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Role of creatine supplementation on the myofibre characteristics and muscle protein synthesis of grass carp (Ctenopharyngodon idellus)

Published online by Cambridge University Press:  05 May 2022

Juan Tian
Affiliation:
Key Laboratory of Freshwater Biodiversity Conservation, the Ministry of Agriculture and Rural Affairs, Yangtze River Fisheries Research Institute, Chinese Academy of Fishery Sciences, Wuhan, 430223, People’s Republic of China
Xiaoli Cheng
Affiliation:
Key Laboratory of Freshwater Biodiversity Conservation, the Ministry of Agriculture and Rural Affairs, Yangtze River Fisheries Research Institute, Chinese Academy of Fishery Sciences, Wuhan, 430223, People’s Republic of China College of Animal Science, Yangtze University, Jingzhou, People’s Republic of China
Lijuan Yu
Affiliation:
Key Laboratory of Freshwater Biodiversity Conservation, the Ministry of Agriculture and Rural Affairs, Yangtze River Fisheries Research Institute, Chinese Academy of Fishery Sciences, Wuhan, 430223, People’s Republic of China
Ming Jiang
Affiliation:
Key Laboratory of Freshwater Biodiversity Conservation, the Ministry of Agriculture and Rural Affairs, Yangtze River Fisheries Research Institute, Chinese Academy of Fishery Sciences, Wuhan, 430223, People’s Republic of China
Weihua Gao
Affiliation:
College of Animal Science, Yangtze University, Jingzhou, People’s Republic of China
Xing Lu
Affiliation:
Key Laboratory of Freshwater Biodiversity Conservation, the Ministry of Agriculture and Rural Affairs, Yangtze River Fisheries Research Institute, Chinese Academy of Fishery Sciences, Wuhan, 430223, People’s Republic of China
Wenbing Zhang
Affiliation:
College of Animal Science, Yangtze University, Jingzhou, People’s Republic of China
Hua Wen*
Affiliation:
Key Laboratory of Freshwater Biodiversity Conservation, the Ministry of Agriculture and Rural Affairs, Yangtze River Fisheries Research Institute, Chinese Academy of Fishery Sciences, Wuhan, 430223, People’s Republic of China
*
*Corresponding author: Dr H. Wen, fax +86 27 81780157, email [email protected]
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Abstract

To assess the role of dietary creatine on myofibre characteristics and protein synthesis in muscle, we fed grass carp (Ctenopharyngodon idellus, initial body weight: 88·47 ± 1·44 g) creatine-supplemented diets (1·84, 5·91, 8·48 and 15·44 g/kg diet) for 8 weeks. Creatine supplementation did not affect growth performance, but significantly increased creatine contents in muscle and liver. At 8·48 g/kg, creatine decreased the activities of alanine transaminase and aspartate aminotransferase in serum and improved hardness and chewiness of muscle due to shorter myofibre mean diameter, higher myofibre density and the frequencies of the diameters of classes I and III and collagen content, longer sarcomere length and upregulated mRNA levels of slow myosin heavy chains. Creatine supplementation upregulated the mRNA expressions of myogenic regulatory factors. The 8·48 g/kg creatine-supplemented diet significantly increased the contents of protein, total amino acids (AA), essential AA and free flavour AAs in muscle, the protein levels of insulin-like growth factor I, myogenic differentiation antigen and PPAR-γ coactlvator-1α in muscle and stimulated the phosphorylation of target of rapamycin (TOR) pathway in muscle. In summary, 8·48 mg/kg creatine improved fish health and skeletal muscle growth and increased hardness and protein synthesis in muscle of grass carp by affecting myofibre characteristics and the TOR signalling pathway. A second-order regression model revealed that the optimal dietary creatine supplementation of grass carp ranges between 8·48 and 12·04 g/kg.

Type
Research Article
Copyright
© The Author(s), 2022. Published by Cambridge University Press on behalf of The Nutrition Society

Aquatic products are sources of PUFA and essential amino acids (EAAs)(Reference Thurstan and Roberts1). Aquaculture products, which account for >50 % of the global fish consumption and provide ∼30 % of the daily animal protein consumption in developing nations, have reduced our dependence on fishing(Reference Wang, Cheng and Liu2). China has led the global aquaculture production in the past decades, especially freshwater aquaculture. Grass carp (Ctenopharyngodon idellus), which is one of the predominant farmed freshwater fish in the world, had a total production of 5·57 million tons in 2020(3). However, compared with wild grass carp, cultured grass carp has a lower content of protein and total amino acids in muscle and poor taste(Reference Ashraf, Zafar and Rauf4). Flesh quality is closely associated with human health and consumer acceptance; therefore, high-quality fish is an important target in aquaculture.

Flesh quality is evaluated by traditional physicochemical texture and sensory characteristics, which in a great degree is determined by structural properties such as collagen, characteristics and types of myofibre(Reference Choi and Kim5) and nutrients levels in muscle(Reference Lie6). In cultured fish, feed contributes to flesh quality due to dietary nutrients or special ingredients retained in a controlled manner(Reference Ayoola7). For instance, the hardness and muscle collagen content of grass carp are significantly enhanced by arginine supplementation(Reference Wang, Liu and Feng8). In white muscle of rainbow trout (Oncorhynchus mykiss), diets rich in soybean meal decrease the mean and median diameters of myofibres and the expression of myogenic differentiation antigen (MyoD) and increase the expression of fast myosin heavy chain (fast-MyHC)(Reference Alami-Durante, Wrutniak-Cabello and Kaushik9).

Creatine is a nitrogenous organic acid that is metabolised from arginine, methionine and glycine in the liver, kidneys and pancreas(Reference Negro, Avanzato, D’Antona, Nabavi and Silva10). Dietary creatine especially from meat and fish is transported to skeletal muscles, brain and testes and plays an important role in energy production during muscle contraction(Reference Gualano, Artioli and Poortmans11). Therefore, creatine supplementation has been used to improve exercise capacity in healthy individuals and athletes. In fish, creatine supplementation promotes flesh quality. At 12·5 g/kg, creatine increases muscle endurance in juvenile rainbow trout(Reference Mcfarlane, Heigenhauser and Mcdonald12). Our previous study on Litopenaeus vannamei showed that diets supplemented with 8·28 g/kg creatine enhanced the hardness and chewiness of muscle by improving the diameter and density of myofibres and increasing collagen content. Furthermore, creatine supplementation improves flesh nutrition and flavour by increasing levels of protein, EAA, and flavour free amino acids in muscle(Reference Cheng, Li and Leng13). In mice, creatine increases muscle protein content by phosphorylating serine/threonine kinase (protein kinase B, Akt), the target of rapamycin (TOR) and ribosome S6 protein kinase (P70S6K)(Reference Cunha, Budni and Ludka14). In rats, creatine transforms MyHCII myofibres to MyHCI(Reference Aguiar, Aguiar and Felisberto15) myofibres by regulating myogenic regulatory factors (MRF)(Reference Negro, Avanzato, D’Antona, Nabavi and Silva10). The creatine-induced myofibre transformation is mediated by the AMPK/PGC-1α (AMP-activated protein kinase/peroxisome proliferator-activated receptor-γ coactlvator-1α)(Reference Ceddia and Sweeney16) and TOR pathways(Reference Morita, Gravel and Hulea17). Therefore, creatine plays a central role in growth and nutrients levels of muscle by inducing gene expressions and participate in the TOR activation response. However, the effects of dietary creatine on fish flesh quality have not been systematically evaluated except for few studies that have evaluated the associations between creatine supplementation and growth performance(Reference Mcfarlane, Heigenhauser and Mcdonald12,Reference Cheng, Li and Leng13,Reference Ramos-Pinto, Lopes and Sousa18,Reference Schrama, Cerqueira and Raposo19,Reference Burns and Gatlin20) .

The continuous high aquaculture production of grass carp is due to intensive farming based on the high utilisation of artificial formulated feed(Reference Zhao, Xia and Zhang21). In general, the creatine content in grass carp feed is low because animal source feedstuffs are rarely used. Therefore, in the current study, the effect of dietary supplementation of four graded levels of creatine (1·84, 5·91, 8·48 & 15·44 g/kg) was evaluated on growth performance, feed utilisation, serum chemistry, flesh texture, proximate and amino acid composition, myofibre characteristics and metabolic pathways in grass carp. The study’s findings will provide a deeper understanding of dietary creatine on the flesh quality and creatine metabolism of fish, and thus eventually provide a novel technology to produce high-quality aquatic products.

