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1. Evolution of the Mutation Spectrum Across a Mammalian Phylogeny.

Author

Beichman, Annabel, Lin, Meixi, Moreno-Estrada, Andrés, Nigenda-Morales, Sergio, Harris, Kelley, and Robinson, Jacqueline

Subjects
mammal, mutagenesis, mutation, mutation spectrum, phylogenetic signal, reproductive age
Abstract

Although evolutionary biologists have long theorized that variation in DNA repair efficacy might explain some of the diversity of lifespan and cancer incidence across species, we have little data on the variability of normal germline mutagenesis outside of humans. Here, we shed light on the spectrum and etiology of mutagenesis across mammals by quantifying mutational sequence context biases using polymorphism data from thirteen species of mice, apes, bears, wolves, and cetaceans. After normalizing the mutation spectrum for reference genome accessibility and k-mer content, we use the Mantel test to deduce that mutation spectrum divergence is highly correlated with genetic divergence between species, whereas life history traits like reproductive age are weaker predictors of mutation spectrum divergence. Potential bioinformatic confounders are only weakly related to a small set of mutation spectrum features. We find that clock-like mutational signatures previously inferred from human cancers cannot explain the phylogenetic signal exhibited by the mammalian mutation spectrum, despite the ability of these signatures to fit each species 3-mer spectrum with high cosine similarity. In contrast, parental aging signatures inferred from human de novo mutation data appear to explain much of the 1-mer spectrums phylogenetic signal in combination with a novel mutational signature. We posit that future models purporting to explain the etiology of mammalian mutagenesis need to capture the fact that more closely related species have more similar mutation spectra; a model that fits each marginal spectrum with high cosine similarity is not guaranteed to capture this hierarchy of mutation spectrum variation among species.

Published
2023

2. Increased mutation and gene conversion within human segmental duplications

Author

Vollger, Mitchell R, Dishuck, Philip C, Harvey, William T, DeWitt, William S, Guitart, Xavi, Goldberg, Michael E, Rozanski, Allison N, Lucas, Julian, Asri, Mobin, Munson, Katherine M, Lewis, Alexandra P, Hoekzema, Kendra, Logsdon, Glennis A, Porubsky, David, Paten, Benedict, Harris, Kelley, Hsieh, PingHsun, and Eichler, Evan E

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Genetics, 2.1 Biological and endogenous factors, Humans, Gene Conversion, Genome, Human, Mutation, Segmental Duplications, Genomic, Polymorphism, Single Nucleotide, Haplotypes, Exons, Cytosine, Guanine, CpG Islands, Human Pangenome Reference Consortium, General Science & Technology
Abstract

Single-nucleotide variants (SNVs) in segmental duplications (SDs) have not been systematically assessed because of the limitations of mapping short-read sequencing data1,2. Here we constructed 1:1 unambiguous alignments spanning high-identity SDs across 102 human haplotypes and compared the pattern of SNVs between unique and duplicated regions3,4. We find that human SNVs are elevated 60% in SDs compared to unique regions and estimate that at least 23% of this increase is due to interlocus gene conversion (IGC) with up to 4.3 megabase pairs of SD sequence converted on average per human haplotype. We develop a genome-wide map of IGC donors and acceptors, including 498 acceptor and 454 donor hotspots affecting the exons of about 800 protein-coding genes. These include 171 genes that have 'relocated' on average 1.61 megabase pairs in a subset of human haplotypes. Using a coalescent framework, we show that SD regions are slightly evolutionarily older when compared to unique sequences, probably owing to IGC. SNVs in SDs, however, show a distinct mutational spectrum: a 27.1% increase in transversions that convert cytosine to guanine or the reverse across all triplet contexts and a 7.6% reduction in the frequency of CpG-associated mutations when compared to unique DNA. We reason that these distinct mutational properties help to maintain an overall higher GC content of SD DNA compared to that of unique DNA, probably driven by GC-biased conversion between paralogous sequences5,6.

Published
2023

6. Resilience integrates concepts in aging research

Author

Promislow, Daniel, Anderson, Rozalyn M., Scheffer, Marten, Crespi, Bernard, DeGregori, James, Harris, Kelley, Horowitz, Barbara Natterson, Levine, Morgan E., Riolo, Maria A., Schneider, David S., Spencer, Sabrina L., Valenzano, Dario Riccardo, and Hochberg, Michael E.

