Impacts of Low Temperature on the Teleost Immune System
As poikilothermic vertebrates, fish can experience changes in water temperature, and hence body temperature, as a result of seasonal changes, migration, or efflux of large quantities of effluent into a body of water. Temperature shifts outside of the optimal temperature range for an individual fish...
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| Published in | Biology (Basel, Switzerland) Vol. 6; no. 4; p. 39 |
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| Main Authors | , , |
| Format | Journal Article |
| Language | English |
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22.11.2017
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| Abstract | As poikilothermic vertebrates, fish can experience changes in water temperature, and hence body temperature, as a result of seasonal changes, migration, or efflux of large quantities of effluent into a body of water. Temperature shifts outside of the optimal temperature range for an individual fish species can have negative impacts on the physiology of the animal, including the immune system. As a result, acute or chronic exposure to suboptimal temperatures can impair an organisms’ ability to defend against pathogens and thus compromise the overall health of the animal. This review focuses on the advances made towards understanding the impacts of suboptimal temperature on the soluble and cellular mediators of the innate and adaptive immune systems of fishes. Although cold stress can result in varying effects in different fish species, acute and chronic suboptimal temperature exposure generally yield suppressive effects, particularly on adaptive immunity. Knowledge of the effects of environmental temperature on fish species is critical for both the optimal management of wild species and the best management practices for aquaculture species. |
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| AbstractList | As poikilothermic vertebrates, fish can experience changes in water temperature, and hence body temperature, as a result of seasonal changes, migration, or efflux of large quantities of effluent into a body of water. Temperature shifts outside of the optimal temperature range for an individual fish species can have negative impacts on the physiology of the animal, including the immune system. As a result, acute or chronic exposure to suboptimal temperatures can impair an organisms’ ability to defend against pathogens and thus compromise the overall health of the animal. This review focuses on the advances made towards understanding the impacts of suboptimal temperature on the soluble and cellular mediators of the innate and adaptive immune systems of fishes. Although cold stress can result in varying effects in different fish species, acute and chronic suboptimal temperature exposure generally yield suppressive effects, particularly on adaptive immunity. Knowledge of the effects of environmental temperature on fish species is critical for both the optimal management of wild species and the best management practices for aquaculture species. As poikilothermic vertebrates, fish can experience changes in water temperature, and hence body temperature, as a result of seasonal changes, migration, or efflux of large quantities of effluent into a body of water. Temperature shifts outside of the optimal temperature range for an individual fish species can have negative impacts on the physiology of the animal, including the immune system. As a result, acute or chronic exposure to suboptimal temperatures can impair an organisms' ability to defend against pathogens and thus compromise the overall health of the animal. This review focuses on the advances made towards understanding the impacts of suboptimal temperature on the soluble and cellular mediators of the innate and adaptive immune systems of fishes. Although cold stress can result in varying effects in different fish species, acute and chronic suboptimal temperature exposure generally yield suppressive effects, particularly on adaptive immunity. Knowledge of the effects of environmental temperature on fish species is critical for both the optimal management of wild species and the best management practices for aquaculture species.As poikilothermic vertebrates, fish can experience changes in water temperature, and hence body temperature, as a result of seasonal changes, migration, or efflux of large quantities of effluent into a body of water. Temperature shifts outside of the optimal temperature range for an individual fish species can have negative impacts on the physiology of the animal, including the immune system. As a result, acute or chronic exposure to suboptimal temperatures can impair an organisms' ability to defend against pathogens and thus compromise the overall health of the animal. This review focuses on the advances made towards understanding the impacts of suboptimal temperature on the soluble and cellular mediators of the innate and adaptive immune systems of fishes. Although cold stress can result in varying effects in different fish species, acute and chronic suboptimal temperature exposure generally yield suppressive effects, particularly on adaptive immunity. Knowledge of the effects of environmental temperature on fish species is critical for both the optimal management of wild species and the best management practices for aquaculture species. |
| Author | Katzenback, Barbara Dixon, Brian Abram, Quinn |
| AuthorAffiliation | Department of Biology, University of Waterloo, 200 University Ave West, Waterloo, ON N2L 3G1, Canada; qhabram@uwaterloo.ca (Q.H.A.); bdixon@uwaterloo.ca (B.D.) |
| AuthorAffiliation_xml | – name: Department of Biology, University of Waterloo, 200 University Ave West, Waterloo, ON N2L 3G1, Canada; qhabram@uwaterloo.ca (Q.H.A.); bdixon@uwaterloo.ca (B.D.) |
| Author_xml | – sequence: 1 givenname: Quinn surname: Abram fullname: Abram, Quinn – sequence: 2 givenname: Brian surname: Dixon fullname: Dixon, Brian – sequence: 3 givenname: Barbara surname: Katzenback fullname: Katzenback, Barbara |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/29165340$$D View this record in MEDLINE/PubMed |
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| Keywords | major histocompatibility class I teleosts macrophages antigen presentation innate immunity temperature antibodies cytokines adaptive immunity lymphocyte proliferation |
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| Snippet | As poikilothermic vertebrates, fish can experience changes in water temperature, and hence body temperature, as a result of seasonal changes, migration, or... |
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| StartPage | 39 |
| SubjectTerms | Adaptive immunity ambient temperature antibodies antigen presentation Aquaculture best management practices Body temperature Chronic exposure cold stress cytokines Fish Immune system innate immunity lymphocyte proliferation macrophages major histocompatibility class I pathogens physiology Review seasonal variation Seasonal variations Species surface water teleosts Temperature Temperature effects Water temperature |
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| Title | Impacts of Low Temperature on the Teleost Immune System |
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