Methionine Requirement of Juvenile Japanese Flounder Paralichthys olivaceus

Abstract.— Growth studies were conducted to determine the dietary methionine requirement of juvenile Japanese flounder Paralichthys olivaceus . A basal diet was formulated to contain 50% crude protein from casein and gelatin, as intact protein sources, supplemented with crystalline L-amino acids (CAA), to correspond to the amino acid pattern found in the whole body protein of the juvenile Japanese flounder, except methionine. Test diets contained six graded levels of L-methionine 0.53, 0.83, 1.13, 1.43, 1.73, and 2.03% of diet (dry matter basis) or 1.06, 1.66, 2.26, 2.86, 3.46 and 4.06% of protein. To prevent leaching losses of water-soluble amino acids, CAA were pre-coated with carboxymethylcellulose (CMC), and diets were further bound with both CMC and κ-carrageenan after addition of the pre-coated CAA. Weighing about 2.80 g, each triplicate group of the juvenile flounder were fed test diets twice a day (5% of body weight) for 40 d. Survival rate, specific growth rate, feed conversion efficiency and apparent protein retention were significantly ( P < 0.05) affected by dietary methionine concentrations. The optimum dietary level of methionine in the presence of 0.06% of dietary cystine for Japanese flounder juvenile was estimated by using break point analysis. The values determined based on weight gain and feed efficiency were 1.49% of diet (or 2.98% of protein) and 1.44% of diet (or 2.88% of protein), respectively. These requirement values are close to the methionine level of flounder whole body protein.     

Reevaluation of the Dietary Protein Requirement of Japanese Flounder Paralichthys olivaceus

An experiment was conducted to determine the dietary protein requirement by different analysis methods and to study the effects of dietary protein levels on growth performance and body composition in Japanese flounder Paralichthys olivaceus fed white fish meal and casein-based diets for 8 wk. After a 1-wk conditioning period, one of six isocaloric diets containing 30, 36, 42, 48, 54, and 60% crude protein (CP) was fed to fish at approximately 4–5% of wet body weight on a dry matter basis to triplicate groups of 15 fish averaging 13.3 ± 0.06 g (mean ± SD). After 8 wk of the feeding trial, weight gain (WG) and feed efficiency (FE) from fish fed 48% CP diet were similar to those from fish fed 42% and 54% CP diets, and were significantly higher than those from fish fed 30, 36 and 60% CP diets ( P < 0.05). Fish fed 48 and 54% CP diets had a significant higher specific growth rate (SGR) than did fish fed 30 and 36% CP diets ( P 0.05). Protein efficiency ratio (PER) was inversely related to the dietary protein level. No significant differences existed in hematocrit (PCV) and survival rate among the dietary treatments. Broken-line model analysis indicated that the optimum dietary protein level could be 44.0 ± 3.0% for maximum WG in Japanese flounder. Polynomial regression analysis of the dose-response showed that maximum WG occurred at 50.2% ( R² = 0.94) based on WG, and the second-order polynomial regression analysis with 95% confidence limits revealed that the range of minimum protein requirement was between 38.9% and 40.3% based on WG. Therefore, these findings suggest that the optimum dietary protein requirement for maximum growth of Japanese flounder is greater than 40%, but less than 44% CP in the fish meal and casein-based diets containing 17.0 kJ/g of energy.     

Effects of Dietary β-1,3 Glucan and Feed Stimulants in Juvenile Olive Flounder, Paralichthys olivaceus

