Introduction
Taurine (2-aminoethanesulfonic acid) is one of the dietary supplements that have been used to promote growth in aquaculture. Historically, taurine has not been considered as an essential amino acid for fish, however, recently taurine is being considered conditionally essential amino acidto promote growth performance in several species (Park et al., 2002; Kim et al., 2003, 2005, 2008b, 2008c; Takagi et al., 2006, 2011; Gaylord et al., 2007; Lunger et al., 2007; Qi et al., 2012, Lim et al., 2013). The major pathway for taurine synthesis from methionine in mammals is believed to involve the transformation of methionine to cystathionine by cystathionine synthetase, the transformation of cystathionine to cysteine by cystathionase, the oxidation of cysteine to cysteine sulfinate, the decarboxylation of cysteine sulfinate to hypotaurine and further oxidation of hypotaurine to taurine (Worden and Stipanuk, 1985). Rhodes and Davis (2011) reported that taurine in marine finfish is essential in a range of 2.6 to 72.0 g kg-1, besides, taurine requirement is directly related to cysteine sulfinic acid decarboxylase activity (Yokoyama, 2001).
Fish have a total sulfur amino acid requirement rather than a specific methionine requirement (Wilson and Halver, 1985). The presence of dispensable amino acid cysteine in the diet represents a sparing effect in that it reduces the need for methionine (Ahmed et al., 2003). An adequate amount of dietary cysteine spares methionine from cysteine synthesis. Thus, the requirement for total sulfur amino acid can be met by a proper mixture of methionine and cysteine. Consequently, sulfur amino acids are taurine precursors, and methionine and cysteine supplementation may spare dietary taurine requirement, supported by Jirsa et al. (2014) and Wang et al. (2014).
Rock bream Oplegnathus fasciatus is an economically important marine fish in East Asia, in 2013, its aquaculture production in Korea was approximately 782 metric tonnes (MOF, 2014). In recent years, along with the crescent interest in culture this species, has also increased the published studies on O. fasciatus nutrition (Kang et al., 1998; Wang et al., 2003; Kim et al., 2008a; Lim and Lee, 2009; Kim et al., 2013). To date, very limited information is available on dietary additives to promote growth in juvenile rock bream (Ko et al., 2008), dietary taurine has been estimated to be optimum at 8.8 mg g- (Lim et al., 2013) and 7.0 mg g-1 (Ferreira et al., 2014). However, there are no reports regarding sulfur amino acids biosynthesis and effects on growth performance of juvenile rock bream. Therefore, the objective of this study is to evaluate the taurine sparing effect of methionine and cysteine in juvenile rock bream Oplegnathus fasciatus diets.
Materials and Methods
Experimental diets
Five experimental diets were formulated using fish meal as the main protein source (Control diet) and also prepared by adding fixed methionine and cysteine at 0.5% each and graded taurine at 0%, 0.25%, 0.5% and 1.0% (S + Tau0, S + Tau0.25, S + Tau0.5 and S + Tau1.0, respectively), as presented in Table 1. The experimental diets were formulated to be isonitrogenous (49% crude protein) and isocaloric (17 kJ gross energy g-1). Energy levels of the diets were calculated based on 23.6, 17.2 and 39.5 kJ g-1 for protein, carbohydrate and lipid, respectively (NRC, 2011). Dietary cysteine and methionine concentrations were similar in levels among the experimental diets. Dietary taurine concentration increased proportionally with taurine supplementation levels, and the concentration (mg taurine g diet-1) was 0.8 in Control and S + Tau0, 3.2 in S + Tau0.25, 5.7 in S + Tau0.5 and 10.7 in S + Tau1.0. Experimental diets were prepared by thoroughly mixing the dry ingredients in an electric mixer, followed by the addition of oil and distilled water. This mixture was formed into dough, and pellets were made by passing the dough through a screw type pelleting machine and air drying the formed pellets for 48 hours. After drying, the pellets were ground, sieved into the proper pellet size, packed and stored at -20°C until use.
