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1. Expanding from local to continental scale—A genetic assessment of the Eurasian wolverine

Author

Bujnáková, Dominika, Lansink, Gerhardus M. J., Abramov, Alexei V., Bulyonkova, Tatiana, Dokuchaev, Nikolai E., Domanov, Trofim, Dvornikov, Mikhail G., Graphodatsky, Alexander, Karabanina, Ekaterina, Kliver, Sergei, Korolev, Andrey N., Kozhechkin, Vladimir V., Litvinov, Yuri N., Mamaev, Nikolay, Monakhov, Vladimir G., Nanova, Olga, Okhlopkov, Innokentiy, Saveljev, Alexander P., Schinov, Anton, Shiriaeva, Elena, Sidorov, Mikhail, Tirronen, Konstantin F., Zakharov, Evgenii S., Zakharova, Nadezhda N., Aspi, Jouni, and Kvist, Laura

Published
2024

2. Widespread horse-based mobility arose around 2200 BCE in Eurasia.

Author

Librado, Pablo, Tressières, Gaetan, Chauvey, Lorelei, Fages, Antoine, Khan, Naveed, Schiavinato, Stéphanie, Calvière-Tonasso, Laure, Kusliy, Mariya, Gaunitz, Charleen, Liu, Xuexue, Wagner, Stefanie, Der Sarkissian, Clio, Seguin-Orlando, Andaine, Perdereau, Aude, Aury, Jean-Marc, Southon, John, Shapiro, Beth, Bouchez, Olivier, Donnadieu, Cécile, Collin, Yvette, Gregersen, Kristian, Jessen, Mads, Christensen, Kirsten, Claudi-Hansen, Lone, Pruvost, Mélanie, Pucher, Erich, Vulic, Hrvoje, Novak, Mario, Rimpf, Andrea, Turk, Peter, Reiter, Simone, Brem, Gottfried, Schwall, Christoph, Barrey, Éric, Robert, Céline, Degueurce, Christophe, Horwitz, Liora, Klassen, Lutz, Rasmussen, Uffe, Kveiborg, Jacob, Johannsen, Niels, Makowiecki, Daniel, Makarowicz, Przemysław, Szeliga, Marcin, Ilchyshyn, Vasyl, Rud, Vitalii, Romaniszyn, Jan, Mullin, Victoria, Verdugo, Marta, Bradley, Daniel, Cardoso, João, Valente, Maria, Telles Antunes, Miguel, Ameen, Carly, Thomas, Richard, Ludwig, Arne, Marzullo, Matilde, Prato, Ornella, Bagnasco Gianni, Giovanna, Tecchiati, Umberto, Granado, José, Schlumbaum, Angela, Deschler-Erb, Sabine, Mráz, Monika, Boulbes, Nicolas, Gardeisen, Armelle, Mayer, Christian, Döhle, Hans-Jürgen, Vicze, Magdolna, Kosintsev, Pavel, Kyselý, René, Peške, Lubomír, OConnor, Terry, Ananyevskaya, Elina, Shevnina, Irina, Logvin, Andrey, Kovalev, Alexey, Iderkhangai, Tumur-Ochir, Sablin, Mikhail, Dashkovskiy, Petr, Graphodatsky, Alexander, Merts, Ilia, Merts, Viktor, Kasparov, Aleksei, Pitulko, Vladimir, Onar, Vedat, Öztan, Aliye, Arbuckle, Benjamin, McColl, Hugh, Renaud, Gabriel, Khaskhanov, Ruslan, Demidenko, Sergey, Kadieva, Anna, Atabiev, Biyaslan, Sundqvist, Marie, Lindgren, Gabriella, López-Cachero, F, Albizuri, Silvia, Trbojević Vukičević, Tajana, and Rapan Papeša, Anita

Abstract

Horses revolutionized human history with fast mobility1. However, the timeline between their domestication and their widespread integration as a means of transport remains contentious2-4. Here we assemble a collection of 475 ancient horse genomes to assess the period when these animals were first reshaped by human agency in Eurasia. We find that reproductive control of the modern domestic lineage emerged around 2200 BCE, through close-kin mating and shortened generation times. Reproductive control emerged following a severe domestication bottleneck starting no earlier than approximately 2700 BCE, and coincided with a sudden expansion across Eurasia that ultimately resulted in the replacement of nearly every local horse lineage. This expansion marked the rise of widespread horse-based mobility in human history, which refutes the commonly held narrative of large horse herds accompanying the massive migration of steppe peoples across Europe around 3000 BCE and earlier3,5. Finally, we detect significantly shortened generation times at Botai around 3500 BCE, a settlement from central Asia associated with corrals and a subsistence economy centred on horses6,7. This supports local horse husbandry before the rise of modern domestic bloodlines.

Published
2024

3. Detailed cytogenetic analysis of three duck species (the northern pintail, mallard, and common goldeneye) and karyotype evolution in the family Anatidae (Anseriformes, Aves)

Author

V. R. Beklemisheva, K. V. Tishakova, S. A. Romanenko, D. A. Andreushkova, V. A. Yudkin, E. А. Interesova, F. Yang, M. A. Ferguson-Smith, A. S. Graphodatsky, and A. A. Proskuryakova

Subjects
anas acuta, anas platyrhynchos, bucephala clangula, burhinus oedicnemus, comparative chromosome painting, constitutive heterochromatin, ribosomal genes, telomere, Genetics, QH426-470
Abstract

Galliformes and Anseriformes are two branches of the Galloanserae group, basal to other Neognathae. In contrast to Galliformes, Anseriformes have not been thoroughly researched by cytogenetic methods. This report is focused on representatives of Anseriformes and the evolution of their chromosome sets. Detailed cytogenetic analysis (G-banding, C-banding, and fluorescence in situ hybridization) was performed on three duck species: the northern pintail (Anas acuta, 2n = 80), the mallard (A. platyrhynchos, 2n = 80), and the common goldeneye (Bucephala clangula, 2n = 80). Using stone curlew (Burhinus oedicnemus, 2n = 42, Charadriiformes) chromosome painting probes, we created homology maps covering macrochromosomes and some microchromosomes. The results indicated a high level of syntenic group conservation among the duck genomes. The two Anas species share their macrochromosome number, whereas in B. clangula, this number is increased due to fissions of two ancestral elements. Additionally, in this species, the presence of massive heterochromatic blocks in most macroautosomes and sex chromosomes was discovered. Localization of clusters of ribosomal DNA and telomere repeats revealed that the duck karyotypes contain some microchromosomes that bear ribosomal RNA genes and/or are enriched for telomere repeats and constitutive heterochromatin. Dot plot (D-GENIES) analysis confirmed the established view about the high level of syntenic group conservation among Anatidae genomes. The new data about the three Anatidae species add knowledge about the transformation of macro- and sex chromosomes of Anseriformes during evolution.