Materials and methods

Ethics statement

The Institutional Animal Care and Use Committee of Yangtze River Fisheries Research Institute approved our study (YFI 2018-40).

Experimental diets

We designed a control diet based on the nutritional requirements of grass carp(22) and formulated three-creatine supplemented diets(Reference Mcfarlane, Heigenhauser and Mcdonald12,Reference Burns and Gatlin20) : 0 (T1), 3 (T2), 6 (T3) and 12 (T4) g/kg creatine monohydrate (Shanghai yuanye Bio-Technology Co., Ltd). The measured creatine contents in four diets were 1·84, 5·91, 8·48 and 15·44 g/kg. First, we pulverised the ingredients and mixed them uniformly with soybean oil. Second, we added different volumes of a creatine monohydrate solution (50 g/l water) based on the treatment. Third, we added water (300 ml/kg dry ingredients) and passed the mixture though a pelletiser with a dye (diameter: 2 mm). The diets were dried at 60°C for 4 h, broken into small pellets and stored at –20°C. Table 1 shows the ingredients and proximate compositions, and Table 2 shows the amino acid contents. Because of the determination method, even though the crude protein contents were different, the TAA contents were similar among the four diets.

Table 1. The ingredients and proximate composition of diets with creatine supplement

* Vitamin premix consisted of (mg/kg diet): vitamin A 4500 mg; vitamin D 1000 mg; vitamin E 100; vitamin K 5; thiamine 10; riboflavin 20; pyridoxine 10; cyanocobalamin 0·05; vitamin C 400; calcium pantothenate 100; folic acid 5;biotin 1; inositol 500; nicotinic acid 150.

Mineral premix consisted of (g/kg premix): KH2PO4, 321; NaCl, 101; MgSO4·7H2O, 150; Ca(H2PO4)2·H2O, 353; FeSO4·7H2O, 19·9; ZnSO4·7H2O, 3·56; MnSO4·4H2O, 1·62; CuSO4 5H2O, 0·31; CoCl2·6H2O, 0·01; KIO3, 0·03;AlCl3 6H2O, 0·25; Na2SeO3, 0·04.

Table 2. The amino acids compositions of diets with creatine supplement

ΣEAA, total essential amino acids; ΣAA, total amino acids.

Fish and feeding trial

The feeding trial was conducted at Yangtze River Fisheries Research Institute (Wuhan, China). We obtained grass carp from a commercial farm (Wuhan, China). Prior to the feeding trial, we maintained the fish in an indoor recirculation aquarium system for 2 weeks and fed them the control diet. The recirculation aquarium system was equipped with heating and cooling refrigeration and temperature control switches, which enabled the water temperature keep at the set value. After fasting for 24 h, we anaesthetised the fish with 80 mg MS-222/l water to minimise suffering. A total of 120 healthy fish of similar size (initial body weight: 88·47 ± 1·44) were selected, weighed and randomly distributed into 12 tanks (400 l water volume). Each diet was randomly assigned to triplicate tanks. Fish were hand-fed with the corresponding diet at 2 % to 3 % of their average body weight until apparent satiation(Reference Du, Liu and Tian23). The fish were fed 3 times daily at 08:30, 12:30 and 16:30. The trial was carried out with a natural photoperiod in recirculation aquarium system and lasted 8 weeks. The filtered freshwater was used as cultured water. Approximately 30 % of the wastewater was drained and replenished in each tank every 2 d. During the feeding period, we monitored the water quality daily at 8:00. Dissolved oxygen was >5·0 mg/l, water temperature was maintained at 27·0 ± 2·0°C, pH was 7·5 ± 0·1, NH4 +-N did not exceed 0·2 mg/l and NO2--N was <0·05 mg/l.

Sampling procedure

At the end of feeding trial, we counted the number of fish per tank and weighed them after a 24-h fasting period for the calculation of weight gain rate, specific growth rate, feeding rate and feed conversion ratio. After being anaesthetised with 200 mg MS-222/l water, the body weight and length of three fish per tank were measured, and blood samples were collected from vertebra vein with a 2-ml injector and stored at 4°C for 4 h. We obtained sera following centrifugation (3200 g/min, 10 min) and stored the serum at –80°C for free amino acid and blood chemistry analysis. We dissected the fish and weighed the viscera and liver to calculate condition factor, viscerosomatic index and hepatosomatic index. We cut the dorsal muscle was into a rectangle (1·0 cm × 1·0 cm × 0·5 cm) for texture analysis and collagen content determination. Additionally, we placed cuboidal muscles (0·2 cm × 0·2 cm × 0·2 cm) in fixative fluid containing 2·5 % glutaraldehyde and stored them at 4°C for transmission electron microscopy analysis. Other cuboidal muscle samples (0·5 cm × 0·5 cm × 0·5 cm) were dipped in PBS containing 4 % paraformaldehyde for 24 h and stored in 70 % alcohol for paraffin section analysis. The muscle samples for histology and transmission electron microscopy were taken from the same region from different fish across treatment.

Following euthanasia, we disinfected another three fish per tank using 75 % alcohol. We transferred muscle (0·2 g) from each fish into a 2-ml microcentrifuge tube, which was immediately frozen in liquid nitrogen and stored at –80°C for mRNA expression and Western blotting. Additionally, muscle (0·1 g) and liver (0·1 g) samples per fish were used for the measurement of creatine, glycocyamine and creatinine contents. We stored the remaining muscle samples at –40°C for amino acid profile and proximate composition analysis. Finally, three fish per tank were stored at –20°C for whole-body composition analysis.

Serum chemistry

The serum triacylglycerol and glucose levels were measured using commercial kits based on the GK-GPO-POD method and hexokinase method, respectively. The serum total protein was estimated using commercial kits based on the bicinchoninic acid assay. The serum enzymatic activities of alanine transaminase and aspartate aminotransferase were estimated using commercial kits based on the LDH-UV method and MDH-UV method, respectively. All the above parameters were quantified in an automatic biochemistry analyser (CHEMIX-800, Sysmex Corporation). All kits were purchased from Sysmex Corporation.

Creatine and metabolite analysis

The levels of creatine and its metabolites in diets, muscle and liver were analysed as previously reported(Reference Cheng, Li and Leng13). Briefly, the samples were homogenised and centrifuged (0·1 g), the supernatants were passed through a 0·45-μm filtration membrane and analysed using ultrahigh-performance liquid chromatography coupled with a triple quadrupole-mass spectrometry (UPLC-QqQ-MS) in multiple reaction monitoring mode with an Acquity UPLC system (Waters Corp.). To quantify and identify the peaks, the standards of creatine, creatinine and glycocyamine were added to the samples. We normalised and converted the peak areas into a two-dimensional data matrix using Excel 2010 software (Microsoft).

Proximate composition and collagen determination in muscle

The contents of crude protein, crude lipid and ash, respectively, in the diets, muscle and whole body were detected using Micro-Kjeldahl, Soxhlet and combustion methods(24). For the determination of moisture, we placed the samples in a vacuum freeze dryer (Christ Beta 2–4 LD plus LT, Marin Christ Corporation) for 48 h. The crude protein content was determined using the Kjeldahl method (n × 6·25). The crude lipid content was measured using the extraction method of ether-methanol. The ash content was determined by incinerating samples at 550°C for 24 h in a muffle furnace (PCD-E3000 Serials, Peaks, Japan). To estimate collagen content, we measured hydroxyproline (Hyp) using UV–vis spectrophotometry(Reference Zhang, Ai and Mai25). Briefly, muscle samples (1·0 g) were homogenised in cold water (9 ml, 4°C) for 1 min and mixed with ice cold sodium hydroxide (0·2 M, 10 ml) at 4°C on a wheel roller for 4 h. Following centrifugation at 10 000 g for 30 min at 4°C, we collected and stored the supernatant (1 ml) at 4°C for Hyp content determination.