Table 1.*The experimental diets were prepared by fixed sulfur amino acid (methionine plus cysteine) at 1% and taurine at 0%, 0.25%, 0.5% and 1.0% (S + Tau0, S + Tau0.25, S + Tau0.5 and S + Tau1.0, respectively) to the Control diet; †Supplied by Suhyup Feed Company, Busan, Korea. ‡Contains (as mg kg-1 diet): Ascorbic acid, 300; dl-Calcium pantothenate, 150; Choline bitatrate, 3000; Inositol, 150; Menadione, 6; Niacin, 150; Pyridoxine․HCl, 15; Riboflavin, 30; Thiamine mononitrate, 15; dl-α-Tocopherol acetate, 201; Retinyl acetate, 6; Biotin, 1.5; Folic acid, 5.4; B12, 0.06. §Contains (as mg kg-1 diet): NaCl, 437.4; MgSO47H2O. 1379.8; NaH2P42H2O, 877.8; Ca(H2PO4)22H2O, 1366.7; K2HPO4, 2414; ZnSO47H2O, 226.4; Fe-Citrate, 299; Ca-lactate, 3004; MnSO4, 0.016; FeSO4, 0.0378; CuSO4, 0.00033; Calcium iodate, 0.0006; MgO, 0.00135; NaSeO3, 0.00025. ¶Supplied by Korea Bio-gen, Chungnam Province, Korea. #L-Methionine and L-Cysteine supplied by Sigma Chemical, St. Louis, Missouri, US.
Experimental fish and feeding trial
Juvenile rock bream O. fasciatus used in the present experiment were obtained from a commercial hatchery (Hungmin, Tongyoung, Korea) and transported to Feeds and Foods Nutrition Research Center, Pukyong National University, Busan, South Korea. Prior to initiation of the feeding trial, all fish were acclimated to the experimental conditions and fed control diet (Con) for 10 days. Groups of 25 fish with initial body weight of 2.75 ± 0.04 g (mean ± SD) were randomly chosen and stocked into each of 15 aquariums (40-L). Feeding rate was adjusted from 4% of BW day-1 to 3% of BW day-1 at the end of 4th week. Total fish weight in each aquarium was determined biweekly and the amount of diet fed to the fish was adjusted accordingly. Feeding was ceased 24 h prior to weighing to minimize fish stress. The feeding trial was conducted in an indoor semi-recirculation sea water system. Throughout the experiment, water temperature was maintained at 20 ± 1°C by a cooler at the water supply tank, water flow at 2.6 L min-1, dissolved oxygen above 7.5 mgL-1, salinity 31 ± 1 ppm and pH 7.7 ± 0.1.
Sample collection and analysis
At the end of the feeding trial, fish were starved for 24 h, counted and weighed to calculate weight gain (WG), feed efficiency (FE), specific growth rate (SGR), protein efficiency ratio (PER) and survival. After the final weighing, three fish per tank were randomly selected and used to determine hepatosomatic index (HSI) and condition factor (CF). Then, 10 fish per tank were randomly selected, minced and stored at -20°C until used for whole-body proximate composition and amino acids (taurine, methionine and cysteine) analysis. Proximate composition analysis of the experimental diets and fish wholebody were analyzed according to standard methods (AOAC, 2006). Samples of diets and fish were dried at 110°C for 24 h using a dry oven to determine their moisture content. Ash content was determined by incineration at 600°C in a muffle furnace. Crude protein content was determined using the Kjeldahl method (N × 6.25) after acid digestion, and crude lipid content was determined by soxhlet extraction using the Soxtec system 1046 (Foss, Hoganas, Sweden) after freeze-drying for 12 h. Samples were prepared for sulfur amino acids and taurine consisted of homogenized whole-body, 1% sulphosalicylic and centrifuged at 3,000 g for 20 min at 4°C. Amino acids concentrations were determined individually with using a Sykam S-433 automatic amino acid analyzer (Sykam, Eresing, Germany).
