Abstract

The success of corals in nutrient poor environments is largely attributed to the symbiosis between the cnidarian host and its intracellular alga. Warm water anomalies have been shown to destabilise this symbiosis, yet detailed analysis of the effect of temperature and expulsion on cell-specific carbon and nutrient allocation in the symbiont is limited. Here, we exposed colonies of the hard coral Acropora millepora to heat stress and using synchrotron-based infrared microscpectroscopy measured the biomolecular profiles of individual in hospite and expelled symbiont cells at an acute state of bleaching. Our results showed symbiont metabolic profiles to be remarkably distinct with heat stress and expulsion, where the two effectors elicited opposing metabolic adjustments independent of treatment or cell type. Elevated temperature resulted in biomolecular changes reflecting cellular stress, with relative increases in free amino acids and phosphorylation of molecules and a concomitant decline in protein content, suggesting protein modification and degradation. This contrasted with the metabolic profiles of expelled symbionts, which showed relative decreases in free amino acids and phosphorylated molecules, but increases in proteins and lipids, suggesting expulsion lessens the overall effect of heat stress on the metabolic signature of the algal symbionts. Interestingly, the combined effects of expulsion and thermal stress were additive, reducing the overall shifts in all biomolecules, with the notable exception of the significant accumulation of lipids and saturated fatty acids. This first use of a single-cell metabolomics approach on the coral symbiosis provides novel insight into coral bleaching and emphasises the importance of a single-cell approach to demark the cell-to-cell variability in the physiology of coral cellular populations.

Highlights

  • The mutualistic association of the unicellular alga Symbiodinium with reef building corals is founded on carbon exchange

  • Biomolecular Profiles of the Coral Symbiosis of the tropics, this bilateral transfer of metabolites provides a competitive advantage for survival, and under stable conditions this host-symbiont interaction is mutually beneficial to both partners

  • Coral reefs are under pressure from warming ocean temperatures triggering mass coral bleaching (Glynn, 1991; De’ath et al, 2009; Hoegh-Guldberg and Bruno, 2010; Hughes et al, 2018), yet despite decades of research motivated by the intensifying loss of coral cover around the globe (Hughes et al, 2017), the underlying cellular mechanisms responsible remain poorly understood

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Summary

Introduction

The mutualistic association of the unicellular alga Symbiodinium with reef building corals is founded on carbon exchange. We took a single-cell approach to examine the photosynthetic viability and biomolecular composition of (1) endosymbiotic (in hospite—encased in animal cell) and (2) actively expelled Symbiodinium cells during both healthy symbiosis and heat-induced bleaching in the reef-building coral Acropora millepora.

Results
Conclusion

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