Your search keyword '"Ryder OA"' showing total 207 results

1. Inference of Gorilla Demographic and Selective History from Whole-Genome Sequence Data

Author

Wall, Jeffrey, McManus, KF, Kelley, JL, Song, S, Veeramah, KR, Woerner, AE, Stevison, LS, Ryder, OA, Kidd, JM, Wall, JD, and Bustamante, CD

Published

2015

2. A comparative genomics multitool for scientific discovery and conservation

Author

Massachusetts Institute of Technology. Department of Biology, Genereux, DP, Serres, A, Armstrong, J, Johnson, J, Marinescu, VD, Muren, E, Juan, D, Bejerano, G, Casewell, NR, Chemnick, LG, Damas, J, Di Palma, F, Diekhans, M, Fiddes, IT, Garber, M, Gladyshev, NV, Goodman, L, Haerty, W, Houck, ML, Hubley, R, Kivioja, T, Koepfli, KP, Kuderna, LFK, Lander, Eric Steven, Meadows, JRS, Murphy, WJ, Nash, W, Noh, HJ, Nweeia, M, Pfenning, AR, Pollard, KS, Ray, DA, Shapiro, B, Smit, AFA, Springer, MS, Steiner, CC, Swofford, R, Taipale, J, Teeling, EC, Turner-Maier, J, Alfoldi, J, Birren, B, Ryder, OA, Lewin, HA, Paten, B, Marques-Bonet, T, Lindblad-Toh, K, Karlsson, EK, Massachusetts Institute of Technology. Department of Biology, Genereux, DP, Serres, A, Armstrong, J, Johnson, J, Marinescu, VD, Muren, E, Juan, D, Bejerano, G, Casewell, NR, Chemnick, LG, Damas, J, Di Palma, F, Diekhans, M, Fiddes, IT, Garber, M, Gladyshev, NV, Goodman, L, Haerty, W, Houck, ML, Hubley, R, Kivioja, T, Koepfli, KP, Kuderna, LFK, Lander, Eric Steven, Meadows, JRS, Murphy, WJ, Nash, W, Noh, HJ, Nweeia, M, Pfenning, AR, Pollard, KS, Ray, DA, Shapiro, B, Smit, AFA, Springer, MS, Steiner, CC, Swofford, R, Taipale, J, Teeling, EC, Turner-Maier, J, Alfoldi, J, Birren, B, Ryder, OA, Lewin, HA, Paten, B, Marques-Bonet, T, Lindblad-Toh, K, and Karlsson, EK

Abstract

© 2020, The Author(s). The Zoonomia Project is investigating the genomics of shared and specialized traits in eutherian mammals. Here we provide genome assemblies for 131 species, of which all but 9 are previously uncharacterized, and describe a whole-genome alignment of 240 species of considerable phylogenetic diversity, comprising representatives from more than 80% of mammalian families. We find that regions of reduced genetic diversity are more abundant in species at a high risk of extinction, discern signals of evolutionary selection at high resolution and provide insights from individual reference genomes. By prioritizing phylogenetic diversity and making data available quickly and without restriction, the Zoonomia Project aims to support biological discovery, medical research and the conservation of biodiversity.

Published

2022

3. Platypus and echidna genomes reveal mammalian biology and evolution

Author

Zhou, Y, Shearwin-Whyatt, L, Li, J, Song, Z, Hayakawa, T, Stevens, D, Fenelon, JC, Peel, E, Cheng, Y, Pajpach, F, Bradley, N, Suzuki, H, Nikaido, M, Damas, J, Daish, T, Perry, T, Zhu, Z, Geng, Y, Rhie, A, Sims, Y, Wood, J, Haase, B, Mountcastle, J, Fedrigo, O, Li, Q, Yang, H, Wang, J, Johnston, SD, Phillippy, AM, Howe, K, Jarvis, ED, Ryder, OA, Kaessmann, H, Donnelly, P, Korlach, J, Lewin, HA, Graves, J, Belov, K, Renfree, MB, Grutzner, F, Zhou, Q, Zhang, G, Zhou, Y, Shearwin-Whyatt, L, Li, J, Song, Z, Hayakawa, T, Stevens, D, Fenelon, JC, Peel, E, Cheng, Y, Pajpach, F, Bradley, N, Suzuki, H, Nikaido, M, Damas, J, Daish, T, Perry, T, Zhu, Z, Geng, Y, Rhie, A, Sims, Y, Wood, J, Haase, B, Mountcastle, J, Fedrigo, O, Li, Q, Yang, H, Wang, J, Johnston, SD, Phillippy, AM, Howe, K, Jarvis, ED, Ryder, OA, Kaessmann, H, Donnelly, P, Korlach, J, Lewin, HA, Graves, J, Belov, K, Renfree, MB, Grutzner, F, Zhou, Q, and Zhang, G

Abstract

Egg-laying mammals (monotremes) are the only extant mammalian outgroup to therians (marsupial and eutherian animals) and provide key insights into mammalian evolution1,2. Here we generate and analyse reference genomes of the platypus (Ornithorhynchus anatinus) and echidna (Tachyglossus aculeatus), which represent the only two extant monotreme lineages. The nearly complete platypus genome assembly has anchored almost the entire genome onto chromosomes, markedly improving the genome continuity and gene annotation. Together with our echidna sequence, the genomes of the two species allow us to detect the ancestral and lineage-specific genomic changes that shape both monotreme and mammalian evolution. We provide evidence that the monotreme sex chromosome complex originated from an ancestral chromosome ring configuration. The formation of such a unique chromosome complex may have been facilitated by the unusually extensive interactions between the multi-X and multi-Y chromosomes that are shared by the autosomal homologues in humans. Further comparative genomic analyses unravel marked differences between monotremes and therians in haptoglobin genes, lactation genes and chemosensory receptor genes for smell and taste that underlie the ecological adaptation of monotremes.

Published

2021

4. Dense sampling of bird diversity increases power of comparative genomics (vol 587, pg 252, 2020)

Author

Feng, S, Stiller, J, Deng, Y, Armstrong, J, Fang, Q, Reeve, AH, Xie, D, Chen, G, Guo, C, Faircloth, BC, Petersen, B, Wang, Z, Zhou, Q, Diekhans, M, Chen, W, Andreu-Sanchez, S, Margaryan, A, Howard, JT, Parent, C, Pacheco, G, Sinding, M-HS, Puetz, L, Cavill, E, Ribeiro, AM, Eckhart, L, Fjeldsa, J, Hosner, PA, Brumfield, RT, Christidis, L, Bertelsen, MF, Sicheritz-Ponten, T, Tietze, DT, Robertson, BC, Song, G, Borgia, G, Claramunt, S, Lovette, IJ, Cowen, SJ, Njoroge, P, Dumbacher, JP, Ryder, OA, Fuchs, J, Bunce, M, Burt, DW, Cracraft, J, Meng, G, Hackett, SJ, Ryan, PG, Jonsson, KA, Jamieson, IG, da Fonseca, RR, Braun, EL, Houde, P, Mirarab, S, Suh, A, Hansson, B, Ponnikas, S, Sigeman, H, Stervander, M, Frandsen, PB, van der Zwan, H, van der Sluis, R, Visser, C, Balakrishnan, CN, Clark, AG, Fitzpatrick, JW, Bowman, R, Chen, N, Cloutier, A, Sackton, TB, Edwards, SV, Foote, DJ, Shakya, SB, Sheldon, FH, Vignal, A, Soares, AER, Shapiro, B, Gonzalez-Solis, J, Ferrer-Obiol, J, Rozas, J, Riutort, M, Tigano, A, Friesen, V, Dalen, L, Urrutia, AO, Szekely, T, Liu, Y, Campana, MG, Corvelo, A, Fleischer, RC, Rutherford, KM, Gemmell, NJ, Dussex, N, Mouritsen, H, Thiele, N, Delmore, K, Liedvogel, M, Franke, A, Hoeppner, MP, Krone, O, Fudickar, AM, Mila, B, Ketterson, ED, Fidler, AE, Friis, G, Parody-Merino, AM, Battley, PF, Cox, MP, Lima, NCB, Prosdocimi, F, Parchman, TL, Schlinger, BA, Loiselle, BA, Blake, JG, Lim, HC, Day, LB, Fuxjager, MJ, Baldwin, MW, Braun, MJ, Wirthlin, M, Dikow, RB, Ryder, TB, Camenisch, G, Keller, LF, DaCosta, JM, Hauber, ME, Louder, MIM, Witt, CC, McGuire, JA, Mudge, J, Megna, LC, Carling, MD, Wang, B, Taylor, SA, Del-Rio, G, Aleixo, A, Vasconcelos, ATR, Mello, CV, Weir, JT, Haussler, D, Li, Q, Yang, H, Wang, J, Lei, F, Rahbek, C, Gilbert, MTP, Graves, GR, Jarvis, ED, Paten, B, Zhang, G, Feng, S, Stiller, J, Deng, Y, Armstrong, J, Fang, Q, Reeve, AH, Xie, D, Chen, G, Guo, C, Faircloth, BC, Petersen, B, Wang, Z, Zhou, Q, Diekhans, M, Chen, W, Andreu-Sanchez, S, Margaryan, A, Howard, JT, Parent, C, Pacheco, G, Sinding, M-HS, Puetz, L, Cavill, E, Ribeiro, AM, Eckhart, L, Fjeldsa, J, Hosner, PA, Brumfield, RT, Christidis, L, Bertelsen, MF, Sicheritz-Ponten, T, Tietze, DT, Robertson, BC, Song, G, Borgia, G, Claramunt, S, Lovette, IJ, Cowen, SJ, Njoroge, P, Dumbacher, JP, Ryder, OA, Fuchs, J, Bunce, M, Burt, DW, Cracraft, J, Meng, G, Hackett, SJ, Ryan, PG, Jonsson, KA, Jamieson, IG, da Fonseca, RR, Braun, EL, Houde, P, Mirarab, S, Suh, A, Hansson, B, Ponnikas, S, Sigeman, H, Stervander, M, Frandsen, PB, van der Zwan, H, van der Sluis, R, Visser, C, Balakrishnan, CN, Clark, AG, Fitzpatrick, JW, Bowman, R, Chen, N, Cloutier, A, Sackton, TB, Edwards, SV, Foote, DJ, Shakya, SB, Sheldon, FH, Vignal, A, Soares, AER, Shapiro, B, Gonzalez-Solis, J, Ferrer-Obiol, J, Rozas, J, Riutort, M, Tigano, A, Friesen, V, Dalen, L, Urrutia, AO, Szekely, T, Liu, Y, Campana, MG, Corvelo, A, Fleischer, RC, Rutherford, KM, Gemmell, NJ, Dussex, N, Mouritsen, H, Thiele, N, Delmore, K, Liedvogel, M, Franke, A, Hoeppner, MP, Krone, O, Fudickar, AM, Mila, B, Ketterson, ED, Fidler, AE, Friis, G, Parody-Merino, AM, Battley, PF, Cox, MP, Lima, NCB, Prosdocimi, F, Parchman, TL, Schlinger, BA, Loiselle, BA, Blake, JG, Lim, HC, Day, LB, Fuxjager, MJ, Baldwin, MW, Braun, MJ, Wirthlin, M, Dikow, RB, Ryder, TB, Camenisch, G, Keller, LF, DaCosta, JM, Hauber, ME, Louder, MIM, Witt, CC, McGuire, JA, Mudge, J, Megna, LC, Carling, MD, Wang, B, Taylor, SA, Del-Rio, G, Aleixo, A, Vasconcelos, ATR, Mello, CV, Weir, JT, Haussler, D, Li, Q, Yang, H, Wang, J, Lei, F, Rahbek, C, Gilbert, MTP, Graves, GR, Jarvis, ED, Paten, B, and Zhang, G

Abstract

A Correction to this paper has been published: https://doi.org/10.1038/s41586-021-03473-8.

