413 results on '"Chow, William"'
Search Results
152. Towards complete and error-free genome assemblies of all vertebrate species
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Rhie, Arang, McCarthy, Shane A, Fedrigo, Olivier, Damas, Joana, Formenti, Giulio, Koren, Sergey, Uliano-Silva, Marcela, Chow, William, Fungtammasan, Arkarachai, Kim, Juwan, Lee, Chul, Ko, Byung June, Chaisson, Mark, Gedman, Gregory L, Cantin, Lindsey J, Thibaud-Nissen, Francoise, Haggerty, Leanne, Bista, Iliana, Smith, Michelle, Haase, Bettina, Mountcastle, Jacquelyn, Winkler, Sylke, Paez, Sadye, Howard, Jason, Vernes, Sonja C, Lama, Tanya M, Grutzner, Frank, Warren, Wesley C, Balakrishnan, Christopher N, Burt, Dave, George, Julia M, Biegler, Matthew T, Iorns, David, Digby, Andrew, Eason, Daryl, Robertson, Bruce, Edwards, Taylor, Wilkinson, Mark, Turner, George, Meyer, Axel, Kautt, Andreas F, Franchini, Paolo, Detrich, H William, Svardal, Hannes, Wagner, Maximilian, Naylor, Gavin JP, Pippel, Martin, Malinsky, Milan, Mooney, Mark, Simbirsky, Maria, Hannigan, Brett T, Pesout, Trevor, Houck, Marlys, Misuraca, Ann, Kingan, Sarah B, Hall, Richard, Kronenberg, Zev, Sović, Ivan, Dunn, Christopher, Ning, Zemin, Hastie, Alex, Lee, Joyce, Selvaraj, Siddarth, Green, Richard E, Putnam, Nicholas H, Gut, Ivo, Ghurye, Jay, Garrison, Erik, Sims, Ying, Collins, Joanna, Pelan, Sarah, Torrance, James, Tracey, Alan, Wood, Jonathan, Dagnew, Robel E, Guan, Dengfeng, London, Sarah E, Clayton, David F, Mello, Claudio V, Friedrich, Samantha R, Lovell, Peter V, Osipova, Ekaterina, Al-Ajli, Farooq O, Secomandi, Simona, Kim, Heebal, Theofanopoulou, Constantina, Hiller, Michael, Zhou, Yang, Harris, Robert S, Makova, Kateryna D, Medvedev, Paul, Hoffman, Jinna, Masterson, Patrick, Clark, Karen, Martin, Fergal, Howe, Kevin, Flicek, Paul, Walenz, Brian P, Kwak, Woori, Clawson, Hiram, Diekhans, Mark, Nassar, Luis, Paten, Benedict, Kraus, Robert HS, Crawford, Andrew J, Gilbert, M Thomas P, Zhang, Guojie, Venkatesh, Byrappa, Murphy, Robert W, Koepfli, Klaus-Peter, Shapiro, Beth, Johnson, Warren E, Di Palma, Federica, Marques-Bonet, Tomas, Teeling, Emma C, Warnow, Tandy, Graves, Jennifer Marshall, Ryder, Oliver A, Haussler, David, O'Brien, Stephen J, Korlach, Jonas, Lewin, Harris A, Howe, Kerstin, Myers, Eugene W, Durbin, Richard, Phillippy, Adam M, and Jarvis, Erich D
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Genome ,Sex Chromosomes ,High-Throughput Nucleotide Sequencing ,Molecular Sequence Annotation ,Genomics ,Sequence Analysis, DNA ,Birds ,Genome Size ,Haplotypes ,Genome, Mitochondrial ,Vertebrates ,Animals ,14. Life underwater ,Sequence Alignment ,Gene Library - 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 species1-4. To address this issue, the international Genome 10K (G10K) consortium5,6 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.
153. Additional file 4 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
- Subjects
animal structures ,fungi ,14. Life underwater - Abstract
Additional file 4: Table S3: Putative α and β hemoglobin genes from other teleosts and Xenopus tropicalis used to generate phylogenetic trees. The table lists all predicted intact α and β hemoglobin genes indentified within Biomart [69] for teleost genomes that have been sequenced and annotated (medaka, zebrafish, tetraodon, danio) and Xenopus tropicalis, which was used as an outgroup. For each hemoglobin gene identified, the table lists the species, chromosome or scaffold, start and stop positions, strand of transcription, Ensembl gene ID and our assigned gene name used in the phylogenetic trees. (PDF 51 KB)
154. Additional file 2 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,food and beverages ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file 2: Table S2A-C: Identified Atlantic salmon putatively functional and pseudogenized hemoglobin genes. S2A) Identified putatively functional Atlantic salmon α hemoglobin genes with chromosome, sequence contig number and approximate location (kb), strand of transcription, most highly similar Atlantic salmon EST cluster (if any), whether the gene has a corresponding full-length EST, whether the gene matches any of the previously published Atlantic salmon hemoglobin genes at the amino acid level and whether the gene is identical to any of those identified on the other Atlantic salmon chromosome. S2B) Identified putatively functional Atlantic salmon β hemoglobin genes with chromosome, sequence contig number and approximate location (kb), strand of transcription, most highly similar Atlantic salmon EST cluster (if any), whether the gene has a corresponding full-length EST, whether the gene matches any of the previously identified Atlantic salmon hemoglobin genes at the amino acid level, whether the gene is identical to any of those identified on the other Atlantic salmon chromosome, and whether the β hemoglobin gene possesses the hallmarks of lacking the Bohr effect. S2C) Putatively identified Atlantic salmon hemoglobin pseudogenes with chromosome, sequence contig, location (kb), direction and descriptions of each exon. (PDF 46 KB)
155. Additional file 9 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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Data_FILES ,14. Life underwater - Abstract
Authors’ original file for figure 5
156. Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,animal diseases ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
157. Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,animal diseases ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
158. Additional file 10 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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Data_FILES ,14. Life underwater - Abstract
Authors’ original file for figure 6
159. An improved pig reference genome sequence to enable pig genetics and genomics research
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Warr, Amanda, Affara, Nabeel, Aken, Bronwen, Beiki, Hamid, Bickhart, Derek M, Billis, Konstantinos, Chow, William, Eory, Lel, Finlayson, Heather A, Flicek, Paul, Girón, Carlos G, Griffin, Darren K, Hall, Richard, Hannum, Greg, Hourlier, Thibaut, Howe, Kerstin, Hume, David A, Izuogu, Osagie, Kim, Kristi, Koren, Sergey, Liu, Haibou, Manchanda, Nancy, Martin, Fergal J, Nonneman, Dan J, O'Connor, Rebecca E, Phillippy, Adam M, Rohrer, Gary A, Rosen, Benjamin D, Rund, Laurie A, Sargent, Carole A, Schook, Lawrence B, Schroeder, Steven G, Schwartz, Ariel S, Skinner, Ben M, Talbot, Richard, Tseng, Elizabeth, Tuggle, Christopher K, Watson, Mick, Smith, Timothy PL, and Archibald, Alan L
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2. Zero hunger ,pig ,reference assembly ,Genome ,genome annotation ,Swine ,Research ,Sus scrofa ,Computational Biology ,Reproducibility of Results ,Molecular Sequence Annotation ,Genomics ,Sequence Analysis, DNA ,pig genomes ,Animals - Abstract
BACKGROUND: The domestic pig (Sus scrofa) is important both as a food source and as a biomedical model given its similarity in size, anatomy, physiology, metabolism, pathology, and pharmacology to humans. The draft reference genome (Sscrofa10.2) of a purebred Duroc female pig established using older clone-based sequencing methods was incomplete, and unresolved redundancies, short-range order and orientation errors, and associated misassembled genes limited its utility. RESULTS: We present 2 annotated highly contiguous chromosome-level genome assemblies created with more recent long-read technologies and a whole-genome shotgun strategy, 1 for the same Duroc female (Sscrofa11.1) and 1 for an outbred, composite-breed male (USMARCv1.0). Both assemblies are of substantially higher (>90-fold) continuity and accuracy than Sscrofa10.2. CONCLUSIONS: These highly contiguous assemblies plus annotation of a further 11 short-read assemblies provide an unprecedented view of the genetic make-up of this important agricultural and biomedical model species. We propose that the improved Duroc assembly (Sscrofa11.1) become the reference genome for genomic research in pigs.
