references.bib

@article{Peyregne2020,
  author  = {Peyrégné, Someone},
  title   = {Title of the Article},
  journal = {Journal Name},
  year    = {2020},
  volume  = {10},
  pages   = {100-110},
  doi     = {10.1000/j.journal.2020.01.001}
}

@article{lindahl1974,
	title = {Heat-induced deamination of cytosine residues in deoxyribonucleic acid},
	author = {Lindahl, Tomas and Nyberg, Barbro},
	year = {1974},
	month = {07},
	date = {1974-07-01},
	journal = {Biochemistry},
	pages = {3405--3410},
	volume = {13},
	number = {16},
	doi = {10.1021/bi00713a035},
	url = {http://dx.doi.org/10.1021/bi00713a035},
	langid = {en}
}

@article{kistler2017,
	title = {A new model for ancient DNA decay based on paleogenomic meta-analysis},
	author = {Kistler, Logan and Ware, Roselyn and Smith, Oliver and Collins, Matthew and Allaby, Robin G.},
	year = {2017},
	month = {05},
	date = {2017-05-09},
	journal = {Nucleic Acids Research},
	pages = {6310--6320},
	volume = {45},
	number = {11},
	doi = {10.1093/nar/gkx361},
	url = {http://dx.doi.org/10.1093/nar/gkx361},
	langid = {en}
}

@article{sawyer2012,
	title = {Temporal Patterns of Nucleotide Misincorporations and DNA Fragmentation in Ancient DNA},
	author = {Sawyer, Susanna and Krause, Johannes and Guschanski, Katerina and Savolainen, Vincent and {Pääbo}, Svante},
	editor = {Lalueza-Fox, Carles},
	year = {2012},
	month = {03},
	date = {2012-03-30},
	journal = {PLoS ONE},
	pages = {e34131},
	volume = {7},
	number = {3},
	doi = {10.1371/journal.pone.0034131},
	url = {http://dx.doi.org/10.1371/journal.pone.0034131},
	langid = {en}
}

@article{meyer2016,
	title = {Nuclear DNA sequences from the Middle Pleistocene Sima de los Huesos hominins},
	author = {Meyer, Matthias and Arsuaga, Juan-Luis and de Filippo, Cesare and Nagel, Sarah and Aximu-Petri, Ayinuer and Nickel, Birgit and {Martínez}, Ignacio and Gracia, Ana and de Castro, {José María Bermúdez} and Carbonell, Eudald and Viola, Bence and Kelso, Janet and {Prüfer}, Kay and {Pääbo}, Svante},
	year = {2016},
	month = {03},
	date = {2016-03-14},
	journal = {Nature},
	pages = {504--507},
	volume = {531},
	number = {7595},
	doi = {10.1038/nature17405},
	url = {http://dx.doi.org/10.1038/nature17405},
	langid = {en}
}

@ARTICLE{Hudson1992,
  title    = "Estimation of levels of gene flow from {DNA} sequence data",
  author   = "Hudson, R R and Slatkin, M and Maddison, W P",
  abstract = "We compare the utility of two methods for estimating the average
              levels of gene flow from DNA sequence data. One method is based
              on estimating FST from frequencies at polymorphic sites, treating
              each site as a separate locus. The other method is based on
              computing the minimum number of migration events consistent with
              the gene tree inferred from their sequences. We compared the
              performance of these two methods on data that were generated by a
              computer simulation program that assumed the infinite sites model
              of mutation and that assumed an island model of migration. We
              found that in general when there is no recombination, the
              cladistic method performed better than FST while the reverse was
              true for rates of recombination similar to those found in
              eukaryotic nuclear genes, although FST performed better for all
              recombination rates for very low levels of migration (Nm = 0.1).",
  journal  = "Genetics",
  volume   =  132,
  number   =  2,
  pages    = "583--589",
  month    =  oct,
  year     =  1992,
  url      = "http://dx.doi.org/10.1093/genetics/132.2.583",
  file     = "All Papers/H/Hudson et al. 1992 - Estimation of levels of gene flow from DNA sequence data.pdf",
  language = "en",
  issn     = "0016-6731",
  pmid     = "1427045",
  doi      = "10.1093/genetics/132.2.583",
  pmc      = "PMC1205159"
}

@ARTICLE{Weir2002,
  title    = "Estimating F-statistics",
  author   = "Weir, B S and Hill, W G",
  abstract = "A moment estimator of, the coancestry coefficient for alleles
              within a population, was described by Weir \& Cockerham in 1984
              (100) and is still widely cited. The estimate is used by
              population geneticists to characterize population structure, by
              ecologists to estimate migration rates, by animal breeders to
              describe genetic variation, and by forensic scientists to
              quantify the strength of matching DNA profiles. This review
              extends the work of Weir \& Cockerham by allowing different
              levels of coancestry for different populations, and by allowing
              non-zero coancestries between pairs of populations. All estimates
              are relative to the average value of theta between pairs of
              populations. Moment estimates for within- and between-population
              theta values are likely to have large sampling variances,
              although these may be reduced by combining information over loci.
              Variances also decrease with the numbers of alleles at a locus,
              and with the numbers of populations sampled. This review also
              extends the work of Weir \& Cockerham by employing maximum
              likelihood methods under the assumption that allele frequencies
              follow the normal distribution over populations. For the case of
              equal theta values within populations and zero theta values
              between populations, the maximum likelihood estimate is the same
              as that given by Robertson \& Hill in 1984 (70). The review
              concludes by relating functions of theta values to times of
              population divergence under a pure drift model.",
  journal  = "Annual review of genetics",
  volume   =  36,
  pages    = "721--750",
  month    =  "11~" # jun,
  year     =  2002,
  url      = "http://dx.doi.org/10.1146/annurev.genet.36.050802.093940",
  file     = "All Papers/W/Weir and Hill 2002 - Estimating F-statistics.pdf",
  language = "en",
  issn     = "0066-4197",
  pmid     = "12359738",
  doi      = "10.1146/annurev.genet.36.050802.093940"
}


@ARTICLE{Bhatia2013,
  title   = "Estimating and interpreting {FST}: The impact of rare variants",
  author  = "Bhatia, G and Patterson, N and Sankararaman, S and Price, A L",
  journal = "Genome research",
  volume  =  23,
  number  =  9,
  pages   = "1514--1521",
  month   =  "1~" # sep,
  year    =  2013,
  url     = "http://genome.cshlp.org/cgi/doi/10.1101/gr.154831.113",
  file    = "All Papers/B/Bhatia et al. 2013 - Bhatia et al. 2013 - Supplemental_Material.pdf;All Papers/B/Bhatia et al. 2013 - Estimating and interpreting FST - The impact of rare variants.pdf;All Papers/B/Bhatia et al. 2013 - Supplemental_Material.docx",
  issn    = "1088-9051"
}

@article{Wilkinson2016,
  doi = {10.1038/sdata.2016.18},
  url = {https://doi.org/10.1038/sdata.2016.18},
  year = {2016},
  month = mar,
  publisher = {Springer Science and Business Media {LLC}},
  volume = {3},
  number = {1},
  author = {Mark D. Wilkinson and Michel Dumontier and IJsbrand Jan Aalbersberg and Gabrielle Appleton and Myles Axton and Arie Baak and Niklas Blomberg and Jan-Willem Boiten and Luiz Bonino da Silva Santos and Philip E. Bourne and Jildau Bouwman and Anthony J. Brookes and Tim Clark and Merc{\`{e}} Crosas and Ingrid Dillo and Olivier Dumon and Scott Edmunds and Chris T. Evelo and Richard Finkers and Alejandra Gonzalez-Beltran and Alasdair J.G. Gray and Paul Groth and Carole Goble and Jeffrey S. Grethe and Jaap Heringa and Peter A.C 't Hoen and Rob Hooft and Tobias Kuhn and Ruben Kok and Joost Kok and Scott J. Lusher and Maryann E. Martone and Albert Mons and Abel L. Packer and Bengt Persson and Philippe Rocca-Serra and Marco Roos and Rene van Schaik and Susanna-Assunta Sansone and Erik Schultes and Thierry Sengstag and Ted Slater and George Strawn and Morris A. Swertz and Mark Thompson and Johan van der Lei and Erik van Mulligen and Jan Velterop and Andra Waagmeester and Peter Wittenburg and Katherine Wolstencroft and Jun Zhao and Barend Mons},
  title = {The {FAIR} Guiding Principles for scientific data management and stewardship},
  journal = {Scientific Data}
}

@article{Wickham2019,
  title = {Welcome to the {tidyverse}},
  author = {Hadley Wickham and Mara Averick and Jennifer Bryan and
    Winston Chang and Lucy D'Agostino McGowan and Romain François and
    Garrett Grolemund and Alex Hayes and Lionel Henry and Jim Hester
    and Max Kuhn and Thomas Lin Pedersen and Evan Miller and Stephan
    Milton Bache and Kirill Müller and Jeroen Ooms and David Robinson
    and Dana Paige Seidel and Vitalie Spinu and Kohske Takahashi and
    Davis Vaughan and Claus Wilke and Kara Woo and Hiroaki Yutani},
  year = {2019},
  journal = {Journal of Open Source Software},
  volume = {4},
  number = {43},
  pages = {1686},
  doi = {10.21105/joss.01686},
}

