Metabolic responses to low temperature in fish muscle

For most fish, body temperature is very close to that of the habitat. The diversity of thermal habitats exploited by fish as well as their capacity to adapt to thermal change makes them excellent organisms in which to examine the evolutionary and phenotypic responses to temperature. An extensive lit...

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Veröffentlicht in:	Biological reviews of the Cambridge Philosophical Society 2004-05, Vol.79 (2), p.409-427
1. Verfasser:	Guderley, Helga
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Sprache:	eng
Schlagworte:	Acclimatization - physiology Adaptation, Physiological Animals antioxidants Body Temperature Regulation - physiology Carassius carassius Cold Temperature Evolutionary biology Fish Fishes - metabolism Fishes - physiology membrane phospholipids Metabolism mitochondria Mitochondria, Muscle - metabolism Morone saxatilis Muscle Fibers, Skeletal Muscle, Skeletal - anatomy & histology Muscle, Skeletal - enzymology Muscle, Skeletal - metabolism Oncorhynchus mykiss Oxygen - metabolism Phenotype proton leak skeletal muscle Temperature effects thermal compensation
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description	For most fish, body temperature is very close to that of the habitat. The diversity of thermal habitats exploited by fish as well as their capacity to adapt to thermal change makes them excellent organisms in which to examine the evolutionary and phenotypic responses to temperature. An extensive literature links cold temperatures with enhanced oxidative capacities in fish tissues, particularly skeletal muscle. Closer examination of inter-species comparisons (i.e. the evolutionary perspective) indicates that the proportion of muscle fibres occupied by mitochondria increases at low temperatures, most clearly in moderately active demersal species. Isolated muscle mitochondria show no compensation of protein-specific rates of substrate oxidation during evolutionary adaptation to cold temperatures. During phenotypic cold acclimation, mitochondrial volume density increases in oxidative muscle of some species (striped bass Morone saxatilis, crucian carp Carassius carassius), but remains stable in others (rainbow trout Oncorhynchus mykiss). A role for the mitochondrial reticulum in distributing oxygen through the complex architecture of skeletal muscle fibres may explain mitochondrial proliferation. In rainbow trout, compensatory increases in the protein-specific rates of mitochondrial substrate oxidation maintain constant capacities except at winter extremes. Changes in mitochondrial properties (membrane phospholipids, enzymatic complement and cristae densities) can enhance the oxidative capacity of muscle in the absence of changes in mitochondrial volume density. Changes in the unsaturation of membrane phospholipids are a direct response to temperature and occur in isolated cells. This fundamental response maintains the dynamic phase behaviour of the membrane and adjusts the rates of membrane processes. However, these adjustments may have deleterious consequences. For fish living at low temperatures, the increased polyunsaturation of mitochondrial membranes should raise rates of mitochondrial respiration which would in turn enhance the formation of reactive oxygen species (ROS), increase proton leak and favour peroxidation of these membranes. Minimisation of mitochondrial oxidative capacities in organisms living at low temperatures would reduce such damage.
doi_str_mv	10.1017/S1464793103006328
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The diversity of thermal habitats exploited by fish as well as their capacity to adapt to thermal change makes them excellent organisms in which to examine the evolutionary and phenotypic responses to temperature. An extensive literature links cold temperatures with enhanced oxidative capacities in fish tissues, particularly skeletal muscle. Closer examination of inter-species comparisons (i.e. the evolutionary perspective) indicates that the proportion of muscle fibres occupied by mitochondria increases at low temperatures, most clearly in moderately active demersal species. Isolated muscle mitochondria show no compensation of protein-specific rates of substrate oxidation during evolutionary adaptation to cold temperatures. During phenotypic cold acclimation, mitochondrial volume density increases in oxidative muscle of some species (striped bass Morone saxatilis, crucian carp Carassius carassius), but remains stable in others (rainbow trout Oncorhynchus mykiss). A role for the mitochondrial reticulum in distributing oxygen through the complex architecture of skeletal muscle fibres may explain mitochondrial proliferation. In rainbow trout, compensatory increases in the protein-specific rates of mitochondrial substrate oxidation maintain constant capacities except at winter extremes. Changes in mitochondrial properties (membrane phospholipids, enzymatic complement and cristae densities) can enhance the oxidative capacity of muscle in the absence of changes in mitochondrial volume density. Changes in the unsaturation of membrane phospholipids are a direct response to temperature and occur in isolated cells. This fundamental response maintains the dynamic phase behaviour of the membrane and adjusts the rates of membrane processes. However, these adjustments may have deleterious consequences. For fish living at low temperatures, the increased polyunsaturation of mitochondrial membranes should raise rates of mitochondrial respiration which would in turn enhance the formation of reactive oxygen species (ROS), increase proton leak and favour peroxidation of these membranes. 