Texture analysis

The texture profile analysis was performed within 2 h of sample collection as previously reported(Reference Wu, Wen and Tian26). Texture indexes including hardness, springiness, gumminess, chewiness, cohesiveness and resilience were measured using a Perten Ruihua instrument (model TVT-300XP) equipped with a cylindrical stainless-steel probe of 50 mm diameter and analysed using a texture analyser program (version 3.42, Perten Instruments Inc.).

Microscopy evaluation

The muscle samples were dehydrated in a series of xylene and alcohol solutions, embedded in paraffin, sliced and stained with haematoxylin-eosin to evaluate the morphology. We captured images (15 images/sample) using a microscope (Olympus BX53).

The transmission electron microscopy analysis of muscle samples was conducted in the Electron Microscope Center of Renmin Hospital of Wuhan University (Wuhan, China). Briefly, the muscle samples were washed 3 times with phosphate buffer (0·1 mmol/l, pH = 7·4) for 15 min each time and fixed with 1 % OsO4 in phosphate buffer (0·1 mmol/l, pH = 7·4) for 2 h at room temperature. Following the removal of OsO4, the samples were rinsed 3 times (15 min each) in phosphate buffer (0·1 mmol/l, pH = 7·4). Subsequently, the samples were dehydrated in a series of alcohol solutions, embedded in epoxy resin for 6 h at 37°C and moved the embedding models with resin and samples into 65°C oven to polymerise for more than 48 h. And then the resin blocks were taken out from the embedding models for standby application at room temperature. The resin blocks were cut to 70 nm thin on the Leica UC7 ultra-microtome. Finally, the ultramicrocuts were stained with 2 % uranium acetate saturated alcohol solution avoid light for 8 min. The images were took using Hitachi HT7800 TEM.

The myofibre characteristics including myofibre diameter (a minimum of fifty myofibres width per image), density (myofibre number per unit area), length of sarcomere and I-band and A-band (a minimum of twenty length/image) were analysed using the Image J Launcher software. Myofibre diameter was calculated as follow: one myofibre area was measured and then the mean diameter was calculated according to πR 2 formula (at least tested fifty myofibres per image). Then the myofibre fibres were divided into three classes according to the calculated diameter (d, μm). Classes I, II and III were categorised according to d ≤ 60, 60 < d ≤ 100 and d > 100, respectively. Class I muscle fibres were categorised as hyperplasia fibres. Class III fibres were categorised as hypertrophic fibres. Myofibre density was a rate of the total number of myofibres in the unit area. The length of the sarcomere is obtained from the shortest distance between two adjacent Z-disk. I-band length was calculated by two deepest points that were perpendicular to the same Z-disk (at least tested 20 length/image). A-band length was analysed by the distance between two boundaries that belong to the same A band in the longitudinal direction (at least tested twenty length per image).

Analysis of composition and content of amino acids

For combined amino acid analysis, we transferred the freeze-dried diets (0·2 g) and muscle (0·1 g) to sealed tubes. The samples were hydrolysed with 6 M hydrochloric acid (15 ml) at 110°C for 24 h. After filtering the hydrolysed solutions with medium speed filter paper, their volumes were adjusted to 100 ml with distilled water. Using a vacuum dryer, the filtrates (1·5 ml) were dried twice in vacuum dryer for 24 h to avoid hydrochloric acid corroding separation column. For free amino acids analysis, the serum (400 μl) and fresh muscle (1·0 g) were mixed with 3 ml of 10 % sulfosalicylic acid. Following incubation at room temperature, the samples were centrifuged at 18 000 g/min for 15 min at 4°C. After pretreatment, approximately 1 ml of samples was passed through a 0·22-μm Millipore membrane and analysed using an amino acid analyser (HITICHI L-8900).

Real-time qPCR

Using TRIzol reagent (Life Technologies), we extracted total RNA from muscle tissue and reversed-transcribed 4 μg RNA to cDNA using PrimeScript® RT reagent kit (Takara). The quantitative real-time PCR (qRT-PCR) was performed using a quantitative thermal cycler (Light 217 Cycler 480II, Roche) with SYBR® Premix Ex TaqTM (Takara). Table 3 shows the sequences of target genes and housekeeping genes (18S). These primers were successfully used in previous studies in grass carp(Reference Zhao, Xia and Zhang21,Reference Nihei, Kobiyama and Ikeda27) . The volume of qRT-PCR reaction was 20 μl including 10 μl SYBR® Premix Ex Taq, 2 μl cDNA sample, 6 μl nuclease-free water, 0·8 μl forward/reverse primers (10 μM) and 0·4 μl ROX reference dye II. The qRT-PCR conditions were the following, 95°C for 5 min, followed by forty cycles of 95°C for 30 s, 60°C for 30 s and 72°C for 30 s, and one step at 72°C for 5 min. Each sample was measured three times. We calculated mRNA expression levels using the 2−ΔΔCT method.

Table 3. Nucleotide sequences of primers and cycling conditions used for PCR amplification

18s, ribosomal protein 18; fMyHC S , s-myosin heavy chain; fMyHC c , c-myosin heavy chain; fMyHCs 30 , S30-myosin heavy chain; fMyHCs 10 , S10-myosin heavy chain; MyoG, myogenic determination gene; MyoD, myogenic differentiation antigen.

Western blotting

Western blotting was performed as previously reported(Reference Shi, Jin and Sun28,Reference Tian, Lu and Jiang29) . The antibodies used in this study were successfully used in previous studies in grass carp(Reference Shi, Jin and Sun28,Reference Tian, Lu and Jiang29) ; the antibodies against these antigenic regions are conserved in fish. We obtained antibodies against phospho-TOR (Ser2448, P-TOR; Cat. no. 2971), TOR (Cat. no. 2972), phospho-ribosomal protein S6 kinase (Thr 389; P-S6K1; Cat. no. 9205), S6K1 (Cat. no. 9206), phospho-4E-binding protein 1 (Thr37/46; P- 4E-BP1; Cat. no. 9459), 4E-BP1 (Cat. no. 9452) and β-tubulin (Cat. no. 2146) from Cell Signaling Technology Inc. Wuhan ABclonal Biotechnology Co. Ltd supplied the antibodies against IGF-I (insulin-like growth factor I; Cat. no. A11985), MyoD1 (Cat. no. A16218) and PGC1α (Cat. no. A11971). We used Image J Launcher software to quantify band intensity.

Statistical analysis

The data were expressed as mean ± sd. The homogeneity of variances and normality of the data were evaluated prior to statistical analysis. Using SPSS 20.0 statistical software (SPSS Inc.), we performed one-way ANOVA and Tukey’s multiple comparison tests. P < 0·05 represented statistical significance.

Results

Growth performance

After an 8-week feeding trial, the survival rate of grass carp was 100 % in all treatments (Table 4). Feed conversion ratio, feeding rate, condition factor, hepatosomatic index and viscerosomatic index were not different among the four treatments (P > 0·05). Fish fed 8·48 g/kg creatine (T3) had the highest weight gain rate and specific growth rate; no significant differences were obtained among the other diets (P > 0·05).

Table 4. Effects of creatine-supplemented diets on growth performance of grass carp

(Mean values and standard deviations)

* Weight gain rate (WGR, %) = 100 × (final body weight – initial body weight)/initial body weight.

Specific growth rate (SGR, %/d) = 100 × ln (final weight/initial weight)/d.

Feed conversion ratio (FCR) = dry feed consumed/(final biomass – initial biomass + dead fish).

§ Feeding rate (FR) = 100 × dry feed consumed × 2/(final body weight + initial body weight)/d.

Condition factor (CF) =100 × (body weight/body length3).

Hepatosomatic index (HSI, %) =100 × (hepatosomatic weight/whole-body weight).

** Viscerosomatic index (VSI, %) = 100 × (viscerosomatic weight/whole-body weight).

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Tukey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

Haematological data

Table 5 shows that the contents of glucose and total protein in serum were not different among the four treatments (P > 0·05). The activities of alanine transaminase and aspartate aminotransferase in serum decreased with increasing dietary creatine supplemented levels, mainly in T3 and T4 (P < 0·05). The triacylglycerol concentrations in serum significantly decreased in T3 than in the control (P < 0·05).

