Complete sequencing of ape genomes

Yoo, DongAhn; Rhie, Arang; Hebbar, Prajna; Antonacci, Francesca; Logsdon, Glennis A.; Solar, Steven J.; Antipov, Dmitry; Pickett, Brandon D.; Safonova, Yana; Montinaro, Francesco; Luo, Yanting; Malukiewicz, Joanna; Storer, Jessica M.; Lin, Jiadong; Sequeira, Abigail N.; Mangan, Riley J.; Hickey, Glenn; Anez, Graciela Monfort; Balachandran, Parithi; Bankevich, Anton; Beck, Christine R.; Biddanda, Arjun; Borchers, Matthew; Bouffard, Gerard G.; Brannan, Emry; Brooks, Shelise Y.; Carbone, Lucia; Carrel, Laura; Chan, Agnes P.; Crawford, Juyun; Diekhans, Mark; Engelbrecht, Eric; Feschotte, Cedric; Formenti, Giulio; Garcia, Gage H.; Gennaro, Luciana de; Gilbert, David; Green, Richard E.; Guarracino, Andrea; Gupta, Ishaan; Haddad, Diana; Han, Junmin; Harris, Robert S.; Hartley, Gabrielle A.; Harvey, William T.; Hiller, Michael; Hoekzema, Kendra; Houck, Marlys L.; Jeong, Hyeonsoo; Kamali, Kaivan; Kellis, Manolis; Kille, Bryce; Lee, Chul; Lee, Youngho; Lees, William; Lewis, Alexandra P.; Li, Qiuhui; Loftus, Mark; Loh, Yong Hwee Eddie; Loucks, Hailey; Ma, Jian; Mao, Yafei; Martinez, Juan F. I.; Masterson, Patrick; McCoy, Rajiv C.; McGrath, Barbara; McKinney, Sean; Meyer, Britta S.; Miga, Karen H.; Mohanty, Saswat K.; Munson, Katherine M.; Pal, Karol; Pennell, Matt; Pevzner, Pavel A.; Porubsky, David; Potapova, Tamara; Ringeling, Francisca R.; Rocha, Joana L.; Ryder, Oliver A.; Sacco, Samuel; Saha, Swati; Sasaki, Takayo; Schatz, Michael C.; Schork, Nicholas J.; Shanks, Cole; Smeds, Linnéa; Son, Dongmin R.; Steiner, Cynthia; Sweeten, Alexander P.; Tassia, Michael G.; Thibaud-Nissen, Françoise; Torres-González, Edmundo; Trivedi, Mihir; Wei, Wenjie; Wertz, Julie; Yang, Muyu; Zhang, Panpan; Zhang, Shilong; Zhang, Yang; Zhang, Zhenmiao; Zhao, Sarah A.; Zhu, Yixin; Jarvis, Erich D.; Gerton, Jennifer L.; Rivas-González, Iker; Paten, Benedict; Szpiech, Zachary A.; Huber, Christian D.; Lenz, Tobias L.; Konkel, Miriam K.; Yi, Soojin V.; Canzar, Stefan; Watson, Corey T.; Sudmant, Peter H.; Molloy, Erin; Garrison, Erik; Lowe, Craig B.; Ventura, Mario; O’Neill, Rachel J.; Koren, Sergey; Makova, Kateryna D.; Phillippy, Adam M.; Eichler, Evan E.

doi:10.1101/2024.07.31.605654

2024

DOI: 10.1101/2024.07.31.605654

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Complete sequencing of ape genomes

DongAhn Yoo,

Arang Rhie,

Prajna Hebbar

et al.

Abstract: We present haplotype-resolved reference genomes and comparative analyses of six ape species, namely: chimpanzee, bonobo, gorilla, Bornean orangutan, Sumatran orangutan, and siamang. We achieve chromosome-level contiguity with unparalleled sequence accuracy (<1 error in 500,000 base pairs), completely sequencing 215 gapless chromosomes telomere-to-telomere. We resolve challenging regions, such as the major histocompatibility complex and immunoglobulin loci, providing more in-depth evolutionary insights. Comp… Show more

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Cited by 7 publications

References 123 publications

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Non-canonical DNA in human and other ape telomere-to-telomere genomes

