Climate change confers a potential advantage to fleshy Antarctic crustose macroalgae over calcified species.

Academic Article

Abstract

  • © 2015 Elsevier B.V. Climate change impacts were investigated in two species of crustose Antarctic macroalgae that may be natural competitors in their habitat. The seawater parameters oceanic pH and temperature were modified to near future projections for the western Antarctic Peninsula in microcosm experiments. Experiments included two crustose algae, the calcified coralline alga Clathromorphum obtectulum and the fleshy encrusting rhodophyte Hildenbrandia sp., and were run for six weeks. Treatments reflected near future ocean conditions under climate change predictions: increased temperature (3.5°C×pH8.1), increased pCO2 (1.5°C×pH7.8), combined factors (3.5°C×pH7.8), and ambient conditions (1.5°C×pH8.1). The physiological responses of the algae were evaluated through photosynthetic parameters (slope to saturation of photo centers (α), saturating irradiance (Ek), maximum electron transport rate (ETRmax), maximum quantum yield of photosystem II (Fv/Fm)), growth, chlorophyll a concentration, and for C. obtectulum calcium carbonate content and Mg/Ca ratio. No negative impacts of elevated temperature or increased pCO2 were observed in either species. The fleshy alga decreased in size in low pH and high temperature treatments alone, but increased growth significantly when these factors were combined. Photosynthetic parameters were depressed by increased temperature in the calcified species and pH in the fleshy species but no significant differences were observed in other parameters in either species. This indicates that Hildenbrandia sp. may have a competitive advantage for space in the subtidal environment in near future oceanic conditions. However because benthic ecology in this geographic region is not well understood it is uncertain how these results will ultimately impact the community.
  • Digital Object Identifier (doi)

    Author List

  • Schoenrock KM; Schram JB; Amsler CD; McClintock JB; Angus RA; Vohra YK
  • Start Page

  • 58
  • End Page

  • 66
  • Volume

  • 474