RT Journal Article
SR Electronic
T1 Effects of temperature and pCO2 on the respiration, biomineralization and photophysiology of the giant clam Tridacna maxima
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 672907
DO 10.1101/672907
A1 Chloé Brahmi
A1 Leila Chapron
A1 Gilles Le Moullac
A1 Claude Soyez
A1 Benoît Beliaeff
A1 Claire E. Lazareth
A1 Nabila Gaertner-Mazouni
A1 Jeremie Vidal-Dupiol
YR 2019
UL http://biorxiv.org/content/early/2019/06/18/672907.abstract
AB Such as many other reef organisms, giant clams are today confronted to global change effects and can suffer mass bleaching or mortality events mainly related to abnormally high seawater temperatures. Despite its strong ecological and socio-economical importance, its responses to the two most alarming threats linked to global change (i.e., ocean warming and acidification) still need to be explored. We investigated physiological responses of 4-years-old Tridacna maxima specimens to realistic levels of temperature and partial pressure of carbon dioxide (pCO2) (+1.5°C and +800 μatm of CO2) predicted for 2100 in French Polynesian lagoons during the warmer season. During a 65-days crossed-factor experiment, individuals were exposed to two temperatures (29.2°C; 30.7°C) and two pCO2 (430 µatm; 1212 µatm) conditions. Impact of each parameter and their potential synergetic effect were evaluated on respiration, biomineralization and photophysiology. Kinetics of thermal and acidification stress were evaluated by performing measurements at different times of exposure (29, 41, 53, 65 days). At 30.7°C, the holobiont O2 production, symbiont photosynthetic yield, and density were negatively impacted. High pCO2 had a significant negative effect on shell growth rate, symbiont photosynthetic yield and density. Shell microstructural modifications were observed from 41 days in all temperature and pCO2 conditions. No significant synergetic effect was found. Today thermal conditions (29.2°C) appeared to be sufficiently stressful to induce a host acclimatization process. All these observations indicate that temperature and pCO2 are both forcing variables affecting T. maxima physiology and jeopardize its survival under environmental conditions predicted for the end of this century.