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Modulation of adrenocorticotrophin hormone (ACTH)-induced expression of stress-related genes by PUFA in inter-renal cells from European sea bass (Dicentrarchus labrax)

Published online by Cambridge University Press:  04 May 2015

Daniel Montero*
Affiliation:
Universidad de Las Palmas de Gran Canaria (ULPGC), Grupo de Investigación en acuicultura (GIA), Instituto Universitario de Sanidad Animal y Seguridad Alimentaria (IUSA), c/ Transmontaña, s/n, 35413, Arucas, Las Palmas, Canary Islands, Spain
Genciana Terova
Affiliation:
University of Insubria, Department of Biotechnology and Life Sciences, Via Dunant, 3-21100 Varese, Italy
Simona Rimoldi
Affiliation:
University of Insubria, Department of Biotechnology and Life Sciences, Via Dunant, 3-21100 Varese, Italy
Lluis Tort
Affiliation:
Universitat Autonoma de Barcelona, Department de Biologia Cel.lular, Fisiologia i immunologia, Edifici M. 08193, Bellaterra, Cerdanyola del Vallès, Barcelona, Spain
Davinia Negrin
Affiliation:
Universidad de Las Palmas de Gran Canaria (ULPGC), Grupo de Investigación en acuicultura (GIA), Instituto Universitario de Sanidad Animal y Seguridad Alimentaria (IUSA), c/ Transmontaña, s/n, 35413, Arucas, Las Palmas, Canary Islands, Spain
María Jesús Zamorano
Affiliation:
Universidad de Las Palmas de Gran Canaria (ULPGC), Grupo de Investigación en acuicultura (GIA), Instituto Universitario de Sanidad Animal y Seguridad Alimentaria (IUSA), c/ Transmontaña, s/n, 35413, Arucas, Las Palmas, Canary Islands, Spain
Marisol Izquierdo
Affiliation:
Universidad de Las Palmas de Gran Canaria (ULPGC), Grupo de Investigación en acuicultura (GIA), Instituto Universitario de Sanidad Animal y Seguridad Alimentaria (IUSA), c/ Transmontaña, s/n, 35413, Arucas, Las Palmas, Canary Islands, Spain
*
*Corresponding author: Dr D. Montero, email [email protected]

Abstract

Dietary fatty acids have been shown to exert a clear effect on the stress response, modulating the release of cortisol. The role of fatty acids on the expression of steroidogenic genes has been described in mammals, but little is known in fish. The effect of different fatty acids on the release of cortisol and expression of stress-related genes of European sea bass (Dicentrarchus labrax) head kidney, induced by a pulse of adenocorticotrophin hormone (ACTH), was studied. Tissue was maintained in superfusion with 60 min of incubation with EPA, DHA, arachidonic acid (ARA), linoleic acid or α-linolenic acid (ALA) during 490 min. Cortisol was measured by RIA. The quantification of stress-related genes transcripts was conducted by One-Step TaqMan real-time RT-PCR. There was an effect of the type of fatty acid on the ACTH-induced release of cortisol, values from ALA treatment being elevated within all of the experimental period. The expression of some steroidogenic genes, such as the steroidogenic acute regulatory protein (StAR) and c-fos, were affected by fatty acids, ALA increasing the expression of StAR after 1 h of ACTH stimulation whereas DHA, ARA and ALA increased the expression of c-fos after 20 min. ARA increased expression of the 11β-hydroxylase gene. Expression of heat shock protein 70 (HSP70) was increased in all the experimental treatments except for ARA. Results corroborate previous studies of the effect of different fatty acids on the release of cortisol in marine fish and demonstrate that those effects are mediated by alteration of the expression of steroidogenic genes.

Type
Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
The online version of this article is published within an Open Access environment subject to the conditions of the Creative Commons Attribution license
Copyright
Copyright © The Author(s) 2015

Cortisol, which is the main corticosteroid in fish( Reference Aluru and Viyajan 1 ), is released into the bloodstream from the inter-renal cells under the action of adrenocorticotrophin hormone (ACTH) via activation of the hypothalamus–pituitary–inter-renal axis following a stressful situation( Reference Wendelaar Bonga 2 ). ACTH stimulation of cortisol synthesis is mainly dependent on the cAMP/protein kinase A (cAMP/PKA) pathway, which involves a signalling cascade integrating G-proteins, cAMP and PKA( Reference Stocco, Wang and Jo 3 ). However, there are other pathways described in fish( Reference Kloas, Reinecke and Hanke 4 ), independent of cAMP activation, including protein kinase C activation via stimulation of angiotensin II or acetylcholine with a final activation of genes involved in steroidogenesis, such as steroidogenic acute regulatory protein (StAR). StAR is involved in the transport of cholesterol through the mitochondrial membrane of the steroidogenic cells to be used as a substrate for steroid synthesis( Reference Stocco, Wang and Jo 3 ). However, although cAMP is the most important second messenger for trophic hormone-stimulated steroid biosynthesis, other mechanisms independent of cAMP have been described, including macrophage-derived factors, and intracellular Ca and/or Cl ions( Reference Stocco, Wang and Jo 3 ). Once the cholesterol is transported into the mitochondria, a cascade of enzymes, such as those belonging to the cytochrome P450 family, is activated. Cytochrome P450 11β (CYP11b) catalyses the last step that transforms 11-desoxicortisol to cortisol( Reference Jiang, Young and Kobayashi 5 ) which is then released into the bloodstream following a stressful situation.

It has been reported that the use of vegetable oils in fish diets alters the post-stress circulating levels of plasma cortisol, both in vivo ( Reference Montero, Kalinowski and Obach 6 Reference Ganga, Montero and Bell 8 ) and in vitro ( Reference Ganga, Bell and Montero 9 ). The limited availability of fish oil to fulfil the increased demand in aquafeeds has induced the necessity to replace this oil by other oils, of marine or terrestrial origin( Reference Tacon and Metian 10 ). Among the different oils used in the aquafeeds industry for such replacement, single vegetable oils or their blends seem to be good candidates that are being used in the diet of different fish species( Reference Turchini, Torstensen and Ng 11 ). Fish growth is not affected by 60–75 % replacement of fish oil with alternative lipid sources, if essential fatty acids requirements are fulfilled. However, high levels of fish oil replacement can induce negative effects in marine fish, depending on fish size, water temperature, the type of oil used, and the amount of fish meal used in the diet( Reference Sales and Glencross 12 ).

Vegetable oils are abundant in n-6 and n-9 C18 long-chain PUFA, mainly linoleic acid (18 : 2n-6, LA) and α-linolenic acid (18 : 3n-3, ALA), but are poor sources of long-chain PUFA, including EPA (20 : 5n-3), DHA (22 : 6n-3) and arachidonic acid (ARA; 20 : 4n-6), which are essential for marine fish. Although vegetable oils have been used in diets for marine fish species( Reference Turchini, Torstensen and Ng 11 , Reference Sales and Glencross 12 ), the reduction in the health-promoting effects provided by long-chain PUFA can be induced if a non-well-balanced blend of oils is used( Reference Turchini, Torstensen and Ng 11 ). Indeed, the use of certain vegetable oils has been reported to alter different immune system-related parameters( Reference Montero, Izquierdo, Turchini, Ng and Tocher 13 , Reference Montero, Mathlouthi and Tort 14 ) and to affect also the stress response in different marine species( Reference Montero, Kalinowski and Obach 6 , Reference Jutfelt, Olsen and Bjornsson 15 ). In particular, ALA has been shown to increase the in vitro release of cortisol from gilthead sea bream inter-renal cells, whereas LA produced the same effect but delayed in time( Reference Ganga, Bell and Montero 9 ). As for the different essential fatty acids, the deficiency of n-3 highly unsaturated fatty acids has been shown to alter the post-stress plasma cortisol levels in gilthead sea bream( Reference Montero, Tort and Izquierdo 16 ) and ARA has been reported to affect whole-body cortisol levels in larval stages of this species( Reference Koven, Barr and Lutzky 17 Reference Alves Martins, Rocha and Castanheira 20 ).

However, the specific mechanisms involved in the modulation of the cortisol release by different fatty acids are still poorly understood. Ganga and et al. ( Reference Ganga, Bell and Montero 9 , Reference Ganga, Tort and Acerete 21 ) demonstrated that the role of different fatty acids in the release of cortisol from the anterior kidney is mediated, at least in part, by the action of cyclo-oxygenase (COX) and lipo-oxygenase (LOX) metabolites( Reference Ganga, Bell and Montero 9 , Reference Ganga, Tort and Acerete 21 ), in a cAMP-dependent manner. However, these authors suggested mechanisms other than COX and LOX metabolites, in which certain fatty acids, such as DHA, modulate the release of cortisol from the inter-renal cells( Reference Ganga, Tort and Acerete 21 ), but they did not define such mechanisms.