@article{FellowsYates2021,
  doi = {10.7717/peerj.10947},
  url = {https://doi.org/10.7717/peerj.10947},
  year = {2021},
  month = mar,
  publisher = {{PeerJ}},
  volume = {9},
  pages = {e10947},
  author = {James A. {Fellows Yates} and Thiseas C. Lamnidis and Maxime Borry and Aida Andrades Valtue{\~{n}}a and Zandra Fagern\"{a}s and Stephen Clayton and Maxime U. Garcia and Judith Neukamm and Alexander Peltzer},
  title = {Reproducible,  portable,  and efficient ancient genome reconstruction with nf-core/eager},
  journal = {{PeerJ}}
}

@article{Mallick2023,
  doi = {10.1101/2023.04.06.535797},
  url = {https://doi.org/10.1101/2023.04.06.535797},
  year = {2023},
  month = apr,
  publisher = {Cold Spring Harbor Laboratory},
  author = {Swapan Mallick and Adam Micco and Matthew Mah and Harald Ringbauer and Iosif Lazaridis and I{\~{n}}igo Olalde and Nick Patterson and David Reich},
  title = {The Allen Ancient {DNA} Resource ({AADR}): A curated compendium of ancient human genomes}
}

@ARTICLE{Patterson2012,
  title    = "Ancient admixture in human history",
  author   = "Patterson, Nick and Moorjani, Priya and Luo, Yontao and Mallick,
              Swapan and Rohland, Nadin and Zhan, Yiping and Genschoreck, Teri
              and Webster, Teresa and Reich, David",
  abstract = "Population mixture is an important process in biology. We present
              a suite of methods for learning about population mixtures,
              implemented in a software package called ADMIXTOOLS, that support
              formal tests for whether mixture occurred and make it possible to
              infer proportions and dates of mixture. We also describe the
              development of a new single nucleotide polymorphism (SNP) array
              consisting of 629,433 sites with clearly documented ascertainment
              that was specifically designed for population genetic analyses
              and that we genotyped in 934 individuals from 53 diverse
              populations. To illustrate the methods, we give a number of
              examples that provide new insights about the history of human
              admixture. The most striking finding is a clear signal of
              admixture into northern Europe, with one ancestral population
              related to present-day Basques and Sardinians and the other
              related to present-day populations of northeast Asia and the
              Americas. This likely reflects a history of admixture between
              Neolithic migrants and the indigenous Mesolithic population of
              Europe, consistent with recent analyses of ancient bones from
              Sweden and the sequencing of the genome of the Tyrolean
              ``Iceman.''",
  journal  = "Genetics",
  volume   =  192,
  number   =  3,
  pages    = "1065--1093",
  month    =  nov,
  year     =  2012,
  url      = "http://dx.doi.org/10.1534/genetics.112.145037",
  file     = "All Papers/P/Patterson et al. 2012 - Ancient admixture in human history.pdf",
  language = "en",
  issn     = "0016-6731, 1943-2631",
  pmid     = "22960212",
  doi      = "10.1534/genetics.112.145037",
  pmc      = "PMC3522152"
}

@ARTICLE{Peter2016,
  title     = "Admixture, Population Structure, and {F-Statistics}",
  author    = "Peter, Benjamin M",
  abstract  = "Many questions about human genetic history can be addressed by
               examining the patterns of shared genetic variation between sets
               of populations. A useful methodological framework for this
               purpose isF-statistics that measure shared genetic drift between
               sets of two, three, and four populations and can be used to test
               simple and complex hypotheses about admixture between
               populations. This article provides context from phylogenetic and
               population genetic theory. I review how F-statistics can be
               interpreted as branch lengths or paths and derive new
               interpretations, using coalescent theory. I further show that
               the admixture tests can be interpreted as testing general
               properties of phylogenies, allowing extension of some ideas
               applications to arbitrary phylogenetic trees. The new results
               are used to investigate the behavior of the statistics under
               different models of population structure and show how population
               substructure complicates inference. The results lead to
               simplified estimators in many cases, and I recommend to replace
               F3 with the average number of pairwise differences for
               estimating population divergence.",
  journal   = "Genetics",
  publisher = "Genetics",
  volume    =  202,
  number    =  4,
  pages     = "1485--1501",
  month     =  apr,
  year      =  2016,
  url       = "http://dx.doi.org/10.1534/genetics.115.183913",
  file      = "All Papers/P/Peter 2016 - Admixture, Population Structure, and F-Statistics.pdf",
  keywords  = "admixture; gene flow; phylogenetic network; phylogenetics;
               population genetics",
  language  = "en",
  issn      = "0016-6731, 1943-2631",
  pmid      = "26857625",
  doi       = "10.1534/genetics.115.183913",
  pmc       = "PMC4905545"
}


@ARTICLE{Raghavan2014,
  title    = "Upper Palaeolithic Siberian genome reveals dual ancestry of
              Native Americans",
  author   = "Raghavan, Maanasa and Skoglund, Pontus and Graf, Kelly E and
              Metspalu, Mait and Albrechtsen, Anders and Moltke, Ida and
              Rasmussen, Simon and Stafford, Jr, Thomas W and Orlando, Ludovic
              and Metspalu, Ene and Karmin, Monika and Tambets, Kristiina and
              Rootsi, Siiri and Mägi, Reedik and Campos, Paula F and
              Balanovska, Elena and Balanovsky, Oleg and Khusnutdinova, Elza
              and Litvinov, Sergey and Osipova, Ludmila P and Fedorova, Sardana
              A and Voevoda, Mikhail I and DeGiorgio, Michael and
              Sicheritz-Ponten, Thomas and Brunak, Søren and Demeshchenko,
              Svetlana and Kivisild, Toomas and Villems, Richard and Nielsen,
              Rasmus and Jakobsson, Mattias and Willerslev, Eske",
  abstract = "The origins of the First Americans remain contentious. Although
              Native Americans seem to be genetically most closely related to
              east Asians, there is no consensus with regard to which specific
              Old World populations they are closest to. Here we sequence the
              draft genome of an approximately 24,000-year-old individual
              (MA-1), from Mal'ta in south-central Siberia, to an average depth
              of 1×. To our knowledge this is the oldest anatomically modern
              human genome reported to date. The MA-1 mitochondrial genome
              belongs to haplogroup U, which has also been found at high
              frequency among Upper Palaeolithic and Mesolithic European
              hunter-gatherers, and the Y chromosome of MA-1 is basal to
              modern-day western Eurasians and near the root of most Native
              American lineages. Similarly, we find autosomal evidence that
              MA-1 is basal to modern-day western Eurasians and genetically
              closely related to modern-day Native Americans, with no close
              affinity to east Asians. This suggests that populations related
              to contemporary western Eurasians had a more north-easterly
              distribution 24,000 years ago than commonly thought. Furthermore,
              we estimate that 14 to 38\% of Native American ancestry may
              originate through gene flow from this ancient population. This is
              likely to have occurred after the divergence of Native American
              ancestors from east Asian ancestors, but before the
              diversification of Native American populations in the New World.
              Gene flow from the MA-1 lineage into Native American ancestors
              could explain why several crania from the First Americans have
              been reported as bearing morphological characteristics that do
              not resemble those of east Asians. Sequencing of another
              south-central Siberian, Afontova Gora-2 dating to approximately
              17,000 years ago, revealed similar autosomal genetic signatures
              as MA-1, suggesting that the region was continuously occupied by
              humans throughout the Last Glacial Maximum. Our findings reveal
              that western Eurasian genetic signatures in modern-day Native
              Americans derive not only from post-Columbian admixture, as
              commonly thought, but also from a mixed ancestry of the First
              Americans.",
  journal  = "Nature",
  volume   =  505,
  number   =  7481,
  pages    = "87--91",
  month    =  "2~" # jan,
  year     =  2014,
  url      = "http://dx.doi.org/10.1038/nature12736",
  file     = "All Papers/R/Raghavan et al. 2014 - Raghavan_2014.pdf;All Papers/R/Raghavan et al. 2014 - Upper Palaeolithic Siberian genome reveals dual ancestry of Native Americans.pdf",
  language = "en",
  issn     = "0028-0836, 1476-4687",
  pmid     = "24256729",
  doi      = "10.1038/nature12736",
  pmc      = "PMC4105016"
}