Published
2024
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4. Species Identification of Ancient and Medieval Representatives of the Genus Equus based on Genetic Data

Author

Maria A. Kusliy, Dmitry G. Malikov, Igor V. Askeyev, Alexey M. Klementyev, Nadezhda V. Vorobieva, Alexander S. Graphodatsky, and Anna S. Molodtseva

Subjects
archaeozoology, molecular genetic analysis, ancient dna, horse, equus, phylogenetics, Archaeology, CC1-960
Abstract

Since one of the peculiarities of the evolutionary history of representatives of the genus Equus (horses, asses and zebras) is the high similarity of the morphology of the skeletons of different species of this genus, morphometric characteristics do not always make it possible to determine the species identity of the discovered horse bone samples. This is especially true for scattered bones and incomplete teeth found separately from whole skeletons. In such a situation, molecular genetic analysis becomes important, which makes it possible to more accurately determine the species. On the basis of mitogenomic data alone, it is difficult to determine whether a sample belongs to a domestic or wild horse; this requires genome-wide analysis. Based on the mitogenome data, it is possible to distinguish clearly different species of the genus Equus from each other. In this work, the authors studied 4 bone samples of ancient horses and 1 bone sample of a medieval horse, found in the Middle Volga region and Southern Siberia. Using the target enrichment method, mitogenomic libraries were obtained for them and their high-throughput sequencing was carried out. Secondary bioinformatics analysis and subsequent analysis of individual reads and phylogenetic reconstructions based on the consensus sequences of the mitogenomes of the studied samples, modern horses from different regions of the world and reference sequences of the domestic horse, Lena horse, Ovodov horse and onager demonstrated the attribution of the studied samples to the above-mentioned species of the genus Equus. Authors’ data showed the preference for using genome-wide sequences to determine the species identity of ancient and modern samples compared to the analysis of individual genetic markers.

Published
2024
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6. Integration of fluorescence in situ hybridization and chromosome-length genome assemblies revealed synteny map for guinea pig, naked mole-rat, and human

Author

Svetlana A. Romanenko, Sergei F. Kliver, Natalia A. Serdyukova, Polina L. Perelman, Vladimir A. Trifonov, Andrei Seluanov, Vera Gorbunova, Jorge Azpurua, Jorge C. Pereira, Malcolm A. Ferguson-Smith, and Alexander S. Graphodatsky

Subjects
Medicine, Science
Abstract

Abstract Descriptions of karyotypes of many animal species are currently available. In addition, there has been a significant increase in the number of sequenced genomes and an ever-improving quality of genome assembly. To close the gap between genomic and cytogenetic data we applied fluorescent in situ hybridization (FISH) and Hi-C technology to make the first full chromosome-level genome comparison of the guinea pig (Cavia porcellus), naked mole-rat (Heterocephalus glaber), and human. Comparative chromosome maps obtained by FISH with chromosome-specific probes link genomic scaffolds to individual chromosomes and orient them relative to centromeres and heterochromatic blocks. Hi-C assembly made it possible to close all gaps on the comparative maps and to reveal additional rearrangements that distinguish the karyotypes of the three species. As a result, we integrated the bioinformatic and cytogenetic data and adjusted the previous comparative maps and genome assemblies of the guinea pig, naked mole-rat, and human. Syntenic associations in the two hystricomorphs indicate features of their putative ancestral karyotype. We postulate that the two approaches applied in this study complement one another and provide complete information about the organization of these genomes at the chromosome level.

Published
2023
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7. Comparative studies of X chromosomes in Cervidae family

Author

Anastasia A. Proskuryakova, Ekaterina S. Ivanova, Alexey I. Makunin, Denis M. Larkin, Malcolm A. Ferguson-Smith, Fengtang Yang, Olga V. Uphyrkina, Polina L. Perelman, and Alexander S. Graphodatsky

Subjects
Medicine, Science
Abstract

Abstract The family Cervidae is the second most diverse in the infraorder Pecora and is characterized by variability in the diploid chromosome numbers among species. X chromosomes in Cervidae evolved through complex chromosomal rearrangements of conserved segments within the chromosome, changes in centromere position, heterochromatic variation, and X-autosomal translocations. The family Cervidae consists of two subfamilies: Cervinae and Capreolinae. Here we build a detailed X chromosome map with 29 cattle bacterial artificial chromosomes of representatives of both subfamilies: reindeer (Rangifer tarandus), gray brocket deer (Mazama gouazoubira), Chinese water deer (Hydropotes inermis) (Capreolinae); black muntjac (Muntiacus crinifrons), tufted deer (Elaphodus cephalophus), sika deer (Cervus nippon) and red deer (Cervus elaphus) (Cervinae). To track chromosomal rearrangements during Cervidae evolution, we summarized new data, and compared them with available X chromosomal maps and chromosome level assemblies of other species. We demonstrate the types of rearrangements that may have underlined the variability of Cervidae X chromosomes. We detected two types of cervine X chromosome—acrocentric and submetacentric. The acrocentric type is found in three independent deer lineages (subfamily Cervinae and in two Capreolinae tribes—Odocoileini and Capreolini). We show that chromosomal rearrangements on the X-chromosome in Cervidae occur at a higher frequency than in the entire Ruminantia lineage: the rate of rearrangements is 2 per 10 million years.

Published
2023
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11. Chromosome-length genome assemblies and cytogenomic analyses of pangolins reveal remarkable chromosome counts and plasticity

Author

Houck, Marlys L., Koepfli, Klaus-Peter, Hains, Taylor, Khan, Ruqayya, Charter, Suellen J., Fronczek, Julie A., Misuraca, Ann C., Kliver, Sergei, Perelman, Polina L., Beklemisheva, Violetta, Graphodatsky, Alexander, Luo, Shu-Jin, O’Brien, Stephen J., Lim, Norman T.-L., Chin, Jason S. C., Guerra, Vanessa, Tamazian, Gaik, Omer, Arina, Weisz, David, Kaemmerer, Kenneth, Sturgeon, Ginger, Gaspard, Joseph, Hahn, Alicia, McDonough, Mark, Garcia-Treviño, Isabel, Gentry, Jordan, Coke, Rob L., Janecka, Jan E., Harrigan, Ryan J., Tinsman, Jen, Smith, Thomas B., Aiden, Erez Lieberman, and Dudchenko, Olga

Published
2023
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12. Precision nomenclature for the new genomics

Author

Lewin, Harris A, Graves, Jennifer A Marshall, Ryder, Oliver A, Graphodatsky, Alexander S, and O'Brien, Stephen J

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Philosophy and Religious Studies, Genetics, Human Genome, Biotechnology, Generic health relevance, Animals, Genome, Genomics, Humans, Terminology as Topic
Abstract

The confluence of two scientific disciplines may lead to nomenclature conflicts that require new terms while respecting historical definitions. This is the situation with the current state of cytology and genomics, which offer examples of distinct nomenclature and vocabularies that require reconciliation. In this article, we propose the new terms C-scaffold (for chromosome-scale assemblies of sequenced DNA fragments, commonly named scaffolds) and scaffotype (the resulting collection of C-scaffolds that represent an organism's genome). This nomenclature avoids conflict with the historical definitions of the terms chromosome (a microscopic body made of DNA and protein) and karyotype (the collection of images of all chromosomes of an organism or species). As large-scale sequencing projects progress, adoption of this nomenclature will assist end users to properly classify genome assemblies, thus facilitating genomic analysis.