In more recent studies, it has been shown that dietary fatty acids are able to modulate the expression of stress response-related genes in different marine fish species( Reference Alves Martins, Rocha and Castanheira 20 , Reference Benitez-Dorta, Caballero and Izquierdo 22 ), as it occurs in mammals( Reference Wang, Dyson and Jo 23 Reference Wang, Shen and Dyson 25 ). The long-chain PUFA have been shown to down-regulate the expression of genes involved in the release of cortisol, such as StAR. Wang et al. ( Reference Wang, Shen and Dyson 25 ) described the role of ARA and epoxygenase metabolites from ARA in cAMP-stimulated steroidogenesis and in the expression of the StAR gene in MA-10 mouse Leydig cells. ARA regulation of steroidogenesis has also been described to be mediated by 5-LOX metabolites( Reference Cooke, Di Cónsoli and Malboreti 26 ). Wang et al. ( Reference Wang, Dyson and Jo 24 ) also described an effect of COX-2-derived ARA metabolites in steroidogenesis through StAR gene expression. C18 fatty acids have been shown to alter adrenal steroidogenesis both in vivo and in vitro ( Reference Chin, Naddafy and Cheng 27 , Reference Hodges, Chin and Naddafy 28 ). In fish, the role of dietary lipids on StAR expression remains unclear. Only some effects of ARA in Senegalese sole whole post-larval StAR gene expression have been described( Reference Alves Martins, Rocha and Castanheira 20 ), without finding a clear correlation between dietary levels of ARA and the expression of this steroidogenic gene.

The regulation of steroidogenesis has been also linked to the action of the activator protein-1 (AP-1) family member c-fos ( Reference Stocco, Wang and Jo 3 , Reference Shea-Eaton, Sandhoff and Lopez 29 ). The c-fos gene is well known as an immediate early gene because it is rapidly expressed in several mammalian brain sites in response to various stressful stimuli, including CO2/H+ elevation( Reference Sato, Severinghaus and Basbaum 30 ). The product of this gene, the c-fos protein, is a nuclear factor that regulates gene transcription by binding to AP-1 regulatory elements in the promoter and enhancer regions of numerous genes( Reference Curran and Franza 31 ). Its biochemical characteristics and molecular nature have been widely studied; however, most of the research has been done using mammalian model species. Indeed, studies on c-fos expression under hypercapnic stress conditions have been carried out in mice( Reference Tankersley, Haxhiu and Gauda 32 ) and rats( Reference Teppema, Veening and Kranenburg 33 , Reference Pete, Mack and Haxhiu 34 ). In both species, following CO2 stimulation, the expression of the c-fos gene was induced within minutes. In fish, the c-fos gene has been cloned in some species, such as Tetraodon negroviridis, Carassius auratus, Ctenopharyngodon idella, Oncorhynchus mykiss, Rivulus marmoratus and Dicentrarchus labrax ( Reference Matsuoka, Fuyuki and Shoji 35 Reference Rimoldi, Terova and Brambilla 38 ), but, to our knowledge, there is no information on tissue expression patterns of the c-fos gene related to different dietary fatty acids and stressful conditions in fish.

Cortisol effects in the cell are mediated by the glucocorticoid receptors (GR), which are members of the nuclear receptor superfamily that act as ligand-dependent transcription factors( Reference Mommsen, Vijayan and Moon 39 ). Within the cytosol, GR is present in a non-activated form together with heat shock proteins (HSP) such as HSP70 and HSP90, whose functions are the assembly, functionality and transport of GR( Reference Pratt and Toft 40 ). HSP are associated to the GR until a hormone signal, such as cortisol, induces a conformation with lower affinity for HSP, dissociating GR from the HSP. Then, the receptors translocate into the nucleus and bind to a specific DNA region, the glucocorticoid response element, to regulate the transcription of glucocorticoid-responsive genes( Reference Aluru and Viyajan 1 , Reference Vijayan, Prunet, Boone, Moon and Mommsen 41 , Reference Terova, Gornati and Rimoldi 42 ). Activated HSP90 and HSP70 play a role in the assembling of other proteins, and they are involved in the regulation of kinetic partitioning between-folding, translocation and aggregation, as well as in immune, apoptotic and inflammatory processes( Reference Roberts, Agius and Saliba 43 ).

The effect of different fatty acids in GR activation has been described in mammals( Reference Ranhotra and Sharma 44 , Reference Oarada, Gonoi and Tsuzuki 45 ). However, little is known about the effect of dietary lipids on GR transcripts in fish. Benitez-Dorta et al. ( Reference Benitez-Dorta, Caballero and Izquierdo 22 ) showed an effect of dietary oils on GR gene expression in different tissues of Senegalese sole subjected to stress. Besides, certain fatty acids, and their metabolites, such as ARA have been shown to regulate HSP in humans( Reference Jurivich, Sistonen and Sarge 46 ). Highly unsaturated fatty acids have been described to exert a heat shock-induced increase of HSP70 gene expression in leucocytes isolated from the pronephros of rainbow trout following incubation with DHA and ARA compared with unsupplemented cells( Reference Samples, Pool and Lumb 47 ), whereas Benitez-Dorta et al. ( Reference Benitez-Dorta, Caballero and Izquierdo 22 ) reported a reduced gene expression of HSP in different tissues of Senegalese sole fed vegetable oil-based diets.

Accordingly, the aim of the present study was to give insights on the effect of different fatty acids on cortisol production in ACTH-stimulated head kidney. For that purpose, European sea bass (Dicentrarchus labrax) isolated head kidney cells were maintained in a superfusion system and were incubated with different fatty acids before an ACTH pulse. European sea bass is highly susceptible to stressful situations and opportunistic pathogen incidence. Besides, the tolerance of this species to dietary changes such as the type of feed oil seems to be lower than that of other marine fish species such as the gilthead sea bream( Reference Varsamos, Flik and Pepin 48 ).

Materials and methods

All the experimental conditions and sampling protocols have been approved by the Animal Welfare and Bioethical Committee from the University of Las Palmas de Gran Canaria.

Animals and experimental conditions

Sexually immature European sea bass supplied by a Spanish fish farm (ADSA, San Bartolomé de Tirajana, Canary Islands, Spain) were acclimatised in the aquaculture facilities of the University of Las Palmas de Gran Canaria (Las Palmas, Spain) for 1 month. Fish of body weight 161·3 ± 14·5 g were distributed in four 1 m3 fibreglass tanks in an open seawater circulation system within the acclimatisation period. Tanks were supplied with seawater at a temperature of 23·3–23·5°C and natural photoperiod (12 h light–12 h dark). Fish were fed twice per d with a commercial feed (Biomar Iberia), 6 d per week. Before the superfusion trial, fish were kept unfed during 24 h to avoid feed interference.

Preparation and stimulation of head kidney tissue

At the end of the acclimatisation period, for each superfusion trial, two fish were randomly taken from each tank, immediately anaesthetised with 2-phenoxyethanol (1:1000, v/v) and blood was collected from the caudal vein to minimise haemorrhage when dissecting the tissue. Superfusion protocols have been described previously in our laboratory( Reference Ganga, Bell and Montero 9 , Reference Ganga, Tort and Acerete 21 ). Head kidney tissue was removed from eight fish in each superfusion trial, weighed, homogenated and kept in HEPES Ringer solution (171 mm-NaCl, 2 mm-KCl, 2 mm-CaCl2H2O, 0·25 % glucose, 0·03 % bovine serum albumin, pH 7·4) as described by Rotllant et al. ( Reference Rotllant, Balm and Pérez-Sánchez 49 ), which was used as the perfusion medium. Then, 200 mg of head kidney homogenates were pooled and distributed in each of the eight perfusion chambers (volume: 0·2 ml) in order to obtain a homogeneous sample in each of them, being tissue from the eight fish in each chamber and trial. Each superfusion trial was conducted in triplicates (8 × 3). The system was temperature-controlled at 18°C, and the superfusion medium was pumped at a rate of 75 ml/min by a Masterplex L/SR multichannel peristaltic pump (Cole Parmer Instrument Company), as previously described by Ganga et al. ( Reference Ganga, Bell and Montero 9 ).

After a stabilisation period of 180 min required for cortisol to reach a stable baseline level as previously described( Reference Ganga, Bell and Montero 9 , Reference Ganga, Tort and Acerete 21 , Reference Rotllant, Balm and Ruane 50 ), tissues were stimulated with ACTH at a concentration of 5 nm-hACTH1–39 (Sigma) for 20 min. Afterwards, superfusion was maintained, being whole pooled tissues and the supernatant fraction collected at before and after 60 min of fatty acid addition (see below), and 20, 40, 60, 110, 160 and 250 min after ACTH stimulation.

The whole pooled head kidney tissues used in each perfusion chambers from each sampling point were stored in RNAlater (Sigma) for 8 h at 4°C. After that, RNAlater was removed and tissues were kept at –80°C until its analysis. Samples were sent to the Department of Biotechnology and Molecular Sciences of the University of Insubria (Varese, Italy) for gene expression analysis. Besides, the supernatant fraction from each sampling point was kept at –20°C. Samples were sent to the Physiology and Cell Biology laboratory at the Universitat Autonoma de Barcelona (Barcenola, Spain) for cortisol analysis.

Perfusion fatty acid treatments

Five treatments were carried out within the present study (plus a control one without fatty acid addition), using different fatty acids: EPA (EPA treatment), DHA (DHA treatment), ARA (ARA treatment), LA (LA treatment) and ALA (ALA treatment). These treatments were similar to the superfusion control protocol except that after the stabilisation period and before ACTH stimulation, tissues were incubated for 1 h with fatty acids diluted in less than 0·5 % of ethanol–medium (v/v) at a concentration of 50 µm, as described previously( Reference Ganga, Tort and Acerete 21 ). Triplicates were conducted for each fatty acid assayed plus the control.