Abstract.— The present study was conducted to investigate the effects of dietary supplementation of β‐1,3 glucan and a laboratory developed feed stimulant, BAISM, as feed additives for juvenile olive flounder, Paralichthys olivaceus. Eight experimental diets were formulated to be isonitrogenous and isocaloric and to contain 50.0% crude protein and 16.4 kJ of available energy/g with or without dietary β‐1,3 glucan and BAISM supplementation. β‐1,3 glucan (G) and BAISM (B) were provided at 0% in the control diet (G₀B₀) and at 0.05% G + 0.45% B (G_0.05B_0.45), 0.05% G + 0.95% B (G_0.05B_0.95), 0.1% G + 0.90% B (G_0.1B_0.9), 0.10% G + 1.90% B (G_0.1B_1.9), 0.15% G + 1.35% B (G_0.15B_1.35), 0.15% G + 2.85% B (G_0.15B_2.85), and 0.30% G + 2.70% B (G_0.3B_2.7) in experimental diets. After the feeding trial, fish fed G_0.1B_0.9, G_0.1B_1.9, and G_0.15B_1.35 diets had higher percent weight gain (WG), feed efficiency ratio (FER), specific growth rate (SGR), protein efficiency ratio (PER), and condition factor (CF) than those fed G₀B₀, G_0.05B_0.45, G_0.05B_0.95, G_0.15B_2.85, and G_0.3B_2.7 diets (P < 0.05); however, there was no significant differences among fish fed G_0.1B_0.9, G_0.1B_1.9, and G_0.15B_1.35 diets. Fish fed G_0.1B_0.9 and G_0.1B_1.9 diets had higher chemiluminescent responses (CL) than those fed the other diets (P < 0.05). Lysozyme activity of fish fed G_0.1B_0.9 diet was significantly higher than that of fish fed the other diets (P < 0.05). These results indicated that the optimum dietary supplementation level of β‐1,3 glucan and BAISM could be approximately 0.10% β‐1,3 glucan + 0.90% BAISM (G_0.1B_0.9) of diet based on WG, FER, SGR, PER, CF, CL, and lysozyme activity in juvenile olive flounder, P. olivaceus.     

Evaluation of Fermented Soybean Curd Residues as an Energy Source in Diets for Juvenile Olive Flounder, Paralichthys olivaceus

A 10‐wk feeding experiment was conducted to evaluate the potential use of fermented soybean curd residues (FSCR) as an energy source in diets for juvenile olive flounder, Paralichthys olivaceus. Five isonitrogenous and isoenergetic diets were formulated to contain dry soybean curd residues to replace wheat meal (WM) at the levels of 0, 25, 50, 75, and 100% (FSCR₀, FSCR₂₅, FSCR₅₀, FSCR₇₅, and FSCR₁₀₀, respectively). Fish averaging 6.00 ± 0.07 g (mean ± SD) were randomly distributed into 15 aquaria as groups of 15 fish and fed the experimental diets in triplicate at a rate of 4–5% of wet body weight per day twice daily on dry matter basis. At the conclusion of the feeding trial, weight gain (WG) and specific growth rate (SGR) of fish fed diet FSCR₂₅ were significantly higher than those of fish fed diets FSCR₅₀, FSCR₇₅, and FSCR₁₀₀ (P < 0.05); however, there were no significant differences in WG and SGR among fish fed diets FSCR₀ and FSCR₂₅ and among those fed diets FSCR₀ and FSCR₅₀. Feed efficiency and protein efficiency ratio of olive flounder fed diet FSCR₂₅ were significantly higher than those of fish fed diets FSCR₅₀, FSCR₇₅, and FSCR₁₀₀ (P < 0.05); however, there were no significant differences in these parameters among fish fed diets FSCR₀ and FSCR₂₅ and among those fed diets FSCR₀, FSCR₅₀, FSCR₇₅, and FSCR₁₀₀. Hematological characteristics, condition factor, hepatosomatic index, and survival rate of fish fed FSCR₀ were not significantly different from those of fish fed the other diets. These results indicated that FSCR could replace up to 50% WM as an energy source in juvenile olive flounder diets based on ANOVA test.     