@ARTICLE{Lamnidis2018,
  title    = "Ancient Fennoscandian genomes reveal origin and spread of
              Siberian ancestry in Europe",
  author   = "Lamnidis, Thiseas C and Majander, Kerttu and Jeong, Choongwon and
              Salmela, Elina and Wessman, Anna and Moiseyev, Vyacheslav and
              Khartanovich, Valery and Balanovsky, Oleg and Ongyerth, Matthias
              and Weihmann, Antje and Sajantila, Antti and Kelso, Janet and
              Pääbo, Svante and Onkamo, Päivi and Haak, Wolfgang and Krause,
              Johannes and Schiffels, Stephan",
  abstract = "European population history has been shaped by migrations of
              people, and their subsequent admixture. Recently, ancient DNA has
              brought new insights into European migration events linked to the
              advent of agriculture, and possibly to the spread of
              Indo-European languages. However, little is known about the
              ancient population history of north-eastern Europe, in particular
              about populations speaking Uralic languages, such as Finns and
              Saami. Here we analyse ancient genomic data from 11 individuals
              from Finland and north-western Russia. We show that the genetic
              makeup of northern Europe was shaped by migrations from Siberia
              that began at least 3500 years ago. This Siberian ancestry was
              subsequently admixed into many modern populations in the region,
              particularly into populations speaking Uralic languages today.
              Additionally, we show that ancestors of modern Saami inhabited a
              larger territory during the Iron Age, which adds to the
              historical and linguistic information about the population
              history of Finland.",
  journal  = "Nature Communications",
  volume   =  9,
  number   =  1,
  pages    = "5018",
  month    =  "27~" # nov,
  year     =  2018,
  url      = "https://doi.org/10.1038/s41467-018-07483-5",
  annote   = "\{pdf:
              ``https://www.nature.com/articles/s41467-018-07483-5.pdf''\}",
  file     = "All Papers/L/Lamnidis et al. 2018 - Ancient Fennoscandian genomes reveal origin and spread of Siberian ancestry in Europe.pdf;All Papers/L/Lamnidis et al. 2018 - Lamnidis et al. 2018 - SI.pdf",
  keywords = "role\_lead",
  issn     = "2041-1723",
  doi      = "10.1038/s41467-018-07483-5"
}


@ARTICLE{Martin2015,
  title     = "Evaluating the use of {ABBA-BABA} statistics to locate
               introgressed loci",
  author    = "Martin, Simon H and Davey, John W and Jiggins, Chris D",
  abstract  = "Several methods have been proposed to test for introgression
               across genomes. One method tests for a genome-wide excess of
               shared derived alleles between taxa using Patterson's D
               statistic, but does not establish which loci show such an excess
               or whether the excess is due to introgression or ancestral
               population structure. Several recent studies have extended the
               use of D by applying the statistic to small genomic regions,
               rather than genome-wide. Here, we use simulations and
               whole-genome data from Heliconius butterflies to investigate the
               behavior of D in small genomic regions. We find that D is
               unreliable in this situation as it gives inflated values when
               effective population size is low, causing D outliers to cluster
               in genomic regions of reduced diversity. As an alternative, we
               propose a related statistic ƒ(d), a modified version of a
               statistic originally developed to estimate the genome-wide
               fraction of admixture. ƒ(d) is not subject to the same biases as
               D, and is better at identifying introgressed loci. Finally, we
               show that both D and ƒ(d) outliers tend to cluster in regions of
               low absolute divergence (d(XY)), which can confound a recently
               proposed test for differentiating introgression from shared
               ancestral variation at individual loci.",
  journal   = "Molecular biology and evolution",
  publisher = "Oxford University Press",
  volume    =  32,
  number    =  1,
  pages     = "244--257",
  month     =  jan,
  year      =  2015,
  url       = "http://dx.doi.org/10.1093/molbev/msu269",
  file      = "All Papers/M/Martin et al. 2015 - Evaluating the use of ABBA-BABA statistics to locate introgressed loci.pdf",
  keywords  = "ABBA–BABA; Heliconius; gene flow; introgression; population
               structure; simulation",
  language  = "en",
  issn      = "0737-4038, 1537-1719",
  pmid      = "25246699",
  doi       = "10.1093/molbev/msu269",
  pmc       = "PMC4271521"
}


@ARTICLE{Green2010,
  title     = "A draft sequence of the Neandertal genome",
  author    = "Green, Richard E and Krause, Johannes and Briggs, Adrian W and
               Maricic, Tomislav and Stenzel, Udo and Kircher, Martin and
               Patterson, Nick and Li, Heng and Zhai, Weiwei and Fritz, Markus
               Hsi-Yang and Hansen, Nancy F and Durand, Eric Y and Malaspinas,
               Anna-Sapfo and Jensen, Jeffrey D and Marques-Bonet, Tomas and
               Alkan, Can and Prüfer, Kay and Meyer, Matthias and Burbano,
               Hernán A and Good, Jeffrey M and Schultz, Rigo and Aximu-Petri,
               Ayinuer and Butthof, Anne and Höber, Barbara and Höffner,
               Barbara and Siegemund, Madlen and Weihmann, Antje and Nusbaum,
               Chad and Lander, Eric S and Russ, Carsten and Novod, Nathaniel
               and Affourtit, Jason and Egholm, Michael and Verna, Christine
               and Rudan, Pavao and Brajkovic, Dejana and Kucan, Zeljko and
               Gusic, Ivan and Doronichev, Vladimir B and Golovanova, Liubov V
               and Lalueza-Fox, Carles and de la Rasilla, Marco and Fortea,
               Javier and Rosas, Antonio and Schmitz, Ralf W and Johnson,
               Philip L F and Eichler, Evan E and Falush, Daniel and Birney,
               Ewan and Mullikin, James C and Slatkin, Montgomery and Nielsen,
               Rasmus and Kelso, Janet and Lachmann, Michael and Reich, David E
               and Pääbo, Svante",
  abstract  = "Neandertals, the closest evolutionary relatives of present-day
               humans, lived in large parts of Europe and western Asia before
               disappearing 30,000 years ago. We present a draft sequence of
               the Neandertal genome composed of more than 4 billion
               nucleotides from three individuals. Comparisons of the
               Neandertal genome to the genomes of five present-day humans from
               different parts of the world identify a number of genomic
               regions that may have been affected by positive selection in
               ancestral modern humans, including genes involved in metabolism
               and in cognitive and skeletal development. We show that
               Neandertals shared more genetic variants with present-day humans
               in Eurasia than with present-day humans in sub-Saharan Africa,
               suggesting that gene flow from Neandertals into the ancestors of
               non-Africans occurred before the divergence of Eurasian groups
               from each other.",
  journal   = "Science",
  publisher = "American Association for the Advancement of Science",
  volume    =  328,
  number    =  5979,
  pages     = "710--722",
  month     =  "7~" # may,
  year      =  2010,
  url       = "http://eutils.ncbi.nlm.nih.gov/entrez/eutils/elink.fcgi?dbfrom=pubmed&id=20448178&retmode=ref&cmd=prlinks",
  file      = "All Papers/G/Green et al. 2010 - A draft sequence of the Neandertal genome.pdf;All Papers/G/Green et al. 2010 - Green_2010_Science.pdf",
  issn      = "0036-8075"
}