160. Additional file 9 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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Data_FILES ,14. Life underwater - Abstract
Authors’ original file for figure 5
161. Additional file 6 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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Data_FILES ,14. Life underwater - Abstract
Authors’ original file for figure 2
162. Additional file 2 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
- Subjects
endocrine system ,food and beverages ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file 2: Table S2A-C: Identified Atlantic salmon putatively functional and pseudogenized hemoglobin genes. S2A) Identified putatively functional Atlantic salmon α hemoglobin genes with chromosome, sequence contig number and approximate location (kb), strand of transcription, most highly similar Atlantic salmon EST cluster (if any), whether the gene has a corresponding full-length EST, whether the gene matches any of the previously published Atlantic salmon hemoglobin genes at the amino acid level and whether the gene is identical to any of those identified on the other Atlantic salmon chromosome. S2B) Identified putatively functional Atlantic salmon β hemoglobin genes with chromosome, sequence contig number and approximate location (kb), strand of transcription, most highly similar Atlantic salmon EST cluster (if any), whether the gene has a corresponding full-length EST, whether the gene matches any of the previously identified Atlantic salmon hemoglobin genes at the amino acid level, whether the gene is identical to any of those identified on the other Atlantic salmon chromosome, and whether the β hemoglobin gene possesses the hallmarks of lacking the Bohr effect. S2C) Putatively identified Atlantic salmon hemoglobin pseudogenes with chromosome, sequence contig, location (kb), direction and descriptions of each exon. (PDF 46 KB)
163. Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,animal diseases ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
164. Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,animal diseases ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
165. Additional file 8 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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Data_FILES ,14. Life underwater - Abstract
Authors’ original file for figure 4
166. Towards complete and error-free genome assemblies of all vertebrate species
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Rhie, Arang, McCarthy, Shane A., Fedrigo, Olivier, Damas, Joana, Formenti, Giulio, Koren, Sergey, Uliano-Silva, Marcela, Chow, William, Fungtammasan, Arkarachai, Kim, Juwan, Lee, Chul, Ko, Byung June, Chaisson, Mark, Gedman, Gregory L., Cantin, Lindsey J., Thibaud-Nissen, Francoise, Haggerty, Leanne, Bista, Iliana, Smith, Michelle, Haase, Bettina, Mountcastle, Jacquelyn, Winkler, Sylke, Paez, Sadye, Howard, Jason, Vernes, Sonja C., Lama, Tanya M., Grutzner, Frank, Warren, Wesley C., Balakrishnan, Christopher N., Burt, Dave, George, Julia M., Biegler, Matthew T., Iorns, David, Digby, Andrew, Eason, Daryl, Robertson, Bruce, Edwards, Taylor, Wilkinson, Mark, Turner, George, Meyer, Axel, Kautt, Andreas F., Franchini, Paolo, Detrich, H. William, Svardal, Hannes, Wagner, Maximilian, Naylor, Gavin J. P., Pippel, Martin, Malinsky, Milan, Mooney, Mark, Simbirsky, Maria, Hannigan, Brett T., Pesout, Trevor, Houck, Marlys, Misuraca, Ann, Kingan, Sarah B., Hall, Richard, Kronenberg, Zev, Sović, Ivan, Dunn, Christopher, Ning, Zemin, Hastie, Alex, Lee, Joyce, Selvaraj, Siddarth, Green, Richard E., Putnam, Nicholas H., Gut, Ivo, Ghurye, Jay, Garrison, Erik, Sims, Ying, Collins, Joanna, Pelan, Sarah, Torrance, James, Tracey, Alan, Wood, Jonathan, Dagnew, Robel E., Guan, Dengfeng, London, Sarah E., Clayton, David F., Mello, Claudio V., Friedrich, Samantha R., Lovell, Peter V., Osipova, Ekaterina, Al-Ajli, Farooq O., Secomandi, Simona, Kim, Heebal, Theofanopoulou, Constantina, Hiller, Michael, Zhou, Yang, Harris, Robert S., Makova, Kateryna D., Medvedev, Paul, Hoffman, Jinna, Masterson, Patrick, Clark, Karen, Martin, Fergal, Howe, Kevin, Flicek, Paul, Walenz, Brian P., Kwak, Woori, Clawson, Hiram, Diekhans, Mark, Nassar, Luis, Paten, Benedict, Kraus, Robert H. S., Crawford, Andrew J., Gilbert, M. Thomas P., Zhang, Guojie, Venkatesh, Byrappa, Murphy, Robert W., Koepfli, Klaus-Peter, Shapiro, Beth, Johnson, Warren E., Di Palma, Federica, Marques-Bonet, Tomas, Teeling, Emma C., Warnow, Tandy, Graves, Jennifer Marshall, Ryder, Oliver A., Haussler, David, O’Brien, Stephen J., Korlach, Jonas, Lewin, Harris A., Howe, Kerstin, Myers, Eugene W., Durbin, Richard, Phillippy, Adam M., and Jarvis, Erich D.
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45/91 ,64 ,631/61/212/2302 ,706/648/697 ,631/181/2474 ,45 ,article ,45/23 ,14. Life underwater ,631/181/735 ,38 - 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 species1–4. To address this issue, the international Genome 10K (G10K) consortium5, 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.