Published
2019

13. An integrated chromosome-scale genome assembly of the Masai giraffe (Giraffa camelopardalis tippelskirchi)

Author

Farré, Marta, Li, Qiye, Darolti, Iulia, Zhou, Yang, Damas, Joana, Proskuryakova, Anastasia A, Kulemzina, Anastasia I, Chemnick, Leona G, Kim, Jaebum, Ryder, Oliver A, Ma, Jian, Graphodatsky, Alexander S, Zhang, Guoije, Larkin, Denis M, and Lewin, Harris A

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Genetics, Biotechnology, Human Genome, Life on Land, Animals, Chromosomes, Mammalian, Computational Biology, Evolution, Molecular, Genome, Genomics, Giraffes, High-Throughput Nucleotide Sequencing, Karyotyping, Molecular Sequence Annotation, Phylogeny, giraffe, Giraffa camelopardalis tippelskirchi, assembly, annotation, ruminant, Giraffa camelopardalis tippelskirchi
Abstract

The Masai giraffe (Giraffa camelopardalis tippelskirchi) is the largest-bodied giraffe and the world's tallest terrestrial animal. With its extreme size and height, the giraffe's unique anatomical and physiological adaptations have long been of interest to diverse research fields. Giraffes are also critical to ecosystems of sub-Saharan Africa, with their long neck serving as a conduit to food sources not shared by other herbivores. Although the genome of a Masai giraffe has been sequenced, the assembly was highly fragmented and suboptimal for genome analysis. Herein we report an improved giraffe genome assembly to facilitate evolutionary analysis of the giraffe and other ruminant genomes. Using SOAPdenovo2 and 170 Gbp of Illumina paired-end and mate-pair reads, we generated a 2.6-Gbp male Masai giraffe genome assembly, with a scaffold N50 of 3 Mbp. The incorporation of 114.6 Gbp of Chicago library sequencing data resulted in a HiRise SOAPdenovo + Chicago assembly with an N50 of 48 Mbp and containing 95% of expected genes according to BUSCO analysis. Using the Reference-Assisted Chromosome Assembly tool, we were able to order and orient scaffolds into 42 predicted chromosome fragments (PCFs). Using fluorescence in situ hybridization, we placed 153 cattle bacterial artificial chromosomes onto giraffe metaphase spreads to assess and assign the PCFs on 14 giraffe autosomes and the X chromosome resulting in the final assembly with an N50 of 177.94 Mbp. In this assembly, 21,621 protein-coding genes were identified using both de novo and homology-based predictions. We have produced the first chromosome-scale genome assembly for a Giraffidae species. This assembly provides a valuable resource for the study of artiodactyl evolution and for understanding the molecular basis of the unique adaptive traits of giraffes. In addition, the assembly will provide a powerful resource to assist conservation efforts of Masai giraffe, whose population size has declined by 52% in recent years.

Published
2019

14. Evolution of gene regulation in ruminants differs between evolutionary breakpoint regions and homologous synteny blocks

Author

Farré, Marta, Kim, Jaebum, Proskuryakova, Anastasia A, Zhang, Yang, Kulemzina, Anastasia I, Li, Qiye, Zhou, Yang, Xiong, Yingqi, Johnson, Jennifer L, Perelman, Polina L, Johnson, Warren E, Warren, Wesley C, Kukekova, Anna V, Zhang, Guojie, O'Brien, Stephen J, Ryder, Oliver A, Graphodatsky, Alexander S, Ma, Jian, Lewin, Harris A, and Larkin, Denis M

Subjects
Human Genome, Genetics, Underpinning research, 1.1 Normal biological development and functioning, Animals, Chromosome Breakpoints, DNA Transposable Elements, Enhancer Elements, Genetic, Evolution, Molecular, Karyotype, Protein Binding, Ruminants, Selection, Genetic, Synteny, Transcription Factors, Biological Sciences, Medical and Health Sciences, Bioinformatics
Abstract

The role of chromosome rearrangements in driving evolution has been a long-standing question of evolutionary biology. Here we focused on ruminants as a model to assess how rearrangements may have contributed to the evolution of gene regulation. Using reconstructed ancestral karyotypes of Cetartiodactyls, Ruminants, Pecorans, and Bovids, we traced patterns of gross chromosome changes. We found that the lineage leading to the ruminant ancestor after the split from other cetartiodactyls was characterized by mostly intrachromosomal changes, whereas the lineage leading to the pecoran ancestor (including all livestock ruminants) included multiple interchromosomal changes. We observed that the liver cell putative enhancers in the ruminant evolutionary breakpoint regions are highly enriched for DNA sequences under selective constraint acting on lineage-specific transposable elements (TEs) and a set of 25 specific transcription factor (TF) binding motifs associated with recently active TEs. Coupled with gene expression data, we found that genes near ruminant breakpoint regions exhibit more divergent expression profiles among species, particularly in cattle, which is consistent with the phylogenetic origin of these breakpoint regions. This divergence was significantly greater in genes with enhancers that contain at least one of the 25 specific TF binding motifs and located near bovidae-to-cattle lineage breakpoint regions. Taken together, by combining ancestral karyotype reconstructions with analysis of cis regulatory element and gene expression evolution, our work demonstrated that lineage-specific regulatory elements colocalized with gross chromosome rearrangements may have provided valuable functional modifications that helped to shape ruminant evolution.

Published
2019

15. Widespread horse-based mobility arose around 2,200 BCE in Eurasia

Author

Librado, Pablo, primary, Tressières, Gaetan, additional, Chauvey, Lorelei, additional, Fages, Antoine, additional, Khan, Naveed, additional, Schiavinato, Stéphanie, additional, Calvière-Tonasso, Laure, additional, Kusliy, Mariya A., additional, Gaunitz, Charleen, additional, Liu, Xuexue, additional, Wagner, Stefanie, additional, Der Sarkissian, Clio, additional, Seguin-Orlando, Andaine, additional, Perdereau, Aude, additional, Aury, Jean-Marc, additional, Southon, John, additional, Shapiro, Beth, additional, Bouchez, Olivier, additional, Donnadieu, Cécile, additional, Collin, Yvette Running Horse, additional, Gregersen, Kristian M., additional, Jessen, Mads Dengsø, additional, Christensen, Kirsten, additional, Claudi-Hansen, Lone, additional, Pruvost, Mélanie, additional, Pucher, Erich, additional, Vulic, Hrvoje, additional, Novak, Mario, additional, Rimpf, Andrea, additional, Turk, Peter, additional, Reiter, Simone, additional, Brem, Gottfried, additional, Schwall, Christoph, additional, Barrey, Éric, additional, Robert, Céline, additional, Degueurce, Christophe, additional, Horwitz, Liora Kolska, additional, Klassen, Lutz, additional, Rasmussen, Uffe, additional, Kveiborg, Jacob, additional, Johannsen, Niels Nørkjær, additional, Makowiecki, Daniel, additional, Makarowicz, Przemysław, additional, Szeliga, Marcin, additional, Ilchyshyn, Vasyl, additional, Rud, Vitalii, additional, Romaniszyn, Jan, additional, Mullin, Victoria E., additional, Verdugo, Marta, additional, Bradley, Daniel G., additional, Cardoso, João L., additional, Valente, Maria J., additional, Antunes, Miguel Telles, additional, Ameen, Carly, additional, Thomas, Richard, additional, Ludwig, Arne, additional, Marzullo, Matilde, additional, Prato, Ornella, additional, Gianni, Giovanna Bagnasco, additional, Tecchiati, Umberto, additional, Granado, José, additional, Schlumbaum, Angela, additional, Deschler-Erb, Sabine, additional, Mráz, Monika Schernig, additional, Boulbes, Nicolas, additional, Gardeisen, Armelle, additional, Mayer, Christian, additional, Döhle, Hans-Jürgen, additional, Vicze, Magdolna, additional, Kosintsev, Pavel A., additional, Kyselý, René, additional, Peške, Lubomír, additional, O’Connor, Terry, additional, Ananyevskaya, Elina, additional, Shevnina, Irina, additional, Logvin, Andrey, additional, Kovalev, Alexey A., additional, Iderkhangai, Tumur-Ochir, additional, Sablin, Mikhail V., additional, Dashkovskiy, Petr K., additional, Graphodatsky, Alexander S., additional, Merts, Ilia, additional, Merts, Viktor, additional, Kasparov, Aleksei K., additional, Pitulko, Vladimir V., additional, Onar, Vedat, additional, Öztan, Aliye, additional, Arbuckle, Benjamin S., additional, McColl, Hugh, additional, Renaud, Gabriel, additional, Khaskhanov, Ruslan, additional, Demidenko, Sergey, additional, Kadieva, Anna, additional, Atabiev, Biyaslan, additional, Sundqvist, Marie, additional, Lindgren, Gabriella, additional, López-Cachero, F. Javier, additional, Albizuri, Silvia, additional, Trbojević Vukičević, Tajana, additional, Rapan Papeša, Anita, additional, Burić, Marcel, additional, Rajić Šikanjić, Petra, additional, Weinstock, Jaco, additional, Vilaró, David Asensio, additional, Codina, Ferran, additional, Dalmau, Cristina García, additional, de Llorens, Jordi Morer, additional, Pou, Josep, additional, de Prado, Gabriel, additional, Sanmartí, Joan, additional, Kallala, Nabil, additional, Torres, Joan Ramon, additional, Maraoui-Telmini, Bouthéina, additional, Belarte Franco, Maria-Carme, additional, Valenzuela-Lamas, Silvia, additional, Zazzo, Antoine, additional, Lepetz, Sébastien, additional, Duchesne, Sylvie, additional, Alexeev, Anatoly, additional, Bayarsaikhan, Jamsranjav, additional, Houle, Jean-Luc, additional, Bayarkhuu, Noost, additional, Turbat, Tsagaan, additional, Crubézy, Éric, additional, Shingiray, Irina, additional, Mashkour, Marjan, additional, Berezina, Natalia Ya., additional, Korobov, Dmitriy S., additional, Belinskiy, Andrey, additional, Kalmykov, Alexey, additional, Demoule, Jean-Paul, additional, Reinhold, Sabine, additional, Hansen, Svend, additional, Wallner, Barbara, additional, Roslyakova, Natalia, additional, Kuznetsov, Pavel F., additional, Tishkin, Alexey A., additional, Wincker, Patrick, additional, Kanne, Katherine, additional, Outram, Alan, additional, and Orlando, Ludovic, additional