@ARTICLE{Lazaridis2014,
  title    = "Ancient human genomes suggest three ancestral populations for
              present-day Europeans",
  author   = "Lazaridis, Iosif and Patterson, Nick and Mittnik, Alissa and
              Renaud, Gabriel and Mallick, Swapan and Kirsanow, Karola and
              Sudmant, Peter H and Schraiber, Joshua G and Castellano, Sergi
              and Lipson, Mark and Berger, Bonnie and Economou, Christos and
              Bollongino, Ruth and Fu, Qiaomei and Bos, Kirsten I and
              Nordenfelt, Susanne and Li, Heng and de Filippo, Cesare and
              Prüfer, Kay and Sawyer, Susanna and Posth, Cosimo and Haak,
              Wolfgang and Hallgren, Fredrik and Fornander, Elin and Rohland,
              Nadin and Delsate, Dominique and Francken, Michael and Guinet,
              Jean-Michel and Wahl, Joachim and Ayodo, George and Babiker,
              Hamza A and Bailliet, Graciela and Balanovska, Elena and
              Balanovsky, Oleg and Barrantes, Ramiro and Bedoya, Gabriel and
              Ben-Ami, Haim and Bene, Judit and Berrada, Fouad and Bravi,
              Claudio M and Brisighelli, Francesca and Busby, George B J and
              Cali, Francesco and Churnosov, Mikhail and Cole, David E C and
              Corach, Daniel and Damba, Larissa and van Driem, George and
              Dryomov, Stanislav and Dugoujon, Jean-Michel and Fedorova,
              Sardana A and Gallego Romero, Irene and Gubina, Marina and
              Hammer, Michael and Henn, Brenna M and Hervig, Tor and
              Hodoglugil, Ugur and Jha, Aashish R and Karachanak-Yankova, Sena
              and Khusainova, Rita and Khusnutdinova, Elza and Kittles, Rick
              and Kivisild, Toomas and Klitz, William and Kučinskas, Vaidutis
              and Kushniarevich, Alena and Laredj, Leila and Litvinov, Sergey
              and Loukidis, Theologos and Mahley, Robert W and Melegh, Béla and
              Metspalu, Ene and Molina, Julio and Mountain, Joanna and
              Näkkäläjärvi, Klemetti and Nesheva, Desislava and Nyambo, Thomas
              and Osipova, Ludmila and Parik, Jüri and Platonov, Fedor and
              Posukh, Olga and Romano, Valentino and Rothhammer, Francisco and
              Rudan, Igor and Ruizbakiev, Ruslan and Sahakyan, Hovhannes and
              Sajantila, Antti and Salas, Antonio and Starikovskaya, Elena B
              and Tarekegn, Ayele and Toncheva, Draga and Turdikulova, Shahlo
              and Uktveryte, Ingrida and Utevska, Olga and Vasquez, René and
              Villena, Mercedes and Voevoda, Mikhail and Winkler, Cheryl A and
              Yepiskoposyan, Levon and Zalloua, Pierre and Zemunik, Tatijana
              and Cooper, Alan and Capelli, Cristian and Thomas, Mark G and
              Ruiz-Linares, Andres and Tishkoff, Sarah A and Singh, Lalji and
              Thangaraj, Kumarasamy and Villems, Richard and Comas, David and
              Sukernik, Rem and Metspalu, Mait and Meyer, Matthias and Eichler,
              Evan E and Burger, Joachim and Slatkin, Montgomery and Pääbo,
              Svante and Kelso, Janet and Reich, David and Krause, Johannes",
  abstract = "We sequenced the genomes of a ∼7,000-year-old farmer from Germany
              and eight ∼8,000-year-old hunter-gatherers from Luxembourg and
              Sweden. We analysed these and other ancient genomes with 2,345
              contemporary humans to show that most present-day Europeans
              derive from at least three highly differentiated populations:
              west European hunter-gatherers, who contributed ancestry to all
              Europeans but not to Near Easterners; ancient north Eurasians
              related to Upper Palaeolithic Siberians, who contributed to both
              Europeans and Near Easterners; and early European farmers, who
              were mainly of Near Eastern origin but also harboured west
              European hunter-gatherer related ancestry. We model these
              populations' deep relationships and show that early European
              farmers had ∼44\% ancestry from a 'basal Eurasian' population
              that split before the diversification of other non-African
              lineages.",
  journal  = "Nature",
  volume   =  513,
  number   =  7518,
  pages    = "409--413",
  month    =  "18~" # sep,
  year     =  2014,
  url      = "http://dx.doi.org/10.1038/nature13673",
  file     = "All Papers/L/Lazaridis et al. 2014 - Ancient human genomes suggest three ancestral populations for present-day Europeans.pdf;All Papers/L/Lazaridis et al. 2014 - Lazaridis_2014.pdf",
  language = "en",
  issn     = "0028-0836, 1476-4687",
  pmid     = "25230663",
  doi      = "10.1038/nature13673",
  pmc      = "PMC4170574"
}

@article{ewels2020,
  title = {The nf-core framework for community-curated bioinformatics pipelines},
  author = {Ewels, Philip A. and Peltzer, Alexander and Fillinger, Sven and Patel, Harshil and Alneberg, Johannes and Wilm, Andreas and Garcia, Maxime Ulysse and Di Tommaso, Paolo and Nahnsen, Sven},
  year = {2020},
  month = {02},
  date = {2020-02-13},
  journal = {Nature Biotechnology},
  pages = {276--278},
  volume = {38},
  number = {3},
  doi = {10.1038/s41587-020-0439-x},
  url = {http://dx.doi.org/10.1038/s41587-020-0439-x},
  langid = {en}
}

@article{Schmid2023,
  doi = {10.1073/pnas.2218375120},
  url = {https://doi.org/10.1073/pnas.2218375120},
  year = {2023},
  month = feb,
  publisher = {Proceedings of the National Academy of Sciences},
  volume = {120},
  number = {9},
  author = {Clemens Schmid and Stephan Schiffels},
  title = {Estimating human mobility in Holocene Western Eurasia with large-scale ancient genomic data},
  journal = {Proceedings of the National Academy of Sciences}
}

@techreport{Annoni2003,
  author      = {A. Annoni and others},
  title       = {Map Projections for Europe},
  institution = {European Commission Joint Research Centre},
  year        = {2003},
  type        = {Technical Report},
  number      = {EUR 20120 EN},
  url         = {http://mapref.org/LinkedDocuments/MapProjectionsForEurope-EUR-20120.pdf}
}

@inbook{Tsoulos2003,
  author      = {Lysandros Tsoulos},
  title       = {An Equal Area Projection for Statistical Mapping in the EU},
  booktitle   = {Map Projections for Europe},
  editor      = {A. Annoni and others},
  publisher   = {European Commission Joint Research Centre},
  year        = {2003},
  pages       = {50-55},
  url         = {http://mapref.org/LinkedDocuments/MapProjectionsForEurope-EUR-20120.pdf}
}

@book{Gramacy2020,
  title = {Surrogates: {G}aussian Process Modeling, Design and \
    Optimization for the Applied Sciences},
  author = {Robert B. Gramacy},
  publisher = {Chapman Hall/CRC},
  address = {Boca Raton, Florida},
  note = {\url{http://bobby.gramacy.com/surrogates/}},
  year = {2020}
}

@Article{Gramacy2016,
  title = {{laGP}: Large-Scale Spatial Modeling via Local Approximate
    Gaussian Processes in {R}},
  author = {Robert B. Gramacy},
  journal = {Journal of Statistical Software},
  year = {2016},
  volume = {72},
  number = {1},
  pages = {1--46},
  doi = {10.18637/jss.v072.i01},
}

@Article{Pebesma2018,
  author = {Edzer Pebesma},
  title = {{Simple Features for R: Standardized Support for Spatial Vector Data}},
  year = {2018},
  journal = {{The R Journal}},
  doi = {10.32614/RJ-2018-009},
  url = {https://doi.org/10.32614/RJ-2018-009},
  pages = {439--446},
  volume = {10},
  number = {1},
}

@Article{Wickham2019,
  title = {Welcome to the {tidyverse}},
  author = {Hadley Wickham and Mara Averick and Jennifer Bryan and
    Winston Chang and Lucy D'Agostino McGowan and Romain François and
    Garrett Grolemund and Alex Hayes and Lionel Henry and Jim Hester
    and Max Kuhn and Thomas Lin Pedersen and Evan Miller and Stephan
    Milton Bache and Kirill Müller and Jeroen Ooms and David Robinson
    and Dana Paige Seidel and Vitalie Spinu and Kohske Takahashi and
    Davis Vaughan and Claus Wilke and Kara Woo and Hiroaki Yutani},
  year = {2019},
  journal = {Journal of Open Source Software},
  volume = {4},
  number = {43},
  pages = {1686},
  doi = {10.21105/joss.01686},
}

@Manual{Massicotte2024,
  title = {rnaturalearth: World Map Data from Natural Earth},
  author = {Philippe Massicotte and Andy South},
  year = {2024},
  note = {R package version 1.0.1.9000, https://github.com/ropensci/rnaturalearth, https://docs.ropensci.org/rnaturalearthhires/},
  url = {https://docs.ropensci.org/rnaturalearth/},
}

@Manual{Wilke2024,
  title = {cowplot: Streamlined Plot Theme and Plot Annotations for 'ggplot2'},
  author = {Claus O. Wilke},
  year = {2024},
  note = {R package version 1.1.3},
  url = {https://wilkelab.org/cowplot/},
}

@Manual{Appelhans2023,
  title = {mapview: Interactive Viewing of Spatial Data in R},
  author = {Tim Appelhans and Florian Detsch and Christoph Reudenbach and Stefan Woellauer},
  year = {2023},
  note = {R package version 2.11.2},
  url = {https://github.com/r-spatial/mapview},
}

@article{Patterson2006,
  title={Population structure and eigenanalysis},
  author={Patterson, Nick and Price, Alkes L and Reich, David},
  journal={PLoS genetics},
  volume={2},
  number={12},
  pages={e190},
  year={2006},
  publisher={Public Library of Science San Francisco, USA}
}

@article{Reich2012,
  title={Reconstructing native American population history},
  author={Reich, David and Patterson, Nick and Campbell, Desmond and Tandon, Arti and Mazieres, St{\'e}phane and Ray, Nicolas and Parra, Maria V and Rojas, Winston and Duque, Constanza and Mesa, Natalia and others},
  journal={Nature},
  volume={488},
  number={7411},
  pages={370--374},
  year={2012},
  publisher={Nature Publishing Group UK London}
}

