Your search keyword '"Bernard Y. Kim"' showing total 8 results

1. Identification and Characterization of Breakpoints and Mutations on Drosophila melanogaster Balancer Chromosomes

Author

Danny E. Miller, Lily Kahsai, Kasun Buddika, Michael J. Dixon, Bernard Y. Kim, Brian R. Calvi, Nicholas S. Sokol, R. Scott Hawley, and Kevin R. Cook

Subjects

balancer chromosomes, chromosomal inversions, p53, ankyrin 2, fucosyltransferase a, Genetics, QH426-470

Published

2020

2. Single-fly genome assemblies fill major phylogenomic gaps across the Drosophilidae Tree of Life.

Author

Bernard Y Kim, Hannah R Gellert, Samuel H Church, Anton Suvorov, Sean S Anderson, Olga Barmina, Sofia G Beskid, Aaron A Comeault, K Nicole Crown, Sarah E Diamond, Steve Dorus, Takako Fujichika, James A Hemker, Jan Hrcek, Maaria Kankare, Toru Katoh, Karl N Magnacca, Ryan A Martin, Teruyuki Matsunaga, Matthew J Medeiros, Danny E Miller, Scott Pitnick, Michele Schiffer, Sara Simoni, Tessa E Steenwinkel, Zeeshan A Syed, Aya Takahashi, Kevin H-C Wei, Tsuya Yokoyama, Michael B Eisen, Artyom Kopp, Daniel Matute, Darren J Obbard, Patrick M O'Grady, Donald K Price, Masanori J Toda, Thomas Werner, and Dmitri A Petrov

Subjects

Biology (General), QH301-705.5

Abstract

Long-read sequencing is driving rapid progress in genome assembly across all major groups of life, including species of the family Drosophilidae, a longtime model system for genetics, genomics, and evolution. We previously developed a cost-effective hybrid Oxford Nanopore (ONT) long-read and Illumina short-read sequencing approach and used it to assemble 101 drosophilid genomes from laboratory cultures, greatly increasing the number of genome assemblies for this taxonomic group. The next major challenge is to address the laboratory culture bias in taxon sampling by sequencing genomes of species that cannot easily be reared in the lab. Here, we build upon our previous methods to perform amplification-free ONT sequencing of single wild flies obtained either directly from the field or from ethanol-preserved specimens in museum collections, greatly improving the representation of lesser studied drosophilid taxa in whole-genome data. Using Illumina Novaseq X Plus and ONT P2 sequencers with R10.4.1 chemistry, we set a new benchmark for inexpensive hybrid genome assembly at US $150 per genome while assembling genomes from as little as 35 ng of genomic DNA from a single fly. We present 183 new genome assemblies for 179 species as a resource for drosophilid systematics, phylogenetics, and comparative genomics. Of these genomes, 62 are from pooled lab strains and 121 from single adult flies. Despite the sample limitations of working with small insects, most single-fly diploid assemblies are comparable in contiguity (>1 Mb contig N50), completeness (>98% complete dipteran BUSCOs), and accuracy (>QV40 genome-wide with ONT R10.4.1) to assemblies from inbred lines. We present a well-resolved multi-locus phylogeny for 360 drosophilid and 4 outgroup species encompassing all publicly available (as of August 2023) genomes for this group. Finally, we present a Progressive Cactus whole-genome, reference-free alignment built from a subset of 298 suitably high-quality drosophilid genomes. The new assemblies and alignment, along with updated laboratory protocols and computational pipelines, are released as an open resource and as a tool for studying evolution at the scale of an entire insect family.

Published

2024

3. Rapid evolutionary diversification of the flamenco locus across simulans clade Drosophila species.

Author

Sarah Signor, Jeffrey Vedanayagam, Bernard Y Kim, Filip Wierzbicki, Robert Kofler, and Eric C Lai