Published
2022
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8. Genomic Evidence of Widespread Admixture from Polar Bears into Brown Bears during the Last Ice Age

Author

Cahill, James A, Heintzman, Peter D, Harris, Kelley, Teasdale, Matthew D, Kapp, Joshua, Soares, Andre ER, Stirling, Ian, Bradley, Daniel, Edwards, Ceiridwen J, Graim, Kiley, Kisleika, Aliaksandr A, Malev, Alexander V, Monaghan, Nigel, Green, Richard E, and Shapiro, Beth

Subjects
Biological Sciences, Genetics, Human Genome, Animals, Climate Change, Fossils, Gene Flow, Hybridization, Genetic, Ice Cover, Ursidae, genomics, hybridization, ancient DNA, ursus, paleogenomics, admixture, Biochemistry and Cell Biology, Evolutionary Biology, Biochemistry and cell biology, Evolutionary biology
Abstract

Recent genomic analyses have provided substantial evidence for past periods of gene flow from polar bears (Ursus maritimus) into Alaskan brown bears (Ursus arctos), with some analyses suggesting a link between climate change and genomic introgression. However, because it has mainly been possible to sample bears from the present day, the timing, frequency, and evolutionary significance of this admixture remains unknown. Here, we analyze genomic DNA from three additional and geographically distinct brown bear populations, including two that lived temporally close to the peak of the last ice age. We find evidence of admixture in all three populations, suggesting that admixture between these species has been common in their recent evolutionary history. In addition, analyses of ten fossil bears from the now-extinct Irish population indicate that admixture peaked during the last ice age, whereas brown bear and polar bear ranges overlapped. Following this peak, the proportion of polar bear ancestry in Irish brown bears declined rapidly until their extinction. Our results support a model in which ice age climate change created geographically widespread conditions conducive to admixture between polar bears and brown bears, as is again occurring today. We postulate that this model will be informative for many admixing species pairs impacted by climate change. Our results highlight the power of paleogenomics to reveal patterns of evolutionary change that are otherwise masked in contemporary data.

Published
2018

9. Q&A: Where did the Neanderthals go?

Author

Harris, Kelley and Nielsen, Rasmus

Subjects
Biological Sciences, Genetics, Human Genome, Animals, Evolution, Molecular, Fossils, Genome, Human, Genomics, Humans, Hybridization, Genetic, Neanderthals, Developmental Biology, Biological sciences
Abstract

Genomic evidence has demonstrated that humans and Neanderthals interbred. Today, the genomes of most individuals outside Africa contain 2-3% Neanderthal DNA. However, it is still hotly debated why the Neanderthals went extinct and if humans contributed to the Neanderthal extinction. In this Q&A we explore what genomic data might have to say about this issue.

Published
2017

14. The Genetic Cost of Neanderthal Introgression

Author

Harris, Kelley and Nielsen, Rasmus

Subjects
Biological Sciences, Genetics, Human Genome, Biotechnology, Animals, Evolution, Molecular, Gene Flow, Genes, Recessive, Genetic Fitness, Genetic Load, Humans, Hybrid Vigor, Inbreeding, Neanderthals, gene flow, archaic hominins, nearly neutral theory, deleterious mutation load, heterosis, Developmental Biology, Biochemistry and cell biology
Abstract

Approximately 2-4% of genetic material in human populations outside Africa is derived from Neanderthals who interbred with anatomically modern humans. Recent studies have shown that this Neanderthal DNA is depleted around functional genomic regions; this has been suggested to be a consequence of harmful epistatic interactions between human and Neanderthal alleles. However, using published estimates of Neanderthal inbreeding and the distribution of mutational fitness effects, we infer that Neanderthals had at least 40% lower fitness than humans on average; this increased load predicts the reduction in Neanderthal introgression around genes without the need to invoke epistasis. We also predict a residual Neanderthal mutational load in non-Africans, leading to a fitness reduction of at least 0.5%. This effect of Neanderthal admixture has been left out of previous debate on mutation load differences between Africans and non-Africans. We also show that if many deleterious mutations are recessive, the Neanderthal admixture fraction could increase over time due to the protective effect of Neanderthal haplotypes against deleterious alleles that arose recently in the human population. This might partially explain why so many organisms retain gene flow from other species and appear to derive adaptive benefits from introgression.

Published
2016

18. Decoding coalescent hidden Markov models in linear time

Author

Harris, Kelley, Sheehan, Sara, Kamm, John A., and Song, Yun S.