Published

2021

5. Dense sampling of bird diversity increases power of comparative genomics

Author

Feng, S, Stiller, J, Deng, Y, Armstrong, J, Fang, Q, Reeve, AH, Xie, D, Chen, G, Guo, C, Faircloth, BC, Petersen, B, Wang, Z, Zhou, Q, Diekhans, M, Chen, W, Andreu-Sanchez, S, Margaryan, A, Howard, JT, Parent, C, Pacheco, G, Sinding, M-HS, Puetz, L, Cavill, E, Ribeiro, AM, Eckhart, L, Fjeldsa, J, Hosner, PA, Brumfield, RT, Christidis, L, Bertelsen, MF, Sicheritz-Ponten, T, Tietze, DT, Robertson, BC, Song, G, Borgia, G, Claramunt, S, Lovette, IJ, Cowen, SJ, Njoroge, P, Dumbacher, JP, Ryder, OA, Fuchs, J, Bunce, M, Burt, DW, Cracraft, J, Meng, G, Hackett, SJ, Ryan, PG, Jonsson, KA, Jamieson, IG, da Fonseca, RR, Braun, EL, Houde, P, Mirarab, S, Suh, A, Hansson, B, Ponnikas, S, Sigeman, H, Stervander, M, Frandsen, PB, van der Zwan, H, van der Sluis, R, Visser, C, Balakrishnan, CN, Clark, AG, Fitzpatrick, JW, Bowman, R, Chen, N, Cloutier, A, Sackton, TB, Edwards, SV, Foote, DJ, Shakya, SB, Sheldon, FH, Vignal, A, Soares, AER, Shapiro, B, Gonzalez-Solis, J, Ferrer-Obiol, J, Rozas, J, Riutort, M, Tigano, A, Friesen, V, Dalen, L, Urrutia, AO, Szekely, T, Liu, Y, Campana, MG, Corvelo, A, Fleischer, RC, Rutherford, KM, Gemmell, NJ, Dussex, N, Mouritsen, H, Thiele, N, Delmore, K, Liedvogel, M, Franke, A, Hoeppner, MP, Krone, O, Fudickar, AM, Mila, B, Ketterson, ED, Fidler, AE, Friis, G, Parody-Merino, AM, Battley, PF, Cox, MP, Lima, NCB, Prosdocimi, F, Parchman, TL, Schlinger, BA, Loiselle, BA, Blake, JG, Lim, HC, Day, LB, Fuxjager, MJ, Baldwin, MW, Braun, MJ, Wirthlin, M, Dikow, RB, Ryder, TB, Camenisch, G, Keller, LF, DaCosta, JM, Hauber, ME, Louder, MIM, Witt, CC, McGuire, JA, Mudge, J, Megna, LC, Carling, MD, Wang, B, Taylor, SA, Del-Rio, G, Aleixo, A, Vasconcelos, ATR, Mello, CV, Weir, JT, Haussler, D, Li, Q, Yang, H, Wang, J, Lei, F, Rahbek, C, Gilbert, MTP, Graves, GR, Jarvis, ED, Paten, B, Zhang, G, Feng, S, Stiller, J, Deng, Y, Armstrong, J, Fang, Q, Reeve, AH, Xie, D, Chen, G, Guo, C, Faircloth, BC, Petersen, B, Wang, Z, Zhou, Q, Diekhans, M, Chen, W, Andreu-Sanchez, S, Margaryan, A, Howard, JT, Parent, C, Pacheco, G, Sinding, M-HS, Puetz, L, Cavill, E, Ribeiro, AM, Eckhart, L, Fjeldsa, J, Hosner, PA, Brumfield, RT, Christidis, L, Bertelsen, MF, Sicheritz-Ponten, T, Tietze, DT, Robertson, BC, Song, G, Borgia, G, Claramunt, S, Lovette, IJ, Cowen, SJ, Njoroge, P, Dumbacher, JP, Ryder, OA, Fuchs, J, Bunce, M, Burt, DW, Cracraft, J, Meng, G, Hackett, SJ, Ryan, PG, Jonsson, KA, Jamieson, IG, da Fonseca, RR, Braun, EL, Houde, P, Mirarab, S, Suh, A, Hansson, B, Ponnikas, S, Sigeman, H, Stervander, M, Frandsen, PB, van der Zwan, H, van der Sluis, R, Visser, C, Balakrishnan, CN, Clark, AG, Fitzpatrick, JW, Bowman, R, Chen, N, Cloutier, A, Sackton, TB, Edwards, SV, Foote, DJ, Shakya, SB, Sheldon, FH, Vignal, A, Soares, AER, Shapiro, B, Gonzalez-Solis, J, Ferrer-Obiol, J, Rozas, J, Riutort, M, Tigano, A, Friesen, V, Dalen, L, Urrutia, AO, Szekely, T, Liu, Y, Campana, MG, Corvelo, A, Fleischer, RC, Rutherford, KM, Gemmell, NJ, Dussex, N, Mouritsen, H, Thiele, N, Delmore, K, Liedvogel, M, Franke, A, Hoeppner, MP, Krone, O, Fudickar, AM, Mila, B, Ketterson, ED, Fidler, AE, Friis, G, Parody-Merino, AM, Battley, PF, Cox, MP, Lima, NCB, Prosdocimi, F, Parchman, TL, Schlinger, BA, Loiselle, BA, Blake, JG, Lim, HC, Day, LB, Fuxjager, MJ, Baldwin, MW, Braun, MJ, Wirthlin, M, Dikow, RB, Ryder, TB, Camenisch, G, Keller, LF, DaCosta, JM, Hauber, ME, Louder, MIM, Witt, CC, McGuire, JA, Mudge, J, Megna, LC, Carling, MD, Wang, B, Taylor, SA, Del-Rio, G, Aleixo, A, Vasconcelos, ATR, Mello, CV, Weir, JT, Haussler, D, Li, Q, Yang, H, Wang, J, Lei, F, Rahbek, C, Gilbert, MTP, Graves, GR, Jarvis, ED, Paten, B, and Zhang, G

Abstract

Whole-genome sequencing projects are increasingly populating the tree of life and characterizing biodiversity1-4. Sparse taxon sampling has previously been proposed to confound phylogenetic inference5, and captures only a fraction of the genomic diversity. Here we report a substantial step towards the dense representation of avian phylogenetic and molecular diversity, by analysing 363 genomes from 92.4% of bird families-including 267 newly sequenced genomes produced for phase II of the Bird 10,000 Genomes (B10K) Project. We use this comparative genome dataset in combination with a pipeline that leverages a reference-free whole-genome alignment to identify orthologous regions in greater numbers than has previously been possible and to recognize genomic novelties in particular bird lineages. The densely sampled alignment provides a single-base-pair map of selection, has more than doubled the fraction of bases that are confidently predicted to be under conservation and reveals extensive patterns of weak selection in predominantly non-coding DNA. Our results demonstrate that increasing the diversity of genomes used in comparative studies can reveal more shared and lineage-specific variation, and improve the investigation of genomic characteristics. We anticipate that this genomic resource will offer new perspectives on evolutionary processes in cross-species comparative analyses and assist in efforts to conserve species.

Published

2020

6. Genome sequence, comparative analysis and population genetics of the domestic horse (Equus caballus)

Author

Wade, CM, Giulotto, E, Sigurdsson, S, Zoli, M, Gnerre, S, Imsland, F, Lear, TL, Adelson, DL, Bailey, E, Bellone, RR, Blöcker, H, Distl, O, Edgar, RC, Garber, M, Leeb, T, Mauceli, E, MacLeod, JN, Penedo, MCT, Raison, JM, Sharpe, T, Vogel, J, Andersson, L, Antczak, DF, Biagi, T, Binns, MM, Chowdhary, BP, Coleman, SJ, Della Valle, G, Fryc, S, Guérin, G, Hasegawa, T, Hill, EW, Jurka, J, Kiialainen, A, Lindgren, G, Liu, J, Magnani, E, Mickelson, JR, Murray, J, Nergadze, SG, Onofrio, R, Pedroni, S, Piras, MF, Raudsepp, T, Rocchi, M, Røed, KH, Ryder, OA, Searle, S, Skow, L, Swinburne, JE, Syvänen, AC, Tozaki, T, Valberg, SJ, Vaudin, M, White, JR, Zody, MC, Lander, ES, and Lindblad-Toh, K

Subjects

Genome, DNA Copy Number Variations, Centromere, Molecular Sequence Data, Chromosome Mapping, Computational Biology, Sequence Analysis, DNA, Chromosomes, Mammalian, Synteny, Article, Evolution, Molecular, Dogs, Genes, Haplotypes, Animals, Domestic, Animals, Humans, Female, Horses, Phylogeny, Repetitive Sequences, Nucleic Acid

Abstract

We report a high-quality draft sequence of the genome of the horse (Equus caballus). The genome is relatively repetitive, but has little segmental duplication. Chromosomes appear to have undergone few historical rearrangements – 48% of equine chromosomes show conserved synteny to a single human chromosome. Equine chromosome 11 is shown to have an evolutionary novel centromere devoid of centromeric satellite DNA, suggesting that centromeric function may arise prior to satellite repeat accumulation. Linkage disequilibrium, showing the influences of early domestication of large herds of female horses, is intermediate in length between dog and human, and there is long-range haplotype sharing among breeds.

Published

2009

7. Brief communication. Centric fusion polymorphisms in waterbuck (Kobus ellipsiprymnus)

Author

Kingswood, SC, primary, Kumamoto, AT, additional, Charter, SJ, additional, Aman, RA, additional, and Ryder, OA, additional

Published

1998

8. Analysis of Relatedness in the California Condors, from DNA Fingerprints

Author

Geyer, CJ, Ryder, OA, Chemnick, LG, and Thompson, EA

Published

1993

9. Advancing stem cell technologies for conservation of wildlife biodiversity.

Author

Hutchinson AM, Appeltant R, Burdon T, Bao Q, Bargaje R, Bodnar A, Chambers S, Comizzoli P, Cook L, Endo Y, Harman B, Hayashi K, Hildebrandt T, Korody ML, Lakshmipathy U, Loring JF, Munger C, Ng AHM, Novak B, Onuma M, Ord S, Paris M, Pask AJ, Pelegri F, Pera M, Phelan R, Rosental B, Ryder OA, Sukparangsi W, Sullivan G, Tay NL, Traylor-Knowles N, Walker S, Weberling A, Whitworth DJ, Williams SA, Wojtusik J, Wu J, Ying QL, Zwaka TP, and Kohler TN

Subjects

Animals, Stem Cells cytology, Animals, Wild, Biodiversity, Conservation of Natural Resources methods, Stem Cell Research

Abstract

Wildlife biodiversity is essential for healthy, resilient and sustainable ecosystems. For biologists, this diversity also represents a treasure trove of genetic, molecular and developmental mechanisms that deepen our understanding of the origins and rules of life. However, the rapid decline in biodiversity reported recently foreshadows a potentially catastrophic collapse of many important ecosystems and the associated irreversible loss of many forms of life on our planet. Immediate action by conservationists of all stripes is required to avert this disaster. In this Spotlight, we draw together insights and proposals discussed at a recent workshop hosted by Revive & Restore, which gathered experts to discuss how stem cell technologies can support traditional conservation techniques and help protect animal biodiversity. We discuss reprogramming, in vitro gametogenesis, disease modelling and embryo modelling, and we highlight the prospects for leveraging stem cell technologies beyond mammalian species., Competing Interests: Competing interests A.M.H. is program manager at Revive and Restore; R.B. is an Associate Director at Conception; S.C. is CEO of Brightfield Therapeutics; A.N. is a co-founder and Chief Scientific Officer of and has equity in GC Therapeutics; S.O. is Director of Species Restoration at Colossal Laboratories and Biosciences; A.J.P. is a Species-lead for Colossal Laboratories and Biosciences.; R.P. is executive director and co-founder of Revive and Restore; G.S. is CSO and co-founder at Occam Biosciences; T.N.K. is a contract employee for Colossal Laboratories and Biosciences., (© 2024. Published by The Company of Biologists Ltd.)

Published

2024

10. Complete sequencing of ape genomes.

Author

Yoo D, Rhie A, Hebbar P, Antonacci F, Logsdon GA, Solar SJ, Antipov D, Pickett BD, Safonova Y, Montinaro F, Luo Y, Malukiewicz J, Storer JM, Lin J, Sequeira AN, Mangan RJ, Hickey G, Anez GM, Balachandran P, Bankevich A, Beck CR, Biddanda A, Borchers M, Bouffard GG, Brannan E, Brooks SY, Carbone L, Carrel L, Chan AP, Crawford J, Diekhans M, Engelbrecht E, Feschotte C, Formenti G, Garcia GH, de Gennaro L, Gilbert D, Green RE, Guarracino A, Gupta I, Haddad D, Han J, Harris RS, Hartley GA, Harvey WT, Hiller M, Hoekzema K, Houck ML, Jeong H, Kamali K, Kellis M, Kille B, Lee C, Lee Y, Lees W, Lewis AP, Li Q, Loftus M, Loh YHE, Loucks H, Ma J, Mao Y, Martinez JFI, Masterson P, McCoy RC, McGrath B, McKinney S, Meyer BS, Miga KH, Mohanty SK, Munson KM, Pal K, Pennell M, Pevzner PA, Porubsky D, Potapova T, Ringeling FR, Roha JL, Ryder OA, Sacco S, Saha S, Sasaki T, Schatz MC, Schork NJ, Shanks C, Smeds L, Son DR, Steiner C, Sweeten AP, Tassia MG, Thibaud-Nissen F, Torres-González E, Trivedi M, Wei W, Wertz J, Yang M, Zhang P, Zhang S, Zhang Y, Zhang Z, Zhao SA, Zhu Y, Jarvis ED, Gerton JL, Rivas-González I, Paten B, Szpiech ZA, Huber CD, Lenz TL, Konkel MK, Yi SV, Canzar S, Watson CT, Sudmant PH, Molloy E, Garrison E, Lowe CB, Ventura M, O'Neill RJ, Koren S, Makova KD, Phillippy AM, and Eichler EE

Abstract

We present haplotype-resolved reference genomes and comparative analyses of six ape species, namely: chimpanzee, bonobo, gorilla, Bornean orangutan, Sumatran orangutan, and siamang. We achieve chromosome-level contiguity with unparalleled sequence accuracy (<1 error in 500,000 base pairs), completely sequencing 215 gapless chromosomes telomere-to-telomere. We resolve challenging regions, such as the major histocompatibility complex and immunoglobulin loci, providing more in-depth evolutionary insights. Comparative analyses, including human, allow us to investigate the evolution and diversity of regions previously uncharacterized or incompletely studied without bias from mapping to the human reference. This includes newly minted gene families within lineage-specific segmental duplications, centromeric DNA, acrocentric chromosomes, and subterminal heterochromatin. This resource should serve as a definitive baseline for all future evolutionary studies of humans and our closest living ape relatives., Competing Interests: COMPETING INTERESTS E.E.E. is a scientific advisory board (SAB) member of Variant Bio, Inc. C.T.W. is a co-founder/CSO of Clareo Biosciences, Inc. W.L. is a co-founder/CIO of Clareo Biosciences, Inc. The other authors declare no competing interests.

