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. 2020 Oct 12;10(1):16995.
doi: 10.1038/s41598-020-73501-6.

Host-symbiont coevolution, cryptic structure, and bleaching susceptibility, in a coral species complex (Scleractinia; Poritidae)

Affiliations

Host-symbiont coevolution, cryptic structure, and bleaching susceptibility, in a coral species complex (Scleractinia; Poritidae)

Z H Forsman et al. Sci Rep. .

Abstract

The 'species' is a key concept for conservation and evolutionary biology, yet the lines between population and species-level variation are often blurred, especially for corals. The 'Porites lobata species complex' consists of branching and mounding corals that form reefs across the Pacific. We used reduced representation meta-genomic sequencing to examine genetic relationships within this species complex and to identify candidate loci associated with colony morphology, cryptic genetic structure, and apparent bleaching susceptibility. We compared existing Porites data with bleached and unbleached colonies of the branching coral P. compressa collected in Kāne'ohe Bay Hawai'i during the 2015 coral bleaching event. Loci that mapped to coral, symbiont, and microbial references revealed genetic structure consistent with recent host-symbiont co-evolution. Cryptic genetic clades were resolved that previous work has associated with distance from shore, but no genetic structure was associated with bleaching. We identified many candidate loci associated with morphospecies, including candidate host and symbiont loci with fixed differences between branching and mounding corals. We also found many loci associated with cryptic genetic structure, yet relatively few loci associated with bleaching. Recent host-symbiont co-evolution and rapid diversification suggests that variation and therefore the capacity of these corals to adapt may be underappreciated.

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Conflict of interest statement

The authors declare no competing interests.

Figures

Figure 1
Figure 1
Examples of variation and habitat distribution within the P. lobata species complex. (A) Porites lobata (yellow massive morphology) shown next to Porites compressa (blue-grey branching morphology) side by side in the same habitat; (B) example of variation in bleaching susceptibility of P. compressa in Kāne‘ohe Bay (C) Type specimens of P. lobata (yellow box) and P. compressa (blue box) illustrating a range of variation (Figures (A) and (C) modified from Forsman et al., please see for more detailed information on type specimens); (D, E) Predictive model of P. lobata and P. compressa distribution, Kāne ‘ohe Hawaiʻi (https://www.pacioos.hawaii.edu/projects/coral/).
Figure 2
Figure 2
Phylogenomic relationships between P. lobata (yellow circles), P. compressa (blue triangles = unbleached, empty triangles = bleached), and outgroup species (P. evermanni = brown circles). (A) coral mitochondrial genome RAxML tree consisting of ~ 18 k bp; (B) coral mitochondrial genome haplotype network; (C) RAxML tree of approximately 3 million SNPs from reads mapped to the P. lutea coral reference genome. mt: mitochondrial. P.sp1 and P.sp2 represent Porites corals with atypical colony morphology, P.sp1 was described by Brown et al. 2020 as an unusually resilient brooding coral. Red * indicates Maximum Likelihood support value > 95%.
Figure 3
Figure 3
PCA plots of Porites metagenomic libraries mapped to different reference datasets. (A) The coral host P. lutea genome; (B) The coral host P. lobata transcriptome; (C) The symbiont Cladocopium C15 genome; (D) The Metagenome-Assembled Bacterial Genomic reference. Ellipses represent 95% CI assuming a normal distribution.
Figure 4
Figure 4
Candidate outlier loci that mapped to the P. lobata host transcriptome. Manhattan plots of morphology (branching vs. mounding), mitochondrial clade (B vs. C) of P. compressa, and bleaching susceptibility (bleached vs. unbleached) of P. compressa. The colored lines represent the Bonferroni (red) and FDR (blue) corrections for multiple comparisons. Values above the red line were considered ‘highly significant’ outlier loci and between the blue and red lines were considered ‘significant’ candidate outlier loci. Values above 1 ×ばつ 1016 are shown as 1 ×ばつ 1016 to standardize the y axis. The green dot represents fixed differences between the chloroplast 23S ribosomal gene from the algal symbiont, and blue dots represent mitochondrial loci.

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