Cortisol measurements

For each fatty acid treatment plus the control (no fatty acid treatment), cortisol concentration in the supernatant fraction was determined by RIA( Reference Rotllant, Balm and Ruane 50 ). The antibody used for the assay was purchased from Biolink S.L. in a final dilution of 1:6000. This antibody cross-reactivity is 100 % with cortisol, 11·40 % with 21-desoxycorticosterone, 8·90 % with 11-desoxycortisol and 1·60 % with 17α-hydroxyprogesterone. Radioactivity was quantified using a liquid scintillation counter. Cortisol levels are given as ng/g tissue per h, as previously described by Ganga et al. ( Reference Ganga, Tort and Acerete 21 ).

Preparation of total RNA

Total RNA was extracted from all the samples using PureYield RNA Midiprep System (Promega), following the protocol described in the PureYield™ RNA Midiprep System Technical Manual no. TM279 (available online at: www.promega.com/tbs).

The quantity of the extracted RNA was calculated using the absorbance at 260 nm, whereas the integrity of RNA was assessed by agarose gel electrophoresis. Crisp 18S and 28S bands, detected by ethidium bromide staining, were indicators of the intact RNA.

Quantitative real-time RT-PCR

Generation of in vitro-transcribed mRNA for standard curves

The approach used for the real-time quantification of our target genes expression relied on the standard curve method for target mRNA quantification. The target genes were c-fos, StAR, CYP11β and HSP70. Following this method, the number of each gene transcript copies could be quantified by comparing them with a standard graph constructed using the known copy number of mRNA of each target gene. The first step in this direction is the generation of standards of mRNA by in vitro transcription. As an example, in the case of c-fos, a forward and a reverse primer were designed based on the mRNA sequences of D. labrax c-fos that we have previously identified( Reference Rimoldi, Terova and Brambilla 38 ) (Genebank accession no. DQ838581). This primer pair was used to create templates for the in vitro transcription of mRNA for c-fos. The forward primer was engineered to contain a T3 phage polymerase promoter gene sequence to its 5′ end (5′-caattaaccctcactaaagggTCTCACAGAGCTCACCCCTA-3′) and used together with the reverse primer (5′-TGGTCTCCATTACTCCTTCCC-3′) in a conventional RT-PCR of total sea bass head kidney RNA. RT-PCR products were then checked on a 2·5 % agarose gel stained with ethidium bromide, cloned using the pGEM®-T cloning vector system (Promega) and subsequently sequenced in the SP6 direction.

In vitro transcription was performed using T3 RNA polymerase and other reagents supplied in the Promega RiboProbe In Vitro Transcription System kit according to the manufacturer's protocol.

The molecular weight (MW) of the in vitro-transcribed RNA for c-fos was calculated according to the following formula:

$$\eqalign{\hbox{c-}fos \hbox{MW} & = \lpar 129 \lpar \hbox{number of A bases}\rpar \times 329\!\cdot\! 2\rpar \cr & \quad+ \lpar 69 \lpar \hbox{number of U bases}\rpar \times 306\!\cdot\! 2\rpar \cr & \quad+ \lpar 66 \lpar \hbox{number of C bases}\rpar \times 305\!\cdot\! 2\rpar \cr & \quad+ \lpar 98 \lpar \hbox{number of G bases}\rpar \times 345\!\cdot\! 2\rpar + 159.}$$

The result was 126 182·2. Spectrophotometry at 260 nm gave a concentration of 132·8 ng/μl for c-fos. Therefore, the concentration of the final working solution was 6·34 × 1011 molecules/μl.

The same aforementioned approach was used for the in vitro transcription of the other target genes such as StAR, CYP11β, GR, HSP90 and HSP70. The primers used are shown in Table 1.

Table 1. Sequences of primers used to synthesise standard mRNA

The MW of the in vitro-transcribed RNA calculated according to the aforementioned formula were 117 433·8 for HSP70, 73 451·4 for StAR and 96 414·6 for CYP11. Spectrophotometry at 260 nm gave a concentration of 33·7 ng/μl for HSP70; 201·1 for CYP11b and 104·0 for StAR. Therefore, the concentrations of the final working solutions were 1·73 × 1011 molecules/μl for HSP70, 1·26 × 1012 for CYP11b and 8·53 × 1011 molecules/μl for StAR.

Generation of standard curves for stress-related genes

The mRNA of target genes produced by in vitro transcription were used as quantitative standards in the analysis of experimental samples. Defined amounts of mRNA of each gene, at 10-fold dilutions, were subjected to real-time PCR using One-Step TaqMan EZ RT-PCR Core Reagents (Life Technologies), including 1 × Taqman buffer, 3 mm-MnOAc, 0·3 mm-dNTP except dTTP, 0·6 mm-dUTP, 0·3 µm forward primer, 0·3 µm reverse primer, 0·2 µm FAM-6 (6-carboxyfluorescein-labelled probe), 5 units rTH DNA polymerase and 0·5 units AmpErase UNG enzyme in a 30 µl reaction. RT-PCR conditions were: 2 min at 50°C, 30 min at 60°C, and 5 min at 95°C, followed by forty cycles consisting of 20 s at 92°C, 1 min at 62°C. The cycle threshold (CT) values obtained by amplification were used to create standard curves for target genes.

Quantification of transcripts by One-Step TaqMan real-time RT-PCR

Total RNA (100 ng) extracted from the experimental samples was subjected, in parallel to 10-fold-diluted, defined amounts of standard mRNA, to real-time PCR under the same experimental conditions as for the establishment of the standard curves. Real-time Assays-by-DesignSM PCR primers and gene-specific fluorogenic probes were designed by Life Technologies. Primer sequences and Taqman® probes of the four target genes are shown in Table 2.

Table 2. Primers and probes for quantitative real-time PCR

TaqMan® PCR was performed using the StepOne Real-time PCR System (Life Technologies). To reduce pipetting errors, master mixes were prepared to set up duplicate reactions (2 × 30 µl) for each sample.

Sample quantification

Data from Taqman® PCR runs were collected with the StepOne Real Time Sequence Detector Program. CT values corresponded to the number of cycles at which the fluorescence emission monitored in real time exceeded the threshold limit. The CT values were used to create standard curves to serve as a basis for calculating the absolute amounts of mRNA in total RNA.

Calculation and statistical analysis

Quantitative PCR data were analysed by one-way ANOVA and each time point was analysed separately. A post hoc test was applied (Tukey). We used the statistics package SPSS Statistics 21 (IBM). The other data were statistically compared using one-way ANOVA. The level of statistical significance was set at P < 0·05.

Results

Cortisol released from superfused head kidney

Basal cortisol values were obtained after the stabilisation period (180 min) and no significant differences were found among values of different fatty acid treatments. After 1 h of incubation with fatty acid, the release of cortisol remained low (Fig. 1). After ACTH stimulation, cortisol values increased in all the experimental groups, the values obtained for head kidney from the EPA, DHA, LA and ALA treatments being significantly higher (P < 0·05) when compared with the control group after 20 min of ACTH stimulation. At 40 min after ACTH stimulation, cortisol values of ALA, ARA and EPA treatments were significantly higher (P < 0·05) that the control values. After 60 min of ACTH stimulation values of cortisol of head kidney from the ALA treatment showed the highest values, within all the superfusion trials, being significantly (P < 0·05) higher for all the sampling points except for 160 min after ACTH stimulation.

Fig. 1. Absolute cortisol secretion by European sea bass (Dicentrarchus labrax) head kidney (HK) after adrenocorticotrophin hormone (ACTH) stimulation following incubation with highly unsaturated fatty acids (FA): EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA). a,b,c Different letters for a given time indicate significant differences (P < 0·05).

StAR, c-fos, CYP11b, GR, HSP70 and HSP90 mRNA copy number in sea bass anterior kidney cells during the perfusion trial

The mRNA copies of StAR were significantly (P < 0·01) affected by the type of fatty acid used in the perfusion trial (Fig. 2), with ALA inducing an increase in expression after 60 min of ACTH pulse. The expression level of this group at this time point of perfusion trial was double that obtained by using the other fatty acids.

Fig. 2. Expression levels of the steroidogenic acute regulatory protein (StAR) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. StAR mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. a,b Different letters for a given time indicate significant differences (P < 0·05).

C-fos mRNA in sea bass head kidney cells in response to the perfusion trial are presented in Fig. 3. As shown, incubation for 60 min with DHA, ALA and ARA contributed to a significant increase in c-fos transcripts (P < 0·01) after 20 min of ACTH induction, as compared with the controls. DHA was the fatty acid that induced the highest c-fos level of expression with 5·13 × 105 mRNA copy number/ng total RNA, followed in a decreasing pattern by ALA with 2·51 × 103, and ARA with 1·31 × 103. The same time of incubation did not have an effect on c-fos transcript levels in cells incubated with either EPA or LA. Indeed, in these cells the mRNA copy number was the same as that of the controls. Subsequently, the expression levels of c-fos in different treatment groups fluctuated insignificantly as compared with the control values until the end of the perfusion trial (Fig. 3).

Fig. 3. Expression levels of the c-fos gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. c-fos mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. Differences were determined by one-way ANOVA and each time point was analysed separately. A post hoc test was applied (Tukey). a,b,c Different letters indicate significantly different means from controls, for the time point tested (P < 0·01).

There were significant effects (P < 0·01) of the type of fatty acid used during the perfusion trial on CYP11b gene expression (Fig. 4). ARA, ALA and DHA treatments at 20 min after ACTH stimulation reached values up to 7·0 × 106 for ARA and 2·8 × 106 for ALA and DHA in comparison with 0·8 × 106 mRNA copies for the EPA, LA and control experimental groups (Fig. 4).

