TY  - GEN
A1  - Paijmans, Johanna L. A.
A1  - Barlow, Axel
A1  - Förster, Daniel W.
A1  - Henneberger, Kirstin
A1  - Meyer, Matthias
A1  - Nickel, Birgit
A1  - Nagel, Doris
A1  - Worsøe Havmøller, Rasmus
A1  - Baryshnikov, Gennady F.
A1  - Joger, Ulrich
A1  - Rosendahl, Wilfried
A1  - Hofreiter, Michael
T1  - Historical biogeography of the leopard (Panthera pardus) and its extinct Eurasian populations
T2  - Postprints der Universität Potsdam Mathematisch-Naturwissenschaftliche Reihe
N2  - Background

Resolving the historical biogeography of the leopard (Panthera pardus) is a complex issue, because patterns inferred from fossils and from molecular data lack congruence. Fossil evidence supports an African origin, and suggests that leopards were already present in Eurasia during the Early Pleistocene. Analysis of DNA sequences however, suggests a more recent, Middle Pleistocene shared ancestry of Asian and African leopards. These contrasting patterns led researchers to propose a two-stage hypothesis of leopard dispersal out of Africa: an initial Early Pleistocene colonisation of Asia and a subsequent replacement by a second colonisation wave during the Middle Pleistocene. The status of Late Pleistocene European leopards within this scenario is unclear: were these populations remnants of the first dispersal, or do the last surviving European leopards share more recent ancestry with their African counterparts?

Results

In this study, we generate and analyse mitogenome sequences from historical samples that span the entire modern leopard distribution, as well as from Late Pleistocene remains. We find a deep bifurcation between African and Eurasian mitochondrial lineages (~ 710 Ka), with the European ancient samples as sister to all Asian lineages (~ 483 Ka). The modern and historical mainland Asian lineages share a relatively recent common ancestor (~ 122 Ka), and we find one Javan sample nested within these.

Conclusions

The phylogenetic placement of the ancient European leopard as sister group to Asian leopards suggests that these populations originate from the same out-of-Africa dispersal which founded the Asian lineages. The coalescence time found for the mitochondrial lineages aligns well with the earliest undisputed fossils in Eurasia, and thus encourages a re-evaluation of the identification of the much older putative leopard fossils from the region. The relatively recent ancestry of all mainland Asian leopard lineages suggests that these populations underwent a severe population bottleneck during the Pleistocene. Finally, although only based on a single sample, the unexpected phylogenetic placement of the Javan leopard could be interpreted as evidence for exchange of mitochondrial lineages between Java and mainland Asia, calling for further investigation into the evolutionary history of this subspecies.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 505 
KW  - Ancient DNA
KW  - Hybridisation capture
KW  - Leopards
KW  - Mitochondrial genomes
KW  - Mitogenomes
KW  - mtDNA
KW  - Palaeogenetics
KW  - Panthera pardus
Y1  - 2019
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-422555
SN  - 1866-8372
IS  - 505
ER  - 
TY  - JOUR
A1  - Paijmans, Johanna L. A.
A1  - Barlow, Axel
A1  - Förster, Daniel W.
A1  - Henneberger, Kirstin
A1  - Meyer, Matthias
A1  - Nickel, Birgit
A1  - Nagel, Doris
A1  - Worsøe Havmøller, Rasmus
A1  - Baryshnikov, Gennady F.
A1  - Joger, Ulrich
A1  - Rosendahl, Wilfried
A1  - Hofreiter, Michael
T1  - Historical biogeography of the leopard (Panthera pardus) and its extinct Eurasian populations
JF  - BMC Evolutionary Biology
N2  - Background

Resolving the historical biogeography of the leopard (Panthera pardus) is a complex issue, because patterns inferred from fossils and from molecular data lack congruence. Fossil evidence supports an African origin, and suggests that leopards were already present in Eurasia during the Early Pleistocene. Analysis of DNA sequences however, suggests a more recent, Middle Pleistocene shared ancestry of Asian and African leopards. These contrasting patterns led researchers to propose a two-stage hypothesis of leopard dispersal out of Africa: an initial Early Pleistocene colonisation of Asia and a subsequent replacement by a second colonisation wave during the Middle Pleistocene. The status of Late Pleistocene European leopards within this scenario is unclear: were these populations remnants of the first dispersal, or do the last surviving European leopards share more recent ancestry with their African counterparts?