Statistical analyses
All data were analyzed by one-way ANOVA. When a significant effect of the treatments was observed, a least significant difference (LSD) test was used to compare means. Treatment effects were considered significant at P < 0.05. Broken line regression analysis (Robbins et al., 1979) of weight gain was applied to determine the optimum inclusion level of taurine in the diet of juvenile rock bream. All statistical analyses were carried out using the SAS 9.1 software (SAS Institute, Cary, NC, US).
Results
Data on weight gain (WG), feed efficiency (FE), specific growth rate (SGR), protein efficiency ratio (PER), hepatosomatic index (HSI), condition factor (CF), and survival rate of juvenile O. fasciatus fed the experimental diets are summarized in Table 2. After the feeding trial, growth performance of fish fed the S + Tau0.25, S + Tau0.5 and S + Tau1.0 diets were significantly higher than those of fish fed the Control diet (P < 0.05); however, there were no significant difference among those of fish fed the S + Tau0.25, S + Tau0.5 and S + Tau1.0 diets (P > 0.05). The WG of fish fed the S + Tau0.25, S + Tau0.5 and S + Tau1.0 diets was significantly higher than that of fish fed the Control and S+Tau0 diets. FE of rock bream fed S + Tau0, S + Tau0.25, S + Tau0.5 and S + Tau1.0 diets was significantly higher than that of fish fed Control diet; fish fed S+Tau1.0 diet showed significantly higher FE than those of fed S + Tau0 diet. SGR of fish fed S + Tau1.0 diet was significantly higher than that of fish fed Control diet; however, there were no significant differences among those of fish fed Control, S + Tau0 and S + Tau0.25, or among fish fed S + Tau0.25, S + Tau0.5 and S + Tau1.0. PER of fish fed S + Tau0, S + Tau0.25, S + Tau0.5 and S + Tau1.0 diets were significantly higher than that of fish fed Control diet. Broken line analysis for WG indicated that when dietary sulfur amino acids were supplied, the optimum taurine supplementation level was 0.33% (Fig. 1). There were no significant differences in HSI, CF and survival among fish fed all experimental diets.
Fig. 1.Broken line analysis of weight gain (%) in juvenile rock bream Oplegnathus fasciatus fed the experimental diets supplemented with sulfur amino acids and taurine for 8 weeks. Values on the X-axis are the taurine supplemented levels in experimental diets. Error bars represent standard deviation (n = 3).
Table 2.*Values are means from triplicate groups of fish, where the mean in each row with a different letters are significantly different (P < 0.05). †Refer to Table 1. ‡Pooled standard error of mean: SD/√n, n = 3 replicated tanks of fish per diet treatment. §Initial fish wet body weight (g). ¶Final fish wet body weight (g). #Weight gain (%), WG = 100 × (final weight – initial weight) × initial weight-1. **Feed efficiency (%), FE =100 × (wet weight gain x dry feed intake-1). ††Specific growth rate (%), SGR =[(ln final weight – ln initial weight) × days-1] × 100. ‡‡Protein efficiency ratio, PER =wet weight gain x protein intake-1 §§Hepatosomatic index, HSI = 100 × (liver weight x body weight-1). ¶¶Condition factor, CF = 100 × [fish weight × fish length (cm3) -1].
Data on proximate composition of juvenile rock bream fed the experimental diets are summarized in Table 3. Fish whole-body crude protein content steadily increased with the increase of dietary taurine level in the presence of sulfur amino acids in the diets. Whole-body protein content of fish fed S + Tau0.5 and S + Tau1.0 were significantly higher than those of fish fed Control and S + Tau0 diets. No significant differences were noted in fish fed S + Tau0.25, S + Tau0.5 and S + Tau1.0 diets, fish fed S + Tau0 and S + Tau0.25 diets, or among that of fish fed Control and S + Tau0 diets. Whole-body crude lipid content significantly decreased with the incremental levels of dietary taurine up to S + Tau0.5. Fish fed S + Tau0.5 and S + Tau1.0 showed significantly lower lipid content than that of fish fed Control, S + Tau0 and S + Tau0.25; however, there was no significant difference between that of fish fed S + Tau0.25 and S + Tau1.0, or between that of fish fed S + Tau0.5 and S + Tau1.0. No significant differences were evident for moisture and ash content of fish fed the experimental diets.
