using the complete dataset. DAPC and Monnonier’s analysis were performed in R using the ADEGENET package (Jombart et al. 2008). DAPC is a multivariate analysis which inferred the probability of individual membership in each different group. The program covered a range of possible clusters from 1 to 10. The interaction number used was 1,000,000,000. 30 principal components, explaining 92.4% of the total variance, were retained as predictors for discriminant analysis.
In addition, we performed a structure analysis on the entire dataset using STRUCTURE software (Pritchard et al. 2000) with a burn-in period of 250,000 simulations followed by a run length of 750,000 Markov chain Monte Carlo (MCMC) simulations and ten iterations for each K (number of clusters) with the admixture model. The results were analysed using STRUCTURE HARVESTER (Earl and vonHoldt 2012) and the K was chosen using a combination of Evanno’s criteria (Evanno et al. 2005) and investigating run convergence using CLUMPP (Jakobsson and Rosenberg 2007). Results were summarized using CLUMPP (Jakobsson and Rosenberg 2007) and drawn using Distruct (Rosenberg 2004). K from 1 to 10 was tested for the entire dataset (6 populations and 161 individuals). The data set was further spit in two: the Isle of Wight for which K = 1 to K = 7 were tested and the rest of the populations (Brownsea, Arran, Baden-Wuerttemberg and Bavaria) for which K = 1 to K = 10 were tested. Isolation by distance (IBD) for the Isle of Wight was investigated using Mantel test provided in the Adegenet package (Jombart et al. 2008). The potential for bottlenecks on the Isle of Wight was investigated using BOTTLENECK (Piry et al. 1999). Effective population size (Ne) was estimated for the population on the Isle of Wight using NeEstimator V2.1 (Do et al. 2014). IBD, bottleneck and Ne were not calculated for the other populations as sample sizes were insufficient.
Spatial distribution and land cover
In order to determine whether the sample of squirrel carcasses from the Isle of Wight might be biased towards where people live and are hence more likely to be found, we determined the broad habitat for sample locations. The habitat categories from the Centre for Ecology and Hydrology Land Cover Map 2015 (2017) were merged to five broad classes: (1). Arable and horticulture 26.2%, (2). Grasslands (consisting of all sub-types of grasslands) 46.5%, (3). Woodland (broadleaf and coniferous woodland) 12.1%, (4). Urban and suburban 2.1% and (5). Other (merging all remaining categories, predominantly coastal littoral, saltwater and saltmarsh) 13.1% of the total area. Subsequently, the study area was divided into 48 equally sized rectangles (10 km2) and the percentage of all land cover categories and the number of squirrel carcasses retrieved in this study was calculated for each rectangle. Spearman rho and Kendall tau was used to establish correlation between land cover types and squirrel numbers. Multiple buffer ring analysis was also employed to investigate the relationship between the location of squirrel carcasses and the distance from settlements on the Isle of Wight (Office for National Statistics, 2011 Census data, ons.gov.uk). A series of buffers at 500 m, 1000 m, 1500 m, 2000 m, 2500 m, 3000 m and 3500 m were created around 21 areas with the highest population density. All spatial analyses used ArcMap 10.1.
Results
Genetic diversity
Out of the 15 microsatellites, one was found not under Hardy–Weinberg equilibrium and it was therefore excluded from the analysis. Samples with less than 70% of microsatellites successfully amplified were also excluded; therefore, the final dataset was composed of 161 individuals. As expected, mean allelic richness was found to be higher in Continental mainland populations (4.34 for Baden-Wuerttemberg, 4.37 for Bavaria) when compared to the islands (2.22 for Isle of Arran, 2.28 for Brownsea Island and 2.69 for the Isle of Wight—Table 1). Fis were calculated for all of our populations (Table 1), and no deficit or excess of heterozygotes was found apart from the Isle of Wight (Fis = 0.132, 0.08; 0.18 95% CI). However, these positive Fis values are likely to be related to the two distinct genetic clusters that were found on this island (i.e., a Wahlund effect).
Population structure
The lowest Bayesian information criterion (BIC) value (194.86) was found for K = 7 in the DAPC analysis. The first 30 PCs of principal component analysis (PCA) explaining 92.4% of the total variance were kept. The first two axes represent respectively 48% and 26% of the variance (Fig. 2). Axis 1 explained the variation between Arran and the rest of the populations. The South German and the UK populations are separated on axis 2. The Isle of Wight and Brownsea Island group together and Bavaria and Baden-Wuerttemberg also form a group of two (Fig. 2).
The population structure of the dataset was further investigated using STRUCTURE (Pritchard et al. 2000). K = 2 was selected as the best model for the entire dataset and in this model the Isle of Wight was found to be genetically distinct from the rest of the populations (Fig. 3a).