167. Additional file 10 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
- Subjects
Data_FILES ,14. Life underwater - Abstract
Authors’ original file for figure 6
168. Additional file 1 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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14. Life underwater - Abstract
Additional file 1: Table S1: Primer and probe sequences. a ~40-mer forward primers were also used as hybridization probes. (PDF 31 KB)
169. Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,animal diseases ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
170. Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,animal diseases ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
171. Additional file 4 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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animal structures ,fungi ,14. Life underwater - Abstract
Additional file 4: Table S3: Putative α and β hemoglobin genes from other teleosts and Xenopus tropicalis used to generate phylogenetic trees. The table lists all predicted intact α and β hemoglobin genes indentified within Biomart [69] for teleost genomes that have been sequenced and annotated (medaka, zebrafish, tetraodon, danio) and Xenopus tropicalis, which was used as an outgroup. For each hemoglobin gene identified, the table lists the species, chromosome or scaffold, start and stop positions, strand of transcription, Ensembl gene ID and our assigned gene name used in the phylogenetic trees. (PDF 51 KB)
172. Additional file 6 of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
- Subjects
Data_FILES ,14. Life underwater - Abstract
Authors’ original file for figure 2
173. Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
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Quinn, Nicole L, Boroevich, Keith A, Lubieniecki, Krzysztof P, Chow, William, Davidson, Evelyn A, Phillips, Ruth B, Koop, Ben F, and Davidson, William S
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endocrine system ,animal diseases ,14. Life underwater ,hormones, hormone substitutes, and hormone antagonists - Abstract
Additional file of Genomic organization and evolution of the Atlantic salmon hemoglobin repertoire
174. Analyses of pig genomes provide insight into porcine demography and evolution
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Groenen, Martien A. M., Archibald, Alan L., Uenishi, Hirohide, Tuggle, Christopher K., Takeuchi, Yasuhiro, Rothschild, Max F., Rogel-Gaillard, Claire, Park, Chankyu, Milan, Denis, Megens, Hendrik-Jan, Li, Shengting, Larkin, Denis M., Kim, Heebal, Frantz, Laurent A. F., Caccamo, Mario, Ahn, Hyeonju, Aken, Bronwen L., Anselmo, Anna, Anthon, Christian, Auvil, Loretta, Badaoui, Bouabid, Beattie, Craig W., Bendixen, Christian, Berman, Daniel, Blecha, Frank, Blomberg, Jonas, Bolund, Lars, Bosse, Mirte, Botti, Sara, Bujie, Zhan, Bystrom, Megan, Capitanu, Boris, Carvalho-Silva, Denise, Chardon, Patrick, Chen, Celine, Cheng, Ryan, Choi, Sang-Haeng, Chow, William, Clark, Richard C., Clee, Christopher, Crooijmans, Richard P. M. A., Dawson, Harry D., Dehais, Patrice, De Sapio, Fioravante, Dibbits, Bert, Drou, Nizar, Du, Zhi-Qiang, Eversole, Kellye, Fadista, João, Fairley, Susan, Faraut, Thomas, Faulkner, Geoffrey J., Fowler, Katie E., Fredholm, Merete, Fritz, Eric, Gilbert, James G. R., Giuffra, Elisabetta, Gorodkin, Jan, Griffin, Darren K., Harrow, Jennifer L., Hayward, Alexander, Howe, Kerstin, Hu, Zhi-Liang, Humphray, Sean J., Hunt, Toby, Hornshøj, Henrik, Jeon, Jin-Tae, Jern, Patric, Jones, Matthew, Jurka, Jerzy, Kanamori, Hiroyuki, Kapetanovic, Ronan, Kim, Jaebum, Kim, Jae-Hwan, Kim, Kyu-Won, Kim, Tae-Hun, Larson, Greger, Lee, Kyooyeol, Lee, Kyung-Tai, Leggett, Richard, Lewin, Harris A., Li, Yingrui, Liu, Wansheng, Loveland, Jane E., Lu, Yao, Lunney, Joan K., Ma, Jian, Madsen, Ole, Mann, Katherine, Matthews, Lucy, McLaren, Stuart, Morozumi, Takeya, Murtaugh, Michael P., Narayan, Jitendra, Truong Nguyen, Dinh, Ni, Peixiang, Oh, Song-Jung, Onteru, Suneel, Panitz, Frank, Park, Eung-Woo, Park, Hong-Seog, Pascal, Geraldine, Paudel, Yogesh, Perez-Enciso, Miguel, Ramirez-Gonzalez, Ricardo, Reecy, James M., Rodriguez-Zas, Sandra, Rohrer, Gary A., Rund, Lauretta, Sang, Yongming, Schachtschneider, Kyle, Schraiber, Joshua G., Schwartz, John, Scobie, Linda, Scott, Carol, Searle, Stephen, Servin, Bertrand, Southey, Bruce R., Sperber, Goran, Stadler, Peter, Sweedler, Jonathan V., Tafer, Hakim, Thomsen, Bo, Wali, Rashmi, Wang, Jian, Wang, Jun, White, Simon, Xu, Xun, Yerle, Martine, Zhang, Guojie, Zhang, Jianguo, Zhang, Jie, Zhao, Shuhong, Rogers, Jane, Churcher, Carol, Schook, Lawrence B., Groenen, Martien A. M., Archibald, Alan L., Uenishi, Hirohide, Tuggle, Christopher K., Takeuchi, Yasuhiro, Rothschild, Max F., Rogel-Gaillard, Claire, Park, Chankyu, Milan, Denis, Megens, Hendrik-Jan, Li, Shengting, Larkin, Denis M., Kim, Heebal, Frantz, Laurent A. F., Caccamo, Mario, Ahn, Hyeonju, Aken, Bronwen L., Anselmo, Anna, Anthon, Christian, Auvil, Loretta, Badaoui, Bouabid, Beattie, Craig W., Bendixen, Christian, Berman, Daniel, Blecha, Frank, Blomberg, Jonas, Bolund, Lars, Bosse, Mirte, Botti, Sara, Bujie, Zhan, Bystrom, Megan, Capitanu, Boris, Carvalho-Silva, Denise, Chardon, Patrick, Chen, Celine, Cheng, Ryan, Choi, Sang-Haeng, Chow, William, Clark, Richard C., Clee, Christopher, Crooijmans, Richard P. M. A., Dawson, Harry D., Dehais, Patrice, De Sapio, Fioravante, Dibbits, Bert, Drou, Nizar, Du, Zhi-Qiang, Eversole, Kellye, Fadista, João, Fairley, Susan, Faraut, Thomas, Faulkner, Geoffrey J., Fowler, Katie E., Fredholm, Merete, Fritz, Eric, Gilbert, James G. R., Giuffra, Elisabetta, Gorodkin, Jan, Griffin, Darren K., Harrow, Jennifer L., Hayward, Alexander, Howe, Kerstin, Hu, Zhi-Liang, Humphray, Sean J., Hunt, Toby, Hornshøj, Henrik, Jeon, Jin-Tae, Jern, Patric, Jones, Matthew, Jurka, Jerzy, Kanamori, Hiroyuki, Kapetanovic, Ronan, Kim, Jaebum, Kim, Jae-Hwan, Kim, Kyu-Won, Kim, Tae-Hun, Larson, Greger, Lee, Kyooyeol, Lee, Kyung-Tai, Leggett, Richard, Lewin, Harris A., Li, Yingrui, Liu, Wansheng, Loveland, Jane E., Lu, Yao, Lunney, Joan K., Ma, Jian, Madsen, Ole, Mann, Katherine, Matthews, Lucy, McLaren, Stuart, Morozumi, Takeya, Murtaugh, Michael P., Narayan, Jitendra, Truong Nguyen, Dinh, Ni, Peixiang, Oh, Song-Jung, Onteru, Suneel, Panitz, Frank, Park, Eung-Woo, Park, Hong-Seog, Pascal, Geraldine, Paudel, Yogesh, Perez-Enciso, Miguel, Ramirez-Gonzalez, Ricardo, Reecy, James M., Rodriguez-Zas, Sandra, Rohrer, Gary A., Rund, Lauretta, Sang, Yongming, Schachtschneider, Kyle, Schraiber, Joshua G., Schwartz, John, Scobie, Linda, Scott, Carol, Searle, Stephen, Servin, Bertrand, Southey, Bruce R., Sperber, Goran, Stadler, Peter, Sweedler, Jonathan V., Tafer, Hakim, Thomsen, Bo, Wali, Rashmi, Wang, Jian, Wang, Jun, White, Simon, Xu, Xun, Yerle, Martine, Zhang, Guojie, Zhang, Jianguo, Zhang, Jie, Zhao, Shuhong, Rogers, Jane, Churcher, Carol, and Schook, Lawrence B.
