Genetic variability of environmental sensitivity revealed by phenotypic variation in body weight and (its) correlations to physiological and behavioral traits.

Adaptive phenotypic plasticity is a key component of the ability of organisms to cope with changing environmental conditions. Fish have been shown to exhibit a substantial level of phenotypic plasticity in response to abiotic and biotic factors. In the present study, we investigate the link between environmental sensitivity assessed globally (revealed by phenotypic variation in body weight) and more targeted physiological and behavioral indicators that are generally used to assess the sensitivity of a fish to environmental stressors. We took advantage of original biological material, the rainbow trout isogenic lines, which allowed the disentangling of the genetic and environmental parts of the phenotypic variance. Ten lines were characterized for the changes of body weight variability (weight measurements taken every month during 18 months), the plasma cortisol response to confinement stress (3 challenges) and a set of selected behavioral indicators. This study unambiguously demonstrated the existence of genetic determinism of environmental sensitivity, with some lines being particularly sensitive to environmental fluctuations and others rather insensitive. Correlations between coefficient of variation (CV) for body weight and behavioral and physiological traits were observed. This confirmed that CV for body weight could be used as an indicator of environmental sensitivity. As the relationship between indicators (CV weight, risk-taking, exploration and cortisol) was shown to be likely depending on the nature and intensity of the stressor, the joint use of several indicators should help to investigate the biological complexity of environmental sensitivity.

Exploration of the hypothalamic-pituitary-adrenal function as a tool to evaluate animal welfare.

Measuring HPA axis activity is the standard approach to the study of stress and welfare in farm animals. Although the reference technique is the use of blood plasma to measure glucocorticoid hormones (cortisol or corticosterone), several alternative methods such as the measurement of corticosteroids in saliva, urine or faeces have been developed to overcome the stress induced by blood sampling itself. In chronic stress situations, as is frequently the case in studies about farm animal welfare, hormonal secretions are usually unchanged but dynamic testing allows the demonstration of functional changes at several levels of the system, including the sensitization of the adrenal cortex to ACTH and the resistance of the axis to feedback inhibition by corticosteroids (dexamethasone suppression test). Beyond these procedural aspects, the main pitfall in the use of HPA axis activity is in the interpretation of experimental data. The large variability of the system has to be taken into consideration, since corticosteroid hormone secretion is usually pulsatile, follows diurnal and seasonal rhythms, is influenced by feed intake and environmental factors such as temperature and humidity, age and physiological state, just to cite the main sources of variation. The corresponding changes reflect the important role of glucocorticoid hormones in a number of basic physiological processes such as energy metabolism and central nervous system functioning. Furthermore, large differences have been found across species, breeds and individuals, which reflect the contribution of genetic factors and environmental influences, especially during development, in HPA axis functioning. Usually, these results will be integrated with data from behavioral observation, production and pathology records in a comprehensive approach of farm animal welfare.

Relationship between changes in mRNAs of the genes encoding steroidogenic acute regulatory protein and P450 cholesterol side chain cleavage in head kidney and plasma levels of cortisol in response to different kinds of acute stress in the rainbow trout (Oncorhynchus mykiss).

In this study, the expression of several genes involved in cortisol synthesis in head kidneys, the site of cortisol production, and in the rainbow trout (Oncorhynchus mykiss) was examined in response to two different acute stressors and an acute ACTH treatment. mRNAs levels of the "steroidogenic acute regulatory" (StAR) sterol transport protein, which transports cholesterol to the inner mitochondrial membrane as well as cytochrome P450 cholesterol side chain cleavage (P450(SCC)) were determined in head kidney (containing the interrenal tissue). In one experiment, we also quantified 3-beta-hydroxysteroid dehydrogenase (3B-HSD) and cytochrome P450(11beta) (11B-H) mRNAs. The presence of these four transcripts in the head kidney was confirmed by Northern blot analysis. For each stress condition, mRNA levels were quantified by quantitative or real-time RT-PCR. The results of these two methods were highly correlated. An acute stress induced by capture, short confinement (2min), and anesthesia (3min) resulted in significant elevation of plasma cortisol (30-fold higher than controls) and an increase in levels of StAR and P450(SCC) mRNAs 3h post-stress. When fish were submitted to an acute stress caused by 5min of chase with a net in a tank, plasma cortisol reached a peak within 1h, but after 3h, levels were only 5-fold higher in stressed trout than in controls and no variations in the expression of StAR, P450(SCC), 3B-HSD, and 11B-H were observed whatever the time post-stress. One hour after acute ACTH stimulation (5IU/kg), plasma cortisol level was 4-fold higher than in control trout and no changes in StAR and P450(SCC) mRNAs levels were detected. The data suggest that the high levels of cortisol after stress need an activation of genes involved in cortisol synthesis, but lower levels do not. Futhermore, under these three test conditions, we always found a strong positive correlation between mRNA levels of StAR and P450(SCC), in contrast to what has been described in mammals. Consequently, the absence of transcription activation with low increase in cortisol levels suggests that other levels of regulation, particularly activation of pre-existing proteins, govern cortisol production.

Biochemical and behavioral effects of carbofuran in goldfish (Carassius auratus).

The effects of concentration (5, 50, and 500 microg/L) and duration (24, 48 h) of exposure to carbofuran, a carbamate insecticide, were assessed on brain catecholamine (norepinephrine [NE] and dopamine), plasma glucose, and hepatic glycogen contents and behavioral activities of goldfish (Carassius auratus). After 24 h of exposure to 50 and 500 microg/L, the level of NE was increased in the olfactory bulbs. The same effect was observed after a 48-h exposure to 500 and 50 microg/L in the telencephalic hemispheres and in the hypothalamus, respectively. An increase in the level of dopamine was also found in hypothalamus after 48 h of exposure to 500 microg/L carbofuran. Plasma glucose increased in concentration after both periods of exposure to carbofuran at 50 and 500 microg/L. Hepatic glycogen concentration decreased after a 48-h exposure to the highest concentration. Behavioral endpoints related to swimming pattern and social interactions were affected after a 24-h exposure to the lowest concentration tested (5 microg/L). The relative sensitivities of these different types of responses to exposure to carbofuran are discussed in light of data on the neurotoxic effects of carbamate and organophosphate insecticides in fish.