Table 5. Effects of creatine-supplemented diets on haematological data of grass carp

(Mean values and standard deviations)

TG, triacylglycerol; GLU, glucose; TP, total protein; ALT, alanine transaminase; AST, aspartate aminotransferase.

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Turkey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

Creatine metabolism analysis

Table 6 shows that muscle creatine contents increased with dietary creatine, mainly in T3 and T4 (P < 0·05). The concentrations of creatine and creatinine in liver increased with >5·91 g/kg creatine (P < 0·05). There were no differences in glycocyamine contents in muscle and liver among the four treatments (P > 0·05).

Table 6. Effects of creatine-supplemented diets on the contents of creatine and metabolites in the muscle and liver of grass carp

(Mean values and standard deviations)

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Tukey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

Muscle textural properties

Table 7 shows that creatine supplementation increased muscle hardness, chewiness and gumminess. These indicators were significantly higher in T3 than in the control (P < 0·05). Muscle cohesiveness showed a decreasing tendency with increasing dietary creatine levels; T4 (15·44 g/kg) had the lowest cohesiveness value (P < 0·05). Springiness and resilience of muscle were unaffected by creatine levels (P > 0·05). Second-order polynomial regression analyses based on flesh hardness revealed that the optimum creatine requirement supplementation for grass carp was 9·56 g/kg (Fig. 1).

Table 7. The muscle textural properties of grass carp fed diets with creatine supplement

(Mean values and standard deviations)

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Turkey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

Fig. 1. Second-order polynomial regression analyses between flesh hardness and dietary creatine levels for grass carp.

Morphology of myofibre

Fish in T3 and T4 exhibited tighter myofibre arrangement (Fig. 2(a)) and smaller myofibre mean diameter (Fig. 2(b)) than those in the control group. Statistical analysis (Fig. 2(c)) revealed that fish fed 8·48 g/kg creatine had the smallest myofibre mean diameter and the highest myofibre density, which were different to those in control fish (P < 0·05). The frequency distribution of the myofibres diameters is presented in Fig. 2(c) in regard to the muscle fibre frequency distribution, class II was higher than class I and class III in all treatment. Diameter classes I (hyperplasia fibres) was significantly higher in T3 and T4 than that in the control (P < 0·05). Frequencies of class III (hyperplastic fibres) were significantly higher in T2 and T3 than that in the control (P < 0·05).

Fig. 2. Effects of creatine-supplemented diets on microstructure of muscle of grass carp. (a) Longitudinal sections of muscle. FD: myofibre diameter. (b) Cross-sections of muscle. MF: muscle fibre. Magnification: 200×. (c) The myofibre diameter and density of muscle in grass carp (n 3). Classes I, II and III were categorised according to diameter = d ≤ 60, 60 < d ≤ 100 and d > 100, respectively. Class I myofibres were categorised as hyperplastic/hyperplasia fibres. Class III myofibres were categorised as hypertrophic fibres.

The transmission electron microscopy images of fish myofibril in T1 and T3 are shown in Fig. 3. Complete mitochondrion and sarcoplasmic reticulum were evident in T1 and T3, and myofibrils were made of regular sarcomeres. The Z line, M line, I-band and A-band appeared (Fig. 3(a)). Compared with the control fish, fish fed 8·48 g/kg creatine had longer sarcomere and I-band length (P < 0·05; Fig. 3(b)).

Fig. 3. Effects of creatine-supplemented diets on morphology of myocytes of grass carp. (a) Transmission electron microscope of fish sarcomere; a: Myofibrillar structure in control group, 8000×magnification; b: Myofibrillar structure in 8·48 g/kg group, 8000×agnification. sr, sarcoplasmic reticulum; tc, terminal cisternae; TT, transverse tubules. (b) Myofibrillar sarcomere length, I-band and A-band width in control group and 8·48 g/kg group (n 3).

Proximate composition and collagen content

Table 8 shows that dietary creatine levels had no significant impact on whole-body composition (P > 0·05). The contents of moisture, ash and crude fat in muscle were not affected by dietary creatine levels (P > 0·05). Muscle crude protein content significantly increased with 8·48 g/kg creatine (P < 0·05).

Table 8. Effects of creatine-supplemented diets on proximate composition and collagen contents in the muscle of grass carp

(Mean values and standard deviations)

Hyp means hydroxyproline.

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Turkey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

Fish fed creatine had higher contents of total Hyp and alkaline-insoluble Hyp than the control fish (P < 0·05). The alkaline-soluble Hyp content was unaffected by dietary creatine levels (P > 0·05).

We used second-order polynomial regression analyses to assess the optimum creatine requirements for maximum Hyp levels. The results revealed that the optimum creatine supplementation was 12·04 g/kg (Fig. 4).

Fig. 4. Second-order polynomial regression analyses between flesh Hyp contents and dietary creatine levels for grass carp.

Amino acid composition in muscle

Table 9 shows the amino acid composition and contents in muscle. The contents of total amino acids and EAA increased with dietary creatine levels and were significantly higher in T3 than in the control (P < 0·05). The contents of aspartic acid, glutamic acid, leucine and lysine in muscle shared a similar increasing trend and were significantly higher in T3 (P < 0·05) than in the control. The contents of methionine and phenylalanine gradually increased in response to dietary creatine levels and achieved the maximum levels in T4 (P < 0·05). Glycine content was higher in creatine-supplemented diets than in the control (P < 0·05). Fish fed 8·48 g/kg creatine had lower proline content compared with fish fed 15·44 g/kg creatine (P < 0·05). There were no significant effects on the contents of other amino acids (P > 0·05).

Table 9. Effects of creatine-supplemented diets on muscle amino acid composition of grass carp

(Mean values and standard deviations)

ΣEAA, total essential amino acids; ΣAA, total amino acids.

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Turkey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

Free amino acid composition in muscle

The results of free amino acids in muscle are shown in Table 10. Free flavour free amino acids including aspartic acid, glycine, glutamic acid and alanine increased with ≥ 8·48 g/kg creatine (P < 0·05). The concentrations of free total amino acids and free EAA gradually increased in response to dietary creatine supplementation and were significantly higher in T4 than in other treatments (P < 0·05). Furthermore, the contents of free serine, threonine, valine, isoleucine, leucine and phenylalanine increased, reaching maximum values in T4 (P < 0·05). Free arginine content was higher in T3 than in other treatments (P < 0·05). Compared with the control, free hydroxylysine content was lower in T4 (P < 0·05). No significant differences were obtained with other free amino acids (P > 0·05).

Table 10. Effects of creatine-supplemented diets on free amino acid composition in the muscle of grass carp

(Mean values and standard deviations)

ΣFAA, total flavour amino acids; ΣEAA, total essential amino acids; ΣAA, total amino acids.

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Turkey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

Free amino acid composition in serum

Free TAA content in serum was higher in T4 than in other treatments (Table 11; P < 0·05). The free EAA contents were higher in creatine-supplemented diets than in the control (P < 0·05). The contents of free threonine, valine and phenylalanine in serum significantly increased in T4 (P < 0·05). T2 had the highest values of free isoleucine, leucine and lysine (P < 0·05), and T4 had the highest values of free arginine and glutamic acid in serum (P < 0·05).

Table 11. Effects of creatine-supplemented diets on free amino acid composition in the serum of grass carp

(Mean values and standard deviations)

ΣEAA, total essential amino acids; ΣAA, total amino acids.

Data are presented as means ± SD (n 3 tanks) and were analysed by one-way ANOVA followed by Turkey’s multiple comparison test.

Different letters indicate the effect was significantly different between treatments (P < 0·05).

mRNA expression levels

Fig. 5 shows that supplemental creatine significantly downregulated the mRNA levels of fast fibre genes including fMyHCs and fMyHCc, which reached the lowest values in T3 (P < 0·05). Conversely, supplemental creatine increased the mRNA levels of slow fibre genes including fMyHC S10 and fMyHC S30 , mainly in T3 (P < 0·05). Creatine supplementation enhanced the expression levels of myogenic regulator factors (MRF) including MyoG and MyoD in muscle, which reached their highest values in T4 (P < 0·05).

