Diets and feed production

Two casein/gelatin-purified diets were prepared at our laboratory. Table 1 summarises the ingredients used, proximate composition, and mycotoxin and pesticide content. Seeds from maize MON 810 (Bt) and the unmodified parent line (nBt) (PR34N44 and PR34N43, respectively; Pioneer HiBred) were grown simultaneously in neighbouring fields in 2007 in Valtierra, Navarra, Spain. These two maize lines have been thoroughly described by Walsh et al. ⁽Reference Walsh, Buzoianu and Gardiner¹⁸⁾ and reported to have only minor differences in proximate and nutrient composition. The preparation of diets involved mixing three different fractions. Gelatin and carophyll pink were dissolved in hot water, at a 9:1 ratio (hot water (about 80°C)–gelatin, w/w), before all the dry ingredients and the oil mixture were carefully added. The blend was mixed in a conventional food processor until becoming homogenous. The paste was poured onto labelled parchment-covered trays and then dried overnight at low temperatures (40°C) in an oven, before grinding, sieving and storing at − 18°C. The same diets were fed to the parental generation (F0) and offspring generation (F1).

Table 1 Formulation and proximate composition of the experimental diets including the content of mycotoxins, the presence of the crystal protein 1Ab (Cry1Ab) protein and pesticide residues

nBt, non-Bacillus thuringiensis; Bt, Bacillus thuringiensis; AA, amino acids; DON, deoxynivalenol; NIV, Nivalenol.

* 60 % Dicalcium phosphate dehydrate, 0·01 % cobalt chloride hexahydrate, 0·04 % copper sulphate, 30 % potassium sulphate, 0·1 % potassium iodide, 2 % magnesium sulphate heptahydrate, 0·1 % manganese sulphate, 5·75 % NaCl, 0·01 % sodium selenite, 1 % zinc sulphate heptahydrate, and 1 % iron sulphate heptahydrate.

† 0·1 % Vitamin A, 0·04 % vitamin D₃, 2 % vitamin E, 0·1 % vitamin K, 4·3 % vitamin C, 40 % choline, 0·15 % thiamin, 0·19 % riboflavin, 0·2 % pyridoxine, 2 % niacin, 4 % inositol, 0·07 % folic acid, 0·6 % calcium pantothenate, 0·75 % biotin, 0·3 % cobalamin and 45·2 % casein salt.

‡ 4·3 % Taurine, 21·4 % aspartic acid, 6·4 % threonine, 8·5 % glycine, 15·2 % alanine, 4·3 % valine, 5·8 % methionine, 4·3 % isoleucine, 8·5 % leucine, 6·4 % lysine, 8·5 % arginine and 6·4 % tryphtophan.

§ Mycotoxin content in the feed is calculated based on the levels found in the ingredients. Mycotoxins below the detection limit: diacetoxyscirpenol < 10 μg/kg; 3-acetyldeoxynivalenol < 10 μg/kg; 15-acetyldeoxynivalenol < 10 μg/kg; T2 toxin and HT2 toxin < 10 μg/kg; aflatoxin G1 < 0·1 μg/kg; aflatoxin G2 < 0·1 μg/kg.

∥ An array of more than 300 pesticides were analysed in the two diets (Bioforsk), and only diphenylamine was detected above the limit of quantification.

Diet chemical analysis

Moisture in the diets was measured by drying at 103°C for 24 h, ash was weighed after burning at 540°C, and lipid content was measured after extraction with ethyl acetate⁽Reference Lie and Lambertsen¹⁹⁾. N content was measured using a nitrogen determinator (LECO FP-428; LECO Corporation) according to the AOAC (Association of Analytical Communities) official methods of analysis, and crude protein content was calculated as N × 6·25. Starch content was measured by enzymatic degradation as described by Hemre et al. ⁽Reference Hemre, Lie and Lied²⁰⁾. Mycotoxin levels in the experimental diets were analysed by the Norwegian Veterinary Institute by GC–MS⁽Reference Langseth, Bernhoft and Rundberget²¹⁾. The content of Cry1Ab in the diets was tested using a commercially available qualitative Bt-Cry1Ab/1Ac ELISA kit (Agdia Biofords). The diets were analysed for pesticide residues by testing against a panel of more than 300 different active substances (BioForsk, Norwegian Institute for Agricultural and Environmental Research, Ås, Norway).