Subjects
Quantitative Biology - Populations and Evolution
Abstract

In many areas of computational biology, hidden Markov models (HMMs) have been used to model local genomic features. In particular, coalescent HMMs have been used to infer ancient population sizes, migration rates, divergence times, and other parameters such as mutation and recombination rates. As more loci, sequences, and hidden states are added to the model, however, the runtime of coalescent HMMs can quickly become prohibitive. Here we present a new algorithm for reducing the runtime of coalescent HMMs from quadratic in the number of hidden time states to linear, without making any additional approximations. Our algorithm can be incorporated into various coalescent HMMs, including the popular method PSMC for inferring variable effective population sizes. Here we implement this algorithm to speed up our demographic inference method diCal, which is equivalent to PSMC when applied to a sample of two haplotypes. We demonstrate that the linear-time method can reconstruct a population size change history more accurately than the quadratic-time method, given similar computation resources. We also apply the method to data from the 1000 Genomes project, inferring a high-resolution history of size changes in the European population., Comment: 18 pages, 5 figures. To appear in the Proceedings of the 18th Annual International Conference on Research in Computational Molecular Biology (RECOMB 2014). The final publication is available at link.springer.com

Published
2014

19. Error-prone polymerase activity causes multinucleotide mutations in humans

Author

Harris, Kelley and Nielsen, Rasmus

Subjects
Quantitative Biology - Populations and Evolution
Abstract

About 2% of human genetic polymorphisms have been hypothesized to arise via multinucleotide mutations (MNMs), complex events that generate SNPs at multiple sites in a single generation. MNMs have the potential to accelerate the pace at which single genes evolve and to confound studies of demography and selection that assume all SNPs arise independently. In this paper, we examine clustered mutations that are segregating in a set of 1,092 human genomes, demonstrating that MNMs become enriched as large numbers of individuals are sampled. We leverage the size of the dataset to deduce new information about the allelic spectrum of MNMs, estimating the percentage of linked SNP pairs that were generated by simultaneous mutation as a function of the distance between the affected sites and showing that MNMs exhibit a high percentage of transversions relative to transitions. These findings are reproducible in data from multiple sequencing platforms. Among tandem mutations that occur simultaneously at adjacent sites, we find an especially skewed distribution of ancestral and derived dinucleotides, with $\textrm{GC}\to \textrm{AA}$, $\textrm{GA}\to \textrm{TT}$ and their reverse complements making up 36% of the total. These same mutations dominate the spectrum of tandem mutations produced by the upregulation of low-fidelity Polymerase $\zeta$ in mutator strains of S. cerevisiae that have impaired DNA excision repair machinery. This suggests that low-fidelity DNA replication by Pol $\zeta$ is at least partly responsible for the MNMs that are segregating in the human population, and that useful information about the biochemistry of MNM can be extracted from ordinary population genomic data. We incorporate our findings into a mathematical model of the multinucleotide mutation process that can be used to correct phylogenetic and population genetic methods for the presence of MNMs.

Published
2013

21. Genomic evidence for the Pleistocene and recent population history of Native Americans

Author

Raghavan, Maanasa, Steinrücken, Matthias, Harris, Kelley, Schiffels, Stephan, Rasmussen, Simon, DeGiorgio, Michael, Albrechtsen, Anders, Valdiosera, Cristina, Ávila-Arcos, María C, Malaspinas, Anna-Sapfo, Eriksson, Anders, Moltke, Ida, Metspalu, Mait, Homburger, Julian R, Wall, Jeff, Cornejo, Omar E, Moreno-Mayar, J Víctor, Korneliussen, Thorfinn S, Pierre, Tracey, Rasmussen, Morten, Campos, Paula F, de Barros Damgaard, Peter, Allentoft, Morten E, Lindo, John, Metspalu, Ene, Rodríguez-Varela, Ricardo, Mansilla, Josefina, Henrickson, Celeste, Seguin-Orlando, Andaine, Malmström, Helena, Stafford, Thomas, Shringarpure, Suyash S, Moreno-Estrada, Andrés, Karmin, Monika, Tambets, Kristiina, Bergström, Anders, Xue, Yali, Warmuth, Vera, Friend, Andrew D, Singarayer, Joy, Valdes, Paul, Balloux, Francois, Leboreiro, Ilán, Vera, Jose Luis, Rangel-Villalobos, Hector, Pettener, Davide, Luiselli, Donata, Davis, Loren G, Heyer, Evelyne, Zollikofer, Christoph PE, Ponce de León, Marcia S, Smith, Colin I, Grimes, Vaughan, Pike, Kelly-Anne, Deal, Michael, Fuller, Benjamin T, Arriaza, Bernardo, Standen, Vivien, Luz, Maria F, Ricaut, Francois, Guidon, Niede, Osipova, Ludmila, Voevoda, Mikhail I, Posukh, Olga L, Balanovsky, Oleg, Lavryashina, Maria, Bogunov, Yuri, Khusnutdinova, Elza, Gubina, Marina, Balanovska, Elena, Fedorova, Sardana, Litvinov, Sergey, Malyarchuk, Boris, Derenko, Miroslava, Mosher, MJ, Archer, David, Cybulski, Jerome, Petzelt, Barbara, Mitchell, Joycelynn, Worl, Rosita, Norman, Paul J, Parham, Peter, Kemp, Brian M, Kivisild, Toomas, Tyler-Smith, Chris, Sandhu, Manjinder S, Crawford, Michael, Villems, Richard, Smith, David Glenn, Waters, Michael R, Goebel, Ted, Johnson, John R, Malhi, Ripan S, Jakobsson, Mattias, Meltzer, David J, Manica, Andrea, Durbin, Richard, Bustamante, Carlos D, Song, Yun S, and Nielsen, Rasmus