- Abstract
For 10,000 years pigs and humans have shared a close and complex relationship. From domestication to modern breeding practices, humans have shaped the genomes of domestic pigs. Here we present the assembly and analysis of the genome sequence of a female domestic Duroc pig (Sus scrofa) and a comparison with the genomes of wild and domestic pigs from Europe and Asia. Wild pigs emerged in South East Asia and subsequently spread across Eurasia. Our results reveal a deep phylogenetic split between European and Asian wild boars ∼1 million years ago, and a selective sweep analysis indicates selection on genes involved in RNA processing and regulation. Genes associated with immune response and olfaction exhibit fast evolution. Pigs have the largest repertoire of functional olfactory receptor genes, reflecting the importance of smell in this scavenging animal. The pig genome sequence provides an important resource for further improvements of this important livestock species, and our identification of many putative disease-causing variants extends the potential of the pig as a biomedical model.
175. Vitamin D metabolism, mineral homeostasis, and bone mineralization in term infants fed human milk, cow milk-based formula, or soy-based formula
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Hillman, Laura S., primary, Chow, William, additional, Salmons, Sharon S., additional, Weaver, Earlene, additional, Erickson, Marilyn, additional, and Hansen, James, additional
- Published
- 1988
- Full Text
- View/download PDF
176. Facing in is not general to all gulls nesting on cliffs
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Burtt, Edward H., primary and Chow, William, additional
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- 1983
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- View/download PDF
177. Automatic generation of interlocking shapes
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Chow, William W, primary
- Published
- 1979
- Full Text
- View/download PDF
178. Determination of carbetamide residues and its aniline metabolite
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Guardigli, Alvaro, primary, Chow, William, additional, and Lefar, Morton S., additional
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- 1972
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- View/download PDF
179. Determination of some acidic herbicides by thin-layer chromatography
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Guardigli, Alvaro., primary, Chow, William., additional, and Lefar, Morton S., additional
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- 1971
- Full Text
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180. Determination of phosalone and its oxygen analog in citrus crops
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Lefar, Morton S., primary, Guardigli, Alvaro., additional, Chow, William., additional, and Martwinski, Patricia M., additional
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- 1971
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181. Corrigendum: The zebrafish reference genome sequence and its relationship to the human genome.
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Howe, Kerstin, Clark, Matthew D., Torroja, Carlos F., Torrance, James, Berthelot, Camille, Muffato, Matthieu, Collins, John E., Humphray, Sean, McLaren, Karen, Matthews, Lucy, McLaren, Stuart, Sealy, Ian, Caccamo, Mario, Churcher, Carol, Scott, Carol, Barrett, Jeffrey C., Koch, Romke, Rauch, Gerd-Jörg, White, Simon, and Chow, William
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HUMAN genome ,ZEBRA danio - Abstract
A correction to the article "The zebrafish reference genome sequence and its relationship to the human genome" by Kerstin Howe and colleagues, published in a 2013 issue of the journal "Nature," is presented.
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- 2014
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182. The evolution of two transmissible cancers in Tasmanian devils.
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Stammnitz, Maximilian R., Gori, Kevin, Kwon, Young Mi, Harry, Edward, Martin, Fergal J., Billis, Konstantinos, Cheng, Yuanyuan, Baez-Ortega, Adrian, Chow, William, Comte, Sebastien, Eggertsson, Hannes, Fox, Samantha, Hamede, Rodrigo, Jones, Menna, Lazenby, Billie, Peck, Sarah, Pye, Ruth, Quail, Michael A., Swift, Kate, and Wang, Jinhong
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- *
TRANSMISSIBLE tumors , *TASMANIAN devil , *DNA mismatch repair , *Y chromosome , *GENETIC variation , *LONG-Term Evolution (Telecommunications) - Abstract
Tasmanian devils have spawned two transmissible cancer lineages, named devil facial tumor 1 (DFT1) and devil facial tumor 2 (DFT2). We investigated the genetic diversity and evolution of these clones by analyzing 78 DFT1 and 41 DFT2 genomes relative to a newly assembled, chromosome-level reference. Time-resolved phylogenetic trees reveal that DFT1 first emerged in 1986 (1982 to 1989) and DFT2 in 2011 (2009 to 2012). Subclone analysis documents transmission of heterogeneous cell populations. DFT2 has faster mutation rates than DFT1 across all variant classes, including substitutions, indels, rearrangements, transposable element insertions, and copy number alterations, and we identify a hypermutated DFT1 lineage with defective DNA mismatch repair. Several loci show plausible evidence of positive selection in DFT1 or DFT2, including loss of chromosome Y and inactivation of MGA, but none are common to both cancers. This study reveals the parallel long-term evolution of two transmissible cancers inhabiting a common niche in Tasmanian devils. [ABSTRACT FROM AUTHOR]
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- 2023
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183. Can profitable trading strategies be derived from investment bestsellers?
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Chow, William Kong Meng
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- 330, Books; Research biases; UK equities; Risk
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- 2001
184. Interlocking shapes in art and engineering
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Chow, William W
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- 1980
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185. Mechanical Properties Of Gels And Other Materials With Respect To Their Use In Pads Transmitting Forces To The Human Body.
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Chow, William Wai-chung
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- 1974
186. 'Facing in' is not general to all gulls nesting on cliffs
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Chow, William and Burtt, Edward H., Jr.