Table 3.*Means of three sampling batches from each tank; values in the same row with different letters are significantly different (P < 0.05). †Refer to Table 1. ‡Pooled standard error of mean: SD/√n, n = 3 replicated tanks of fish per diet treatment.
Taurine and sulfur amino acids (methionine and cysteine) concentrations in whole-body of fish fed the experimental diets are presented in Figs. 2a and 2b, respectively. Whole-body taurine content of fish fed the experimental diets showed an increase trend as taurine was supplemented in the diets. Fish fed the S + Tau1.0 diet had a significantly higher whole-body taurine content than those of fish fed the other experimental diets. Also, fish fed the S + Tau0.25 diet showed significantly higher taurine content than fish fed the Control and S + Tau0 diets; however, there were no significant differences between fish fed diets which were not supplemented by taurine (Control and S + Tau0). Whole-body sulfur amino acids content of fish fed the experimental diets supplied with methionine and cysteine (S + Tau0, S + Tau0.25, S + Tau0.5 and S + Tau1.0) was significantly higher than that of fish fed the Control diet.
Fig. 2.(a) Taurine and (b) sulfur amino acids (methionine plus cysteine) contents in whole-body of juvenile rock bream Oplegnathus fasciatus fed experimental diets prepared by adding fixed sulfur amino acids at 1% and graded taurine at 0%, 0.25%, 0.5% and 1.0% (S + Tau0.25, S + Tau0.5 and S + Tau1.0, respectively) to the Control diet. Different letter on each bar represents significant difference (P < 0.05). Error bars represent standard deviation.
Discussion
Methionine, cysteine and taurine supplementations promoted growth performance of rock bream, and indicated an increase trend with dietary taurine supplementation. Based on ANOVA test there seemed to be no benefits of increasing taurine supplementation in diets beyond 0.25%, in the presence of methionine and cysteine supplementation, as fish fed diets with superior supplemented levels of taurine did not significantly improved growth performance. However, according to broken line regression analysis of WG, optimum dietary taurine supplementation was estimated to be 0.33%, which indicates that the optimum inclusion level could be 4.2 mg taurine g diet-1 with sparing. The optimum dietary taurine supplementation level suggested in this experiment is lower than those found previously for rock bream, 7.0 mg (Ferreira et al., 2014) and 8.8 mg (Lim et al., 2013) taurine g-1 diet without sparing. The growth performance results of this experiment indicated that excessive taurine supplementation (S + Tau0.5 and S + Tau1.0) did not improve growth compared to the optimal taurine inclusion (S + Tau0.25), when sulfur amino acid (SAA) were supplemented. Similarly to the present feeding trial results, Qi et al. (2012) also found that with increasing dietary taurine, growth performance increased and then reached a plateau, with no beneficial effects when taurine was supplied above the required levels. However, fish fed methionine and cysteine diet (S + Tau0) did not show higher growth performance compared to Control diet. Conversely, Wang et al. (2014) reported that not only taurine supplementation but also methionine and cysteine significantly promoted growth performance in juvenile turbot Psetta maxima. Our growth performance finding suggests the possibility that juvenile O. fasciatus may have taurine biosynthesis capability, but may not be enough to meet its requirement.
