Tilapia is the second most farmed fish worldwide, just after carp(1). Nevertheless, there are still many challenges to overcome in order to farm tilapia under economic and environmentally sustainable principles. Part of the challenge is dependent on the development of sustainable feeds that will ensure an optimal nutritional status for the fish while promoting N and P retention, thus reducing nutrient excretion into the aquatic environment.
In order to increase the sustainability of aquaculture feeds, inclusion levels of plant ingredients in fish diets have increased. Soybean meal has been successfully included in aquafeeds(Reference Carter and Hauler2–Reference Nguyen, Davis and Saoud4) due to its high protein content and relatively well-balanced amino acid profile. However, soy-based diets are limited in methionine (Met) and require its supplementation in order to fulfil fish requirements(Reference Gatlin, Barrows and Brown5).
Met is an indispensable amino acid involved in protein synthesis, transmethylation reactions and antioxidant defence. Met metabolism occurs mainly in the liver where l-Met is converted into s-adenosylmethionine (SAM), a methyl donor for several reactions. Subsequently, SAM donates its methyl group and is transformed into s-adenosylhomocysteine (SAH), which is rapidly converted into homocysteine. Hepatic homocysteine can be remethylated back to Met by adding a methyl group from trimethylglycine or can irreversibly enter the transsulphuration pathway(Reference Selhub6). The transsulphuration pathway converts homocysteine into cystathionine and then cysteine. Ultimately, cysteine can be incorporated into proteins, metabolised into glutathione or oxidised to form taurine(Reference Stipanuk7).
dl-Methionine (dl-Met) and methionine hydroxyl analogue (MHA; dl-2-hydroxy-4-methylthiobutyrate or dl-HMTBA and its Ca salt) are synthetic sources of Met that are often supplemented to animal feeds. dl-Met is a racemic mixture of d- and l-isomers of Met, while MHA is a racemic mixture of d- and l-isomers of MHA(Reference Dibner8). MHA chemical structure is similar to that of Met; however, it contains a hydroxyl group instead of the amino group. Recently, studies in rainbow trout (Oncorhynchus mykiss) suggested that dl-Met and MHA uptake in the gut apical surface is facilitated by Na-dependent transporters and mediated by proton-independent transporters across the basolateral membrane(Reference To, Masagounder and Loewen9,Reference To, Subramaniam and Masagounder10) . Data comparing the intestinal flux rates of dl-Met and MHA suggest a faster intestinal transport of the former synthetic source(Reference Dibner8,Reference To, Subramaniam and Masagounder10,Reference Maenz and Engele-Schaan11) .
Since animals can only metabolise l-amino acids, d-isomers of dl-Met first need to be converted to a keto-Met intermediate (keto-methylthio-butanoic acid, KMB) and then transaminated to l-Met before becoming available(Reference Dibner8,Reference Zhang, Wong and Gilbert12) . On the other hand, both the d- and l-isomers of MHA need to be converted to KMB to become available(Reference Dibner8,Reference Zhang, Wong and Gilbert12) . These differences are likely to be reflected as differences in absorption and metabolism and may result in different biological efficiencies. Numerous studies in terrestrial animals and fish advocate that MHA supplementation results in lower bioavailability of this compound compared with dl-Met(Reference Keembiyehetty and Gatlin13–Reference Sauer, Emrich and Piepho15). In rainbow trout, dietary MHA-Ca salt was found to have lower bioavailability than dl-Met, resulting in 69 % lower fish weight gain, 60 % lower growth rate and 73 % lower N retention in fish(Reference Powell, Chowdhury and Bureau16). Similarly, growth performance and feed utilisation indicators in common carp (Cyprinus carpio) fed dl-Met and MHA-Ca supplemented diets demonstrated that MHA-Ca was 41–50 % as available as dl-Met on weight-for-weight basis(Reference Zhou, He and Su17). In contrast, some authors report similar efficiencies among Met sources based on growth and feed efficiency in several aquatic animals(Reference Goff and Gatlin18–Reference Zhou, Wang and Bei21). On the other hand, a study performed in channel catfish observed that dietary MHA-Ca supplementation resulted in improved body weight, weight gain, feed conversion ratio and protein efficiency ratio(Reference Zhao, Li and Leng22). Based on the data published, NRC(23) concluded that it is reasonable to assume that the biological efficacy of MHA in fish is 75–80 % that of dl-Met on an equimolar basis (63–67 % on a weight basis). Generating data on growth, diet utilisation and Met metabolism in a commercial relevant species such as the Nile tilapia (Oreochromis niloticus) is of paramount importance for the aquaculture industry.
In this context, the objective of the present study was to understand how the dietary source of Met affects Met metabolism and growth of Nile tilapia juveniles. Radiolabelled Met sources were used in a nutrient flux assay to evaluate their influence in the amino acid metabolic pathways.