Optimum Dietary Level of Chlorella Powder as a Feed Additive for Growth Performance of Juvenile Olive Flounder,Paralichthys olivaceus

ABSTRACT

The present study was conducted toestimate the optimum dietary supplementation level of Chlorella powder as a feed additive to optimize growth of juvenile olive flounder, Paralichthys olivaceus. Four experimental diets supplemented with Chlorella powder (CHP) at 0, 1, 2 and 4% (CHP₀, CHP₁, CHP₂, and CHP₄, respectively) of diet as a dry-matter (DM) basis were prepared. Three replicate groups of fish averaging 1.1±0.02 g were fed one of the four experimental diets for 12 weeks. After the feeding trial, fish fed the CHP₂ diet had a higher (P < 0.05) weight gain (819%) than did fish fed CHP₀ (707%) and CHP₁(712%); however, there was no significant difference between fish fed CHP₂ (8197%) and CHP₄ (7559%) as among fish fed CHP₀, CHP₁, and CHP₄ (P > 0.05). Fish fed CHP₂ had a higher (P < 0.05) feed efficiency (134%) than did fish fed CHP₀ (123%); however, there was no significant difference (P > 0.05) among fish fed CHP₀ (123%), CHP₁ (125%), and CHP₄ (125%) as among fish fed CHP1 (125%), CHP₂ (134%), and CHP₄ (125%). Fish fed CHP₂ and CHP₄ had a lower (P < 0.05) serum glucose level (average 32.9 mg/dL) than did fish fed CHP₀ and CHP1 (average 34.8 mg/dL). Fish fed CHP1 and CHP₂ had a lower (P < 0.05) serum glutamic oxaloacetic transaminase (GOT) level than did fish fed CHP0 and CHP₄. Glutamic pyruvic transaminase (GPT) levels significantly (P < 0.05) deceased as dietary CHP increased. Fish fed CHP₂ and CHP₄ had a less (P < 0.05) whole-body fat than did fish fed CHP₀. These results indicate that the optimum dietary supplementation level of Chlorella powder as a feed additive in juvenile olive flounder could be approximately 2% of diet.     

Effects of Putative Growth or Health‐Enhancing Dietary Additives on Juvenile Olive Flounder,Paralichthys olivaceus,Performance

The effect on growth and body composition of various dietary additives with putative growth or health‐enhancing properties were determined in juvenile olive flounder (25 g initial weight). Nine experimental diets were prepared to contain one of the following additives: control (Con) with no additive, Opuntia ficus‐indica ver. saboten (OF), propolis (PP), lactic acid bacteria (LA), γ‐poly‐glutamic acid (PG), onion extract (OE), organic sulfur (OS), Biostone® (BS), and fig extract (FE). Fishmeal, dehulled soybean meal, and corn gluten were used as the protein source of the experimental diets. Wheat flour and soybean oil were used as the carbohydrate and lipid sources, respectively. Dietary additives were included in each experimental diet at 1% at the expense of wheat flour except for the FE (aqueous), which was substituted at 1% of the amount of water added to the diet. Fish were hand‐fed to satiation twice a day for 6 d/wk for 6 wk. Weight gain of fish fed the OE diet was higher than that of fish fed with the PP diet. Chemical composition of fish was not different among the experimental diets. OE was the most effective dietary additive to improve performance of olive flounder among additives used in this study.     

Evaluation of Toxicity of Dietary Chelated Copper in Juvenile Olive Flounder,Paralichthys olivaceus,Based on Growth and Tissue Copper Concentration

The present study was conducted to determine the safe and toxic levels of dietary copper in juvenile olive flounder, Paralichthys olivaceus, fed Mintrex^® copper, a chelated dietary copper source. Fish averaging 3.8 ± 0.13 g (mean ± SD) were fed 1 of 10 diets (n = 3) containing 7 (Cu₀), 10.4 (CuM₅), 15.8 (CuM₁₀), 24.9 (CuM₂₀), 43.4 (CuM₄₀), 82.1 (CuM₈₀), 158 (CuM₁₆₀), 308 (CuM₃₂₀), 658 (CuM₆₄₀), and 1267 (CuM₁₂₈₀) mg Cu/kg diet. At the end of 12 wk of feeding trial, weight gain (WG), specific growth rate, and protein efficiency ratio of fish fed CuM₅ and CuM₁₀ diets were significantly higher than those fed CuM₈₀, CuM₁₆₀, CuM₃₂₀, CuM₆₄₀, and CuM₁₂₈₀ diets (P < 0.05). Survival of fish fed Cu₀, CuM₅, CuM₁₀, CuM₂₀, and CuM₄₀ diets was significantly higher than those of fish fed CuM₃₂₀, CuM₆₄₀, and CuM₁₂₈₀ diets. Whole‐body lipid content of fish decreased while whole‐body ash increased with dietary copper levels. Whole‐body and tissue copper concentrations increased with dietary copper levels. Although ANOVA test suggested that the toxic level of dietary Cu in juvenile olive flounder, P. olivaceus, could be 320 mg/kg diet, broken‐line analysis of WG indicated a level of 286 mg/kg diet when Mintrex^®Cu is used as the dietary copper source.     