Fig. 5. Effects of creatine-supplemented diets on relative mRNA expression of genes in muscle of grass carp. (a) fMyHCs and fMyHCc expressed in fast skeletal muscle. (b) fMyHC S10 and fMyHC S30 expressed in slow skeletal muscle. (c) Myogenic regulator factors (MyoG and MyoD) expressed in skeletal muscle of grass carp (n 3).

Effects of dietary creatine on nutrient sensing networks

Diets supplemented with 5·91 and 8·48 g/kg creatine significantly increased the protein expressions of IGF-I, MyoD1 and PGC-1α in muscle (Fig. 6; P < 0·05). Additionally, 8·48 g/kg creatine increased the phosphorylation of TOR, S6K1 and 4E-BP1 in muscle (P < 0·05).

Fig. 6. Effects of creatine-supplemented diets on nutrient-sensing signalling pathways in muscle of grass carp (n 3). IGF-I, insulin-like growth factor I; MyoD1, myogenic differentiation antigen; PGC-1α, peroxisome proliferator-activated receptor-γ coactivator-1α; TOR, target of rapamycin; p-TOR, phosphorylated TOR; 4EBP1, eukaryotic translation initiation factor 4E-binding protein 1; p-4EBP1, phosphorylated 4EBP1; S6K1, ribosome S6 protein kinase 1; p-S6K1, phosphorylated S6K1.

Discussion

In this study, grass carp fed 8·48 g/kg creatine had the highest weight gain rate; however, it was not significantly to that of control fish. Similar results have been reported in juvenile rainbow trout(Reference Mcfarlane, Heigenhauser and Mcdonald12), L. vannamei (Reference Cheng, Li and Leng13) and gilthead seabream (Sparus aurata)(Reference Ramos-Pinto, Lopes and Sousa18,Reference Schrama, Cerqueira and Raposo19) . In red drum, 19·8 g/kg creatine improved weight gain and feed efficiency(Reference Burns and Gatlin20). The possible explanation for this inconsistency may be attributed to differences in fish species and feeding environments such as surrounding temperature(Reference Borchel, Verleih and Rebl30). Further research should be conducted to draw more definitive conclusions.

Blood biochemical parameters are usually used to determine the general health status of fish(Reference Wagner and Congleton31). Aspartate aminotransferase and alanine transaminase are amino transferases related to amino acid metabolism. When organs such as liver are damaged, their activities in serum will be increased(Reference Ohgo, Yokoyama and Hirose32). We found for the first time in fish that 8·48–15·44 g/kg creatine decreased the activities of aspartate aminotransferase and ALT in serum, and 8·48 creatine decreased serum triacylglycerol content, which were consistent with the results reported in rats(Reference da Silva, Leonard and Jacobs33). These results suggested creatine supplementation had a positive effect on fish health.

It is important to understand the metabolic process of feed additives in fish. In general, creatine synthesis is initiated in the kidneys with the formation of guanidinoacetate from arginine and glycine, a reaction catalysed by glycine amidinotransferase. Guanidinoacetate is released by the kidneys and methylated in the liver to produce creatine, which mainly accumulates in the muscle (95 %) and to a lesser extent in the liver, brain, kidneys and testes. Finally, creatine triggers a series of reactions to improve muscle performance and is primarily broken down into creatinine(Reference Brosnan and Brosnan34). The major function of exogenous creatine is to maximise the intracellular pool of total creatine(Reference Burns and Gatlin20); however, the effect of creatine supplementation on the content of glycocyamine and creatinine in fish is unknown. In this study, we measured the contents of creatine, creatinine and glycocyamine in muscle and liver of fish. Creatine supplementation increased creatine levels but did not affect the contents of creatinine and glycocyamine in muscle. Furthermore, creatine supplementation increased the contents of creatine and creatinine in the liver. Extensive retention of creatinine in liver may cause hepatic traumatic necrosis and high-grade nephrosis(Reference Ejiofor, Ebhohon and Ndukaku35), suggesting that dietary creatine should be appropriate in grass carp. The content of glycocyamine in muscle and liver was unaffected by dietary creatine levels. Therefore, exogenous creatine levels between 1·84 and 15·44 g/kg had no impact on endogenous creatine synthesis of grass carp in this study.

Creatine supplementation induced several biochemical reactions that affected meat quality(Reference Brosnan and Brosnan34,Reference James, Goodband and Unruh36) . Textural characteristics including chewiness, hardness (firmness), cohesiveness, springiness, gumminess and resilience are important qualities in aquatic products and are key attributes in the mechanical processing of fillets(Reference Johnston37). In gilthead seabream, diets supplemented with 20 g/kg creatine improved textural properties including hardness and chewiness(Reference Schrama, Cerqueira and Raposo19). In this study, 8·48 g/kg creatine improved muscular hardness and chewiness. In raw fish texture, flesh quality varies with collagen amount, myofibre density and myofibre diameter(Reference Lin, Zeng and Zhu38,Reference Periago, Ayala and López-Albors39) . Collagen is positively associated with muscular hardness in grass carp and contributes to tensile strength(Reference Sun, Xu and Li40). Our findings revealed that creatine improved flesh hardness by increasing alkaline-insoluble collagen content. Similar results were reported in L. vannamei (Reference Cheng, Li and Leng13). Moderate dietary creatine levels promote muscular hardness and collagen deposition, and the optimum creatine supplementation for grass carp ranges between 9·56 and 12·04 g/kg. High flesh quality is characterised by a small myofibre diameter and a high myofibre density, which increase firmness(Reference Hurling, Rodell and Hunt41). Until now, little was known about the effects of dietary creatine on fish fibre cellularity. In this study, 8·48 g/kg creatine significantly increased fibre density and the frequencies of the diameters of classes I and III, which was evident by the improvement in myofibre hyperplasia and hypertrophic, indicating creatine supplementation at 8·48 g/kg promotes the growth of skeletal muscle in grass carp. However, 15·44 g/kg creatine decreased muscular cohesiveness and the frequencies of class I, which may negatively affect flesh texture and muscle growth(Reference Listrat, Lebret and Louveau42), suggesting the level of dietary creatine should be <15·44 g/kg.

Sarcomere length is a predictor of muscle function and flesh quality(Reference Guzek, Głąbski and Głąbska43,Reference Wei, Li and Xu44) . Sarcomeres are precisely aligned in fibres and consist of alternating light (I-band) and dark (A-band) bands. The postmortem sarcomere length affects textural characteristics, water-holding capacity of raw muscle, flesh taste and colour. For example, short sarcomeres after rigor increase hardness but reduce water-holding capacity in pork muscle(Reference Ertbjerg and Puolanne45). In this study, 8·48 g/kg creatine significantly increased sarcomere length by increasing the I-band length. Therefore, creatine increased flesh hardness in fish by affecting the long sarcomeres. The different results between pigs and fish may be attributed to differences in living surroundings and movement patterns.

The textural improvements in muscle are not solely attributable to fibre characteristics, but rather to myofibre types. Dietary creatine increased MyHC I mRNA levels and decreased MyHC II mRNA levels in rat muscle(Reference Aguiar, Aguiar and Felisberto15) and L. vannamei (Reference Cheng, Li and Leng13). In our study, fMyHC s30 and fMyHC s10 in the slow skeletal muscle increased while fMyHCs and fMyHCc in the fast skeletal muscle decreased with increasing creatine supplementation. Compared with fast fibres, slow fibres have a higher number of long sarcomeres(Reference Medler and Mykles46), which correspond to the increased sarcomere length in our study.