Subjects
Biological Sciences, Genetics, History, Heritage and Archaeology, Human Society, Historical Studies, Anthropology, Minority Health, Human Genome, American Indian or Alaska Native, Americas, Gene Flow, Genomics, History, Ancient, Human Migration, Humans, Indians, North American, Models, Genetic, Siberia, General Science & Technology
Abstract

How and when the Americas were populated remains contentious. Using ancient and modern genome-wide data, we found that the ancestors of all present-day Native Americans, including Athabascans and Amerindians, entered the Americas as a single migration wave from Siberia no earlier than 23 thousand years ago (ka) and after no more than an 8000-year isolation period in Beringia. After their arrival to the Americas, ancestral Native Americans diversified into two basal genetic branches around 13 ka, one that is now dispersed across North and South America and the other restricted to North America. Subsequent gene flow resulted in some Native Americans sharing ancestry with present-day East Asians (including Siberians) and, more distantly, Australo-Melanesians. Putative "Paleoamerican" relict populations, including the historical Mexican Pericúes and South American Fuego-Patagonians, are not directly related to modern Australo-Melanesians as suggested by the Paleoamerican Model.

Published
2015

22. POPULATION GENETICS. Genomic evidence for the Pleistocene and recent population history of Native Americans.

Author

Raghavan, Maanasa, Steinrücken, Matthias, Harris, Kelley, Schiffels, Stephan, Rasmussen, Simon, DeGiorgio, Michael, Albrechtsen, Anders, Valdiosera, Cristina, Ávila-Arcos, María C, Malaspinas, Anna-Sapfo, Eriksson, Anders, Moltke, Ida, Metspalu, Mait, Homburger, Julian R, Wall, Jeff, Cornejo, Omar E, Moreno-Mayar, J Víctor, Korneliussen, Thorfinn S, Pierre, Tracey, Rasmussen, Morten, Campos, Paula F, de Barros Damgaard, Peter, Allentoft, Morten E, Lindo, John, Metspalu, Ene, Rodríguez-Varela, Ricardo, Mansilla, Josefina, Henrickson, Celeste, Seguin-Orlando, Andaine, Malmström, Helena, Stafford, Thomas, Shringarpure, Suyash S, Moreno-Estrada, Andrés, Karmin, Monika, Tambets, Kristiina, Bergström, Anders, Xue, Yali, Warmuth, Vera, Friend, Andrew D, Singarayer, Joy, Valdes, Paul, Balloux, Francois, Leboreiro, Ilán, Vera, Jose Luis, Rangel-Villalobos, Hector, Pettener, Davide, Luiselli, Donata, Davis, Loren G, Heyer, Evelyne, Zollikofer, Christoph PE, Ponce de León, Marcia S, Smith, Colin I, Grimes, Vaughan, Pike, Kelly-Anne, Deal, Michael, Fuller, Benjamin T, Arriaza, Bernardo, Standen, Vivien, Luz, Maria F, Ricaut, Francois, Guidon, Niede, Osipova, Ludmila, Voevoda, Mikhail I, Posukh, Olga L, Balanovsky, Oleg, Lavryashina, Maria, Bogunov, Yuri, Khusnutdinova, Elza, Gubina, Marina, Balanovska, Elena, Fedorova, Sardana, Litvinov, Sergey, Malyarchuk, Boris, Derenko, Miroslava, Mosher, MJ, Archer, David, Cybulski, Jerome, Petzelt, Barbara, Mitchell, Joycelynn, Worl, Rosita, Norman, Paul J, Parham, Peter, Kemp, Brian M, Kivisild, Toomas, Tyler-Smith, Chris, Sandhu, Manjinder S, Crawford, Michael, Villems, Richard, Smith, David Glenn, Waters, Michael R, Goebel, Ted, Johnson, John R, Malhi, Ripan S, Jakobsson, Mattias, Meltzer, David J, Manica, Andrea, Durbin, Richard, Bustamante, Carlos D, Song, Yun S, and Nielsen, Rasmus