A significantly positive linear relationship between the content of taurine accumulated in whole-body and the level of taurine in the diets was noted in the present study. This result is similar to our previous experiment with juvenile rock bream (Ferreira et al., 2014) as well as for those reported for juvenile flounder (Park et al., 2002; Kim et al., 2003, 2005a, 2005b, 2008b), juvenile red sea bream (Matsunari et al., 2008) and juvenile turbot (Qi et al., 2012). Moreover, Wang et al. (2014) also reported that juvenile turbot fed diets supplemented with methionine and cysteine did not significantly change taurine concentration compared to the Control diet. Whole-body SAA content were found to be higher in fish fed methionine and cysteine supplemented diets compared to that of fish fed diet without supplementation. However, no significant difference was observed in whole-body SAA content among fish fed SAA acids supplemented diets. Once, the major pathway for taurine synthesis in mammals is believed to involve the transformation of methionine to cystathionine, the transformation of cystathionine to cysteine, the oxidation of cysteine to cysteine sulfinate, the decarboxylation of cysteine sulfinate to hypotaurine and further oxidation of hypotaurine to taurine (Worden and Stipanuk, 1985), our result is more likely resulted from the accumulation of taurine and sulfur amino acids through the feed intake. The results of the present study associated to the above taurine biosynthesis pathway and the previous results with rock bream (Lim et al., 2013; Ferreira et al., 2014) may suggest that there was a possible taurine insufficiency in the Control and low taurine supplemented (S + Tau0) diets, as well as that the sulfur amino acids accumulated in the whole-body of rock bream may indicate that juvenile rock bream has a limited taurine biosynthesis ability through sulfur amino acids pathway. Park et al. (2002) reported similar results with olive flounder, and Kendler (1989) observed a decrease of whole body cystathionine in rainbow trout fed taurine supplemented diets, suggesting that species with taurine biosynthesis ability tend to show a reduced content of cystathionine in the whole-body with the increase of dietary taurine.
In the present study, while whole-body crude protein was found to be increased with increasing dietary taurine. In the presence of sulfur amino acids, crude lipid content significantly decreased with increasing of dietary taurine. These results are similar to our previous publication (Ferreira et al., 2014); however, the supplementation of methionine and cysteine in the diets enhanced the protein content in whole-body. In lipid metabolism, the roles of taurine include conjugation with bile acids in the liver which increase the use of the bile acids, the degradation of cholesterol metabolites and the participation in micelle formation contributing to fat absorption in the small intestine (Yokogoshi et al., 1999).
Although rock bream seems to have limited ability to synthesize taurine through sulfur amino acids pathway, its taurine requirement ranged between 3.3 to 4.2 mg taurine g-1 diet through supplementation of sulfur amino acids (methionine + cysteine) at a level of 27 mg g-1 diet. In our previous study, we reported that 0.62% taurine supplementation are required to improve growth in juvenile rock bream through broken line analysis of WG (Ferreira et al., 2014). Therefore, the findings of the present study indicated that growth could be improved in juvenile rock bream by supplementing taurine at a level approximately 50% lower than our previous experiment result (Ferreira et al., 2014). In other words, dietary supplementation of methionine and cysteine at a level of 1% could spare 0.25 to 0.33% of taurine in juvenile O. fasciatus diets.
This conclusion is based on broken line regression analysis of WG and ANOVA. Further studies are recommended to investigate the adequate supplementation levels of methionine and cysteine and the dietary sulfur amino acids modulations of taurine biosynthesis in juvenile rock bream.
References
- Ahmed IM, Khan A and Jafri AK. 2003. Dietary methionine requirement of fingerling Indian major carp, Cirrhinusmrigala (Hamilton). Aqua Int 11, 449-462. https://doi.org/10.1023/B:AQUI.0000004181.89420.a2
- AOAC (Association of Official Analytical Chemists). 2006. Official Methods of Analysis.18th ed. Association of Official Analytical Chemists, Gaithersburg, MD, US.
- Gaylord TG, Barrows FT, Teague AM, Johansen KA, Overturf KE and Shepherd B. 2007. Supplementation of taurine and methionine to all-plant protein diets for rainbow trout (Oncorhynchus mykiss). Aquaculture 269, 514-524. https://doi.org/10.1016/j.aquaculture.2007.04.011
- Jirsa D, Davis DA, Salze GP, Rhodes M and Drawbridge M. 2014. Taurine requirement for juvenile white seabass (Atractoscion nobilis) fed soy-based diets. Aquaculture 422-423, 36-41. https://doi.org/10.1016/j.aquaculture.2013.11.029
- Kang YJ, Lee SM, Hwang HK and Bai SC. 1998. Optimum dietary protein and lipid levels on growth in parrot fish (Oplegnathus fasciatus). Korean J Aquat Sci 11, 1 – 10.