First Evidence for Hybrid Breakdown in the Backcross of Olive Flounder,Paralichthys olivaceus,and Summer Flounder,Paralichthys dentatus

Hybrid and parental backcross experiments were performed using olive flounder, Paralichthys olivaceus, summer flounder, Paralichthys dentatus, and their female F₁ hybrids to examine hybrid fitness in the backcross. Fertilization rate, hatching rate, and combined fitness measure (CFM, product of fertilization rate and hatching rate) were detected and the results showed that the CFM of hybrid and backcross generations was reduced significantly compared to pure olive flounder crosses. Genomic inheritance from parents to backcross progeny was also detected by amplified fragment length polymorphism (AFLP). Almost all AFLP bands observed in parents were presented in backcross progeny (backcross1, 218/227; backcross2, 265/282), although 9 and 17 parental bands were missing in backcross1 and backcross2, respectively. Novel bands (absent in parents) also occurred in progeny at the frequencies of 5.63% (13/231) in backcross1 and 3.28% (9/274) in backcross2. Additionally, 27.40 and 31.18% of AFLP markers deviated from expected Mendelian ratio in backcross1 and backcross2, respectively. The present study suggests that genetic incompatibilities may exist between olive flounder and summer flounder. Furthermore, possible implications of segregation distortion for reduced hybrid fitness in backcross generations are discussed.     

Supplementation of Protein Hydrolysates to a Low‐fishmeal Diet Improves Growth and Health Status of Juvenile Olive Flounder,Paralichthys olivaceus

An 11‐wk feeding trial was conducted to evaluate three different protein hydrolysates as feed ingredients in high‐plant‐protein diets for juvenile olive flounder. Five experimental diets were fed to juvenile olive flounder to examine the effect of three different protein hydrolysates on growth performance, innate immunity, and disease resistance against bacterial infection. A basal fishmeal (FM)‐based diet was regarded as a high‐FM diet (HFM) and a diet containing soy protein concentrate (SPC) as a substitute for 50% FM protein was considered as a low‐FM diet (LFM). Three other diets contained three different sources of protein hydrolysates, including shrimp, tilapia, and krill hydrolysates (designated as SH, TH, and KH), replacing 12% of FM protein. All diets were formulated to be isonitrogenous and isocaloric. Triplicate groups of fish (15.1 ± 0.1 g) were handfed one of the diets to apparent satiation twice daily for 11 wk and subsequently challenged against Edwardsiella tarda. Growth performance and feed utilization of fish fed hydrolysate‐supplemented diets were significantly improved compared to those of fish fed the LFM diet. Dietary inclusion of the protein hydrolysates significantly enhanced apparent digestibility of dry matter and protein of the diets. In the proximal intestine, histological alterations were observed in the fish fed the LFM diet. The fish fed the hydrolysate diets showed significantly longer mucosal fold and enterocytes and greater number of goblet cells compared to fish fed the LFM diet. Respiratory burst activity was significantly higher in fish fed the TH and KH diets than fish fed the LFM diet. Significantly higher immunoglobulin levels were found in fish fed SH and KH diets compared to those of fish fed the LFM diet. Dietary inclusion of the protein hydrolysates in SPC‐based diets exhibited the highest lysozyme activity. Significantly higher superoxide activity was observed in groups of fish fed the KH diet. Fish offered the protein hydrolysates were more resistant to bacterial infection caused by E. tarda. The results of this study suggest that the tested protein hydrolysates can be used as potential dietary supplements to improve growth performance and health status of juvenile olive flounder when they were fed a LFM diet.     