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- 1983
187. A haplotype-resolved genome assembly of the Nile rat facilitates exploration of the genetic basis of diabetes.
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Toh, Huishi, Yang, Chentao, Formenti, Giulio, Raja, Kalpana, Yan, Lily, Tracey, Alan, Chow, William, Howe, Kerstin, Bergeron, Lucie A., Zhang, Guojie, Haase, Bettina, Mountcastle, Jacquelyn, Fedrigo, Olivier, Fogg, John, Kirilenko, Bogdan, Munegowda, Chetan, Hiller, Michael, Jain, Aashish, Kihara, Daisuke, and Rhie, Arang
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- *
NILE tilapia , *MICE , *RATTUS norvegicus , *TYPE 2 diabetes , *RATS , *METABOLIC disorders - Abstract
Background: The Nile rat (Avicanthis niloticus) is an important animal model because of its robust diurnal rhythm, a cone-rich retina, and a propensity to develop diet-induced diabetes without chemical or genetic modifications. A closer similarity to humans in these aspects, compared to the widely used Mus musculus and Rattus norvegicus models, holds the promise of better translation of research findings to the clinic. Results: We report a 2.5 Gb, chromosome-level reference genome assembly with fully resolved parental haplotypes, generated with the Vertebrate Genomes Project (VGP). The assembly is highly contiguous, with contig N50 of 11.1 Mb, scaffold N50 of 83 Mb, and 95.2% of the sequence assigned to chromosomes. We used a novel workflow to identify 3613 segmental duplications and quantify duplicated genes. Comparative analyses revealed unique genomic features of the Nile rat, including some that affect genes associated with type 2 diabetes and metabolic dysfunctions. We discuss 14 genes that are heterozygous in the Nile rat or highly diverged from the house mouse. Conclusions: Our findings reflect the exceptional level of genomic resolution present in this assembly, which will greatly expand the potential of the Nile rat as a model organism. [ABSTRACT FROM AUTHOR]
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- 2022
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188. Genomic consequences of domestication of the Siamese fighting fish.
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Young Mi Kwon, Vranken, Nathan, Hoge, Carla, Lichak, Madison R., Norovich, Amy L., Francis, Kerel X., Camacho-Garcia, Julia, Bista, Iliana, Wood, Jonathan, McCarthy, Shane, Chow, William, Heok Hui Tan, Howe, Kerstin, Bandara, Sepalika, von Lintig, Johannes, Rüber, Lukas, Durbin, Richard, Svarda, Hannes, and Bendesky, Andres
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- *
DOMESTICATION of animals , *LOCUS (Genetics) , *SEX determination , *MOSAICISM , *BIOLOGICAL evolution , *LIFE sciences - Abstract
The article presents a study which explores genomic consequences of domestication of the Siamese fighting fish. It demonstrate how simple genetic architectures paired with anatomical modularity can lead to vast phenotypic diversity generated during animal domestication and launch betta as a powerful new system for evolutionary genetics.
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- 2022
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189. Reference genome and demographic history of the most endangered marine mammal, the vaquita.
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Morin, Phillip A., Archer, Frederick I., Avila, Catherine D., Balacco, Jennifer R., Bukhman, Yury V., Chow, William, Fedrigo, Olivier, Formenti, Giulio, Fronczek, Julie A., Fungtammasan, Arkarachai, Gulland, Frances M. D., Haase, Bettina, Peter Heide‐Jorgensen, Mads, Houck, Marlys L., Howe, Kerstin, Misuraca, Ann C., Mountcastle, Jacquelyn, Musser, Whitney, Paez, Sadye, and Pelan, Sarah
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- *
RARE mammals , *MARINE mammals , *GENOMES , *DEMOGRAPHY , *RNA sequencing , *HETEROZYGOSITY - 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. see also the Perspective by Annabel Whibley [ABSTRACT FROM AUTHOR]
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- 2021
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190. The complete sequence of a human genome
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Sergey Nurk, Sergey Koren, Arang Rhie, Mikko Rautiainen, Andrey V. Bzikadze, Alla Mikheenko, Mitchell R. Vollger, Nicolas Altemose, Lev Uralsky, Ariel Gershman, Sergey Aganezov, Savannah J. Hoyt, Mark Diekhans, Glennis A. Logsdon, Michael Alonge, Stylianos E. Antonarakis, Matthew Borchers, Gerard G. Bouffard, Shelise Y. Brooks, Gina V. Caldas, Nae-Chyun Chen, Haoyu Cheng, Chen-Shan Chin, William Chow, Leonardo G. de Lima, Philip C. Dishuck, Richard Durbin, Tatiana Dvorkina, Ian T. Fiddes, Giulio Formenti, Robert S. Fulton, Arkarachai Fungtammasan, Erik Garrison, Patrick G. S. Grady, Tina A. Graves-Lindsay, Ira M. Hall, Nancy F. Hansen, Gabrielle A. Hartley, Marina Haukness, Kerstin Howe, Michael W. Hunkapiller, Chirag Jain, Miten Jain, Erich D. Jarvis, Peter Kerpedjiev, Melanie Kirsche, Mikhail Kolmogorov, Jonas Korlach, Milinn Kremitzki, Heng Li, Valerie V. Maduro, Tobias Marschall, Ann M. McCartney, Jennifer McDaniel, Danny E. Miller, James C. Mullikin, Eugene W. Myers, Nathan D. Olson, Benedict Paten, Paul Peluso, Pavel A. Pevzner, David Porubsky, Tamara Potapova, Evgeny I. Rogaev, Jeffrey A. Rosenfeld, Steven L. Salzberg, Valerie A. Schneider, Fritz J. Sedlazeck, Kishwar Shafin, Colin J. Shew, Alaina Shumate, Ying Sims, Arian F. A. Smit, Daniela C. Soto, Ivan Sović, Jessica M. Storer, Aaron Streets, Beth A. Sullivan, Françoise Thibaud-Nissen, James Torrance, Justin Wagner, Brian P. Walenz, Aaron Wenger, Jonathan M. D. Wood, Chunlin Xiao, Stephanie M. Yan, Alice C. Young, Samantha Zarate, Urvashi Surti, Rajiv C. McCoy, Megan Y. Dennis, Ivan A. Alexandrov, Jennifer L. Gerton, Rachel J. O’Neill, Winston Timp, Justin M. Zook, Michael C. Schatz, Evan E. Eichler, Karen H. Miga, Adam M. Phillippy, Nurk, Sergey [0000-0003-1301-5749], Koren, Sergey [0000-0002-1472-8962], Rhie, Arang [0000-0002-9809-8127], Rautiainen, Mikko [0000-0003-2971-267X], Bzikadze, Andrey V [0000-0002-7928-7950], Vollger, Mitchell R [0000-0002-8651-1615], Altemose, Nicolas [0000-0002-7231-6026], Uralsky, Lev [0000-0002-5565-7961], Gershman, Ariel [0000-0001-8899-8781], Aganezov, Sergey [0000-0003-2458-8323], Hoyt, Savannah J [0000-0001-7804-3236], Diekhans, Mark [0000-0002-0430-0989], Logsdon, Glennis A [0000-0003-2396-0656], Alonge, Michael [0000-0002-3692-1819], Antonarakis, Stylianos E [0000-0001-8907-5823], Borchers, Matthew [0000-0001-5903-3489], Bouffard, Gerard G [0000-0001-8744-6440], Chen, Nae-Chyun [0000-0002-4140-4568], Cheng, Haoyu [0000-0002-9209-5793], Chin, Chen-Shan [0000-0003-4394-2455], Chow, William [0000-0002-9056-201X], de Lima, Leonardo G [0000-0001-6340-6065], Dishuck, Philip C [0000-0003-2223-9787], Durbin, Richard [0000-0002-9130-1006], Fiddes, Ian T [0000-0002-1580-7443], Formenti, Giulio [0000-0002-7554-5991], Fungtammasan, Arkarachai [0000-0003-2398-0358], Garrison, Erik [0000-0003-3821-631X], Grady, Patrick GS [0000-0003-0180-7810], Graves-Lindsay, Tina A [0000-0002-0409-891X], Hall, Ira M [0000-0003-4442-6655], Hansen, Nancy F [0000-0002-0950-0699], Haukness, Marina [0000-0001-9991-8089], Howe, Kerstin [0000-0003-2237-513X], Jain, Miten [0000-0002-4571-3982], Jarvis, Erich D [0000-0001-8931-5049], Kirsche, Melanie [0000-0002-6631-4761], Kolmogorov, Mikhail [0000-0002-5489-9045], Korlach, Jonas [0000-0003-3047-4250], Kremitzki, Milinn [0000-0001-7980-3153], Li, Heng [0000-0003-4874-2874], Maduro, Valerie V [0000-0001-8250-9844], Marschall, Tobias [0000-0002-9376-1030], McDaniel, Jennifer [0000-0003-1987-0914], Miller, Danny E [0000-0001-6096-8601], Mullikin, James C [0000-0003-0825-3750], Myers, Eugene W [0000-0002-6580-7839], Olson, Nathan D [0000-0003-2585-3037], Paten, Benedict [0000-0001-8863-3539], Pevzner, Pavel A [0000-0002-0418-165X], Porubsky, David [0000-0001-8414-8966], Potapova, Tamara [0000-0003-2761-1795], Rosenfeld, Jeffrey A [0000-0002-8750-2841], Salzberg, Steven L [0000-0002-8859-7432], Sedlazeck, Fritz J [0000-0001-6040-2691], Shafin, Kishwar [0000-0001-5252-3434], Shumate, Alaina [0000-0002-4450-1857], Smit, Arian FA [0000-0003-2088-3165], Soto, Daniela C [0000-0002-6292-655X], Sović, Ivan [0000-0002-5900-4319], Storer, Jessica M [0000-0002-9619-5265], Streets, Aaron [0000-0002-3909-8389], Sullivan, Beth A [0000-0001-5216-4603], Thibaud-Nissen, Françoise [0000-0003-4957-7807], Torrance, James [0000-0002-6117-8190], Walenz, Brian P [0000-0001-8431-1428], Wenger, Aaron [0000-0003-1183-0432], Wood, Jonathan MD [0000-0002-7545-2162], Xiao, Chunlin [0000-0001-8702-4889], Yan, Stephanie M [0000-0002-6880-465X], Young, Alice C [0000-0003-0549-9261], Zarate, Samantha [0000-0001-5570-2059], McCoy, Rajiv C [0000-0003-0615-146X], Dennis, Megan Y [0000-0002-8502-5420], Alexandrov, Ivan A [0000-0003-4342-2003], Gerton, Jennifer L [0000-0003-0743-3637], O'Neill, Rachel J [0000-0002-1525-6821], Timp, Winston [0000-0003-2083-6027], Zook, Justin M [0000-0003-2309-8402], Schatz, Michael C [0000-0002-4118-4446], Eichler, Evan E [0000-0002-8246-4014], Miga, Karen H [0000-0001-9709-4565], Phillippy, Adam M [0000-0003-2983-8934], and Apollo - University of Cambridge Repository
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Chromosomes, Artificial, Bacterial ,Genome ,Multidisciplinary ,General Science & Technology ,Genome, Human ,1.1 Normal biological development and functioning ,Human Genome ,Bacterial ,DNA ,Sequence Analysis, DNA ,Chromosomes ,Cell Line ,Underpinning research ,Reference Values ,Artificial ,Human Genome Project ,Genetics ,Chromosomes, Human ,Humans ,Generic health relevance ,Sequence Analysis ,Human - Abstract
Since its initial release in 2000, the human reference genome has covered only the euchromatic fraction of the genome, leaving important heterochromatic regions unfinished. Addressing the remaining 8% of the genome, the Telomere-to-Telomere (T2T) Consortium presents a complete 3.055 billion–base pair sequence of a human genome, T2T-CHM13, that includes gapless assemblies for all chromosomes except Y, corrects errors in the prior references, and introduces nearly 200 million base pairs of sequence containing 1956 gene predictions, 99 of which are predicted to be protein coding. The completed regions include all centromeric satellite arrays, recent segmental duplications, and the short arms of all five acrocentric chromosomes, unlocking these complex regions of the genome to variational and functional studies.
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- 2022
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191. Laser interstitial thermal therapy for treatment of a recurrent skull base chordoma: illustrative case.
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Chow WD, Lehman VT, and Gompel JJV
- Abstract
Background: The authors applied laser interstitial thermal therapy (LITT) to a recurrent skull base chordoma, which has not been previously described., Observations: A 63-year-old man was initially diagnosed with an 8-cm destructive clival chordoma, which was aggressively resected endoscopically but recurred despite multiple operations, proton radiation therapy, and chemotherapy. The patient underwent uncomplicated LITT for a subtemporal mass, which palliated the tumor for 10 months. However, it did not ultimately prevent the need for resection, although it may have delayed the surgery., Lessons: This case study demonstrates the feasibility and safety of LITT in treating these typically surgically challenging tumors. https://thejns.org/doi/10.3171/CASE24534.
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- 2024
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192. Distinct patterns of genetic variation at low-recombining genomic regions represent haplotype structure.
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Ishigohoka J, Bascón-Cardozo K, Bours A, Fuß J, Rhie A, Mountcastle J, Haase B, Chow W, Collins J, Howe K, Uliano-Silva M, Fedrigo O, Jarvis ED, Pérez-Tris J, Illera JC, and Liedvogel M
- Abstract
Genomic regions sometimes show patterns of genetic variation distinct from the genome-wide population structure. Such deviations have often been interpreted to represent effects of selection. However, systematic investigation of whether and how non-selective factors, such as recombination rates, can affect distinct patterns has been limited. Here, we associate distinct patterns of genetic variation with reduced recombination rates in a songbird, the Eurasian blackcap (Sylvia atricapilla), using a new reference genome assembly, whole-genome resequenc- ing data and recombination maps. We find that distinct patterns of genetic variation reflect haplotype structure at genomic regions with different prevalence of reduced recombination rate across populations. At low-recombining regions shared in most populations, distinct patterns reflect conspicuous haplotypes segregating in multiple populations. At low-recombining regions found only in a few populations, distinct patterns represent variance among cryptic haplotypes within the low-recombining populations. With simulations, we confirm that these distinct patterns evolve neutrally by reduced recombination rate, on which the effects of selection can be overlaid. Our results highlight that distinct patterns of genetic variation can emerge through evolutionary reduction of local recombination rate. The recombination landscape as an evolvable trait therefore plays an important role determining the heterogeneous distribution of genetic variation along the genome., (© The Author(s) 2024. Published by Oxford University Press on behalf of The Society for the Study of Evolution (SSE).)