Fish husbandry and experimental design

The trials were conducted in accordance with the Norwegian Animal Welfare Act no. 73 of 20 December 1974 and the Regulation on Animal Experimentation of 15 January 1996. The experiments were run in an AHAB multiple rack zebrafish system (Aquatic habitats, Aquatic Eco-Systems) with reverse osmosis followed by automatic salt dosing of the water, UV, and mechanical and carbon filtration of the water. During the trials, the temperature was 28·5 ± 0·5°C, salinity was 500 ± 30 μS/cm, oxygen was >90 % saturation, photoperiod was 14 h light–10 h dark with lights on from 22.00 to 08.00 hours. Larvae were fed ad libitum with Artemia nauplii for 1 month before starting the parental feeding trial (F0) on 7 February 2011. In this trial, 120 zebrafish larvae (35 d post-hatch, dph) were distributed into six tanks (3·0 litres, n 3) and randomly assigned to one of the following two diets: Bt-maize diet and nBt-maize diet. The offspring feeding trial (F1) was started on 3 October 2011 in which 168 zebrafish larvae (39 dph) obtained from the parental generation (fourth spawning) were distributed into twelve tanks (3·0 litres) and fed one of the following three regimens: Bt-maize diet Bt–Bt (larvae from the Bt-maize diet-fed parental generation, n 4); nBt-maize diet Bt–nBt (larvae from the Bt-maize diet-fed parental generation, n 3); nBt-maize diet nBt–nBt (larvae from the nBt-maize diet-fed parental generation, n 5). Fig. 1 presents an overview of the experimental design. Mortality was recorded on a daily basis. The parental generation feeding trial (F0) followed a restricted feeding regimen, where feeding was adjusted to the growing biomass in each tank and gradually reduced from 10 to 2–3 % of total biomass during the trial. The offspring generation feeding trial (F1) followed a pair-feeding regimen in which the fish tank that demonstrated the lowest feed intake determined the amount of feed offered to the other tanks. Within both the generations, fish in all tanks were given the same amount of feed twice a day and efforts were made to avoid feed waste by giving small portions. Feed particle size was gradually increased with increasing fish size from 315–400 μm up to 560–700 μm at the end of the feeding trial.

Fig. 1 Overview of the experimental design, time of sampling and age (days post-hatch; dph) of the zebrafish in the feeding trial. The parental zebrafish were fed Bt (Bacillus thuringiensis)-maize or nBt (non-Bt)-maize diets (n 3) for 45 and 283 d. The offspring generation (F1) were fed the same diets as those fed to their parents, Bt–Bt-maize (n 4) or nBt–nBt-maize (n 5), or cross-over Bt–nBt-maize (n 3) for 45 d. Data on parent fish (F0) fecundity were collected between 175 and 300 dph. F1 embryos (51 h post-fertilisation) and F1 larvae (4 dph) were collected for epigenetic analysis and swimming activity measurements, respectively.

Tissue sampling – parental generation

Before handling, all fish were euthanised by immersion in an ice water bath (4°C or less)⁽Reference Wilson, Bunte and Carty²²⁾. After 45 d of feeding, fish were sampled on 24 March 2011 (80 dph). Data on fish performance were recorded from seven to ten randomly selected fish per tank. All fish were wet weighed to the nearest 0·01 g, total length was determined to the nearest millimetre and sex was recorded. Blood was sampled from three to four fish per tank by cutting off the tail posterior to the anal fin and by collecting the blood into capillary tubes coated with heparin. For differential leucocyte counts, a small droplet of blood was placed at the end of a glass slide to produce smears before being fixed in methanol. The mid-intestine was obtained from four fish per tank and dissected using fine surgical tools under magnification before being quickly frozen in liquid N₂ and stored for later RNA extraction and gene expression analysis. All remaining fish were pooled into two experimental tanks (10 litres): Bt-maize group: twenty-two fish (two females); nBt-maize group: sixteen fish (four females), and fed the same experimental feeds for another 6 months (1–2 % of the biomass). Fertilised eggs were collected from the Bt-maize and nBt-maize groups on 23 August and larvae that hatched on 25 August (offspring generation). Data on reproductive performance were collected at the following time points in the pooled tanks: at 175–297 dph for fecundity (seven samplings); at 127–183 dph in fertilised eggs for epigenetics (three samplings); at 274–300 dph in F1 larvae for swimming activity (three samplings). Finally, on 16 November 2011, at day 283 (317 dph), all remaining fish from the parental generation (F0) were sampled and wet weighed to the nearest 0·01 g and total length was determined to the nearest millimetre. Livers were collected from ten fish (F0) per diet and dissected before being quickly frozen in liquid N₂ and stored at − 80°C for later CuZn superoxide dismutase (SOD) analysis.