@UNPUBLISHED{Akturk2023-yr,
  title    = "Benchmarking kinship estimation tools for ancient genomes using
              pedigree simulations",
  author   = "Akt{\"u}rk, {\c S}evval and Mapelli, Igor and G{\"u}ler, Merve
              Nur and G{\"u}r{\"u}n, Kanat and Kat{\i}rc{\i}o{\u g}lu,
              B{\"u}{\c s}ra and Vural, K{\i}v{\i}lc{\i}m Ba{\c s}ak and Sa{\u
              g}l{\i}can, Ekin and {\c C}etin, Mehmet and Yaka, Reyhan and
              S{\"u}rer, Elif and Ata{\u g}, G{\"o}zde and {\c C}oko{\u g}lu,
              Sevim Seda and Sevkar, Arda and Ezgi Alt{\i}n{\i}{\c s}{\i}k, N
              and Koptekin, Dilek and Somel, Mehmet",
  abstract = "There is growing interest in uncovering genetic kinship patterns
              in past societies using low-coverage paleogenomes. Here, we
              benchmark four tools for kinship estimation with such data:
              lcMLkin, NgsRelate, KIN, and READ, which differ in their input,
              IBD-estimation methods and statistical approaches. We used
              pedigree and ancient genome sequence simulations to evaluate
              these tools when only a limited number (1K to 50K) of shared SNPs
              (with minor allele frequency $\geq$0.01) are available. The
              performance of all four tools was comparable using $\geq$20K
              SNPs. We found that first-degree related pairs can be accurately
              classified even with 1K SNPs, with 85\% F1 scores using READ and
              96\% using NgsRelate or lcMLkin. Distinguishing third-degree
              relatives from unrelated pairs or second-degree relatives was
              also possible with high accuracy (F1 >90\%) with 5K SNPs using
              NgsRelate and lcMLkin, while READ and KIN showed lower success
              (69\% and 79\%, respectively). Meanwhile, noise in population
              allele frequencies and inbreeding (first cousin mating) led to
              deviations in kinship coefficients, with different sensitivities
              across tools. We conclude that using multiple tools in parallel
              might be an effective approach to achieve robust estimates on
              ultra-low coverage genomes. \#\#\# Competing Interest Statement
              The authors have declared no competing interest.",
  journal  = "bioRxiv",
  pages    = "2023.11.08.566300",
  month    =  nov,
  year     =  2023,
  language = "en"
}

@UNPUBLISHED{Alacamli2024-xq,
  title    = "{READv2}: Advanced and user-friendly detection of biological
              relatedness in archaeogenomics",
  author   = "Ala{\c c}aml{\i}, Erkin and Naidoo, Thijessen and Akt{\"u}rk, {\c
              S}evval and G{\"u}ler, Merve N and Mapelli, Igor and Vural,
              K{\i}v{\i}lc{\i}m Ba{\c s}ak and Somel, Mehmet and Malmstr{\"o}m,
              Helena and G{\"u}nther, Torsten",
  abstract = "The possibility to obtain genome-wide ancient DNA data from
              multiple individuals has facilitated an unprecedented perspective
              into prehistoric societies. Studying biological relatedness in
              these groups requires tailored approaches for analyzing ancient
              DNA due to its low coverage, post-mortem damage, and potential
              ascertainment bias. Here we present READv2 (Relatedness
              Estimation from Ancient DNA version 2), an improved Python 3
              re-implementation of the most widely used tool for this purpose.
              While providing increased portability and making the software
              future-proof, we are also able to show that READv2 (a) is orders
              of magnitude faster than its predecessor; (b) has increased power
              to detect pairs of relatives using optimized default parameters;
              and, when the number of overlapping SNPs is sufficient, (c) can
              differentiate between full-siblings and parent-offspring, and (d)
              can classify pairs of third-degree relatedness. We further use
              READv2 to analyze a large empirical dataset that has previously
              needed two separate tools to reconstruct complex pedigrees. We
              show that READv2 yields results and precision similar to the
              combined approach but is faster and simpler to run. READv2 will
              become a valuable part of the archaeogenomic toolkit in providing
              an efficient and user-friendly classification of biological
              relatedness from pseudohaploid ancient DNA data. \#\#\# Competing
              Interest Statement The authors have declared no competing
              interest.",
  journal  = "bioRxiv",
  pages    = "2024.01.23.576660",
  month    =  jan,
  year     =  2024,
  language = "en"
}


@ARTICLE{Fernandes2021-ze,
  title    = "{TKGWV2}: an ancient {DNA} relatedness pipeline for ultra-low
              coverage whole genome shotgun data",
  author   = "Fernandes, Daniel M and Cheronet, Olivia and Gelabert, Pere and
              Pinhasi, Ron",
  abstract = "Estimation of genetically related individuals is playing an
              increasingly important role in the ancient DNA field. In recent
              years, the numbers of sequenced individuals from single sites
              have been increasing, reflecting a growing interest in
              understanding the familial and social organisation of ancient
              populations. Although a few different methods have been
              specifically developed for ancient DNA, namely to tackle issues
              such as low-coverage homozygous data, they require a
              0.1-1$\times$ minimum average genomic coverage per analysed pair
              of individuals. Here we present an updated version of a method
              that enables estimates of 1st and 2nd-degrees of relatedness with
              as little as 0.026$\times$ average coverage, or around 18,000
              SNPs from 1.3 million aligned reads per sample with average
              length of 62 bp-four times less data than 0.1$\times$ coverage at
              similar read lengths. By using simulated data to estimate false
              positive error rates, we further show that a threshold even as
              low as 0.012$\times$, or around 4000 SNPs from 600,000 reads,
              will always show 1st-degree relationships as related. Lastly, by
              applying this method to published data, we are able to identify
              previously undocumented relationships using individuals that had
              been excluded from prior kinship analysis due to their very low
              coverage. This methodological improvement has the potential to
              enable relatedness estimation on ancient whole genome shotgun
              data during routine low-coverage screening, and therefore improve
              project management when decisions need to be made on which
              individuals are to be further sequenced.",
  journal  = "Sci. Rep.",
  volume   =  11,
  number   =  1,
  pages    = "21262",
  month    =  oct,
  year     =  2021,
  language = "en"
}



@ARTICLE{Furtwangler2020-ce,
  title    = "Ancient genomes reveal social and genetic structure of Late
              Neolithic Switzerland",
  author   = "Furtw{\"a}ngler, Anja and Rohrlach, A B and Lamnidis, Thiseas C
              and Papac, Luka and Neumann, Gunnar U and Siebke, Inga and
              Reiter, Ella and Steuri, Noah and Hald, J{\"u}rgen and Denaire,
              Anthony and Schnitzler, Bernadette and Wahl, Joachim and
              Ramstein, Marianne and Schuenemann, Verena J and Stockhammer,
              Philipp W and Hafner, Albert and L{\"o}sch, Sandra and Haak,
              Wolfgang and Schiffels, Stephan and Krause, Johannes",
  abstract = "Genetic studies of Neolithic and Bronze Age skeletons from Europe
              have provided evidence for strong population genetic changes at
              the beginning and the end of the Neolithic period. To further
              understand the implications of these in Southern Central Europe,
              we analyze 96 ancient genomes from Switzerland, Southern Germany,
              and the Alsace region in France, covering the Middle/Late
              Neolithic to Early Bronze Age. Similar to previously described
              genetic changes in other parts of Europe from the early 3rd
              millennium BCE, we detect an arrival of ancestry related to Late
              Neolithic pastoralists from the Pontic-Caspian steppe in
              Switzerland as early as 2860-2460 calBCE. Our analyses suggest
              that this genetic turnover was a complex process lasting almost
              1000 years and involved highly genetically structured populations
              in this region.",
  journal  = "Nat. Commun.",
  volume   =  11,
  number   =  1,
  pages    = "1915",
  month    =  apr,
  year     =  2020,
  language = "en"
}


@ARTICLE{Harris2020-vr,
  title    = "Array programming with {NumPy}",
  author   = "Harris, Charles R and Millman, K Jarrod and van der Walt,
              St{\'e}fan J and Gommers, Ralf and Virtanen, Pauli and
              Cournapeau, David and Wieser, Eric and Taylor, Julian and Berg,
              Sebastian and Smith, Nathaniel J and Kern, Robert and Picus,
              Matti and Hoyer, Stephan and van Kerkwijk, Marten H and Brett,
              Matthew and Haldane, Allan and Del R{\'\i}o, Jaime Fern{\'a}ndez
              and Wiebe, Mark and Peterson, Pearu and G{\'e}rard-Marchant,
              Pierre and Sheppard, Kevin and Reddy, Tyler and Weckesser, Warren
              and Abbasi, Hameer and Gohlke, Christoph and Oliphant, Travis E",
  abstract = "Array programming provides a powerful, compact and expressive
              syntax for accessing, manipulating and operating on data in
              vectors, matrices and higher-dimensional arrays. NumPy is the
              primary array programming library for the Python language. It has
              an essential role in research analysis pipelines in fields as
              diverse as physics, chemistry, astronomy, geoscience, biology,
              psychology, materials science, engineering, finance and
              economics. For example, in astronomy, NumPy was an important part
              of the software stack used in the discovery of gravitational
              waves1 and in the first imaging of a black hole2. Here we review
              how a few fundamental array concepts lead to a simple and
              powerful programming paradigm for organizing, exploring and
              analysing scientific data. NumPy is the foundation upon which the
              scientific Python ecosystem is constructed. It is so pervasive
              that several projects, targeting audiences with specialized
              needs, have developed their own NumPy-like interfaces and array
              objects. Owing to its central position in the ecosystem, NumPy
              increasingly acts as an interoperability layer between such array
              computation libraries and, together with its application
              programming interface (API), provides a flexible framework to
              support the next decade of scientific and industrial analysis.",
  journal  = "Nature",
  volume   =  585,
  number   =  7825,
  pages    = "357--362",
  month    =  sep,
  year     =  2020,
  language = "en"
}



