Abstract

The interaction between phospholipid (PL) and cholesterol (CH) on growth performance, molting rate, hepatopancreas fatty acid composition, and ovary development of the female red swamp crayfish (Procambarus clarkii) was investigated. Nine diets containing three PL levels (0, 20, and 60 g/kg) and three CH levels (0, 5, and 10 g/kg) were included in the study. Female crayfish (initial weight:  g) were reared for 60 days. There was no significant interaction between dietary PL and CH levels (). However, the best growth performance and ovarian development were observed in crayfish receiving the 60 g/kg PL and 10 g/kg CH diet. High PL levels promoted CH transport in the hepatopancreas, and long-chain unsaturated fatty acid (C20:4n-6, C20:5n-3, and C22:6n-3) content of the hepatopancreas increased with the addition of PL in the diet. The molting rate increased with increasing CH levels in the diet containing 60 g/kg PL. Real-time quantitative polymerase chain reaction revealed that dietary CH enhanced the molting rate by improving the ecdysone receptor genes at transcription. This study showed that crayfish fed a diet containing 10 g/kg CH and 60 g/kg PL obtained maximum growth, molting rate, and ovary development.

1. Introduction

The red swamp freshwater crayfish (Procambarus clarkii) belongs to the family Cambaridae. This species is widely produced in China because of its strong environmental adaptability, delicious taste, and high nutritional value [1]. Crayfish production reached more than 2 million tons in 2019, according to the China Fishery Statistical Yearbook [2]. Currently, molting performance and ovarian development have become two important factors affecting the sustainability of the crayfish farming industry [3, 4]. Therefore, an artificial diet that improves molting and ovarian development needs to be developed by the industry.

Phospholipids (PL) and cholesterol (CH) are lipids that are the critical components of membranes and lipoproteins [5]. Most crustaceans cannot synthesize PL or CH sufficiently to meet their requirements during juvenile stages [4, 6]. Hence, appropriate PL and CH levels in the feed of crustaceans are required. PL are polar lipids that provide energy for the life activities of crustaceans and are conducive for facilitating the absorption and transport of lipids via emulsification [7, 8]. PL can also improve feed palatability [9]. The PL level added is approximately 20 g/kg in commercial crustacean feeds, satisfying the requirements of crustaceans [1013]. However, several studies have shown that the PL in feed is not necessary for the growth performance of some crustaceans [1416]. Song et al. [13] reported that excessive PL levels (60 g/kg) compared to low PL levels reduced the growth performance of female Portunus trituberculatus. Optimal dietary PL levels for juvenile shrimp have been reported to be between 1.2% and 1.5% [1719]. The reasons for the different optimal PL levels in feed are attributed to its different sources and components. CH acts as a precursor of steroid hormones involved in reproduction and molting [20, 21]. The optimal levels of dietary CH in shrimp diets range from 0 g/kg to 10 g/kg [5, 2224]. The recommended level of CH is approximately 5 g/kg in crayfish feeds [2527].

The underlying reasons for molt death syndrome are related to inadequate content of nutrients (e.g., high unsaturated fatty acids, PL, CH, and total lipids), which are stored in the hepatopancreas [11, 2830]. Previous studies have shown that CH transported from the hepatopancreas results in the variation of the ecdysteroid signal transduction and changes the molting performance in crustacean [4, 31, 32].

Studies have revealed that PL promotes the transfer of lipids from the hepatopancreas to the ovary during ovary maturation [13, 33]. Steroid hormones are present in crustaceans, including 17β-estradiol, estrone, 17α-hydroxyprogesterone, and 17α-hydroxypregnenolone [3436]. The hepatopancreas and ovaries synthesize hormones promoting ovarian development, such as estradiol [37]. CH is an important precursor of steroid hormones, and ovarian development in crustaceans can be induced by adding CH to the diet [3840]. Gong et al. [23] reported a significant interactive effect between PL and CH on the growth of the juvenile Litopenaeus vannamei. However, more research has shown that no interaction effects were observed between PL and CH in the growth performance of the commercial crustaceans [17, 18, 24].

