The Food Web of Potter Cove (Antarctica): complexity, structure and function
Knowledge of the food web structure and complexity are central to better understand ecosystem functioning. A food-web approach includes both species and energy flows among them, providing a natural framework for characterizing species’ ecological roles and the mechanisms through which biodiversity i...
Guardado en:
| Autores principales: | , , , , , , , , , , , , , , |
|---|---|
| Formato: | JOUR |
| Materias: | |
| Acceso en línea: | http://hdl.handle.net/20.500.12110/paper_02727714_v200_n_p141_Marina |
| Aporte de: |
| id |
todo:paper_02727714_v200_n_p141_Marina |
|---|---|
| record_format |
dspace |
| spelling |
todo:paper_02727714_v200_n_p141_Marina2023-10-03T15:15:19Z The Food Web of Potter Cove (Antarctica): complexity, structure and function Marina, T.I. Salinas, V. Cordone, G. Campana, G. Moreira, E. Deregibus, D. Torre, L. Sahade, R. Tatián, M. Barrera Oro, E. De Troch, M. Doyle, S. Quartino, M.L. Saravia, L.A. Momo, F.R. Antarctica Degree distribution Ecological networks Marine ecosystem Structure amphipod benthic environment biodiversity carbon flux complexity demersal fish ecosystem function energy flow food web functional group marine ecosystem network analysis pelagic environment specialization trophic cascade trophic interaction trophic structure Antarctic Peninsula Antarctica Antarctica King George Island Potter Cove South Shetland Islands West Antarctica Amphipoda Knowledge of the food web structure and complexity are central to better understand ecosystem functioning. A food-web approach includes both species and energy flows among them, providing a natural framework for characterizing species’ ecological roles and the mechanisms through which biodiversity influences ecosystem dynamics. Here we present for the first time a high-resolution food web for a marine ecosystem at Potter Cove (northern Antarctic Peninsula). Eleven food web properties were analyzed in order to document network complexity, structure and topology. We found a low linkage density (3.4), connectance (0.04) and omnivory percentage (45), as well as a short path length (1.8) and a low clustering coefficient (0.08). Furthermore, relating the structure of the food web to its dynamics, an exponential degree distribution (in- and out-links) was found. This suggests that the Potter Cove food web may be vulnerable if the most connected species became locally extinct. For two of the three more connected functional groups, competition overlap graphs imply high trophic interaction between demersal fish and niche specialization according to feeding strategies in amphipods. On the other hand, the prey overlap graph shows also that multiple energy pathways of carbon flux exist across benthic and pelagic habitats in the Potter Cove ecosystem. Although alternative food sources might add robustness to the web, network properties (low linkage density, connectance and omnivory) suggest fragility and potential trophic cascade effects. © 2017 Elsevier Ltd JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_02727714_v200_n_p141_Marina |
| institution |
Universidad de Buenos Aires |
| institution_str |
I-28 |
| repository_str |
R-134 |
| collection |
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) |
| topic |
Antarctica Degree distribution Ecological networks Marine ecosystem Structure amphipod benthic environment biodiversity carbon flux complexity demersal fish ecosystem function energy flow food web functional group marine ecosystem network analysis pelagic environment specialization trophic cascade trophic interaction trophic structure Antarctic Peninsula Antarctica Antarctica King George Island Potter Cove South Shetland Islands West Antarctica Amphipoda |
| spellingShingle |
Antarctica Degree distribution Ecological networks Marine ecosystem Structure amphipod benthic environment biodiversity carbon flux complexity demersal fish ecosystem function energy flow food web functional group marine ecosystem network analysis pelagic environment specialization trophic cascade trophic interaction trophic structure Antarctic Peninsula Antarctica Antarctica King George Island Potter Cove South Shetland Islands West Antarctica Amphipoda Marina, T.I. Salinas, V. Cordone, G. Campana, G. Moreira, E. Deregibus, D. Torre, L. Sahade, R. Tatián, M. Barrera Oro, E. De Troch, M. Doyle, S. Quartino, M.L. Saravia, L.A. Momo, F.R. The Food Web of Potter Cove (Antarctica): complexity, structure and function |
| topic_facet |
Antarctica Degree distribution Ecological networks Marine ecosystem Structure amphipod benthic environment biodiversity carbon flux complexity demersal fish ecosystem function energy flow food web functional group marine ecosystem network analysis pelagic environment specialization trophic cascade trophic interaction trophic structure Antarctic Peninsula Antarctica Antarctica King George Island Potter Cove South Shetland Islands West Antarctica Amphipoda |