Tissue sampling – offspring generation

The offspring larvae were reared in our laboratory under conditions the same as those described for the parental generation. Embryos (51 h post-fertilisation) were collected for global DNA methylation analysis (F1) and larvae (4 dph) were collected for analysing swimming activity (F1). The methodology used is described below. Before the offspring fish sampling (83 dph), which was performed on 16 November 2011, all fish were euthanised by immersion in an ice water bath (4°C or less)⁽Reference Wilson, Bunte and Carty²²⁾. Data on fish performance of all fish were recorded (fourteen fish per tank) using a procedure the same as that used for the parental generation, and the liver and mid-intestine were dissected from six fish as described before, quickly frozen in N₂ and stored at − 80°C for later gene expression analysis. For histological evaluation, the whole intestinal tract was immediately sampled and placed into standard Bouin's solution. After fixation, the samples were dehydrated in graded series of alcohol, equilibrated in xylene and embedded in paraffin.

RNA isolation and quantitative real-time RT-PCR (parental generation and offspring generation)

Total RNA was extracted from individual mid-intestinal and liver tissues using the TRIzol reagent according to the manufacturer's instructions (Invitrogen, Life Technologies), and residual genomic DNA was removed by DNase treatment using DNA-free reagents (Ambion). RNA quality and integrity were assessed using NanoDrop ND-1000 Spectrophotometer (NanoDrop Technologies) and the Agilent 2100 Bioanalyzer (Agilent Technologies). A total of twenty-four intestines were sampled from the parental generation (two to three intestines per tank) and seventy-two livers/intestines were sampled from the offspring generation (four livers/intestines per tank). The sequences of the PCR primers used for the quantification of the mRNA transcriptional levels of the target genes as well as the reference genes are given in Table 2 (Invitrogen, Life Technologies). All primer pairs were tested using a one-step RT PCR kit (Qiagen), and the reaction specificity of each assay was verified by observing a single peak at the expected temperature on the melting curve. The RT reactions were run in triplicate on ninety-six-well reaction plates with the GeneAmp PCR 9700 machine (Applied Biosystems) using TaqMan Reverse Transcription Reagent containing Multiscribe Reverse transcriptase (50 U/μl) (Applied Biosystems). A twofold serial dilution curve (1000–31 ng RNA) of the pooled sample was constructed with six dilutions for the calculation of PCR efficiency. Non-template and non-amplification controls were run in addition to the experimental samples. Total RNA inputs were 250 ng (liver) and 500 ng (intestine) in each RT reaction. Reaction plates with 384 wells were used in which 2 μl of complementary DNA from each RT reaction were mixed with 8 μl of LightCycler 480 SYBR^® Green Master Mix (Roche Applied Sciences) with forward and reverse primers (500 nm of each). PCR was achieved with a 5 min activation and denaturation step at 95°C, followed by forty-five cycles of a 15 s denaturing step at 95°C, a 60 s annealing step and a 30 s synthesis step at 72°C. C _t values were calculated using the second maximum derivative method in the Light Cycler^® 480 software (Roche Applied Sciences). The mean normalised expression of the target genes was determined using a normalisation factor calculated by the geNorm software⁽Reference Vandesompele, De Preter and Pattyn²³⁾ (Biogazelle). Target genes were normalised against an index of the reference genes (ribosomal protein L13A (Rpl13a) and elongation factor 1 (EF1α)). The reference genes were stable with gene expression stability (M) values of 0·41 (liver), 0·68 (mid-intestine, F0) and 0·19 (mid-intestine, F1).

Table 2 Primer pair sequences and GenBank accession numbers for genes used for quantitative real-time PCR

Cyp1A, cytochrome P-450, family 1, subfamily A; CuZn SOD, CuZn superoxide dismutase; ghrelin, ghrelin/obestatin prehormone; MGAM, maltase glucoamylase (α-glucosidase); Slc5a1, sodium/glucose co-transporter (family 5, member 1); PCNA, proliferating cell nuclear antigen; RPL13A, ribosomal protein L13A; EF1α, elongation factor 1α.