Subjects

Genetics, QH426-470

Abstract

Suppression of transposable elements (TEs) is paramount to maintain genomic integrity and organismal fitness. In D. melanogaster, the flamenco locus is a master suppressor of TEs, preventing the mobilization of certain endogenous retrovirus-like TEs from somatic ovarian support cells to the germline. It is transcribed by Pol II as a long (100s of kb), single-stranded, primary transcript, and metabolized into ~24-32 nt Piwi-interacting RNAs (piRNAs) that target active TEs via antisense complementarity. flamenco is thought to operate as a trap, owing to its high content of recent horizontally transferred TEs that are enriched in antisense orientation. Using newly-generated long read genome data, which is critical for accurate assembly of repetitive sequences, we find that flamenco has undergone radical transformations in sequence content and even copy number across simulans clade Drosophilid species. Drosophila simulans flamenco has duplicated and diverged, and neither copy exhibits synteny with D. melanogaster beyond the core promoter. Moreover, flamenco organization is highly variable across D. simulans individuals. Next, we find that D. simulans and D. mauritiana flamenco display signatures of a dual-stranded cluster, with ping-pong signals in the testis and/or embryo. This is accompanied by increased copy numbers of germline TEs, consistent with these regions operating as functional dual-stranded clusters. Overall, the physical and functional diversity of flamenco orthologs is testament to the extremely dynamic consequences of TE arms races on genome organization, not only amongst highly related species, but even amongst individuals.

Published

2023

4. Correction: Highly contiguous assemblies of 101 drosophilid genomes

Author

Bernard Y Kim, Jeremy R Wang, Danny E Miller, Olga Barmina, Emily Delaney, Ammon Thompson, Aaron A Comeault, David Peede, Emmanuel RR D'Agostino, Julianne Pelaez, Jessica M Aguilar, Diler Haji, Teruyuki Matsunaga, Ellie Armstrong, Molly Zych, Yoshitaka Ogawa, Marina Stamenković-Radak, Mihailo Jelić, Marija Savić Veselinović, Marija Tanasković, Pavle Erić, Jian-Jun Gao, Takehiro K Katoh, Masanori J Toda, Hideaki Watabe, Masayoshi Watada, Jeremy S Davis, Leonie C Moyle, Giulia Manoli, Enrico Bertolini, Vladimír Košťál, R Scott Hawley, Aya Takahashi, Corbin D Jones, Donald K Price, Noah Whiteman, Artyom Kopp, Daniel R Matute, and Dmitri A Petrov

Subjects

Medicine, Science, Biology (General), QH301-705.5

Published

2022

5. Highly contiguous assemblies of 101 drosophilid genomes

Author

Bernard Y Kim, Jeremy R Wang, Danny E Miller, Olga Barmina, Emily Delaney, Ammon Thompson, Aaron A Comeault, David Peede, Emmanuel RR D'Agostino, Julianne Pelaez, Jessica M Aguilar, Diler Haji, Teruyuki Matsunaga, Ellie E Armstrong, Molly Zych, Yoshitaka Ogawa, Marina Stamenković-Radak, Mihailo Jelić, Marija Savić Veselinović, Marija Tanasković, Pavle Erić, Jian-Jun Gao, Takehiro K Katoh, Masanori J Toda, Hideaki Watabe, Masayoshi Watada, Jeremy S Davis, Leonie C Moyle, Giulia Manoli, Enrico Bertolini, Vladimír Košťál, R Scott Hawley, Aya Takahashi, Corbin D Jones, Donald K Price, Noah Whiteman, Artyom Kopp, Daniel R Matute, and Dmitri A Petrov

Subjects

Drosophila, Drosophilidae, comparative genomics, genome assembly, nanopore, long reads, Medicine, Science, Biology (General), QH301-705.5

Abstract

Over 100 years of studies in Drosophila melanogaster and related species in the genus Drosophila have facilitated key discoveries in genetics, genomics, and evolution. While high-quality genome assemblies exist for several species in this group, they only encompass a small fraction of the genus. Recent advances in long-read sequencing allow high-quality genome assemblies for tens or even hundreds of species to be efficiently generated. Here, we utilize Oxford Nanopore sequencing to build an open community resource of genome assemblies for 101 lines of 93 drosophilid species encompassing 14 species groups and 35 sub-groups. The genomes are highly contiguous and complete, with an average contig N50 of 10.5 Mb and greater than 97% BUSCO completeness in 97/101 assemblies. We show that Nanopore-based assemblies are highly accurate in coding regions, particularly with respect to coding insertions and deletions. These assemblies, along with a detailed laboratory protocol and assembly pipelines, are released as a public resource and will serve as a starting point for addressing broad questions of genetics, ecology, and evolution at the scale of hundreds of species.