Published

2024

11. Unraveling the genomic diversity and admixture history of captive tigers in the United States.

Author

Armstrong EE, Mooney JA, Solari KA, Kim BY, Barsh GS, Grant VB, Greenbaum G, Kaelin CB, Panchenko K, Pickrell JK, Rosenberg N, Ryder OA, Yokoyama T, Ramakrishnan U, Petrov DA, and Hadly EA

Subjects

Animals, United States, Phylogeny, Conservation of Natural Resources, Genomics methods, Genome genetics, Animals, Zoo genetics, Tigers genetics, Tigers classification, Genetic Variation, Endangered Species

Abstract

Genomic studies of endangered species have primarily focused on describing diversity patterns and resolving phylogenetic relationships, with the overarching goal of informing conservation efforts. However, few studies have investigated genomic diversity housed in captive populations. For tigers ( Panthera tigris ), captive individuals vastly outnumber those in the wild, but their diversity remains largely unexplored. Privately owned captive tiger populations have remained an enigma in the conservation community, with some believing that these individuals are severely inbred, while others believe they may be a source of now-extinct diversity. Here, we present a large-scale genetic study of the private (non-zoo) captive tiger population in the United States, also known as "Generic" tigers. We find that the Generic tiger population has an admixture fingerprint comprising all six extant wild tiger subspecies. Of the 138 Generic individuals sequenced for the purpose of this study, no individual had ancestry from only one subspecies. We show that the Generic tiger population has a comparable amount of genetic diversity relative to most wild subspecies, few private variants, and fewer deleterious mutations. We observe inbreeding coefficients similar to wild populations, although there are some individuals within both the Generic and wild populations that are substantially inbred. Additionally, we develop a reference panel for tigers that can be used with imputation to accurately distinguish individuals and assign ancestry with ultralow coverage (0.25×) data. By providing a cost-effective alternative to whole-genome sequencing (WGS), the reference panel provides a resource to assist in tiger conservation efforts for both ex- and in situ populations., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

12. The complete sequence and comparative analysis of ape sex chromosomes.

Author

Makova KD, Pickett BD, Harris RS, Hartley GA, Cechova M, Pal K, Nurk S, Yoo D, Li Q, Hebbar P, McGrath BC, Antonacci F, Aubel M, Biddanda A, Borchers M, Bornberg-Bauer E, Bouffard GG, Brooks SY, Carbone L, Carrel L, Carroll A, Chang PC, Chin CS, Cook DE, Craig SJC, de Gennaro L, Diekhans M, Dutra A, Garcia GH, Grady PGS, Green RE, Haddad D, Hallast P, Harvey WT, Hickey G, Hillis DA, Hoyt SJ, Jeong H, Kamali K, Pond SLK, LaPolice TM, Lee C, Lewis AP, Loh YE, Masterson P, McGarvey KM, McCoy RC, Medvedev P, Miga KH, Munson KM, Pak E, Paten B, Pinto BJ, Potapova T, Rhie A, Rocha JL, Ryabov F, Ryder OA, Sacco S, Shafin K, Shepelev VA, Slon V, Solar SJ, Storer JM, Sudmant PH, Sweetalana, Sweeten A, Tassia MG, Thibaud-Nissen F, Ventura M, Wilson MA, Young AC, Zeng H, Zhang X, Szpiech ZA, Huber CD, Gerton JL, Yi SV, Schatz MC, Alexandrov IA, Koren S, O'Neill RJ, Eichler EE, and Phillippy AM

Subjects

Animals, Female, Male, Gorilla gorilla genetics, Hylobatidae genetics, Pan paniscus genetics, Pan troglodytes genetics, Phylogeny, Pongo abelii genetics, Pongo pygmaeus genetics, Telomere genetics, Evolution, Molecular, DNA Copy Number Variations genetics, Humans, Endangered Species, Reference Standards, Hominidae genetics, Hominidae classification, X Chromosome genetics, Y Chromosome genetics

Abstract

Apes possess two sex chromosomes-the male-specific Y chromosome and the X chromosome, which is present in both males and females. The Y chromosome is crucial for male reproduction, with deletions being linked to infertility 1 . The X chromosome is vital for reproduction and cognition 2 . Variation in mating patterns and brain function among apes suggests corresponding differences in their sex chromosomes. However, owing to their repetitive nature and incomplete reference assemblies, ape sex chromosomes have been challenging to study. Here, using the methodology developed for the telomere-to-telomere (T2T) human genome, we produced gapless assemblies of the X and Y chromosomes for five great apes (bonobo (Pan paniscus), chimpanzee (Pan troglodytes), western lowland gorilla (Gorilla gorilla gorilla), Bornean orangutan (Pongo pygmaeus) and Sumatran orangutan (Pongo abelii)) and a lesser ape (the siamang gibbon (Symphalangus syndactylus)), and untangled the intricacies of their evolution. Compared with the X chromosomes, the ape Y chromosomes vary greatly in size and have low alignability and high levels of structural rearrangements-owing to the accumulation of lineage-specific ampliconic regions, palindromes, transposable elements and satellites. Many Y chromosome genes expand in multi-copy families and some evolve under purifying selection. Thus, the Y chromosome exhibits dynamic evolution, whereas the X chromosome is more stable. Mapping short-read sequencing data to these assemblies revealed diversity and selection patterns on sex chromosomes of more than 100 individual great apes. These reference assemblies are expected to inform human evolution and conservation genetics of non-human apes, all of which are endangered species., (© 2024. The Author(s).)

Published

2024

13. Genetic load and viability of a future restored northern white rhino population.

Author

Wilder AP, Steiner CC, Hendricks S, Haller BC, Kim C, Korody ML, and Ryder OA

Abstract

As biodiversity loss outpaces recovery, conservationists are increasingly turning to novel tools for preventing extinction, including cloning and in vitro gametogenesis of biobanked cells. However, restoration of populations can be hindered by low genetic diversity and deleterious genetic load. The persistence of the northern white rhino ( Ceratotherium simum cottoni ) now depends on the cryopreserved cells of 12 individuals. These banked genomes have higher genetic diversity than southern white rhinos ( C. s. simum ), a sister subspecies that successfully recovered from a severe bottleneck, but the potential impact of genetic load is unknown. We estimated how demographic history has shaped genome-wide genetic load in nine northern and 13 southern white rhinos. The bottleneck left southern white rhinos with more fixed and homozygous deleterious alleles and longer runs of homozygosity, whereas northern white rhinos retained more deleterious alleles masked in heterozygosity. To gauge the impact of genetic load on the fitness of a northern white rhino population restored from biobanked cells, we simulated recovery using fitness of southern white rhinos as a benchmark for a viable population. Unlike traditional restoration, cell-derived founders can be reintroduced in subsequent generations to boost lost genetic diversity and relieve inbreeding. In simulations with repeated reintroduction of founders into a restored population, the fitness cost of genetic load remained lower than that borne by southern white rhinos. Without reintroductions, rapid growth of the restored population (>20-30% per generation) would be needed to maintain comparable fitness. Our results suggest that inbreeding depression from genetic load is not necessarily a barrier to recovery of the northern white rhino and demonstrate how restoration from biobanked cells relieves some constraints of conventional restoration from a limited founder pool. Established conservation methods that protect healthy populations will remain paramount, but emerging technologies hold promise to bolster these tools to combat the extinction crisis., Competing Interests: The authors have no conflicts of interest to disclose., (© 2024 The Authors. Evolutionary Applications published by John Wiley & Sons Ltd.)

Published

2024

14. Vocal learning-associated convergent evolution in mammalian proteins and regulatory elements.

Author

Wirthlin ME, Schmid TA, Elie JE, Zhang X, Kowalczyk A, Redlich R, Shvareva VA, Rakuljic A, Ji MB, Bhat NS, Kaplow IM, Schäffer DE, Lawler AJ, Wang AZ, Phan BN, Annaldasula S, Brown AR, Lu T, Lim BK, Azim E, Clark NL, Meyer WK, Pond SLK, Chikina M, Yartsev MM, Pfenning AR, Andrews G, Armstrong JC, Bianchi M, Birren BW, Bredemeyer KR, Breit AM, Christmas MJ, Clawson H, Damas J, Di Palma F, Diekhans M, Dong MX, Eizirik E, Fan K, Fanter C, Foley NM, Forsberg-Nilsson K, Garcia CJ, Gatesy J, Gazal S, Genereux DP, Goodman L, Grimshaw J, Halsey MK, Harris AJ, Hickey G, Hiller M, Hindle AG, Hubley RM, Hughes GM, Johnson J, Juan D, Kaplow IM, Karlsson EK, Keough KC, Kirilenko B, Koepfli KP, Korstian JM, Kowalczyk A, Kozyrev SV, Lawler AJ, Lawless C, Lehmann T, Levesque DL, Lewin HA, Li X, Lind A, Lindblad-Toh K, Mackay-Smith A, Marinescu VD, Marques-Bonet T, Mason VC, Meadows JRS, Meyer WK, Moore JE, Moreira LR, Moreno-Santillan DD, Morrill KM, Muntané G, Murphy WJ, Navarro A, Nweeia M, Ortmann S, Osmanski A, Paten B, Paulat NS, Pfenning AR, Phan BN, Pollard KS, Pratt HE, Ray DA, Reilly SK, Rosen JR, Ruf I, Ryan L, Ryder OA, Sabeti PC, Schäffer DE, Serres A, Shapiro B, Smit AFA, Springer M, Srinivasan C, Steiner C, Storer JM, Sullivan KAM, Sullivan PF, Sundström E, Supple MA, Swofford R, Talbot JE, Teeling E, Turner-Maier J, Valenzuela A, Wagner F, Wallerman O, Wang C, Wang J, Weng Z, Wilder AP, Wirthlin ME, Xue JR, and Zhang X

Subjects

Animals, Chiroptera genetics, Chiroptera physiology, Chromatin metabolism, Larynx physiology, Epigenesis, Genetic, Genome, Amino Acid Sequence, Machine Learning, Vocalization, Animal physiology, Motor Cortex cytology, Motor Cortex physiology, Enhancer Elements, Genetic, Motor Neurons physiology, Gene Expression Regulation, Evolution, Molecular, Proteins genetics, Proteins metabolism, Eutheria genetics, Eutheria physiology

Abstract

Vocal production learning ("vocal learning") is a convergently evolved trait in vertebrates. To identify brain genomic elements associated with mammalian vocal learning, we integrated genomic, anatomical, and neurophysiological data from the Egyptian fruit bat ( Rousettus aegyptiacus ) with analyses of the genomes of 215 placental mammals. First, we identified a set of proteins evolving more slowly in vocal learners. Then, we discovered a vocal motor cortical region in the Egyptian fruit bat, an emergent vocal learner, and leveraged that knowledge to identify active cis-regulatory elements in the motor cortex of vocal learners. Machine learning methods applied to motor cortex open chromatin revealed 50 enhancers robustly associated with vocal learning whose activity tended to be lower in vocal learners. Our research implicates convergent losses of motor cortex regulatory elements in mammalian vocal learning evolution.

