Abstract
Astrangia poculata is a temperate scleractinian coral that exists in facultative symbiosis with the dinoflagellate alga Breviolum psygmophilum across a range spanning the Gulf of Mexico to Cape Cod, Massachusetts. Our previous work on metabolic thermal performance of Virginia (VA) and Rhode Island (RI) populations of A. poculata revealed physiological signatures of cold (RI) and warm (VA) adaptation of these populations to their respective local thermal environments. Here, we used whole-transcriptome sequencing (mRNA-Seq) to evaluate genetic differences and identify potential loci involved in the adaptive signature of VA and RI populations. Sequencing data from 40 A. poculata individuals, including 10 colonies from each population and symbiotic state (VA-white, VA-brown, RI-white, and RI-brown), yielded a total of 1,808 host-associated and 59 algal symbiont-associated single nucleotide polymorphisms (SNPs) post filtration. Fst outlier analysis identified 66 putative high outlier SNPs in the coral host and 4 in the algal symbiont. Differentiation of VA and RI populations in the coral host was driven by putatively adaptive loci, not neutral divergence (Fst = 0.16, p = 0.001 and Fst = 0.002, p = 0.269 for outlier and neutral SNPs respectively). In contrast, we found evidence of neutral population differentiation in B. psygmophilum (Fst = 0.093, p = 0.001). Several putatively adaptive host loci occur on genes previously associated with the coral stress response. In the symbiont, three of four putatively adaptive loci are associated with photosystem proteins. The opposing pattern of neutral differentiation in B. psygmophilum, but not the A. poculata host, reflects the contrasting dynamics of coral host and algal symbiont population connectivity, dispersal, and gene by environment interactions.
Highlights
Population connectivity in marine systems is shaped by a complex mixture of factors, including oceanographic currents (Selkoe, Henzler & Gaines, 2008), planktonic larval durations and behavior (Selkoe & Toonen, 2011), life history dynamics (Bradbury et al, 2008), and environmentally driven selection (Limborg et al, 2012), among othersHow to cite this article Aichelman HE, Barshis DJ. 2020
The unfiltered vcf file had a total of 1,214,003 variants, 432,676 of which were on host contigs and 16,417 of which were on symbiont contigs
We found contrasting levels of genetic connectivity in the different partners of the Astrangia poculata holobiont, with neutral gene flow and adaptive divergence in the coral host versus neutral and adaptive divergence in the algal symbiont. This highlights how the interacting forces of oceanography, environmentally driven selection, local adaptation, and reproductive biology can manifest in differential connectivity of a marine holobiont system
Summary
Population connectivity in marine systems is shaped by a complex mixture of factors, including oceanographic currents (Selkoe, Henzler & Gaines, 2008), planktonic larval durations and behavior (Selkoe & Toonen, 2011), life history dynamics (Bradbury et al, 2008), and environmentally driven selection (Limborg et al, 2012), among othersHow to cite this article Aichelman HE, Barshis DJ. 2020. Patterns of differential connectivity of coral hosts and symbionts has been observed, with coral hosts generally exhibiting connectivity across larger scales compared to their hosted algal symbionts (Baums, Devlin-Durante & LaJeunesse, 2014; Pettay & LaJeunesse, 2013; Pinzon & LaJeunesse, 2011) This difference in dispersal among symbiotic partners could be influenced by distinct life history strategies and resulting dispersal abilities, transmission strategy of symbionts (i.e., horizontal vs vertical), and/or differential selection pressures (Baums, Devlin-Durante & LaJeunesse, 2014)
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