Published
2024
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16. The origins and spread of domestic horses from the Western Eurasian steppes

Author

Librado, Pablo, Khan, Naveed, Fages, Antoine, Kusliy, Mariya A., Suchan, Tomasz, Tonasso-Calvière, Laure, Schiavinato, Stéphanie, Alioglu, Duha, Fromentier, Aurore, Perdereau, Aude, Aury, Jean-Marc, Gaunitz, Charleen, Chauvey, Lorelei, Seguin-Orlando, Andaine, Der Sarkissian, Clio, Southon, John, Shapiro, Beth, Tishkin, Alexey A., Kovalev, Alexey A., Alquraishi, Saleh, Alfarhan, Ahmed H., Al-Rasheid, Khaled A. S., Seregély, Timo, Klassen, Lutz, Iversen, Rune, Bignon-Lau, Olivier, Bodu, Pierre, Olive, Monique, Castel, Jean-Christophe, Boudadi-Maligne, Myriam, Alvarez, Nadir, Germonpré, Mietje, Moskal-del Hoyo, Magdalena, Wilczyński, Jarosław, Pospuła, Sylwia, Lasota-Kuś, Anna, Tunia, Krzysztof, Nowak, Marek, Rannamäe, Eve, Saarma, Urmas, Boeskorov, Gennady, Lōugas, Lembi, Kyselý, René, Peške, Lubomír, Bălășescu, Adrian, Dumitrașcu, Valentin, Dobrescu, Roxana, Gerber, Daniel, Kiss, Viktória, Szécsényi-Nagy, Anna, Mende, Balázs G., Gallina, Zsolt, Somogyi, Krisztina, Kulcsár, Gabriella, Gál, Erika, Bendrey, Robin, Allentoft, Morten E., Sirbu, Ghenadie, Dergachev, Valentin, Shephard, Henry, Tomadini, Noémie, Grouard, Sandrine, Kasparov, Aleksei, Basilyan, Alexander E., Anisimov, Mikhail A., Nikolskiy, Pavel A., Pavlova, Elena Y., Pitulko, Vladimir, Brem, Gottfried, Wallner, Barbara, Schwall, Christoph, Keller, Marcel, Kitagawa, Keiko, Bessudnov, Alexander N., Bessudnov, Alexander, Taylor, William, Magail, Jérome, Gantulga, Jamiyan-Ombo, Bayarsaikhan, Jamsranjav, Erdenebaatar, Diimaajav, Tabaldiev, Kubatbeek, Mijiddorj, Enkhbayar, Boldgiv, Bazartseren, Tsagaan, Turbat, Pruvost, Mélanie, Olsen, Sandra, Makarewicz, Cheryl A., Valenzuela Lamas, Silvia, Albizuri Canadell, Silvia, Nieto Espinet, Ariadna, Iborra, Ma Pilar, Lira Garrido, Jaime, Rodríguez González, Esther, Celestino, Sebastián, Olària, Carmen, Arsuaga, Juan Luis, Kotova, Nadiia, Pryor, Alexander, Crabtree, Pam, Zhumatayev, Rinat, Toleubaev, Abdesh, Morgunova, Nina L., Kuznetsova, Tatiana, Lordkipanize, David, Marzullo, Matilde, Prato, Ornella, Bagnasco Gianni, Giovanna, Tecchiati, Umberto, Clavel, Benoit, Lepetz, Sébastien, Davoudi, Hossein, Mashkour, Marjan, Berezina, Natalia Ya., Stockhammer, Philipp W., Krause, Johannes, Haak, Wolfgang, Morales-Muñiz, Arturo, Benecke, Norbert, Hofreiter, Michael, Ludwig, Arne, Graphodatsky, Alexander S., Peters, Joris, Kiryushin, Kirill Yu., Iderkhangai, Tumur-Ochir, Bokovenko, Nikolay A., Vasiliev, Sergey K., Seregin, Nikolai N., Chugunov, Konstantin V., Plasteeva, Natalya A., Baryshnikov, Gennady F., Petrova, Ekaterina, Sablin, Mikhail, Ananyevskaya, Elina, Logvin, Andrey, Shevnina, Irina, Logvin, Victor, Kalieva, Saule, Loman, Valeriy, Kukushkin, Igor, Merz, Ilya, Merz, Victor, Sakenov, Sergazy, Varfolomeyev, Victor, Usmanova, Emma, Zaibert, Viktor, Arbuckle, Benjamin, Belinskiy, Andrey B., Kalmykov, Alexej, Reinhold, Sabine, Hansen, Svend, Yudin, Aleksandr I., Vybornov, Alekandr A., Epimakhov, Andrey, Berezina, Natalia S., Roslyakova, Natalia, Kosintsev, Pavel A., Kuznetsov, Pavel F., Anthony, David, Kroonen, Guus J., Kristiansen, Kristian, Wincker, Patrick, Outram, Alan, and Orlando, Ludovic

Published
2021
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17. Karyotypic and molecular evidence supports the endemic Tibetan hamsters as a separate divergent lineage of Cricetinae

Author

Svetlana A. Romanenko, Vladimir S. Lebedev, Anna A. Bannikova, Svetlana V. Pavlova, Natalia A. Serdyukova, Natalia Yu. Feoktistova, Qu Jiapeng, Sun Yuehua, Alexey V. Surov, and Alexander S. Graphodatsky

Subjects
Medicine, Science
Abstract

Abstract The genus status of Urocricetus was defined recently based on morphological and molecular data. Even though the amount of evidence for a separate phylogenetic position of this genus among Cricetinae continues to increase, there is still no consensus on its relationship to other groups. Here we give the first comprehensive description of the U. kamensis karyotype (2n = 30, NFa = 50) including results of comparative cytogenetic analysis and detailed examination of its phylogenetic position by means of numerous molecular markers. The molecular data strongly indicated that Urocricetus is a distant sister group to Phodopus. Comparative cytogenetic data showed significant reorganization of the U. kamensis karyotype compared to karyotypes of all other hamsters investigated earlier. The totality of findings undoubtedly means that Urocricetus belongs to a separate divergent lineage of Cricetinae.