Published

2024

15. The Complete Sequence and Comparative Analysis of Ape Sex Chromosomes.

Author

Makova KD, Pickett BD, Harris RS, Hartley GA, Cechova M, Pal K, Nurk S, Yoo D, Li Q, Hebbar P, McGrath BC, Antonacci F, Aubel M, Biddanda A, Borchers M, Bomberg E, Bouffard GG, Brooks SY, Carbone L, Carrel L, Carroll A, Chang PC, Chin CS, Cook DE, Craig SJC, de Gennaro L, Diekhans M, Dutra A, Garcia GH, Grady PGS, Green RE, Haddad D, Hallast P, Harvey WT, Hickey G, Hillis DA, Hoyt SJ, Jeong H, Kamali K, Kosakovsky Pond SL, LaPolice TM, Lee C, Lewis AP, Loh YE, Masterson P, McCoy RC, Medvedev P, Miga KH, Munson KM, Pak E, Paten B, Pinto BJ, Potapova T, Rhie A, Rocha JL, Ryabov F, Ryder OA, Sacco S, Shafin K, Shepelev VA, Slon V, Solar SJ, Storer JM, Sudmant PH, Sweetalana, Sweeten A, Tassia MG, Thibaud-Nissen F, Ventura M, Wilson MA, Young AC, Zeng H, Zhang X, Szpiech ZA, Huber CD, Gerton JL, Yi SV, Schatz MC, Alexandrov IA, Koren S, O'Neill RJ, Eichler E, and Phillippy AM

Abstract

Apes possess two sex chromosomes-the male-specific Y and the X shared by males and females. The Y chromosome is crucial for male reproduction, with deletions linked to infertility. The X chromosome carries genes vital for reproduction and cognition. Variation in mating patterns and brain function among great apes suggests corresponding differences in their sex chromosome structure and evolution. However, due to their highly repetitive nature and incomplete reference assemblies, ape sex chromosomes have been challenging to study. Here, using the state-of-the-art experimental and computational methods developed for the telomere-to-telomere (T2T) human genome, we produced gapless, complete assemblies of the X and Y chromosomes for five great apes (chimpanzee, bonobo, gorilla, Bornean and Sumatran orangutans) and a lesser ape, the siamang gibbon. These assemblies completely resolved ampliconic, palindromic, and satellite sequences, including the entire centromeres, allowing us to untangle the intricacies of ape sex chromosome evolution. We found that, compared to the X, ape Y chromosomes vary greatly in size and have low alignability and high levels of structural rearrangements. This divergence on the Y arises from the accumulation of lineage-specific ampliconic regions and palindromes (which are shared more broadly among species on the X) and from the abundance of transposable elements and satellites (which have a lower representation on the X). Our analysis of Y chromosome genes revealed lineage-specific expansions of multi-copy gene families and signatures of purifying selection. In summary, the Y exhibits dynamic evolution, while the X is more stable. Finally, mapping short-read sequencing data from >100 great ape individuals revealed the patterns of diversity and selection on their sex chromosomes, demonstrating the utility of these reference assemblies for studies of great ape evolution. These complete sex chromosome assemblies are expected to further inform conservation genetics of nonhuman apes, all of which are endangered species., Competing Interests: Competing Interests EEE is a scientific advisory board (SAB) member of Variant Bio, Inc. RJO is a scientific advisory board (SAB) member of Colossal Biosciences, Inc. CL is a scientific advisory board (SAB) member of Nabsys, Inc. and Genome Insight, Inc.

Published

2023

16. Maximizing the potential for living cell banks to contribute to global conservation priorities.

Author

Mooney A, Ryder OA, Houck ML, Staerk J, Conde DA, and Buckley YM

Subjects

Animals, Animals, Zoo, Internationality, Endangered Species, Biodiversity, Amphibians, Reptiles, Birds, Mammals, Conservation of Natural Resources methods, Commerce

Abstract

Although cryobanking represents a powerful conservation tool, a lack of standardized information on the species represented in global cryobanks, and inconsistent prioritization of species for future sampling, hinder the conservation potential of cryobanking, resulting in missed conservation opportunities. We analyze the representation of amphibian, bird, mammal, and reptile species within the San Diego Zoo Wildlife Alliance Frozen Zoo® living cell collection (as of April 2019) and implement a qualitative framework for the prioritization of species for future sampling. We use global conservation assessment schemes (including the International Union for Conservation of Nature (IUCN) Red List of Threatened Species™, the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES), the Alliance for Zero Extinction, the EDGE of Existence, and Climate Change Vulnerability), and opportunities for sample acquisition from the global zoo and aquarium community, to identify priority species for cryobanking. We show that 965 species, including 5% of all IUCN Red List "Threatened" amphibians, birds, mammals, and reptiles, were represented in the collection and that sampling from within existing zoo and aquarium collections could increase representation to 16.6% (by sampling an additional 707 "Threatened" species). High-priority species for future cryobanking efforts include the whooping crane (Grus americana), crested ibis (Nipponia nippon), and Siberian crane (Leucogeranus leucogeranus). Each of these species are listed under every conservation assessment scheme and have ex situ populations available for sampling. We also provide species prioritizations based on subsets of these assessment schemes together with sampling opportunities from the global zoo and aquarium community. We highlight the difficulties in obtaining in situ samples, and encourage the formation of a global cryobanking database together with the establishment of new cryobanks in biodiversity-rich regions., (© 2023 The Authors. Zoo Biology published by Wiley Periodicals LLC.)

Published

2023

17. Chromosome-length genome assembly and karyotype of the endangered black-footed ferret (Mustela nigripes).

Author

Kliver S, Houck ML, Perelman PL, Totikov A, Tomarovsky A, Dudchenko O, Omer AD, Colaric Z, Weisz D, Aiden EL, Chan S, Hastie A, Komissarov A, Ryder OA, Graphodatsky A, Johnson WE, Maldonado JE, Pukazhenthi BS, Marinari PE, Wildt DE, and Koepfli KP

Subjects

Animals, Male, Karyotype, Karyotyping, Fertility, Ferrets genetics, Endangered Species

Abstract

The black-footed ferret (Mustela nigripes) narrowly avoided extinction to become an oft-cited example of the benefits of intensive management, research, and collaboration to save a species through ex situ conservation breeding and reintroduction into its former range. However, the species remains at risk due to possible inbreeding, disease susceptibility, and multiple fertility challenges. Here, we report the de novo genome assembly of a male black-footed ferret generated through a combination of linked-read sequencing, optical mapping, and Hi-C proximity ligation. In addition, we report the karyotype for this species, which was used to anchor and assign chromosome numbers to the chromosome-length scaffolds. The draft assembly was ~2.5 Gb in length, with 95.6% of it anchored to 19 chromosome-length scaffolds, corresponding to the 2n = 38 chromosomes revealed by the karyotype. The assembly has contig and scaffold N50 values of 148.8 kbp and 145.4 Mbp, respectively, and is up to 96% complete based on BUSCO analyses. Annotation of the assembly, including evidence from RNA-seq data, identified 21,406 protein-coding genes and a repeat content of 37.35%. Phylogenomic analyses indicated that the black-footed ferret diverged from the European polecat/domestic ferret lineage 1.6 million yr ago. This assembly will enable research on the conservation genomics of black-footed ferrets and thereby aid in the further restoration of this endangered species., (© The Author(s) 2023. Published by Oxford University Press on behalf of The American Genetic Association. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

18. Evolutionary constraint and innovation across hundreds of placental mammals.

Author

Christmas MJ, Kaplow IM, Genereux DP, Dong MX, Hughes GM, Li X, Sullivan PF, Hindle AG, Andrews G, Armstrong JC, Bianchi M, Breit AM, Diekhans M, Fanter C, Foley NM, Goodman DB, Goodman L, Keough KC, Kirilenko B, Kowalczyk A, Lawless C, Lind AL, Meadows JRS, Moreira LR, Redlich RW, Ryan L, Swofford R, Valenzuela A, Wagner F, Wallerman O, Brown AR, Damas J, Fan K, Gatesy J, Grimshaw J, Johnson J, Kozyrev SV, Lawler AJ, Marinescu VD, Morrill KM, Osmanski A, Paulat NS, Phan BN, Reilly SK, Schäffer DE, Steiner C, Supple MA, Wilder AP, Wirthlin ME, Xue JR, Birren BW, Gazal S, Hubley RM, Koepfli KP, Marques-Bonet T, Meyer WK, Nweeia M, Sabeti PC, Shapiro B, Smit AFA, Springer MS, Teeling EC, Weng Z, Hiller M, Levesque DL, Lewin HA, Murphy WJ, Navarro A, Paten B, Pollard KS, Ray DA, Ruf I, Ryder OA, Pfenning AR, Lindblad-Toh K, and Karlsson EK

Subjects

Animals, Female, Humans, Conserved Sequence genetics, Genome, Human, Eutheria genetics, Evolution, Molecular

Abstract

Zoonomia is the largest comparative genomics resource for mammals produced to date. By aligning genomes for 240 species, we identify bases that, when mutated, are likely to affect fitness and alter disease risk. At least 332 million bases (~10.7%) in the human genome are unusually conserved across species (evolutionarily constrained) relative to neutrally evolving repeats, and 4552 ultraconserved elements are nearly perfectly conserved. Of 101 million significantly constrained single bases, 80% are outside protein-coding exons and half have no functional annotations in the Encyclopedia of DNA Elements (ENCODE) resource. Changes in genes and regulatory elements are associated with exceptional mammalian traits, such as hibernation, that could inform therapeutic development. Earth's vast and imperiled biodiversity offers distinctive power for identifying genetic variants that affect genome function and organismal phenotypes.

Published

2023

19. The contribution of historical processes to contemporary extinction risk in placental mammals.

Author

Wilder AP, Supple MA, Subramanian A, Mudide A, Swofford R, Serres-Armero A, Steiner C, Koepfli KP, Genereux DP, Karlsson EK, Lindblad-Toh K, Marques-Bonet T, Munoz Fuentes V, Foley K, Meyer WK, Ryder OA, and Shapiro B

Subjects

Animals, Female, Pregnancy, Genome, Population Density, Risk, Eutheria genetics, Extinction, Biological, Genetic Variation

Abstract

Species persistence can be influenced by the amount, type, and distribution of diversity across the genome, suggesting a potential relationship between historical demography and resilience. In this study, we surveyed genetic variation across single genomes of 240 mammals that compose the Zoonomia alignment to evaluate how historical effective population size ( N e ) affects heterozygosity and deleterious genetic load and how these factors may contribute to extinction risk. We find that species with smaller historical N e carry a proportionally larger burden of deleterious alleles owing to long-term accumulation and fixation of genetic load and have a higher risk of extinction. This suggests that historical demography can inform contemporary resilience. Models that included genomic data were predictive of species' conservation status, suggesting that, in the absence of adequate census or ecological data, genomic information may provide an initial risk assessment.

Published

2023

20. Genome report: chromosome-level draft assemblies of the snow leopard, African leopard, and tiger (Panthera uncia, Panthera pardus pardus, and Panthera tigris).

Author

Armstrong EE, Campana MG, Solari KA, Morgan SR, Ryder OA, Naude VN, Samelius G, Sharma K, Hadly EA, and Petrov DA

Subjects

Animals, Genome, Chromosomes genetics, Panthera genetics, Tigers genetics

Abstract

The big cats (genus Panthera) represent some of the most popular and charismatic species on the planet. Although some reference genomes are available for this clade, few are at the chromosome level, inhibiting high-resolution genomic studies. We assembled genomes from 3 members of the genus, the tiger (Panthera tigris), the snow leopard (Panthera uncia), and the African leopard (Panthera pardus pardus), at chromosome or near-chromosome level. We used a combination of short- and long-read technologies, as well as proximity ligation data from Hi-C technology, to achieve high continuity and contiguity for each individual. We hope that these genomes will aid in further evolutionary and conservation research of this iconic group of mammals., (© The Author(s) 2022. Published by Oxford University Press on behalf of Genetics Society of America.)

Published

2022

21. Towards a Genetic Linkage Map of the California Condor, an Endangered New World Vulture Species.

Author

Romanov MN, Da Y, Chemnick LG, Thomas SM, Dandekar SS, Papp JC, and Ryder OA

Abstract

The development of a linkage map is an important component for promoting genetic and genomic studies in California condors, an endangered New World vulture species. Using a set of designed anonymous microsatellite markers, we genotyped a reference condor population involving 121 individuals. After marker validation and genotype filtering, the genetic linkage analysis was performed using 123 microsatellite loci. This resulted in the identification of 15 linkage groups/subgroups that formed a first-generation condor genetic map, while no markers linked to a lethal chondrodystrophy mutation were found. A panel of polymorphic markers that is instrumental in molecular parentage diagnostics and other genetic studies in the California condor was selected. Further condor conservation genomics research will be focused on updating the linkage map and integrating it with cytogenetic and BAC-based physical maps and ultimately with the genome sequence assembly.