The objective of the present study was to investigate the effects of the interaction between PL and CH on the growth performance, hepatopancreas fatty acid composition, molting performance, and ovary development in female juvenile crayfish (P. clarkii) fed semipurified diets.

2. Materials and Methods

2.1. Experimental Diets

Nine isonitrogenous semipurified diets containing three PL levels (0, 20, and 60 g/kg) and three CH levels (0, 5, and 10 g/kg) were formulated for the present study, and the diets are defined as Diet1 (0/0), Diet2 (20/0), Diet3 (60/0), Diet4 (0/5), Diet5 (20/5), Diet6 (60/5), Diet7 (0/10), Diet8 (20/10), and Diet9 (60/10) (Table 1). PL was supplied by soybean lecithin powder at a purity of 95.6% and contained phosphatidylcholine, phosphatidylethanolamine, phosphatidylinositol, and phosphatidate at 21%, 20%, 14%, and 8%, respectively. The purity of the dietary CH was over 90%. The levels of soybean oil were adjusted to balance the total lipid content.

Prior to preparing the experiment feeds, all dry ingredients were ground into a fine powder through a 250 μm mesh. The diets were then thoroughly mixed manually with soybean oil. Water was added to form a dough that was immediately extruded through a 2 mm die orifice and air-dried at room temperature for 48 h. All diets were stored at -20°C in black plastic bags until use.

2.2. Experimental Rearing System

The indoor experiment rearing system was composed of 12 plastic tanks. Each tank (, ) contained 30 independent culture units (, ). There were several holes between the adjacent units to ensure water exchange. All units were continuously aerated, and a 14 h light and 10 h dark cycle was applied. Polyvinyl chloride tubes () were provided as shelters for P. clarkii at the bottom of each unit. The culture system was supplied with filtered freshwater, and the water depth of each unit was maintained at 10 cm. A 50% water exchange occurred each day.

2.3. Experimental Animals and Feeding Trial

The experiment was conducted at the Chongming Research Base of Shanghai Ocean University (Shanghai, China). Healthy, active, and intact P. clarkii juvenile females with immature ovaries containing undeveloped oocytes were obtained from a local crayfish farm in mid-June, 2019. All juvenile crayfish were kept individually in an experiment unit and fed Diet1 twice daily (07 : 00 and 17 : 00) for 7 days to acclimatize them to the feed and experimental conditions.

After the conditioning period, all crayfish were weighed () on an electronic balance (JA4002, Shanghai Puchun Measure Instrument Co., Ltd., Shanghai, China), and 270 P. clarkii (average initial weight: ) were randomly divided into nine treatments. Each dietary treatment had three replicates, with each replicate having 10 crayfish (1 crayfish unit-1) that were randomly placed into 12 plastic tanks (270 units). All crayfish were fed a daily ration of 3%–5% body weight divided into two meals (07 : 00 and 18 : 30, 30% and 70% of total daily feed input, respectively). Any uneaten feed and produced feces were cleaned at 13 : 00 daily during the culture trial. Mortality and molting performance were monitored and recorded daily.

During the feeding phase of the experiment, the water quality was monitored daily using a water quality meter (YSI ProPlus, Visay Instruments Inc., USA). Water temperature was maintained at throughout the trial, pH was 7.0 to 7.5, ammonia nitrogen was less than 0.5 mg/L, dissolved oxygen was more than 5.0 mg/L, and nitrite was less than 0.15 mg/L.

2.4. Sample Collection

At the end of the feeding trial, the crayfish were fasted for 24 h before sampling. Crayfish weights were measured using an electronic balance (). All crayfish were sampled. Blood samples were collected through the ventral sinus in the first abdominal segment using a 1 mL syringe and centrifuged at 3000 r/min for 10 min. The supernatants were collected and stored in 2 mL tubes at -80°C for subsequent measurements. The crayfish were dissected to obtain the hepatopancreas and gonadal tissues to calculate the gonadosomatic index (GSI) and hepatosomatic index (HSI) and were stored at -80°C for subsequent analyses of the fatty acid profile. The hepatopancreas which fed different CH levels when PL addition level was 60 g/kg was stored at -80°C for the RNA extraction. The hepatopancreas and gonads which fed different PL levels when CH addition level was 10 g/kg, with a length of 1 cm, were then sampled and immersed in Bouin’s solution for histology analysis. The survival rate (SR, %), weight gain rate (WGR, %), specific growth rate (SGR, % per day), HSI, and GSI were calculated using the following formulas:

