Proteome Dynamics Across the Blastogenic Cycle of Botryllus schlosseri Reveals Targets for Cell Immortalization

The colonial tunicate Botryllus schlosseri regenerates weekly through a cyclical process in which adult zooids are replaced by a new generation of buds. While this dynamic asexual development is a hallmark of the species, its molecular regulation remains poorly understood. This study presents the first comprehensive proteomic analysis of B. schlosseri blastogenesis at the individual zooid level, using data-independent acquisition mass spectrometry to quantify protein abundance across developmental stages. The results reveal extensive proteome remodeling between proliferating buds and degenerating zooids. Co-expression analysis identified stage-specific protein modules enriched for biosynthesis and cell cycle pathways in buds, and for apoptosis, catabolism, and metabolic remodeling in zooids. A focused comparison between takeover buds and takeover zooids uncovered distinct regulatory programs controlling proliferation and senescence. Key proteins, including CDK1, CDK2, HDAC2, and PCNA, were identified as candidate regulators of cell cycle progression. These findings provide a molecular framework for understanding regeneration in a basal chordate and offer protein targets that may enable cell cycle re-entry and long-term culture of tunicate primary cells.