Optimum Dietary Protein Levels and Protein to Energy Ratios in Olive Flounder Paralichthys olivaceus

The olive flounder Paralichthys olivaceus is one of the most commercially important fish species in Korea. In order to formulate better diets for cultured olive flounder we evaluated the optimum dietary protein requirements for larval, fry and juvenile olive flounder, and the optimum dietary protein to energy ratio for juvenile olive flounder. Results of four separate experiments suggested that the optimum dietary protein requirements were 60% in larvae (0.3 g), 46.4–51.2% in 4.1-g juvenile, and 40–44% in 13.3 g growing olive flounder. The optimum dietary protein to energy ratio based on weight gain, feed efficiency, specific growth rate, and protein retention efficiency was 27–28 mg protein/kJ 2 energy (35 and 45% CP for diets containing 12.5 and 16.7 kJ energylg diet, respectively).     

微生态制剂对牙鲆幼鱼脂肪酶的影响

试验结果表明,微生态制剂可提高牙鲆幼鱼消化道的脂肪酶活性,微生态制剂的使用方式和使用的间隔时间影响其使用效果。拌饲投喂与在水中同时使用微生态制剂,在7 d内使脂肪酶活性大大提高,但随后采用这种使用方式的试验组脂肪酶活性又迅速降低。而只在水中使用微生态制剂的各试验组的脂肪酶活性却随着试验的进行,逐步提高。有利于脂肪酶活性提高的最佳方案是只在水中使用微生态制剂,使用间隔时间为7 d,芽孢杆菌∶乳酸菌为10∶1,菌液密度为105/m l。     

舟山海域褐牙鲆全人工繁育技术研究

2010年3月至6月,在浙江省海洋水产研究所西闪试验场进行了舟山褐牙鲆全人工繁育技术研究。在水温16.0～23.0℃,盐度26～27,溶解氧5.0～6.0mg/L的条件下,历经60d的培育,累计育成平均全长3.6cm以上的牙鲆鱼苗80×104万尾,受精率87.9%,孵化率90.9%,全长3cm～5cm的鱼苗培育成活率32%。     

Use of Fermented Fisheries By-products and Soybean Curd Residues Mixture as a Fish Meal Replacer in Diets of Juvenile Olive Flounder, Paralichthys olivaceus

A 10‐wk feeding trial was conducted to evaluate the potential use of fermented fisheries by‐products and soybean curd residues mixture (FFSM) as a partial replacement for fish meal (FM) in the diet of juvenile olive flounder, Paralichthys olivaceus. Five experimental diets were formulated with FFSM replacing 0, 15, 30, 45, and 60% of the FM protein (FFSM₀, FFSM₁₅, FFSM₃₀, FFSM₄₅, and FFSM₆₀, respectively). Juvenile olive flounder averaging 5.99 ± 0.08 g (mean ± SD) were randomly distributed into aquaria at 15 fish/aquarium, with three replicate aquaria for each experimental diet. Weight gain (WG) of fish fed FFSM₀, FFSM₁₅, and FFSM₃₀ was significantly higher than that of fish fed FFSM₄₅ and FFSM₆₀ (P < 0.05). Also, WG of fish fed FFSM₄₅ was significantly higher than that of fish fed FFSM₆₀ (P < 0.05). There were no significant differences in WG among fish fed FFSM₀, FFSM₁₅, and FFSM₃₀ (P > 0.05). Specific growth rate (SGR) of fish fed FFSM₁₅ was significantly higher than that of fish fed FFSM₄₅ and FFSM₆₀ (P < 0.05). Also, SGR of fish fed FFSM₀, FFSM₁₅, FFSM₃₀, and FFSM₄₅ was significantly higher than that of fish fed FFSM₆₀ (P < 0.05). There were no significant differences in SGR among fish fed FFSM₀, FFSM₁₅, and FFSM₃₀ and among those fed FFSM₀, FFSM₃₀, and FFSM₄₅ (P > 0.05). Feed efficiency (FE) and protein efficiency ratio (PER) of fish fed FFSM₆₀ were significantly lower than those of fish fed FFSM₀, FFSM₁₅, FFSM₃₀, and FFSM₄₅ (P < 0.05); however, there were no significant differences in FE and PER among fish fed FFSM₀, FFSM₁₅, FFSM₃₀, and FFSM₄₅. Hepatosomatic index of fish fed FFSM₀, FFSM₁₅, and FFSM₃₀ was significantly higher than that of fish fed FFSM₆₀ (P < 0.05); however, there were no significant differences among fish fed FFSM₀, FFSM₁₅, FFSM₃₀, and FFSM₄₅ and among those fed FFSM₄₅ and FFSM₆₀. No significant differences were observed in condition factor and survival rate among all dietary groups tested. The whole‐body proximate composition averaged 75.0 (% dry matter basis [DM]), 8.66 (% DM), 16.38 (% DM), and 76.1%, for crude protein, crude lipid, ash, and moisture, respectively. Based on growth performance, the FFSM could replace up to 30% FM protein by the ANOVA test; however, broken‐line model analysis indicated 28.7% as an optimum replacement level in juvenile olive flounder diets.     

