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How does the coral, Pocillopora acuta, survive the challenging intertidal environment? A genome-wide analysis
  • Rosa Celia Du,
  • Danwei Huang,
  • Peter Todd
Rosa Celia Du
National University of Singapore

Corresponding Author:[email protected]

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Danwei Huang
National University of Singapore
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Peter Todd
National University of Singapore
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Abstract

Characterisation of genomic variation among corals can help uncover variants underlying trait differences and contribute towards genotype prioritisation in coastal restoration projects. For example, there is growing interest in identifying resilient genotypes for transplantation, and to better understand the genetic processes that allow some individuals to survive in specific conditions better than others. The coral species Pocillopora acuta is known to survive in a wide range of habitats, from reefs to seawalls, suggesting its potential use as a starter species for ecological engineering efforts involving coral transplantation onto intertidal seawalls. However, the intertidal section of coastal armour is a challenging environment for corals, with conditions during periods of emersion being particularly stressful. Here, we scanned the entire genome of P. acuta corals for DNA polymorphisms to identify the regions harbouring SNPs and copy number variations (CNVs) that separate intertidal colonies (n=18) from those found in subtidal areas (n=21). Findings revealed 74,391 high quality SNPs distributed across 386 regions of the P. acuta genome. While the majority of the detected SNPs were in non-coding regions, 12% were identified in exons (i.e. coding regions). Functional SNPs that were significantly associated with intertidal colonies were found in overrepresented genomic regions linked to cellular homeostasis, metabolism, and signalling process, which can represent local environmental adaptation in the intertidal. Interestingly, regions that exhibited CNVs were also associated with metabolic and signalling processes, suggesting intertidal corals have a high capacity to perform biological functions critical for survival in extreme environments.