2.5. Biochemical Analysis and Fatty Acid Composition

The chemical composition of diets and tissues was measured according to standard methods with slight modifications. The moisture of the diet samples was measured by oven drying at 105°C to a constant weight, and the moisture of tissues was determined according to freeze-dried analysis. Ash was measured using a muffle furnace at 550°C for 8 h [41]. The crude protein content was determined by measuring nitrogen () using the Kjeldahl method. Total lipids were extracted with chloroform-methanol (2 : 1, ) [42].

For fatty acid analysis, total lipids from the hepatopancreas and diets were esterified by boiling 14% boron trifluoride/methanol (), and fatty acid methyl esters (FAMEs) were extracted using hexane [43]. FAMEs were esterified analyzed using an Agilent 7890B GC/5977A gas chromatograph-mass spectrometer with an Omegawax 320-fused silica capillary column (30 m ×0.32 mm ×0.25 μm; Supelco, Bellefonte, PA, USA). The injector and detector temperatures were maintained at 260°C. The column temperature was initially set at 40°C and increased at a rate of 10°C min-1 to 170°C and held for 1 min, followed by an increase at a rate of 2°C min-1 to 220°C and held for 1 min. It was then further increased at a rate of 2°C min-1 to a final temperature of 230°C and held for 30 min until all FAMEs had been eluted. The peaks were identified by comparing retention times with a 37-component FAME standard mixture (18919-1AMP, Sigma-Aldrich Co., St. Louis, MO, USA). The fatty acid composition was expressed as the percentage of each fatty acid to the total fatty acids (% total fatty acids).

2.6. Hepatopancreas and Gonad Histology

The tissue samples which fed different PL levels when CH addition level was 10 g/kg were dehydrated in a series of alcohol solutions and embedded in paraffin. The paraffin blocks were sectioned (7 μm) in serial sagittal sections using a Lecia RM 2245 rotary microtome, and the slides were stained with haematoxylin-eosin. The morphological structure of the tissue was observed using a light microscope (Nikon YS100), and photographs were taken.

2.7. 17β-Estradiol, Total Cholesterol, High-Density Lipoprotein Cholesterol, and Low-Density Lipoprotein Cholesterol Content Assays

The 17β-estradiol (E2) in ovaries was measured using an enzyme immunoassay kit (ELISA) (Nanjing Jiancheng Bioengineering Institute, Nanjing, China). Total cholesterol (TCH), high-density lipoprotein cholesterol (HDL-C), and low-density lipoprotein cholesterol (LDL-C) determinations in the hepatopancreas and serum were analyzed with a spectrophotometer and corresponding detection kits (Nanjing Jiancheng Bioengineering Institute, Nanjing, China) according to the manufacturer’s guidelines.

2.8. RNA Extraction, cDNA Synthesis, and Gene Expression

Total RNA was extracted from the P. clarkii hepatopancreas with RNAiso Plus (TaKaRa, Japan) following the manufacturer’s protocol and then dissolved in DEPC treated water. The quantity and quality of isolated RNA were evaluated using spectrophotometric (OD260/280) analysis and 1% agarose gel electrophoresis, respectively. TATA-binding protein was used as the reference gene in this study, and primers (Table 2) for molting genes were designed using Primer Premier 5.0 software based on the published mRNA sequences of P. clarkii [4]. cDNA synthesis via reverse transcription was performed using a PremeScript™ RT reagent kit (TaKaRa, Japan) according to the manufacturer’s protocol. The quantitative real-time PCR was performed using a TaKaRa SYBR® Prime Script™ RTPCR kit (Takara, Japan). Amplification was performed in a 96-well plate with a 20 μL reaction volume containing 10 μL Fast qPCR Mix, 0.8 μL of each primer (10 μM), 2 μL cDNA template, and 6.4 μL PCR-grade water. The amplification procedure was per denaturation (95°C, 1 min), denaturation (95°C, 10 s, 40 cycles), annealing (60°C, 5 s, 40 cycles), extension (72°C, 15 s, 40 cycles), and melting curve at 95°C after 30 min. The 2-ΔΔCT comparative CT method was used to analyze the expression level of these genes [44].