Published
2021
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19. Widespread horse-based mobility arose around 2200 bcein Eurasia

Author

Librado, Pablo, Tressières, Gaetan, Chauvey, Lorelei, Fages, Antoine, Khan, Naveed, Schiavinato, Stéphanie, Calvière-Tonasso, Laure, Kusliy, Mariya A., Gaunitz, Charleen, Liu, Xuexue, Wagner, Stefanie, Der Sarkissian, Clio, Seguin-Orlando, Andaine, Perdereau, Aude, Aury, Jean-Marc, Southon, John, Shapiro, Beth, Bouchez, Olivier, Donnadieu, Cécile, Collin, Yvette Running Horse, Gregersen, Kristian M., Jessen, Mads Dengsø, Christensen, Kirsten, Claudi-Hansen, Lone, Pruvost, Mélanie, Pucher, Erich, Vulic, Hrvoje, Novak, Mario, Rimpf, Andrea, Turk, Peter, Reiter, Simone, Brem, Gottfried, Schwall, Christoph, Barrey, Éric, Robert, Céline, Degueurce, Christophe, Horwitz, Liora Kolska, Klassen, Lutz, Rasmussen, Uffe, Kveiborg, Jacob, Johannsen, Niels Nørkjær, Makowiecki, Daniel, Makarowicz, Przemysław, Szeliga, Marcin, Ilchyshyn, Vasyl, Rud, Vitalii, Romaniszyn, Jan, Mullin, Victoria E., Verdugo, Marta, Bradley, Daniel G., Cardoso, João L., Valente, Maria J., Telles Antunes, Miguel, Ameen, Carly, Thomas, Richard, Ludwig, Arne, Marzullo, Matilde, Prato, Ornella, Bagnasco Gianni, Giovanna, Tecchiati, Umberto, Granado, José, Schlumbaum, Angela, Deschler-Erb, Sabine, Mráz, Monika Schernig, Boulbes, Nicolas, Gardeisen, Armelle, Mayer, Christian, Döhle, Hans-Jürgen, Vicze, Magdolna, Kosintsev, Pavel A., Kyselý, René, Peške, Lubomír, O’Connor, Terry, Ananyevskaya, Elina, Shevnina, Irina, Logvin, Andrey, Kovalev, Alexey A., Iderkhangai, Tumur-Ochir, Sablin, Mikhail V., Dashkovskiy, Petr K., Graphodatsky, Alexander S., Merts, Ilia, Merts, Viktor, Kasparov, Aleksei K., Pitulko, Vladimir V., Onar, Vedat, Öztan, Aliye, Arbuckle, Benjamin S., McColl, Hugh, Renaud, Gabriel, Khaskhanov, Ruslan, Demidenko, Sergey, Kadieva, Anna, Atabiev, Biyaslan, Sundqvist, Marie, Lindgren, Gabriella, López-Cachero, F. Javier, Albizuri, Silvia, Trbojević Vukičević, Tajana, Rapan Papeša, Anita, Burić, Marcel, Rajić Šikanjić, Petra, Weinstock, Jaco, Asensio Vilaró, David, Codina, Ferran, García Dalmau, Cristina, Morer de Llorens, Jordi, Pou, Josep, de Prado, Gabriel, Sanmartí, Joan, Kallala, Nabil, Torres, Joan Ramon, Maraoui-Telmini, Bouthéina, Belarte Franco, Maria-Carme, Valenzuela-Lamas, Silvia, Zazzo, Antoine, Lepetz, Sébastien, Duchesne, Sylvie, Alexeev, Anatoly, Bayarsaikhan, Jamsranjav, Houle, Jean-Luc, Bayarkhuu, Noost, Turbat, Tsagaan, Crubézy, Éric, Shingiray, Irina, Mashkour, Marjan, Berezina, Natalia Ya., Korobov, Dmitriy S., Belinskiy, Andrey, Kalmykov, Alexey, Demoule, Jean-Paul, Reinhold, Sabine, Hansen, Svend, Wallner, Barbara, Roslyakova, Natalia, Kuznetsov, Pavel F., Tishkin, Alexey A., Wincker, Patrick, Kanne, Katherine, Outram, Alan, and Orlando, Ludovic

Abstract

Horses revolutionized human history with fast mobility1. However, the timeline between their domestication and their widespread integration as a means of transport remains contentious2–4. Here we assemble a collection of 475 ancient horse genomes to assess the period when these animals were first reshaped by human agency in Eurasia. We find that reproductive control of the modern domestic lineage emerged around 2200 bce, through close-kin mating and shortened generation times. Reproductive control emerged following a severe domestication bottleneck starting no earlier than approximately 2700 bce, and coincided with a sudden expansion across Eurasia that ultimately resulted in the replacement of nearly every local horse lineage. This expansion marked the rise of widespread horse-based mobility in human history, which refutes the commonly held narrative of large horse herds accompanying the massive migration of steppe peoples across Europe around 3000 bceand earlier3,5. Finally, we detect significantly shortened generation times at Botai around 3500 bce, a settlement from central Asia associated with corrals and a subsistence economy centred on horses6,7. This supports local horse husbandry before the rise of modern domestic bloodlines.

Published
2024
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21. Review of population history reconstruction methods in conservation biology

Author

Azamat A. Totikov, Andrey A. Tomarovsky, Aliya R. Yakupova, Alexander S. Graphodatsky, and Sergei F. Kliver

Subjects
Ecology, Health, Toxicology and Mutagenesis, Genetics, Biochemistry, Agricultural and Biological Sciences (miscellaneous), Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Biotechnology
Abstract

Demographic history reconstruction is based on the estimation of effective population size (Ne), which is inferred and interpreted in various fields of evolutionary and conservation biology. Interest in Ne estimation is growing, as the key evolutionary forces and their are linked to Ne, and genetic data become increasingly accessible. However, what is effective population size, and how can we obtain an estimate of effective population size? In this review, we describe the history of the term Ne and explore existing methods for obtaining historical and contemporary estimates of changes in effective population size. We provide a detailed overview of methods based on sequential Markovian coalescence (SMC), generalized phylogenetic coalescence (G-PhoCS), identity by descent (IBD) and identity by state (IBS) similarity, as well as methods using allele frequency spectrum (AFS). For each method, we briefly summarize the underlying theory and note its advantages and disadvantages. In the final section of the review, we present examples of the use of these methods for various non-model species with conservation status.

Published
2023
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24. High genetic diversity of ancient horses from the Ukok Plateau.

Author

Nadezhda V Vorobieva, Alexey I Makunin, Anna S Druzhkova, Mariya A Kusliy, Vladimir A Trifonov, Kseniya O Popova, Natalia V Polosmak, Vyacheslav I Molodin, Sergei K Vasiliev, Michael V Shunkov, and Alexander S Graphodatsky

Subjects
Medicine, Science
Abstract

A growing number of researchers studying horse domestication come to a conclusion that this process happened in multiple locations and involved multiple wild maternal lines. The most promising approach to address this problem involves mitochondrial haplotype comparison of wild and domestic horses from various locations coupled with studies of possible migration routes of the ancient shepherds. Here, we sequenced complete mitochondrial genomes of six horses from burials of the Ukok plateau (Russia, Altai Mountains) dated from 2.7 to 1.4 thousand years before present and a single late Pleistocene wild horse from the neighboring region (Denisova cave). Sequencing data indicates that the wild horse belongs to an extinct pre-domestication lineage. Integration of the domestic horse data with known Eurasian haplotypes of a similar age revealed two distinct groups: the first one widely distributed in Europe and presumably imported to Altai, and the second one specific for Altai Mountains and surrounding area.