Subjects
Humans, Genomics, Models, Genetic, History, Ancient, Indians, North American, Americas, Siberia, Gene Flow, Human Migration, Human Genome, Genetics, General Science & Technology
Abstract

How and when the Americas were populated remains contentious. Using ancient and modern genome-wide data, we found that the ancestors of all present-day Native Americans, including Athabascans and Amerindians, entered the Americas as a single migration wave from Siberia no earlier than 23 thousand years ago (ka) and after no more than an 8000-year isolation period in Beringia. After their arrival to the Americas, ancestral Native Americans diversified into two basal genetic branches around 13 ka, one that is now dispersed across North and South America and the other restricted to North America. Subsequent gene flow resulted in some Native Americans sharing ancestry with present-day East Asians (including Siberians) and, more distantly, Australo-Melanesians. Putative "Paleoamerican" relict populations, including the historical Mexican Pericúes and South American Fuego-Patagonians, are not directly related to modern Australo-Melanesians as suggested by the Paleoamerican Model.

Published
2015

23. The Projection of a Test Genome onto a Reference Population and Applications to Humans and Archaic Hominins

Author

Yang, Melinda A, Harris, Kelley, and Slatkin, Montgomery

Subjects
Biological Sciences, Genetics, Human Genome, Animals, Computer Simulation, Evolution, Molecular, Gene Flow, Genetics, Population, Genome, Genome, Human, Genomics, Hominidae, Humans, Models, Genetic, Population Density, Population Groups, archaic admixture, frequency spectrum, human demography, human population genetics, Developmental Biology, Biochemistry and cell biology
Abstract

We introduce a method for comparing a test genome with numerous genomes from a reference population. Sites in the test genome are given a weight, w, that depends on the allele frequency, x, in the reference population. The projection of the test genome onto the reference population is the average weight for each x, [Formula: see text]. The weight is assigned in such a way that, if the test genome is a random sample from the reference population, then [Formula: see text]. Using analytic theory, numerical analysis, and simulations, we show how the projection depends on the time of population splitting, the history of admixture, and changes in past population size. The projection is sensitive to small amounts of past admixture, the direction of admixture, and admixture from a population not sampled (a ghost population). We compute the projections of several human and two archaic genomes onto three reference populations from the 1000 Genomes project-Europeans, Han Chinese, and Yoruba-and discuss the consistency of our analysis with previously published results for European and Yoruba demographic history. Including higher amounts of admixture between Europeans and Yoruba soon after their separation and low amounts of admixture more recently can resolve discrepancies between the projections and demographic inferences from some previous studies.

Published
2014

24. Error-prone polymerase activity causes multinucleotide mutations in humans

Author

Harris, Kelley and Nielsen, Rasmus

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Genetics, Generic health relevance, Animals, DNA Replication, DNA-Directed DNA Polymerase, Gene Frequency, Genome, Human, Humans, Macaca mulatta, Models, Genetic, Mutation, Pan troglodytes, Polymorphism, Single Nucleotide, Medical and Health Sciences, Bioinformatics
Abstract

About 2% of human genetic polymorphisms have been hypothesized to arise via multinucleotide mutations (MNMs), complex events that generate SNPs at multiple sites in a single generation. MNMs have the potential to accelerate the pace at which single genes evolve and to confound studies of demography and selection that assume all SNPs arise independently. In this paper, we examine clustered mutations that are segregating in a set of 1092 human genomes, demonstrating that the signature of MNM becomes enriched as large numbers of individuals are sampled. We estimate the percentage of linked SNP pairs that were generated by simultaneous mutation as a function of the distance between affected sites and show that MNMs exhibit a high percentage of transversions relative to transitions, findings that are reproducible in data from multiple sequencing platforms and cannot be attributed to sequencing error. Among tandem mutations that occur simultaneously at adjacent sites, we find an especially skewed distribution of ancestral and derived alleles, with GC → AA, GA → TT, and their reverse complements making up 27% of the total. These mutations have been previously shown to dominate the spectrum of the error-prone polymerase Pol ζ, suggesting that low-fidelity DNA replication by Pol ζ is at least partly responsible for the MNMs that are segregating in the human population. We develop statistical estimates of MNM prevalence that can be used to correct phylogenetic and population genetic inferences for the presence of complex mutations.