2.9. Statistical Analysis

The data are presented as the . Statistical analysis for homogeneity was undertaken with Levene’s test, and when necessary, arcsine, square root, or logarithmic transformations were performed prior to analysis. One-way analysis of variance (ANOVA) analyses were performed and differences determined using Duncan’s multiple range test. The relationship between CH levels and growth performance and PL levels regarding fatty acid composition was associated using Pearson’s correlation coefficients. Two-way ANOVA analysis was used to separate the effects of PL, CH, and their interaction. A value of <0.05 was considered statistically significant. The relative expression levels were calculated using the 2-ΔΔCT equation [44].

3. Results

3.1. Growth and Molting Performance

The growth performances of P. clarkii fed diets with different PL and CH supplementations are presented in Table 3. Growth performance was significantly affected by PL level () based on the two-way ANOVA. The WGR and SGR were highest in crayfish fed a diet of 60 g/kg PL and 10 g/kg CH supplementation (Tables 4 and 5; Figures 1 and 2). No significant difference was detected for the SR of crayfish among the different dietary treatments (). With an increasing CH level up to 10%, the optimum molting rate was obtained when the crayfish were fed the 60 g/kg PL diet (Figure 3).

3.2. Hepatopancreas and Ovary Development

As shown in Table 6 and Figure 4, the PL and CH interaction significantly affected the total lipid content in the hepatopancreas and E2 in the ovaries (). The total lipid levels decreased significantly with increasing PL levels up to 60 g/kg in the diet (). Additionally, the HSI was significantly affected by the CH level (), and the GSI was significantly affected by the PL level () in the feed. The highest HSI was obtained in the juvenile crayfish fed the 0 g/kg CH, and the poorest GSI was obtained when juvenile crayfish were fed the 0 g/kg PL diet ().

Figures 5 and 6 show the hepatopancreas and ovary morphological structure of P. clarkii fed different diets. B-cells in the 60 g/kg PL level group were more abundant than the crayfish fed the other feed groups. A noticeable increase in the number of vacuoles in R-cells was observed in the group without PL supplementation compared to crayfish fed the other diets () (Table 7). The eggs were more compactly arranged and signified advanced developmental stages in the 60 g/kg PL diet.

3.3. Muscle Proximate and Hepatopancreas Fatty Acid Composition

The proximate composition of crayfish muscle is summarized in Table 8. Based on the two-way ANOVA analysis, the muscle total lipid, ash, and moisture showed no significant difference among the different treatments (). The muscle protein level showed significant differences among the different PL and CH levels (), and the highest content occurred in the 5 g/kg CH group.

Table 9 shows the fatty acid composition (%, total detectable fatty acids) in the diets of juvenile female P. clarkii, with a higher C18:2n-6 content found in diets containing increasing dietary PL levels (Table 10). The results for hepatopancreas fatty acid composition are shown in Tables 11 and 12. The C18:2n-6 content showed a decreasing trend, whereas C20:4n-6, C20:5n-3, and C22:6n-3 contents showed an increasing trend with an increase in dietary PL supplementation (Table 10 and Figure 7).

3.4. Hepatopancreas and Serum CH Composition

Table 13 shows the hepatopancreas and serum CH composition of juvenile P. clarkii fed the nine diets. The two-way ANOVA showed that the serum TCH content, HDL-C, and LDL-C, and the hepatopancreas TCH content were significantly affected by dietary PL and CH levels (). With an increase in the PL level, the serum HDL-C/LDL-C showed a decreasing trend (Figure 8). In contrast, the TCH of the hepatopancreas showed an increasing trend (). Likewise, the serum TG content increased with an increase in dietary CH supplementation ().

