Alexandre Buttler, head of EPFL's Ecological Systems Laboratory (ECOS), and Luca Bragazza, a scientist at ECOS, along with a team of European researchers including two former EPFL post-docs, analyzed 560 intact peat bog samples from 56 European countries to study how peat bog ecosystems respond to different temperatures, precipitation levels and air pollution levels. They found that peat bog properties remained the same across the board, demonstrating a surprising ability to adapt to climatic variation. This is because species that were suited to a certain climate were replaced elsewhere by other species that were better suited to the new climate yet serving the same function within the ecosystem. The research has just been published in Nature Communications.
Peat bogs play an essential role on our planet. While they cover only 3% of the earth's surface, they store some 500 metric gigatons of carbon . This is the equivalent of 67% of all the CO2 in the air, or all the CO2 held in the world's boreal forestland, which makes up 10% of the earth's surface. A depth of one meter of peat corresponds to approximately 1,000 years of carbon storage. Because so much carbon is currently locked up in peat bogs, understanding how they respond to climate change is essential to know whether they might one day release massive amounts of CO2 into the air. Peat bogs are found on wet, acidic soil and have low biodiversity, which differs little from one region to the next – only around 60 species live in these ecosystems. What's more, these species are known to be sensitive to environmental conditions; they consist of vascular plants (shrubs, grasses and carnivorous plants) and moss (Sphagnum). Those factors would seem to indicate that peat bogs are exceptionally vulnerable to climate change, e.g., if the moss disappeared and vascular plants grew in its place, the ecosystem would shift dramatically and its CO2 storage capacity would shrink considerably.
Good news is hard to come by in environmental science these days. Fortunately, peat bogs' astonishing ability to resist climate change gives scientists reason to cheer. "Ecologists tend to believe that ecosystems with low biodiversity are more likely to disappear when environmental conditions change, even slightly. But what we found here opens the door to new ways of understanding biodiversity. Our study also underscores how important it is to preserve peat bogs – not just for their own sake, but also for the ecological services and benefits they bring," says Bragazza.
Analyzing 560 peat bog samples was no mean feat. The researchers first determined each sample's biodiversity "taxonomy," listing the number and abundance of each species in the samples. They then identified over a dozen functional traits of the species characterizing their role within its ecosystem. These functional characteristics include how they absorb water or capture light, the amount of carbon, nitrogen and phosphorous the moss contains, and the thickness, size and diameter of the vascular plants' leaves. The researchers obtained information about these functional characteristics from an existing database, and ran this information against the species they found in their peat bog samples. "We took the average value of each functional characteristic given in the database, factoring in the abundance of each species in the samples. That allowed us to go beyond simply comparing the species in our samples," says Bragazza.
Surprisingly, the researchers found "functional redundancy" in the samples. That is, the vascular plants and moss replaced each other based on the climatic conditions their ecosystem was exposed to, enabling the peat ecosystem as a whole to survive. "The average values for the functional characteristics didn't change, even if the taxonomy did. For instance, some species in the peat bog samples from Ireland don't exist in the samples from Sweden; those samples have other species that are better suited to the Swedish climate. But even when the species are different, they serve the same function within the ecosystem – they have the same size leaves and stems, for example," says Bragazza.
"Peat bogs are excellent CO2 sinks and have an unparalleled ability to adapt to climate change. That's in stark contrast to prairies, which nevertheless have greater biodiversity. Climate change can disrupt hay production in prairies and cause lasting damage to the ecosystem," says Buttler. Bragazza goes on to stress the importance of protecting peat bogs: "Their ability to adapt to climate change and therefore keep on storing CO2 depends on how well their species can move from one bog to the next and create this 'functional redundancy.' Our study once again shows that it's vital to maintain peat bogs' biodiversity and prevent them from becoming isolated."
The vast amount of data that the team collected from peat bogs across Europe will be used to carry out further research, such as comparative analyses of the bogs' microbial compositions and assessments of their resistance thresholds. A promising way to learn more about peat bogs' unexpected properties.
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Reference
Bjorn J. M. Robroek, Vincent E. J. Jassey, Richard J. Payne, MagalĂ MartĂ, Luca Bragazza, Albert Bleeker, Alexandre Buttler, Simon J. M. Caporn, Nancy B. Dise, Jens Kattge, Katarzyna Zaj?c, Bo H. Svensson, Jasper van Ruijven, and Jos T. A. Verhoeven. "Taxonomic and functional turnover are decoupled in European peat bogs," Nature Communications, 27 October 2017.
This study was carried out under the BiodivERsA-PEATBOG EU research program, with the support of several research institutes including EPFL and the Swiss Federal Institute for Forest, Snow and Landscape Research (WSL).
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http://dx.doi.org/10.1038/s41467-017-01350-5