Published
2014

25. Population Genomics Reveal Recent Speciation and Rapid Evolutionary Adaptation in Polar Bears

Author

Liu, Shiping, Lorenzen, Eline D, Fumagalli, Matteo, Li, Bo, Harris, Kelley, Xiong, Zijun, Zhou, Long, Korneliussen, Thorfinn Sand, Somel, Mehmet, Babbitt, Courtney, Wray, Greg, Li, Jianwen, He, Weiming, Wang, Zhuo, Fu, Wenjing, Xiang, Xueyan, Morgan, Claire C, Doherty, Aoife, O’Connell, Mary J, McInerney, James O, Born, Erik W, Dalén, Love, Dietz, Rune, Orlando, Ludovic, Sonne, Christian, Zhang, Guojie, Nielsen, Rasmus, Willerslev, Eske, and Wang, Jun

Subjects
Biological Sciences, Genetics, Heart Disease, Cardiovascular, Human Genome, Atherosclerosis, Adaptation, Physiological, Adipose Tissue, Animals, Apolipoproteins B, Arctic Regions, Biological Evolution, Fatty Acids, Gene Flow, Genetics, Population, Genome, Ursidae, Medical and Health Sciences, Developmental Biology, Biological sciences, Biomedical and clinical sciences
Abstract

Polar bears are uniquely adapted to life in the High Arctic and have undergone drastic physiological changes in response to Arctic climates and a hyper-lipid diet of primarily marine mammal prey. We analyzed 89 complete genomes of polar bear and brown bear using population genomic modeling and show that the species diverged only 479-343 thousand years BP. We find that genes on the polar bear lineage have been under stronger positive selection than in brown bears; nine of the top 16 genes under strong positive selection are associated with cardiomyopathy and vascular disease, implying important reorganization of the cardiovascular system. One of the genes showing the strongest evidence of selection, APOB, encodes the primary lipoprotein component of low-density lipoprotein (LDL); functional mutations in APOB may explain how polar bears are able to cope with life-long elevated LDL levels that are associated with high risk of heart disease in humans.

Published
2014

26. Inferring demographic history from a spectrum of shared haplotype lengths.

Author

Harris, Kelley and Nielsen, Rasmus

Subjects
Africa, African Continental Ancestry Group, Animals, Europe, European Continental Ancestry Group, Gene Flow, Genetics, Population, Genome, Human, Haplotypes, Hominidae, Human Genome Project, Humans, Models, Genetic, Neanderthals
Abstract

There has been much recent excitement about the use of genetics to elucidate ancestral history and demography. Whole genome data from humans and other species are revealing complex stories of divergence and admixture that were left undiscovered by previous smaller data sets. A central challenge is to estimate the timing of past admixture and divergence events, for example the time at which Neanderthals exchanged genetic material with humans and the time at which modern humans left Africa. Here, we present a method for using sequence data to jointly estimate the timing and magnitude of past admixture events, along with population divergence times and changes in effective population size. We infer demography from a collection of pairwise sequence alignments by summarizing their length distribution of tracts of identity by state (IBS) and maximizing an analytic composite likelihood derived from a Markovian coalescent approximation. Recent gene flow between populations leaves behind long tracts of identity by descent (IBD), and these tracts give our method power by influencing the distribution of shared IBS tracts. In simulated data, we accurately infer the timing and strength of admixture events, population size changes, and divergence times over a variety of ancient and recent time scales. Using the same technique, we analyze deeply sequenced trio parents from the 1000 Genomes project. The data show evidence of extensive gene flow between Africa and Europe after the time of divergence as well as substructure and gene flow among ancestral hominids. In particular, we infer that recent African-European gene flow and ancient ghost admixture into Europe are both necessary to explain the spectrum of IBS sharing in the trios, rejecting simpler models that contain less population structure.