Materials and methods
Diets
Three experimental diets were formulated to be isonitrogenous and isoenergetic (Table 1). Diet REF was a negative control, without fishmeal inclusion, formulated to be 40 % below the Met requirement for Nile tilapia(23). No Met was supplemented to this diet. Experimental diets were the REF diet supplemented with 1·5 g/kg dl-Met (dlM diet) and 1·8 g/kg MHA-Ca (equal on molar basis to 1·5 g/kg dl-Met; MHA diet). To minimise variability among diets, one common basal diet was formulated, and the respective supplemental Met source was added in DLM and MHA diets. Diets were formulated to meet the minimum requirements of amino acids on digestible basis for Nile tilapia juveniles, except for Met. Apparent digestibility coefficients of amino acids for the ingredients used were taken from published review data(Reference Konnert and Masagounder24,Reference Konnert, Schrama and Masagounder25) . Diets were supplemented with selected indispensable amino acids and di-calcium phosphate to avoid amino acid or mineral imbalances.
* Solvent extracted dehulled soybean meal: 457 g/kg crude protein (CP), 31 g/kg crude fat (CF), CARGILL.
† Soycomil P: 620 g/kg CP, 7 g/kg CF, ADM.
‡ Maize meal: 81 g/kg CP; 37 g/kg CF, Casa Lanchinha.
§ Lysamine GPS: 840 g/kg CP, 10 g/kg CF, ROQUETTE Frères.
|| Wheat bran: 149 g/kg CP, 40 g/kg CF, Cerealis Moagens S.A.
¶ Henry Lamotte Oils GmbH.
** Sopropêche.
†† DCP: 168 g/kg P, 209 g/kg Ca, Premix Lda.
‡‡ PREMIX Lda. Vitamins (mg/kg diet): dl-alpha tocopherol acetate, 100 mg; sodium menadione bisulphate, 25 mg; retinyl acetate, 6.88 mg; dl-cholecalciferol, 0.050 mg; thiamin, 30 mg; riboflavin, 30 mg; pyridoxine, 20 mg; cyanocobalamin, 0.1 mg; nicotinic acid, 200 mg; folic acid, 15 mg; ascorbic acid, 1000 mg; inositol, 500 mg; biotin, 3 mg; calcium panthotenate, 100 mg; choline chloride, 1000 mg; betaine, 500 mg. Minerals (g or mg kg/diet): cobalt carbonate, 0·65 mg; copper sulphate, 9 mg; ferric sulphate, 6 mg; potassium iodide, 0·5 mg; manganese oxide, 9·6 mg; sodium selenite, 0·01 mg; zinc sulphate, 7·5 mg; sodium chloride, 400 mg; calcium carbonate, 1·86 g; excipient wheat middlings.
Upon ingredient grinding with a hammer mill (model SH1; Hosokawa-Alpine) and its mixing in a double-helixmixer, all diets (pellet sizes 1·2 and 2·0 mm) were manufactured using a twin-screw extruder (model BC45; Clextral) at SPAROS Lda. Upon cold extrusion, diets were dried in a vibrating fluid bed dryer (model DR100; TGC Extrusion). After cooling, the oils were added to the pellets by vacuum coating (model PG-10VCLAB). Throughout the duration of the trial, experimental feeds were stored at room temperature, in a cool and aerated storage room. Proximate composition and amino acid analysis were determined in all experimental diets, as reported in Tables 1 and 2, respectively.
* Analysed dl-Met in the DLM diet was 1.1 g/kg.
† Active content of MHA in the MHA diet is 1.1 g/kg (equal on molar basis to dl-Met) since MHA-Ca active form is 84 %.
Growth trial
The experiment was carried out in compliance with the Guidelines of the European Union Council (Directive 2010/63/EU) and Portuguese legislation for the use of laboratory animals. Nile tilapia (Silver Natural Male Tilapia™) juveniles were obtained from Til-Aqua International B.V. and the experiment was conducted at Centre of Marine Sciences of Algarve (CCMAR) facilities (Faro, Portugal). CCMAR facilities and their staff are certified to house and conduct experiments with live animals (Group-C licenses by the Direção Geral de Alimentação e Veterinária, Ministério da Agricultura, Florestas e Desenvolvimento Rural, Portugal). Upon arrival, fish were acclimatised to the new rearing facilities in a recirculating aquaculture system and were fed a commercial diet (crude protein: 340 g/kg; crude fat: 50 g/kg).
Juvenile Nile tilapia were reared in 100-litre cylindrical tanks in a recirculating aquaculture system equipped with a mechanical filter, a submerged biological filter and a UV steriliser. Photoperiod was natural (10 h light: 14 h dark), temperature averaged 25·9 (sd 0·5)°C and dissolved oxygen in water was maintained above 85 % of saturation. Water quality parameters were monitored daily and adjusted when necessary: pH was maintained between 7·0 and 8·2 and the concentration of unionised ammonia and nitrites in water was 0 mg/l during the whole experimental period. Mortality was monitored daily.
Fish with an initial mean body weight of 2·3 (sd 0·4) g were allocated into nine tanks at an initial density of 1·1 kg/m3 (fifty fish per tank). Eight fish from the initial stock were sampled and the whole fish were stored at −20°C until analysis of proximate composition. Triplicate tanks were randomly assigned to one of the three dietary treatments (REF, DLM and MHA). Fish were fed to visual satiety by hand, three times a day (09.30, 12.30 and 16.30 hours) and feed intake was recorded daily for 57 d.