Dietary Soy Peptide Enhances Thermotolerance and Survival of Juvenile Japanese Flounder,Paralichthys olivaceus

Soy peptide (SP), a soy protein enzymatic hydrolysate, contains bioactive substances that could be utilized as an immune‐stimulating feed ingredient. The experiment evaluated the efficacy of dietary SP on promoting growth, and enhancing tolerance and survival to heat stress in juvenile Japanese flounder, Paralichthys olivaceus. Four diets were incorporated with different levels of SP (0, 2, 5, and 10%) and a 6‐wk feeding trial ensued. Following the feeding trial, the experimental groups were subjected to heat stress to measure survival rate and heat shock protein 70s (HSP70s) in gill, liver, and skin. Fish fed diets with SP inclusion showed considerable decrease in percent weight gain. Significantly higher lethal time values to 50% mortality (LT₅₀) value were recorded for fish fed 10% SP. Moreover, LT₅₀ values of fish fed 2 and 5% SP were significantly higher compared with fish fed control diet. HSP70s produced in all the tissues were significantly highest in fish fed 10% SP. HSP70s values were significantly higher in fish fed 2 and 5% SP compared with fish fed control diet. A significant reduction in HSP70s among all groups during recovery period was also observed. These results suggest that SP can be used to enhance the immune response and survival of P. olivaceus under heat stress.     

Effects of Water Velocity on Growth Performance of Juvenile Japanese Flounder Paralichthys olivaceus

Critical swimming speed (Ucrit) of juvenile Japanese flounder Paralichthys olivaceus with 12.5-cm body length was determined to be 1.8-body lengthkec. A feeding trial was conducted to investigate the effects of water velocity on growth and other nutritional parameters of juvenile flounder (initial mean body weight: 5.7 g/fish), which is a sedentary species. The fish were raised in three water velocities, < 0.3 body length/sec (control), 0.9 body length/sec (slow) and 2.1 body length/sec (moderate), for 8 wk. Over the course of the feeding trial, the weight gain of the control, slow and moderate groups of fish were. 634%. 671% and 564%. respectively (significant between slow and moderate groups). A second order polynomial suggested that the optimum water velocity occurred at about 1.0 body length/sec. The feed efficiency of the moderate group (1.48) was significantly lower than those of the control (1.56) and slow (1.56) groups, while there were no significant differences in feed intake (1.72–1.75% of wet biomass) among the treatments. Water velocity did not affect the proximate composition of the whole body; however, rearing the fish at the moderate water velocity did slightly but significantly reduce protein retention. Lipid content of fin muscles was significantly different among the treatments: control (14.9%), slow (17.6%) and moderate groups (11.6%). Unlike salmonids, water current does not seem effective for improving growth and feed efficiency in juvenile Japanese flounder.     

