Ancestral secretory programs underlie the evolution of morphological innovations across Spiralia

Understanding how morphological innovation arise from ancestral genetic and cellular systems remains a major challenge in evolutionary biology. Molluscan shells represent one of the most diverse morphological novelties within Spiralia and have been central to the ecological and evolutionary diversification of molluscs. However, the cellular basis of shell formation and the evolutionary origin of shell-forming cell types remain poorly understood. Here, we present a single-cell transcriptomic atlas of the Pacific oyster ( Crassostrea gigas ) mantle and show that molluscan shell-forming cell types are evolutionarily recent innovations built upon ancestral epithelial secretory systems of spiralians. We identify five spatially segregated shell-forming epithelial cell types, and demonstrate that larval and adult shell-forming cells are developmentally independent and characterized by transcriptomes enriched for evolutionarily young genes. Cross-species cell-type comparisons further reveal that oyster shell-related genes are embedded within conserved epithelial and secretory programs across spiralians. Together, we propose that a substantial genetic foundation for shell formation was already present in the last common ancestor of Spiralia, and that molluscan shell diversity arose through repeated co-option of ancestral genetic programs coupled with novel genes. Our study provides a framework for understanding how ancient cellular architectures can be repeatedly reconfigured to generate morphological novelty during evolution.