% The entry below contains non-ASCII chars that could not be converted
% to a LaTeX equivalent.
@ARTICLE{Kennett2017-qw,
  title    = "Archaeogenomic evidence reveals prehistoric matrilineal dynasty",
  author   = "Kennett, Douglas J and Plog, Stephen and George, Richard J and
              Culleton, Brendan J and Watson, Adam S and Skoglund, Pontus and
              Rohland, Nadin and Mallick, Swapan and Stewardson, Kristin and
              Kistler, Logan and LeBlanc, Steven A and Whiteley, Peter M and
              Reich, David and Perry, George H",
  abstract = "For societies with writing systems, hereditary leadership is
              documented as one of the hallmarks of early political complexity
              and governance. In contrast, it is unknown whether hereditary
              succession played a role in the early formation of prehistoric
              complex societies that lacked writing. Here we use an
              archaeogenomic approach to identify an elite matriline that
              persisted between 800 and 1130 CE in Chaco Canyon, the centre of
              an expansive prehistoric complex society in the Southwestern
              United States. We show that nine individuals buried in an elite
              crypt at Pueblo Bonito, the largest structure in the canyon, have
              identical mitochondrial genomes. Analyses of nuclear genome data
              from six samples with the highest DNA preservation demonstrate
              mother-daughter and grandmother-grandson relationships, evidence
              for a multigenerational matrilineal descent group. Together,
              these results demonstrate the persistence of an elite matriline
              in Chaco for ∼330 years.",
  journal  = "Nat. Commun.",
  volume   =  8,
  pages    = "14115",
  month    =  feb,
  year     =  2017,
  language = "en"
}


@ARTICLE{McKinney2010-zp,
  title    = "Data Structures for Statistical Computing in Python",
  author   = "McKinney, Wes",
  abstract = "In this paper we are concerned with the practical issues of
              working with data sets common to finance, statistics, and other
              related fields. pandas is a new library which aims to facilitate
              working with these data sets and to provide a set of fundamental
              building blocks for implementing statistical models. We will
              discuss specific design issues encountered in the course of
              developing pandas with relevant examples and some comparisons
              with the R language. We conclude by discussing possible future
              directions for statistical computing and data analysis using
              Python.",
  pages    = "56--61",
  year     =  2010
}


@ARTICLE{Monroy_Kuhn2018-fb,
  title    = "Estimating genetic kin relationships in prehistoric populations",
  author   = "Monroy Kuhn, Jose Manuel and Jakobsson, Mattias and G{\"u}nther,
              Torsten",
  abstract = "Archaeogenomic research has proven to be a valuable tool to trace
              migrations of historic and prehistoric individuals and groups,
              whereas relationships within a group or burial site have not been
              investigated to a large extent. Knowing the genetic kinship of
              historic and prehistoric individuals would give important
              insights into social structures of ancient and historic cultures.
              Most archaeogenetic research concerning kinship has been
              restricted to uniparental markers, while studies using
              genome-wide information were mainly focused on comparisons
              between populations. Applications which infer the degree of
              relationship based on modern-day DNA information typically
              require diploid genotype data. Low concentration of endogenous
              DNA, fragmentation and other post-mortem damage to ancient DNA
              (aDNA) makes the application of such tools unfeasible for most
              archaeological samples. To infer family relationships for
              degraded samples, we developed the software READ (Relationship
              Estimation from Ancient DNA). We show that our heuristic approach
              can successfully infer up to second degree relationships with as
              little as 0.1x shotgun coverage per genome for pairs of
              individuals. We uncover previously unknown relationships among
              prehistoric individuals by applying READ to published aDNA data
              from several human remains excavated from different cultural
              contexts. In particular, we find a group of five closely related
              males from the same Corded Ware culture site in modern-day
              Germany, suggesting patrilocality, which highlights the
              possibility to uncover social structures of ancient populations
              by applying READ to genome-wide aDNA data. READ is publicly
              available from https://bitbucket.org/tguenther/read.",
  journal  = "PLoS One",
  volume   =  13,
  number   =  4,
  pages    = "e0195491",
  month    =  apr,
  year     =  2018,
  language = "en"
}



@ARTICLE{Patterson2012-im,
  title    = "Ancient admixture in human history",
  author   = "Patterson, Nick and Moorjani, Priya and Luo, Yontao and Mallick,
              Swapan and Rohland, Nadin and Zhan, Yiping and Genschoreck, Teri
              and Webster, Teresa and Reich, David",
  abstract = "Population mixture is an important process in biology. We present
              a suite of methods for learning about population mixtures,
              implemented in a software package called ADMIXTOOLS, that support
              formal tests for whether mixture occurred and make it possible to
              infer proportions and dates of mixture. We also describe the
              development of a new single nucleotide polymorphism (SNP) array
              consisting of 629,433 sites with clearly documented ascertainment
              that was specifically designed for population genetic analyses
              and that we genotyped in 934 individuals from 53 diverse
              populations. To illustrate the methods, we give a number of
              examples that provide new insights about the history of human
              admixture. The most striking finding is a clear signal of
              admixture into northern Europe, with one ancestral population
              related to present-day Basques and Sardinians and the other
              related to present-day populations of northeast Asia and the
              Americas. This likely reflects a history of admixture between
              Neolithic migrants and the indigenous Mesolithic population of
              Europe, consistent with recent analyses of ancient bones from
              Sweden and the sequencing of the genome of the Tyrolean
              ``Iceman.''",
  journal  = "Genetics",
  volume   =  192,
  number   =  3,
  pages    = "1065--1093",
  month    =  nov,
  year     =  2012,
  language = "en"
}


@ARTICLE{Rivollat2020-qq,
  title    = "Ancient genome-wide {DNA} from France highlights the complexity
              of interactions between Mesolithic hunter-gatherers and Neolithic
              farmers",
  author   = "Rivollat, Ma{\"\i}t{\'e} and Jeong, Choongwon and Schiffels,
              Stephan and K{\"u}{\c c}{\"u}kkal{\i}p{\c c}{\i}, {\.I}{\c s}il
              and Pemonge, Marie-H{\'e}l{\`e}ne and Rohrlach, Adam Benjamin and
              Alt, Kurt W and Binder, Didier and Friederich, Susanne and
              Ghesqui{\`e}re, Emmanuel and Gronenborn, Detlef and Laporte, Luc
              and Lefranc, Philippe and Meller, Harald and R{\'e}veillas,
              H{\'e}l{\`e}ne and Rosenstock, Eva and Rottier, St{\'e}phane and
              Scarre, Chris and Soler, Ludovic and Wahl, Joachim and Krause,
              Johannes and Deguilloux, Marie-France and Haak, Wolfgang",
  abstract = "Starting from 12,000 years ago in the Middle East, the Neolithic
              lifestyle spread across Europe via separate continental and
              Mediterranean routes. Genomes from early European farmers have
              shown a clear Near Eastern/Anatolian genetic affinity with
              limited contribution from hunter-gatherers. However, no genomic
              data are available from modern-day France, where both routes
              converged, as evidenced by a mosaic cultural pattern. Here, we
              present genome-wide data from 101 individuals from 12 sites
              covering today's France and Germany from the Mesolithic (N = 3)
              to the Neolithic (N = 98) (7000-3000 BCE). Using the genetic
              substructure observed in European hunter-gatherers, we
              characterize diverse patterns of admixture in different regions,
              consistent with both routes of expansion. Early western European
              farmers show a higher proportion of distinctly western
              hunter-gatherer ancestry compared to central/southeastern
              farmers. Our data highlight the complexity of the biological
              interactions during the Neolithic expansion by revealing major
              regional variations.",
  journal  = "Sci Adv",
  volume   =  6,
  number   =  22,
  pages    = "eaaz5344",
  month    =  may,
  year     =  2020,
  language = "en"
}