Published
2020
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25. Overexpression of rRNA genes in a patient with intellectual disability and familial 13p+ chromosome

Author

I. S. Kolesnikova, A. A. Tulupov, A. A. Dolskiy, M. A. Lemskaya, A. A. Savelov, E. D. Petrovsky, A. A. Antonov, Yu. V. Maksimova, A. R. Shorina, I. G. Sergeeva, A. S. Telepova, A. S. Graphodatsky, and D. V. Yudkin

Subjects
интеллектуальная недостаточность, рибосомная днк (рднк), рибосомная рнк (ррнк), ядрышкообразующий район (яор), функциональная мрт, тракты головного мозга, Medicine
Abstract

A study of a child with intellectual disability revealed an enlarged p-arm in chromosome 13 and amplified rDNA. qRT-PCR showed an approximately 6-fold increased level of rRNA in the patient’s blood samples. fMRI study revealed changes in uncinate fasciculus. His father is a carrier of the same chromosome, healthy and has a normal level of rRNA.

Published
2018
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26. Chromosomal Evolution of the Talpinae

Author

Biltueva, Larisa S., primary, Vorobieva, Nadezhda V., additional, Lemskya, Natalya A., additional, Perelman, Polina L., additional, Trifonov, Vladimir A., additional, Panov, Victor V., additional, Abramov, Alexey V., additional, Kawada, Shin-ichiro, additional, Serdukova, Natalya A., additional, and Graphodatsky, Alexandr S., additional

Published
2023
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29. Are molecular cytogenetics and bioinformatics suggesting diverging models of ancestral mammalian genomes?

Author

Froenicke, Lutz, Caldés, Montserrat Garcia, Graphodatsky, Alexander, Müller, Stefan, Lyons, Leslie A, Robinson, Terence J, Volleth, Marianne, Yang, Fengtang, and Wienberg, Johannes

Abstract

"Excavating" ancestral genomes The recent release of the chicken genome sequence (Hillier et al. 2004Go) provided exciting news for the comparative genomics community as it allows insights into the early evolution of the human genome. A bird species can now be used as an outgroup to model early mammalian genome organization and reshuffling. The genome sequence data have already been incorporated in a computational analysis of chicken, mouse, rat, and human genome sequences for the reconstruction of the ancestral genome organization of both a mammalian ancestor as well as a murid rodent ancestor (Hillier et al. 2004Go; Bourque et al. 2005Go). This bioinformatic effort joins a molecular cytogenetic model (Richard et al. 2003Go; Yang et al. 2003Go; Robinson et al. 2004Go; Svartman et al. 2004Go; Wienberg 2004Go; Froenicke 2005Go) as the second global approach to explore the architecture of the ancestral eutherian karyotype—a fundamental question in comparative genomics. Since both models use the human genome as reference, they are readily comparable. Surprisingly, however, they share few similarities. Only two small autosomes and the sex chromosomes of the hypothesized ancestral karyotypes are common to both. Unfortunately, given its significance, neither the extent of these differences nor their impact on comparative genomics have been discussed by Bourque and colleagues (2005Go). In an attempt to redress this, we compare the two methods of ancestral genome reconstruction, verify the resulting models, and discuss reasons for their apparent divergence.

Published
2006

31. Red fox genome assembly identifies genomic regions associated with tame and aggressive behaviours

Author

Kukekova, Anna V., Johnson, Jennifer L., Xiang, Xueyan, Feng, Shaohong, Liu, Shiping, Rando, Halie M., Kharlamova, Anastasiya V., Herbeck, Yury, Serdyukova, Natalya A., Xiong, Zijun, Beklemischeva, Violetta, Koepfli, Klaus-Peter, Gulevich, Rimma G., Vladimirova, Anastasiya V., Hekman, Jessica P., Perelman, Polina L., Graphodatsky, Aleksander S., O’Brien, Stephen J., Wang, Xu, Clark, Andrew G., Acland, Gregory M., Trut, Lyudmila N., and Zhang, Guojie

Published
2018
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33. De novo assembling and primary analysis of genome and transcriptome of gray whale Eschrichtius robustus

Author

Alexey А. Moskalev, Anna V. Kudryavtseva, Alexander S. Graphodatsky, Violetta R. Beklemisheva, Natalya A. Serdyukova, Konstantin V. Krutovsky, Vadim V. Sharov, Ivan V. Kulakovskiy, Andrey S. Lando, Artem S. Kasianov, Dmitry A. Kuzmin, Yuliya A. Putintseva, Sergey I. Feranchuk, Mikhail V. Shaposhnikov, Vadim E. Fraifeld, Dmitri Toren, Anastasia V. Snezhkina, and Vasily V. Sitnik

Subjects
Gray whale, Eschrichtius robustus, Genome, Transcriptome, DNA repair, Hypoxia-response, Evolution, QH359-425
Abstract

Abstract Background Gray whale, Eschrichtius robustus (E. robustus), is a single member of the family Eschrichtiidae, which is considered to be the most primitive in the class Cetacea. Gray whale is often described as a “living fossil”. It is adapted to extreme marine conditions and has a high life expectancy (77 years). The assembly of a gray whale genome and transcriptome will allow to carry out further studies of whale evolution, longevity, and resistance to extreme environment. Results In this work, we report the first de novo assembly and primary analysis of the E. robustus genome and transcriptome based on kidney and liver samples. The presented draft genome assembly is complete by 55% in terms of a total genome length, but only by 24% in terms of the BUSCO complete gene groups, although 10,895 genes were identified. Transcriptome annotation and comparison with other whale species revealed robust expression of DNA repair and hypoxia-response genes, which is expected for whales. Conclusions This preliminary study of the gray whale genome and transcriptome provides new data to better understand the whale evolution and the mechanisms of their adaptation to the hypoxic conditions.

Published
2017
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34. Chromosomal Evolution of the Talpinae

Author

Biltueva, Larisa S, primary, Vorobieva, Nadezhda V, additional, Lemskya, Natalya A, additional, Perelman, Polina L., additional, Trifonov, Vladimir A, additional, Panov, Victor V, additional, Abramov, Alexey V, additional, Kawada, Shin-ichiro, additional, Serdukova, Natalya A, additional, and Graphodatsky, Alexandr S, additional

Published
2023
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36. Chromosome-Length Assembly of the Baikal Seal (Pusa sibirica) Genome Reveals a Historically Large Population Prior to Isolation in Lake Baikal

Author

Yakupova, Aliya, Tomarovsky, Andrey, Totikov, Azamat, Beklemisheva, Violetta, Logacheva, Maria, Perelman, Polina L., Komissarov, Aleksey, Dobrynin, Pavel, Krasheninnikova, Ksenia, Tamazian, Gaik, Serdyukova, Natalia A., Rayko, Mike, Bulyonkova, Tatiana, Cherkasov, Nikolay, Pylev, Vladimir, Peterfeld, Vladimir, Penin, Aleksey, Balanovska, Elena, Lapidus, Alla, OBrien, Stephen J., Graphodatsky, Alexander, Koepfli, Klaus-Peter, Kliver, Sergei, Yakupova, Aliya, Tomarovsky, Andrey, Totikov, Azamat, Beklemisheva, Violetta, Logacheva, Maria, Perelman, Polina L., Komissarov, Aleksey, Dobrynin, Pavel, Krasheninnikova, Ksenia, Tamazian, Gaik, Serdyukova, Natalia A., Rayko, Mike, Bulyonkova, Tatiana, Cherkasov, Nikolay, Pylev, Vladimir, Peterfeld, Vladimir, Penin, Aleksey, Balanovska, Elena, Lapidus, Alla, OBrien, Stephen J., Graphodatsky, Alexander, Koepfli, Klaus-Peter, and Kliver, Sergei

Abstract

Pusa sibirica, the Baikal seal, is the only extant, exclusively freshwater, pinniped species. The pending issue is, how and when they reached their current habitat-the rift lake Baikal, more than three thousand kilometers away from the Arctic Ocean. To explore the demographic history and genetic diversity of this species, we generated a de novo chromosome-length assembly, and compared it with three closely related marine pinniped species. Multiple whole genome alignment of the four species compared with their karyotypes showed high conservation of chromosomal features, except for three large inversions on chromosome VI. We found the mean heterozygosity of the studied Baikal seal individuals was relatively low (0.61 SNPs/kbp), but comparable to other analyzed pinniped samples. Demographic reconstruction of seals revealed differing trajectories, yet remarkable variations in Ne occurred during approximately the same time periods. The Baikal seal showed a significantly more severe decline relative to other species. This could be due to the difference in environmental conditions encountered by the earlier populations of Baikal seals, as ice sheets changed during glacial-interglacial cycles. We connect this period to the time of migration to Lake Baikal, which occurred ~3-0.3 Mya, after which the population stabilized, indicating balanced habitat conditions.

