TY - JOUR
T1 - Metabolic acceleration in the pond snail Lymnaea stagnalis?
AU - Zimmer, Elke
AU - Ducrot, Virginie
AU - Jager, Tjalling
AU - Koene, Joris
AU - Lagadic, Laurent
AU - Kooijman, Sebastiaan A.L.M.
N1 - Funding Information:
We thank the guest editor Mike Kearney and two anonymous reviewers for their critical comments which greatly helped to improve the manuscript. We further thank Alpar Barsi and Marc Roucaute at INRA for providing zero-variate data points, and Fernando Monroy at the group Ecological Sciences at the VU for providing respiration data of adult snails. This research has been supported by the European Union under the 7th Framework Programme (project acronym CREAM, contract number PITN-GA-2009-238148 ), and by French funds under the Program “Environnement-Santé-Travail” from ANSES (project acronym MODENDO, contract number EST 2011/1/153 ).
Publisher Copyright:
© 2014 Elsevier B.V.
PY - 2014/11/1
Y1 - 2014/11/1
N2 - Under constant environmental conditions, most animals tend to grow following the von Bertalanffy growth curve. Deviations from this curve can point to changes in the environment that the animals experience, such as food limitation when the available food is not sufficient or suitable. However, such deviations can also point to a phenomenon called metabolic acceleration, which is receiving increasing attention in the field of Dynamic Energy Budget (DEB) modeling. Reasons for such an acceleration are usually changes in shape during ontogeny, which cause changes in the surface area to volume ratio of the organism. Those changes, in turn, lead to changes in some of the model parameters that have length in their dimension. The life-history consequences of metabolic acceleration as implemented in the DEB theory are an s-shaped growth curve (when body size is expressed as a length measure) and a prolongation of the hatching time. The great pond snail Lymnaea stagnalis was earlier found to be food limited during the juvenile phase in laboratory experiments conducted under classical ecotoxicity test protocols. The pond snail has isomorphic shell growth but yet does not exhibit the expected von Bertalanffy growth curve under food limitation. When applying the standard DEB model to data from such life-cycle experiments, we also found that the hatching time is consistently underestimated, which could be a sign of metabolic acceleration. We here present an application of the DEB model including metabolic acceleration to the great pond snail. We account for the simultaneous hermaphroditism of the snail by including a model extension that describes the relative investment into the male and female function. This model allowed us to adequately predict the life history of the snail over the entire life cycle. However, the pond snail does not change in shape substantially after birth, so the original explanation for the metabolic acceleration does not hold. Since the change in shape is not the only explanation for metabolic acceleration in animals, we discuss the possible other explanations for this pattern in L. stagnalis.
AB - Under constant environmental conditions, most animals tend to grow following the von Bertalanffy growth curve. Deviations from this curve can point to changes in the environment that the animals experience, such as food limitation when the available food is not sufficient or suitable. However, such deviations can also point to a phenomenon called metabolic acceleration, which is receiving increasing attention in the field of Dynamic Energy Budget (DEB) modeling. Reasons for such an acceleration are usually changes in shape during ontogeny, which cause changes in the surface area to volume ratio of the organism. Those changes, in turn, lead to changes in some of the model parameters that have length in their dimension. The life-history consequences of metabolic acceleration as implemented in the DEB theory are an s-shaped growth curve (when body size is expressed as a length measure) and a prolongation of the hatching time. The great pond snail Lymnaea stagnalis was earlier found to be food limited during the juvenile phase in laboratory experiments conducted under classical ecotoxicity test protocols. The pond snail has isomorphic shell growth but yet does not exhibit the expected von Bertalanffy growth curve under food limitation. When applying the standard DEB model to data from such life-cycle experiments, we also found that the hatching time is consistently underestimated, which could be a sign of metabolic acceleration. We here present an application of the DEB model including metabolic acceleration to the great pond snail. We account for the simultaneous hermaphroditism of the snail by including a model extension that describes the relative investment into the male and female function. This model allowed us to adequately predict the life history of the snail over the entire life cycle. However, the pond snail does not change in shape substantially after birth, so the original explanation for the metabolic acceleration does not hold. Since the change in shape is not the only explanation for metabolic acceleration in animals, we discuss the possible other explanations for this pattern in L. stagnalis.
KW - Dynamic Energy Budget
KW - Food limitation
KW - Metabolic acceleration
KW - Mollusk
KW - Simultaneous hermaphroditism
UR - http://www.scopus.com/inward/record.url?scp=85027925533&partnerID=8YFLogxK
U2 - 10.1016/j.seares.2014.07.006
DO - 10.1016/j.seares.2014.07.006
M3 - Article
AN - SCOPUS:85027925533
SN - 1385-1101
VL - 94
SP - 84
EP - 91
JO - Journal of Sea Research
JF - Journal of Sea Research
ER -