When population structure on the Isle of Wight was investigated separately this indicated that the island population is separated into two different clusters (Fig. 3b). The Evanno’s method suggests that K = 3 is the appropriate K (Fig. 3b) however, increasing the number of K only divides one of the clusters (Fig. 3b), therefore K = 2 was chosen as the best K to explain the data. The island appears to harbour two genetically different populations, one located in the west and the other on the east of the island (Fig. 4).
The genetic structure of the four remaining populations was further tested and even though the best K was found to be K = 2 using the Evanno method, further inspection of the results using CLUMPP reveals that K = 2, K = 3 and K = 4 did not converge. K = 5 was found to converge and to give the best fit to the data (Fig. 3c). In this analysis, Brownsea and Arran islands displayed genetic signatures that were distinct from each other, and the two South German populations clustered together (Fig. 3c). The German population structure was investigated further using structure and again it was not possible to differentiate them (supplementary material 1A). A 3D factorial was also generated, axis 1 was found to explain 100% of the variation and differentiate both populations (supplementary material 1B).
Pairwise Fst between all those populations was calculated and was found to be between 0.18 and 0.45 with a significant p-value except between the two German populations (Fst = 0.01, p = 0.23—Table 2). A Mantel test was performed for the Isle of Wight and the geographical and genetic matrices were found to be positively correlated (0.372, p = 0.0001). There were insufficient numbers of samples to conduct this test for the remaining sites.
Genetic boundaries on the Isle of Wight were investigated further using Monnonier’s algorithm (Fig. 5) which identifies the centre of the island, as well as small proportion of the coast, as forming a genetic barrier (Fig. 5).
Bottleneck and effective population size on the Isle of Wight
Ne and the probability of a recent bottleneck was investigated on both parts of the Isle of Wight. No sign of a bottleneck was found on the island under the SMM (Step Mutation Model) using a Wilcoxon test (p = 0.83 and p = 0.90 for the west and the east of the island respectively). Ne was found to be 40.3 for the western part of the Isle of Wight and 73.7 for the eastern part of the island using the linkage disequilibrium method with a frequency threshold of 0.05. Fis was calculated for both populations on the Isle of Wight. Fis was found to be 0.061 (− 0.031; 0.151, 95% CI) and 0.067 (0.013; 0.122, 95% CI) for the west and the east population respectively revealing a signature of inbreeding in the Eastern population on the Isle of Wight.
Testing the sampling validity for S. vulgaris on the Isle of Wight
Red squirrels obtained from the Isle of Wight for this study were sampled by the general public and so we tested the spatial distribution of the samples to determine whether any bias toward location of samples in, or close to, settlements might have affected our data. Multiple buffer ring analysis indicated that the highest concentrations of red squirrels sampled on the Isle of Wight were in close proximity to human settlements (Fig. 6). 40% of all red squirrel sightings were recorded within 500 m of the outer perimeter of the settlements, while only 21% are recorded at a distance of 2000 m, or more, from the outer perimeter of the settlements. The association between red squirrels and land cover was also tested, and no association was found between red squirrel data locations and urban land cover class. The only significant correlation between land cover type and red squirrel carcass locations was with woodland (Spearman’s Rho = 0.34, p < 0.05, Kendall Tau = 0.27, p < 0.05).
Discussion
Our results indicated a clear fragmentation of the red squirrel populations on the Isle of Wight. This reinforces previous conclusions from spatially explicit population dynamics modelling (Rushton et al. 1999) that landscape management to provide dispersal corridors and to interconnect woodlands is critical for the long term future of the species on the island.
We also found relatively low genetic diversity for the island in comparison to continental squirrels. However, no genetic bottleneck was detected on the Isle of Wight. It is worth noting that low genetic diversity has also been reported for other red squirrel populations in the UK when they are compared to continental populations using Major Histocompatibility Complex (MHC) class II (Ballingal et al. 2016) and when using mtDNA (Baratt et al. 1999; Hale et al. 2004; Ogden et al. 2005). Our results also supported previous findings from mtDNA, indicating that the Isle of Wight population is genetically close to the Brownsea Island population, which probably reflects a common origin, and that those island populations share unique haplotypes when compared to a European dataset (Hardouin et al. 2019).