At the end of the trial, each tank was bulk weighed. Ten fish from each tank were euthanised with a lethal dose of anaesthetic (1·5 ml/l phenoxyethanol; Sigma-Aldrich). Whole-body, liver and viscera weight of five individual fish were recorded for calculation of biometric indexes and liver samples were snap-frozen in liquid N2 and kept at −20°C until free amino acid analysis. The other five fish were stored at −20°C until analysis of whole-body proximate composition and amino acid content. Fish were fasted for 24 h before initial and final samplings.
Metabolic utilisation of supplemental methionine sources
At the end of the growth trial, to understand how different dietary Met sources are absorbed and metabolised in tilapia juveniles, a time-course metabolic trial was performed using radiolabelled dl-Met and MHA. REF diet was not included in this trial since the aim was to assess putative differences in the metabolic flux of the Met supplemental sources and not of the intact protein. Random fish fed the DLM or MHA diet were transferred to the nutrient flux laboratory after being fasted for 24 h.
dl-(1–14C)-Methionine (14C-dl-Met; 0·00185 GBq) and (1–14C)-calcium bis-methionine hydroxyl analogue (14C-MHA; 0·00185 GBq) (Campro Scientific GmbH) were used as tracers to radiolabel the experimental diets (DLM and MHA). The methodology for labelling the experimental diets was established in previous works of the authors(Reference Rocha, Dias and Geurden26–Reference Teodósio, Engrola and Colen28). The tracers were diluted in freshwater Ringer solution and a known value of the tracer was dispensed using a micropipette on individual pellets of the correspondent experimental diet. The pellets were dried at 50°C for 1 h. Eight pellets per fish, corresponding to 0·3 % body weight, were loaded into a hollow plastic tube of 1·5 mm inner diameter and stored for subsequent tube-feeding. Prior to tube-feeding, the amount of radioactivity (DPM) of ten individual pellets from each experimental diet labelled with the corresponding tracer was determined in a TriCarb 2910TR low activity liquid scintillation analyser (Perkin Elmer) after adding the scintillation cocktail (Ultima Gold XR; Perkin Elmer).
The in vivo method of tube-feeding used to perform the metabolic trials was adapted from Costas(Reference Costas29), which was a modification of the method first described by Rust(Reference Rust, Hardy and Stickney30) and modified by Rønnestad(Reference Rønnestad, Rojas-García and Tonheim31). Fish were anaesthetised (200 mg/l MS-222 buffered with sodium bicarbonate; Sigma-Aldrich) and subsequently were taken out of the water using a fish net and placed onto a dry plastic tray. The previously loaded plastic tube containing the radiolabelled pellets was inserted into the fish mouth and the feed pellets were gently pushed directly into the oesophagus using a solid piece with a smaller diameter placed inside as a plunger. The diameter and length of the hollow plastic tube were previously tested to avoid injuring the fish oesophagus. This procedure lasted approximately 10 s. The metabolic fate of the tracer (14C-dl-Met or 14C-MHA) was considered to represent the fate of the tracee (dl-Met or MHA-Ca)(Reference Conceição, Morais and Rønnestad32).
After tube-feeding, fish were placed into a tank with clean and aerated freshwater to eliminate any residual anaesthetic and were monitored for eventual pellet regurgitation. After this period, fish were transferred into individual incubation chambers containing 2 litres of freshwater at 26°C. Each chamber was hermetically sealed and supplied with a gentle oxygen flow. After the incubation period, oxygen flow was stopped and fish were euthanised inside the chambers by a lethal dose of anaesthetic (750 mg/l of MS-222 buffered with sodium bicarbonate). The incubation periods were 1, 2, 3, 4 or 6 h (n 6–7 fish for each diet and incubation period). Fish was removed from the chamber and weighed.
Water samples were collected from each individual chamber to determine the amount of radioactivity (DPM) present in the incubation water. The radioactivity present in the incubation water resulted from evacuated (non-absorbed) and/or catabolised radiolabelled Met source as CO2. Viscera, liver, skin-on fillets and the rest of the fish were collected and weighed. Viscera consisted of washed digestive tract (so that no alimentary bolus was present), spleen, pancreas and perivisceral fat and will be designated from hereafter as Viscera compartment; skin-on fillets (muscle with skin), as Muscle compartment and the rest of the fish (consisting of head, heart, kidney, bones and fins) as Residual compartment. Viscera and Liver compartments were analysed as whole. Muscle and Residual compartments were minced using a coffee grinder until a homogeneous mixture was obtained and 0·5 g samples were taken for further analysis.
All fish tissues were incubated at 4°C for 24 h with 6 % (w/v) TCA, with periodical stirrings. After this period, tissue samples were taken and the TCA samples collected for radioactivity determination (from hereafter designated as Free fraction). In order to get a better insight of the metabolic flux of 14C-dl-Met and 14C-MHA, tissue samples from the 6 h incubation period were homogenised and underwent a series of extraction procedures to separate organic compounds such as protein, lipids and other metabolites as described previously by Rocha(Reference Rocha, Dias and Geurden26). Briefly, samples were transferred to a clean vial and further homogenised in distilled water using an Ultra-turrax homogeniser (IKA). Total lipids were extracted using a modified Bligh and Dyer method(Reference Bligh and Dyer33) for small volumes, and total protein was extracted based on a TCA precipitation method(Reference Panchout, Letendre and Bultelle34). The supernatant containing non-extracted metabolites was collected for radioactivity determination. Protein pellet was resuspended in an appropriate volume of Solvable™ (Perkin Elmer) and kept at 50ºC until complete solubilisation was achieved. Lipids and other metabolites are designated as Others fraction, while protein as Protein fraction. Scintillation cocktail (Ultima Gold XR; Perkin Elmer) was added to all samples and DPM were counted in a TriCarb 2910TR low activity liquid scintillation analyser (Perkin Elmer). All counts were corrected for quench and lumex. Radioactivity found in the Incubation Water and in the Free fractions of all compartments was normalised for fish or tissue weight and expressed as DPM/g. Radioactivity present 6 h after feeding the radiolabelled nutrients in the Protein and Others fractions of all compartments was expressed as DPM.