- Kendler BS. 1989. Taurine: an overview of its role in preventative medicine. Prev Med 18, 79-100. https://doi.org/10.1016/0091-7435(89)90056-X
- Kim KM, Lee JU, Kim JW, Han SJ, Kim KD and Jo JY. 2008a. Daily feeding rates of parrot fish Oplegnathus fasciatus fed extruded pellet at the different water temperatures. Korean J Aquat Sci 21, 294-298.
- Kim SK, Matsunari H, Nomura K, Tanaka H, Yokoyama M, Murata Y, Ishihara K and Takeuchi T. 2008b. Effect of dietary taurine and lipid contents on conjugated bile acid composition and growth performance of juvenile Japanese flounder Paralichthys olivaceus. Fish Sci 74, 875-881. https://doi.org/10.1111/j.1444-2906.2008.01602.x
- Kim SK, Takeuchi T, Akimoto A, Furuita H, Yamamoto T, Yokoyama M and Murata Y. 2005b. Effect of taurine supplemented practical diet on growth performance and taurine contents in whole body and tissues of juvenile Japanese flounder Paralichthys olivaceus. Fish Sci 71, 627-632. https://doi.org/10.1111/j.1444-2906.2005.01008.x
- Kim SK, Takeuchi T, Yokoyama M and Murata M. 2003. Effect of dietary supplementation with taurine, beta-alanine and GABA on the growth of juvenile and fingerling Japanese flounder Paralichthys olivaceus. Fish Sci 69, 242-248.
- Kim SK, Takeuchi T, Yokoyama M, Murata Y, Kaneniwa M and Sakakura Y. 2005a. Effect of dietary taurine levels on growth and feeding behavior of juvenile Japanese flounder Paralichthys olivaceus. Aquaculture 250, 765-774. https://doi.org/10.1016/j.aquaculture.2005.04.073
- Kim SS, Rahimnejad S, Kim KW and Lee KJ. 2013. Partial replacement of fish meal with Spirulina pacifica in diets for parrot fish (Oplegnathus fasciatus). Turkish J Fish Aqua Sci 13, 197-204.
- Ko GY, Lim SG, Kim SS, Oh DH and Lee KJ. 2008. Effects of dietary supplementation of scoria on growth and protein digestibility in juvenile parrot fish Oplegnathus fasciatus and olive flounder Paralichthys olivaceus. Korean J Aquat Sci 21, 133-138.
- Kuzmina VV, Gavrovskaya LK and Ryzhova OV. 2010. Taurine. Effect on exotrophia and metabolism in mammals and fish. J Evol Biochem Phys 46, 19-27. https://doi.org/10.1134/S0022093010010020
- Lim SJ and Lee KJ. 2009. Partial replacement of fish meal by cottonseed meal and soybean meal with iron and phytase supplementation for parrot fish Oplegnathus fasciatus. Aquaculture 290, 283-289. https://doi.org/10.1016/j.aquaculture.2009.02.018
- Lim SJ, Oh DH, Khosravi S, Cha JH, Park SH, Kim KW and Lee KJ. 2013. Taurine is an essential nutrient for juvenile parrot fish Oplegnathus fasciatus. Aquaculture 414-415, 274-279. https://doi.org/10.1016/j.aquaculture.2013.08.013
- Lunger AN, McLean E, Gaylord TG, Kuhn D and Craig SR. 2007. Taurine supplementation to alternative dietary proteins used in fish meal replacement enhances growth of juvenile cobia (Rachycentron canadum). Aquaculture 271, 401-410. https://doi.org/10.1016/j.aquaculture.2007.07.006
- Matsunari H, Yamamoto T, Kim SK, Goto T and Takeuchi T. 2008. Optimum dietary taurine level in casein-based diet for juvenile red sea bream Pagrus major. Fish Sci 74, 347-353. https://doi.org/10.1111/j.1444-2906.2008.01532.x
- MOF (Ministry of Ocean and Fisheries). 2014. Statistical database for fisheries production. http://www.fips.go.kr Accessed: November 15, 2014.