| description |
Knowledge of the food web structure and complexity are central to better understand ecosystem functioning. A food-web approach includes both species and energy flows among them, providing a natural framework for characterizing species’ ecological roles and the mechanisms through which biodiversity influences ecosystem dynamics. Here we present for the first time a high-resolution food web for a marine ecosystem at Potter Cove (northern Antarctic Peninsula). Eleven food web properties were analyzed in order to document network complexity, structure and topology. We found a low linkage density (3.4), connectance (0.04) and omnivory percentage (45), as well as a short path length (1.8) and a low clustering coefficient (0.08). Furthermore, relating the structure of the food web to its dynamics, an exponential degree distribution (in- and out-links) was found. This suggests that the Potter Cove food web may be vulnerable if the most connected species became locally extinct. For two of the three more connected functional groups, competition overlap graphs imply high trophic interaction between demersal fish and niche specialization according to feeding strategies in amphipods. On the other hand, the prey overlap graph shows also that multiple energy pathways of carbon flux exist across benthic and pelagic habitats in the Potter Cove ecosystem. Although alternative food sources might add robustness to the web, network properties (low linkage density, connectance and omnivory) suggest fragility and potential trophic cascade effects. © 2017 Elsevier Ltd |
| format |
JOUR |
| author |
Marina, T.I. Salinas, V. Cordone, G. Campana, G. Moreira, E. Deregibus, D. Torre, L. Sahade, R. Tatián, M. Barrera Oro, E. De Troch, M. Doyle, S. Quartino, M.L. Saravia, L.A. Momo, F.R. |
| author_facet |
Marina, T.I. Salinas, V. Cordone, G. Campana, G. Moreira, E. Deregibus, D. Torre, L. Sahade, R. Tatián, M. Barrera Oro, E. De Troch, M. Doyle, S. Quartino, M.L. Saravia, L.A. Momo, F.R. |
| author_sort |
Marina, T.I. |
| title |
The Food Web of Potter Cove (Antarctica): complexity, structure and function |
| title_short |
The Food Web of Potter Cove (Antarctica): complexity, structure and function |
| title_full |
The Food Web of Potter Cove (Antarctica): complexity, structure and function |
| title_fullStr |
The Food Web of Potter Cove (Antarctica): complexity, structure and function |
| title_full_unstemmed |
The Food Web of Potter Cove (Antarctica): complexity, structure and function |
| title_sort |
food web of potter cove (antarctica): complexity, structure and function |
| url |
http://hdl.handle.net/20.500.12110/paper_02727714_v200_n_p141_Marina |
| work_keys_str_mv |
AT marinati thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT salinasv thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT cordoneg thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT campanag thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT moreirae thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT deregibusd thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT torrel thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT sahader thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT tatianm thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT barreraoroe thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT detrochm thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT doyles thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT quartinoml thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT saraviala thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT momofr thefoodwebofpottercoveantarcticacomplexitystructureandfunction AT marinati foodwebofpottercoveantarcticacomplexitystructureandfunction AT salinasv foodwebofpottercoveantarcticacomplexitystructureandfunction AT cordoneg foodwebofpottercoveantarcticacomplexitystructureandfunction AT campanag foodwebofpottercoveantarcticacomplexitystructureandfunction AT moreirae foodwebofpottercoveantarcticacomplexitystructureandfunction AT deregibusd foodwebofpottercoveantarcticacomplexitystructureandfunction AT torrel foodwebofpottercoveantarcticacomplexitystructureandfunction AT sahader foodwebofpottercoveantarcticacomplexitystructureandfunction AT tatianm foodwebofpottercoveantarcticacomplexitystructureandfunction AT barreraoroe foodwebofpottercoveantarcticacomplexitystructureandfunction AT detrochm foodwebofpottercoveantarcticacomplexitystructureandfunction AT doyles foodwebofpottercoveantarcticacomplexitystructureandfunction AT quartinoml foodwebofpottercoveantarcticacomplexitystructureandfunction AT saraviala foodwebofpottercoveantarcticacomplexitystructureandfunction AT momofr foodwebofpottercoveantarcticacomplexitystructureandfunction |
| _version_ |
1807320589017284608 |