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The diversity of thermal habitats exploited by fish as well as their capacity to adapt to thermal change makes them excellent organisms in which to examine the evolutionary and phenotypic responses to temperature. An extensive literature links cold temperatures with enhanced oxidative capacities in fish tissues, particularly skeletal muscle. Closer examination of inter-species comparisons (i.e. the evolutionary perspective) indicates that the proportion of muscle fibres occupied by mitochondria increases at low temperatures, most clearly in moderately active demersal species. Isolated muscle mitochondria show no compensation of protein-specific rates of substrate oxidation during evolutionary adaptation to cold temperatures. During phenotypic cold acclimation, mitochondrial volume density increases in oxidative muscle of some species (striped bass Morone saxatilis, crucian carp Carassius carassius), but remains stable in others (rainbow trout Oncorhynchus mykiss). A role for the mitochondrial reticulum in distributing oxygen through the complex architecture of skeletal muscle fibres may explain mitochondrial proliferation. In rainbow trout, compensatory increases in the protein-specific rates of mitochondrial substrate oxidation maintain constant capacities except at winter extremes. Changes in mitochondrial properties (membrane phospholipids, enzymatic complement and cristae densities) can enhance the oxidative capacity of muscle in the absence of changes in mitochondrial volume density. Changes in the unsaturation of membrane phospholipids are a direct response to temperature and occur in isolated cells. This fundamental response maintains the dynamic phase behaviour of the membrane and adjusts the rates of membrane processes. However, these adjustments may have deleterious consequences. For fish living at low temperatures, the increased polyunsaturation of mitochondrial membranes should raise rates of mitochondrial respiration which would in turn enhance the formation of reactive oxygen species (ROS), increase proton leak and favour peroxidation of these membranes. Minimisation of mitochondrial oxidative capacities in organisms living at low temperatures would reduce such damage.</description><subject>Acclimatization - physiology</subject><subject>Adaptation, Physiological</subject><subject>Animals</subject><subject>antioxidants</subject><subject>Body Temperature Regulation - physiology</subject><subject>Carassius carassius</subject><subject>Cold Temperature</subject><subject>Evolutionary biology</subject><subject>Fish</subject><subject>Fishes - metabolism</subject><subject>Fishes - physiology</subject><subject>membrane phospholipids</subject><subject>Metabolism</subject><subject>mitochondria</subject><subject>Mitochondria, Muscle - metabolism</subject><subject>Morone saxatilis</subject><subject>Muscle Fibers, Skeletal</subject><subject>Muscle, Skeletal - anatomy & histology</subject><subject>Muscle, Skeletal - enzymology</subject><subject>Muscle, Skeletal - metabolism</subject><subject>Oncorhynchus mykiss</subject><subject>Oxygen - metabolism</subject><subject>Phenotype</subject><subject>proton leak</subject><subject>skeletal muscle</subject><subject>Temperature effects</subject><subject>thermal compensation</subject><issn>1464-7931</issn><issn>1469-185X</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2004</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqFkElPwzAQhS0EYv8BXFDEgVvAjrf4CGUXBYn9ZtnpGAJJU-xEpf8eQyuQQIiTrZnvPc17CG0QvEMwkbvXhAkmFSWYYixols-h5ThSKcn5w_znn6Uf-yW0EsIzxnEg6CJaIpwoklG8jHgfWmObqiwSD2HUDAOEpG2SqhknLdQj8KbtPCTlMHFleErqLhQVrKEFZ6oA67N3Fd0eHd70TtLzy-PT3t55WnAlVSqEcE5gBmAZsUAco9Zxw3KcW6mssRibyFHmcgaKOzCFlMploDB1A2zpKtqe-o5889pBaHVdhgKqygyh6YKWWYzEJP0XJDLLGWckgls_wOem88MYQmc0lsIElREiU6jwTQgenB75sjZ-ognWH83rX81HzebMuLM1DL4Vs6ojwKfAuKxg8r-j3r-6Y1hFXTrVlaGFty-d8S9aSCq5vr841id9eXB_cNbXPPJ0dryprS8Hj_Ad8e_z3wEFHKpG</recordid><startdate>200405</startdate><enddate>200405</enddate><creator>Guderley, Helga</creator><general>Cambridge University Press</general><general>Blackwell Publishing Ltd</general><scope>BSCLL</scope><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QG</scope><scope>7SN</scope><scope>7SS</scope><scope>C1K</scope><scope>F1W</scope><scope>H95</scope><scope>L.G</scope><scope>7X8</scope></search><sort><creationdate>200405</creationdate><title>Metabolic responses to low temperature in