3.5. mRNA Expression of Genes Related to Molting

Gene expression related to molting is shown in Figure 9. Diet9 had the highest levels of ecdysone receptor- (EcR-) mRNA in the hepatopancreas among the three treatments (). When the addition amount of PL was 60 g/kg, P. clarkii fed with 10 g/kg CH supplementation had significantly higher EcR expression level than the P. clarkii fed with 0 and 5 g/kg CH supplementation (), which showed a positive trend with increasing CH levels in the diet.

4. Discussion

The present study showed no interaction between dietary PL and CH levels on the growth performance of juvenile female P. clarkii under controlled environmental conditions. This result is similar to other studies that examined the swimming crab Po. trituberculatus [30], black tiger prawn Penaeus monodon [17], marine shrimp Penaeus penicillatus [18], and freshwater prawn Macrobrachium rosenbergii [14]. One possible reason for observing normal growth without PL and CH supplementation was that the red swamp crayfish can synthesize PL and steroids to fulfill its growth needs. Similar results have been obtained in other studies [14, 24, 26, 45]. The second possible reason could be due to choline chloride in feed, which could serve as the material for phosphatidylcholine synthesis [46]. Crustaceans can synthesize phosphatidylcholine [45]. In the present study, 5 g/kg choline chloride was added in different experiment feeds, which could meet the normal growth requirement of juvenile female P. clarkii.

As a source of energy, cell membrane component, and emulsifier, PL was added to the diet of crustaceans. Increasing growth is one of the beneficial effects of supplementing PL in the diet [33, 47, 48]. The growth performance indicated that the crayfish fed a semipurified diet containing up to 6% of PL (soybean lecithin) significantly enhanced growth compared to the diet lacking supplemental PL.

Many crustaceans are incapable of de novo synthesis of sterols [49]. However, high dietary sterol levels in diets retard growth in crustaceans [25, 32, 50]. For the crayfish fed diets supplemented with 0–20 g/kg PL, the final weight, WGR, and SGR showed a negative growth response with an increase in dietary CH supplementation. This result was in accordance with results for juvenile Penaeus monodon [51]. The best growth performance of crayfish was when 60 g/kg PL and 10 g/kg CH were supplemented in the diet. This might be caused by CH playing a crucial role in the metabolism of nutrients, such as amino acids, fatty acids, and vitamins [52]. In addition, the Y-organs of crustaceans synthesize and secrete ecdysteroid (molting hormones), which control the molting performance [53]. The ecdysone is bound to the EcR and retinoid X receptor (RXR) in the nucleus, which activates the EcR-RXR complex, and the complex can regulate the transcription of target genes, such as chitinase [5457]. Moreover, CH serves as a precursor of ecdysteroid biosynthesis in crustaceans [27, 52]. Several studies have shown that the recommended CH level in the diet enhanced the molting performance in crustaceans [27, 31]. In the present study, for all PL 60 g/kg groups, the crayfish fed with a CH supplemental level of 10 g/kg had a significantly higher molting rate, and the relative EcR expression level in this group was also the highest. Previous studies have shown that dietary CH supplemental level affected ecdysteroid signal transduction [4] and molting rate determined the growth performance of crustaceans [27]. Therefore, the increased molting rate caused by the higher PL and CH levels might be the main reason for the better growth performance of the Diet9 group.

The hepatopancreas is the crucial organ for lipid absorption, storage, and transport in crustaceans [58, 59]. Its histology can be used to monitor the nutritional value of diets in aquaculture [60]. The hepatopancreas comprises four main types of cells within the hepatopancreatic tubules: F-cells that synthesize digestive enzymes and absorption, E-cells that are undifferentiated, and R-cells and B-cells that are responsible for nutrition storage and digestion, respectively [6164]. In the present study, the decreased numbers of R-cells were due to the decreased accumulation of lipids in the hepatopancreas of the crayfish fed higher PL content diets (60 g/kg). In contrast, the numbers of B-cells showed an increasing trend, implying an increased transport of lipids in the hepatopancreas of crayfish fed high PL level diets. In previous studies, R-cells and B-cells had a similar trend, caused by the transport of nutrients such as lipids [64, 65].