Differential leucocyte counts (parental generation)

Within 24 h of sampling, all blood films were stained with the May–Grünwald stain (Merck & Company, Inc.) for 5 min and the Giemsa stain (Merck & Company, Inc.) for 15 min. From each fish sampled, 100 leucocytes were counted and identified either as lymphocytes, granulocytes or monocytes and expressed as a percentage of the total number of leucocytes examined. Each sample was blinded and examined randomly with an Olympus light microscope (BX 51) (Olympus).

Copper zinc superoxide dismutase enzyme activity (parental generation)

Individual liver samples from the parental generation were prepared by adding 500 μl of a cold buffer (20 mm-HEPES, pH 7·2, containing 1 mm-ethylene glycol tetraacetic acid (EGTA), 210 mm-mannitol and 70 mm-sucrose) before being homogenised at 3 × 10 s at 6000 rpm (Precellys 24 homogeniser; Bertin Corp.). The samples were then centrifuged at 10 000 g for 15 min at 4°C before the supernatant was collected and stored at − 80°C for later enzyme analysis. CuZn SOD enzyme activity was assayed according to the assay protocol (SOD assay kit, item no. 706002, Cayman Chemical Company). The absorbance was read at 450 nm using a standard plate reader with a shaker. Using a standard protein assay kit (Pierce^® BCA protein assay kit, Thermo Scientific, Pierce Biotechnology), one-third of the supernatant was used for assaying the protein content. The definition of one unit of SOD activity (U) is as follows: the quantity of enzyme required to cause 50 % dismutation of the superoxide radical. The results are expressed as U/min per mg protein.

Fecundity measurements (parental generation)

For the reproductive study, 5-litre breeding tanks equipped with a spawning tray, which consisted of a fine net with an appropriate mesh size for eggs to fall through, close to the bottom of the tank, were used. Males and females from each dietary group were housed separately until the next morning when the light period commenced and they were allowed to breed. The measure of reproductive success was the number of eggs produced by the females per dietary group. Subsequently, after each fecundity experiment, eggs were collected and counted from each group 3 h after the beginning of the light period. Fecundity data are based on groups of females⁽Reference Knowles^2–Reference Then⁴⁾ mating with three males and are cumulative values that also include the impact of unfertilised eggs.

Analysis of global DNA methylation (offspring generation)

Eggs were carefully rinsed in system water before being incubated with the E3 medium (5 mm-NaCl, 0·17 mm-KCl, 0·33 mm-CaCl₂, 0·33 mm-MgSO₄ and 0·1 % Methylene Blue) at 29°C, collected at 51 h post-fertilisation and preserved in liquid N₂ for later DNA methylation analysis. The total numbers of embryos analysed from each group were 240 (Bt-maize group) and 330 (nBt-maize group). DNA from the embryos was prepared using the method of Skjærven et al. ⁽Reference Skjærven, Hamre and Finn²⁴⁾ as modified by Ramsahoye⁽Reference Ramsahoye²⁵⁾. Briefly, thirty pooled embryos were thoroughly homogenised in 1 ml of TRIzol (Invitrogen, Life Technologies) using a pestle before homogenising at 3 × 10 s at 6000 rpm (Precellys 24 homogeniser; Bertin Corp.). Total DNA was extracted according to the TRIzol protocol before being further purified and digested into nucleotides⁽Reference Skjærven, Hamre and Finn²⁴⁾. The samples were stored at − 80°C until further HPLC analyses. Isocratic reverse-phase HPLC was used to analyse the DNA⁽Reference Skjærven, Hamre and Finn²⁴⁾. Briefly, the mobile phase (20 mm-orthophosphoric acid, pH 2·5) was filtered before use and was run through the HPLC system for approximately 15 min at 0·5 ml/min and 30 min at 1·0 ml/min before each sample series to stabilise the system. The flow of the mobile phase was set to 1 ml/min during the analysis. After each sample series, the HPLC system was washed with 5 % acetonitrile in water for at least 2 h. The samples were run together with nucleotide standards combined in a standard mix. The standard mix consisted of cytosine (dCMP; 2′-deoxycytidine 5′-monophosphate; Sigma D7750), uracil (2,4-dihydroxypyrimidine, Sigma U0750) and methylated cytosine (5mdCMP; 5-methyl deoxycytidine 5′-monophosphate, disodium salt, Reliable Biopharmaceutical product no. 61-1979). Uracil was included in the standard mix as a reference for RNA-free DNA. The percentage of 5-methylcytosine nucleotides was calculated using the following formula⁽Reference Ramsahoye²⁵⁾:

