Author
Listed:
- Glennis A. Logsdon
(University of Washington School of Medicine
University of Pennsylvania)
- Peter Ebert
(Heinrich Heine University
Heinrich Heine University)
- Peter A. Audano
(The Jackson Laboratory for Genomic Medicine)
- Mark Loftus
(Clemson University
Clemson University
The Jackson Laboratory for Genomic Medicine)
- David Porubsky
(University of Washington School of Medicine)
- Jana Ebler
(Heinrich Heine University
Heinrich Heine University)
- Feyza Yilmaz
(The Jackson Laboratory for Genomic Medicine)
- Pille Hallast
(The Jackson Laboratory for Genomic Medicine)
- Timofey Prodanov
(Heinrich Heine University
Heinrich Heine University)
- DongAhn Yoo
(University of Washington School of Medicine)
- Carolyn A. Paisie
(The Jackson Laboratory for Genomic Medicine)
- William T. Harvey
(University of Washington School of Medicine)
- Xuefang Zhao
(Broad Institute of MIT and Harvard
Massachusetts General Hospital
Massachusetts General Hospital and Harvard Medical School)
- Gianni V. Martino
(Clemson University
Clemson University
College of Graduate Studies)
- Mir Henglin
(Heinrich Heine University
Heinrich Heine University)
- Katherine M. Munson
(University of Washington School of Medicine)
- Keon Rabbani
(University of Southern California)
- Chen-Shan Chin
(Pathos AI Inc.)
- Bida Gu
(University of Southern California)
- Hufsah Ashraf
(Heinrich Heine University
Heinrich Heine University)
- Stephan Scholz
(Heinrich Heine University
Heinrich Heine University)
- Olanrewaju Austine-Orimoloye
(European Bioinformatics Institute)
- Parithi Balachandran
(The Jackson Laboratory for Genomic Medicine)
- Marc Jan Bonder
(University Medical Center Groningen
Oncode Institute
German Cancer Research Center)
- Haoyu Cheng
(Yale School of Medicine)
- Zechen Chong
(University of Alabama)
- Jonathan Crabtree
(University of Maryland School of Medicine)
- Mark Gerstein
(Yale University
Yale University)
- Lisbeth A. Guethlein
(Stanford University)
- Patrick Hasenfeld
(European Molecular Biology Laboratory (EMBL))
- Glenn Hickey
(University of California)
- Kendra Hoekzema
(University of Washington School of Medicine)
- Sarah E. Hunt
(European Bioinformatics Institute)
- Matthew Jensen
(Yale University
Yale University)
- Yunzhe Jiang
(Yale University
Yale University)
- Sergey Koren
(National Institutes of Health)
- Youngjun Kwon
(University of Washington School of Medicine)
- Chong Li
(Temple University
Temple University)
- Heng Li
(Dana-Farber Cancer Institute
Harvard Medical School)
- Jiaqi Li
(Yale University
Yale University)
- Paul J. Norman
(University of Colorado School of Medicine
University of Colorado School of Medicine)
- Keisuke K. Oshima
(University of Pennsylvania)
- Benedict Paten
(University of California)
- Adam M. Phillippy
(National Institutes of Health)
- Nicholas R. Pollock
(University of Colorado School of Medicine)
- Tobias Rausch
(European Molecular Biology Laboratory (EMBL))
- Mikko Rautiainen
(University of Helsinki)
- Yuwei Song
(University of Alabama)
- Arda Söylev
(Heinrich Heine University
Heinrich Heine University)
- Arvis Sulovari
(University of Washington School of Medicine)
- Likhitha Surapaneni
(European Bioinformatics Institute)
- Vasiliki Tsapalou
(European Molecular Biology Laboratory (EMBL))
- Weichen Zhou
(University of Michigan)
- Ying Zhou
(Dana-Farber Cancer Institute)
- Qihui Zhu
(The Jackson Laboratory for Genomic Medicine
Stanford Health Care)
- Michael C. Zody
(New York Genome Center)
- Ryan E. Mills
(University of Michigan)
- Scott E. Devine
(University of Maryland School of Medicine)
- Xinghua Shi
(Temple University
Temple University)
- Michael E. Talkowski
(Broad Institute of MIT and Harvard
Massachusetts General Hospital
Massachusetts General Hospital and Harvard Medical School)
- Mark J. P. Chaisson
(University of Southern California)
- Alexander T. Dilthey
(Heinrich Heine University
Heinrich Heine University)
- Miriam K. Konkel
(Clemson University
Clemson University)
- Jan O. Korbel
(European Molecular Biology Laboratory (EMBL))
- Charles Lee
(The Jackson Laboratory for Genomic Medicine)
- Christine R. Beck
(The Jackson Laboratory for Genomic Medicine
The University of Connecticut Health Center)
- Evan E. Eichler
(University of Washington School of Medicine
University of Washington)
- Tobias Marschall
(Heinrich Heine University
Heinrich Heine University)
Abstract
Diverse sets of complete human genomes are required to construct a pangenome reference and to understand the extent of complex structural variation. Here we sequence 65 diverse human genomes and build 130 haplotype-resolved assemblies (median continuity of 130 Mb), closing 92% of all previous assembly gaps1,2 and reaching telomere-to-telomere status for 39% of the chromosomes. We highlight complete sequence continuity of complex loci, including the major histocompatibility complex (MHC), SMN1/SMN2, NBPF8 and AMY1/AMY2, and fully resolve 1,852 complex structural variants. In addition, we completely assemble and validate 1,246 human centromeres. We find up to 30-fold variation in α-satellite higher-order repeat array length and characterize the pattern of mobile element insertions into α-satellite higher-order repeat arrays. Although most centromeres predict a single site of kinetochore attachment, epigenetic analysis suggests the presence of two hypomethylated regions for 7% of centromeres. Combining our data with the draft pangenome reference1 significantly enhances genotyping accuracy from short-read data, enabling whole-genome inference3 to a median quality value of 45. Using this approach, 26,115 structural variants per individual are detected, substantially increasing the number of structural variants now amenable to downstream disease association studies.
Suggested Citation
Glennis A. Logsdon & Peter Ebert & Peter A. Audano & Mark Loftus & David Porubsky & Jana Ebler & Feyza Yilmaz & Pille Hallast & Timofey Prodanov & DongAhn Yoo & Carolyn A. Paisie & William T. Harvey &, 2025.
"Complex genetic variation in nearly complete human genomes,"
Nature, Nature, vol. 644(8076), pages 430-441, August.
Handle:
RePEc:nat:nature:v:644:y:2025:i:8076:d:10.1038_s41586-025-09140-6
DOI: 10.1038/s41586-025-09140-6
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