Solanum pan-genetics reveals paralogues as contingencies in crop engineering

Benoit, Matthias, Jenike, Katharine M, Satterlee, James W, Ramakrishnan, Srividya, Gentile, Iacopo, Hendelman, Anat, Passalacqua, Michael J, Suresh, Hamsini, Shohat, Hagai, Robitaille, Gina M, Fitzgerald, Blaine, Alonge, Michael, Wang, Xingang, Santos, Ryan, He, Jia, Ou, Shujun, Golan, Hezi, Green, Yumi, Swartwood, Kerry, Karavolias, Nicholas G, Sierra, Gina P, Orejuela, Andres, Roda, Federico, Goodwin, Sara, McCombie, W Richard, Kizito, Elizabeth B, Gagnon, Edeline, Knapp, Sandra, Särkinen, Tiina E, Frary, Amy, Gillis, Jesse, Van Eck, Joyce, Schatz, Michael C, Lippman, Zachary B (March 2025) Solanum pan-genetics reveals paralogues as contingencies in crop engineering. Nature. ISSN 0028-0836 (Public Dataset)

[thumbnail of 10.1038.s41586-025-08619-6.pdf]

PDF
10.1038.s41586-025-08619-6.pdf - Published Version
Available under License Creative Commons Attribution.
Download (59MB)

URL: https://www.ncbi.nlm.nih.gov/pubmed/40044854

DOI: 10.1038/s41586-025-08619-6

Abstract

Pan-genomics and genome-editing technologies are revolutionizing breeding of global crops1,2. A transformative opportunity lies in exchanging genotype-to-phenotype knowledge between major crops (that is, those cultivated globally) and indigenous crops (that is, those locally cultivated within a circumscribed area)3-5 to enhance our food system. However, species-specific genetic variants and their interactions with desirable natural or engineered mutations pose barriers to achieving predictable phenotypic effects, even between related crops6,7. Here, by establishing a pan-genome of the crop-rich genus Solanum8 and integrating functional genomics and pan-genetics, we show that gene duplication and subsequent paralogue diversification are major obstacles to genotype-to-phenotype predictability. Despite broad conservation of gene macrosynteny among chromosome-scale references for 22 species, including 13 indigenous crops, thousands of gene duplications, particularly within key domestication gene families, exhibited dynamic trajectories in sequence, expression and function. By augmenting our pan-genome with African eggplant cultivars9 and applying quantitative genetics and genome editing, we dissected an intricate history of paralogue evolution affecting fruit size. The loss of a redundant paralogue of the classical fruit size regulator CLAVATA3 (CLV3)10,11 was compensated by a lineage-specific tandem duplication. Subsequent pseudogenization of the derived copy, followed by a large cultivar-specific deletion, created a single fused CLV3 allele that modulates fruit organ number alongside an enzymatic gene controlling the same trait. Our findings demonstrate that paralogue diversifications over short timescales are underexplored contingencies in trait evolvability. Exposing and navigating these contingencies is crucial for translating genotype-to-phenotype relationships across species.

Item Type:	Paper
Subjects:	organism description > plant behavior organism description > plant
CSHL Authors:	Benoit, Matthias Gentile, Iacopo Hendelman, Anat Robitaille, Gina Wang, Xingang Goodwin, Sara Gillis, Jesse Lippman, Zachary B. Satterlee, James Passalacqua, Michael Suresh, Hamsini Shohat, Hagai Fitzgerald, Blaine He, Jia McCombie, W. Richard Santos, Ryan
Communities:	CSHL labs > Gillis Lab CSHL labs > Lippman lab CSHL labs > McCombie lab CSHL labs > Goodwin lab School of Biological Sciences > Publications CSHL Cancer Center Shared Resources CSHL Cancer Center Shared Resources > Sequencing Technology & Analysis Service
SWORD Depositor:	CSHL Elements
Depositing User:	CSHL Elements
Date:	5 March 2025
Date Deposited:	06 Mar 2025 13:38
Last Modified:	06 Mar 2025 18:21
Related URLs:	Publisher
Dataset ID:	SRA: PRJNA1073673 https://www.solpangenomics.com/ https://solgenomics.net/ftp/genomes/Solanum_pangenomics/ http://github.com/maputnik/osm-liberty/
URI:	https://repository.cshl.edu/id/eprint/41809

Actions (login required)

Administrator's edit/view item