Aquaculture, ISSN 0044-8486, 05/2014, Volume 428-429, pp. 174 - 183
Teleosts and other aquatic ectotherms have the ability to withstand prolonged periods of low water temperatures (cold-acclimation) and fasting, and can often...
Myostatin | Compensatory growth | Catch-up growth | Hybrid striped bass | Insulin-like growth factor | Growth hormone receptor | BREAM SPARUS-AURATA | SEA BASS | SKELETAL-MUSCLE | FISHERIES | IGF-BINDING PROTEINS | MARINE & FRESHWATER BIOLOGY | JUVENILE ATLANTIC SALMON | DICENTRARCHUS-LABRAX | COHO SALMON | TROUT ONCORHYNCHUS-MYKISS | HORMONE-RECEPTOR | Somatotropin | RNA | Statistics | Fishes
Myostatin | Compensatory growth | Catch-up growth | Hybrid striped bass | Insulin-like growth factor | Growth hormone receptor | BREAM SPARUS-AURATA | SEA BASS | SKELETAL-MUSCLE | FISHERIES | IGF-BINDING PROTEINS | MARINE & FRESHWATER BIOLOGY | JUVENILE ATLANTIC SALMON | DICENTRARCHUS-LABRAX | COHO SALMON | TROUT ONCORHYNCHUS-MYKISS | HORMONE-RECEPTOR | Somatotropin | RNA | Statistics | Fishes
Journal Article
Biological Reviews, ISSN 1464-7931, 02/2011, Volume 86, Issue 1, pp. 97 - 116
According to life‐history theory, growth rates are subject to strong directional selection due to reproductive and survival advantages associated with large...
trade‐offs | condition | time constraints | compensatory growth | physiology | predation | life‐history evolution | Condition | Compensatory growth | Trade-offs | Physiology | Predation | Life-history evolution | Time constraints | LIFE-HISTORY TRAITS | CONFLICTING SELECTION PRESSURES | trade-offs | YELLOW DUNG FLIES | BEETLE HARMONIA-AXYRIDIS | ADAPTIVE PHENOTYPIC PLASTICITY | RISK TRADE-OFF | life-history evolution | JUVENILE ATLANTIC SALMON | BIOLOGY | CATCH-UP GROWTH | TROUT ONCORHYNCHUS-MYKISS | ENERGY ACQUISITION RATES | Biological Evolution | Eating | Food Chain | Animals | Energy Metabolism | Growth | Models, Biological | Environment | Life Cycle Stages | Physiological aspects | Environmental aspects | Evolution | Predation (Biology) | Research
trade‐offs | condition | time constraints | compensatory growth | physiology | predation | life‐history evolution | Condition | Compensatory growth | Trade-offs | Physiology | Predation | Life-history evolution | Time constraints | LIFE-HISTORY TRAITS | CONFLICTING SELECTION PRESSURES | trade-offs | YELLOW DUNG FLIES | BEETLE HARMONIA-AXYRIDIS | ADAPTIVE PHENOTYPIC PLASTICITY | RISK TRADE-OFF | life-history evolution | JUVENILE ATLANTIC SALMON | BIOLOGY | CATCH-UP GROWTH | TROUT ONCORHYNCHUS-MYKISS | ENERGY ACQUISITION RATES | Biological Evolution | Eating | Food Chain | Animals | Energy Metabolism | Growth | Models, Biological | Environment | Life Cycle Stages | Physiological aspects | Environmental aspects | Evolution | Predation (Biology) | Research
Journal Article
Aquaculture, ISSN 0044-8486, 05/2019, Volume 507, pp. 349 - 360
Farmed gilthead sea bream ( ) is able to grow efficiently with new feed formulations based on plant ingredients. Here, two experimental diets with standard and...
Diet flexibility | Genetic selection | Plant-based diets | Intestinal plasticity | Growth performance | Gilthead sea bream | RAINBOW-TROUT | LOW FISH-MEAL | COMPENSATORY GROWTH | BY-ENVIRONMENT INTERACTION | FISHERIES | FLESH QUALITY | MARINE & FRESHWATER BIOLOGY | GENETIC CORRELATIONS | SALMON SALMO-SALAR | TROUT ONCORHYNCHUS-MYKISS | ATLANTIC SALMON | Family | Growth | Statistics | Analysis | Genomics | Food additives industry
Diet flexibility | Genetic selection | Plant-based diets | Intestinal plasticity | Growth performance | Gilthead sea bream | RAINBOW-TROUT | LOW FISH-MEAL | COMPENSATORY GROWTH | BY-ENVIRONMENT INTERACTION | FISHERIES | FLESH QUALITY | MARINE & FRESHWATER BIOLOGY | GENETIC CORRELATIONS | SALMON SALMO-SALAR | TROUT ONCORHYNCHUS-MYKISS | ATLANTIC SALMON | Family | Growth | Statistics | Analysis | Genomics | Food additives industry
Journal Article
General and Comparative Endocrinology, ISSN 0016-6480, 2006, Volume 150, Issue 3, pp. 462 - 472
Abstract To examine the various mechanisms involved in compensatory growth in Oncorhynchus mykiss , an experimental protocol involving 1, 2 or 4 weeks of...
