An adult sea butterfly, a tiny free swimming sea snail. Photo Credit: Victoria Peck – British Antarctic Survey |
Shelled pteropods, commonly known as sea butterflies, are increasingly exposed to ocean changes, but some species are more vulnerable to this threat. In a new study, published this month in the journal Frontiers in Marine Science, British Antarctic Survey (BAS) scientists examining pteropod life cycles in the Southern Ocean have found that some species might be more vulnerable to this threat due to different timings of their life cycle.
Sea butterflies are tiny, free-swimming sea snails, which are an important part of the marine ecosystem. They are also vulnerable to climate change as their shells are sensitive to ocean acidification. Now, a team of researchers led by BAS has examined the life cycles of two free-swimming sea snail species. They found that one is less vulnerable to changes in the Southern Ocean than the other, which could affect the sea snails on a population level and in turn impact the marine ecosystem.
The world’s oceans absorb approximately a quarter of all carbon dioxide (CO2) emissions. During absorption, CO2 reacts with seawater and oceanic pH levels fall. This is known as ocean acidification and results in lower carbon ion concentrations. Certain ocean inhabitants use carbon ions to build and sustain their shells. Pteropods, which are important components of the marine ecosystem, are among them.
Certain aspects about pteropods, including life cycles and population dynamics, are not well-studied. This is partly due to their size – some sea butterfly species measure less than a millimetre in length – and poor long-term survival in captivity. Now, a team of marine scientists has examined life cycles, abundance, and seasonal variability of shelled sea butterflies in the north-east Scotia Sea, a region undergoing some of the fastest climate change in the Southern Ocean.
Dr Clara Manno, a marine ecologist at BAS, says:“Decline in Antarctic Ocean pteropod populations could have cascading ramifications to the food web and carbon cycle. Knowledge about the life cycle of this keystone organism may improve prediction of ocean acidification impacts on the Antarctic ecosystem.”
For their work, the scientists collected sea butterflies in a sediment trap, a sampling device moored at 400 meters depth.
Dr Vicky Peck, a palaeoceanographer at BAS and co-author of the study, says:“It is impossible to observe the full life cycle of sea butterflies in a laboratory setting, so we had to piece together information about their spawning, growth rate and population structure. Using sediment trap samples, we successfully reconstructed their life cycle over a year.”
For the two dominant species collected – Limacina rangii and Limacina retroversa – the scientists observed contrasting life cycles, leading to different vulnerabilities to changing oceans. L. rangii, a polar species, can be found in both adults and juveniles during the winter months. L. retroversa, a subpolar species, appears to occur only as adults during the winter. During the coldest season, ocean water is more acidic than during other times of the year because cooler temperatures increase the amount of CO2 that can dissolve into the ocean. The life stages of sea butterflies that exist then are more exposed and vulnerable to increased levels of ocean acidification.
The fact that L. rangii adults and juveniles coexist over winter may give them a survival advantage. If one cohort is vulnerable, the overall population stability is not at risk. With L. retroversa, however, if one cohort is removed, the whole population may be vulnerable. The researchers noted that despite species being impacted differently, neither is likely to remain unharmed if exposed to unfavorable conditions for extended time periods.
As the intensity and duration of ocean acidification events increase, they begin to overlap with spawning events in the spring. This may put the most vulnerable life stage, the larvae, particularly at risk and could jeopardize future populations, the scientists warned. To learn how such a scenario might play out in the Scotia Sea, the research team will continue to study sea butterflies dwelling there.
Dr Jessie Gardner of BAS, lead author of the study, says:“The next step will be to focus on multiyear sediment trap samples to identify longer-term changes in the life cycle associated with environmental change”.
Published in journal: Frontiers in Marine Science
Source/Credit: British Antarctic Survey
Reference Number: mb051623_01