Marine ecosystem assessment for the Southern Ocean : Birds and marine mammals in a changing climate
- Bestley, Sophie, Ropert-Coudert, Yan, Bengtson Nash, Susan, Brooks, Cassandra, Cotté, Cedric, Dewar, Meagan, Friedlaender, Ari, Jackson, Jennifer, Labrousse, Sara, Lowther, Andrew, McMahon, Clive, Phillips, Richard, Pistorius, Pierre, Puskic, Peter, Reis, Ana, Reisinger, Ryan, Santos, Mercedes, Tarszisz, Esther, Tixier, Paul, Trathan, Philip, Wege, Mia, Wienecke, Barbara
- Authors: Bestley, Sophie , Ropert-Coudert, Yan , Bengtson Nash, Susan , Brooks, Cassandra , Cotté, Cedric , Dewar, Meagan , Friedlaender, Ari , Jackson, Jennifer , Labrousse, Sara , Lowther, Andrew , McMahon, Clive , Phillips, Richard , Pistorius, Pierre , Puskic, Peter , Reis, Ana , Reisinger, Ryan , Santos, Mercedes , Tarszisz, Esther , Tixier, Paul , Trathan, Philip , Wege, Mia , Wienecke, Barbara
- Date: 2020
- Type: Text , Journal article , Review
- Relation: Frontiers in Ecology and Evolution Vol. 8, no. (2020), p. 1-39
- Full Text:
- Reviewed:
- Description: The massive number of seabirds (penguins and procellariiformes) and marine mammals (cetaceans and pinnipeds) – referred to here as top predators – is one of the most iconic components of the Antarctic and Southern Ocean. They play an important role as highly mobile consumers, structuring and connecting pelagic marine food webs and are widely studied relative to other taxa. Many birds and mammals establish dense breeding colonies or use haul-out sites, making them relatively easy to study. Cetaceans, however, spend their lives at sea and thus aspects of their life cycle are more complicated to monitor and study. Nevertheless, they all feed at sea and their reproductive success depends on the food availability in the marine environment, hence they are considered useful indicators of the state of the marine resources. In general, top predators have large body sizes that allow for instrumentation with miniature data-recording or transmitting devices to monitor their activities at sea. Development of scientific techniques to study reproduction and foraging of top predators has led to substantial scientific literature on their population trends, key biological parameters, migratory patterns, foraging and feeding ecology, and linkages with atmospheric or oceanographic dynamics, for a number of species and regions. We briefly summarize the vast literature on Southern Ocean top predators, focusing on the most recent syntheses. We also provide an overview on the key current and emerging pressures faced by these animals as a result of both natural and human causes. We recognize the overarching impact that environmental changes driven by climate change have on the ecology of these species. We also evaluate direct and indirect interactions between marine predators and other factors such as disease, pollution, land disturbance and the increasing pressure from global fisheries in the Southern Ocean. Where possible we consider the data availability for assessing the status and trends for each of these components, their capacity for resilience or recovery, effectiveness of management responses, risk likelihood of key impacts and future outlook. © Copyright © 2020 Bestley, Ropert-Coudert, Bengtson Nash, Brooks, Cotté, Dewar, Friedlaender, Jackson, Labrousse, Lowther, McMahon, Phillips, Pistorius, Puskic, Reis, Reisinger, Santos, Tarszisz, Tixier, Trathan, Wege and Wienecke.
- Authors: Bestley, Sophie , Ropert-Coudert, Yan , Bengtson Nash, Susan , Brooks, Cassandra , Cotté, Cedric , Dewar, Meagan , Friedlaender, Ari , Jackson, Jennifer , Labrousse, Sara , Lowther, Andrew , McMahon, Clive , Phillips, Richard , Pistorius, Pierre , Puskic, Peter , Reis, Ana , Reisinger, Ryan , Santos, Mercedes , Tarszisz, Esther , Tixier, Paul , Trathan, Philip , Wege, Mia , Wienecke, Barbara
- Date: 2020
- Type: Text , Journal article , Review
- Relation: Frontiers in Ecology and Evolution Vol. 8, no. (2020), p. 1-39
- Full Text:
- Reviewed:
- Description: The massive number of seabirds (penguins and procellariiformes) and marine mammals (cetaceans and pinnipeds) – referred to here as top predators – is one of the most iconic components of the Antarctic and Southern Ocean. They play an important role as highly mobile consumers, structuring and connecting pelagic marine food webs and are widely studied relative to other taxa. Many birds and mammals establish dense breeding colonies or use haul-out sites, making them relatively easy to study. Cetaceans, however, spend their lives at sea and thus aspects of their life cycle are more complicated to monitor and study. Nevertheless, they all feed at sea and their reproductive success depends on the food availability in the marine environment, hence they are considered useful indicators of the state of the marine resources. In general, top predators have large body sizes that allow for instrumentation with miniature data-recording or transmitting devices to monitor their activities at sea. Development of scientific techniques to study reproduction and foraging of top predators has led to substantial scientific literature on their population trends, key biological parameters, migratory patterns, foraging and feeding ecology, and linkages with atmospheric or oceanographic dynamics, for a number of species and regions. We briefly summarize the vast literature on Southern Ocean top predators, focusing on the most recent syntheses. We also provide an overview on the key current and emerging pressures faced by these animals as a result of both natural and human causes. We recognize the overarching impact that environmental changes driven by climate change have on the ecology of these species. We also evaluate direct and indirect interactions between marine predators and other factors such as disease, pollution, land disturbance and the increasing pressure from global fisheries in the Southern Ocean. Where possible we consider the data availability for assessing the status and trends for each of these components, their capacity for resilience or recovery, effectiveness of management responses, risk likelihood of key impacts and future outlook. © Copyright © 2020 Bestley, Ropert-Coudert, Bengtson Nash, Brooks, Cotté, Dewar, Friedlaender, Jackson, Labrousse, Lowther, McMahon, Phillips, Pistorius, Puskic, Reis, Reisinger, Santos, Tarszisz, Tixier, Trathan, Wege and Wienecke.