Published
2023

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

Author

Kliver, Sergei, Houck, Marlys L., Perelman, Polina L., Totikov, Azamat, Tomarovsky, Andrei, Dudchenko, Olga, Omer, Arina D., Colaric, Zane, Weisz, David, Aiden, Erez Lieberman, Chan, Saki, Hastie, Alex, Komissarov, Aleksey, Ryder, Oliver A., Graphodatsky, Alexander, Johnson, Warren E., Maldonado, Jesús E., Pukazhenthi, Budhan S., Marinari, Paul E., Wildt, David E., Koepfli, Klaus-Peter, Kliver, Sergei, Houck, Marlys L., Perelman, Polina L., Totikov, Azamat, Tomarovsky, Andrei, Dudchenko, Olga, Omer, Arina D., Colaric, Zane, Weisz, David, Aiden, Erez Lieberman, Chan, Saki, Hastie, Alex, Komissarov, Aleksey, Ryder, Oliver A., Graphodatsky, Alexander, Johnson, Warren E., Maldonado, Jesús E., Pukazhenthi, Budhan S., Marinari, Paul E., Wildt, David E., and Koepfli, Klaus-Peter

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 years 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.

Published
2023

38. Chromosome-length genome assemblies and cytogenomic analyses of pangolins reveal remarkable chromosome counts and plasticity

Author

Marlys L. Houck, Klaus-Peter Koepfli, Taylor Hains, Ruqayya Khan, Suellen J. Charter, Julie A. Fronczek, Ann C. Misuraca, Sergei Kliver, Polina L. Perelman, Violetta Beklemisheva, Alexander Graphodatsky, Shu-Jin Luo, Stephen J. O’Brien, Norman T.-L. Lim, Jason S. C. Chin, Vanessa Guerra, Gaik Tamazian, Arina Omer, David Weisz, Kenneth Kaemmerer, Ginger Sturgeon, Joseph Gaspard, Alicia Hahn, Mark McDonough, Isabel Garcia-Treviño, Jordan Gentry, Rob L. Coke, Jan E. Janecka, Ryan J. Harrigan, Jen Tinsman, Thomas B. Smith, Erez Lieberman Aiden, and Olga Dudchenko

Subjects
Genetics
Published
2023
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39. Maps of Constitutive-Heterochromatin Distribution for Four Martes Species (Mustelidae, Carnivora, Mammalia) Show the Formative Role of Macrosatellite Repeats in Interspecific Variation of Chromosome Structure

Author

Beklemisheva, Violetta R., primary, Lemskaya, Natalya A., additional, Prokopov, Dmitry Yu., additional, Perelman, Polina L., additional, Romanenko, Svetlana A., additional, Proskuryakova, Anastasia A., additional, Serdyukova, Natalya A., additional, Utkin, Yaroslav A., additional, Nie, Wenhui, additional, Ferguson-Smith, Malcolm A., additional, Yang, Fentang, additional, and Graphodatsky, Alexander S., additional

Published
2023
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41. Complete mitochondrial genome of an extinct Equus (Sussemionus) ovodovi specimen from Denisova cave (Altai, Russia)

Author

Anna S. Druzhkova, Alexey I. Makunin, Nadezhda V. Vorobieva, Sergey K. Vasiliev, Nikolai D. Ovodov, Mikhail V. Shunkov, Vladimir A. Trifonov, and Alexander S. Graphodatsky

Subjects
equus, ovodovi, sussemionus, equids, ancient, dna, mitochondrial, genome, Genetics, QH426-470
Abstract

Sussemionus is an extinct subgenus of Equus first characterized and delineated in 2010. The almost complete mitochondrial genome is available only for a single specimen of Sussemionus – a 40,000 years old E. ovodovi from Proskuryakova cave (Khakassia, Russia). Our studies of ancient horses from Denisova cave (Altai, Russia) revealed mitochondrial DNA of this species in a 32,000 years old sample. Using alignments to multiple mitochondrial genomes of non-caballine equids, we recovered 100% complete mitochondrial genome of E. ovodovi for the first time. Phylogenetic analysis demonstrates close relationship between this individual and the one previously described in Khakassia.

Published
2017
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43. Genetic History of the Altai Breed Horses: From Ancient Times to Modernity.

Author

Kusliy, Mariya A., Yurlova, Anna A., Neumestova, Alexandra I., Vorobieva, Nadezhda V., Gutorova, Natalya V., Molodtseva, Anna S., Trifonov, Vladimir A., Popova, Kseniya O., Polosmak, Natalia V., Molodin, Vyacheslav I., Vasiliev, Sergei K., Semibratov, Vladimir P., Iderkhangai, Tumur-O., Kovalev, Alexey A., Erdenebaatar, Diimaajav, Graphodatsky, Alexander S., and Tishkin, Alexey A.

Subjects
HORSE breeding, HORSE breeds, MITOCHONDRIAL DNA, HYPERVARIABLE regions, MODERNITY, GENETIC markers
Abstract

This study focuses on expanding knowledge about the genetic diversity of the Altai horse native to Siberia. While studying modern horses from two Altai regions, where horses were subjected to less crossbreeding, we tested the hypothesis, formulated on the basis of morphological data, that the Altai horse is represented by two populations (Eastern and Southern) and that the Mongolian horse has a greater genetic proximity to Eastern Altai horses. Bone samples of ancient horses from different cultures of Altai were investigated to clarify the genetic history of this horse breed. As a genetic marker, we chose hypervariable region I of mitochondrial DNA. The results of the performed phylogenetic and population genetic analyses of our and previously published data confirmed the hypothesis stated above. As we found out, almost all the haplotypes of the ancient domesticated horses of Altai are widespread among modern Altai horses. The differences between the mitochondrial gene pools of the ancient horses of Altai and Mongolia are more significant than between those of modern horses of the respective regions, which is most likely due to an increase in migration processes between these regions after the Early Iron Age. [ABSTRACT FROM AUTHOR]

Published
2023
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44. Comparative Studies of Karyotypes in the Cervidae Family

Author

Anastasia A. Proskuryakova, Ekaterina S. Ivanova, Polina L. Perelman, Malcolm A. Ferguson-Smith, Fentang Yang, Innokentiy M. Okhlopkov, and Alexander S. Graphodatsky

Subjects
Genetics, Molecular Biology, Genetics (clinical)
Abstract

The family Cervidae is the second most diverse family in the infraorder Pecora and is characterized by a striking variability in the diploid chromosome numbers among species, ranging from 6 to 70. Chromosomal rearrangements in Cervidae have been studied in detail by chromosome painting. There are many comparative cytogenetic data for both subfamilies (Cervinae and Capreolinae) based on homologies with chromosomes of cattle and Chinese muntjac. Previously it was found that interchromosomal rearrangements are the major type of rearrangements occurring in the Cervidae family. Here, we build a detailed chromosome map of a female reindeer (Rangifer tarandus, 2n = 70, Capreolinae) and a female black muntjac (Muntiacus crinifrons, 2n = 8, Cervinae) with dromedary homologies to find out what other types of rearrangements may have underlined the variability of Cervidae karyotypes. To track chromosomal rearrangements and the distribution of nucleolus organizer regions not only during Cervidae but also Pecora evolution, we summarized new data and compared them with chromosomal maps of other already studied species. We discuss changes in the pecoran ancestral karyotype in the light of new painting data. We show that intrachromosomal rearrangements in autosomes of Cervidae are more frequent than previously thought: at least 13 inversions in evolutionary breakpoint regions were detected.