Population structure and connectivity on the Isle of Wight
As S. vulgaris is an arboreal specialist, with a preference for closed canopy (Gurnell et al. 2002; Samaras and Youlatos 2010), it is unsurprising that fragmentation of woodland habitats has been shown to affect the genetic diversity of red squirrels (Wauters et al. 1994; Hale et al. 2001b; Trizio et al. 2005; Simpson et al. 2013b; Rézouki et al. 2014; O’Meara et al. 2018). Our findings suggest that this impediment to gene flow may also be true for squirrels on the Isle of Wight. Our assessment of the distribution of the red squirrel samples did indicate that they tended to be found relatively close to human settlement. This result is expected as the squirrels have been collected with the help of the general public for the Wight Squirrel Project monitoring program (Simpson et al. 2013a) and this influenced sample locations. Relatively few samples were collected from the centre of the island where human density is low (Fig. 5) and this could represent a potential sampling error. Nevertheless, the East/West population structure that we found seems likely to be associated with the pattern of woodland cover on the island. Most of the larger patches of woodland, which are most likely to harbour larger populations of squirrels (Van Apeldoorn et al. 1994) are situated to the East and West, with only small, isolated woodlands in the centre (Rushton et al. 1999, Fig. 5) which was found to reprensent a barrier to gene flow. It may be pertinent that the landscape on the island has been highly modified since early history and, that there is thought to be more woodland on the island now than there has been for hundreds of years (IWBP 2009).
The regeneration of woodland on the island in recent decades, such as by the Forestry Commission funded JIGSAW project (Quine and Watts 2007), should provide opportunities for creatively managing the landscape connectivity for the red squirrel and other woodland specialists. Although it is important to note that the benefits of landscape connectivity cannot necessarily be assumed for all woodland specialists (Watts et al. 2016). Rushton et al. (1999) recommended maintaining large woodlands, which can act as population sources, and ensuring the presence of habitat corridors, such as hedgerows, in order to conserve the red squirrels on the Isle of Wight. Since then, the importance of habitat corridors in the restoration of genetic mixing for red squirrels has been demonstrated (Hale et al. 2001b; Trizio et al. 2005).
Although, the importance of corridors for red squirrels is clear, the design of functional corridors is affected by muliple considerations: patch size and quality, matrix composition and barriers to dispersal. So, it will be important to understand the dispersal behaviour of the Isle of Wight red squirrels in order to understand the mechanisms underlying the population structure and to develop any measures that may be effective in enhancing genetic mixing. As the woodlands of the Isle of Wight are dominated by mixed woodlands providing a range of tree seed crops (Rushton et al. 1999), breeding dispersal would be expected to be relatively rare as this is generally a phenomenon of habitats with unreliable food sources (Lurz et al. 1997). Gene flow between woodland patches would most likely occur through dispersal of adult males in search of mates and young squirrels dispersing from their natal ranges (reviewed in Bosch and Lurz 2012). Given the wide range of dispersal distances that have been recorded for this species in fragmented landscapes (e.g. Wauters et al. 2010, Bosch and Lurz 2012, Hämäläinen et al. 2019), further work will be needed to determine the functionality of apparent landscape corridors, the potential for natal dispersal in the Isle of Wight, and how this might be enhanced. The permeability of the matrix and presence of barriers will also be important factors (Trizio et al. 2005). Although roads appeared not to be a barrier for the dispersal of red squirrels in an urban environment (Fey et al. 2016) other studies have shown that road crossing can be a major cause of mortality (Simpson et al. 2013a on the Isle of Wight, LaRose et al. 2010 in Scotland). Given that the tendency for red squirrels to cross roads appears to be life stage and state specific (Fey et al. 2016), there might be potential to manage particular crossing points when juvenile dispersal is at its most prevalent. Appropriate bridges to connect woodlands fragmented by roads can also benefit other wildlife, such as the hazel dormouse Muscardinus avellanarius (White and Hughes 2019).
Another possible barrier to gene flow on the Isle of Wight could be the Medina river in the north of the island (Fig. 6). Even though red squirrels are able to swim (Kenward and Hodder 1998, Bosch and Lurz 2012), it would be likely to decrease gene flow. For example, in Ireland the river Shannon has been found to act as a barrier for the migration of grey squirrels even if some individuals were occasionaly able to swim across (Carey et al. 2007). However, the river Medina is only 17 km long, therefore, its impact is likely to be limited.
Phylogeographic structure
Red squirrels in Europe have been found to lack phylogeographical structure when using mitochondrial DNA (Barrat et al. 1999; Grill et al. 2009; Hardouin et al. 2019). In contrast, microsatellite techniques used here demonstrated a clear population structure despite using a modest number of markers. We showed that the population of Brownsea Island and Isle of Wight are genetically closer to one another than to the Isle of Arran population (Scotland), whereas the two mainland populations from southern Germany were genetically similar to each other. This result suggests that nuclear markers might help us to understand the evolutionary history of the species. Such a lack of genetic structure in mtDNA when compared to nuclear markers is not uncommon and has been found in several species such as the red fox (Vulpes vulpes) for example (Teacher et al. 2011; Statham et al. 2018; McDevitt et al. 2020).