Published

2022

22. Evolution of the ancestral mammalian karyotype and syntenic regions.

Author

Damas J, Corbo M, Kim J, Turner-Maier J, Farré M, Larkin DM, Ryder OA, Steiner C, Houck ML, Hall S, Shiue L, Thomas S, Swale T, Daly M, Korlach J, Uliano-Silva M, Mazzoni CJ, Birren BW, Genereux DP, Johnson J, Lindblad-Toh K, Karlsson EK, Nweeia MT, Johnson RN, and Lewin HA

Subjects

Animals, Cattle genetics, Chromosomes, Mammalian genetics, Eutheria genetics, Humans, Phylogeny, Sloths genetics, Evolution, Molecular, Karyotype, Mammals genetics, Synteny genetics

Abstract

Decrypting the rearrangements that drive mammalian chromosome evolution is critical to understanding the molecular bases of speciation, adaptation, and disease susceptibility. Using 8 scaffolded and 26 chromosome-scale genome assemblies representing 23/26 mammal orders, we computationally reconstructed ancestral karyotypes and syntenic relationships at 16 nodes along the mammalian phylogeny. Three different reference genomes (human, sloth, and cattle) representing phylogenetically distinct mammalian superorders were used to assess reference bias in the reconstructed ancestral karyotypes and to expand the number of clades with reconstructed genomes. The mammalian ancestor likely had 19 pairs of autosomes, with nine of the smallest chromosomes shared with the common ancestor of all amniotes (three still conserved in extant mammals), demonstrating a striking conservation of synteny for ∼320 My of vertebrate evolution. The numbers and types of chromosome rearrangements were classified for transitions between the ancestral mammalian karyotype, descendent ancestors, and extant species. For example, 94 inversions, 16 fissions, and 14 fusions that occurred over 53 My differentiated the therian from the descendent eutherian ancestor. The highest breakpoint rate was observed between the mammalian and therian ancestors (3.9 breakpoints/My). Reconstructed mammalian ancestor chromosomes were found to have distinct evolutionary histories reflected in their rates and types of rearrangements. The distributions of genes, repetitive elements, topologically associating domains, and actively transcribed regions in multispecies homologous synteny blocks and evolutionary breakpoint regions indicate that purifying selection acted over millions of years of vertebrate evolution to maintain syntenic relationships of developmentally important genes and regulatory landscapes of gene-dense chromosomes.

Published

2022

23. Phylogenomics of the world's otters.

Author

de Ferran V, Figueiró HV, de Jesus Trindade F, Smith O, Sinding MS, Trinca CS, Lazzari GZ, Veron G, Vianna JA, Barbanera F, Kliver S, Serdyukova N, Bulyonkova T, Ryder OA, Gilbert MTP, Koepfli KP, and Eizirik E

Subjects

Animals, Base Sequence, Phylogeny, Otters genetics

Abstract

Comparative whole-genome analyses hold great power to illuminate commonalities and differences in the evolution of related species that share similar ecologies. The mustelid subfamily Lutrinae includes 13 currently recognized extant species of otters, 1-5 a semiaquatic group whose evolutionary history is incompletely understood. We assembled a dataset comprising 24 genomes from all living otter species, 14 of which were newly sequenced. We used this dataset to infer phylogenetic relationships and divergence times, to characterize patterns of genome-wide genealogical discordance, and to investigate demographic history and current genomic diversity. We found that genera Lutra, Aonyx, Amblonyx, and Lutrogale form a coherent clade that should be synonymized under Lutra, simplifying the taxonomic structure of the subfamily. The poorly known tropical African Aonyx congicus and the more widespread Aonyx capensis were found to be reciprocally monophyletic (having diverged 440,000 years ago), supporting the validity of the former as a distinct species. We observed variable changes in effective population sizes over time among otters within and among continents, although several species showed similar trends of expansions and declines during the last 100,000 years. This has led to different levels of genomic diversity assessed by overall heterozygosity, genome-wide SNV density, and run of homozygosity burden. Interestingly, there were cases in which diversity metrics were consistent with the current threat status (mostly based on census size), highlighting the potential of genomic data for conservation assessment. Overall, our results shed light on otter evolutionary history and provide a framework for further in-depth comparative genomic studies targeting this group., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

24. A Chromosome-Length Reference Genome for the Endangered Pacific Pocket Mouse Reveals Recent Inbreeding in a Historically Large Population.

Author

Wilder AP, Dudchenko O, Curry C, Korody M, Turbek SP, Daly M, Misuraca A, Wang G, Khan R, Weisz D, Fronczek J, Aiden EL, Houck ML, Shier DM, Ryder OA, and Steiner CC

Subjects

Animals, Chromosomes, Homozygote, Mice, Sequence Analysis, DNA, Genome, Inbreeding

Abstract

High-quality reference genomes are fundamental tools for understanding population history, and can provide estimates of genetic and demographic parameters relevant to the conservation of biodiversity. The federally endangered Pacific pocket mouse (PPM), which persists in three small, isolated populations in southern California, is a promising model for studying how demographic history shapes genetic diversity, and how diversity in turn may influence extinction risk. To facilitate these studies in PPM, we combined PacBio HiFi long reads with Omni-C and Hi-C data to generate a de novo genome assembly, and annotated the genome using RNAseq. The assembly comprised 28 chromosome-length scaffolds (N50 = 72.6 MB) and the complete mitochondrial genome, and included a long heterochromatic region on chromosome 18 not represented in the previously available short-read assembly. Heterozygosity was highly variable across the genome of the reference individual, with 18% of windows falling in runs of homozygosity (ROH) >1 MB, and nearly 9% in tracts spanning >5 MB. Yet outside of ROH, heterozygosity was relatively high (0.0027), and historical Ne estimates were large. These patterns of genetic variation suggest recent inbreeding in a formerly large population. Currently the most contiguous assembly for a heteromyid rodent, this reference genome provides insight into the past and recent demographic history of the population, and will be a critical tool for management and future studies of outbreeding depression, inbreeding depression, and genetic load., (© The Author(s) 2022. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published

2022

25. Author Correction: Comparative and demographic analysis of orang-utan genomes.

Author

Locke DP, Hillier LW, Warren WC, Worley KC, Nazareth LV, Muzny DM, Yang SP, Wang Z, Chinwalla AT, Minx P, Mitreva M, Cook L, Delehaunty KD, Fronick C, Schmidt H, Fulton LA, Fulton RS, Nelson JO, Magrini V, Pohl C, Graves TA, Markovic C, Cree A, Dinh HH, Hume J, Kovar CL, Fowler GR, Lunter G, Meader S, Heger A, Ponting CP, Marques-Bonet T, Alkan C, Chen L, Cheng Z, Kidd JM, Eichler EE, White S, Searle S, Vilella AJ, Chen Y, Flicek P, Ma J, Raney B, Suh B, Burhans R, Herrero J, Haussler D, Faria R, Fernando O, Darré F, Farré D, Gazave E, Oliva M, Navarro A, Roberto R, Capozzi O, Archidiacono N, Della Valle G, Purgato S, Rocchi M, Konkel MK, Walker JA, Ullmer B, Batzer MA, Smit AFA, Hubley R, Casola C, Schrider DR, Hahn MW, Quesada V, Puente XS, Ordoñez GR, López-Otín C, Vinar T, Brejova B, Ratan A, Harris RS, Miller W, Kosiol C, Lawson HA, Taliwal V, Martins AL, Siepel A, RoyChoudhury A, Ma X, Degenhardt J, Bustamante CD, Gutenkunst RN, Mailund T, Dutheil JY, Hobolth A, Schierup MH, Ryder OA, Yoshinaga Y, de Jong PJ, Weinstock GM, Rogers J, Mardis ER, Gibbs RA, and Wilson RK

Published

2022

26. Reference genomes for conservation.

Author

Paez S, Kraus RHS, Shapiro B, Gilbert MTP, Jarvis ED, Al-Ajli FO, Ceballos G, Crawford AJ, Fedrigo O, Johnson RN, Johnson WE, Marques-Bonet T, Morin PA, Mueller RC, Ryder OA, Teeling EC, and Venkatesh B

Abstract

High-quality reference genomes for non-model species can benefit conservation.

Published

2022

27. Corrigendum to: Facultative Parthenogenesis in California Condors.

Author

Ryder OA, Thomas S, Judson JM, Romanov MN, Dandekar S, Papp JC, Sidak-Loftis LC, Walker K, Stalis IH, Mace M, Steiner CC, and Chemnick LG

Published

2022

28. Response to Bakker et al.

Author

Robinson JA, Bowie RCK, Dudchenko O, Aiden EL, Hendrickson SL, Steiner CC, Ryder OA, Mindell DP, and Wall JD

Abstract

Robinson and colleagues respond to the points raised about their paper by Bakker et al., Competing Interests: Declaration of interests J.D.W. receives research funding from Sierra Pacific Industries. E.L.A. is Scientific Advisory Board co-chair and consultant for HolyHaid Lab Corporation (Shenzhen, China), whose parent company is Hollyhigh International Capital (Beijing and Shanghai, China)., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

29. Darwinian genomics and diversity in the tree of life.

Author

Stephan T, Burgess SM, Cheng H, Danko CG, Gill CA, Jarvis ED, Koepfli KP, Koltes JE, Lyons E, Ronald P, Ryder OA, Schriml LM, Soltis P, VandeWoude S, Zhou H, Ostrander EA, and Karlsson EK

Subjects

Animals, Evolution, Molecular, Genetic Variation genetics, Genome genetics, Genomics trends, Humans, Phylogeny, Biodiversity, Biological Evolution, Genomics methods

Abstract

Genomics encompasses the entire tree of life, both extinct and extant, and the evolutionary processes that shape this diversity. To date, genomic research has focused on humans, a small number of agricultural species, and established laboratory models. Fewer than 18,000 of ∼2,000,000 eukaryotic species (<1%) have a representative genome sequence in GenBank, and only a fraction of these have ancillary information on genome structure, genetic variation, gene expression, epigenetic modifications, and population diversity. This imbalance reflects a perception that human studies are paramount in disease research. Yet understanding how genomes work, and how genetic variation shapes phenotypes, requires a broad view that embraces the vast diversity of life. We have the technology to collect massive and exquisitely detailed datasets about the world, but expertise is siloed into distinct fields. A new approach, integrating comparative genomics with cell and evolutionary biology, ecology, archaeology, anthropology, and conservation biology, is essential for understanding and protecting ourselves and our world. Here, we describe potential for scientific discovery when comparative genomics works in close collaboration with a broad range of fields as well as the technical, scientific, and social constraints that must be addressed., Competing Interests: The authors declare no competing interest., (Copyright © 2022 the Author(s). Published by PNAS.)

Published

2022

30. Why sequence all eukaryotes?

Author

Blaxter M, Archibald JM, Childers AK, Coddington JA, Crandall KA, Di Palma F, Durbin R, Edwards SV, Graves JAM, Hackett KJ, Hall N, Jarvis ED, Johnson RN, Karlsson EK, Kress WJ, Kuraku S, Lawniczak MKN, Lindblad-Toh K, Lopez JV, Moran NA, Robinson GE, Ryder OA, Shapiro B, Soltis PS, Warnow T, Zhang G, and Lewin HA

Subjects

Animals, Biodiversity, Biological Evolution, Ecology, Ecosystem, Genome, Genomics methods, Humans, Phylogeny, Base Sequence genetics, Eukaryota genetics, Genomics ethics

Abstract

Life on Earth has evolved from initial simplicity to the astounding complexity we experience today. Bacteria and archaea have largely excelled in metabolic diversification, but eukaryotes additionally display abundant morphological innovation. How have these innovations come about and what constraints are there on the origins of novelty and the continuing maintenance of biodiversity on Earth? The history of life and the code for the working parts of cells and systems are written in the genome. The Earth BioGenome Project has proposed that the genomes of all extant, named eukaryotes-about 2 million species-should be sequenced to high quality to produce a digital library of life on Earth, beginning with strategic phylogenetic, ecological, and high-impact priorities. Here we discuss why we should sequence all eukaryotic species, not just a representative few scattered across the many branches of the tree of life. We suggest that many questions of evolutionary and ecological significance will only be addressable when whole-genome data representing divergences at all of the branchings in the tree of life or all species in natural ecosystems are available. We envisage that a genomic tree of life will foster understanding of the ongoing processes of speciation, adaptation, and organismal dependencies within entire ecosystems. These explorations will resolve long-standing problems in phylogenetics, evolution, ecology, conservation, agriculture, bioindustry, and medicine., Competing Interests: The authors declare no competing interest., (Copyright © 2022 the Author(s). Published by PNAS.)

Published

2022

31. The Earth BioGenome Project 2020: Starting the clock.

Author

Lewin HA, Richards S, Lieberman Aiden E, Allende ML, Archibald JM, Bálint M, Barker KB, Baumgartner B, Belov K, Bertorelle G, Blaxter ML, Cai J, Caperello ND, Carlson K, Castilla-Rubio JC, Chaw SM, Chen L, Childers AK, Coddington JA, Conde DA, Corominas M, Crandall KA, Crawford AJ, DiPalma F, Durbin R, Ebenezer TE, Edwards SV, Fedrigo O, Flicek P, Formenti G, Gibbs RA, Gilbert MTP, Goldstein MM, Graves JM, Greely HT, Grigoriev IV, Hackett KJ, Hall N, Haussler D, Helgen KM, Hogg CJ, Isobe S, Jakobsen KS, Janke A, Jarvis ED, Johnson WE, Jones SJM, Karlsson EK, Kersey PJ, Kim JH, Kress WJ, Kuraku S, Lawniczak MKN, Leebens-Mack JH, Li X, Lindblad-Toh K, Liu X, Lopez JV, Marques-Bonet T, Mazard S, Mazet JAK, Mazzoni CJ, Myers EW, O'Neill RJ, Paez S, Park H, Robinson GE, Roquet C, Ryder OA, Sabir JSM, Shaffer HB, Shank TM, Sherkow JS, Soltis PS, Tang B, Tedersoo L, Uliano-Silva M, Wang K, Wei X, Wetzer R, Wilson JL, Xu X, Yang H, Yoder AD, and Zhang G

Subjects

Animals, Biodiversity, Genomics, Humans, Base Sequence genetics, Eukaryota genetics

Abstract

Competing Interests: The authors declare no competing interest.

