Pomphorhynchus laevis manipulates Gammarus pulex behaviour despite salt pollution
Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free‐living species and their associated parasites. Acanthocephalan parasites are able to alter their intermediate host's phenotype to reach final hosts, but this process...
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| Published in: | Freshwater biology Vol. 65; no. 10; pp. 1718 - 1725 |
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| Main Authors: | , , , |
| Format: | Journal Article |
| Language: | English |
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| Abstract | Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free‐living species and their associated parasites. Acanthocephalan parasites are able to alter their intermediate host's phenotype to reach final hosts, but this process could be affected by salt pollution, thereby compromising survival of the parasite.
We experimentally assessed the impact of salt on the extended phenotype of the parasite Pomphorhynchus laevis in their intermediate host, the amphipod Gammarus pulex, based on three amphipod behaviours: distance covered in flowing water, phototaxis, and geotaxis. We hypothesised that: (1) salt pollution negatively affected the behaviour of uninfected gammarids, and (2) that P. laevis could maintain their capacity to manipulate their host despite this pollution.
All three amphipod behaviours were altered by P. laevis: infected G. pulex covered a greater distance, were less photophobic and were more attracted to the water surface than uninfected amphipods, in control or salt‐polluted water. However, salinity reduced distance covered in flowing water and increased attraction to the water surface of uninfected and infected G. pulex. For the phototaxis behaviour, P. laevis enhanced this capacity of manipulation in salt‐polluted water compared to control water.
Pomphorhynchus laevis can still manipulate the behaviour of their intermediate host in salt‐polluted water. Acanthocephalan parasites have not been known to be able to manipulate their intermediate host when under pollution stress. Trophic interactions, but not the chances of parasite transmission to their definitive host, appear to be affected by salt pollution.
Our study indicates that behavioural modifications induced by complex lifecycle parasites should be more considered in the context of growing concentrations of chemical pollutants in some freshwater ecosystems. Interspecific interactions, and particularly host–parasite relationships, are a key component of ecosystem stability and their alteration could result in major changes in energy flow. |
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| AbstractList | Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free‐living species and their associated parasites. Acanthocephalan parasites are able to alter their intermediate host's phenotype to reach final hosts, but this process could be affected by salt pollution, thereby compromising survival of the parasite.We experimentally assessed the impact of salt on the extended phenotype of the parasite Pomphorhynchus laevis in their intermediate host, the amphipod Gammarus pulex, based on three amphipod behaviours: distance covered in flowing water, phototaxis, and geotaxis. We hypothesised that: (1) salt pollution negatively affected the behaviour of uninfected gammarids, and (2) that P. laevis could maintain their capacity to manipulate their host despite this pollution.All three amphipod behaviours were altered by P. laevis: infected G. pulex covered a greater distance, were less photophobic and were more attracted to the water surface than uninfected amphipods, in control or salt‐polluted water. However, salinity reduced distance covered in flowing water and increased attraction to the water surface of uninfected and infected G. pulex. For the phototaxis behaviour, P. laevis enhanced this capacity of manipulation in salt‐polluted water compared to control water.Pomphorhynchus laevis can still manipulate the behaviour of their intermediate host in salt‐polluted water. Acanthocephalan parasites have not been known to be able to manipulate their intermediate host when under pollution stress. Trophic interactions, but not the chances of parasite transmission to their definitive host, appear to be affected by salt pollution.Our study indicates that behavioural modifications induced by complex lifecycle parasites should be more considered in the context of growing concentrations of chemical pollutants in some freshwater ecosystems. Interspecific interactions, and particularly host–parasite relationships, are a key component of ecosystem stability and their alteration could result in major changes in energy flow. Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free‐living species and their associated parasites. Acanthocephalan parasites are able to alter their intermediate host's phenotype to reach final hosts, but this process could be affected by salt pollution, thereby compromising survival of the parasite. We experimentally assessed the impact of salt on the extended phenotype of the parasite Pomphorhynchus laevis in their intermediate host, the amphipod Gammarus pulex, based on three amphipod behaviours: distance covered in flowing water, phototaxis, and geotaxis. We hypothesised that: (1) salt pollution negatively affected the behaviour of uninfected gammarids, and (2) that P. laevis could maintain their capacity to manipulate their host despite this pollution. All three amphipod behaviours were altered by P. laevis: infected G. pulex covered a greater distance, were less photophobic and were more attracted to the water surface than uninfected amphipods, in control or salt‐polluted water. However, salinity reduced distance covered in flowing water and increased attraction to the water surface of uninfected and infected G. pulex. For the phototaxis behaviour, P. laevis enhanced this capacity of manipulation in salt‐polluted water compared to control water. Pomphorhynchus laevis can still manipulate the behaviour of their intermediate host in salt‐polluted water. Acanthocephalan parasites have not been known to be able to manipulate their intermediate host when under pollution stress. Trophic interactions, but not the chances of parasite transmission to their definitive host, appear to be affected by salt pollution. Our study indicates that behavioural modifications induced by complex lifecycle parasites should be more considered in the context of growing concentrations of chemical pollutants in some freshwater ecosystems. Interspecific interactions, and particularly host–parasite relationships, are a key component of ecosystem stability and their alteration could result in major changes in energy flow. Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free-living species and their associated parasites. Acanthocephalan parasites are able to alter their intermediate host's phenotype to reach final hosts, but this process could be affected by salt pollution, thereby compromising survival of the parasite.2. We experimentally assessed the impact of salt on the extended phenotype of the parasite Pomphorhynchus laevis in their intermediate host, the amphipod Gammarus pulex, based on three amphipod behaviours: distance covered in flowing water, phototaxis, and geotaxis. We hypothesised that: (1) salt pollution negatively affected the behaviour of uninfected gammarids, and (2) that P. laevis could maintain their capacity to manipulate their host despite this pollution.3. All three amphipod behaviours were altered by P. laevis: infected G. pulex covered a greater distance, were less photophobic and were more attracted to the water surface than uninfected amphipods, in control or salt-polluted water. However, salinity reduced distance covered in flowing water and increased attraction to the water surface of uninfected and infected G. pulex. For the phototaxis behaviour, P. laevis enhanced this capacity of manipulation in salt-polluted water compared to control water.4. Pomphorhynchus laevis can still manipulate the behaviour of their intermediate host in salt-polluted water. Acanthocephalan parasites have not been known to be able to manipulate their intermediate host when under pollution stress. Trophic interactions, but not the chances of parasite transmission to their definitive host, appear to be affected by salt pollution.5. Our study indicates that behavioural modifications induced by complex lifecycle parasites should be more considered in the context of growing concentrations of chemical pollutants in some freshwater ecosystems. Interspecific interactions, and particularly host–parasite relationships, are a key component of ecosystem stability and their alteration could result in major changes in energy flow. Abstract Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free‐living species and their associated parasites. Acanthocephalan parasites are able to alter their intermediate host's phenotype to reach final hosts, but this process could be affected by salt pollution, thereby compromising survival of the parasite. We experimentally assessed the impact of salt on the extended phenotype of the parasite Pomphorhynchus laevis in their intermediate host, the amphipod Gammarus pulex , based on three amphipod behaviours: distance covered in flowing water, phototaxis, and geotaxis. We hypothesised that: (1) salt pollution negatively affected the behaviour of uninfected gammarids, and (2) that P. laevis could maintain their capacity to manipulate their host despite this pollution. All three amphipod behaviours were altered by P. laevis : infected G. pulex covered a greater distance, were less photophobic and were more attracted to the water surface than uninfected amphipods, in control or salt‐polluted water. However, salinity reduced distance covered in flowing water and increased attraction to the water surface of uninfected and infected G. pulex . For the phototaxis behaviour, P. laevis enhanced this capacity of manipulation in salt‐polluted water compared to control water. Pomphorhynchus laevis can still manipulate the behaviour of their intermediate host in salt‐polluted water. Acanthocephalan parasites have not been known to be able to manipulate their intermediate host when under pollution stress. Trophic interactions, but not the chances of parasite transmission to their definitive host, appear to be affected by salt pollution. Our study indicates that behavioural modifications induced by complex lifecycle parasites should be more considered in the context of growing concentrations of chemical pollutants in some freshwater ecosystems. Interspecific interactions, and particularly host–parasite relationships, are a key component of ecosystem stability and their alteration could result in major changes in energy flow. |
| Author | Kaldonski, Nicolas Franquet, Evelyne Logez, Maxime Fanton, Hadrien |
| Author_xml | – sequence: 1 givenname: Hadrien orcidid: 0000-0003-4437-797X surname: Fanton fullname: Fanton, Hadrien email: hadrien.fanton@imbe.fr organization: CNRS, IRD, IMBE – sequence: 2 givenname: Evelyne orcidid: 0000-0002-7779-772X surname: Franquet fullname: Franquet, Evelyne organization: CNRS, IRD, IMBE – sequence: 3 givenname: Maxime orcidid: 0000-0001-9843-0495 surname: Logez fullname: Logez, Maxime organization: RECOVER – sequence: 4 givenname: Nicolas orcidid: 0000-0002-2788-7241 surname: Kaldonski fullname: Kaldonski, Nicolas organization: CNRS, IRD, IMBE |
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| CitedBy_id | crossref_primary_10_1016_j_jtemb_2022_127037 crossref_primary_10_1016_j_scitotenv_2022_156091 crossref_primary_10_1016_j_envpol_2023_121791 |
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| Keywords | phenotypic alterations host–parasite interactions salinisation acanthocephala amphipoda |
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| Snippet | Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free‐living species and their... Abstract Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free‐living species and... Salt pollution of freshwater ecosystems represents a major threat to biodiversity, and particularly to interactions between free-living species and their... |
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| SubjectTerms | acanthocephala amphipoda Aquatic crustaceans Aquatic ecosystems Behavior Biodiversity Biodiversity and Ecology Chemical pollutants Chemical pollution Disease transmission Distance Ecology, environment Ecosystem stability Ecosystems Energy flow Environmental changes Environmental Sciences Flow stability Freshwater Freshwater ecosystems Freshwater pollution Gammarus pulex Geotaxis host–parasite interactions Inland water environment Interspecific relationships Life cycle analysis Life Sciences Parasites Phenotypes phenotypic alterations Phototaxis Pollutants Pollution Pollution control Pomphorhynchus laevis salinisation Salts Survival Symbiosis Trophic relationships Water pollution |
| Title | Pomphorhynchus laevis manipulates Gammarus pulex behaviour despite salt pollution |
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