Allelic richness in our samples was found to be higher in mainland populations when compared to islands, which is expected (Nei et al. 1975). In small populations, there is a risk that alleles associated with better fitness might behave neutrally if genetic drift is stronger than natural selection (Wright 1931; Bouzat 2010). The protection of island populations is often a conservation priority due their unique genetic make-up, however, it can also lead to the risk of conserving an inbred population in order to conserve genetic uniqueness (Weeks et al. 2016). However, recent studies have demonstrated that adaptive differentation can act on islands even where strong drift occurs (Funk et al. 2016; Prentice et al. 2017). Therefore, understanding the role of genetic drift and natural selection in red squirrels on the Isle of Wight would be a critical step in order to infer if the loss of genetic diversity is a threat to the population and to develop an effective conservation strategy.
Conservation of the Isle of Wight and Brownsea squirrel populations
Previous work, using mtDNA, has shown that the last remaining red squirrel populations in the south of the England form two separate Evolutionary Significant Units (ESUs): (i) Isle of Wight and (ii) Brownsea/ Furzey combined as squirrels have been found to move between Brownsea and Furzey islands (Thain and Hodder 2015). Populations were also found to be genetically unique compared to 54 European populations using mtDNA markers (Hardouin et al. 2019). Here, our results supported those findings as we also found a high genetic divergence for those islands. Fst between Brownsea and the Isle of Wight was found to be 0.35 with p < 0.05 (Table 2). Nevertheless, they seem to be closely related to each other when compared to Isle of Arran and southern German populations (Fig. 2).
As genetic diversity on the Isle of Wight and Brownsea Island was found to be low using both mtDNA techniques (Hardouin et al. 2019) and microsatellites (this study), there could be concerns for the long term future of the population. No signs of inbreeding were found on Brownsea Island with our small dataset, however some sign of inbreeding was found in the Eastern population of red squirrels on the Isle of Wight. However, Ne on the Isle of Wight was only 40.3 in the west and 73.7 in the east. As Ne > 1000 is the value currently accepted as the minimum threshold to maintain adequate adaptive potential (Willi et al. 2006) the genetic health of the population requires ongoing monitoring. In terms of national strategy, it would be of particular interest to investigate the genetic structure of the British population further to identify possible rescue sources in case they are ever needed for these remnant populations of squirrels in the South of the UK. Ogden et al. (2005) employed this strategy by including donor squirrels from other areas to maximise genetic heterogeneity for conservation of red squirrels in Wales.
If genetic rescue by translocation of squirrels between Brownsea and the Isle of Wight was contemplated, this would require consideration of many risks including: outbreeding depression, loss of local adaptation, replacemenent of recipient genetic background and pathogen transmission (Week et al. 2011). The geographical and genetic similarity between the Isle of Wight and Brownsea populations would probably mean a very low risk of outbreeding depression, loss of local adaptation and replacement of genetic background. The main issue is likely to be the potential for pathogen transmission, for instance, Mycobacterium leprae causing leprosy is present on Brownsea Island and M. lepromatosis on the Isle of Wight (Avanzi et al. 2016).
Data availability
Genotype data is provided as supplementary material in a genepop format.
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Acknowledgements
We would like to thank the Wight Squirrel Project for commissioning the research as well as all the people of the Isle of Wight who helped collecting samples. The authors also would like to thank Korinna Seybold, Sabine Gallenberger, Jessica Hoch, Anette Hübsch, Sonja Jonas, Katharina Volk, Tobias Knauf-Witzens, Stefan Bosch and Jessica Weindl for collecting samples in southern Germany. We also would like to thank Kate Sampson, Corinna Goeckeritz, Andy Walker, Robert Logan, Angela Cott, Timothy Hartley, Nicki Tutton, Luke Johns, Chris Thain (National Trust for Scotland, Forestry Commission Scotland, National Trust Brownsea, Dorset Wildlife Trust) who were involved in the collection of samples on Brownsea Island and the Isle of Arran. The authors would also like to thank Alice Galligar for her help in the lab. We would also like to thank the three anonymous reviewers who helped to improve our manuscript.
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The work was commissioned by the Wight Squirrel Project.
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EAH and HB conceived the study. HB, AKS, AM and PWWL conducted field work for this investigation. RGU and VS did collect samples, dissect and provide tissues samples. EAH conducted the laboratory work. EAH, MC and KHH conducted the data analysis. EAH and KHH wrote the final manuscript. All authors were involved in writing and data interpretation and read and approved the final manuscript.
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Hardouin, E.A., Butler, H., Cvitanović, M. et al. Wildlife conservation in a fragmented landscape: the Eurasian red squirrel on the Isle of Wight. Conserv Genet 22, 571–583 (2021). https://doi.org/10.1007/s10592-021-01380-z
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DOI: https://doi.org/10.1007/s10592-021-01380-z