Food-limited invertebrate larvae in the Southern Ocean: testing a paradigm

A long-standing paradigm of larval ecology is that the high incidence of non-feeding larval development in Antarctic invertebrates is an adaptation to limited availability of algal food. Antarctic plankton communities have a relatively high diversity and abundance of invertebrate larvae, some of whi...

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Bibliographic Details
Published in:Marine Ecology Progress Series
Main Authors: Ameneiro, Julia, Lubián, L. M., Sangrà, Pablo, Vázquez, E.
Format: Article in Journal/Newspaper
Language:English
Published: 2016
Subjects:
Online Access:http://hdl.handle.net/10553/42076
https://doi.org/10.3354/meps11786
Description
Summary:A long-standing paradigm of larval ecology is that the high incidence of non-feeding larval development in Antarctic invertebrates is an adaptation to limited availability of algal food. Antarctic plankton communities have a relatively high diversity and abundance of invertebrate larvae, some of which are planktotrophic and synchronize the presence of feeding larval stages to peaks in summer phytoplankton. Among the echinoderm larvae found between 30 December 2002 and 7 January 2003 in the Bransfield Strait, the planktotrophic brachiolaria of Odontaster were the most abundant. Although phytoplankton is the main food source for planktotrophic larvae of asteroids in other oceans, previous estimates of the carbon requirements of larvae of the Antarctic asteroid O. validus have indicated that these larvae could not survive on natural levels of Antarctic phytoplankton. The main aims of the present study were to establish whether the abundance of Odontaster larvae is related to that of palatable phytoplankton and to determine whether the availability of the latter would be sufficient to cover the carbon requirements of the larvae. We found that of all palatable phytoplanktonic groups (Cryptophyceae, picoplankton, nanoplankton and ultraplankton), only Cryptophyceae was a significant predictor of brachiolaria abundance, along with the stratification index. We also found that the carbon content of the total palatable phytoplankton would be sufficient to meet the carbon requirements of Odontaster larvae at almost all stations and depths. Although O. validus spawns between mid- and late winter when the concentration of phytoplankton is lowest, winter spawning may be one way of meeting the exogenous energetic requirements of larvae.