Background Previous phylogeographic studies of the lion (Panthera leo) have improved our insight into the distribution of genetic variation, as well as a revised taxonomy which now recognizes a... Show moreBackground Previous phylogeographic studies of the lion (Panthera leo) have improved our insight into the distribution of genetic variation, as well as a revised taxonomy which now recognizes a northern (Panthera leo leo) and a southern (Panthera leo melanochaita) subspecies. However, existing whole range phylogeographic studies on lions either consist of very limited numbers of samples, or are focused on mitochondrial DNA and/or a limited set of microsatellites. The geographic extent of genetic lineages and their phylogenetic relationships remain uncertain, clouded by massive sampling gaps, sex-biased dispersal and incomplete lineage sorting. Results In this study we present results of low depth whole genome sequencing and subsequent variant calling in ten lions sampled throughout the geographic range, resulting in the discovery of >150,000 Single Nucleotide Polymorphisms (SNPs). Phylogenetic analyses revealed the same basal split between northern and southern populations, as well as four population clusters on a more local scale. Further, we designed a SNP panel, including 125 autosomal and 14 mitochondrial SNPs, which was tested on >200 lions from across their range. Results allow us to assign individuals to one of these four major clades (West & Central Africa, India, East Africa, or Southern Africa) and delineate these clades in more detail. Conclusions The results presented here, particularly the validated SNP panel, have important applications, not only for studying populations on a local geographic scale, but also for tracing samples of unknown origin for forensic purposes, and for guiding conservation management of ex situ populations. Thus, these genomic resources not only contribute to our understanding of the evolutionary history of the lion, but may also play a crucial role in conservation efforts aimed at protecting the species in its full diversity. Show less
Bertola, L.D.; Vermaat, M.; Lesilau, F.; Chege, M.; Tumenta, P.N.; Sogbohossou, E.A.; ... ; Vrieling, K. 2022
Background Previous phylogeographic studies of the lion (Panthera leo) have improved our insight into the distribution of genetic variation, as well as a revised taxonomy which now recognizes a... Show moreBackground Previous phylogeographic studies of the lion (Panthera leo) have improved our insight into the distribution of genetic variation, as well as a revised taxonomy which now recognizes a northern (Panthera leo leo) and a southern (Panthera leo melanochaita) subspecies. However, existing whole range phylogeographic studies on lions either consist of very limited numbers of samples, or are focused on mitochondrial DNA and/or a limited set of microsatellites. The geographic extent of genetic lineages and their phylogenetic relationships remain uncertain, clouded by massive sampling gaps, sex-biased dispersal and incomplete lineage sorting. Results In this study we present results of low depth whole genome sequencing and subsequent variant calling in ten lions sampled throughout the geographic range, resulting in the discovery of >150,000 Single Nucleotide Polymorphisms (SNPs). Phylogenetic analyses revealed the same basal split between northern and southern populations, as well as four population clusters on a more local scale. Further, we designed a SNP panel, including 125 autosomal and 14 mitochondrial SNPs, which was tested on >200 lions from across their range. Results allow us to assign individuals to one of these four major clades (West & Central Africa, India, East Africa, or Southern Africa) and delineate these clades in more detail. Conclusions The results presented here, particularly the validated SNP panel, have important applications, not only for studying populations on a local geographic scale, but also for tracing samples of unknown origin for forensic purposes, and for guiding conservation management of ex situ populations. Thus, these genomic resources not only contribute to our understanding of the evolutionary history of the lion, but may also play a crucial role in conservation efforts aimed at protecting the species in its full diversity. Show less
Trimbos, K.B.; Cieraad, E.; Schrama, M.J.J.; Saarloos, A.I.; Musters, C.J. M.; Bertola, L.D.; Bodegom, P.M. van 2020
