Image_1_Potential Acclimatization and Adaptive Responses of Adult and Trans-Generation Coral Larvae From a Naturally Acidified Habitat.JPEG

Coral reefs are one of the most susceptible ecosystems to ocean acidification (OA) caused by increasing atmospheric carbon dioxide (CO 2 ). OA is suspected to impact the calcification rate of corals as well as multiple early life stages including larval and settlement stages. Meanwhile, there is now...

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Bibliographic Details
Main Authors: Haruko Kurihara, Yuri Suhara, Izumi Mimura, Yimnang Golbuu
Format: Still Image
Language:unknown
Published: 2020
Subjects:
Oceanography
Marine Biology
Marine Geoscience
Biological Oceanography
Chemical Oceanography
Physical Oceanography
Marine Engineering
coral
high-CO2
local adaptation
trans-generation acclimatization
naturally acidified site
Ocean acidification
Online Access:https://doi.org/10.3389/fmars.2020.581160.s001
https://figshare.com/articles/figure/Image_1_Potential_Acclimatization_and_Adaptive_Responses_of_Adult_and_Trans-Generation_Coral_Larvae_From_a_Naturally_Acidified_Habitat_JPEG/13295183
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Summary:Coral reefs are one of the most susceptible ecosystems to ocean acidification (OA) caused by increasing atmospheric carbon dioxide (CO 2 ). OA is suspected to impact the calcification rate of corals as well as multiple early life stages including larval and settlement stages. Meanwhile, there is now a strong interest in evaluating if organisms have the potential for acclimatization or adaptation to OA. Here, by taking advantage of a naturally acidified site in Nikko Bay, Palau where corals are presumably exposed to high CO 2 conditions for their entire life history, we tested if adult and the next-generation larvae of the brooder coral Pocillopora acuta originating from the high-CO 2 site are more tolerant to high CO 2 conditions compared to the individuals from a control site. Larvae released from adults collected from the high-CO 2 site within the bay and a control site outside the bay were reciprocally cultivated under experimental control or high-CO 2 seawater conditions to evaluate their physiology. Additionally, reciprocal transplantation of adult P. acuta corals were conducted between the high-CO 2 and control sites in the field. The larvae originating from the control site showed lower Chlorophyll-a content and lipid percentages when reared under high-CO 2 compared to control seawater conditions, while larvae originating from the high-CO 2 site did not. Additionally, all 10 individuals of adult P. acuta from control site died when transplanted within the bay, while all P. acuta corals within the bay survived at both control and high-CO 2 site. Furthermore, P. acuta within the bay showed higher calcification and net photosynthesis rates when exposed to the condition they originated from. These results are one of the first results that indicate the possibility that the long-living corals could enable to show local adaptation to different environmental conditions including high seawater pCO 2 .

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