Effects of CO2-induced ocean environmental changes on marine life: implications for aquaculture

The world's oceans are becoming warmer and acidic. The atmospheric carbon dioxide concentration has increased from 280 ppm at pre-industrial revolution to above 380 ppm today. The 4th IPCC report predicts that it will range from 540 to nearly 1,000 ppm by the end of the century. The increased C...

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Bibliographic Details
Main Authors: Ishimatsu, Atsushi, Kurihara, Haruko
Other Authors: Acosta, Belen O., Coloso, Relicardo M., de Jesus-Ayson, Evelyn Grace T., Toledo, Joebert D.
Format: Conference Object
Language:English
Published: Aquaculture Department, Southeast Asian Fisheries Development Center 2011
Subjects:
corals
development
Echinoidea
Penaeidae
Eastern Pacific
abiotic factors
acidification
adaptation
growth
aquaculture
calcification
carbon dioxide
climate change
data processing
Environmental changes
Environmental effects
fisheries
global warming
gonads
larval stage
marine environment
Oceans
ovaries
survival
temperature effects
water temperature
carbonic acid
ph effects
Pacific
Carbonic acid
Ocean acidification
Online Access:http://hdl.handle.net/10862/1821
https://repository.seafdec.org.ph/bitstream/10862/1821/2/1821-IshimatsuA2011.pdf.jpg
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Summary:The world's oceans are becoming warmer and acidic. The atmospheric carbon dioxide concentration has increased from 280 ppm at pre-industrial revolution to above 380 ppm today. The 4th IPCC report predicts that it will range from 540 to nearly 1,000 ppm by the end of the century. The increased CO 2 not only warms surface seawater, but also acidifies it (usually termed as ocean acidification) by diffusing across the ocean surface and forming carbonic acid. Our knowledge is still scarce as to how these ocean environmental changes will affect marine life. The early studies on the impact of ocean acidification focused on corals aiming to clarify effects of high-CO 2 seawater on their calcification processes. However, more recent studies have revealed that in fact ocean acidification, either alone or coupled with warming, could have detrimental impacts on a variety of biological processes in different taxa. We have shown that early development of marine bivalves (oysters and mussels) could be severely disrupted under elevated CO 2 conditions (ca. 2,000 ppm). When a marine shrimp was exposed to seawater equilibrated with air containing 1,000 ppm CO 2 for 30 weeks, survival was only 55% as compared with 90% in the control. Gonad maturation of a sea urchin was delayed by one month under the same CO 2 conditions at ambient temperature, but when accompanied with increased temperature of 2 degree C above ambient, gonad maturation was not only delayed but also significantly suppressed; the number of eggs in the ovary was reduced to only 20% of the control. It has been shown that tropical animals already live near their thermal tolerant maxima, and therefore even small increases of environmental temperature could reduce their environmental fitness. These recent findings bear significant implication in aquaculture and fisheries production, in particular, in tropical countries. This paper will summarize recent data on these topics and discuss possible adaptation measures.

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