Solanum pan-genomics and pan-genetics reveal paralogs as contingencies in crop engineering

Matthias Benoit, Katharine M Jenike, James W Satterlee, Srividya Ramakrishnan, Iacopo Gentile, Anat Hendelman, Michael J Passalacqua, Hamsini Suresh, Hagai Shohat, Gina M Robitaille, Blaine Fitzgerald, Michael M Alonge, Xingang Wang, Ryan Santos, Jia He, Shujun Ou, Hezi Golan, Yumi Green, Kerry Swartwood, Gina P Sierra, Andres Orejuela, Federico Fornaguera, Sara Goodwin, William Richard McCombie, Elizabeth Balyejusa Kizito, Edeline Gagnon, Sandra Knapp, Tiina Sarkinen, Amy Frary, Jesse Gillis, Joyce Van Eck, Michael C Schatz, Zachary B Lippman
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Abstract

Pan-genomics and genome editing technologies are revolutionizing the breeding of globally cultivated crops. A transformative opportunity lies in the reciprocal exchange of genotype-to-phenotype knowledge of agricultural traits between these major crops and hundreds of locally cultivated indigenous crops, thereby enhancing the diversity and resilience of our food system. However, species-specific genetic variants and their interactions with desired natural or engineered mutations pose barriers to achieving predictable phenotypic effects, even between closely related crops or genotypes. Here, by establishing a pan-genome of the crop-rich genus Solanum and integrating functional genomics and genetics, we show that gene duplication and subsequent paralog diversification are a major obstacle to genotype-phenotype predictability. Despite broad conservation of gene macrosynteny among chromosome-scale references for 22 species, including 13 indigenous crops, hundreds of global and lineage-specific gene duplications exhibited dynamic evolutionary trajectories in paralog sequence, expression, and function, including among members of key domestication gene families. Extending our pan-genome with 10 cultivars of African eggplant and leveraging quantitative genetics and genome editing, we uncovered an intricate history of paralog emergence and evolution within this indigenous crop. The loss of an ancient redundant paralog of the classical regulator of stem cell proliferation and fruit organ number, CLAVATA3 (CLV3), was compensated by a lineage-specific tandem duplication. Subsequent pseudogenization of the derived copy followed by a cultivar-specific structural variant resulted in a single fused functional copy of CLV3 that modifies locule number alongside a newly identified gene controlling the same trait. Our findings demonstrate that paralog diversifications over short evolutionary periods are critical yet underexplored contingencies in trait evolvability and independent crop domestication histories. Unraveling these contingencies is crucial for translating genotype-to-phenotype relationships across related species.
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茄科植物泛基因组学和泛遗传学揭示了作物工程中的旁系亲缘关系
泛基因组学和基因组编辑技术正在彻底改变全球栽培作物的育种。这些主要作物与数百种当地栽培的土著作物之间可以相互交流农业性状的基因型到表型知识,从而提高我们粮食系统的多样性和复原力,这是一个变革性的机遇。然而,物种特有的基因变异及其与所需的自然或工程突变之间的相互作用,对实现可预测的表型效应构成了障碍,即使在亲缘关系很近的作物或基因型之间也是如此。在这里,通过建立作物丰富的茄属的泛基因组并整合功能基因组学和遗传学,我们表明基因复制和随后的旁系多样化是基因型-表型可预测性的主要障碍。尽管包括 13 种本土作物在内的 22 个物种的染色体尺度参考文献中的基因大合成得到了广泛的保护,但数百个全球性和品系特异性基因重复在旁系序列、表达和功能方面表现出动态的进化轨迹,包括关键驯化基因家族成员之间的进化轨迹。通过对非洲茄子的 10 个栽培品种进行泛基因组扩展,并利用定量遗传学和基因组编辑技术,我们发现了这种本土作物中旁系亲属出现和进化的复杂历史。干细胞增殖和果实器官数量的经典调控因子CLAVATA3(CLV3)的一个古老冗余旁系亲属的缺失被一个特定品系的串联重复所弥补。随后对衍生拷贝进行假基因化,再加上栽培品种特异性结构变异,形成了 CLV3 的单个融合功能拷贝,它与新发现的控制相同性状的基因一起改变了子房室数。我们的研究结果表明,短进化时期的旁系变异是性状可进化性和独立作物驯化历史中至关重要但却未被充分探索的偶然因素。揭示这些偶然性对于在相关物种间转换基因型到表型的关系至关重要。
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