Published

2022

32. Whole-genome sequences shed light on the demographic history and contemporary genetic erosion of free-ranging jaguar (Panthera onca) populations.

Author

Lorenzana GP, Figueiró HV, Kaelin CB, Barsh GS, Johnson J, Karlsson E, Morato RG, Sana DA, Cullen L, May JA Jr, Moraes EA Jr, Kantek DLZ, Silveira L, Murphy WJ, Ryder OA, and Eizirik E

Subjects

Animals, Conservation of Natural Resources, Demography, Panthera genetics

Abstract

Competing Interests: Conflict of interest All authors declare no conflict of interest.

Published

2022

33. Facultative Parthenogenesis in California Condors.

Author

Ryder OA, Thomas S, Judson JM, Romanov MN, Dandekar S, Papp JC, Sidak-Loftis LC, Walker K, Stalis IH, Mace M, Steiner CC, and Chemnick LG

Subjects

Female, Homozygote, Humans, Male, Phylogeny, Fertility, Parthenogenesis genetics

Abstract

Parthenogenesis is a relatively rare event in birds, documented in unfertilized eggs from columbid, galliform, and passerine females with no access to males. In the critically endangered California condor, parentage analysis conducted utilizing polymorphic microsatellite loci has identified two instances of parthenogenetic development from the eggs of two females in the captive breeding program, each continuously housed with a reproductively capable male with whom they had produced offspring. Paternal genetic contribution to the two chicks was excluded. Both parthenotes possessed the expected male ZZ sex chromosomes and were homozygous for all evaluated markers inherited from their dams. These findings represent the first molecular marker-based identification of facultative parthenogenesis in an avian species, notably of females in regular contact with fertile males, and add to the phylogenetic breadth of vertebrate taxa documented to have reproduced via asexual reproduction., (© The American Genetic Association. 2021.)

Published

2021

34. Historical population declines prompted significant genomic erosion in the northern and southern white rhinoceros (Ceratotherium simum).

Author

Sánchez-Barreiro F, Gopalakrishnan S, Ramos-Madrigal J, Westbury MV, de Manuel M, Margaryan A, Ciucani MM, Vieira FG, Patramanis Y, Kalthoff DC, Timmons Z, Sicheritz-Pontén T, Dalén L, Ryder OA, Zhang G, Marquès-Bonet T, Moodley Y, and Gilbert MTP

Subjects

Animals, Genomics, Inbreeding, Anthropogenic Effects, Perissodactyla genetics

Abstract

Large vertebrates are extremely sensitive to anthropogenic pressure, and their populations are declining fast. The white rhinoceros (Ceratotherium simum) is a paradigmatic case: this African megaherbivore has suffered a remarkable decline in the last 150 years due to human activities. Its subspecies, the northern (NWR) and the southern white rhinoceros (SWR), however, underwent opposite fates: the NWR vanished quickly, while the SWR recovered after the severe decline. Such demographic events are predicted to have an erosive effect at the genomic level, linked to the extirpation of diversity, and increased genetic drift and inbreeding. However, there is little empirical data available to directly reconstruct the subtleties of such processes in light of distinct demographic histories. Therefore, we generated a whole-genome, temporal data set consisting of 52 resequenced white rhinoceros genomes, representing both subspecies at two time windows: before and during/after the bottleneck. Our data reveal previously unknown population structure within both subspecies, as well as quantifiable genomic erosion. Genome-wide heterozygosity decreased significantly by 10% in the NWR and 36% in the SWR, and inbreeding coefficients rose significantly by 11% and 39%, respectively. Despite the remarkable loss of genomic diversity and recent inbreeding it suffered, the only surviving subspecies, the SWR, does not show a significant accumulation of genetic load compared to its historical counterpart. Our data provide empirical support for predictions about the genomic consequences of shrinking populations, and our findings have the potential to inform the conservation efforts of the remaining white rhinoceroses., (© 2021 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2021

35. An Annotated Draft Genome for the Andean Bear, Tremarctos ornatus.

Author

Saremi NF, Oppenheimer J, Vollmers C, O'Connell B, Milne SA, Byrne A, Yu L, Ryder OA, Green RE, and Shapiro B

Subjects

Animals, Cell Nucleus, Female, Genome, Molecular Sequence Annotation, Phylogeny, South America, Ursidae genetics

Abstract

The Andean bear is the only extant member of the Tremarctine subfamily and the only extant ursid species to inhabit South America. Here, we present an annotated de novo assembly of a nuclear genome from a captive-born female Andean bear, Mischief, generated using a combination of short and long DNA and RNA reads. Our final assembly has a length of 2.23 Gb, and a scaffold N50 of 21.12 Mb, contig N50 of 23.5 kb, and BUSCO score of 88%. The Andean bear genome will be a useful resource for exploring the complex phylogenetic history of extinct and extant bear species and for future population genetics studies of Andean bears., (© The American Genetic Association. 2021.)

Published

2021

36. Genome-wide diversity in the California condor tracks its prehistoric abundance and decline.

Author

Robinson JA, Bowie RCK, Dudchenko O, Aiden EL, Hendrickson SL, Steiner CC, Ryder OA, Mindell DP, and Wall JD

Subjects

Animals, Ecosystem, Female, Genomics, Population Density, Endangered Species, Falconiformes classification, Falconiformes genetics, Genome genetics

Abstract

Due to their small population sizes, threatened and endangered species frequently suffer from a lack of genetic diversity, potentially leading to inbreeding depression and reduced adaptability. 1 During the latter half of the twentieth century, North America's largest soaring bird, 2 the California condor (Gymnogyps californianus; Critically Endangered 3 ), briefly went extinct in the wild. Though condors once ranged throughout North America, by 1982 only 22 individuals remained. Following decades of captive breeding and release efforts, there are now >300 free-flying wild condors and ∼200 in captivity. The condor's recent near-extinction from lead poisoning, poaching, and loss of habitat is well documented, 4 but much about its history remains obscure. To fill this gap and aid future management of the species, we produced a high-quality chromosome-length genome assembly for the California condor and analyzed its genome-wide diversity. For comparison, we also examined the genomes of two close relatives: the Andean condor (Vultur gryphus; Vulnerable 3 ) and the turkey vulture (Cathartes aura; Least Concern 3 ). The genomes of all three species show evidence of historic population declines. Interestingly, the California condor genome retains a high degree of variation, which our analyses reveal is a legacy of its historically high abundance. Correlations between genome-wide diversity and recombination rate further suggest a history of purifying selection against linked deleterious alleles, boding well for future restoration. We show how both long-term evolutionary forces and recent inbreeding have shaped the genome of the California condor, and provide crucial genomic resources to enable future research and conservation., Competing Interests: Declaration of interests J.D.W. receives research funding from Sierra Pacific Industries. E.L.A. is Scientific Advisory Board co-chair and consultant for HolyHaid Lab Corporation (Shenzhen, China), whose parent company is Hollyhigh International Capital (Beijing and Shanghai, China)., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2021

37. Recent Evolutionary History of Tigers Highlights Contrasting Roles of Genetic Drift and Selection.

Author

Armstrong EE, Khan A, Taylor RW, Gouy A, Greenbaum G, Thiéry A, Kang JT, Redondo SA, Prost S, Barsh G, Kaelin C, Phalke S, Chugani A, Gilbert M, Miquelle D, Zachariah A, Borthakur U, Reddy A, Louis E, Ryder OA, Jhala YV, Petrov D, Excoffier L, Hadly E, and Ramakrishnan U

Subjects

Animals, Conservation of Natural Resources, Genetic Variation, Genome, India, Phylogeography, Biological Evolution, Genetic Drift, Inbreeding, Selection, Genetic, Tigers genetics

Abstract

Species conservation can be improved by knowledge of evolutionary and genetic history. Tigers are among the most charismatic of endangered species and garner significant conservation attention. However, their evolutionary history and genomic variation remain poorly known, especially for Indian tigers. With 70% of the world's wild tigers living in India, such knowledge is critical. We re-sequenced 65 individual tiger genomes representing most extant subspecies with a specific focus on tigers from India. As suggested by earlier studies, we found strong genetic differentiation between the putative tiger subspecies. Despite high total genomic diversity in India, individual tigers host longer runs of homozygosity, potentially suggesting recent inbreeding or founding events, possibly due to small and fragmented protected areas. We suggest the impacts of ongoing connectivity loss on inbreeding and persistence of Indian tigers be closely monitored. Surprisingly, demographic models suggest recent divergence (within the last 20,000 years) between subspecies and strong population bottlenecks. Amur tiger genomes revealed the strongest signals of selection related to metabolic adaptation to cold, whereas Sumatran tigers show evidence of weak selection for genes involved in body size regulation. We recommend detailed investigation of local adaptation in Amur and Sumatran tigers prior to initiating genetic rescue., (© The Author(s) 2021. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2021

38. How to Make a Rodent Giant: Genomic Basis and Tradeoffs of Gigantism in the Capybara, the World's Largest Rodent.

Author

Herrera-Álvarez S, Karlsson E, Ryder OA, Lindblad-Toh K, and Crawford AJ

Subjects

Animals, Female, Growth genetics, Multigene Family, Neoplasms genetics, Rodentia growth & development, Biological Evolution, Body Size genetics, Genome, Rodentia genetics

Abstract

Gigantism results when one lineage within a clade evolves extremely large body size relative to its small-bodied ancestors, a common phenomenon in animals. Theory predicts that the evolution of giants should be constrained by two tradeoffs. First, because body size is negatively correlated with population size, purifying selection is expected to be less efficient in species of large body size, leading to increased mutational load. Second, gigantism is achieved through generating a higher number of cells along with higher rates of cell proliferation, thus increasing the likelihood of cancer. To explore the genetic basis of gigantism in rodents and uncover genomic signatures of gigantism-related tradeoffs, we assembled a draft genome of the capybara (Hydrochoerus hydrochaeris), the world's largest living rodent. We found that the genome-wide ratio of nonsynonymous to synonymous mutations (ω) is elevated in the capybara relative to other rodents, likely caused by a generation-time effect and consistent with a nearly neutral model of molecular evolution. A genome-wide scan for adaptive protein evolution in the capybara highlighted several genes controlling postnatal bone growth regulation and musculoskeletal development, which are relevant to anatomical and developmental modifications for an increase in overall body size. Capybara-specific gene-family expansions included a putative novel anticancer adaptation that involves T-cell-mediated tumor suppression, offering a potential resolution to the increased cancer risk in this lineage. Our comparative genomic results uncovered the signature of an intragenomic conflict where the evolution of gigantism in the capybara involved selection on genes and pathways that are directly linked to cancer., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution.)

Published

2021

39. Reference genome and demographic history of the most endangered marine mammal, the vaquita.

Author

Morin PA, Archer FI, Avila CD, Balacco JR, Bukhman YV, Chow W, Fedrigo O, Formenti G, Fronczek JA, Fungtammasan A, Gulland FMD, Haase B, Peter Heide-Jorgensen M, Houck ML, Howe K, Misuraca AC, Mountcastle J, Musser W, Paez S, Pelan S, Phillippy A, Rhie A, Robinson J, Rojas-Bracho L, Rowles TK, Ryder OA, Smith CR, Stevenson S, Taylor BL, Teilmann J, Torrance J, Wells RS, Westgate AJ, and Jarvis ED

Subjects

Animals, Chromosomes, Female, Genetics, Population, Endangered Species, Genome, Phocoena genetics

Abstract

The vaquita is the most critically endangered marine mammal, with fewer than 19 remaining in the wild. First described in 1958, the vaquita has been in rapid decline for more than 20 years resulting from inadvertent deaths due to the increasing use of large-mesh gillnets. To understand the evolutionary and demographic history of the vaquita, we used combined long-read sequencing and long-range scaffolding methods with long- and short-read RNA sequencing to generate a near error-free annotated reference genome assembly from cell lines derived from a female individual. The genome assembly consists of 99.92% of the assembled sequence contained in 21 nearly gapless chromosome-length autosome scaffolds and the X-chromosome scaffold, with a scaffold N50 of 115 Mb. Genome-wide heterozygosity is the lowest (0.01%) of any mammalian species analysed to date, but heterozygosity is evenly distributed across the chromosomes, consistent with long-term small population size at genetic equilibrium, rather than low diversity resulting from a recent population bottleneck or inbreeding. Historical demography of the vaquita indicates long-term population stability at less than 5,000 (Ne) for over 200,000 years. Together, these analyses indicate that the vaquita genome has had ample opportunity to purge highly deleterious alleles and potentially maintain diversity necessary for population health., (© 2020 The Authors. Molecular Ecology Resources published by John Wiley & Sons Ltd.)