To estimate the availability of the radiolabelled nutrient in each compartment, the area under the curve (AUC) from 1 to 6 h was calculated as follows:
where t is the time point, DPM i is the amount of radioactivity found at t i and n is the total number of measures(Reference Pruessner, Kirschbaum and Meinlschmid35). AUC was expressed as a percentage of total cumulated (1–6 h) radioactivity (DPM) per dietary treatment.
Biochemical analysis
Raw materials (soybean meal, soy protein concentrate, pea protein concentrate, maize meal and wheat bran) were analysed for DM, crude protein and amino acid content using NIR (AMINONIR®, Evonik Nutrition & Care) before diet formulation.
Chemical analysis followed standard procedures of the Association of Official Analytical Chemists(36) and was run in duplicates. Before analysis, diets and pooled whole-body fish were finely ground. Moisture content was determined by drying the samples at 105°C for 24 h and ash content by incineration in a muffle furnace at 550°C for 6 h. Freeze-dried whole-body samples and diets were analysed for crude protein (N × 6·25) by wet chemistry (AMINOLab®, Evonik Nutrition & Care) using the combustion/Dumas method; crude fat by petroleum ether extraction using a Soxtherm Multistat/SX PC (Gerhardt); gross energy by combustion in an adiabatic bomb calorimeter (Werke C2000; IKA) calibrated with benzoic acid and P content by digestion at 230°C in a Kjeldatherm block digestion unit followed by digestion at 75°C in a water bath and absorbance determination at 820 nm (adapted from AFNOR V 04-406).
Amino acid content in diets and whole-body fish samples were analysed by wet chemistry (AMINOLab®, Evonik Nutrition & Care) using ion exchange chromatography. Hepatic free amino acids and SAM and SAH contents were determined after homogenisation of freeze-dried samples in 0·1 M HCl on ice, centrifugation at 1500 × g at 4°C for 15 min and deproteinisation of the supernatant by centrifugal ultrafiltration (10 kDa cut-off, 2500 × g at 4°C for 20 min). All samples were pre-column derivatised with Waters AccQ Fluor Reagent (6-aminoquinolyl-N-hydroxysuccinimidyl carbamate) using the AccQ Tag method (Waters), except samples for SAM and SAH analysis, which were not derivatised. All analyses were performed by ultra-high-performance liquid chromatography on a Waters Reversed-Phase Amino Acid Analysis System, using norvaline as an internal standard. Amino acids were identified by retention times of standard mixtures (Waters) and pure standards (Sigma-Aldrich). Instrument control, data acquisition and processing were achieved by the use of Waters Empower software.
Nutritional indicators
Growth performance parameters, somatic indexes and nutrient retention were calculated as follows:
Daily voluntary feed intake (% ABM/d) = 100 × (apparent feed intake/ABM/d), where ABM is average body mass = (final biomass + initial biomass)/2.
Feed conversion ratio = apparent feed intake/wet weight gain.
Protein efficiency ratio = wet weight gain/crude protein intake.
Hepatosomatic index (%) = 100 × (liver weight/total weight).
Viscerosomatic index (%) = 100 × (viscera weight/total weight).
Protein or energy retention (% intake) = 100 × ((final body protein or energy content – initial body protein or energy content)/(protein or energy intake)).
Daily N intake (mg N/kg/d) = N intake/ABM/d.
Daily N gain (mg N/kg/d) = (final body N content − initial body N content)/ABM/d.
Daily N loss (mg N/kg/d) = daily N intake − daily N gain.
Statistical analysis
Sample size was determined based on preliminary power analysis to ensure a probability of at least 80 % in the detection of treatment effects. Data are presented as means and standard deviations. Data expressed as a percentage were arcsine square root transformed previously to the statistical analysis(Reference Ennos37). All data were checked for normal distribution and homogeneity of variances. Differences among groups were identified by one-way ANOVA followed by Tukey’s multiple-comparison test or, when the assumptions for the ANOVA failed, by Kruskal–Wallis one-way ANOVA by ranks followed by Dunn’s multiple-comparison tests. Data from the time-course metabolic trials were subjected to linear regression analysis to understand the relationship between the tracer (14C-dl-Met or 14C-MHA) and incubation time in each compartment (Incubation Water, Viscera, Liver, Muscle and Residual compartments). Additionally, one-way ANOVA followed by planned contrasts test was performed to compare the differences between 14C-dl-Met and 14C-MHA fed fish at each time point. At 6 h time point, Mann–Whitney U test was additionally used to identify differences in the Protein and Others fractions of the several body compartments. All statistical differences were considered significant at P < 0·05. Statistical analyses were performed using the open source software R version 3.6.1.