Risk assessment of SARS-CoV-2 in Antarctic wildlife
- Barbosa, Andres, Varsani, Arvind, Morandini, Virginia, Grimaldi, Wray, Vanstreels, Ralph, Diaz, Julia, Boulinier, Thierry, Dewar, Meagan, González-Acuña, Daniel, Gray, Rachael, McMahon, Clive, Miller, Gary, Power, Michelle, Gamble, Amandine, Wille, Michelle
- Authors: Barbosa, Andres , Varsani, Arvind , Morandini, Virginia , Grimaldi, Wray , Vanstreels, Ralph , Diaz, Julia , Boulinier, Thierry , Dewar, Meagan , González-Acuña, Daniel , Gray, Rachael , McMahon, Clive , Miller, Gary , Power, Michelle , Gamble, Amandine , Wille, Michelle
- Date: 2021
- Type: Text , Journal article
- Relation: Science of the Total Environment Vol. 755, no. 2 (2021), p. 1-8
- Full Text:
- Reviewed:
- Description: The coronavirus disease 2019 (COVID-19) pandemic is caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). This pathogen has spread rapidly across the world, causing high numbers of deaths and significant social and economic impacts. SARS-CoV-2 is a novel coronavirus with a suggested zoonotic origin with the potential for cross-species transmission among animals. Antarctica can be considered the only continent free of SARS-CoV-2. Therefore, concerns have been expressed regarding the potential human introduction of this virus to the continent through the activities of research or tourism to minimise the effects on human health, and the potential for virus transmission to Antarctic wildlife. We assess the reverse-zoonotic transmission risk to Antarctic wildlife by considering the available information on host susceptibility, dynamics of the infection in humans, and contact interactions between humans and Antarctic wildlife. The environmental conditions in Antarctica seem to be favourable for the virus stability. Indoor spaces such as those at research stations, research vessels or tourist cruise ships could allow for more transmission among humans and depending on their movements between different locations the virus could be spread across the continent. Among Antarctic wildlife previous in silico analyses suggested that cetaceans are at greater risk of infection whereas seals and birds appear to be at a low infection risk. However, caution needed until further research is carried out and consequently, the precautionary principle should be applied. Field researchers handling animals are identified as the human group posing the highest risk of transmission to animals while tourists and other personnel pose a significant risk only when in close proximity (< 5 m) to Antarctic fauna. We highlight measures to reduce the risk as well as identify of knowledge gaps related to this issue. © 2020 The Authors
- Authors: Barbosa, Andres , Varsani, Arvind , Morandini, Virginia , Grimaldi, Wray , Vanstreels, Ralph , Diaz, Julia , Boulinier, Thierry , Dewar, Meagan , González-Acuña, Daniel , Gray, Rachael , McMahon, Clive , Miller, Gary , Power, Michelle , Gamble, Amandine , Wille, Michelle
- Date: 2021
- Type: Text , Journal article
- Relation: Science of the Total Environment Vol. 755, no. 2 (2021), p. 1-8
- Full Text:
- Reviewed:
- Description: The coronavirus disease 2019 (COVID-19) pandemic is caused by the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). This pathogen has spread rapidly across the world, causing high numbers of deaths and significant social and economic impacts. SARS-CoV-2 is a novel coronavirus with a suggested zoonotic origin with the potential for cross-species transmission among animals. Antarctica can be considered the only continent free of SARS-CoV-2. Therefore, concerns have been expressed regarding the potential human introduction of this virus to the continent through the activities of research or tourism to minimise the effects on human health, and the potential for virus transmission to Antarctic wildlife. We assess the reverse-zoonotic transmission risk to Antarctic wildlife by considering the available information on host susceptibility, dynamics of the infection in humans, and contact interactions between humans and Antarctic wildlife. The environmental conditions in Antarctica seem to be favourable for the virus stability. Indoor spaces such as those at research stations, research vessels or tourist cruise ships could allow for more transmission among humans and depending on their movements between different locations the virus could be spread across the continent. Among Antarctic wildlife previous in silico analyses suggested that cetaceans are at greater risk of infection whereas seals and birds appear to be at a low infection risk. However, caution needed until further research is carried out and consequently, the precautionary principle should be applied. Field researchers handling animals are identified as the human group posing the highest risk of transmission to animals while tourists and other personnel pose a significant risk only when in close proximity (< 5 m) to Antarctic fauna. We highlight measures to reduce the risk as well as identify of knowledge gaps related to this issue. © 2020 The Authors
- «
- ‹
- 1
- ›
- »