Results

In this study, we generate and analyse mitogenome sequences from historical samples that span the entire modern leopard distribution, as well as from Late Pleistocene remains. We find a deep bifurcation between African and Eurasian mitochondrial lineages (~ 710 Ka), with the European ancient samples as sister to all Asian lineages (~ 483 Ka). The modern and historical mainland Asian lineages share a relatively recent common ancestor (~ 122 Ka), and we find one Javan sample nested within these.

Conclusions

The phylogenetic placement of the ancient European leopard as sister group to Asian leopards suggests that these populations originate from the same out-of-Africa dispersal which founded the Asian lineages. The coalescence time found for the mitochondrial lineages aligns well with the earliest undisputed fossils in Eurasia, and thus encourages a re-evaluation of the identification of the much older putative leopard fossils from the region. The relatively recent ancestry of all mainland Asian leopard lineages suggests that these populations underwent a severe population bottleneck during the Pleistocene. Finally, although only based on a single sample, the unexpected phylogenetic placement of the Javan leopard could be interpreted as evidence for exchange of mitochondrial lineages between Java and mainland Asia, calling for further investigation into the evolutionary history of this subspecies.
KW  - Ancient DNA
KW  - Hybridisation capture
KW  - Leopards
KW  - Mitochondrial genomes
KW  - Mitogenomes
KW  - mtDNA
KW  - Palaeogenetics
KW  - Panthera pardus
Y1  - 2018
U6  - https://doi.org/10.1186/s12862-018-1268-0
SN  - 1471-2148
VL  - 18
IS  - 156
PB  - BioMed Central und Springer
CY  - London, Berlin und Heidelberg
ER  - 
TY  - JOUR
A1  - Alberti, Federica
A1  - Gonzalez, Javier
A1  - Paijmans, Johanna L. A.
A1  - Basler, Nikolas
A1  - Preick, Michaela
A1  - Henneberger, Kirstin
A1  - Trinks, Alexandra
A1  - Rabeder, Gernot
A1  - Conard, Nicholas J.
A1  - Muenzel, Susanne C.
A1  - Joger, Ulrich
A1  - Fritsch, Guido
A1  - Hildebrandt, Thomas
A1  - Hofreiter, Michael
A1  - Barlow, Axel
T1  - Optimized DNA sampling of ancient bones using Computed Tomography scans
JF  - Molecular ecology resources
N2  - The prevalence of contaminant microbial DNA in ancient bone samples represents the principal limiting factor for palaeogenomic studies, as it may comprise more than 99% of DNA molecules obtained. Efforts to exclude or reduce this contaminant fraction have been numerous but also variable in their success. Here, we present a simple but highly effective method to increase the relative proportion of endogenous molecules obtained from ancient bones. Using computed tomography (CT) scanning, we identify the densest region of a bone as optimal for sampling. This approach accurately identifies the densest internal regions of petrous bones, which are known to be a source of high-purity ancient DNA. For ancient long bones, CT scans reveal a high-density outermost layer, which has been routinely removed and discarded prior to DNA extraction. For almost all long bones investigated, we find that targeted sampling of this outermost layer provides an increase in endogenous DNA content over that obtained from softer, trabecular bone. This targeted sampling can produce as much as 50-fold increase in the proportion of endogenous DNA, providing a directly proportional reduction in sequencing costs for shotgun sequencing experiments. The observed increases in endogenous DNA proportion are not associated with any reduction in absolute endogenous molecule recovery. Although sampling the outermost layer can result in higher levels of human contamination, some bones were found to have more contamination associated with the internal bone structures. Our method is highly consistent, reproducible and applicable across a wide range of bone types, ages and species. We predict that this discovery will greatly extend the potential to study ancient populations and species in the genomics era.
KW  - ancient DNA
KW  - computer tomography
KW  - palaeogenomics
KW  - paleogenetics
KW  - petrous bone
Y1  - 2018
U6  - https://doi.org/10.1111/1755-0998.12911
SN  - 1755-098X
SN  - 1755-0998
VL  - 18
IS  - 6
SP  - 1196
EP  - 1208
PB  - Wiley
CY  - Hoboken
ER  -