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- 2024
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193. A genomic basis of vocal rhythm in birds.
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Sebastianelli M, Lukhele SM, Secomandi S, de Souza SG, Haase B, Moysi M, Nikiforou C, Hutfluss A, Mountcastle J, Balacco J, Pelan S, Chow W, Fedrigo O, Downs CT, Monadjem A, Dingemanse NJ, Jarvis ED, Brelsford A, vonHoldt BM, and Kirschel ANG
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- Animals, Male, Genomics, Genome genetics, Female, Songbirds genetics, Songbirds physiology, Birds genetics, Birds physiology, Vocalization, Animal physiology
- Abstract
Vocal rhythm plays a fundamental role in sexual selection and species recognition in birds, but little is known of its genetic basis due to the confounding effect of vocal learning in model systems. Uncovering its genetic basis could facilitate identifying genes potentially important in speciation. Here we investigate the genomic underpinnings of rhythm in vocal non-learning Pogoniulus tinkerbirds using 135 individual whole genomes distributed across a southern African hybrid zone. We find rhythm speed is associated with two genes that are also known to affect human speech, Neurexin-1 and Coenzyme Q8A. Models leveraging ancestry reveal these candidate loci also impact rhythmic stability, a trait linked with motor performance which is an indicator of quality. Character displacement in rhythmic stability suggests possible reinforcement against hybridization, supported by evidence of asymmetric assortative mating in the species producing faster, more stable rhythms. Because rhythm is omnipresent in animal communication, candidate genes identified here may shape vocal rhythm across birds and other vertebrates., (© 2024. The Author(s).)
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- 2024
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194. A revamped rat reference genome improves the discovery of genetic diversity in laboratory rats.
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de Jong TV, Pan Y, Rastas P, Munro D, Tutaj M, Akil H, Benner C, Chen D, Chitre AS, Chow W, Colonna V, Dalgard CL, Demos WM, Doris PA, Garrison E, Geurts AM, Gunturkun HM, Guryev V, Hourlier T, Howe K, Huang J, Kalbfleisch T, Kim P, Li L, Mahaffey S, Martin FJ, Mohammadi P, Ozel AB, Polesskaya O, Pravenec M, Prins P, Sebat J, Smith JR, Solberg Woods LC, Tabakoff B, Tracey A, Uliano-Silva M, Villani F, Wang H, Sharp BM, Telese F, Jiang Z, Saba L, Wang X, Murphy TD, Palmer AA, Kwitek AE, Dwinell MR, Williams RW, Li JZ, and Chen H
- Subjects
- Rats, Animals, Molecular Sequence Annotation, Whole Genome Sequencing, Genetic Variation genetics, Genome genetics, Genomics
- Abstract
The seventh iteration of the reference genome assembly for Rattus norvegicus-mRatBN7.2-corrects numerous misplaced segments and reduces base-level errors by approximately 9-fold and increases contiguity by 290-fold compared with its predecessor. Gene annotations are now more complete, improving the mapping precision of genomic, transcriptomic, and proteomics datasets. We jointly analyzed 163 short-read whole-genome sequencing datasets representing 120 laboratory rat strains and substrains using mRatBN7.2. We defined ∼20.0 million sequence variations, of which 18,700 are predicted to potentially impact the function of 6,677 genes. We also generated a new rat genetic map from 1,893 heterogeneous stock rats and annotated transcription start sites and alternative polyadenylation sites. The mRatBN7.2 assembly, along with the extensive analysis of genomic variations among rat strains, enhances our understanding of the rat genome, providing researchers with an expanded resource for studies involving rats., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)
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- 2024
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195. A revamped rat reference genome improves the discovery of genetic diversity in laboratory rats.
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de Jong TV, Pan Y, Rastas P, Munro D, Tutaj M, Akil H, Benner C, Chen D, Chitre AS, Chow W, Colonna V, Dalgard CL, Demos WM, Doris PA, Garrison E, Geurts AM, Gunturkun HM, Guryev V, Hourlier T, Howe K, Huang J, Kalbfleisch T, Kim P, Li L, Mahaffey S, Martin FJ, Mohammadi P, Ozel AB, Polesskaya O, Pravenec M, Prins P, Sebat J, Smith JR, Solberg Woods LC, Tabakoff B, Tracey A, Uliano-Silva M, Villani F, Wang H, Sharp BM, Telese F, Jiang Z, Saba L, Wang X, Murphy TD, Palmer AA, Kwitek AE, Dwinell MR, Williams RW, Li JZ, and Chen H
- Abstract
The seventh iteration of the reference genome assembly for Rattus norvegicus -mRatBN7.2-corrects numerous misplaced segments and reduces base-level errors by approximately 9-fold and increases contiguity by 290-fold compared to its predecessor. Gene annotations are now more complete, significantly improving the mapping precision of genomic, transcriptomic, and proteomics data sets. We jointly analyzed 163 short-read whole genome sequencing datasets representing 120 laboratory rat strains and substrains using mRatBN7.2. We defined ~20.0 million sequence variations, of which 18.7 thousand are predicted to potentially impact the function of 6,677 genes. We also generated a new rat genetic map from 1,893 heterogeneous stock rats and annotated transcription start sites and alternative polyadenylation sites. The mRatBN7.2 assembly, along with the extensive analysis of genomic variations among rat strains, enhances our understanding of the rat genome, providing researchers with an expanded resource for studies involving rats., Competing Interests: Declaration of interests The authors declare no competing interests.
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- 2023
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196. Janus kinase inhibition for the treatment of refractory frontal fibrosing alopecia: A case series and review of the literature.
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Dunn C, Griffith V, Coican A, Dane A, Chow W, Aneja S, Nathoo R, Leavitt A, and Hawkins SD
- Abstract
Competing Interests: None disclosed.
- Published
- 2023
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197. Genomics of cold adaptations in the Antarctic notothenioid fish radiation.
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Bista I, Wood JMD, Desvignes T, McCarthy SA, Matschiner M, Ning Z, Tracey A, Torrance J, Sims Y, Chow W, Smith M, Oliver K, Haggerty L, Salzburger W, Postlethwait JH, Howe K, Clark MS, William Detrich H 3rd, Christina Cheng CH, Miska EA, and Durbin R
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- Animals, Genomics, Vertebrates, Phylogeny, Hemoglobins genetics, Antarctic Regions, Fishes genetics, Perciformes
- Abstract
Numerous novel adaptations characterise the radiation of notothenioids, the dominant fish group in the freezing seas of the Southern Ocean. To improve understanding of the evolution of this iconic fish group, here we generate and analyse new genome assemblies for 24 species covering all major subgroups of the radiation, including five long-read assemblies. We present a new estimate for the onset of the radiation at 10.7 million years ago, based on a time-calibrated phylogeny derived from genome-wide sequence data. We identify a two-fold variation in genome size, driven by expansion of multiple transposable element families, and use the long-read data to reconstruct two evolutionarily important, highly repetitive gene family loci. First, we present the most complete reconstruction to date of the antifreeze glycoprotein gene family, whose emergence enabled survival in sub-zero temperatures, showing the expansion of the antifreeze gene locus from the ancestral to the derived state. Second, we trace the loss of haemoglobin genes in icefishes, the only vertebrates lacking functional haemoglobins, through complete reconstruction of the two haemoglobin gene clusters across notothenioid families. Both the haemoglobin and antifreeze genomic loci are characterised by multiple transposon expansions that may have driven the evolutionary history of these genes., (© 2023. The Author(s).)