Results
Growth performance and feed utilisation
At the end of the growth trial, survival was 100 % in all treatments and fish had a 9–10-fold increase in body weight (Table 3). Fish fed the DLM diet were significantly heavier (28·3 (sd 4·7) g) than fish fed the REF (24·1 (sd 3·0) g) and the MHA (24·8 (sd 2·7) g) diets (P < 0·05). Fish biomass gain differed marginally with the different dietary treatments (P = 0·08). Feed intake was similar among experimental groups. Fish fed the DLM diet presented a significantly lower feed conversion ratio than fish fed the REF diet (P < 0·05). Protein efficiency ratio was significantly higher in fish fed the DLM (3·4 (sd 0·1)) than the REF (3·1 (sd 0·1)) diet (P < 0·05). Dietary treatments did not affect significantly hepatosomatic and viscerosomatic indexes (P > 0·05).
* Initial body weight = 2·3 (sd 0·4) g for all dietary treatments (n 150). Values are presented as means and standard deviations (n 15 for final body weight, HSI and VSI; n 3 for the remaining parameters).
a,bDifferent superscripts within the same row indicate significant differences (P < 0·05) among diets. Absence of superscripts indicates no significant differences.
Whole-body fish composition and nutrient retention
Fish from the DLM diet presented significantly higher body protein and energy content than fish from the MHA diet (P < 0·05; Table 4). Fish whole-body moisture, ash, fat and P content were not affected by the dietary treatments (P > 0·05). Additionally, whole-body total Met content was significantly higher in DLM fed fish (3·86 (sd 0·01) g/kg) than in fish from the REF (3·54 (sd 0·11) g/kg) or MHA (3·50 (sd 0·14) g/kg) dietary treatments (P < 0·05). No significant differences were found for the other amino acids among experimental groups. Protein and energy retention were significantly higher for fish fed the DLM diet than for fish fed the other diets (P < 0·05; Table 4).
* Initial body composition: moisture = 742.8 g/kg WW; ash = 40.0 g/kg WW; protein = 164.6 g/kg WW; fat = 47.7 g/kg WW; P = 5.9 g/kg WW; energy = 5.5 MJ/kg WW. Values are presented as means and standard deviations (n 3).
a,bDifferent superscripts within the same row indicate significant differences (P < 0.05) among diets. Absence of superscripts indicates no significant differences.
Dietary treatments did not influence daily N intake. DLM fish exhibited the highest daily N gain (726 (sd 3) mg N/kg/d), significantly different from REF (657 (sd 8) mg N/kg/d) or MHA (660(sd 22) mg N/kg/d) fed fish (P < 0·05). Moreover, fish from the DLM group presented the lowest daily N loss (667 (sd 43) mg N/kg/d), which was significantly different from the REF group (P < 0·05; Fig. 1).
Methionine and one-carbon metabolites
Free Met (Fig. 2(A)) was significantly higher in liver of fish fed the DLM and MHA diets than in REF fed fish (P < 0·05). SAM (1·25–1·35 mg SAM/g dry weight (DW) liver), SAH (0·23–0·27 mg SAH/g DW liver) or SAM/SAH ratio (4·79–5·48) were not affected by the dietary treatments (P > 0·05). Homocysteine levels (Fig. 2(B)) were significantly lower in DLM fish than in fish fed REF and MHA diets (P < 0·05). Cystathionine was significantly lower in fish fed the supplemented diets than in fish fed the REF diet (P < 0·05; Fig. 2(C)). Free cysteine content was not affected by the dietary treatments (P > 0·05; 0·17–0·20 mg Cys/g DW liver). Fish fed the DLM diet had more hepatic taurine content than fish fed REF and MHA diets (P < 0·05). In addition, there were no significant differences in taurine content between fish fed REF and MHA diets (P > 0·05; Fig. 2(D)). Hepatic trimethylglycine was significantly lower in fish fed the DLM (0·05 (sd 0·00) mg TMG/g DW liver) than the REF (0·06 (sd 0·00) mg TMG/g DW liver) diet (P < 0·05). No significant differences in hepatic trimethylglycine content were found for fish fed the MHA diet compared with the other groups (P > 0·05).
Moreover, total free amino acids were significantly higher in DLM fish liver (108·42 (sd 2·90) mg/g DW liver) than in liver of fish fed the REF (86·48 (sd 3·29) mg/g DW liver) and the MHA (86·08 (sd 1·81) mg/g DW liver) diets (P < 0·05). Similarly, the sum of free indispensable and dispensable amino acids was significantly higher in liver of fish fed the DLM diet than in liver of fish fed the other diets (P < 0·05; Fig. 3).
Metabolic utilisation of supplemental methionine sources
The amount of radiolabelled tracer found in Incubation Water had a linear increase during the time course for both DLM and MHA treatments (Table 5; P < 0·05). Also, at the end of the time course (6 h) a higher amount of 14C-MHA was present in the Incubation Water compartment than of 14C-dl-Met (P < 0·05; Fig. 4). Furthermore, the AUC for the MHA diet was 2·4-fold higher than for the DLM diet, indicating a higher evacuation and/or catabolism of 14C-MHA compared with 14C-dl-Met by juvenile tilapia (Table 5).