The growth and differentiation of myofibres can be mediated by IGF-I and MRF(Reference Mònica, Laura and Vanesa47), which can be induced by creatine(Reference Negro, Avanzato, D’Antona, Nabavi and Silva10,Reference Kraemer, Luk, Lombard, Bagchi, Nair and Sen48,Reference Willoughby and Rosene49) . Our study found that mRNA expression including MyoD and MyoG in skeletal muscle increased with increasing creatine supplementation levels. Similar results were reported in gilthead seabream(Reference Ramos-Pinto, Lopes and Sousa18). Creatine supplementation increased the protein expression of IGF-I and MyoD1, suggesting that creatine affected the myofibre types of grass carp by regulating the expression of IGF-I and MRF. Additionally, the transformation of myofibres from fast myofibres to slow myofibres can be mediated by PGC-1α, which may be activated by energy stress(Reference Morita, Gravel and Hulea17) and increases the mRNA levels of genes involved in the regulation of the mitochondrial function and biogenesis(Reference Nikolić, Rhedin and Rustan50). Our study findings showed that creatine supplementation increased PGC-1α levels, consistent with the increased mRNA levels of fMyHC s30 and fMyHC s10 in the slow skeletal muscle. These results revealed that the transformation of fibre types by creatine supplementation is mediated by PGC-1α.

In grass carp, 8·48 g/kg creatine-induced muscle protein synthesis. Creatine increased the protein level of IGF-I and the phosphorylation levels of TOR, 4E-BP1 and S6K1. Creatine-induced hypertrophy of C2C12 cells with through partially mediated by overexpression of IGF-I and MRF(Reference Louis, Van Beneden and Dehoux51). Creatine increased muscle protein deposition by activating IGF-I-Akt/TOR pathways. Protein synthesis induced by feeding stimulation in fish depends on the adequacy of amino acid pools in plasma and tissues, which mediate the activities of nutrient-sensing pathways such as TOR. In blunt snout bream (Megalobrama amblycephala), arginine activates the TOR signalling by increasing the postprandial-free amino acid contents in plasma(Reference Liang, Ren and Habte-Tsion52). In this study, creatine-supplemented diets increased the contents of free EAA in serum compared with the control diet, especially the contents of lysine and leucine, which are effective in nutrient sensing(Reference Azizi, Nematollahi and Mojazi Amiri53). TOR activation is the main driver of creatine-induced protein synthesis, which is in response to an increase in free EAA contents in serum. However, the highest level of dietary creatine did not contribute to the highest content of muscular protein. It is possible that excess creatine promoted insulin resistance through negative feedback and affected IGF-I expression, thereby reducing the stimulation of TOR(Reference Um, D’Alessio and Thomas54). Consistent with the above results, IGF-I in the presence of serum-free amino acids could activate TOR signalling pathways (Fig. 7), and the effect was most significant when creatine content was 8·48 g/kg.

Fig. 7. The mechanism of dietary creatine supplementation on the muscular protein synthesis of grass carp.

High-quality proteins are readily digestible and contain EAA(Reference Mohanty, Mahanty and Ganguly55). In this study, dietary creatine increased muscular EAA content, suggesting that the nutritional value of flesh increased. Lysine and leucine, required for protein synthesis in muscle of fish(Reference Li, Mai and Trushenski56), increased in fish fed 8·48 g/kg creatine. Glycine, aspartic acid and glutamic acid, which provide several health benefits(Reference Sarma, Akhtar and Das57), increased with 8·48 g/kg creatine. Therefore, diets supplemented with 8·48 g/kg creatine improved muscle nutrition, which enhances the utility of fish as a protein source.

Flavour affects flesh quality and consumer acceptance. Free amino acids contribute to flesh flavour(Reference Hong, Regenstein and Luo58). In fish, aspartic acid and glutamic acid are representatives of the umami taste, and glycine and alanine contribute to sweetness(Reference Ma, Feng and Wu59). Dietary creatine at 8·48 g/kg increased FAA content, suggesting that creatine may improve flesh umami and sweetness in grass carp. Leucine and isoleucine generate aroma compounds through the Maillard reaction(Reference Ma, Feng and Wu59); therefore, creatine may promote the formation of aroma compounds in fish muscle.

In vivo, the phosphogen system, glycolysis system and aerobic oxidation system are activated successively to meet the energy requirements of muscles during exercise. The phosphogen system is mainly composed of creatine, phosphocreatine and creatine kinase, which is the earliest and most efficient energy supply pathway for muscle movement(Reference Wallimann, Wyss and Brdiczka60). These results in present study suggested that exogenous creatine increased the creatine pool of body, reduced the consumption of other energy nutrients and enhanced other’s nutrients deposition. Meanwhile, creatine transporter regulates the creatine pool through a negative feedback inhibition mechanism and is considered to be a regulatory switch to control creatine concentration in vivo (Reference Speer, Neukomm and Murphy61). Future experiments must address new questions, like the effects of creatine on regulation energy homeostasis and creatine transporters in fish.

In conclusion, dietary creatine effectively improved the flesh quality of grass carp (Fig. 8) by the following mechanisms. First, creatine supplementation increased flesh hardness and chewiness by improving myofibre characteristics, which is mediated by IGF-I, MRF and PGC-1α. Second, creatine supplementation increased the contents of EAA in serum, which further activate the TOR pathway and increase muscle protein synthesis (Fig. 7). Third, creatine supplementation improved flesh flavour by increasing the content of flavour free amino acids. Therefore, flesh quality of grass carp increased when dietary creatine content was 8·48–12·04 g/kg.

Fig. 8. The conclusion of the effects of dietary creatine supplementation on the flesh quality of grass carp.

Acknowledgements

We thank Chuangju Li and Guiwei Zou for providing essential facilities and help during the qRT-PCR analysis; Xiujuan Bi and Xing Lv for help with the feeding trial and Meifeng Li for help during analysed the reference format.

This study was supported by the National Key R&D Program of China (No. 2018YFD0900400 and No. 2019YFD0900200), Central Public-interest Scientific Institution Basal Research Fund CAFS (No. 2019ZY18) and National Natural Science Foundation of China (No. 31702361).

J. T., W. Z. and H. W. designed the research; X. C., W. G., M. J. and X. L. conducted the experiments and analysed the data; X. C., J. T. and L. Y. wrote the paper; J. T. and W. Z. have primary responsibility for final content and all the authors have read and approved the final manuscript.

The authors declare no conflict of interest.

