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Understanding Marine Life’s Ability To Adapt To Climate Change

August 26, 2013
Image Caption: This shows CO2 vents. Credit: Plymouth University

University of Plymouth

A study into marine life around an underwater volcanic vent in the Mediterranean, might hold the key to understanding how some species will be able to survive in increasingly acidic sea water should anthropogenic climate change continue.

Researchers have discovered that some species of polychaete worms are able to modify their metabolic rates to better cope with and thrive in waters high in carbon dioxide (CO2), which is otherwise poisonous to other, often closely-related species.

The study sheds new light on the robustness of some marine species and the relative resilience of marine biodiversity should atmospheric CO2 continue to cause ocean acidification.

A team of scientists led by Plymouth University, and including colleagues from the Naples Zoological Station in Ischia; the Marine Ecology Laboratory ENEA in La Spezia, Italy; the University of Texas Galveston; and the University of Hull, conducted a three-year research project into the potential mechanisms that species of worm polychaetes use to live around the underwater CO2 vent of Ischia in Southern Italy.

The researchers collected specimens found in waters characterized by either elevated or low levels of CO2, and placed them in specially-constructed ‘transplantation chambers’, which were then lowered into areas both within and away from the volcanic vent.

They monitored the responses of the worms and found that one of the species that had been living inside the CO2 vent was physiologically and genetically adapted to the acidic conditions, whilst another was able to survive inside the vent by adjusting its metabolism.

Project leader Dr Piero Calosi, of Plymouth University’s Marine Institute, said: “Previous studies have shown that single-cell algae can genetically adapt to elevated levels of carbon dioxide, but this research has demonstrated that a marine animal can physiologically and genetically adapt to chronic and elevated levels of carbon dioxide.

“Furthermore, we show that both plasticity and adaptation are key to preventing some species’ from suffering extinction in the face of on-going ocean acidification, and that these two strategies may be largely responsible to defining the fate of marine biodiversity.”

The results revealed that species normally found inside the CO2 vent were better able to regulate their metabolic rate when exposed to high CO2 conditions, whilst species only found outside the CO2 vent were clearly impaired by acidic waters. In fact, their metabolism either greatly decreased, indicating reduced energy production, or greatly increased, indicating a surge in the basic cost of living, in both cases making life inside the vent unsustainable.

Dr Maria-Cristina Gambi, of the Naples Zoological Station in Ischia, explained: “Despite some species showing the ability to metabolically adapt and adjust to the extreme conditions that are found inside the CO2 vents, others appear unable to physiologically cope with such conditions.

”In this sense, our findings could help to explain mass extinctions of the past, and potential extinctions in the future, as well as shed light on the resilience of some species to on-going ocean acidification.”

The team also found that those species adapted to live inside the CO2 vent showed slightly higher metabolic rates and were much smaller in size – up to 80% smaller – indicating that adaptation came at a cost of energy for growth.

Dr Calosi concluded that: ”Ultimately, species’ physiological responses to high CO2, as those reported by our study, may have repercussions on their abundance and distribution, and thus on the structure and dynamics of marine communities. This in turn will impact those ecosystem functions that humans rely upon to obtain goods and services from the ocean.”

The research was funded by a Natural Environment Research Council UK Ocean Acidification Research Programme grant, and an Assemble Marine EU FP7 scheme, and is the first of its kind to bring together both the physiological and genetic evidence for adaptation to elevated pCO2 in a multicellular organism.

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Source: University of Plymouth



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