Transcriptomic signatures across a critical sedimentation threshold in a major reef-building coral

Abstract

AbstractSedimentation is a major cause of global near-shore coral reef decline. While negative impacts of sedimentation on coral reef community composition have been well documented, the effects of sedimentation on coral metabolismin situhave received comparatively little attention. Using transcriptomics, we identified gene expression patterns changing across a previously defined sedimentation threshold that was deemed critical due to changes in coral cover and community composition. We identified genes, pathways, and molecular processes associated with this transition that may allow corals, such asPorites lobata, to tolerate chronic, severe sedimentation and persist in turbid environments. Alternative energy generation pathways may helpPorites lobatamaintain a persistent stress response to survive while light and oxygen availability are diminished. We found evidence for the expression of genes linked to increased environmental sensing and cellular communication that likely allowPorites lobatato efficiently respond to sedimentation stress and associated pathogen challenges. Cell damage increases under stress; consequently, we found apoptosis pathways over-represented under severe sedimentation, a likely consequence of damaged cell removal to maintain colony integrity. The results presented here provide a framework for the response ofPorites lobatato sedimentation stress under field conditions. Testing this framework and its related hypotheses using multi-omics approaches can further our understanding of metabolic plasticity and acclimation potential of corals to sedimentation and their resilience in turbid reef systems.