Published

2021

40. Genomic insights into the conservation status of the world's last remaining Sumatran rhinoceros populations.

Author

von Seth J, Dussex N, Díez-Del-Molino D, van der Valk T, Kutschera VE, Kierczak M, Steiner CC, Liu S, Gilbert MTP, Sinding MS, Prost S, Guschanski K, Nathan SKSS, Brace S, Chan YL, Wheat CW, Skoglund P, Ryder OA, Goossens B, Götherström A, and Dalén L

Subjects

Animals, Borneo, Female, Gene Flow, Genetic Variation, Genome, History, 21st Century, History, Ancient, Inbreeding, Indonesia, Loss of Function Mutation, Male, Mutation, Population Density, Selection, Genetic, Conservation of Natural Resources, Endangered Species history, Perissodactyla genetics

Abstract

Small populations are often exposed to high inbreeding and mutational load that can increase the risk of extinction. The Sumatran rhinoceros was widespread in Southeast Asia, but is now restricted to small and isolated populations on Sumatra and Borneo, and most likely extinct on the Malay Peninsula. Here, we analyse 5 historical and 16 modern genomes from these populations to investigate the genomic consequences of the recent decline, such as increased inbreeding and mutational load. We find that the Malay Peninsula population experienced increased inbreeding shortly before extirpation, which possibly was accompanied by purging. The populations on Sumatra and Borneo instead show low inbreeding, but high mutational load. The currently small population sizes may thus in the near future lead to inbreeding depression. Moreover, we find little evidence for differences in local adaptation among populations, suggesting that future inbreeding depression could potentially be mitigated by assisted gene flow among populations.

Published

2021

41. Platypus and echidna genomes reveal mammalian biology and evolution.

Author

Zhou Y, Shearwin-Whyatt L, Li J, Song Z, Hayakawa T, Stevens D, Fenelon JC, Peel E, Cheng Y, Pajpach F, Bradley N, Suzuki H, Nikaido M, Damas J, Daish T, Perry T, Zhu Z, Geng Y, Rhie A, Sims Y, Wood J, Haase B, Mountcastle J, Fedrigo O, Li Q, Yang H, Wang J, Johnston SD, Phillippy AM, Howe K, Jarvis ED, Ryder OA, Kaessmann H, Donnelly P, Korlach J, Lewin HA, Graves J, Belov K, Renfree MB, Grutzner F, Zhou Q, and Zhang G

Subjects

Animals, Female, Male, Mammals genetics, Phylogeny, Sex Chromosomes genetics, Biological Evolution, Genome, Platypus genetics, Tachyglossidae genetics

Abstract

Egg-laying mammals (monotremes) are the only extant mammalian outgroup to therians (marsupial and eutherian animals) and provide key insights into mammalian evolution 1,2 . Here we generate and analyse reference genomes of the platypus (Ornithorhynchus anatinus) and echidna (Tachyglossus aculeatus), which represent the only two extant monotreme lineages. The nearly complete platypus genome assembly has anchored almost the entire genome onto chromosomes, markedly improving the genome continuity and gene annotation. Together with our echidna sequence, the genomes of the two species allow us to detect the ancestral and lineage-specific genomic changes that shape both monotreme and mammalian evolution. We provide evidence that the monotreme sex chromosome complex originated from an ancestral chromosome ring configuration. The formation of such a unique chromosome complex may have been facilitated by the unusually extensive interactions between the multi-X and multi-Y chromosomes that are shared by the autosomal homologues in humans. Further comparative genomic analyses unravel marked differences between monotremes and therians in haptoglobin genes, lactation genes and chemosensory receptor genes for smell and taste that underlie the ecological adaptation of monotremes.

Published

2021

42. Author Correction: Dense sampling of bird diversity increases power of comparative genomics.

Author

Feng S, Stiller J, Deng Y, Armstrong J, Fang Q, Reeve AH, Xie D, Chen G, Guo C, Faircloth BC, Petersen B, Wang Z, Zhou Q, Diekhans M, Chen W, Andreu-Sánchez S, Margaryan A, Howard JT, Parent C, Pacheco G, Sinding MS, Puetz L, Cavill E, Ribeiro ÂM, Eckhart L, Fjeldså J, Hosner PA, Brumfield RT, Christidis L, Bertelsen MF, Sicheritz-Ponten T, Tietze DT, Robertson BC, Song G, Borgia G, Claramunt S, Lovette IJ, Cowen SJ, Njoroge P, Dumbacher JP, Ryder OA, Fuchs J, Bunce M, Burt DW, Cracraft J, Meng G, Hackett SJ, Ryan PG, Jønsson KA, Jamieson IG, da Fonseca RR, Braun EL, Houde P, Mirarab S, Suh A, Hansson B, Ponnikas S, Sigeman H, Stervander M, Frandsen PB, van der Zwan H, van der Sluis R, Visser C, Balakrishnan CN, Clark AG, Fitzpatrick JW, Bowman R, Chen N, Cloutier A, Sackton TB, Edwards SV, Foote DJ, Shakya SB, Sheldon FH, Vignal A, Soares AER, Shapiro B, González-Solís J, Ferrer-Obiol J, Rozas J, Riutort M, Tigano A, Friesen V, Dalén L, Urrutia AO, Székely T, Liu Y, Campana MG, Corvelo A, Fleischer RC, Rutherford KM, Gemmell NJ, Dussex N, Mouritsen H, Thiele N, Delmore K, Liedvogel M, Franke A, Hoeppner MP, Krone O, Fudickar AM, Milá B, Ketterson ED, Fidler AE, Friis G, Parody-Merino ÁM, Battley PF, Cox MP, Lima NCB, Prosdocimi F, Parchman TL, Schlinger BA, Loiselle BA, Blake JG, Lim HC, Day LB, Fuxjager MJ, Baldwin MW, Braun MJ, Wirthlin M, Dikow RB, Ryder TB, Camenisch G, Keller LF, DaCosta JM, Hauber ME, Louder MIM, Witt CC, McGuire JA, Mudge J, Megna LC, Carling MD, Wang B, Taylor SA, Del-Rio G, Aleixo A, Vasconcelos ATR, Mello CV, Weir JT, Haussler D, Li Q, Yang H, Wang J, Lei F, Rahbek C, Gilbert MTP, Graves GR, Jarvis ED, Paten B, and Zhang G

Published

2021

43. Towards complete and error-free genome assemblies of all vertebrate species.

Author

Rhie A, McCarthy SA, Fedrigo O, Damas J, Formenti G, Koren S, Uliano-Silva M, Chow W, Fungtammasan A, Kim J, Lee C, Ko BJ, Chaisson M, Gedman GL, Cantin LJ, Thibaud-Nissen F, Haggerty L, Bista I, Smith M, Haase B, Mountcastle J, Winkler S, Paez S, Howard J, Vernes SC, Lama TM, Grutzner F, Warren WC, Balakrishnan CN, Burt D, George JM, Biegler MT, Iorns D, Digby A, Eason D, Robertson B, Edwards T, Wilkinson M, Turner G, Meyer A, Kautt AF, Franchini P, Detrich HW 3rd, Svardal H, Wagner M, Naylor GJP, Pippel M, Malinsky M, Mooney M, Simbirsky M, Hannigan BT, Pesout T, Houck M, Misuraca A, Kingan SB, Hall R, Kronenberg Z, Sović I, Dunn C, Ning Z, Hastie A, Lee J, Selvaraj S, Green RE, Putnam NH, Gut I, Ghurye J, Garrison E, Sims Y, Collins J, Pelan S, Torrance J, Tracey A, Wood J, Dagnew RE, Guan D, London SE, Clayton DF, Mello CV, Friedrich SR, Lovell PV, Osipova E, Al-Ajli FO, Secomandi S, Kim H, Theofanopoulou C, Hiller M, Zhou Y, Harris RS, Makova KD, Medvedev P, Hoffman J, Masterson P, Clark K, Martin F, Howe K, Flicek P, Walenz BP, Kwak W, Clawson H, Diekhans M, Nassar L, Paten B, Kraus RHS, Crawford AJ, Gilbert MTP, Zhang G, Venkatesh B, Murphy RW, Koepfli KP, Shapiro B, Johnson WE, Di Palma F, Marques-Bonet T, Teeling EC, Warnow T, Graves JM, Ryder OA, Haussler D, O'Brien SJ, Korlach J, Lewin HA, Howe K, Myers EW, Durbin R, Phillippy AM, and Jarvis ED

Subjects

Animals, Birds, Gene Library, Genome Size, Genome, Mitochondrial, Haplotypes, High-Throughput Nucleotide Sequencing, Molecular Sequence Annotation, Sequence Alignment, Sequence Analysis, DNA, Sex Chromosomes genetics, Genome, Genomics methods, Vertebrates genetics

Abstract

High-quality and complete reference genome assemblies are fundamental for the application of genomics to biology, disease, and biodiversity conservation. However, such assemblies are available for only a few non-microbial species 1-4 . To address this issue, the international Genome 10K (G10K) consortium 5,6 has worked over a five-year period to evaluate and develop cost-effective methods for assembling highly accurate and nearly complete reference genomes. Here we present lessons learned from generating assemblies for 16 species that represent six major vertebrate lineages. We confirm that long-read sequencing technologies are essential for maximizing genome quality, and that unresolved complex repeats and haplotype heterozygosity are major sources of assembly error when not handled correctly. Our assemblies correct substantial errors, add missing sequence in some of the best historical reference genomes, and reveal biological discoveries. These include the identification of many false gene duplications, increases in gene sizes, chromosome rearrangements that are specific to lineages, a repeated independent chromosome breakpoint in bat genomes, and a canonical GC-rich pattern in protein-coding genes and their regulatory regions. Adopting these lessons, we have embarked on the Vertebrate Genomes Project (VGP), an international effort to generate high-quality, complete reference genomes for all of the roughly 70,000 extant vertebrate species and to help to enable a new era of discovery across the life sciences.

Published

2021

44. Diverse phylogenomic datasets uncover a concordant scenario of laurasiatherian interordinal relationships.

Author

Lv X, Hu J, Hu Y, Li Y, Xu D, Ryder OA, Irwin DM, and Yu L

Subjects

Animals, Genetic Loci, Genetic Markers, Introns genetics, Likelihood Functions, Eutheria classification, Eutheria genetics, Genome, Phylogeny

Abstract

Resolving the interordinal relationships in the mammalian superorder Laurasiatheria has been among the most intractable problems in higher-level mammalian systematics, with many conflicting hypotheses having been proposed. The present study collected three different sources of genome-scale data with comprehensive taxon sampling of laurasiatherian species, including two protein-coding datasets (4,186 protein-coding genes for an amino acid dataset comprising 2,761,247 amino acid residues and a nucleotide dataset comprising 5,516,340 nucleotides from 1st and 2nd codon positions), an intronic dataset (1,210 introns comprising 1,162,723 nucleotides) and an ultraconserved elements (UCEs) dataset (1,246 UCEs comprising 1,946,472 nucleotides) from 40 species representing all six laurasiatherian orders and 7 non-laurasiatherian outgroups. Remarkably, phylogenetic trees reconstructed with the four datasets using different tree-building methods (RAxML, FastTree, ASTRAL and MP-EST) all supported the relationship (Eulipotyphla, (Chiroptera, ((Carnivora, Pholidota), (Cetartiodactyla, Perissodactyla)))). We find a resolution of interordinal relationships of Laurasiatheria among all types of markers used in the present study, and the likelihood ratio tests for tree comparisons confirmed that the present tree topology is the optimal hypothesis compared to other examined hypotheses. Jackknifing subsampling analyses demonstrate that the results of laurasiatherian tree reconstruction varied with the number of loci and ordinal representatives used, which are likely the two main contributors to phylogenetic disagreements of Laurasiatheria seen in previous studies. Our study provides significant insight into laurasiatherian evolution, and moreover, an important methodological strategy and reference for resolving phylogenies of adaptive radiation, which have been a long-standing challenge in the field of phylogenetics., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

45. Characterization of 29 polymorphic microsatellite markers developed by genomic screening of Sumatran rhinoceros (Dicerorhinus sumatrensis).

Author

Brandt JR, Saidah SH, Zhao K, Ishida Y, Apriyana I, Ryder OA, Ramono W, Sudoyo H, Suryadi H, Van Coeverden de Groot PJ, and Roca AL

Subjects

Animals, Genome, Genomics, Indonesia, Microsatellite Repeats genetics, Perissodactyla genetics

Abstract

Objective: The Sumatran rhinoceros is critically endangered, with fewer than 100 individuals surviving across its current range. Accurate census estimates of the remaining populations are essential for development and implementation of conservation plans. In order to enable molecular censusing, we here develop microsatellite markers with amplicon sizes of short length, appropriate for non-invasive fecal sampling., Results: Due to limited sample quantity and potential lack of genome-wide diversity, Illumina sequence reads were generated from two Sumatran rhinoceros samples. Genomic screening identified reads with short tandem repeats and loci that were polymorphic within the dataset. Twenty-nine novel polymorphic microsatellite markers were characterized (A = 2.4; H O  = 0.30). These were sufficient to distinguish among individuals (P ID  < 0.0001), and to distinguish among siblings (P ID(sib)  < 0.0001). Among rhinos in Indonesia, almost all markers were established as polymorphic and effective for genotyping DNA from fecal samples. Notably, the markers amplified and displayed microsatellite polymorphisms using DNA extracted from 11 fecal samples collected non-invasively from wild Sumatran rhinoceros. These microsatellite markers provide an important resource for a census and genetic studies of wild Sumatran rhinos.

