An ancient monoaminergic signaling system coordinates contractility in a nerveless sponge

Chemical neurotransmission was a key animal innovation, enabling multicellular coordination of physiology and locomotion. Sponges are early-diverging animals that lack neurons and muscles, yet still coordinate contraction and relaxation of their filter-feeding water canals. Here, we show that Spongilla lacustris synthesizes the monoamines tryptamine, phenethylamine, and tyramine to elicit distinct canal behaviors. We identify previously uncharacterized decarboxylases and vesicular transporters coexpressed in secretory neuroid and metabolic cells. Using phosphoproteomics and label-free 3D imaging, we show that tryptamine activates GPCR signaling and Rho GTPases, remodeling adhesion and actomyosin networks in contractile canal epithelia to drive localized constrictions and whole-body deflations. Together, these findings define an ancestral monoaminergic system linking secretory and contractile cell types that predate neurons and was later elaborated for neuromodulation of synaptic transmission. Overall design: RNA-seq profiling of juvenile freshwater sponge (Spongilla lacustris) treated with 37.5 µM tryptamine for 1 h, 4 h, or 4h with washout and 24 h recovery.