@article {Rohrlach2023.04.17.537144,
	author = {Adam B Rohrlach and Jonathan Tuke and Divyaratan Popli and Wolfgang Haak},
	title = {BREADR: An R Package for the Bayesian Estimation of Genetic Relatedness from Low-coverage Genotype Data},
	elocation-id = {2023.04.17.537144},
	year = {2023},
	doi = {10.1101/2023.04.17.537144},
	publisher = {Cold Spring Harbor Laboratory},
	abstract = {Robust and reliable estimates of how individuals are biologically related to each other are a key source of information when reconstructing pedigrees. In combination with contextual data, reconstructed pedigrees can be used to infer possible kinship practices in prehistoric populations. However, standard methods to estimate biological relatedness from genome sequence data cannot be applied to low coverage sequence data, such as are common in ancient DNA (aDNA) studies. Critically, a statistically robust method for assessing and quantifying the confidence of a classification of a specific degree of relatedness for a pair of individuals, using low coverage genome data, is lacking.In this paper we present the R-package BREADR (Biological RElatedness from Ancient DNA in R), which leverages the so-called pairwise mismatch rate, calculated on optimally-thinned genome-wide pseudo-haploid sequence data, to estimate genetic relatedness up to the second degree, assuming an underlying binomial distribution. BREADR also returns a posterior probability for each degree of relatedness, from identical twins/same individual, first-degree, second-degree or {\textquotedblleft}unrelated{\textquotedblright} pairs, allowing researchers to quantify and report the uncertainty, even for particularly low-coverage data. We show that this method accurately recovers degrees of relatedness for sequence data with coverage as low as 0.04X using simulated data, and then compare the performance of BREADR on empirical data from Bronze Age Iberian human sequence data. The BREADR package is designed for pseudo-haploid genotype data, common in aDNA studies.Competing Interest StatementThe authors have declared no competing interest.},
	URL = {https://www.biorxiv.org/content/early/2023/04/18/2023.04.17.537144},
	eprint = {https://www.biorxiv.org/content/early/2023/04/18/2023.04.17.537144.full.pdf},
	journal = {bioRxiv}
}


@ARTICLE{Wright1922-vm,
  title     = "Coefficients of Inbreeding and Relationship",
  author    = "Wright, Sewall",
  journal   = "Am. Nat.",
  publisher = "[University of Chicago Press, American Society of Naturalists]",
  volume    =  56,
  number    =  645,
  pages     = "330--338",
  year      =  1922
}

@article{prüfer2021,
	title = {A genome sequence from a modern human skull over 45,000 years old from Zlatý k{\r{u}}{\v{n}} in Czechia},
	author = {{Prüfer}, Kay and Posth, Cosimo and Yu, He and Stoessel, Alexander and Spyrou, Maria A. and Deviese, Thibaut and Mattonai, Marco and Ribechini, Erika and Higham, Thomas and {Velemínský}, Petr and {Br{\r{u}}{\v{z}}ek}, Jaroslav and Krause, Johannes},
	year = {2021},
	month = {04},
	date = {2021-04-07},
	journal = {Nature Ecology & Evolution},
	pages = {820--825},
	volume = {5},
	number = {6},
	doi = {10.1038/s41559-021-01443-x},
	url = {http://dx.doi.org/10.1038/s41559-021-01443-x},
	langid = {en}
}

@article{prüfer2021,
	title = {A genome sequence from a modern human skull over 45,000 years old from Zlatý k{\r{u}}{\v{n}} in Czechia},
	author = {{Prüfer}, Kay and Posth, Cosimo and Yu, He and Stoessel, Alexander and Spyrou, Maria A. and Deviese, Thibaut and Mattonai, Marco and Ribechini, Erika and Higham, Thomas and {Velemínský}, Petr and {Br{\r{u}}{\v{z}}ek}, Jaroslav and Krause, Johannes},
	year = {2021},
	month = {04},
	date = {2021-04-07},
	journal = {Nature Ecology & Evolution},
	pages = {820--825},
	volume = {5},
	number = {6},
	doi = {10.1038/s41559-021-01443-x},
	url = {http://dx.doi.org/10.1038/s41559-021-01443-x},
	langid = {en}
}

@article{higham2014,
	title = {The timing and spatiotemporal patterning of Neanderthal disappearance},
	author = {Higham, Tom and Douka, Katerina and Wood, Rachel and Ramsey, Christopher Bronk and Brock, Fiona and Basell, Laura and Camps, Marta and Arrizabalaga, Alvaro and Baena, Javier and {Barroso-Ruíz}, Cecillio and Bergman, Christopher and Boitard, Coralie and Boscato, Paolo and {Caparrós}, Miguel and Conard, Nicholas J. and Draily, Christelle and Froment, Alain and {Galván}, Bertila and Gambassini, Paolo and Garcia-Moreno, Alejandro and Grimaldi, Stefano and Haesaerts, Paul and Holt, Brigitte and Iriarte-Chiapusso, Maria-Jose and Jelinek, Arthur and {Jordá Pardo}, {Jesús F.} and {Maíllo-Fernández}, {José-Manuel} and Marom, Anat and Maroto, {Julià} and {Menéndez}, Mario and Metz, Laure and Morin, {Eugène} and Moroni, Adriana and Negrino, Fabio and Panagopoulou, Eleni and Peresani, Marco and Pirson, {Stéphane} and de la Rasilla, Marco and Riel-Salvatore, Julien and Ronchitelli, Annamaria and Santamaria, David and Semal, Patrick and Slimak, Ludovic and Soler, Joaquim and Soler, {Narcís} and Villaluenga, Aritza and Pinhasi, Ron and Jacobi, Roger},
	year = {2014},
	month = {08},
	date = {2014-08-20},
	journal = {Nature},
	pages = {306--309},
	volume = {512},
	number = {7514},
	doi = {10.1038/nature13621},
	url = {http://dx.doi.org/10.1038/nature13621},
	langid = {en}
}

@article{hajdinjak2021,
	title = {Initial Upper Palaeolithic humans in Europe had recent Neanderthal ancestry},
	author = {Hajdinjak, Mateja and Mafessoni, Fabrizio and Skov, Laurits and Vernot, Benjamin and {Hübner}, Alexander and Fu, Qiaomei and Essel, Elena and Nagel, Sarah and Nickel, Birgit and Richter, Julia and Moldovan, Oana Teodora and Constantin, Silviu and Endarova, Elena and Zahariev, Nikolay and Spasov, Rosen and Welker, Frido and Smith, Geoff M. and Sinet-Mathiot, Virginie and Paskulin, Lindsey and Fewlass, Helen and Talamo, Sahra and Rezek, Zeljko and Sirakova, Svoboda and Sirakov, Nikolay and McPherron, Shannon P. and Tsanova, Tsenka and Hublin, Jean-Jacques and Peter, Benjamin M. and Meyer, Matthias and Skoglund, Pontus and Kelso, Janet and {Pääbo}, Svante},
	year = {2021},
	month = {04},
	date = {2021-04-07},
	journal = {Nature},
	pages = {253--257},
	volume = {592},
	number = {7853},
	doi = {10.1038/s41586-021-03335-3},
	url = {http://dx.doi.org/10.1038/s41586-021-03335-3},
	langid = {en}
}

@article{prüfer2017,
	title = {A high-coverage Neandertal genome from Vindija Cave in Croatia},
	author = {{Prüfer}, Kay and de Filippo, Cesare and Grote, Steffi and Mafessoni, Fabrizio and {Korlevi{\'{c}}}, Petra and Hajdinjak, Mateja and Vernot, Benjamin and Skov, Laurits and Hsieh, Pinghsun and {Peyrégne}, {Stéphane} and Reher, David and Hopfe, Charlotte and Nagel, Sarah and Maricic, Tomislav and Fu, Qiaomei and Theunert, Christoph and Rogers, Rebekah and Skoglund, Pontus and Chintalapati, Manjusha and Dannemann, Michael and Nelson, Bradley J. and Key, Felix M. and Rudan, Pavao and {Ku{\'{c}}an}, {{\v{Z}}eljko} and {Gu{\v{s}}i{\'{c}}}, Ivan and Golovanova, Liubov V. and Doronichev, Vladimir B. and Patterson, Nick and Reich, David and Eichler, Evan E. and Slatkin, Montgomery and Schierup, Mikkel H. and {Andrés}, Aida M. and Kelso, Janet and Meyer, Matthias and {Pääbo}, Svante},
	year = {2017},
	month = {11},
	date = {2017-11-03},
	journal = {Science},
	pages = {655--658},
	volume = {358},
	number = {6363},
	doi = {10.1126/science.aao1887},
	url = {http://dx.doi.org/10.1126/science.aao1887},
	langid = {en}
}

@misc{peter2020,
	title = {100,000 years of gene flow between Neandertals and Denisovans in the Altai mountains},
	author = {Peter, Benjamin M},
	year = {2020},
	month = {03},
	date = {2020-03-15},
	url = {http://dx.doi.org/10.1101/2020.03.13.990523}
}