References

Thurstan, RH & Roberts, CM (2014) The past and future of fish consumption: can supplies meet healthy eating recommendations? Mar Pollut Bull 89, 511.CrossRefGoogle ScholarPubMed
Wang, Q, Cheng, L, Liu, J, et al. (2015) Freshwater aquaculture in PR China: trends and prospects. Rev Aquacult 7, 283302.CrossRefGoogle Scholar
FAO (2020) The State of World Fisheries and Aquaculture 2020. Rome: FAO.Google Scholar
Ashraf, M, Zafar, A, Rauf, A, et al. (2011) Nutritional values of wild and cultivated silver carp (Hypophthalmichthys molitrix) and grass carp (Ctenopharyngodon idella). Int J Agric Biol 13, 15608530.Google Scholar
Choi, YM & Kim, BC (2009) Muscle fiber characteristics, myofibrillar protein isoforms, and meat quality. Livest Sci 122, 105118.CrossRefGoogle Scholar
Lie, Ø (2001) Flesh quality – the role of nutrition. Aquacult Res 32, 341348.CrossRefGoogle Scholar
Ayoola, MO (2016) Application of Dietary Bentonite Clay as Feed Addictive on Feed Quality, Water Quality and Production Performance of African Catfish (Clarias gariepinus). Stellenbosch: Stellenbosch University.Google Scholar
Wang, B, Liu, Y, Feng, L, et al. (2015) Effects of dietary arginine supplementation on growth performance, flesh quality, muscle antioxidant capacity and antioxidant-related signalling molecule expression in young grass carp (Ctenopharyngodon idella). Food Chem 167, 9199.CrossRefGoogle ScholarPubMed
Alami-Durante, H, Wrutniak-Cabello, C, Kaushik, SJ, et al. (2010) Skeletal muscle cellularity and expression of myogenic regulatory factors and myosin heavy chains in rainbow trout (Oncorhynchus mykiss): effects of changes in dietary plant protein sources and amino acid profiles. Comp Biochem Physiol A Mol Integr Physiol 156, 561568.CrossRefGoogle ScholarPubMed
Negro, M, Avanzato, I & D’Antona, G (2019) Creatine in skeletal muscle physiology. In Nonvitamin and Nonmineral Nutritional Supplements, pp. 5968 [Nabavi, SM and Silva, AS, editors]. London: Academic Press.Google Scholar
Gualano, B, Artioli, GG, Poortmans, JR, et al. (2010) Exploring the therapeutic role of creatine supplementation. Amino Acids 38, 3144.CrossRefGoogle ScholarPubMed
Mcfarlane, WJ, Heigenhauser, G & Mcdonald, DG (2001) Creatine supplementation affects sprint endurance in juvenile rainbow trout. Comp Biochem Physiol A Mol Integr Physiol 130, 857866.CrossRefGoogle ScholarPubMed
Cheng, X, Li, M, Leng, X, et al. (2021) Creatine improves the flesh quality of Pacific white shrimp (Litopenaeus vannamei) reared in freshwater. Food Chem 354, 129498.CrossRefGoogle ScholarPubMed
Cunha, MP, Budni, J, Ludka, FK, et al. (2016) Involvement of PI3K/Akt signaling pathway and its downstream intracellular targets in the antidepressant-like effect of creatine. Mol Neurobiol 53, 29542968.CrossRefGoogle ScholarPubMed
Aguiar, AF, Aguiar, DH, Felisberto, AD, et al. (2010) Effects of creatine supplementation during resistance training on myosin heavy chain (MHC) expression in rat skeletal muscle fibers. J Strength Cond Res 24, 8896.CrossRefGoogle ScholarPubMed
Ceddia, RB & Sweeney, G (2004) Creatine supplementation increases glucose oxidation and AMPK phosphorylation and reduces lactate production in L6 rat skeletal muscle cells. J Physiol 555, 409421.CrossRefGoogle ScholarPubMed
Morita, M, Gravel, SP, Hulea, L, et al. (2015) mTOR coordinates protein synthesis, mitochondrial activity and proliferation. Cell Cycle 14, 473480.CrossRefGoogle ScholarPubMed
Ramos-Pinto, L, Lopes, G, Sousa, V, et al. (2019) Dietary creatine supplementation in gilthead seabream (Sparus aurata) increases dorsal muscle area and the expression of myod1 and capn1 genes. Front Endocrinol 10, 161.CrossRefGoogle ScholarPubMed
Schrama, D, Cerqueira, M, Raposo, CS, et al. (2018) Dietary creatine supplementation in gilthead seabream (Sparus aurata): comparative proteomics analysis on fish allergens, muscle quality, and liver. Front Physiol 9, 1844.CrossRefGoogle ScholarPubMed
Burns, AF & Gatlin, DM III (2019) Dietary creatine requirement of red drum (Sciaenops ocellatus) and effects of water salinity on responses to creatine supplementation. Aquaculture 506, 320324.CrossRefGoogle Scholar
Zhao, HH, Xia, JG, Zhang, X, et al. (2018) Diet affects muscle quality and growth traits of grass carp (Ctenopharyngodon idellus): a comparison between grass and artificial feed. Front Physiol 9, 283.CrossRefGoogle ScholarPubMed
NRC (2011) Nutrient Requirements of Fish and Shrimp. Washington, DC: National Academies Press.Google Scholar
Du, Z-Y, Liu, Y-J, Tian, L-X, et al. (2006) The influence of feeding rate on growth, feed efficiency and body composition of juvenile grass carp (Ctenopharyngodon idella). Aquacult Int 14, 247257.CrossRefGoogle Scholar
AOAC (2005) Official Methods of Analysis, 18th ed. Arlington, VA: AOAC.Google Scholar
Zhang, KK, Ai, QH, Mai, KS, et al. (2013) Effects of dietary hydroxyproline on growth performance, body composition, hydroxyproline and collagen concentrations in tissues in relation to prolyl 4-hydroxylase α(I) gene expression of juvenile turbot, Scophthalmus maximus L. fed high plant protein diets. Aquaculture 404–405, 7784.CrossRefGoogle Scholar
Wu, F, Wen, H, Tian, J, et al. (2018) Effect of stocking density on growth performance, serum biochemical parameters, and muscle texture properties of genetically improved farm tilapia, Oreochromis niloticus . Aquacult Int 26, 12471259.CrossRefGoogle Scholar
Nihei, Y, Kobiyama, A, Ikeda, D, et al. (2006) Molecular cloning and mRNA expression analysis of carp embryonic, slow and cardiac myosin heavy chain isoforms. J Exp Biol 209, 188.CrossRefGoogle ScholarPubMed
Shi, XC, Jin, A, Sun, J, et al. (2018) The protein-sparing effect of α-lipoic acid in juvenile grass carp, Ctenopharyngodon idellus: effects on lipolysis, fatty acid β-oxidation and protein synthesis. Br J Nutr 120, 977987.CrossRefGoogle ScholarPubMed
Tian, J, Lu, X, Jiang, M, et al. (2020) AMPK activation by dietary AICAR affects the growth performance and glucose and lipid metabolism in juvenile grass carp. Aquacult Nutr 26, 314.CrossRefGoogle Scholar
Borchel, A, Verleih, M, Rebl, A, et al. (2014) Creatine metabolism differs between mammals and rainbow trout (Oncorhynchus mykiss). SpringerPlus 3, 510.CrossRefGoogle ScholarPubMed
Wagner, T & Congleton, J (2011) Blood chemistry correlates of nutritional condition, tissue damage, and stress in migrating juvenile Chinook salmon (Oncorhynchus tshawytscha). Can J Fish AquatSci 61, 10661074.CrossRefGoogle Scholar
Ohgo, H, Yokoyama, H, Hirose, H, et al. (2009) Significance of ALT/AST ratio for specifying subjects with metabolic syndrome in its silent stage. Diabetes Metab Syndr 3, 36.CrossRefGoogle Scholar
da Silva, RP, Leonard, K-A & Jacobs, RL (2017) Dietary creatine supplementation lowers hepatic triacylglycerol by increasing lipoprotein secretion in rats fed high-fat diet. J Nutr Biochem 50, 4653.CrossRefGoogle ScholarPubMed
Brosnan, ME & Brosnan, JT (2016) The role of dietary creatine. Amino Acids 48, 17851791.Google ScholarPubMed
Ejiofor, E, Ebhohon, S & Ndukaku, OY (2015) Effect of fermented and unfermented cocoa bean on some liver enzymes, creatinine and antioxidant in wistar albino rats. Carpathian J Food Sci Technol 7, 132138.Google Scholar
James, BW, Goodband, RD, Unruh, JA, et al. (2002) A review of creatine supplementation and its potential to improve pork quality. J Appl Anim Res 21, 116.CrossRefGoogle Scholar
Johnston, IA (1999) Muscle development and growth: potential implications for flesh quality in fish. Aquaculture 177, 99115.CrossRefGoogle Scholar
Lin, WL, Zeng, QX & Zhu, ZW (2009) Different changes in mastication between crisp grass carp (Ctenopharyngodon idellus C.et V) and grass carp (Ctenopharyngodon idellus) after heating: The relationship between texture and ultrastructure in muscle tissue. Food Res Int 42, 271278.CrossRefGoogle Scholar
Periago, MJ, Ayala, MD, López-Albors, O, et al. (2005) Muscle cellularity and flesh quality of wild and farmed sea bass, Dicentrarchus labrax L . Aquaculture 249, 175188.CrossRefGoogle Scholar
Sun, WT, Xu, XY, Li, XQ, et al. (2018) Effects of dietary geniposidic acid on growth performance, flesh quality and collagen gene expression of grass carp, Ctenopharyngodon idella . Aquacult Nutr 24, 11121121.CrossRefGoogle Scholar
Hurling, R, Rodell, JB & Hunt, HD (1996) Fiber diameter and fish texture. J Texture Stud 27, 679685.CrossRefGoogle Scholar
Listrat, A, Lebret, B, Louveau, I, et al. (2016) How muscle structure and composition influence meat and flesh quality. Sci World J 2016, 114.CrossRefGoogle ScholarPubMed
Guzek, D, Głąbski, K, Głąbska, D, et al. (2012) Comparison of sarcomere length for two types of meat from animal family Suidae–analysis of measurements carried out by microscopic technique. Adv Sci Technol Res J 6, 1317.CrossRefGoogle Scholar
Wei, YL, Li, BX, Xu, HG, et al. (2020) Fish protein hydrolysate in diets of turbot affects muscle fibre morphometry, and the expression of muscle growth-related genes. Aquacult Nutr 26, 17801791.CrossRefGoogle Scholar
Ertbjerg, P & Puolanne, E (2017) Muscle structure, sarcomere length and influences on meat quality: a review. Meat Sci 132, 139152.CrossRefGoogle ScholarPubMed
Medler, S & Mykles, DL (2015) Muscle structure, fiber types, and physiology. Nat Hist Crust 4, 103133.Google Scholar
Mònica, RF, Laura, A, Vanesa, JA, et al. (2011) Differential effects on proliferation of GH and IGFs in sea bream (Sparus aurata) cultured myocytes. Gen Comp Endocrinol 172, 4449.Google Scholar
Kraemer, WJ, Luk, HY, Lombard, JR, et al. (2013) Physiological basis for creatine supplementation in skeletal muscle. In Nutrition and Enhanced Sports Performance, pp. 385394 [Bagchi, D, Nair, S and Sen, CK, editors]. San Diego: Academic Press.CrossRefGoogle Scholar
Willoughby, DS & Rosene, JM (2003) Effects of oral creatine and resistance training on myogenic regulatory factor expression. Med Sci Sports Exerc 35, 923.CrossRefGoogle ScholarPubMed
Nikolić, N, Rhedin, M, Rustan, AC, et al. (2012) Overexpression of PGC-1α increases fatty acid oxidative capacity of human skeletal muscle cells. Biochem Res Int 2012, 714074.CrossRefGoogle ScholarPubMed
Louis, M, Van Beneden, R, Dehoux, M, et al. (2004) Creatine increases IGF-I and myogenic regulatory factor mRNA in C2C12 cells. FEBS Lett 557, 243247.CrossRefGoogle Scholar
Liang, HL, Ren, MC, Habte-Tsion, HM, et al. (2016) Dietary arginine affects growth performance, plasma amino acid contents and gene expressions of the TOR signaling pathway in juvenile blunt snout bream, Megalobrama amblycephala . Aquaculture 461, 18.Google Scholar
Azizi, S, Nematollahi, MA, Mojazi Amiri, B, et al. (2016) Lysine and leucine deficiencies affect myocytes development and IGF signaling in gilthead sea bream (Sparus aurata). PLOS ONE 11, E0147618.Google ScholarPubMed
Um, SH, D’Alessio, D & Thomas, G (2006) Nutrient overload, insulin resistance, and ribosomal protein S6 kinase 1, S6K1. Cell Metab 3, 393402.CrossRefGoogle ScholarPubMed
Mohanty, B, Mahanty, A, Ganguly, S, et al. (2014) Amino acid compositions of 27 food fishes and their importance in clinical nutrition. J Amino Acids 2014, 269797.CrossRefGoogle ScholarPubMed
Li, P, Mai, KS, Trushenski, J, et al. (2009) New developments in fish amino acid nutrition: towards functional and environmentally oriented aquafeeds. Amino Acids 37, 4353.CrossRefGoogle ScholarPubMed
Sarma, D, Akhtar, MS, Das, P, et al. (2013) Nutritional quality in terms of amino acid and fatty acid of five coldwater fish species: implications to human health. Natl Acad Sci Lett 36, 385391.CrossRefGoogle Scholar
Hong, H, Regenstein, JM & Luo, Y (2017) The importance of ATP-related compounds for the freshness and flavor of post-mortem fish and shellfish muscle: a review. Crit Rev Food Sci Nutr 57, 17871798.Google ScholarPubMed
Ma, XZ, Feng, L, Wu, P, et al. (2020) Enhancement of flavor and healthcare substances, mouthfeel parameters and collagen synthesis in the muscle of on-growing grass carp (Ctenopharyngodon idella) fed with graded levels of glutamine. Aquaculture 528, 735486.CrossRefGoogle Scholar
Wallimann, T, Wyss, M, Brdiczka, D, et al. (1992) Intracellular compartmentation, structure and function of creatine kinase isoenzymes in tissues with high and fluctuating energy demands: the ‘phosphocreatine circuit’ for cellular energy homeostasis. Biochem J 281, 2140.CrossRefGoogle ScholarPubMed
Speer, O, Neukomm, L, Murphy, R, et al. (2004) Creatine transporters: a reappraisal. Mol Cell Biochem 256–257, 407424.CrossRefGoogle Scholar
Figure 0