$$\begin{eqnarray} mdCMP\ (as\ \%\ of\ total\ C) = \frac {nmol\ of\ mdCMP}{nmol\ (mdCMP + dCMP)}\times 100. \end{eqnarray}$$ $$

The molar equivalent of each nucleotide was calculated using the areas under each peak divided by the extinction coefficients for the nucleotides (extinction coefficient for dCMP = 9300 and mdCMP = 8600).

Analysis of the swimming activity of larvae (offspring generation)

At 4 dph, the F1 larvae were placed individually in wells of a ninety-six-well plate containing the E3 medium, and swimming activity was measured using the ZebraLab Quantization software (Viewpoint Life Sciences) equipped with an IR light source, a high-resolution digital IR camera and a hood to exclude external light. Swimming activity was measured for 60 min with alternating light and dark cycles of 10 min. Movement was captured within predefined areas (freezing area, low-movement activity; mid-area, medium-movement activity; burst area, high-movement activity), and output parameters were duration and counts within each area. The sum of total duration was always 60 min. Each time the larvae moved from one area to another, one count was registered, and the counts varied from 100 in slow larvae to 10 000 in active larvae. The total numbers of larvae analysed for each group were 131 (Bt-maize group) and 281 (nBt-maize group).

Histological evaluation of zebrafish intestines (offspring generation)

From the paraffin-embedded intestinal tissues, longitudinal and/or transverse sections (3 μm) were cut and stained with haematoxylin and eosin and mounted on glass microscope slides. Intestinal tissues (proximal intestine and mid-intestine) of all the sections were blinded and evaluated by trained personnel using a light microscope (Carl Zeiss, Inc.), and images were captured using the AxioVision Rel. 4.7 software (Kemet International Limited). Morphology was evaluated according to the following criteria: (1) enterocyte nucleus position; (2) enterocyte vacuolisation; (3) submucosal width and cellularity; (4) lamina propria width and cellularity; (5) intraepithelial leucocyte frequency; (6) enterocyte hyperplasia; (7) goblet cell frequency; (8) presence of mucosal fold fusion. Serial sections were evaluated when necessary. The degree of histological changes was assessed as normal, mild, moderate or severe.

Calculations

$$\begin{eqnarray} CF = \left (\frac {body\ weight\ (mg)}{fork\ length\quad (mm)^{3}}\right )\times 100, \end{eqnarray}$$ $$

$$\begin{eqnarray} FCR = \frac {feed\ eaten\ (mg)}{body\ mass\ increase\ (mg)}, \end{eqnarray}$$ $$

$$\begin{eqnarray} Specific\ growth\ rate = \left (\frac {ln\ final\ weight - ln\ initial\ weight}{duration\ of\ study\ in\ days}\right )\times 100. \end{eqnarray}$$ $$

Statistical analysis

Statistical analysis was conducted using Statistica™ 7 (StatSoft, Inc.) and GraphPad Prism 5 (GraphPad Software, Inc.). A one-way ANOVA (general lineal model) or unpaired t test was used for data obtained from the F1 or F0 generation, respectively. Data were always evaluated to ensure that the criteria for performing the statistical tests were fulfilled (Bartlett's test for equal variances). In cases when the ANOVA showed significant differences, post hoc tests (Tukey's honestly significant difference test or Fisher's least significant difference test) were used to find which groups differed. Data from the histological evaluations were subjected to a contingency analysis. Data obtained from the pooled fish tanks, performance parameters (F0) after 283 d (Bt-maize: n 11; nBt-maize: n 10), CuZn SOD enzyme analysis (Bt-maize: n 11; nBt-maize: n 10), leucocyte counts (Bt-maize: n 6; nBt-maize: n 8) and reproduction parameters, are reported as means with their 95 % CI. All reported P values are two sided and significance was set at P< 0·05.