@article{skov2018,
	title = {Detecting archaic introgression using an unadmixed outgroup},
	author = {Skov, Laurits and Hui, Ruoyun and Shchur, Vladimir and Hobolth, Asger and Scally, Aylwyn and Schierup, Mikkel Heide and Durbin, Richard},
	editor = {Racimo, Fernando},
	year = {2018},
	month = {09},
	date = {2018-09-18},
	journal = {PLOS Genetics},
	pages = {e1007641},
	volume = {14},
	number = {9},
	doi = {10.1371/journal.pgen.1007641},
	url = {http://dx.doi.org/10.1371/journal.pgen.1007641},
	langid = {en}
}

@misc{iasi2024,
	title = {Neandertal ancestry through time: Insights from genomes of ancient and present-day humans},
	author = {Iasi, Leonardo N. M. and Chintalapati, Manjusha and Skov, Laurits and Mesa, Alba Bossoms and Hajdinjak, Mateja and Peter, Benjamin M. and Moorjani, Priya},
	year = {2024},
	month = {05},
	date = {2024-05-13},
	url = {http://dx.doi.org/10.1101/2024.05.13.593955}
}

@article{fu2015,
	title = {An early modern human from Romania with a recent Neanderthal ancestor},
	author = {Fu, Qiaomei and Hajdinjak, Mateja and Moldovan, Oana Teodora and Constantin, Silviu and Mallick, Swapan and Skoglund, Pontus and Patterson, Nick and Rohland, Nadin and Lazaridis, Iosif and Nickel, Birgit and Viola, Bence and {Prüfer}, Kay and Meyer, Matthias and Kelso, Janet and Reich, David and {Pääbo}, Svante},
	year = {2015},
	month = {06},
	date = {2015-06-22},
	journal = {Nature},
	pages = {216--219},
	volume = {524},
	number = {7564},
	doi = {10.1038/nature14558},
	url = {http://dx.doi.org/10.1038/nature14558},
	langid = {en}
}

@article{green_draft_2010,
	title = {A {Draft} {Sequence} of the {Neandertal} {Genome}},
	volume = {328},
	url = {http://science.sciencemag.org/content/328/5979/710.abstract},
	doi = {10.1126/science.1188021},
	abstract = {Neandertals, the closest evolutionary relatives of present-day humans, lived in large parts of Europe and western Asia before disappearing 30,000 years ago. We present a draft sequence of the Neandertal genome composed of more than 4 billion nucleotides from three individuals. Comparisons of the Neandertal genome to the genomes of five present-day humans from different parts of the world identify a number of genomic regions that may have been affected by positive selection in ancestral modern humans, including genes involved in metabolism and in cognitive and skeletal development. We show that Neandertals shared more genetic variants with present-day humans in Eurasia than with present-day humans in sub-Saharan Africa, suggesting that gene flow from Neandertals into the ancestors of non-Africans occurred before the divergence of Eurasian groups from each other.},
	number = {5979},
	journal = {Science},
	author = {Green, Richard E. and Krause, Johannes and Briggs, Adrian W. and Maricic, Tomislav and Stenzel, Udo and Kircher, Martin and Patterson, Nick and Li, Heng and Zhai, Weiwei and Fritz, Markus Hsi-Yang and Hansen, Nancy F. and Durand, Eric Y. and Malaspinas, Anna-Sapfo and Jensen, Jeffrey D. and Marques-Bonet, Tomas and Alkan, Can and Prüfer, Kay and Meyer, Matthias and Burbano, Hernán A. and Good, Jeffrey M. and Schultz, Rigo and Aximu-Petri, Ayinuer and Butthof, Anne and Höber, Barbara and Höffner, Barbara and Siegemund, Madlen and Weihmann, Antje and Nusbaum, Chad and Lander, Eric S. and Russ, Carsten and Novod, Nathaniel and Affourtit, Jason and Egholm, Michael and Verna, Christine and Rudan, Pavao and Brajkovic, Dejana and Kucan, Željko and Gušic, Ivan and Doronichev, Vladimir B. and Golovanova, Liubov V. and Lalueza-Fox, Carles and de la Rasilla, Marco and Fortea, Javier and Rosas, Antonio and Schmitz, Ralf W. and Johnson, Philip L. F. and Eichler, Evan E. and Falush, Daniel and Birney, Ewan and Mullikin, James C. and Slatkin, Montgomery and Nielsen, Rasmus and Kelso, Janet and Lachmann, Michael and Reich, David and Pääbo, Svante},
	month = may,
	year = {2010},
	pages = {710}
}

@article{reich_genetic_2010,
	title = {Genetic history of an archaic hominin group from {Denisova} {Cave} in {Siberia}},
	volume = {468},
	url = {https://doi.org/10.1038/nature09710},
	journal = {Nature},
	author = {Reich, David and Green, Richard E. and Kircher, Martin and Krause, Johannes and Patterson, Nick and Durand, Eric Y. and Viola, Bence and Briggs, Adrian W. and Stenzel, Udo and Johnson, Philip L. F. and Maricic, Tomislav and Good, Jeffrey M. and Marques-Bonet, Tomas and Alkan, Can and Fu, Qiaomei and Mallick, Swapan and Li, Heng and Meyer, Matthias and Eichler, Evan E. and Stoneking, Mark and Richards, Michael and Talamo, Sahra and Shunkov, Michael V. and Derevianko, Anatoli P. and Hublin, Jean-Jacques and Kelso, Janet and Slatkin, Montgomery and Pääbo, Svante},
	month = dec,
	year = {2010},
	pages = {1053}
}

@article{meyer_high-coverage_2012,
	title = {A high-coverage genome sequence from an archaic {Denisovan} individual},
	volume = {338},
	issn = {1095-9203},
	doi = {10.1126/science.1224344},
	abstract = {We present a DNA library preparation method that has allowed us to reconstruct a high-coverage (30×) genome sequence of a Denisovan, an extinct relative of Neandertals. The quality of this genome allows a direct estimation of Denisovan heterozygosity indicating that genetic diversity in these archaic hominins was extremely low. It also allows tentative dating of the specimen on the basis of "missing evolution" in its genome, detailed measurements of Denisovan and Neandertal admixture into present-day human populations, and the generation of a near-complete catalog of genetic changes that swept to high frequency in modern humans since their divergence from Denisovans.},
	language = {eng},
	number = {6104},
	journal = {Science (New York, N.Y.)},
	author = {Meyer, Matthias and Kircher, Martin and Gansauge, Marie-Theres and Li, Heng and Racimo, Fernando and Mallick, Swapan and Schraiber, Joshua G. and Jay, Flora and Prüfer, Kay and de Filippo, Cesare and Sudmant, Peter H. and Alkan, Can and Fu, Qiaomei and Do, Ron and Rohland, Nadin and Tandon, Arti and Siebauer, Michael and Green, Richard E. and Bryc, Katarzyna and Briggs, Adrian W. and Stenzel, Udo and Dabney, Jesse and Shendure, Jay and Kitzman, Jacob and Hammer, Michael F. and Shunkov, Michael V. and Derevianko, Anatoli P. and Patterson, Nick and Andrés, Aida M. and Eichler, Evan E. and Slatkin, Montgomery and Reich, David and Kelso, Janet and Pääbo, Svante},
	month = oct,
	year = {2012},
	pmid = {22936568},
	pmcid = {PMC3617501},
	keywords = {Neanderthals, Fossils, Genome, Human, Humans, Alleles, Animals, Base Sequence, Gene Flow, Gene Library, Genetic Variation, Heterozygote, Molecular Sequence Data, Sequence Analysis, DNA},
	pages = {222--226},
	file = {Accepted Version:/home/leonardo_iasi/Zotero/storage/XK9P6I93/Meyer et al. - 2012 - A high-coverage genome sequence from an archaic De.pdf:application/pdf}
}

@article{Peter_admixture_2016,
    author = {Peter, Benjamin M},
    title = "{Admixture, Population Structure, and F-Statistics}",
    journal = {Genetics},
    volume = {202},
    number = {4},
    pages = {1485-1501},
    year = {2016},
    month = {02},
    abstract = "{Many questions about human genetic history can be addressed by examining the patterns of shared genetic variation between sets of populations. A useful methodological framework for this purpose is F-statistics that measure shared genetic drift between sets of two, three, and four populations and can be used to test simple and complex hypotheses about admixture between populations. This article provides context from phylogenetic and population genetic theory. I review how F-statistics can be interpreted as branch lengths or paths and derive new interpretations, using coalescent theory. I further show that the admixture tests can be interpreted as testing general properties of phylogenies, allowing extension of some ideas applications to arbitrary phylogenetic trees. The new results are used to investigate the behavior of the statistics under different models of population structure and show how population substructure complicates inference. The results lead to simplified estimators in many cases, and I recommend to replace F3 with the average number of pairwise differences for estimating population divergence.}",
    issn = {1943-2631},
    doi = {10.1534/genetics.115.183913},
    url = {https://doi.org/10.1534/genetics.115.183913},
    eprint = {https://academic.oup.com/genetics/article-pdf/202/4/1485/46813224/genetics1485.pdf},
}