Published
2022

47. Draft de novo Genome Assembly of the Elusive Jaguarundi, Puma yagouaroundi

Author

Natalia A. Serdyukova, Aleksey Komissarov, Ksenia Krasheninnikova, Polina L. Perelman, Stephen J. O'Brien, Daria V. Zhernakova, Pavel Dobrynin, Klaus-Peter Koepfli, Sergei Kliver, David W. Mohr, Gaik Tamazian, Alan F. Scott, Nikolay Cherkasov, Alexander S. Graphodatsky, and Anna S. Zhuk

Subjects
Male, AcademicSubjects/SCI01140, 0106 biological sciences, Felidae, genome annotation, Jhered/6, Genome Resources, Sequence assembly, Genomics, 010603 evolutionary biology, 01 natural sciences, Genome, linked reads, 03 medical and health sciences, Puma, biology.animal, Genetics, Animals, Acinonyx jubatus, 10X Genomics Chromium, Molecular Biology, Genetics (clinical), Puma yagouaroundi, 030304 developmental biology, 0303 health sciences, biology, Contig, Molecular Sequence Annotation, Genome project, biology.organism_classification, whole genome assembly, Evolutionary biology, Female, Biotechnology
Abstract

The Puma lineage within the family Felidae consists of 3 species that last shared a common ancestor around 4.9 million years ago. Whole-genome sequences of 2 species from the lineage were previously reported: the cheetah (Acinonyx jubatus) and the mountain lion (Puma concolor). The present report describes a whole-genome assembly of the remaining species, the jaguarundi (Puma yagouaroundi). We sequenced the genome of a male jaguarundi with 10X Genomics linked reads and assembled the whole-genome sequence. The assembled genome contains a series of scaffolds that reach the length of chromosome arms and is similar in scaffold contiguity to the genome assemblies of cheetah and puma, with a contig N50 = 100.2 kbp and a scaffold N50 = 49.27 Mbp. We assessed the assembled sequence of the jaguarundi genome using BUSCO, aligned reads of the sequenced individual and another published female jaguarundi to the assembled genome, annotated protein-coding genes, repeats, genomic variants and their effects with respect to the protein-coding genes, and analyzed differences of the 2 jaguarundis from the reference mitochondrial genome. The jaguarundi genome assembly and its annotation were compared in quality, variants, and features to the previously reported genome assemblies of puma and cheetah. Computational analyzes used in the study were implemented in transparent and reproducible way to allow their further reuse and modification.

Published
2021
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49. Complete Mitochondrial Genomes of Ancient Canids Suggest a European Origin of Domestic Dogs

Author

Thalmann, O., Shapiro, B., Cui, P., Schuenemann, V. J., Sawyer, S. K., Greenfield, D. L., Germonpré, M. B., Sablin, M. V., López-Giráldez, F., Domingo-Roura, X., Napierala, H., Uerpmann, H-P., Loponte, D. M., Acosta, A. A., Giemsch, L., Schmitz, R. W., Worthington, B., Buikstra, J. E., Druzhkova, A., Graphodatsky, A. S., Ovodov, N. D., Wahlberg, N., Freedman, A. H., Schweizer, R. M., Koepfli, K.-P., Leonard, J. A., Meyer, M., Krause, J., Pääbo, S., Green, R. E., and Wayne, R. K.

Published
2013
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50. Performance and automation of ancient DNA capture with RNA hyRAD probes

Author

Stéphanie Schiavinato, Tomasz Suchan, Alexander J.E. Pryor, Keiko Kitagawa, Alexander Bessudnov, Naveed Khan, Marek Nowak, Alan K. Outram, Silvia Valenzuela-Lamas, Johannes Krause, Mariya A. Kusliy, Laure Tonasso-Calvière, Alexander A. Bessudnov, Sylwia Pospuła, Marcel Keller, Alexey A. Tishkin, Lorelei Chauvey, John Southon, Alexander S. Graphodatsky, Krzysztof Tunia, Jarosław Wilczyński, Ludovic Orlando, Magdalena Moskal-del-Hoyo, Centre d'anthropologie et de génomique de Toulouse (CAGT), Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS), Université Toulouse III Paul Sabatier, Centre National de la Recherche Scientifique (France), European Research Council, and Russian Foundation for Basic Research

Subjects
0106 biological sciences, Endogenous content, DNA damage, [SDV]Life Sciences [q-bio], 300 Social sciences, sociology & anthropology, 610 Medicine & health, Computational biology, Biology, 010603 evolutionary biology, 01 natural sciences, Genome, DNA hybridization-caputre techniques, Automation, 03 medical and health sciences, chemistry.chemical_compound, Genetics, Animals, Horses, Performance of hyRad, DNA, Ancient, ComputingMilieux_MISCELLANEOUS, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Ancient DNA, business.industry, RNA, RNA Probes, Sequence Analysis, DNA, Restriction enzyme, chemistry, [SDE]Environmental Sciences, business, DNA, Biotechnology
Abstract

DNA hybridization-capture techniques allow researchers to focus their sequencing efforts on preselected genomic regions. This feature is especially useful when analys- ing ancient DNA (aDNA) extracts, which are often dominated by exogenous environ- mental sources. Here, we assessed, for the first time, the performance of hyRAD as an inexpensive and design-free alternative to commercial capture protocols to obtain authentic aDNA data from osseous remains. HyRAD relies on double enzymatic re- striction of fresh DNA extracts to produce RNA probes that cover only a fraction ofthe genome and can serve as baits for capturing homologous fragments from aDNA li- braries. We found that this approach could retrieve sequence data from horse remains coming from a range of preservation environments, including beyond radiocarbon range, yielding up to 146.5-fold on-target enrichment for aDNA extracts showing ex- tremely low endogenous content (20%¿30%), while the fraction of endogenous reads mapping on- and off-target was relatively insensi- tive to the original endogenous DNA content. Procedures based on two instead of a single round of capture increased on-target coverage up to 3.6-fold. Additionally, we used methylation-sensitive restriction enzymes to produce probes targeting hypo- methylated regions, which improved data quality by reducing post-mortem DNA dam- age and mapping within multicopy regions. Finally, we developed a fully automated hyRAD protocol utilizing inexpensive robotic platforms to facilitate capture process- ing. Overall, our work establishes hyRAD as a cost-effective strategy to recover a set of shared orthologous variants across multiple ancient samples., This project received funding from: the University Paul Sabatier IDEX Chaire d’Excellence (OURASI); the CNRS Programme de Recherche Conjoint (PRC); the CNRS International Research Project (IRP AMADEUS); the European Union’s Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement No. 797449; the Russian Foundation for Basic Research, project No. 19-59-15001 “Horses and their importance in the life of the ancient population of Altai and adjacent territories: interdisciplinary research and reconstruction”; and the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (grant agreement 681605).

Published
2022
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