Fig. 4. Expression levels of the cytochrome P450 11β (CYP11b) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. CYP11b mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. Differences were determined by one-way ANOVA and each time point was analysed separately. A post hoc test was applied (Tukey). a,b,c Different letters indicate significantly different means from controls, for the time point tested (P < 0·01).

We did not found any effects of the type of fatty acid used within the perfusion trial on the expression of GR or HSP90 genes (Figs. 5 and 6), whereas ACTH stimulation was associated with a significant increase in HSP70 transcripts (Fig. 7). Indeed, at 40 min after the ACTH pulse, the HSP70 mRNA copies in cells incubated with LA, DHA, EPA and ALA were significantly higher than that of the controls (P < 0·05), whereas the number of transcripts in cells incubated with ARA remained at the same sampling time point equal to that of the controls. At 40 min after the ACTH pulse, LA incubation induced the highest expression of HSP70 with 2·45 × 105 mRNA copies/ng total RNA, followed in a decreasing pattern by DHA with 1·76 × 105, EPA with 1·59 × 105, and ALA with 1·06 × 105 copies/ng total RNA. At 60 min after the ACTH pulse, the expression levels of HSP70 in the LA, DHA, EPA and ALA groups decreased significantly as compared with the previous sampling point (40 min), and then fluctuated insignificantly as compared with the control values till the end of the perfusion trial (Fig. 7).

Fig. 5. Expression levels of the glucocorticoid receptor (GR) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. GR mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean.

Fig. 6. Expression levels of the heat shock protein 90 (HSP90) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. HSP90 mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean.

Fig. 7. Expression levels of the heat shock protein 70 (HSP70) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. HSP70 mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. Differences were determined by one-way ANOVA and each time point was analysed separately. A post hoc test was applied (Tukey). a,b,c,dDifferent letters indicate significantly different means from controls, for the time point tested (P < 0·01).

The transcript copies of oxidative stress-related genes catalase (CAT), superoxide dismutase (SOD) and glutathione peroxidase (GPX) in different groups at time zero, after incubation for 60 min with different fatty acids, and at different time points after ACTH pulse did not show any significant differences from the controls (data not shown).

Discussion

Results obtained in the present study corroborate the effect of different fatty acids on the release of cortisol in marine fish, previously described both in vivo ( Reference Montero, Kalinowski and Obach 6 , Reference Ganga, Montero and Bell 8 , Reference Montero, Tort and Izquierdo 16 Reference Van Anholt, Koven and Lutzky 19 , Reference Van Anolt, Spanings and Nixon 51 , Reference Alves Martins, Rocha and Martínez-Rodriguez 52 ) and in vitro ( Reference Ganga, Bell and Montero 9 , Reference Ganga, Tort and Acerete 21 ). In agreement with the results previously obtained in gilthead sea bream under similar superfusion conditions( Reference Ganga, Tort and Acerete 21 ), both EPA and ARA induced an increase of cortisol release in ACTH-stimulated inter-renal cells of European sea bass. Moreover, the effect obtained by EPA incubation was faster in time (significantly different at 20 min after ACTH stimulation) than in the case of ARA, which showed a significant difference from the controls at 40 min after ACTH stimulation. Dietary ARA has been shown to affect whole-body cortisol and stress response in different marine fish larvae( Reference Koven, Barr and Lutzky 17 , Reference Koven, Van Anholt and Lutzky 18 , Reference Alves Martins, Rocha and Castanheira 20 , Reference Alves Martins, Rocha and Martínez-Rodriguez 52 , Reference Lund and Steenfeldt 53 ) including European sea bass( Reference Atalah, Hernández-Cruz and Ganuza 54 ). However, since these studies were conducted in whole larvae, and ARA was supplied through either artemia or microdiets, the assignment of an ARA direct effect on whole-body cortisol of larvae is too premature( Reference Alves Martins, Rocha and Castanheira 20 ).

The addition of DHA induced an increase of cortisol release at only 20 min after ACTH stimulation, but incubation with ALA induced an increase of cortisol release from ACTH-stimulated inter-renal cells during the entire period studied. These results also corroborate those previously reported for other marine species such as gilthead sea bream( Reference Ganga, Montero and Bell 8 , Reference Ganga, Bell and Montero 9 ) fed on diets based on linseed oil, which is an ALA-rich vegetable oil. Similarly, in Atlantic salmon smolts, feeding high-n-3/n-6 diets increased post-stress plasma cortisol( Reference Oxley, Jolly and Eide 7 ). In agreement, in human subjects, some reports indicated that increasing the dietary n-6:n-3 fatty acids ratio by increasing the ratio between LA and LNA up to 4:1 reduced blood cortisol and cholesterol levels( Reference Yehuda, Rabidovitz and Carasso 55 ).

The role of different fatty acids as modulators of steroidogenesis in mammals has been widely described, most studies being related to reproductive tissues( Reference Wang, Dyson and Jo 23 , Reference Wang, Dyson and Jo 24 , Reference Wonnacott, Kwong and Hughes 56 , Reference Hughes, Kwong and Li 57 ) and, to a lesser extent, to the adrenal gland( Reference Stocco, Wang and Jo 3 , Reference Chin, Naddafy and Cheng 27 ). Steroidogenesis is modulated by a multiple range of signalling pathways, in a very complex manner( Reference Stocco, Wang and Jo 3 ). The activation of the cAMP/PKA signalling cascade leads to the phosphorylation of transcriptional factors that regulate StAR gene transcription( Reference Reinhart, Williams and Stocco 58 ), but cAMP also induces ARA release( Reference Wang, Dyson and Mondillo 59 ), ARA metabolic derivatives transducing signals to the nucleus to regulate StAR gene expression, being both pathways necessary for trophic hormone-stimulated steroidogenesis( Reference Wang, Walsh and Reinhart 60 ). In the present study, there were no significant differences in the ACTH-induced expression of the StAR gene immediately after the ACTH pulse, even when an increase in cortisol was detected in all experimental groups after stimulation with the trophic hormone. An increase in whole-body cortisol after stress without an increase in StAR gene expression has also been described in Senegalese sole post-larvae fed different ARA levels in the diet( Reference Alves Martins, Rocha and Castanheira 20 ). Those authors hypothesised that higher StAR transcription may not be necessary for cortisol production. StAR is involved in the transport of cholesterol through the mitochondrial membrane of the steroidogenic cells to be used as the substrate for steroid synthesis. Such transport may also have been carried out by an available pool of inactive StAR protein( Reference Castillo, Castellana and Acerete 61 ). However, Stocco et al. ( Reference Stocco, Wang and Jo 3 ) pointed out that a chronic response involves an increase in the transcription/translation of steroidogenic-related genes whereas during an acute response to hormonal stimulation there is an absolute requirement for de novo protein synthesis for an acute production of steroids. Thus, it is also probable that the maximum peak of StAR expression is produced earlier than the sampling time point of 20 min after the ACTH pulse, explaining the lack of response of this gene found in our experiment and other previous studies( Reference Alves Martins, Rocha and Castanheira 20 ). It is interesting to point out that within the present study, a significant increase of StAR gene expression in the ALA treatment was found after 60 min of ACTH stimulation. The expression of StAR is directly related to the activity of the PG endoperoxide synthase II (PTGS2), which in turn is modulated by PUFA( Reference Ringbom, Huss and Stenholm 62 ). α-Linolenate, derived from ALA, is a poor substrate for PTGS2 in comparison with arachidonate or linoleate( Reference Laneuville, Breuer and Xu 63 ). Thus the activity of PTGS2 is expected to be lower in an ALA-enriched medium, and a putative stimulatory effect on steroidogenesis through PTGS2 inhibition may have contributed to an increase of StAR gene expression. This could explain the increase of cortisol release found in ALA treatment after ACTH stimulation in the present study and how linseed oil, which is rich in ALA, increases plasma cortisol in marine fish( Reference Montero, Kalinowski and Obach 6 , Reference Ganga, Montero and Bell 8 , Reference Benitez-Dorta, Caballero and Izquierdo 22 ).

Steroidogenesis has been described as being linked to the action of different ARA metabolites. The critical role of ARA-mediated metabolites in steroidogenesis has been widely described in mammals, via activation of secretory phospholipase A2 (PLA2) through activation of G protein after ACTH stimulation( Reference Stocco, Wang and Jo 3 ). PLA2 catalyses the release of fatty acids from phospholipids. Alves Martins et al. ( Reference Alves Martins, Rocha and Castanheira 20 ) have proposed a direct relationship between expression of PLA2 and whole post-larvae cortisol in Senegalese sole after 3 h of stress. However, other factors must be taken into consideration to elucidate this relationship, including the fast secretory PLA2-induced release of ARA after trophic hormone stimulation (less than 1 min)( Reference Stocco, Wang and Jo 3 ) since most of the previous studies evaluated PLA2 after several minutes or even hours. Different types of secretory PLA2, such as group X secretory PLA2, have been described to reduce StAR gene expression in mouse adrenals( Reference Shridas, Bailey and Boyanovsky 64 ). Besides, at least one other ARA-releasing pathway has been described in steroidogenesis, which depends on the cAMP-induced activation of the CoA thioesterase( Reference Maloberti, Mele and Neuman 65 ). It remains to be determined whether steroidogenesis dependence of secretory PLA2 plays a similar functional role in fish after stress.