Smeds,

Kamali,

Kejnovská

et al. 2024

Preprint

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Non-canonical (non-B) DNA structures (e.g., bent DNA, hairpins, G-quadruplexes, Z-DNA, etc.), which form at certain sequence motifs (e.g., A-phased repeats, inverted repeats, etc.), have emerged as important regulators of cellular processes and drivers of genome evolution. Yet, they have been understudied due to their repetitive nature and potentially inaccurate sequences generated with short-read technologies. Here we comprehensively characterize such motifs in the long-read telomere-to-telomere (T2T) genomes of human, bonobo, chimpanzee, gorilla, Bornean orangutan, Sumatran orangutan, and siamang. Non-B DNA motifs are enriched at the genomic regions added to T2T assemblies, and occupy 9-15%, 9-11%, and 12-38% of autosomes, and chromosomes X and Y, respectively. Functional regions (e.g., promoters and enhancers) and repetitive sequences are enriched in non-B DNA motifs. Non-B DNA motifs concentrate at short arms of acrocentric chromosomes in a pattern reflecting their satellite repeat content and might contribute to satellite dynamics in these regions. Most centromeres and/or their flanking regions are enriched in at least one non-B DNA motif type, consistent with a potential role of non-B structures in determining centromeres. Our results highlight the uneven distribution of predicted non-B DNA structures across ape genomes and suggest their novel functions in previously inaccessible genomic regions.

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Non-canonical DNA in human and other ape telomere-to-telomere genomes

Smeds,

Kamali,

Kejnovská

et al. 2024

Preprint

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Highly accurate assembly polishing with DeepPolisher

Mastoras,

Asri,

Brambrink

et al. 2024

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Accurate genome assemblies are essential for biological research, but even the highest quality assemblies retain errors caused by the technologies used to construct them. Base-level errors are typically fixed with an additional polishing step that uses reads aligned to the draft assembly to identify necessary edits. However, current methods struggle to find a balance between over- and under-polishing. Here, we present an encoder-only transformer model for assembly polishing called DeepPolisher, which predicts corrections to the underlying sequence using Pacbio HiFi read alignments to a diploid assembly. Our pipeline introduces a method, PHARAOH (Phasing Reads in Areas Of Homozygosity), which uses ultra-long ONT data to ensure alignments are accurately phased and to correctly introduce heterozygous edits in falsely homozygous regions. We demonstrate that the DeepPolisher pipeline can reduce assembly errors by half, with a greater than 70% reduction in indel errors. We have applied our DeepPolisher-based pipeline to 180 assemblies from the next Human Pangenome Reference Consortium (HPRC) data release, producing an average predicted Quality Value (QV) improvement of 3.4 (54% error reduction) for the majority of the genome.

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Gene expansions contributing to human brain evolution

Soto,

Uribe-Salazar,

Kaya

et al. 2024

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Genomic drivers of human-specific neurological traits remain largely undiscovered. Duplicated genes expanded uniquely in the human lineage likely contributed to brain evolution, including the increased complexity of synaptic connections between neurons and the dramatic expansion of the neocortex. Discovering duplicate genes is challenging because the similarity of paralogs makes them prone to sequence-assembly errors. To mitigate this issue, we analyzed a complete telomere-to-telomere human genome sequence (T2T-CHM13) and identified 213 duplicated gene families likely containing human-specific paralogs (>98% identity). Positing that genes important in universal human brain features should exist with at least one copy in all modern humans and exhibit expression in the brain, we narrowed in on 362 paralogs with at least one copy across thousands of ancestrally diverse genomes and present in human brain transcriptomes. Of these, 38 paralogs co-express in gene modules enriched for autism-associated genes and potentially contribute to human language and cognition. We narrowed in on 13 duplicate gene families with human-specific paralogs that are fixed among modern humans and show convincing brain expression patterns. Using long-read DNA sequencing revealed hidden variation across 200 modern humans of diverse ancestries, uncovering signatures of selection not previously identified, including possible balancing selection of CD8B. To understand the roles of duplicated genes in brain development, we generated zebrafish CRISPR "knockout" models of nine orthologs and transiently introduced mRNA-encoding paralogs, effectively "humanizing" the larvae. Morphometric, behavioral, and single-cell RNA-seq screening highlighted, for the first time, a possible role for GPR89B in dosage-mediated brain expansion and FRMPD2B function in altered synaptic signaling, both hallmark features of the human brain. Our holistic approach provides important insights into human brain evolution as well as a resource to the community for studying additional gene expansion drivers of human brain evolution.

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Complete sequencing of ape genomes

Cited by 7 publications

References 123 publications

Non-canonical DNA in human and other ape telomere-to-telomere genomes

Non-canonical DNA in human and other ape telomere-to-telomere genomes

Highly accurate assembly polishing with DeepPolisher

Gene expansions contributing to human brain evolution

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