Effects of Dietary Supplementation of Barodon on Growth Performance,Innate Immunity and Disease Resistance of Juvenile Olive Flounder,Paralichthys olivaceus,Against Streptococcus iniae

This study was conducted to evaluate the effects of dietary supplementation of Barodon, an anionic alkali mineral complex, on growth, feed utilization, humoral innate immunity and disease resistance of olive flounder. A basal experimental diet was used as a control and supplemented with 0.1, 0.2, 0.3, 0.4, or 0.5% Barodon. Triplicate groups of fish (26.4 ± 0.2 g) were fed one of the diets to apparent satiation twice daily for 10 wk. The growth performance was enhanced (P < 0.05) linearly and quadratically in fish fed diets containing Barodon compared with that in fish fed the control. Feed utilization was significantly improved by Barodon supplementation. Serum lysozyme and antiprotease activities were increased quadratically in Barodon fed groups. Also, significantly higher superoxide dismutase activity was found in Barodon‐fed fish. Dietary supplementation of 0.1–0.3% Barodon resulted in significant enhancement of fish disease resistance against Streptococcus iniae. The findings in this study indicate that dietary supplementation of Barodon can enhance growth, feed utilization, innate immunity, and disease resistance of olive flounder and that the optimum level seems to be 0.1% in diets.     

Compensatory Growth of Olive Flounder,Paralichthys olivaceus,Fed the Extruded Pellet with Different Feeding Regimes

This study was performed to determine compensatory growth of juvenile olive flounder fed the extruded pellet (EP) with different feeding regimes. Seven treatments with triplicates of different feeding regimes were prepared; α fish was daily fed for 6 d a week throughout 8 wk (8WF); α fish was starved for 1 wk and then fed for 3 wk twice [(1WS + 3WF) × 2]; β fish was starved for 2 wk and then fed for 6 wk (2WS + 6WF); χ fish was starved for 5 d and then fed for 9 d four times [(5DS + 9DF) × 4]; δ fish was starved for 10 d and then fed for 18 d twice [(10DS + 18DF) × 2]; δ fish was starved for 2 d, fed for 5 d, starved for 3 d, and then fed for 4 d four times [(2DS + 5DF + 3DS + 4DF) × 4]; and φ fish was starved for 4 d, fed for 10 d, starved for 6 d, and then fed for 8 d twice [(4DS + 10DF + 6DS + 8DF) × 2], respectively. Total feeding day was all same, 36 d except for control group (48 d). Weight gain of flounder in the 8WF treatment was higher than that of fish in other treatments. And weight gain of flounder in the 2WS + 6WF treatment was higher than that of fish in the (5DS + 9DF) × 4 and (4DS + 10DF + 6DS + 8DF) × 2 treatments. Feed consumption of flounder in the 8WF treatment was higher than that of fish experienced feed deprivation. Feed efficiency ratio (FER), protein efficiency ratio (PER), and protein retention (PR) were not significantly different among treatments. Chemical composition of the whole body of fish with and without liver, except for moisture content of liver, was not different among treatments. T₃ level of fish in the 8WF and 2WS + 6WF treatments was higher than that of fish in the (5DS + 9DF) × 4 treatment. It can be concluded that juvenile olive flounder achieved better compensatory growth at 6‐wk refeeding after 2‐wk feed deprivation compared with that of fish with different feeding regimes. And T₃ level of fish seemed to partially play an important role in achieving compensatory growth.     

Dietary Phosphorus Requirement of Juvenile Red Drum Sciaenops ocellatus

Eight isoenergetic and isonitrogenous diets containing graded levels of inorganic phosphorus were fed to juvenile red drum Sciaenops ocellatus for an 11 week period. Red drum were maintained in a brackish water (5–6 ppt) recirculating system. There were no significant differences in weight gain or feed conversion. However, survival was generally lower for fish fed deficient diets. Phosphorus supplements up to 0.86% increased bone calcium and scale ash, calcium, and phosphorus values. Bone ash and phosphorus were not significantly affected above 0.71% dietary phosphorus. It appears that approximately 0.86% dietary phosphorus is needed for maximum tissue mineralization of juvenile red drum.