The fatty acids released are metabolised through one of the three enzymic pathways: COX-2, LOX or epoxygenase. It has been reported that ARA metabolites produced through the LOX pathway stimulated steroidogenesis in Leydig cells of mammals( Reference Wang, Dyson and Jo 23 ), whereas COX-2 appears to be responsible for a tonic inhibition of steroidogenesis in those cells( Reference Wang, Shen and Dyson 25 ). ARA metabolites produced by epoxygenase activity, the epoxyeicosatrienoic acids, regulate StAR at the transcription level( Reference Wang, Shen and Dyson 25 ). PG modulate the sensitivity of the mammalian hypothalamus–pituitary–inter-renal axis, altering the stress response( Reference Nasushita, Watanobe and Takebe 66 ), whereas COX-derived PG have been shown to increase in vitro cortisol release in inter-renal tissue of female frogs( Reference Gobbetti and Zerani 67 ).

As far as we know, there are no studies in fish on the effect of the different ARA metabolites in steroidogenesis, although the implication of COX-derived metabolites in cortisol release has been suggested in fish( Reference Koven, Barr and Lutzky 17 Reference Van Anholt, Koven and Lutzky 19 , Reference Van Anolt, Spanings and Nixon 51 , Reference Van Anholt, Spanings and Koven 68 ). Ganga et al. ( Reference Ganga, Tort and Acerete 21 ) demonstrated that the role of ARA and EPA as modulators of the release of cortisol from ACTH-stimulated inter-renal cells is mediated, at least in part, by COX-2-derived metabolites, since the incubation of head kidney in a indomethacin-enriched medium decreased the release of cortisol from gilthead sea bream inter-renal cells incubated in an ARA- or EPA-enriched medium( Reference Ganga, Tort and Acerete 21 ). In a similar way, the effect of linseed oil in sea bream diets on the in vitro release of cortisol from inter-renal cells after ACTH stimulation has been proved to be mediated also by COX-2- and LOX-derived metabolites( Reference Ganga, Bell and Montero 9 ).

Although the role of ARA and EPA on steroidogenesis seems to be mainly mediated by their role in eicosanoid production, Ganga et al. ( Reference Ganga, Tort and Acerete 21 ) suggested other mechanisms for the role of DHA in the release of cortisol from inter-renal cells in sea bream. The utilisation of indomethacin, an inhibitor of COX activity, did not affect the release of cortisol from head kidney of sea bream in a DHA-enriched medium. DHA has been described to reduce PGF2-α, a PG which has been proved to modulate the expression of StAR( Reference Fiedler, Plouffe and Hales 69 ). DHA can also modulate steroidogenesis through its role as a PPAR-α activator( Reference Zúñiga, Cancino and Medina 70 ) and steroidogenic factor 1 (SF-1)( Reference Jump, Botolin and Wang 71 , Reference Honkakoski and Negishi 72 ), that in turn modulate genes involved in the stress response such as StAR, among others( Reference Pavlikova, Kortner and Arukwe 73 ). DHA can also influence steroidogenesis through its role as a regulator of intracellular Ca( Reference Bonin and Khan 74 ). The increase in intracellular Ca2+, either released from intracellular stores or by mobilisation from extracellular spaces, is known to play an important role in steroidogenesis( Reference Stocco, Wang and Jo 3 ).

In the present study, there was a clear effect of DHA on the expression of c-fos. C-fos expression significantly increased 5-fold after 20 min of stress when compared with control. C-fos is a member of the AP-1 response elements( Reference Karin, Liu and Zandi 75 ). The role of AP-1 response elements on steroidogenesis has been described in mammals. In the adult rat, it has been proved that c-fos mRNA and FOS protein are reliable indices of adrenocortical activation( Reference Okimoto, Blaus and Schmidt 76 ). C-fos overexpression in Y1 adrenal cells led to a decrease in StAR gene promoter activity( Reference Shea-Eaton, Sandhoff and Lopez 29 ), whereas in contrast, overexpression of c-fos enhanced steroidogenesis in MA-10 cells by increasing StAR gene expression and interaction with transcription factors such as SF-1 to regulate steroidogenesis( Reference Wooton-Kee and Clark 77 ), acting as an endogenous promoter( Reference Rincon Garriz, Suarez and Capponi 78 ). The role of c-fos in steroidogenesis has been proved to be cAMP activation independent( Reference Rincon Garriz, Suarez and Capponi 78 ), suggesting the possible action of DHA on steroidogenesis through mechanisms other than the COX-2 pathway, as pointed out by Ganga et al. ( Reference Ganga, Tort and Acerete 21 ). As far as we know, this is the first time that c-fos expression has been related to the stress response and fatty acids in European sea bass and even fish. The clear effect found for the DHA treatment together with the increase also seen in the ARA and ALA treatments indicate different ways of modulation of cortisol release from the inter-renal cells of marine fish. Further studies must be conducted to clarify the specific role of c-fos in vivo when feeding marine fish with diets containing different type of oils.

Fatty acids may affect not only cholesterol transportation through the mitochondrial membrane, but also through the metabolic pathway of cholesterol to produce steroids. Interestingly, oxidative stress has been shown to alter steroidogenesis by producing inappropriate StAR-mediated trafficking of peroxidised cholesterol in streroidogenic tissues, resulting in damage and dysfunction in mitochondria( Reference Koritowski, Rodriguez-Agudo and Pilat 79 ). In the present study, all the indicators of oxidative stress measured remained unaltered within all the experiment, values obtained for each treatment being equal to the control values, and thus any possible effect of oxidative-induced metabolites of any of the fatty acid used within the study can be rejected.

There are few data on how fatty acids modulate the expression of cytochromes related to cortisol synthesis, the so-called CYP11, that have been described in several fish species( Reference Uno, Ishizuka and Itakura 80 ) including European sea bass( Reference Socorro, Martins and Deloffre 81 ). As far as we know, there are no previous studies on the 11β-hydroxylase (CYP11b) mRNA of European sea bass. Aluru & Vijayan( Reference Aluru and Vijayan 82 ) reported an increase of 11β-hydroxylase mRNA abundance together with plasma cortisol concentration, in groups of rainbow trout in response to 1 h of handling, and preceded the rise of cortisol level in zebrafish (Danio rerio) embryos( Reference Alsop and Vijayan 83 ), establishing that CYP11β expression reacts to stressful stimuli to synthesise cortisol. Although no evidence has been found on the role of dietary fatty acids on the expression of cytochrome genes in fish, it has been demonstrated that the gene expression of 17α-hydroxylase, a member of cytochrome P450 which participates in the cortisol pathway, is down-regulated in mice fed with a high-fish oil diet( Reference Takahashi, Tsuboyama-Kasaoka and Nakatani 84 ). Within the present study we found an increase (7-fold) in CYP11b gene expression in head kidney from the ARA treatment after 20 min of ACTH stimulation. Besides, head kidney from both the DHA and ALA treatments also showed an increased (2-fold) gene expression in CYP11b when compared with the control group. These results correspond to those groups in which c-fos expression is also increased. More studies are required to obtain information in vitro and in vivo on the role of fatty acids in the expression of the different CYP, since not only CYP11b determines steroidogenesis( Reference Uno, Ishizuka and Itakura 80 ).

Finally, within the present study, no effects of the different fatty acid used were found on glucocorticoid receptor gene expression. There is not so much information on the role of fatty acids as modulators of GR expression. Feeding soyabean oil has been found to affect glucocorticoid receptors in mice( Reference Oarada, Gonoi and Tsuzuki 45 ), whereas Benitez-Dorta et al. ( Reference Benitez-Dorta, Caballero and Izquierdo 22 ) found a marked effect of the type of dietary oils on the expression of GR genes in different tissues of Senegalese sole. Those authors found a reduction in the stress-induced increase of liver GR genes in Senegalese sole fed a vegetable oil-based diet in comparison with fish oil-fed sole. In muscle, feeding vegetable oils, particularly soyabean oil, caused an over-expression of the GR2 gene in response to chasing stress. Besides, Benitez-Dorta et al. ( Reference Benitez-Dorta, Caballero and Izquierdo 22 ) found that the use of dietary vegetable oils in Senegalese sole reduced the gene expression of HSP90AB in muscle and HSP70 in intestine. HSP70 gene expression has been reported to be regulated by other dietary factors such as starvation( Reference Cara, Alaru and Moyano 85 ), energy restriction( Reference Heydari, Wu and Takahashi 86 ) or arginine supplementation( Reference Wu, Ruan and Gao 87 ). PUFA, and specifically DHA and ARA, have been shown to enhance the heat-induced stress response in rainbow trout (Oncorhynchus mykiss) leucocytes( Reference Samples, Pool and Lumb 47 ), whereas an increased gene expression of HSP90 has been also found in the liver of rainbow trout fed alternative diets containing soyabean meal( Reference Sealey, Barrows and Smith 88 ).