Published

2021

46. Rewinding Extinction in the Northern White Rhinoceros: Genetically Diverse Induced Pluripotent Stem Cell Bank for Genetic Rescue.

Author

Korody ML, Ford SM, Nguyen TD, Pivaroff CG, Valiente-Alandi I, Peterson SE, Ryder OA, and Loring JF

Subjects

Animals, Cell Differentiation genetics, Cells, Cultured, Cryopreservation methods, Fibroblasts cytology, Fibroblasts metabolism, Gene Expression, Induced Pluripotent Stem Cells metabolism, Karyotyping, Nanog Homeobox Protein genetics, Perissodactyla classification, Reverse Transcriptase Polymerase Chain Reaction, SOXB1 Transcription Factors genetics, Species Specificity, Biological Specimen Banks, Endangered Species, Extinction, Biological, Genetic Variation, Induced Pluripotent Stem Cells cytology, Perissodactyla genetics

Abstract

Extinction rates are rising, and current conservation technologies may not be adequate for reducing species losses. Future conservation efforts may be aided by the generation of induced pluripotent stem cells (iPSCs) from highly endangered species. Generation of a set of iPSCs from multiple members of a species can capture some of the dwindling genetic diversity of a disappearing species. We generated iPSCs from fibroblasts cryopreserved in the Frozen Zoo ® : nine genetically diverse individuals of the functionally extinct northern white rhinoceros ( Ceratotherium simum cottoni ) and two from the closely related southern white rhinoceros ( Ceratotherium simum simum ). We used a nonintegrating Sendai virus reprogramming method and developed analyses to confirm the cells' pluripotency and differentiation potential. This work is the first step of a long-term interdisciplinary plan to apply assisted reproduction techniques to the conservation of this highly endangered species. Advances in iPSC differentiation may enable generation of gametes in vitro from deceased and nonreproductive individuals that could be used to repopulate the species.

Published

2021

47. Dense sampling of bird diversity increases power of comparative genomics.

Author

Feng S, Stiller J, Deng Y, Armstrong J, Fang Q, Reeve AH, Xie D, Chen G, Guo C, Faircloth BC, Petersen B, Wang Z, Zhou Q, Diekhans M, Chen W, Andreu-Sánchez S, Margaryan A, Howard JT, Parent C, Pacheco G, Sinding MS, Puetz L, Cavill E, Ribeiro ÂM, Eckhart L, Fjeldså J, Hosner PA, Brumfield RT, Christidis L, Bertelsen MF, Sicheritz-Ponten T, Tietze DT, Robertson BC, Song G, Borgia G, Claramunt S, Lovette IJ, Cowen SJ, Njoroge P, Dumbacher JP, Ryder OA, Fuchs J, Bunce M, Burt DW, Cracraft J, Meng G, Hackett SJ, Ryan PG, Jønsson KA, Jamieson IG, da Fonseca RR, Braun EL, Houde P, Mirarab S, Suh A, Hansson B, Ponnikas S, Sigeman H, Stervander M, Frandsen PB, van der Zwan H, van der Sluis R, Visser C, Balakrishnan CN, Clark AG, Fitzpatrick JW, Bowman R, Chen N, Cloutier A, Sackton TB, Edwards SV, Foote DJ, Shakya SB, Sheldon FH, Vignal A, Soares AER, Shapiro B, González-Solís J, Ferrer-Obiol J, Rozas J, Riutort M, Tigano A, Friesen V, Dalén L, Urrutia AO, Székely T, Liu Y, Campana MG, Corvelo A, Fleischer RC, Rutherford KM, Gemmell NJ, Dussex N, Mouritsen H, Thiele N, Delmore K, Liedvogel M, Franke A, Hoeppner MP, Krone O, Fudickar AM, Milá B, Ketterson ED, Fidler AE, Friis G, Parody-Merino ÁM, Battley PF, Cox MP, Lima NCB, Prosdocimi F, Parchman TL, Schlinger BA, Loiselle BA, Blake JG, Lim HC, Day LB, Fuxjager MJ, Baldwin MW, Braun MJ, Wirthlin M, Dikow RB, Ryder TB, Camenisch G, Keller LF, DaCosta JM, Hauber ME, Louder MIM, Witt CC, McGuire JA, Mudge J, Megna LC, Carling MD, Wang B, Taylor SA, Del-Rio G, Aleixo A, Vasconcelos ATR, Mello CV, Weir JT, Haussler D, Li Q, Yang H, Wang J, Lei F, Rahbek C, Gilbert MTP, Graves GR, Jarvis ED, Paten B, and Zhang G

Subjects

Animals, Chickens genetics, Conservation of Natural Resources, Datasets as Topic, Finches genetics, Humans, Selection, Genetic genetics, Synteny genetics, Birds classification, Birds genetics, Genome genetics, Genomics methods, Genomics standards, Phylogeny

Abstract

Whole-genome sequencing projects are increasingly populating the tree of life and characterizing biodiversity 1-4 . Sparse taxon sampling has previously been proposed to confound phylogenetic inference 5 , and captures only a fraction of the genomic diversity. Here we report a substantial step towards the dense representation of avian phylogenetic and molecular diversity, by analysing 363 genomes from 92.4% of bird families-including 267 newly sequenced genomes produced for phase II of the Bird 10,000 Genomes (B10K) Project. We use this comparative genome dataset in combination with a pipeline that leverages a reference-free whole-genome alignment to identify orthologous regions in greater numbers than has previously been possible and to recognize genomic novelties in particular bird lineages. The densely sampled alignment provides a single-base-pair map of selection, has more than doubled the fraction of bases that are confidently predicted to be under conservation and reveals extensive patterns of weak selection in predominantly non-coding DNA. Our results demonstrate that increasing the diversity of genomes used in comparative studies can reveal more shared and lineage-specific variation, and improve the investigation of genomic characteristics. We anticipate that this genomic resource will offer new perspectives on evolutionary processes in cross-species comparative analyses and assist in efforts to conserve species.

Published

2020

48. Interspecific Gene Flow and the Evolution of Specialization in Black and White Rhinoceros.

Author

Moodley Y, Westbury MV, Russo IM, Gopalakrishnan S, Rakotoarivelo A, Olsen RA, Prost S, Tunstall T, Ryder OA, Dalén L, and Bruford MW

Subjects

Animals, Feeding Behavior, Female, Genome, Male, Mutation Rate, Gene Flow, Perissodactyla genetics, Reproductive Isolation

Abstract

Africa's black (Diceros bicornis) and white (Ceratotherium simum) rhinoceros are closely related sister-taxa that evolved highly divergent obligate browsing and grazing feeding strategies. Although their precursor species Diceros praecox and Ceratotherium mauritanicum appear in the fossil record ∼5.2 Ma, by 4 Ma both were still mixed feeders, and were even spatiotemporally sympatric at several Pliocene sites in what is today Africa's Rift Valley. Here, we ask whether or not D. praecox and C. mauritanicum were reproductively isolated when they came into Pliocene secondary contact. We sequenced and de novo assembled the first annotated black rhinoceros reference genome and compared it with available genomes of other black and white rhinoceros. We show that ancestral gene flow between D. praecox and C. mauritanicum ceased sometime between 3.3 and 4.1 Ma, despite conventional methods for the detection of gene flow from whole genome data returning false positive signatures of recent interspecific migration due to incomplete lineage sorting. We propose that ongoing Pliocene genetic exchange, for up to 2 My after initial divergence, could have potentially hindered the development of obligate feeding strategies until both species were fully reproductively isolated, but that the more severe and shifting paleoclimate of the early Pleistocene was likely the ultimate driver of ecological specialization in African rhinoceros., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2020

49. Pre-extinction Demographic Stability and Genomic Signatures of Adaptation in the Woolly Rhinoceros.

Author

Lord E, Dussex N, Kierczak M, Díez-Del-Molino D, Ryder OA, Stanton DWG, Gilbert MTP, Sánchez-Barreiro F, Zhang G, Sinding MS, Lorenzen ED, Willerslev E, Protopopov A, Shidlovskiy F, Fedorov S, Bocherens H, Nathan SKSS, Goossens B, van der Plicht J, Chan YL, Prost S, Potapova O, Kirillova I, Lister AM, Heintzman PD, Kapp JD, Shapiro B, Vartanyan S, Götherström A, and Dalén L

Subjects

Animals, Climate Change, Extinction, Biological, Fossils, Genome genetics, Genomics methods, Population Density, Population Dynamics, Archaeology methods, DNA, Ancient analysis, Perissodactyla genetics

Abstract

Ancient DNA has significantly improved our understanding of the evolution and population history of extinct megafauna. However, few studies have used complete ancient genomes to examine species responses to climate change prior to extinction. The woolly rhinoceros (Coelodonta antiquitatis) was a cold-adapted megaherbivore widely distributed across northern Eurasia during the Late Pleistocene and became extinct approximately 14 thousand years before present (ka BP). While humans and climate change have been proposed as potential causes of extinction [1-3], knowledge is limited on how the woolly rhinoceros was impacted by human arrival and climatic fluctuations [2]. Here, we use one complete nuclear genome and 14 mitogenomes to investigate the demographic history of woolly rhinoceros leading up to its extinction. Unlike other northern megafauna, the effective population size of woolly rhinoceros likely increased at 29.7 ka BP and subsequently remained stable until close to the species' extinction. Analysis of the nuclear genome from a ∼18.5-ka-old specimen did not indicate any increased inbreeding or reduced genetic diversity, suggesting that the population size remained steady for more than 13 ka following the arrival of humans [4]. The population contraction leading to extinction of the woolly rhinoceros may have thus been sudden and mostly driven by rapid warming in the Bølling-Allerød interstadial. Furthermore, we identify woolly rhinoceros-specific adaptations to arctic climate, similar to those of the woolly mammoth. This study highlights how species respond differently to climatic fluctuations and further illustrates the potential of palaeogenomics to study the evolutionary history of extinct species., Competing Interests: Declaration of Interests The authors declare no competing interests., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2020

50. Broad host range of SARS-CoV-2 predicted by comparative and structural analysis of ACE2 in vertebrates.

Author

Damas J, Hughes GM, Keough KC, Painter CA, Persky NS, Corbo M, Hiller M, Koepfli KP, Pfenning AR, Zhao H, Genereux DP, Swofford R, Pollard KS, Ryder OA, Nweeia MT, Lindblad-Toh K, Teeling EC, Karlsson EK, and Lewin HA

Subjects

Amino Acids, Animals, Betacoronavirus metabolism, Binding Sites, COVID-19, Coronavirus Infections virology, Evolution, Molecular, Genetic Variation, Host Specificity, Humans, Pandemics, Peptidyl-Dipeptidase A metabolism, Pneumonia, Viral virology, Protein Binding, Receptors, Virus chemistry, Receptors, Virus genetics, Receptors, Virus metabolism, SARS-CoV-2, Selection, Genetic, Spike Glycoprotein, Coronavirus chemistry, Spike Glycoprotein, Coronavirus metabolism, Vertebrates, Betacoronavirus physiology, Coronavirus Infections metabolism, Peptidyl-Dipeptidase A chemistry, Peptidyl-Dipeptidase A genetics, Pneumonia, Viral metabolism

Abstract

The novel coronavirus severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is the cause of COVID-19. The main receptor of SARS-CoV-2, angiotensin I converting enzyme 2 (ACE2), is now undergoing extensive scrutiny to understand the routes of transmission and sensitivity in different species. Here, we utilized a unique dataset of ACE2 sequences from 410 vertebrate species, including 252 mammals, to study the conservation of ACE2 and its potential to be used as a receptor by SARS-CoV-2. We designed a five-category binding score based on the conservation properties of 25 amino acids important for the binding between ACE2 and the SARS-CoV-2 spike protein. Only mammals fell into the medium to very high categories and only catarrhine primates into the very high category, suggesting that they are at high risk for SARS-CoV-2 infection. We employed a protein structural analysis to qualitatively assess whether amino acid changes at variable residues would be likely to disrupt ACE2/SARS-CoV-2 spike protein binding and found the number of predicted unfavorable changes significantly correlated with the binding score. Extending this analysis to human population data, we found only rare (frequency <0.001) variants in 10/25 binding sites. In addition, we found significant signals of selection and accelerated evolution in the ACE2 coding sequence across all mammals, and specific to the bat lineage. Our results, if confirmed by additional experimental data, may lead to the identification of intermediate host species for SARS-CoV-2, guide the selection of animal models of COVID-19, and assist the conservation of animals both in native habitats and in human care., Competing Interests: The authors declare no competing interest., (Copyright © 2020 the Author(s). Published by PNAS.)

Published

2020