The application of eDNA techniques for the detection, monitoring, and conservation of biodiversity holds great promise. While many studies apply eDNA techniques in aquatic systems to determine the... Show moreThe application of eDNA techniques for the detection, monitoring, and conservation of biodiversity holds great promise. While many studies apply eDNA techniques in aquatic systems to determine the presence or absence of a given species, using eDNA for the purpose of species density or biomass predictions remains a challenge, especially for freshwater invertebrates that shed exoskeletons. Here, we aimed to determine whether and how eDNA concentrations relate to exoskeleton‐shedding invertebrate densities. We used microcosms holding different densities of a common invertebrate freshwater species, Daphnia magna. During 2 weeks, we monitored temporal dynamics of eDNA and the eDNA/density relationship by taking water samples and quantifying eDNA concentrations with the droplet digital PCR. The setup included one treatment without and one with homogenization before sampling, to test the effects of admixture on the relation between eDNA concentration and density. Daphnia magna individuals were removed after 1.5 weeks to track DNA degradation rates. In the stagnant water setup, hardly any DNA was detected before D. magna removal. Within days after removal, eDNA concentrations became undetectable. No significant correlation between D. magna density and eDNA concentrations was observed. In the homogenization treatment, a significant positive correlation between eDNA concentration and densities was demonstrated for the days around D. magna removal, albeit with some within‐treatment variability. Our results show that, given adequate time for eDNA production and degradation to stabilize, positive correlations between eDNA and organism densities in water with sufficient homogenization are detectable for exoskeleton‐shedding invertebrates. Therefore, our study indicates that—although difficult—using eDNA to quantify freshwater exoskeleton‐shedding invertebrate densities may be possible under field conditions if circumstances result in frequent homogenization of the water column. Show less
Bertola, L.D.; Jongbloed, H.; Gaag, K.J. van der; Kniff, P. de; Yamaguchi, N.; Hooghiermstra, H.; ... ; Iongh, H.H. de 2016
The evolutionary history of a species is key for understanding the taxonomy and for the design of effective management strategies for species conservation. The knowledge about the phylogenetic... Show moreThe evolutionary history of a species is key for understanding the taxonomy and for the design of effective management strategies for species conservation. The knowledge about the phylogenetic position of the lion ( Panthera leo ) in West/Central Africa is largely based on mitochondrial markers. Previous studies using mtDNA only have shown this region to hold a distinct evolutionary lineage. In addition, anthropogenic factors have led to a strong decline in West/Central African lion numbers, thus, the conservation value of these popula- tions is particularly high. Here, we investigate whether autosomal markers are concordant with previously described phylogeographic patterns, and confirm the unique position of the West/Central African lion. Analysis of 20 microsatellites and 1,454 bp of the mitochondrial DNA in 16 lion populations representing the entire geographic range of the species found congruence in both types of markers, identifying four clusters: 1) West/Central Africa, 2) East Africa, 3) Southern Africa and 4) India. This is not in line with the current taxonomy, as defined by the IUCN, which only recognizes an African and an Asiatic subspecies. There are no indications that genetic diversity in West/Central Africa lions is lower than in either East or Southern Africa, however, given this genetic distinction and the recent declines of lion numbers in this region, we strongly recommend prioritization of conservation projects in West/Central Africa. As the current taxonomic nomenclature does not reflect the evolution- ary history of the lion, we suggest that a taxonomic revision of the lion is warranted Show less
Insights into the spatial distribution of genetic diversity is key for understanding the evolutionary history and for effective species conservation. For the lion, all African populations are... Show moreInsights into the spatial distribution of genetic diversity is key for understanding the evolutionary history and for effective species conservation. For the lion, all African populations are considered to belong to one subspecies, while the Asiatic subspecies is confined to a single population in India. However, it is suggested that the genetic diversity is greater than the taxonomy implies. Notably the West and Central African lion represents a unique clade, which is relevant because the populations in this region are generally small and isolated. Phylogenetic analyses of mtDNA data, microsatellites and autosomal SNPs from lion populations throughout their complete geographic range show congruent patterns in which the Asiatic subspecies has a nested position within the West/Central African lion. Recognizing a northern subspecies, including the Asiatic lion, and a southern subspecies, is more in line with the evolutionary history of the lion. A revision of the taxonomy is therefore warranted. Show less
