Your search keyword '"Jennifer R. Balacco"' showing total 3 results

1. A pangenome graph reference of 30 chicken genomes allows genotyping of large and complex structural variants

Author

Edward S. Rice, Antton Alberdi, James Alfieri, Giridhar Athrey, Jennifer R. Balacco, Philippe Bardou, Heath Blackmon, Mathieu Charles, Hans H. Cheng, Olivier Fedrigo, Steven R. Fiddaman, Giulio Formenti, Laurent A. F. Frantz, M. Thomas P. Gilbert, Cari J. Hearn, Erich D. Jarvis, Christophe Klopp, Sofia Marcos, Andrew S. Mason, Deborah Velez-Irizarry, Luohao Xu, and Wesley C. Warren

Subjects

Gallus gallus, K locus, IGLL1, ev21, Biology (General), QH301-705.5

Abstract

Abstract Background The red junglefowl, the wild outgroup of domestic chickens, has historically served as a reference for genomic studies of domestic chickens. These studies have provided insight into the etiology of traits of commercial importance. However, the use of a single reference genome does not capture diversity present among modern breeds, many of which have accumulated molecular changes due to drift and selection. While reference-based resequencing is well-suited to cataloging simple variants such as single-nucleotide changes and short insertions and deletions, it is mostly inadequate to discover more complex structural variation in the genome. Methods We present a pangenome for the domestic chicken consisting of thirty assemblies of chickens from different breeds and research lines. Results We demonstrate how this pangenome can be used to catalog structural variants present in modern breeds and untangle complex nested variation. We show that alignment of short reads from 100 diverse wild and domestic chickens to this pangenome reduces reference bias by 38%, which affects downstream genotyping results. This approach also allows for the accurate genotyping of a large and complex pair of structural variants at the K feathering locus using short reads, which would not be possible using a linear reference. Conclusions We expect that this new paradigm of genomic reference will allow better pinpointing of exact mutations responsible for specific phenotypes, which will in turn be necessary for breeding chickens that meet new sustainability criteria and are resilient to quickly evolving pathogen threats.

Published

2023

2. Low mutation rate in epaulette sharks is consistent with a slow rate of evolution in sharks

Author

Ashley T. Sendell-Price, Frank J. Tulenko, Mats Pettersson, Du Kang, Margo Montandon, Sylke Winkler, Kathleen Kulb, Gavin P. Naylor, Adam Phillippy, Olivier Fedrigo, Jacquelyn Mountcastle, Jennifer R. Balacco, Amalia Dutra, Rebecca E. Dale, Bettina Haase, Erich D. Jarvis, Gene Myers, Shawn M. Burgess, Peter D. Currie, Leif Andersson, and Manfred Schartl

Subjects

Science

Abstract

Abstract Sharks occupy diverse ecological niches and play critical roles in marine ecosystems, often acting as apex predators. They are considered a slow-evolving lineage and have been suggested to exhibit exceptionally low cancer rates. These two features could be explained by a low nuclear mutation rate. Here, we provide a direct estimate of the nuclear mutation rate in the epaulette shark (Hemiscyllium ocellatum). We generate a high-quality reference genome, and resequence the whole genomes of parents and nine offspring to detect de novo mutations. Using stringent criteria, we estimate a mutation rate of 7×10−10 per base pair, per generation. This represents one of the lowest directly estimated mutation rates for any vertebrate clade, indicating that this basal vertebrate group is indeed a slowly evolving lineage whose ability to restore genetic diversity following a sustained population bottleneck may be hampered by a low mutation rate.

Published

2023

3. An improved germline genome assembly for the sea lamprey Petromyzon marinus illuminates the evolution of germline-specific chromosomes

Author

Nataliya Timoshevskaya, Kaan İ. Eşkut, Vladimir A. Timoshevskiy, Sofia M.C. Robb, Carson Holt, Jon E. Hess, Hugo J. Parker, Cindy F. Baker, Allison K. Miller, Cody Saraceno, Mark Yandell, Robb Krumlauf, Shawn R. Narum, Ralph T. Lampman, Neil J. Gemmell, Jacquelyn Mountcastle, Bettina Haase, Jennifer R. Balacco, Giulio Formenti, Sarah Pelan, Ying Sims, Kerstin Howe, Olivier Fedrigo, Erich D. Jarvis, and Jeramiah J. Smith

Subjects

CP: Molecular biology, Biology (General), QH301-705.5

Abstract

Summary: Programmed DNA loss is a gene silencing mechanism that is employed by several vertebrate and nonvertebrate lineages, including all living jawless vertebrates and songbirds. Reconstructing the evolution of somatically eliminated (germline-specific) sequences in these species has proven challenging due to a high content of repeats and gene duplications in eliminated sequences and a corresponding lack of highly accurate and contiguous assemblies for these regions. Here, we present an improved assembly of the sea lamprey (Petromyzon marinus) genome that was generated using recently standardized methods that increase the contiguity and accuracy of vertebrate genome assemblies. This assembly resolves highly contiguous, somatically retained chromosomes and at least one germline-specific chromosome, permitting new analyses that reconstruct the timing, mode, and repercussions of recruitment of genes to the germline-specific fraction. These analyses reveal major roles of interchromosomal segmental duplication, intrachromosomal duplication, and positive selection for germline functions in the long-term evolution of germline-specific chromosomes.

Published

2023