Published
2013

33. Increased mutation and gene conversion within human segmental duplications.

Author

Vollger, Mitchell, Vollger, Mitchell, Dishuck, Philip, Harvey, William, DeWitt, William, Guitart, Xavi, Goldberg, Michael, Rozanski, Allison, Lucas, Julian, Asri, Mobin, Munson, Katherine, Lewis, Alexandra, Hoekzema, Kendra, Logsdon, Glennis, Porubsky, David, Paten, Benedict, Harris, Kelley, Hsieh, PingHsun, Eichler, Evan, Vollger, Mitchell, Vollger, Mitchell, Dishuck, Philip, Harvey, William, DeWitt, William, Guitart, Xavi, Goldberg, Michael, Rozanski, Allison, Lucas, Julian, Asri, Mobin, Munson, Katherine, Lewis, Alexandra, Hoekzema, Kendra, Logsdon, Glennis, Porubsky, David, Paten, Benedict, Harris, Kelley, Hsieh, PingHsun, and Eichler, Evan

Abstract

Single-nucleotide variants (SNVs) in segmental duplications (SDs) have not been systematically assessed because of the limitations of mapping short-read sequencing data1,2. Here we constructed 1:1 unambiguous alignments spanning high-identity SDs across 102 human haplotypes and compared the pattern of SNVs between unique and duplicated regions3,4. We find that human SNVs are elevated 60% in SDs compared to unique regions and estimate that at least 23% of this increase is due to interlocus gene conversion (IGC) with up to 4.3 megabase pairs of SD sequence converted on average per human haplotype. We develop a genome-wide map of IGC donors and acceptors, including 498 acceptor and 454 donor hotspots affecting the exons of about 800 protein-coding genes. These include 171 genes that have relocated on average 1.61 megabase pairs in a subset of human haplotypes. Using a coalescent framework, we show that SD regions are slightly evolutionarily older when compared to unique sequences, probably owing to IGC. SNVs in SDs, however, show a distinct mutational spectrum: a 27.1% increase in transversions that convert cytosine to guanine or the reverse across all triplet contexts and a 7.6% reduction in the frequency of CpG-associated mutations when compared to unique DNA. We reason that these distinct mutational properties help to maintain an overall higher GC content of SD DNA compared to that of unique DNA, probably driven by GC-biased conversion between paralogous sequences5,6.

Published
2023

38. The Mutationathon highlights the importance of reaching standardization in estimates of pedigree-based germline mutation rates

Author

Bergeron, Lucie A., Besenbacher, Søren, Turner, Tychele N., Versoza, Cyril J., Wang, Richard J., Price, Alivia Lee, Armstrong, Ellie, Riera, Meritxell, Carlson, Jedidiah, Chen, Hwei-Yen, Hahn, Matthew W., Harris, Kelley, Kleppe, April Snøfrid, López-Nandam, Elora H., Moorjani, Priya, Pfeifer, Susanne P., Tiley, George P., Yoder, Anne D., Zhang, Guojie, Schierup, Mikkel H., Bergeron, Lucie A., Besenbacher, Søren, Turner, Tychele N., Versoza, Cyril J., Wang, Richard J., Price, Alivia Lee, Armstrong, Ellie, Riera, Meritxell, Carlson, Jedidiah, Chen, Hwei-Yen, Hahn, Matthew W., Harris, Kelley, Kleppe, April Snøfrid, López-Nandam, Elora H., Moorjani, Priya, Pfeifer, Susanne P., Tiley, George P., Yoder, Anne D., Zhang, Guojie, and Schierup, Mikkel H.

Abstract

In the past decade, several studies have estimated the human per-generation germline mutation rate using large pedigrees. More recently, estimates for various non-human species have been published. However, methodological differences among studies in detecting germline mutations and estimating mutation rates make direct comparisons difficult. Here, we describe the many different steps involved in estimating pedigree-based mutation rates, including sampling, sequencing, mapping, variant calling, filtering, and how to appropriately account for false-positive and false-negative rates. For each step, we review the different methods and parameter choices that have been used in the recent literature. Additionally, we present the results from a “Mutationathon”, a competition organized among five research labs to compare germline mutation rate estimates for a single pedigree of rhesus macaques. We report almost a two-fold variation in the final estimated rate among groups using different post-alignment processing, calling, and filtering criteria and provide details into the sources of variation across studies. Though the difference among estimates is not statistically significant, this discrepancy emphasizes the need for standardized methods in mutation rate estimations and the difficulty in comparing rates from different studies. Finally, this work aims to provide guidelines for computational and statistical benchmarks for future studies interested in identifying germline mutations from pedigrees.