Table 1. The ingredients and proximate composition of diets with creatine supplement

Figure 1

Table 2. The amino acids compositions of diets with creatine supplement

Figure 2

Table 3. Nucleotide sequences of primers and cycling conditions used for PCR amplification

Figure 3

Table 4. Effects of creatine-supplemented diets on growth performance of grass carp(Mean values and standard deviations)

Figure 4

Table 5. Effects of creatine-supplemented diets on haematological data of grass carp(Mean values and standard deviations)

Figure 5

Table 6. Effects of creatine-supplemented diets on the contents of creatine and metabolites in the muscle and liver of grass carp(Mean values and standard deviations)

Figure 6

Table 7. The muscle textural properties of grass carp fed diets with creatine supplement(Mean values and standard deviations)

Figure 7

Fig. 1. Second-order polynomial regression analyses between flesh hardness and dietary creatine levels for grass carp.

Figure 8

Fig. 2. Effects of creatine-supplemented diets on microstructure of muscle of grass carp. (a) Longitudinal sections of muscle. FD: myofibre diameter. (b) Cross-sections of muscle. MF: muscle fibre. Magnification: 200×. (c) The myofibre diameter and density of muscle in grass carp (n 3). Classes I, II and III were categorised according to diameter = d ≤ 60, 60 < d ≤ 100 and d > 100, respectively. Class I myofibres were categorised as hyperplastic/hyperplasia fibres. Class III myofibres were categorised as hypertrophic fibres.

Figure 9

Fig. 3. Effects of creatine-supplemented diets on morphology of myocytes of grass carp. (a) Transmission electron microscope of fish sarcomere; a: Myofibrillar structure in control group, 8000×magnification; b: Myofibrillar structure in 8·48 g/kg group, 8000×agnification. sr, sarcoplasmic reticulum; tc, terminal cisternae; TT, transverse tubules. (b) Myofibrillar sarcomere length, I-band and A-band width in control group and 8·48 g/kg group (n 3).

Figure 10

Table 8. Effects of creatine-supplemented diets on proximate composition and collagen contents in the muscle of grass carp(Mean values and standard deviations)

Figure 11

Fig. 4. Second-order polynomial regression analyses between flesh Hyp contents and dietary creatine levels for grass carp.

Figure 12

Table 9. Effects of creatine-supplemented diets on muscle amino acid composition of grass carp(Mean values and standard deviations)

Figure 13

Table 10. Effects of creatine-supplemented diets on free amino acid composition in the muscle of grass carp(Mean values and standard deviations)

Figure 14

Table 11. Effects of creatine-supplemented diets on free amino acid composition in the serum of grass carp(Mean values and standard deviations)

Figure 15

Fig. 5. Effects of creatine-supplemented diets on relative mRNA expression of genes in muscle of grass carp. (a) fMyHCs and fMyHCc expressed in fast skeletal muscle. (b) fMyHCS10 and fMyHCS30 expressed in slow skeletal muscle. (c) Myogenic regulator factors (MyoG and MyoD) expressed in skeletal muscle of grass carp (n 3).

Figure 16

Fig. 6. Effects of creatine-supplemented diets on nutrient-sensing signalling pathways in muscle of grass carp (n 3). IGF-I, insulin-like growth factor I; MyoD1, myogenic differentiation antigen; PGC-1α, peroxisome proliferator-activated receptor-γ coactivator-1α; TOR, target of rapamycin; p-TOR, phosphorylated TOR; 4EBP1, eukaryotic translation initiation factor 4E-binding protein 1; p-4EBP1, phosphorylated 4EBP1; S6K1, ribosome S6 protein kinase 1; p-S6K1, phosphorylated S6K1.

Figure 17

Fig. 7. The mechanism of dietary creatine supplementation on the muscular protein synthesis of grass carp.

Figure 18

Fig. 8. The conclusion of the effects of dietary creatine supplementation on the flesh quality of grass carp.