The fatty acid composition of the hepatopancreas reflects the dietary fatty acid composition [11, 66] and is a lipid storage organ that is more affected by feed than other organs [43]. At the same CH supplementation in feed, the linoleic acid (C18:2n-6) content in the diet gradually increased with an increase in PL levels. This might be attributed to the soybean lecithin, which contained higher levels of C18:2n-6 [30, 67]. The content of polyunsaturated fatty acids (PUFA) and long-chain unsaturated fatty acids (lcPUFA) in the hepatopancreas presented an increasing trend with increasing PL content in the feed. Previous studies have demonstrated that the appropriate PL in feed could promote fatty acid synthase activity in the hepatopancreas. Similar speculations were observed in previous studies examining the freshwater crustacean [68, 69]. Thereby, we speculate that P. clarkii was capable of synthesizing PUFA and lcPUFA, which utilizes exogenous linolenic acid, although the crayfish could not synthesize de novo PUFA and lcPUFA. Thus, P. clarkii could be an excellent model organism for lcPUFA synthesis in crustaceans.

HDL and LDL can reflect the CH transport in the serum of crustaceans [5], and an increased or decreased HDL/LDL proportion indicates whether CH in the serum enters the hepatopancreas to participate in metabolic activities or moves from the hepatopancreas to tissues [66, 70]. In the present study, the proportion of HDL/LDL decreased with an increase in PL content. This is because PL promotes the transport of lipids [13, 71], which carry more lipids into the ovaries from the hepatopancreas during ovarian development. The serum TG content was not significantly affected by the PL addition levels. Similarly, Lin et al. [12] reported no significant difference in serum TG content between the soybean lecithin group and the control. A positive correlation between the serum TG content and dietary CH level was observed in the present study, which was in agreeance with the results of previous studies [30, 70].

Lipids are crucial for the development of ovaries [72]. Appropriate dietary PL and CH supplementation are conducive to ovarian development in crustaceans [13, 39, 59, 73]. In the present study, almost all eggs were in stage IV, with staging confirmed according to the methodology described by Kulkarni et al. [74]. Crayfish fed with diets containing high PL (60 g/kg) content had higher GSI, and the eggs were more compactly arranged in tissue sections. Many researchers have shown that the hepatopancreas can synthesize steroid estrogens, such as E2, which are derivatives of CH, and are then transported through the hemolymph to the ovary [36, 49, 75]. E2 can activate the vitellogenin, accelerating ovarian tissue development [7679]. Therefore, PL facilitates CH absorption and metabolism in the hepatopancreas and increases vitellogenin activity in the ovaries, improving ovarian development. An inverse correlation between HSI and GSI was observed in the present study, confirming this inference. E2 content shows an increasing trend followed by a decreasing trend with increasing ovarian development in crustaceans [8082]. When Emerita asiatica eggs developed into stage V, the E2 levels gradually stabilized to a low level [36]. In the present study, the significant decrease in the E2 levels in the PL 60 g/kg and CH 5 g/kg group was similar to this situation. The comparison of ovarian development among dietary PL and CH levels showed that the addition of CH effectively improved ovarian development only when there was a sufficient PL level.

5. Conclusion

Optimal dietary PL and CH levels improved the growth performance and promoted ovarian development in the crayfish P. clarkii when the CH addition level was 10 g/kg and the PL level was at least 60 g/kg. The serum CH level showed that higher dietary PL levels facilitated the transport of CH from the hepatopancreas, leading to changes in the molting rate and ovarian development.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare no conflict of interest.

Authors’ Contributions

Shouquan Hou designed and performed the whole experiment under the help of Jiayao Li. Shouquan Hou drafted the manuscript. Jinghao Li, Shaicheng Zhu, and Jin Huang revised the manuscript. Yongxu Cheng provided the experimental facilities.

Acknowledgments

This study was funded by National Key Research and Development Program of China (2019YFD0900304), the Special Fund for Centrally-Guided Local Science and Technology Development in Anhui Province (201907d06020008), the Industrial Strong Town Project of the Ministry of Agriculture and Rural Affairs and the National Development and Reform Commission of China (2019-245), the Special Fund (CARS-48) of Chinese Agriculture Research System from Ministry of Agriculture of China, and the construction and improvement project (No. A1-2801-18-1003) for high level university in Shanghai from Shanghai Education Commission.