* Please refer to ‘Metabolic utilisation of supplemental methionine sources’ section for further details.
After 1 h of diet ingestion, the amount of tracer found in Viscera (Fig. 5(A)) and Liver (Fig. 5(B)) Free fractions was higher in the DLM than in the MHA fish, although only significantly different for the Liver Free fraction (P < 0·05; Fig. 5(B)). The 14C-dl-Met presented a linear decrease during the incubation period in both compartments (P < 0·05; Table 5). On the other hand, this linear pattern was not found in fish fed MHA diet. The amount of tracer in Viscera Free fraction increased up to 4 h and then decreased at 6 h to values slightly below the values determined for the DLM fed fish (Fig. 5(A)). After 4 h of ingestion, the amount of tracer found in Viscera Free fraction of MHA fed fish was significantly higher than in fish fed the DLM diet (P < 0·05; Fig. 5(A)). Regarding the 14C-MHA in the Liver Free fraction, a plateau was observed from 2 h until the end of the incubation period (Fig. 5(B)). The AUC in the Viscera and Liver Free fractions was similar for both dietary treatments, indicating a similar bioavailability of both Met sources along the experimental period (Table 5).
The presence of 14C-dl-Met in the Residual Free fraction presented a peak at 2 h after diet ingestion (Fig. 5(C)), while for 14C-MHA a linear increase was observed during the whole incubation period (P < 0·05; Table 5). The amount of tracer found in the Residual Free fraction of DLM fed fish was significantly higher than in fish fed the MHA diet (P < 0·05; Fig. 5(C)) at 3 h after diet ingestion. Similar to the Residual Free fraction, the amount of tracer found in the Muscle Free fraction (Fig. 5(D)) of MHA fed fish exhibited a linear increase with time (P < 0·05; Table 5), while for the 14C-dl-Met a peak was found 2 h after diet ingestion. The amount of 14C-dl-Met found in Muscle Free fraction was significantly higher than that of 14C-MHA (P < 0·05) at 2 and 3 h after diet ingestion. The AUC for the Residual and Muscle Free fractions was 1·3 and 1·9-fold higher in DLM fed fish than in fish fed MHA diet, respectively, indicating a higher bioavailability of the Met source in the fish fed the DLM diet (Table 5).
At the end of the incubation period (6 h), a significantly higher amount of tracer was determined in the Viscera and Muscle Protein fractions from DLM fed fish (Fig. 6; P < 0·05). No significant differences between treatments were detected in Liver and Residual Protein fractions (P > 0·05). Regarding the Others fraction (lipids and other metabolites), there were no significant differences between treatments in all compartments (P > 0·05). The amount of tracer present in the Liver Others fraction was the lowest (333 and 222 DPM for fish fed the DLM and MHA diets, respectively) and the highest in the Residual Others fraction (2858 and 3037 for DLM and MHA fed fish, respectively).
Discussion
The in vivo method using radiolabelled tracers (14C-dl-Met and 14C-MHA) was utilised to gain a deeper understanding on how different Met sources may affect the dietary Met utilisation by Nile tilapia juveniles. The amount of tracer found in the Incubation Water increased with time in both treatments; moreover, the analysis of the AUC from 1 to 6 h after ingestion revealed a higher amount of 14C-MHA than of 14C-dl-Met indicating a greater evacuation of unabsorbed MHA and/or higher catabolism of this Met source compared with dl-Met. The solubility of MHA-Ca in water is higher than that of dl-Met(38); however, since the labelled pellets were placed directly into the fish oesophagus and were not in contact with water, the radioactivity present in the Incubation Water was the result of the evacuation of unabsorbed tracer. Similarly, in broiler chicks fed 14C-dl-Met or 14C-MHA a higher amount of tracer was present in the excrements of 14C-MHA fed birds than in excrements of birds fed the 14C-dl-Met(Reference Saunderson39,Reference Lingens and Molnar40) . dl-Met and MHA uptake is mediated by Na-dependent transporters across the brush border membrane(Reference To, Masagounder and Loewen9,Reference To, Subramaniam and Masagounder10) ; however, MHA is also partly transported by diffusion(Reference Maenz and Engele-Schaan41). In rainbow trout, it has been demonstrated that MHA presents a slower intestinal absorption rate than dl-Met(Reference To, Subramaniam and Masagounder10). This indicates that MHA stays longer in the intestine being more prone to bacterial degradation(Reference Drew, Van Kessel and Maenz42) that would lead to a further decrease in the intestinal absorption of MHA and its evacuation. Combined, these two factors may contribute to the increased amount of unabsorbed 14C-MHA relative to 14C-dl-Met in the Incubation Water.
In our study, Viscera and Liver Free fractions of DLM and MHA fed fish presented a similar cumulative bioavailability of 14C-dl-Met and 14C-MHA for the 6 h period. However, a comparison between the two dietary treatments revealed different patterns of tracer flux in these compartments throughout the in vivo trial. Fish fed the DLM diet presented a peak in Liver Free fraction 1 h after feeding, while no peak was observed during the 6 h time course for MHA fed fish. The d-isomer of dl-Met and l- and d-isomers of MHA need to be converted to l-Met to become available to the animal via a two-step process(Reference Dibner8,Reference Dibner and Knight43) ; however, the l-isomer present in dl-Met is readily available. Therefore, the results from the in vivo metabolic trial suggest a faster availability of dl-Met to metabolic processes than of MHA.