Endocrinology & Metabolism | Myostatin | Compensatory growth | Growth factors | Myogenic regulator factors | FGFs | IGF-I | RAINBOW-TROUT | growth factors | MESSENGER-RNA EXPRESSION | MYOSTATIN GENE | compensatory growth | myogenic regulator factors | NUTRITIONAL REGULATION | FACTOR-I | myostatin | CYPRINUS-CARPIO | SKELETAL-MUSCLE | ENDOCRINOLOGY & METABOLISM | GENE-EXPRESSION | COHO SALMON | Oncorhynchus mykiss - metabolism | Liver - metabolism | RNA, Messenger - analysis | Muscle, Skeletal - metabolism | Myogenin - genetics | Oncorhynchus mykiss - growth & development | Insulin - metabolism | Animals | Transforming Growth Factor beta - genetics | Analysis of Variance | Receptors, Somatomedin - metabolism | Somatomedins - genetics | Statistics, Nonparametric | Fasting - metabolism | Blood Glucose - metabolism | Transforming Growth Factor beta - metabolism | Myogenin - metabolism | Somatomedins - metabolism
Endocrinology & Metabolism | Myostatin | Compensatory growth | Growth factors | Myogenic regulator factors | FGFs | IGF-I | RAINBOW-TROUT | growth factors | MESSENGER-RNA EXPRESSION | MYOSTATIN GENE | compensatory growth | myogenic regulator factors | NUTRITIONAL REGULATION | FACTOR-I | myostatin | CYPRINUS-CARPIO | SKELETAL-MUSCLE | ENDOCRINOLOGY & METABOLISM | GENE-EXPRESSION | COHO SALMON | Oncorhynchus mykiss - metabolism | Liver - metabolism | RNA, Messenger - analysis | Muscle, Skeletal - metabolism | Myogenin - genetics | Oncorhynchus mykiss - growth & development | Insulin - metabolism | Animals | Transforming Growth Factor beta - genetics | Analysis of Variance | Receptors, Somatomedin - metabolism | Somatomedins - genetics | Statistics, Nonparametric | Fasting - metabolism | Blood Glucose - metabolism | Transforming Growth Factor beta - metabolism | Myogenin - metabolism | Somatomedins - metabolism
Journal Article
Proceedings. Biological sciences / The Royal Society, ISSN 0962-8452, 02/2013, Volume 280, Issue 1752, p. 20122370
The hypothesized negative relationship between growth rate and lifespan has proved very difficult to test robustly because of potentially confounding...
Phenotypic plasticity | Compensatory growth | Longevity | Trade-off | Resource allocation | Investment | OXIDATIVE STRESS | compensatory growth | DNA-DAMAGE | TRAJECTORIES | trade-off | SHORT-LIVED FISH | investment | phenotypic plasticity | DIETARY RESTRICTION | CELLULAR SENESCENCE | FEMALE | EVOLUTIONARY BIOLOGY | resource allocation | BIOLOGY | longevity | ECOLOGY | SEX-DIFFERENCES | REPRODUCTION | Temperature | Male | Scotland | Photoperiod | Reproduction | Animals | Genetic Fitness | Smegmamorpha - growth & development | Environment | Female | Seasons | Smegmamorpha - physiology | investment, longevity | 1001
Phenotypic plasticity | Compensatory growth | Longevity | Trade-off | Resource allocation | Investment | OXIDATIVE STRESS | compensatory growth | DNA-DAMAGE | TRAJECTORIES | trade-off | SHORT-LIVED FISH | investment | phenotypic plasticity | DIETARY RESTRICTION | CELLULAR SENESCENCE | FEMALE | EVOLUTIONARY BIOLOGY | resource allocation | BIOLOGY | longevity | ECOLOGY | SEX-DIFFERENCES | REPRODUCTION | Temperature | Male | Scotland | Photoperiod | Reproduction | Animals | Genetic Fitness | Smegmamorpha - growth & development | Environment | Female | Seasons | Smegmamorpha - physiology | investment, longevity | 1001
Journal Article
2002, 2nd ed., ISBN 0851994849, xii, 347
Book
Ecology Letters, ISSN 1461-023X, 05/2007, Volume 10, Issue 5, pp. 355 - 363
Consistent individual differences in boldness, reactivity, aggressiveness, and other ‘personality traits’ in animals are stable within individuals but vary...
