Abstract
Ocean acidification (OA) can be detrimental to calcifying marine organisms, with stunting of invertebrate larval development one of the most consistent responses. Effects are usually measured by short‐term, within‐generation exposure, an approach that does not consider the potential for adaptation. We examined the genetic response to OA of larvae of the tropical sea urchin Echinometra sp. C. raised on coral reefs that were either influenced by CO2 vents (pH ~ 7.9, future OA condition) or nonvent control reefs (pH 8.2). We assembled a high quality de novo transcriptome of Echinometra embryos (8 hr) and pluteus larvae (48 hr) and identified 68,056 SNPs. We tested for outlier SNPs and functional enrichment in embryos and larvae raised from adults from the control or vent sites. Generally, highest F ST values in embryos were observed between sites (intrinsic adaptation, most representative of the gene pool in the spawned populations). This comparison also had the highest number of outlier loci (40). In the other comparisons, classical adaptation (comparing larvae with adults from the control transplanted to either the control or vent conditions) and reverse adaptation (larvae from the vent site returned to the vent or explanted at the control), we only observed modest numbers of outlier SNPs (6–19) and only enrichment in two functional pathways. Most of the outliers detected were silent substitutions without adaptive potential. We conclude that there is little evidence of realized adaptation potential during early development, while some potential (albeit relatively low) exists in the intrinsic gene pool after more than one generation of exposure.
Highlights
Increased sea surface temperatures (SST) and ocean acidification (OA), as a result of rising Pco2 concentrations, are driving changes in marine ecosystems
This design should allow us to distin‐ guish outlier single nucleotide polymorphisms (SNPs) in genes providing potential for adaptation to Ocean acidification (OA) during short incubations, from those already differentiated in the two source populations
This research tested the hypothesis that long‐term exposure of adult sea urchins to elevated Pco2 or short‐term (8, 48 hr) larval exposure can lead to adaptation to ocean acidification conditions
Summary
In situ Echinometra larval growth studies in these sites showed that exposure to future OA conditions can lead to stunted and abnormal growth (Lamare et al, 2016) This is in agreement with previous laboratory studies on the same genus (Uthicke, Soars, et al, 2013) and on a wide variety of sea urchins from tropical to arctic regions (Byrne et al, 2013). We compared larvae derived from adult urchins from either a control or vent location that were cross transplanted to the reciprocal site with those exposed at their parent's origin (Figure 1) This design should allow us to distin‐ guish outlier SNPs in genes providing potential for adaptation to OA during short incubations, from those already differentiated in the two source populations
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