fish muscle</title><author>Guderley, Helga</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c5979-666ff604eeb41be1f43bf5a4808b79bab00a97934f84e95feac779f2e903fd0b3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2004</creationdate><topic>Acclimatization - physiology</topic><topic>Adaptation, Physiological</topic><topic>Animals</topic><topic>antioxidants</topic><topic>Body Temperature Regulation - physiology</topic><topic>Carassius carassius</topic><topic>Cold Temperature</topic><topic>Evolutionary biology</topic><topic>Fish</topic><topic>Fishes - metabolism</topic><topic>Fishes - physiology</topic><topic>membrane phospholipids</topic><topic>Metabolism</topic><topic>mitochondria</topic><topic>Mitochondria, Muscle - metabolism</topic><topic>Morone saxatilis</topic><topic>Muscle Fibers, Skeletal</topic><topic>Muscle, Skeletal - anatomy & histology</topic><topic>Muscle, Skeletal - enzymology</topic><topic>Muscle, Skeletal - metabolism</topic><topic>Oncorhynchus mykiss</topic><topic>Oxygen - metabolism</topic><topic>Phenotype</topic><topic>proton leak</topic><topic>skeletal muscle</topic><topic>Temperature effects</topic><topic>thermal compensation</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Guderley, Helga</creatorcontrib><collection>Istex</collection><collection>Medline</collection><collection>MEDLINE</collection><collection>MEDLINE (Ovid)</collection><collection>MEDLINE</collection><collection>MEDLINE</collection><collection>PubMed</collection><collection>CrossRef</collection><collection>Animal Behavior Abstracts</collection><collection>Ecology Abstracts</collection><collection>Entomology Abstracts (Full archive)</collection><collection>Environmental Sciences and Pollution Management</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 1: Biological Sciences & Living Resources</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) Professional</collection><collection>MEDLINE - 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The diversity of thermal habitats exploited by fish as well as their capacity to adapt to thermal change makes them excellent organisms in which to examine the evolutionary and phenotypic responses to temperature. An extensive literature links cold temperatures with enhanced oxidative capacities in fish tissues, particularly skeletal muscle. Closer examination of inter-species comparisons (i.e. the evolutionary perspective) indicates that the proportion of muscle fibres occupied by mitochondria increases at low temperatures, most clearly in moderately active demersal species. Isolated muscle mitochondria show no compensation of protein-specific rates of substrate oxidation during evolutionary adaptation to cold temperatures. During phenotypic cold acclimation, mitochondrial volume density increases in oxidative muscle of some species (striped bass Morone saxatilis, crucian carp Carassius carassius), but remains stable in others (rainbow trout Oncorhynchus mykiss). A role for the mitochondrial reticulum in distributing oxygen through the complex architecture of skeletal muscle fibres may explain mitochondrial proliferation. In rainbow trout, compensatory increases in the protein-specific rates of mitochondrial substrate oxidation maintain constant capacities except at winter extremes. Changes in mitochondrial properties (membrane phospholipids, enzymatic complement and cristae densities) can enhance the oxidative capacity of muscle in the absence of changes in mitochondrial volume density. Changes in the unsaturation of membrane phospholipids are a direct response to temperature and occur in isolated cells. This fundamental response maintains the dynamic phase behaviour of the membrane and adjusts the rates of membrane processes. However, these adjustments may have deleterious consequences. For fish living at low temperatures, the increased polyunsaturation of mitochondrial membranes should raise rates of mitochondrial respiration which would in turn enhance the formation of reactive oxygen species (ROS), increase proton leak and favour peroxidation of these membranes. Minimisation of mitochondrial oxidative capacities in organisms living at low temperatures would reduce such damage.</abstract><cop>Oxford, UK</cop><pub>Cambridge University Press</pub><pmid>15191230</pmid><doi>10.1017/S1464793103006328</doi><tpages>19</tpages></addata></record>
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subjects	Acclimatization - physiology Adaptation, Physiological Animals antioxidants Body Temperature Regulation - physiology Carassius carassius Cold Temperature Evolutionary biology Fish Fishes - metabolism Fishes - physiology membrane phospholipids Metabolism mitochondria Mitochondria, Muscle - metabolism Morone saxatilis Muscle Fibers, Skeletal Muscle, Skeletal - anatomy & histology Muscle, Skeletal - enzymology Muscle, Skeletal - metabolism Oncorhynchus mykiss Oxygen - metabolism Phenotype proton leak skeletal muscle Temperature effects thermal compensation
title	Metabolic responses to low temperature in fish muscle
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