Published

2021

6. A community-maintained standard library of population genetic models

Author

Jeffrey R Adrion, Christopher B Cole, Noah Dukler, Jared G Galloway, Ariella L Gladstein, Graham Gower, Christopher C Kyriazis, Aaron P Ragsdale, Georgia Tsambos, Franz Baumdicker, Jedidiah Carlson, Reed A Cartwright, Arun Durvasula, Ilan Gronau, Bernard Y Kim, Patrick McKenzie, Philipp W Messer, Ekaterina Noskova, Diego Ortega-Del Vecchyo, Fernando Racimo, Travis J Struck, Simon Gravel, Ryan N Gutenkunst, Kirk E Lohmueller, Peter L Ralph, Daniel R Schrider, Adam Siepel, Jerome Kelleher, and Andrew D Kern

Subjects

simulation, reproducibility, open source, Medicine, Science, Biology (General), QH301-705.5

Abstract

The explosion in population genomic data demands ever more complex modes of analysis, and increasingly, these analyses depend on sophisticated simulations. Recent advances in population genetic simulation have made it possible to simulate large and complex models, but specifying such models for a particular simulation engine remains a difficult and error-prone task. Computational genetics researchers currently re-implement simulation models independently, leading to inconsistency and duplication of effort. This situation presents a major barrier to empirical researchers seeking to use simulations for power analyses of upcoming studies or sanity checks on existing genomic data. Population genetics, as a field, also lacks standard benchmarks by which new tools for inference might be measured. Here, we describe a new resource, stdpopsim, that attempts to rectify this situation. Stdpopsim is a community-driven open source project, which provides easy access to a growing catalog of published simulation models from a range of organisms and supports multiple simulation engine backends. This resource is available as a well-documented python library with a simple command-line interface. We share some examples demonstrating how stdpopsim can be used to systematically compare demographic inference methods, and we encourage a broader community of developers to contribute to this growing resource.

Published

2020

7. Deleterious variation shapes the genomic landscape of introgression.

Author

Bernard Y Kim, Christian D Huber, and Kirk E Lohmueller

Subjects

Genetics, QH426-470

Abstract

While it is appreciated that population size changes can impact patterns of deleterious variation in natural populations, less attention has been paid to how gene flow affects and is affected by the dynamics of deleterious variation. Here we use population genetic simulations to examine how gene flow impacts deleterious variation under a variety of demographic scenarios, mating systems, dominance coefficients, and recombination rates. Our results show that admixture between populations can temporarily reduce the genetic load of smaller populations and cause increases in the frequency of introgressed ancestry, especially if deleterious mutations are recessive. Additionally, when fitness effects of new mutations are recessive, between-population differences in the sites at which deleterious variants exist creates heterosis in hybrid individuals. Together, these factors lead to an increase in introgressed ancestry, particularly when recombination rates are low. Under certain scenarios, introgressed ancestry can increase from an initial frequency of 5% to 30-75% and fix at many loci, even in the absence of beneficial mutations. Further, deleterious variation and admixture can generate correlations between the frequency of introgressed ancestry and recombination rate or exon density, even in the absence of other types of selection. The direction of these correlations is determined by the specific demography and whether mutations are additive or recessive. Therefore, it is essential that null models of admixture include both demography and deleterious variation before invoking other mechanisms to explain unusual patterns of genetic variation.

Published

2018

8. Population genetic models of GERP scores suggest pervasive turnover of constrained sites across mammalian evolution.

Author

Christian D Huber, Bernard Y Kim, and Kirk E Lohmueller

Subjects

Genetics, QH426-470

Abstract

Comparative genomic approaches have been used to identify sites where mutations are under purifying selection and of functional consequence by searching for sequences that are conserved across distantly related species. However, the performance of these approaches has not been rigorously evaluated under population genetic models. Further, short-lived functional elements may not leave a footprint of sequence conservation across many species. We use simulations to study how one measure of conservation, the Genomic Evolutionary Rate Profiling (GERP) score, relates to the strength of selection (Nes). We show that the GERP score is related to the strength of purifying selection. However, changes in selection coefficients or functional elements over time (i.e. functional turnover) can strongly affect the GERP distribution, leading to unexpected relationships between GERP and Nes. Further, we show that for functional elements that have a high turnover rate, adding more species to the analysis does not necessarily increase statistical power. Finally, we use the distribution of GERP scores across the human genome to compare models with and without turnover of sites where mutations are under purifying selection. We show that mutations in 4.51% of the noncoding human genome are under purifying selection and that most of this sequence has likely experienced changes in selection coefficients throughout mammalian evolution. Our work reveals limitations to using comparative genomic approaches to identify deleterious mutations. Commonly used GERP score thresholds miss over half of the noncoding sites in the human genome where mutations are under purifying selection.

Published

2020