Abstract
Coral health is currently diagnosed retroactively; colonies are deemed “stressed” upon succumbing to bleaching or disease. Ideally, health inferences would instead be made on a pre-death timescale that would enable, for instance, environmental mitigation that could promote coral resilience. To this end, diverse Caribbean coral (Orbicella faveolata) genotypes of varying resilience to high temperatures along the Florida Reef Tract were exposed herein to elevated temperatures in the laboratory, and a proteomic analysis was taken with a subset of 20 samples via iTRAQ labeling followed by nano-liquid chromatography + mass spectrometry; 46 host coral and 40 Symbiodiniaceae dinoflagellate proteins passed all stringent quality control criteria, and the partial proteomes of biopsies of (1) healthy controls, (2) sub-lethally stressed samples, and (3) actively bleaching corals differed significantly from one another. The proteomic data were then used to train predictive models of coral colony bleaching susceptibility, and both generalized regression and machine-learning-based neural networks were capable of accurately forecasting the bleaching susceptibility of coral samples based on their protein signatures. Successful future testing of the predictive power of these models in situ could establish the capacity to proactively monitor coral health.
Highlights
IntroductionAcademic Editors: Andrew Baumann and Michael Wink
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations
The goal of this analysis was to assess multi-collinearity across response variables, as well as to ascertain that there was sufficient proteomic variation across genotypes and treatments to proceed with analyzing the data in a predictive modeling framework
Summary
Academic Editors: Andrew Baumann and Michael Wink. Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Climate change threatens key ecosystems around the globe, with coral reefs being at particular risk given the marked thermo-sensitivity of the framework-building coraldinoflagellate endosymbioses [1]. Scleractinian environmental physiology is a well-established field [2], with many dozens of articles published annually on laboratory exposures of diverse coral species to various environmental stressors (e.g., elevated temperatures and ocean acidification [3]). The implicit goal of these studies is to improve predictions about how reefs will change in the coming decades, though the data from such environmental challenge studies are rarely used to develop analytical tools
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