consistent individual differences | coping styles | personality | costs of growth | temperament | Behavioral trait syndromes | foraging under predation risk | boldness | growth‐mortality tradeoffs | Growth-mortality tradeoffs | Costs of growth | Personality | Consistent individual differences | Coping styles | Foraging under predation risk | Boldness | Temperament | AGGRESSIVE-BEHAVIOR | PHENOTYPIC PLASTICITY | COMPENSATORY GROWTH | growth-mortality tradeoffs | INDIVIDUAL VARIATION | PREDATOR INSPECTION BEHAVIOR | STICKLEBACKS GASTEROSTEUS-ACULEATUS | behavioral trait syndromes | NATURAL-SELECTION | ECOLOGY | PUMPKINSEED SUNFISH | MUTATION-SELECTION BALANCE | STANDARD METABOLIC-RATE | Behavior, Animal | Animals | Growth | Mortality | Animal behavior
consistent individual differences | coping styles | personality | costs of growth | temperament | Behavioral trait syndromes | foraging under predation risk | boldness | growth‐mortality tradeoffs | Growth-mortality tradeoffs | Costs of growth | Personality | Consistent individual differences | Coping styles | Foraging under predation risk | Boldness | Temperament | AGGRESSIVE-BEHAVIOR | PHENOTYPIC PLASTICITY | COMPENSATORY GROWTH | growth-mortality tradeoffs | INDIVIDUAL VARIATION | PREDATOR INSPECTION BEHAVIOR | STICKLEBACKS GASTEROSTEUS-ACULEATUS | behavioral trait syndromes | NATURAL-SELECTION | ECOLOGY | PUMPKINSEED SUNFISH | MUTATION-SELECTION BALANCE | STANDARD METABOLIC-RATE | Behavior, Animal | Animals | Growth | Mortality | Animal behavior
Journal Article
Journal of Fish Biology, ISSN 0022-1112, 05/2018, Volume 92, Issue 5, pp. 1333 - 1341
The effect of feed cycling (consisting of periods of starvation followed by periods of refeeding to satiation) on compensatory growth was evaluated in growth...
aquaculture | Oncorhynchus kisutch | compensatory growth | catch‐up growth | GH‐transgenic Coho salmon | GH-transgenic Coho salmon | catch-up growth | FISHERIES | PROTEIN | MARINE & FRESHWATER BIOLOGY | FISHES | BODY-COMPOSITION | ENERGY-UTILIZATION | Somatotropin | Cabinet officers | Animal genetic engineering | Fishes | Starvation | Life history | Growth rate | Salmon | Hormones | Transgenic fish | Body mass | Capacity | Compensation | Satiety | Fish | Freshwater fish | Growth hormone | Feeds | Feed composition | Feed
aquaculture | Oncorhynchus kisutch | compensatory growth | catch‐up growth | GH‐transgenic Coho salmon | GH-transgenic Coho salmon | catch-up growth | FISHERIES | PROTEIN | MARINE & FRESHWATER BIOLOGY | FISHES | BODY-COMPOSITION | ENERGY-UTILIZATION | Somatotropin | Cabinet officers | Animal genetic engineering | Fishes | Starvation | Life history | Growth rate | Salmon | Hormones | Transgenic fish | Body mass | Capacity | Compensation | Satiety | Fish | Freshwater fish | Growth hormone | Feeds | Feed composition | Feed
Journal Article
Journal of Animal Ecology, ISSN 0021-8790, 11/2012, Volume 81, Issue 6, pp. 1233 - 1243
1. As size is tightly associated with fitness, compensatory strategies for growth loss can be vital for restoring individual fitness. However, immediate and...
Animal feeding behavior | Life histories | Larvae | Predators | Ecological genetics | Animal ecology | Tadpoles | Lipids | Predation | Metamorphosis | Low temperature | life history strategies | metamorphosis | time‐stressed populations | Rana temporaria | catch‐up growth | Catch-up growth | Life history strategies | Time-stressed populations | SIZE | COMPENSATORY GROWTH | catch-up growth | RANA-TEMPORARIA | RATES | ZOOLOGY | TEMPERATURE | NATURAL-SELECTION | LIFE-HISTORY | ECOLOGY | PREDATION RISK | time-stressed populations | PLASTICITY | Cold Temperature | Rana temporaria - growth & development | Body Size | Stress, Physiological | Lipid Metabolism | Motor Activity | Food Chain | Metamorphosis, Biological | Sweden | Animals | Time Factors | Larva - growth & development | Environment | Rana temporaria - physiology | Frogs | Growth | Amphibians | Physical growth | Macroecology | Environmental conditions | Naturvetenskap | Natural Sciences
Animal feeding behavior | Life histories | Larvae | Predators | Ecological genetics | Animal ecology | Tadpoles | Lipids | Predation | Metamorphosis | Low temperature | life history strategies | metamorphosis | time‐stressed populations | Rana temporaria | catch‐up growth | Catch-up growth | Life history strategies | Time-stressed populations | SIZE | COMPENSATORY GROWTH | catch-up growth | RANA-TEMPORARIA | RATES | ZOOLOGY | TEMPERATURE | NATURAL-SELECTION | LIFE-HISTORY | ECOLOGY | PREDATION RISK | time-stressed populations | PLASTICITY | Cold Temperature | Rana temporaria - growth & development | Body Size | Stress, Physiological | Lipid Metabolism | Motor Activity | Food Chain | Metamorphosis, Biological | Sweden | Animals | Time Factors | Larva - growth & development | Environment | Rana temporaria - physiology | Frogs | Growth | Amphibians | Physical growth | Macroecology | Environmental conditions | Naturvetenskap | Natural Sciences
Journal Article