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- 2023
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198. Divergent sensory and immune gene evolution in sea turtles with contrasting demographic and life histories.
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Bentley BP, Carrasco-Valenzuela T, Ramos EKS, Pawar H, Souza Arantes L, Alexander A, Banerjee SM, Masterson P, Kuhlwilm M, Pippel M, Mountcastle J, Haase B, Uliano-Silva M, Formenti G, Howe K, Chow W, Tracey A, Sims Y, Pelan S, Wood J, Yetsko K, Perrault JR, Stewart K, Benson SR, Levy Y, Todd EV, Shaffer HB, Scott P, Henen BT, Murphy RW, Mohr DW, Scott AF, Duffy DJ, Gemmell NJ, Suh A, Winkler S, Thibaud-Nissen F, Nery MF, Marques-Bonet T, Antunes A, Tikochinski Y, Dutton PH, Fedrigo O, Myers EW, Jarvis ED, Mazzoni CJ, and Komoroske LM
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- Animals, Ecosystem, Population Dynamics, Turtles
- Abstract
Sea turtles represent an ancient lineage of marine vertebrates that evolved from terrestrial ancestors over 100 Mya. The genomic basis of the unique physiological and ecological traits enabling these species to thrive in diverse marine habitats remains largely unknown. Additionally, many populations have drastically declined due to anthropogenic activities over the past two centuries, and their recovery is a high global conservation priority. We generated and analyzed high-quality reference genomes for the leatherback ( Dermochelys coriacea ) and green ( Chelonia mydas ) turtles, representing the two extant sea turtle families. These genomes are highly syntenic and homologous, but localized regions of noncollinearity were associated with higher copy numbers of immune, zinc-finger, and olfactory receptor (OR) genes in green turtles, with ORs related to waterborne odorants greatly expanded in green turtles. Our findings suggest that divergent evolution of these key gene families may underlie immunological and sensory adaptations assisting navigation, occupancy of neritic versus pelagic environments, and diet specialization. Reduced collinearity was especially prevalent in microchromosomes, with greater gene content, heterozygosity, and genetic distances between species, supporting their critical role in vertebrate evolutionary adaptation. Finally, diversity and demographic histories starkly contrasted between species, indicating that leatherback turtles have had a low yet stable effective population size, exhibit extremely low diversity compared with other reptiles, and harbor a higher genetic load compared with green turtles, reinforcing concern over their persistence under future climate scenarios. These genomes provide invaluable resources for advancing our understanding of evolution and conservation best practices in an imperiled vertebrate lineage.
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- 2023
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199. A chromosome-level reference genome and pangenome for barn swallow population genomics.
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Secomandi S, Gallo GR, Sozzoni M, Iannucci A, Galati E, Abueg L, Balacco J, Caprioli M, Chow W, Ciofi C, Collins J, Fedrigo O, Ferretti L, Fungtammasan A, Haase B, Howe K, Kwak W, Lombardo G, Masterson P, Messina G, Møller AP, Mountcastle J, Mousseau TA, Ferrer Obiol J, Olivieri A, Rhie A, Rubolini D, Saclier M, Stanyon R, Stucki D, Thibaud-Nissen F, Torrance J, Torroni A, Weber K, Ambrosini R, Bonisoli-Alquati A, Jarvis ED, Gianfranceschi L, and Formenti G
- Subjects
- Animals, Metagenomics, Genome genetics, Genomics, Chromosomes, Swallows genetics
- Abstract
Insights into the evolution of non-model organisms are limited by the lack of reference genomes of high accuracy, completeness, and contiguity. Here, we present a chromosome-level, karyotype-validated reference genome and pangenome for the barn swallow (Hirundo rustica). We complement these resources with a reference-free multialignment of the reference genome with other bird genomes and with the most comprehensive catalog of genetic markers for the barn swallow. We identify potentially conserved and accelerated genes using the multialignment and estimate genome-wide linkage disequilibrium using the catalog. We use the pangenome to infer core and accessory genes and to detect variants using it as a reference. Overall, these resources will foster population genomics studies in the barn swallow, enable detection of candidate genes in comparative genomics studies, and help reduce bias toward a single reference genome., Competing Interests: Declaration of interests D.S. and K.W. are full-time employees at Pacific Biosciences, a company commercializing single-molecule sequencing technologies., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)
- Published
- 2023
- Full Text
- View/download PDF
200. The swan genome and transcriptome, it is not all black and white.
- Author
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Karawita AC, Cheng Y, Chew KY, Challagulla A, Kraus R, Mueller RC, Tong MZW, Hulme KD, Bielefeldt-Ohmann H, Steele LE, Wu M, Sng J, Noye E, Bruxner TJ, Au GG, Lowther S, Blommaert J, Suh A, McCauley AJ, Kaur P, Dudchenko O, Aiden E, Fedrigo O, Formenti G, Mountcastle J, Chow W, Martin FJ, Ogeh DN, Thiaud-Nissen F, Howe K, Tracey A, Smith J, Kuo RI, Renfree MB, Kimura T, Sakoda Y, McDougall M, Spencer HG, Pyne M, Tolf C, Waldenström J, Jarvis ED, Baker ML, Burt DW, and Short KR
- Subjects
- Animals, Transcriptome, Endothelial Cells, Australia, Influenza in Birds, Anseriformes
- Abstract
Background: The Australian black swan (Cygnus atratus) is an iconic species with contrasting plumage to that of the closely related northern hemisphere white swans. The relative geographic isolation of the black swan may have resulted in a limited immune repertoire and increased susceptibility to infectious diseases, notably infectious diseases from which Australia has been largely shielded. Unlike mallard ducks and the mute swan (Cygnus olor), the black swan is extremely sensitive to highly pathogenic avian influenza. Understanding this susceptibility has been impaired by the absence of any available swan genome and transcriptome information., Results: Here, we generate the first chromosome-length black and mute swan genomes annotated with transcriptome data, all using long-read based pipelines generated for vertebrate species. We use these genomes and transcriptomes to show that unlike other wild waterfowl, black swans lack an expanded immune gene repertoire, lack a key viral pattern-recognition receptor in endothelial cells and mount a poorly controlled inflammatory response to highly pathogenic avian influenza. We also implicate genetic differences in SLC45A2 gene in the iconic plumage of the black swan., Conclusion: Together, these data suggest that the immune system of the black swan is such that should any avian viral infection become established in its native habitat, the black swan would be in a significant peril., (© 2023. The Author(s).)
- Published
- 2023
- Full Text
- View/download PDF
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