In fish fed the DLM diet, the tracer was available to the Residual Free fraction (Free fractions in head, heart, kidney, bones and fins) faster than in MHA fed fish. Moreover, for the 6 h trial, the cumulative Met source bioavailability in Residual compartment was higher in DLM than in MHA fed fish. Although the liver is the major site of conversion of d-Met and of d- and l-MHA to l-Met, this process also occurs in the kidney(Reference Dibner8,Reference Saunderson39,Reference Dupuis, Saunderson and Puigserver44) . This may explain the high amount of tracer found in the Residual Free fraction, as this compartment includes the kidney among other tissues. Other studies have reported higher amounts of 14C-dl-Met than of 14C-MHA recovered in the kidney of broilers(Reference Saunderson39,Reference Lingens and Molnar40) . In a study where chicken kidney homogenates were incubated with 14C-labelled l-Met, dl-Met or MHA, dl-Met was found to be the substrate most readily converted into the intermediate KMB, revealing that the majority of the KMB produced in the kidney would result from the oxidation of the d- and not the l-isomer of dl-Met(Reference Dupuis, Saunderson and Puigserver44). Further studies are necessary to confirm if in fish the kidney plays an important role in the conversion of d- to l-Met.
After being converted, the Met originating from the different dietary Met sources is transported to the rest of the body to be utilised by the fish. As a consequence of the faster absorption and hepatic metabolism, 2 h after feeding a higher amount of tracer was observed in the Muscle Free fraction of DLM fish, implying that dietary Met is available earlier for utilisation when fish are fed this source. Also, cumulative Met bioavailability in Muscle Free fraction was higher in DLM than in MHA fed fish. Therefore, one can consider that Met is readily available for protein synthesis faster and for a longer period in DLM fed fish than in fish fed the MHA diet. In fact, 6 h after feeding, the amount of tracer found in the Protein fractions of all compartments of DLM fed fish was higher than in MHA fed fish, with significant differences detected in Viscera and Muscle compartments. This indicates that DLM fish exhibited a faster and more effective incorporation of Met into muscle protein. Although the amount of tracer present in the Liver Protein fraction of DLM fish was higher than in fish fed the MHA diet, the difference was not significant due to a high variability within treatments. The vital physiological functions of the liver in detoxification, protein synthesis and digestion, constantly producing metabolites, may account for this variability.
In both dietary treatments, the amount of tracer retained in the lipid fraction, the major component of the Others fraction, was very low. Metabolic studies in gilthead seabream(Reference Rocha, Dias and Geurden26,Reference Rocha, Dias and Geurden45) and Senegalese sole(Reference Navarro-Guillén, Yúfera and Engrola46) using a 14C-amino acid mixture have previously demonstrated that absorbed amino acids were preferentially used for protein synthesis and only a small proportion were converted into lipids.
At the end of the growth trial, the content of hepatic free amino acids and one-carbon metabolites was determined in fish fed control and supplemented diets. The content of total hepatic free amino acids in fish fed the DLM diet was significantly higher than in fish fed the REF or the MHA diets, due to an increase in both indispensable and dispensable amino acids. Since these are not postprandial results, it indicates a higher bioavailability of amino acids for metabolic purposes in Nile tilapia fed diets supplemented with DLM. Met supplementation caused an increment of free Met in liver, independently of the source. Met dietary supplementation studies in Nile tilapia(Reference Michelato, Furuya and Gatlin47) and Atlantic salmon (Salmo salar)(Reference Espe, Hevrøy and Liaset48,Reference Espe, Andersen and Holen49) were unable to observe a similar effect of dietary supplementation in hepatic Met levels, possibly due to the fact that these studies report postprandial results unlike the present study where fish were sampled 24 h after feeding, hence the result of basal metabolism. The increase in free Met levels in liver indicates a higher availability for protein synthesis, transmethylation reactions and antioxidant defence in fish fed supplemented diets (DLM and MHA diets) compared with fish fed the non-supplemented diet (REF diet). In the present study, DLM and MHA fed fish presented similar levels of hepatic Met, SAM and SAH, while homocysteine was significantly lower in fish fed the DLM diet in comparison with the other dietary treatments. This suggests that the different Met sources follow different metabolic pathways. In neonatal pigs, to meet Met requirements, protein synthesis is favoured over Met transmethylation and the Met pool is conserved by increasing homocysteine production and suppressing transsulphuration(Reference Bauchart-Thevret, Stoll and Chacko50). In the present study, the hepatic free amino acid analysis indicates that fish fed MHA and REF diets probably remethylate homocysteine back to Met, with the addition of a methyl group from trimethylglycine. On the contrary, DLM fed fish seem to divert Met to the transsulphuration pathway, resulting in a significantly higher hepatic taurine content in DLM compared with MHA fed fish. Similarly, feeding Atlantic salmon with soy-based diets supplemented with dl-Met also resulted in an increase in the transsulphuration pathway and consequently higher hepatic taurine content(Reference Espe, Hevrøy and Liaset48). These results indicate a stimulation of the transsulphuration pathway in fish fed the DLM diet.