In the present experiment, no effects were detected on HSP90 gene expression, and, interestingly, the present results showed a significantly increased HSP70 gene expression in all the fatty acid treatments except the ARA treatment. ARA has been described as a potent modulator of HSP in humans( Reference Jurivich, Sistonen and Sarge 46 ), through the activation of heat shock factor, being ARA metabolites, and specially PGE2, was more related to the HSP activation( Reference Shah, Tulapurkar and Singh 89 ). Jurivich et al. ( Reference Jurivich, Sistonen and Sarge 46 ) demonstrated that 20 µm-ARA was enough to activate HSP72 expression at 37°C in HeLa cells, but ARA concentration up to 20 µm had no effect on reported activity in the absence of heat shock( Reference Shah, Tulapurkar and Singh 89 ), demonstrating that the effect of ARA is dose dependent. This could be in agreement with the results obtained in the present experiment, if we consider that the exposure of head kidney to a medium enriched with ARA in the doses used in this experiment could be exceeding the concentration required for HSP gene expression activation, whereas the rest of the treatments showed an effect. It must be taken into consideration that the present study was conducted on the head kidney. The complexity of this tissue, with immune cells associated, inter-renals and other constitutive and renal tissues associated. Further experiments are required to elucidate the effect of fatty acids in the activation of HSP and GR in other target tissues for cortisol action.

In conclusion, the results obtained in the present study showed a clear modulation of different fatty acids on cortisol release from European sea bass, partly mediated by the effects on the expression of stress-related genes. Further studies are needed to elucidate the role of those fatty acids as effectors on the expression of stress-related genes in vivo, feeding animals different type of oils and levels of essential fatty acids in the diet. However, with the present results we corroborate previous results indicating that ALA increases basal and post-stress cortisol in marine fish, clarifying that the ALA-induced elevation of cortisol release from the inter-renal cells can be mediated by different pathways and effects on different genes. Whether the increased amount of cortisol from the ALA treatment is due to an addition of different effects remains unclear, but induction of StAR and c-fos clearly increased the ACTH-induced cortisol release from head kidney enriched with ALA.

As far as we know, this is the first time that c-fos expression has been studied in European sea bass or even in any fish species, associated with different fatty acids and the stress response. The clear results obtained by DHA treatment explains a previous hypothesis on the role of DHA as a modulator of the release of cortisol, proposed to be independent of the COX-2 pathway. The use of c-fos as a bioindicator of fatty acid-mediated modulation of cortisol release is still premature, but the present results indicated the potential use of this indicator in fatty acid studies. Further experiments need to be conducted in vivo to clarify this. The same can be proposed for the effect of ARA on the expression of CYP11b. As this cytochrome modulates the final step in the cortisol synthesis pathway, its potential use as a bioindicator of ARA-mediated stress needs to be studied in vivo.

Acknowledgements

The present study is a contribution to a European Union-funded project (ARRAINA: Advanced Research Initiatives for Nutrition and Aquaculture, KBBE-2011-288925).

D. M. formulated the research question(s), designed the study, carried it out, analysed the data and wrote the article. G. T. analysed the data and wrote the article. S. R. analysed the data and wrote the article. L. T. designed the study, analysed the data and wrote the article. D. N. carried out the study. M. J. Z. formulated the research questions, designed the study, analysed the data and wrote the article. M. I. formulated the research questions, designed the study and wrote the article.

There are no conflicts of interest.