Published
2022

40. The Mutationathon highlights the importance of reaching standardization in estimates of pedigree-based germline mutation rates

Author

Bergeron, Lucie A, primary, Besenbacher, Søren, additional, Turner, Tychele, additional, Versoza, Cyril J, additional, Wang, Richard J, additional, Price, Alivia Lee, additional, Armstrong, Ellie, additional, Riera, Meritxell, additional, Carlson, Jedidiah, additional, Chen, Hwei-yen, additional, Hahn, Matthew W, additional, Harris, Kelley, additional, Kleppe, April Snøfrid, additional, López-Nandam, Elora H, additional, Moorjani, Priya, additional, Pfeifer, Susanne P, additional, Tiley, George P, additional, Yoder, Anne D, additional, Zhang, Guojie, additional, and Schierup, Mikkel H, additional

Published
2022
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41. Author response: The Mutationathon highlights the importance of reaching standardization in estimates of pedigree-based germline mutation rates

Author

Bergeron, Lucie A, primary, Besenbacher, Søren, additional, Turner, Tychele, additional, Versoza, Cyril J, additional, Wang, Richard J, additional, Price, Alivia Lee, additional, Armstrong, Ellie, additional, Riera, Meritxell, additional, Carlson, Jedidiah, additional, Chen, Hwei-yen, additional, Hahn, Matthew W, additional, Harris, Kelley, additional, Kleppe, April Snøfrid, additional, López-Nandam, Elora H, additional, Moorjani, Priya, additional, Pfeifer, Susanne P, additional, Tiley, George P, additional, Yoder, Anne D, additional, Zhang, Guojie, additional, and Schierup, Mikkel H, additional

Published
2022
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43. Inference of population history and mutation biology from human genetic variation

Author

Harris, Kelley

Subjects
Bioinformatics, Applied mathematics, Genetics, coalescent theory, demographic history, genetic drift, human genetic variation, mutation, population genetics
Abstract

Human genetic diversity bears many imprints of our species’ migration out of Africa. When our ancestral population expanded across the globe and settled into nearly every habitable environment, genetic diversity was reduced, distributed and redistributed by an intricate series of population bottlenecks and migrations. The coalescent process is a mathematical model that describes the probability distribution of modern DNA sequences that could have evolved from a common ancestor following a specific demographic scenario; in principle, this gives us the means to infer the history that is most consistent with large datasets of genomes sequenced from living people. In practice, however, the coalescent is such a complicated model that such calculations are intractable to perform exactly. Here, I introduce several new techniques for performing approximate demographic inference under the coalescent; these operate by condensing samples of genomes into more compact summary statistics and then mathematically approximating the probability distributions that these statistics should follow. I then use these techniques to infer joint demographic histories from European and African genomes, describing a complex out-of-Africa migration that involved multiple pop- ulation size changes as well as a long period of migration between the diverging continental groups. The good match between predicted and observed genomic samples indicates that the coalescent is a useful framework for describing the evolution of humans; however, I also note systematic discrepancies between the model and the data. In the last two chapters of this thesis, I go on to show that some deviations of human data from coalescent predictions stem from the coalescent’s oversimplication of the way mutations are generated. One stan- dard assumption is that mutations occur independently; in contrast, at least 2% of human occur in linked clusters and are likely to have been generated by multinucleotide mutation events (MNMs). Examining the derived and ancestral alleles of these MNMs, I show that they are enriched for transversions and that many bear the specific signature of error-prone Polymerase ζ. A second assumption I show to be violated is that the mutation rate has not changed over time and is constant across populations. I show this indirectly by demon- strating that C→T transitions, particularly in the context TCC→TTC, are more frequent in Europeans than in other populations. Although it is not clear whether this mutation rate change was functionally significant or driven by selection, it demonstrates that the process of genome evolution has not stayed constant during recent human history, but has been regionally differentiated by the forces that shape our primary genome sequences.

Published
2015

47. Mutationathon: towards standardization in estimates of pedigree-based germline mutation rates

Author

Bergeron, Lucie A., primary, Besenbacher, Søren, additional, Turner, Tychele N., additional, Versoza, Cyril J., additional, Wang, Richard J., additional, Price, Alivia Lee, additional, Armstrong, Ellie, additional, Riera, Meritxell, additional, Carlson, Jedidiah, additional, Chen, Hwei-yen, additional, Hahn, Matthew W., additional, Harris, Kelley, additional, Snøfrid Lo Natalie M Kleppe, April, additional, López-Nandam, Elora H., additional, Moorjani, Priya, additional, Pfeifer, Susanne P., additional, Tiley, George P., additional, Yoder, Anne D., additional, Zhang, Guojie, additional, and Schierup, Mikkel H., additional

Published
2021
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