DLM and MHA fed fish had a similar intake of dietary Met, cysteine and taurine. The experimental diets were soy-based, hence low in taurine. In fact, taurine content in all diets was below 0·1 g/kg. Taurine is an end product of Met metabolism and of the transsulphuration pathway. Therefore, although Met and cysteine hepatic levels were similar in fish fed DLM and MHA diets, a higher hepatic taurine content was found in the former, probably due to a higher availability of Met, as indicated by the metabolic trials. Higher hepatic taurine content is beneficial for the fish as taurine is involved in numerous physiological functions. In fish, taurine plays important roles in bile salt formation(Reference Kim, Matsunari and Takeuchi51,Reference Kim, Matsunari and Nomura52) , lipid digestion(Reference Richard, Colen and Aragão27), osmoregulation(Reference Takagi, Murata and Goto53) and antioxidant defence(Reference Li, Lai and Li54–Reference Martins, Magalhães and Castro56) and it also increases amino acid retention(Reference Richard, Colen and Aragão27,Reference Pinto, Figueira and Ribeiro57) . In Nile tilapia, it has been demonstrated that dietary taurine supplementation improves growth performance(Reference Al-Feky, El-Sayed and Ezzat58). In the present work, taurine status in DLM fed fish might have partially contributed to the improvement in growth performance observed in the growth trial. Diet supplementation with dl-Met increased fish body weight when compared with REF and MHA fed fish. Relative to the REF diet, DLM diet produced more 214 g in biomass gain, whereas MHA diet produced only more 124 g (on tank basis). This indicates that on equimolar basis MHA is only 58 % as efficient as dl-Met in terms of biomass gain. dl-Met supplementation improved feed conversion and protein efficiency ratios when compared with the basal diet (REF), while MHA fed fish presented intermediate results. These results are in agreement with previous studies in fish(Reference Keembiyehetty and Gatlin13,Reference Powell, Chowdhury and Bureau16,Reference Zhou, He and Su17,Reference Keembiyehetty and Gatlin59) , demonstrating that dl-Met supplementation improves growth and promotes protein accretion more efficiently in Nile tilapia.
In the metabolic trial, it was established that the distinct Met sources are utilised differently by Nile tilapia juveniles in the short term. Residual and Muscle Free fractions shown higher availability of Met in DLM than in MHA fed fish and 6 h after feeding a greater amount of tracer in the Muscle Protein fraction was found in the former. These differences were also reflected in the long term. At the end of the experimental period, protein retention in DLM fed fish was higher than in fish fed the MHA diet. Protein and total Met whole-body content were also higher in fish fed the DLM diet than in fish from the MHA group. The differences found between DLM and MHA fed fish in total Met content and availability explain the differences in protein content, reinforcing that Nile tilapia ultimately utilises dl-Met more efficiently for protein deposition than MHA.
The augmented protein retention was ultimately reflected in the N balance. All diets were isonitrogenous and feed intake was similar in all treatments, resulting in similar N intake among treatments. However, DLM fed fish presented the highest N gain and the lowest N losses, indicating that these fish were more efficient in retaining N than MHA fed fish. Similar results have been reported in studies performed with rainbow trout juveniles(Reference Powell, Chowdhury and Bureau16), where the relative bioavailability of MHA was compared with dl-Met by dose–response trials regarding growth performance and nutrient retention. Lower N losses are related to higher protein digestibility and/or lower catabolism, resulting in lower N release to the environment. The in vivo metabolic trial revealed that the amount of tracer present in the Incubation Water increased with time and was lower in fish fed the DLM diet than in MHA fed fish. Consequently, in the long-term trial this is reflected in the N balance, indicating that dietary dl-Met supplementation contributes to a reduction in the environmental impact of Nile tilapia farming.
In conclusion, dietary Met sources influence Met absorption and utilisation in Nile tilapia juveniles. The in vivo study indicated that dl-Met is more retained than MHA probably due to a faster absorption rate as well as a greater availability of free Met in the tissues to be utilised by Nile tilapia. Additionally, Met from the different sources appears to follow distinct metabolic pathways; while Met from the DLM seems to be transsulphurated, Met from MHA and REF diets is probably remethylated to Met to maintain the free Met pool. In the long term, dietary dl-Met supplementation of soy-based diets improved growth performance and N retention in Nile tilapia, reducing the environmental impact and contributing towards a more sustainable industry.
Acknowledgements
The authors would like to acknowledge the support of Evonik Operations GmbH (Germany) through project IsoMet, national funds from FCT – Foundation for Science and Technology (Portugal) through project UIDB/04326/2020 to CCMAR, and European Social Funds contracts IF/00482/2014/CP1217/CT0005 to S. E. and DL 57/2016/CP1361/CT0033 to C. A.
C. A., S. E. and K.M. conceived the experiment. K. M. formulated the experimental diets. M. C. and R.C. conducted the experimental trials and laboratory analysis. R. T. conducted laboratory and data analysis, and wrote the manuscript under the supervision of S. E. and C. A. All authors contributed to and approved the manuscript.
KM is a full-time employee of Evonik Operations GmbH.