References

1. Aluru, N & Viyajan, MM (2009) Stress transcriptomics in fish: a role for genomic cortisol signaling. Gen Comp Endocrinol 164, 142150.Google Scholar
2. Wendelaar Bonga, SE (1997) The stress response in fish. Physiol Rev 77, 591625.Google Scholar
3. Stocco, DM, Wang, X, Jo, Y, et al. (2005) Multiple signaling pathways regulation steroidogenesis and steroidogenic acute regulatory protein expression: more complicated than we thought. Mol Endocrinol 19, 26472659.Google Scholar
4. Kloas, W, Reinecke, M & Hanke, W (1994) Role of the atrial matriuretic peptid for adrenal regulation in teleost fish Cyprinus carpio . Am J Physiol 267, R1034R1042.Google Scholar
5. Jiang, JQ, Young, G, Kobayashi, T, et al. (1998) Eel (Anguilla japonica) testis 11β-hydroxylase gene is expressed in interrenal tissue and its product lacks aldosterone synthesizing activity. Mol Cell Endocrinol 146, 207211.CrossRefGoogle ScholarPubMed
6. Montero, D, Kalinowski, T, Obach, A, et al. (2003) Vegetable lipid sources for gilthead sea bream (Sparus aurata): effects on fish health. Aquaculture 225, 353370.Google Scholar
7. Oxley, A, Jolly, C, Eide, T, et al. (2010) The combined impact of plant-derived dietary ingredients and acute stress on the intestinal arachidonic acid cascade in Atlantic salmon (Salmo salar). Br J Nutr 103, 851861.CrossRefGoogle ScholarPubMed
8. Ganga, R, Montero, D, Bell, JG, et al. (2011) Stress response in sea bream (Sparus aurata) held under crowded conditions and fed diets containing linseed and/or soybean oil. Aquaculture 311, 215223.CrossRefGoogle Scholar
9. Ganga, R, Bell, JG, Montero, D, et al. (2011) Adrenocorticotrophic hormone-stimulated cortisol release by head kidney inter-renal tissue from sea bream (Sparus aurata) fed with linseed oil and soybean oil. Br J Nutr 105, 238247.Google Scholar
10. Tacon, AGJ & Metian, M (2008) Global overview on the use of fish meal and fish oil in industrially compounded aquafeeds: trends and future prospects. Aquaculture 285, 146158.Google Scholar
11. Turchini, GM, Torstensen, BE & Ng, WK (2009) Fish oil replacement in finfish nutrition. Rev Aquac 1, 1057.CrossRefGoogle Scholar
12. Sales, J & Glencross, B (2010) A meta-analysis of the effects of dietary marine oil replacement with vegetable oils on growth, feed conversion and muscle fatty acid composition of fish species. Aquac Nutr 17, e271e287.CrossRefGoogle Scholar
13. Montero, D & Izquierdo, MS (2010) Welfare and health of fish fed vegetable oils as alternative lipid sources to fish oil. In Fish Oil Replacement and Alternative Lipid Sources in Aquaculture Feeds, pp. 439486 [Turchini, G, Ng, W and Tocher, D, editors]. Cambridge, UK: CRC Press.Google Scholar
14. Montero, D, Mathlouthi, F, Tort, L, et al. (2010) Replacement of dietary fish oil by vegetable oils affects humoral immunity and expression of pro-inflammatory cytokines genes in gilthead sea bream. Fish Shellfish Immunol 29, 10731081.Google Scholar
15. Jutfelt, F, Olsen, RE, Bjornsson, BT, et al. (2007) Parr–smolt transformation and dietary vegetable lipids affect intestinal nutrient uptake, barrier function and plasma cortisol levels in Atlantic salmon. Aquaculture 273, 298311.Google Scholar
16. Montero, D, Tort, L, Izquierdo, MS, et al. (1998) Depletion of serum alternative complement pathway activity in gilthead sea bream caused by α tocopherol and n-3 HUFA dietary deficiencies. Fish Physiol Biochem 18, 399407.CrossRefGoogle Scholar
17. Koven, W, Barr, Y, Lutzky, S, et al. (2001) The effect of dietary arachidonic acid (20:4n-6) on growth, survival and resistance to handling stress in gilthead seabream (Sparus aurata) larvae. Aquaculture 193, 107122.Google Scholar
18. Koven, W, Van Anholt, R, Lutzky, S, et al. (2003) The effect of arachidonic acid on growth, survival, and cortisol levels in different-age gilthead sea bream larvae (Sparus aurata) exposed to handling or daily salinity change. Aquaculture 228, 307320.Google Scholar
19. Van Anholt, R, Koven, W, Lutzky, S, et al. (2004) Dietary supplementation with arachidonic acid alters the stress response of gilthead seabream (Sparus aurata) larvae. Aquaculture 238, 369383.CrossRefGoogle Scholar
20. Alves Martins, D, Rocha, F, Castanheira, F, et al. (2013) Effects of dietary arachidonic acid on cortisol production and gene expression in stress response in Senegalese sole (Solea senegalensis) post larvae. Fish Physiol Biochem 39, 12231238.Google Scholar
21. Ganga, R, Tort, L, Acerete, L, et al. (2006) Modulation of ACTH-induced cortisol release by polyunsaturated fatty acids in interrenal cells from gilthead seabream. J Endocrinol 190, 3945.Google Scholar
22. Benitez-Dorta, V, Caballero, MJ, Izquierdo, MS, et al. (2013) Total substitution of fish oil by vegetable oils in Senegalese sole (Solea senegalensis) diets: effects on fish performance, biochemical composition, and expression of some glucocoticoid receptor-related genes. Fish Physiol Biochem 39, 335349.Google Scholar
23. Wang, XJ, Dyson, MT, Jo, Y, et al. (2003) Involvement of 5-lipoxygenase metabolites of arachidonic acid in cyclic AMP-stimulated steroidogenesis and steroidogenic acute regulatory protein gene expression. J Steroid Biochem Mol Biol 85, 159166.Google Scholar
24. Wang, XJ, Dyson, MT, Jo, Y, et al. (2003) Inhibition of cyclooxygenase-2 activity enhances steroidogenesis and steroidogenic acute regulatory gene expression in MA-10 mouse Leydig cells. Endocrinology 144, 33683375.Google Scholar
25. Wang, X, Shen, CL, Dyson, MT, et al. (2006) The involvement of epoxygenase metabolites of arachidonic acid in cAMP-stimulated steroidogenesis and streoidogenic acute regulatory protein gene expression. J Endocrinol 190, 871878.CrossRefGoogle ScholarPubMed
26. Cooke, M, Di Cónsoli, H, Malboreti, P, et al. (2013) Expression and function of OEX receptor, an eicosanoid receptor, in steroidogenic cells. Mol Cell Endocrinol 371, 7178.Google Scholar
27. Chin, EC, Naddafy, JM, Cheng, Z, et al. (2006) Dietary polyunsaturated fatty acid supplementation in vivo modulates ovine adrenal steroidogenesis in vitro . Endocr Abstr 11, 750.Google Scholar
28. Hodges, LM, Chin, EC, Naddafy, JM, et al. (2006) Polyunsaturated fatty acids in vivo and in vitro affect expression of steroidogenic acute regulatory protein in steroidogenic tissues. Endocr Abstr 12, 98.Google Scholar
29. Shea-Eaton, W, Sandhoff, TW, Lopez, D, et al. (2002) Transcriptional repression of the rat steroidogenic acute regulatory (StAR) protein gene by the AP-1 family member c-Fos. Mol Cell Endocrinol 188, 161170.Google Scholar
30. Sato, M, Severinghaus, JW & Basbaum, AI (1992) Medullary CO2 chemoreceptor neuron identification by c-fos immunocytochemistry. J Appl Physiol 73, 96100.CrossRefGoogle ScholarPubMed
31. Curran, T & Franza, B Jr (1988) Fos and Jun: the AP-1 connection. Cell 55, 395397.Google Scholar
32. Tankersley, CG, Haxhiu, MA & Gauda, EB (2002) Differential CO2-induced c-fos gene expression in the nucleus tractus solitarii of inbred mouse strains. J Appl Physiol 92, 12771284.CrossRefGoogle Scholar
33. Teppema, LJ, Veening, JG, Kranenburg, A, et al. (1997) Expression of c-fos in the rat brainstem after exposure to hypoxia and to normoxic and hyperoxic hypercapnia. J Comp Neurol 388, 169190.3.0.CO;2-#>CrossRefGoogle ScholarPubMed
34. Pete, G, Mack, SO, Haxhiu, MA, et al. (2002) CO2-induced c-fos expression in brainstem preprotachynin mRNA containing neurons. Respir Physiol Neurol 130, 265274.Google Scholar
35. Matsuoka, I, Fuyuki, K, Shoji, T, et al. (1998) Identification of c-fos related genes and their induction by neural activation in rainbow trout brain. Biochim Biophys Acta 1395, 220227.Google Scholar
36. Trower, MK, Orton, SM, Purvis, IJ, et al. (1996) Conservation of synteny between the genome of the pufferfish (Fugu rubripes) and the region on human chromosome 14 (14q24·3) associated with familiar Alzheimer disease (AD3 locus). Proc Natl Acad Sci U S A 93, 13661369.Google Scholar
37. Li, Y, Kim, I, Kim, YJ, et al. (2004) Cloning and sequence analysis of the self-fertilizing fish Rivulus marmoratus immediate early gene c-fos . Mar Environ Res 58, 681685.Google Scholar
38. Rimoldi, S, Terova, G, Brambilla, F, et al. (2009) Molecular characterizaton and expression analysis of Na+/H+ exchanger (NHE)-1 and c-Fos genes in sea bass (Dicentrarchus labrax, L) exposed to acute and chronic hypercapnia. J Exp Mar Biol Ecol 375, 3240.CrossRefGoogle Scholar
39. Mommsen, TP, Vijayan, MM & Moon, TW (1999) Cortisol in teleosts: dynamics, mechanisms of action, and metabolic regulation. Rev Fish Biol Fish 9, 211268.Google Scholar
40. Pratt, WB & Toft, DO (1997) Steroid receptor interactions with heat shock protein and immunophilin chaperones. Endocr Rev 18, 306360.Google Scholar
41. Vijayan, MM, Prunet, P & Boone, AN (2005) Xenobiotic impact on corticosteroid signaling. In Biochemical and Molecular Biology of Fishes Environmental Toxicology, vol. 6, pp. 365394 [Moon, TW and Mommsen, TP, editors]. Amsterdam: Elsevier.Google Scholar
42. Terova, G, Gornati, R, Rimoldi, S, et al. (2005) Quantification of a glucocorticoid receptor in sea bass (Dicentrarchus labrax, L.) reared at high stocking density. Gene 357, 144151.CrossRefGoogle ScholarPubMed
43. Roberts, RJ, Agius, C, Saliba, C, et al. (2010) Heat shock proteins (chaperones) in fish and shellfish and their potential role in relation to fish health: a review. J Fish Dis 33, 789801.Google Scholar
44. Ranhotra, HS & Sharma, R (2004) Polyunsaturated fatty acids inhibit mouse hepatic glucocorticoid receptor activation in vitro . Indian J Biochem Biophys 41, 246249.Google ScholarPubMed
45. Oarada, M, Gonoi, T, Tsuzuki, T, et al. (2007) Effect of dietary oils on lymphocyte immunological activity in psychologically stressed mice. Biosci Biotechnol Biochem 71, 174182.CrossRefGoogle ScholarPubMed
46. Jurivich, DA, Sistonen, L, Sarge, KD, et al. (1994) Arachidonate is a potent modulator of human heat-shock gene transcription. Proc Natl Acad Sci U S A 91, 22802284.Google Scholar
47. Samples, BL, Pool, GL & Lumb, RH (1999) Polyunsaturated fatty acids enhance the heat induced stress response in rainbow trout (Oncorhynchus mykiss) leukocytes. Comp Biochem Physiol Part B: Biochem Mol Biol 123, 389397.Google Scholar
48. Varsamos, S, Flik, G, Pepin, JF, et al. (2006) Husbandry stress during early life stages affects the stress response and health status of juvenile sea bass, Dicentrarchus labrax. Fish Shellfish Immunol 20, 8396.Google Scholar
49. Rotllant, J, Balm, PHM, Pérez-Sánchez, J, et al. (2001) Pituitary and interrenal function in gilthead sea bream (Sparus aurata L., Teleostei) after handling and confinement stress. Gen Comp Endocrinol 121, 333342.CrossRefGoogle ScholarPubMed
50. Rotllant, J, Balm, PHM, Ruane, NM, et al. (2000) Pituitary proopiomelanocortin-derived peptides and hypothalamus–pituitary–interrenal axis activity in gilthead sea bream (Sparus aurata) during prolonged crowding stress: differential regulation of adrenocorticotropin hormone and α-melanocyte-stimulating hormone release by corticotropin-releasing hormone and thyrotropin-releasing hormone. Gen Comp Endocrinol 119, 152163.Google Scholar
51. Van Anolt, RD, Spanings, FAT, Nixon, O, et al. (2012) The effects of arachidonic acid on the endocrine and osmoregulatory response of tilapia (Oreochromis mossambicus) acclimated to seawater and subjected to confinement stress. Fish Physiol Biochem 38, 703713.Google Scholar
52. Alves Martins, D, Rocha, F, Martínez-Rodriguez, G, et al. (2012) Teleost fish larvae adapt to dietary arachidonic acid supply through modulation of the expression of lipid metabolism and stress genes. Br J Nutr 108, 864874.Google Scholar
53. Lund, I & Steenfeldt, TD (2011) The effects of dietary long-chain essential fatty acids on growth and stress tolerance in pikeperch larvae (Sander lucioperca L.). Aquac Nutr 17, 191199.Google Scholar
54. Atalah, E, Hernández-Cruz, CM, Ganuza, E, et al. (2011) Importance of dietary arachidonic acid for the growth, survival and stress resistance of larval European sea bass (Dicentrarchus labrax) fed high dietary docosahexaenoic and eicosapentaenoic acids. Aquac Res 42, 12611268.Google Scholar
55. Yehuda, S, Rabidovitz, S, Carasso, RL, et al. (2000) Fatty acid mixture counters changes in cortisol, colesterol and impairs learning. Int J Neurosci 101, 7387.Google Scholar
56. Wonnacott, KE, Kwong, WY, Hughes, J, et al. (2010) Dietary omega-3 and -6 polyunsaturated fatty acids affect the composition and development of sheep granulosa cells, oocyte and embryos. Reproduction 139, 5769.CrossRefGoogle ScholarPubMed
57. Hughes, J, Kwong, WY, Li, D, et al. (2011) Effects of omega-3 and -6 polyunsaturated fatty acids on ovine follicular cell steroidogenesis, embryo development and molecular markers of fatty acid metabolism. Reproduction 141, 105118.CrossRefGoogle ScholarPubMed
58. Reinhart, AJ, Williams, SC & Stocco, DM (1999) Transcriptional regulation of the StAR gene. Mol Cel Endocrinol 151, 114121.CrossRefGoogle ScholarPubMed
59. Wang, XJ, Dyson, MT, Mondillo, C, et al. (2002) Interaction between arachidonic acid and cAMP signaling pathways enhances steroidogenesis and StAR gene expression in MA-10 Leydig tumor cells. Mol Cel Endocrinol 188, 5563.Google Scholar
60. Wang, XJ, Walsh, LP, Reinhart, AJ, et al. (2000) The role of arachidonic acid in steroidogenesis and steroidogenic acute regulatory (StAR) gene and protein expression. J Biol Chem 275, 2020420209.Google Scholar
61. Castillo, J, Castellana, B, Acerete, L, et al. (2008) Stress-induced regulation of steroidogenic acute regulatory protein expression in head kidney of gilthead seabream (Sparus aurata). J Endocrinol 196, 313322.Google Scholar
62. Ringbom, T, Huss, U, Stenholm, A, et al. (2001) COX-2 inhibitory effects of naturally occurring and modified fatty acids. J Nat Prod 64, 745749.Google Scholar
63. Laneuville, O, Breuer, DK, Xu, N, et al. (1995) Fatty acid substrate specificities of human prostaglandin-endoperoxide H synthase-1 and -2. Formation of 12-hydroxy-(9Z, 13E/Z, 15Z)-octadecatrienoic acids from α-linolenic acid. J Biol Chem 270, 1933019336.Google Scholar
64. Shridas, P, Bailey, WH, Boyanovsky, BB, et al. (2010) Group X secretory phospholipase A2 regulates the expression of steroidogenic acute regulatory protein (StAR) in mouse adrenals. J Biol Chem 285, 2003120039.Google Scholar
65. Maloberti, P, Mele, PG, Neuman, J, et al. (2000) Regulation of arachidonic acid release in steroidogenesis: role of a new acyl-CoA thioesterase (ARTISt). Endocr Res 26, 55995607.Google Scholar
66. Nasushita, R, Watanobe, H & Takebe, K (1997) A comparative study of adrenocorticotropin-releasing activity of prostaglandins E1, E2, F and D2 in the rat. Prostaglandins Leukot Essent Fatty Acids 56, 165168.Google Scholar
67. Gobbetti, A & Zerani, M (1993) Prostaglandin E2 and prostaglandin F2α involvement in the corticosterone and cortisol release by the female frog, Rana esculenta, during ovulation. J Exp Zool 267, 164170.CrossRefGoogle ScholarPubMed
68. Van Anholt, R.D, Spanings, FA, Koven, WM, et al. (2004) Dietary supplementation with arachidonic acid in tilapia (Oreochromis mossambicus) reveals physiological effects not mediated by prostaglandins. Gen Comp Endocrinol 139, 215226.Google Scholar
69. Fiedler, EP, Plouffe, L, Hales, DB, et al. (1999) Prostaglandin F induces a rapid decline in progesterone production and stroidogenic acute regulatory protein expression in isolated rat corpus luteum without altering messenger ribonucleic acid expression. Biol Reprod 61, 643650.Google Scholar
70. Zúñiga, J, Cancino, M, Medina, F, et al. (2011) n-3 PUFA supplementation triggers PPAR-a activation and PPAR-a/NF-kB interaction: anti-inflammatory implications in liver ischemia–reperfusion injury. PLoS ONE 6, e28502.Google Scholar
71. Jump, DB, Botolin, D, Wang, Y, et al. (2008) Docosahexaenoic acid (DHA) and hepatic gene transcription. Chem Phys Lipids 153, 313.Google Scholar
72. Honkakoski, P & Negishi, M (2000) Regulation of cytochrome P450 (CYP) genes by nuclear receptors. Biochem J 347, 321337.Google Scholar
73. Pavlikova, N, Kortner, TM & Arukwe, A (2010) Modulation of acute steroidogenesis, peroxisome proliferator-activated receptors and CYP3A/PXR in salmon interrenal tissues by tributylin and the second messenger activator, forskolin. Chem-Biol Interact 185, 119127.Google Scholar
74. Bonin, A & Khan, NA (2000) Regulation of calcium signaling by docosahexaenoic acid in human T-cells: implication of CRAC channels. J Lipid Res 41, 277284.Google Scholar
75. Karin, M, Liu, Z & Zandi, E (1997) Ap-1 function and regulation. Curr Opin Cell Biol 9, 240246.CrossRefGoogle ScholarPubMed
76. Okimoto, DK, Blaus, A, Schmidt, M, et al. (2002) Differential expression of c-fos and tyrosine hydroxylase mRNA in the adrenal gland of the infant rat: evidence for an adrenal hyporesponsive period. Endocrinology 143, 17171725.Google Scholar
77. Wooton-Kee, CR & Clark, BJ (2000) Steroidogenic factor-1 influences protein–deoxyribonucleic acid interactions within the cyclic adenosine 3,5-monophosphate-responsive regions of the murine steroidogenic acute regulatory protein gene. Endocrinology 141, 13451355.Google Scholar
78. Rincon Garriz, JM, Suarez, C & Capponi, A (2009) C-fos mediates angiotensin II-induced aldosterone production and protein synthesis in bovine adrenal glomerulosa cells. Endocrinology 150, 12941302.Google Scholar
79. Koritowski, W, Rodriguez-Agudo, D, Pilat, A, et al. (2010) StARD4-mediated translocation of 7-hydroperoxycholesterol to isolated mitochondria: deleterious effects and implications for steroidogenesis under oxidative stress conditions. Biochem Biophys Res Commun 392, 5862.Google Scholar
80. Uno, T, Ishizuka, M & Itakura, T (2012) Cytochorme p450 (CYP) in fish. Env Tox Pharmacol 34, 113.Google Scholar
81. Socorro, S, Martins, RS, Deloffre, L, et al. (2007) A cDNA for European sea bass (Dicentrarchus labrax) 11β-hydroxylase: gene expression during the thermosensitive period and gonadogenesis. Gen Comp Endocrinol 150, 164173.Google Scholar
82. Aluru, N & Vijayan, MM (2006) Aryl hydrocarbon receptor activation impairs cortisol response to stress in rainbow trout by disrupting the rate-limiting steps in steroidogenesis. Endocrinology 147, 18951903.Google Scholar
83. Alsop, D & Vijayan, MM (2008) Development of the corticosteroid stress axis and receptor expression in zebrafish. Am J Physiol Reg Integr Comp Physiol 294, R711R719.Google Scholar
84. Takahashi, M, Tsuboyama-Kasaoka, N, Nakatani, T, et al. (2002) Fish oil feeding alters liver gene expressions to defend against PPARα activation and ROS production. Am J Physiol 282, G338G348.Google Scholar
85. Cara, JB, Alaru, N, Moyano, FJ, et al. (2005) Food-deprivation induces HSP70 and HSP90 protein expression in larval gilthead sea bream and rainbow trout. Comp Biochem Physiol 142, 426431.Google Scholar
86. Heydari, AR, Wu, B, Takahashi, R, et al. (1993) Expression of heat shock protein 70 is altered by age and diet at the level of transcription. Mol Cel Biol 13, 29092918.Google Scholar
87. Wu, X, Ruan, Z, Gao, Y, et al. (2010) Dietary supplementation with l-arginine or n-carbamylglutamate enhances intestinal growth and heat shock protein-70 expression in weanling pigs fed a corn- and soybean meal-based diet. Amino Acids 39, 831839.Google Scholar
88. Sealey, WM, Barrows, FT, Smith, CE, et al. (2010) Dietary supplementation strategies to improve performances of rainbow trout Oncorhynchus mykiss fed plant-based diets. Bull Fish Res Agen 31, 1523.Google Scholar
89. Shah, NG, Tulapurkar, ME, Singh, IS, et al. (2010) Prostaglandin E2 potentiates heat shock-induced heat shock-induced heat shock protein 72 expression in A549 cells. Prostaglandins Other Lipid Mediat 93, 17.Google Scholar
Figure 0

Table 1. Sequences of primers used to synthesise standard mRNA

Figure 1

Table 2. Primers and probes for quantitative real-time PCR

Figure 2

Fig. 1. Absolute cortisol secretion by European sea bass (Dicentrarchus labrax) head kidney (HK) after adrenocorticotrophin hormone (ACTH) stimulation following incubation with highly unsaturated fatty acids (FA): EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA). a,b,c Different letters for a given time indicate significant differences (P < 0·05).

Figure 3

Fig. 2. Expression levels of the steroidogenic acute regulatory protein (StAR) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. StAR mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. a,b Different letters for a given time indicate significant differences (P < 0·05).

Figure 4

Fig. 3. Expression levels of the c-fos gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. c-fos mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. Differences were determined by one-way ANOVA and each time point was analysed separately. A post hoc test was applied (Tukey). a,b,c Different letters indicate significantly different means from controls, for the time point tested (P < 0·01).

Figure 5

Fig. 4. Expression levels of the cytochrome P450 11β (CYP11b) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. CYP11b mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. Differences were determined by one-way ANOVA and each time point was analysed separately. A post hoc test was applied (Tukey). a,b,c Different letters indicate significantly different means from controls, for the time point tested (P < 0·01).

Figure 6

Fig. 5. Expression levels of the glucocorticoid receptor (GR) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. GR mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean.

Figure 7

Fig. 6. Expression levels of the heat shock protein 90 (HSP90) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. HSP90 mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean.

Figure 8

Fig. 7. Expression levels of the heat shock protein 70 (HSP70) gene measured by real-time PCR in Dicentrarchus labrax head kidney cells in the course of the perfusion trial. HSP70 mRNA copy number was normalised as a ratio to 100 ng total RNA. Cells were sampled after the stabilisation period (0 h), 60 min after highly unsaturated fatty acids (FA) incubation (EPA, DHA, arachidonic acid (ARA), linoleic acid (LA) and α-linolenic acid (ALA)), 20 min after adrenocorticotrophin hormone (ACTH) stimulation, and then sequentially at 40, 60, 110, 160 and 250 min following the ACTH pulse. The means of three replicates in each sampling point are shown. Bars indicate standard error of the mean. Differences were determined by one-way ANOVA and each time point was analysed separately. A post hoc test was applied (Tukey). a,b,c,dDifferent letters indicate significantly different means from controls, for the time point tested (P < 0·01).