Abstract
A 30-day feeding trial was conducted to determine the effects of dietary glycyrrhizin (GL) on survival, growth performance, expression of feeding-related genes, activities of digestive enzymes, antioxidant capacity, and expression of inflammatory factors of large yellow croaker larvae with an initial weight of mg. Four 53.80% crude protein and 16.40% crude lipid diets were formulated with supplementation of 0%, 0.005%, 0.01%, and 0.02% GL, respectively. Results indicated that larvae fed diets with GL had higher survival rate and specific growth rate than the control (). Compared with the control, the mRNA expression of orexigenic factor genes including neuropeptide Y (npy) and agouti-related protein (agrp) were significantly increased in larvae fed the diet with 0.005% GL, while the mRNA expression of anorexigenic factor genes including thyrotropin-releasing hormone (trh), cocaine and amphetamine regulated transcript (cart), and leptin receptor (lepr) were significantly decreased in larvae fed the diet with 0.005% GL (). The trypsin activity in larvae fed the diet with 0.005% GL was significantly higher than the control (). The alkaline phosphatase (AKP) activity in larvae fed the diet with 0.01% GL was significantly higher than the control (). A clear increase of total glutathione (T-GSH) content, activities of superoxide dismutase (SOD), and glutathione peroxidase (GSH-Px) was observed in larvae fed the diet with 0.01% GL compared with the control (). Moreover, the mRNA expression of interleukin-1β (il-1β) and interleukin-6 (il-6) (proinflammatory genes) in larvae fed the diet with 0.02% GL were significantly lower than the control (). In conclusion, the supplementation of 0.005% -0.01% GL could enhance the expression of orexigenic factor genes, activities of digestive enzymes and antioxidant capacity, ultimately improving the survival, and growth performance of large yellow croaker larvae.
1. Introduction
Glycyrrhizin (GL), also known as glycyrrhizic acid (GA), is an important effective component of licorice, which is a traditional Chinese herbal medicine [1–3]. GL is also recognized as a natural green sweetener, and the sweetness of GL can reach hundreds of times that of sucrose [4–6]. In recent years, the pharmacological action of GL such as liver protection [7–9], anticancer [10, 11], and anti-inflammatory [12–15] have been widely recognized.
Several studies indicated that many main components of Chinese herbal medicines have the advantages of natural, nontoxic, and pollution-free and could be added into animal diets to increase the survival and growth performance of cultured animals. [16–18]. In recent years, studies have proved that GL could promote the growth performance, anti-inflammatory capacity, and innate immunity in the study of poultry and mammalian species [19, 20]. However, the application of GL in aquatic diets has been rarely reported. Results of the study in white shrimp (Litopenaeus vannamei), Asian seabass (Lateolabrax maculatus), and blunt snout bream (Megalobrama amblycephala) prove that GL could improve the anti-inflammatory capacity [21–23]. In particular, Harikrishnan et al. found that different dosages of GL could improve the growth, activity of digestive-antioxidant, and innate-adaptive defense of silver carp (Hypophthalmichthys molitrix) [24].
Because of the high nutritional and economic value, large yellow croaker (Larimichthys crocea) is popular in China [25, 26]. Large yellow croaker larvae are in the nutritional transition period from endogenous nutrition to exogenous nutrition [27, 28]. The larvae already have vision, smell, and taste when they ingested for the first time [29, 30]. However, the weak food intake capacity, immature digestive system, and poor stress resistance of larvae could lead to high mortality. [31–33]. At present, finding suitable feed additives to improve the appetite, digestion, absorption, and immunity of fish larvae is an important nutrition strategy to improve the survival rate of larvae. [34, 35].Though GL has good application prospects and development potential, there are no reports of GL found in the case of fish larvae farming. Therefore, the purpose of this study was to reveal whether GL supplementation could increase the survival, growth performance, expression of feeding-related genes, activities of digestive enzymes, antioxidant capacity, and expression of inflammatory factors in large yellow croaker larvae.
2. Materials and Methods
2.1. Feed Ingredients and Diet Formulation
In this trial four isonitrogenous (53.80% crude protein) and isolipidic (16.40% crude lipid) microdiets were formulated with the supplementing levels of 0%, 0.005%, 0.01%, and 0.02% of GL, respectively (Table 1). Pure GL (above 99.0%) were purchased from Qingdao kaitaike industry and Trade Co., