Seeds provide 70% of the global food supply, making them crucial for food security. Understanding the molecular mechanisms governing seed development, dormancy, and germination has become increasingly urgent as climate change impacts crop productivity. Over the last three years, 'omics technologies have transformed our understanding of seed biology through comprehensive molecular profiling at unprecedented resolution. This review synthesises recent advances in seed biology enabled by cutting-edge 'omics applications in Arabidopsis and crops. We examine how the integration of epigenomics, genomics, transcriptomics, proteomics, and metabolomics analysis has enabled reconstruction of the complex regulatory networks controlling seed development, dormancy, and germination. The recent emergence of single-cell and spatial technologies has been revolutionary, uncovering previously unknown cell types and tissue-specific regulatory mechanisms. Key discoveries include the identification of critical phosphorylation networks, metabolic transitions, and hormone signalling activity in seeds. Advanced genomic approaches have provided insights into crop domestication and trait control, while proteomics and metabolomics have been used to characterise essential regulatory modules controlling dormancy release and germination. These findings provide valuable molecular frameworks for developing climate-resilient crops and enhanced seed vigour through targeted genetic improvements, as well as optimised agricultural practices for ensuring global food security.
Keywords: development; dormancy; germination; multi-omics integration; single-cell genomics; spatial transcriptomics; systems biology.
© The Author(s) 2025. Published by Oxford University Press on behalf of the Society for Experimental Biology.