High pCO 2 levels affect metabolic rate, but not feeding behavior and fitness, of farmed giant mussel Choromytilus chorus

dc.contributor.authorBenítez, S.
dc.contributor.authorLagos, N.A.
dc.contributor.authorOsores, S.
dc.contributor.authorOpitz, T.
dc.contributor.authorDuarte, C.
dc.contributor.authorNavarro, J.M.
dc.contributor.authorLardies, M.A.
dc.date.accessioned2019-11-28T13:04:28Z
dc.date.available2019-11-28T13:04:28Z
dc.date.issued2018
dc.descriptionIndexación: Scopus.es
dc.descriptionAcknowledgements. We thank Luisa Saavedra and Araceli Rodriguez-Romero for their help in the field and during laboratory activities. We also acknowledge Laura Ramajo for help with AT estimations. Emily Giles Neill provided valuable comments that greatly improved the manuscript. Special thanks are due to the reviewers and the editor for very constructive comments on the manuscript. This study was supported by the Millennium Nucleus Center for the Study of Multiple drivers on Marine Socio-Ecological Systems (MUSELS) funded by MINECON NC120086, PIA CONICYT ACT-172037 and FONDECYT grant nos. 1140938 and 1140092 to N.A.L. and M.A.L.
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dc.description.abstractBenthic habitats such as intertidal areas, sandy or rocky shores, upwelling zones, and estuaries are characterized by variable environmental conditions. This high variability of environmental stressors such as temperature, salinity, and pH/pCO 2 levels have been shown to impose restrictions on organismal performance. The giant mussel Choromytilus chorus forms intertidal and subtidal mussel beds in estuarine zones associated with fjords occurring in southern Chile and is an important aquacultural resource in Patagonia. In this study, we estimated the sensitivity of physiological traits and energy balance of C. chorus juveniles exposed to 3 pCO 2 treatments (500, 750, and 1200 μatm) for 30 d. Results showed that in acidified, high pCO 2 conditions, C. chorus juveniles had increased metabolic rates; however, other physiological traits (clearance and ingestion rates, ammonia excretion, absorption efficiency, growth rate, biomass production, net calcification, and dissolution rates) were not affected. These results suggest that when subjected to acidification, the adaptive response of C. chorus triggers tradeoffs among physiological traits that favor sustained feeding and growth in order to combat increased metabolic stress. As has been reported for other marine organisms, chronic exposure to variable pH/pCO 2 in their native habitats, such as estuarine zones, could explain the differential acclimatization capacity of giant mussels to cope with the increase in pCO 2 . Additionally, the fact that the mussels did not suffer from mortality indicates that increased pCO 2 levels may have chronic, but not lethal, effects on this species under these experimental conditions. © The authors 2017.es
dc.description.urihttps://www.int-res.com/abstracts/aei/v10/p267-278/
dc.identifier.citationAquaculture Environment Interactions, 10, pp. 267-278.es
dc.identifier.issn1869-215X
dc.identifier.otherDOI: 10.3354/AEI00271
dc.identifier.urihttp://repositorio.unab.cl/xmlui/handle/ria/10863
dc.language.isoenes
dc.publisherInter-Researches
dc.subjectAcclimationes
dc.subjectAquaculturees
dc.subjectEstuarieses
dc.subjectpHes
dc.subjectPhenotypic plasticityes
dc.subjectPhysiological traitses
dc.titleHigh pCO 2 levels affect metabolic rate, but not feeding behavior and fitness, of farmed giant mussel Choromytilus choruses
dc.typeArtículoes
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