- NRC (National Research Council). 2011. Nutrient Requirements of Fish and Shrimp.National Academies Press, Washington, DC, US.
- Park GS, Takeuchi T, Yokoyama M and Seikai T. 2002. Optimal dietary taurine level for growth of juvenile Japanese flounder Paralichthys olivaceus. Fish Sci 68, 824- 829. https://doi.org/10.1046/j.1444-2906.2002.00498.x
- Qi G, Ai Q, Mai K, Xu W, Liufu Z, Yun B and Zhou H. 2012. Effects of dietary taurine supplementation to a casein-based diet on growth performance and taurine distribution in two sizes of juvenile turbot (Scophthalmus maximus L.). Aquaculture 358-359, 122-128. https://doi.org/10.1016/j.aquaculture.2012.06.018
- Rhodes M and Davis DA. 2011. Taurine: critical supplement for marine fish feed. Global Aquaculture Advocate Nov/Dec: 34-35.
- Robbins KR, Norton HW and Baker DH. 1979. Estimation of nutrient requirements from growth data. J Nutri 109, 1710-1714. https://doi.org/10.1093/jn/109.10.1710
- Takagi S, Murata H, Goto T, Hatate H, Endo M, Yamashita H, Miyatake H and Ukawa M. 2011. Role of taurine deficiency in inducing green liver symptom and effect of dietary taurine supplementation in improving growth in juvenile red sea bream Pagrus major fed non-fishmeal diets based on soybean protein concentrate. Fish Sci 77, 235-244. https://doi.org/10.1007/s12562-011-0322-2
- Takagi S, Murata H, Goto T, Hayashi M, Hatate H, Endo M, Yamashita H and Ukawa M. 2006. Hemolytic suppression roles of taurine in yellowtail Seriola quinqueradiata fed non-fishmeal diet based on soybean protein. Fish Sci 72, 546 – 555.
- Wang Q, He G, Wang X, Mai K, Xu W and Zhou H. 2014. Dietary sulfur amino acid modulations of taurine biosynthesis in juvenile turbot (Psetta maxima). Aquaculture 422-423, 141-145. https://doi.org/10.1016/j.aquaculture.2013.12.014
- Wang X, Kim KM, Bai SC, Huh MD and Cho BY. 2003. Effects of the different levels of dietary vitamin C on growth and tissue ascorbic acid changes in parrot fish (Oplegnathus fasciatus). Aquaculture 215, 203-211. https://doi.org/10.1016/S0044-8486(02)00042-X
- Wilson RP and Halver JE. 1986. Protein and amino acid requirements of fishes. Ann Rev Nutri 6, 225-244. https://doi.org/10.1146/annurev.nu.06.070186.001301
- Worden JA and Stipanuk MK. 1985. A comparison by species, age and sex of cysteine sulfinate decarboxylase activity and taurine concentration in liver and brain of animals. Comp Biochem Physiol 82, 233-239. https://doi.org/10.1016/0300-9629(85)90732-7
- Yokogoshi H, Mochizuki H, Nanami K, Hida Y, Miyachi F and Oda H. 1999. Dietary taurine enhances cholesterol degradation and reduces serum and liver cholesterol concentrations in rats fed a highcholesterol diet. J Nutr 129, 1705-1712. https://doi.org/10.1093/jn/129.9.1705
- Yokoyama M, Takeuchi T, Park GS and Nakazoe J. 2001. Hepatic cysteine sulphinate decarboxylase activity in fish. Aquac Res 32, 216-220. https://doi.org/10.1046/j.1355-557x.2001.00017.x