Host-derived lipid transfer and metabolic reprogramming in a ciliate–algal symbiosis

Symbiotic associations enable species to integrate complementary traits and adapt to novel environments. However, how the host and endosymbiont exchange nutrients remains poorly understood in most cases. Previously Paramecium bursaria cells were shown to reorganize lipid droplets to accommodate endosymbiotic Chlorella cells and interfering with lipid metabolism reduced the endosymbiont number. Here, we combined transcriptomics, lipidomics, imaging mass spectrometry, and stable-isotope tracing to investigate organic nutrient exchange in this symbiotic system. Our results reveal that endosymbiotic algae undergo extensive reprogramming of lipid metabolic pathways and accumulate markedly higher levels of triglycerides than free-living algae. Isotope-labeling experiments demonstrate that at least some of these lipids originate from the host, providing direct evidence for organic carbon transfer from Paramecium to its algal endosymbionts. Together, our results show that the establishment of symbiosis fundamentally reshapes algal lipid metabolism and uncover an unexpected host-to-symbiont lipid provisioning mechanism—opposite to the canonical direction of carbon flow observed in most photosynthetic symbioses. This work provides new insight into the metabolic principles that sustain and stabilize endosymbiotic partnerships.