Light-harvesting strategies and competition drive niche partitioning among Ostreobium lineages in the spectral architecture of the coral reef

Ostreobium, a siphonous green alga capable of living inside of calcium carbonate substrates, including the skeletons of reef-building corals. This study investigates spectral niche preferences and physiological strategies of Ostreobium using community-wide experiments. We exposed natural Ostreobium communities from Porites lutea collected across shallow, mid, and deeper-water sites to three light conditions: far-red, blue, and white light, simulating healthy shallow-water corals, deeper water conditions, and bleached coral skeletons respectively. Using 16S rRNA metabarcoding and chlorophyll analysis, we assessed community changes and physiological responses over 16 weeks. We show significant variation in spectral preferences among Ostreobium OTUs, with clear evidence for both generalist and specialist strategies. Chlorophyll analysis showed photoacclimation responses through changes in pigment compositions. Our work shows that the spectral architecture of the reef plays a role in structuring Ostreobium communities, but the many mismatches between spectral preferences of OTUs and their observed presence in nature, suggests that inter-species competition is likely to be an even stronger contributor to community structure across the reefs microhabitats. We show that physiological heterogeneity within Ostreobium is strongly phylogenetically structured, and our results clearly highlight the importance of considering OTU-level differences when predicting community responses to environmental disturbances such as coral bleaching. While generalist OTUs dominate natural communities, these do poorly in incubations, and we hypothesise that white light specialists may become key players during coral bleaching events. Our work is a substantial advance in our understanding of Ostreobium ecology and provides a framework for interpreting future environmental sequencing data, offering insights into the functional roles of the different OTUs.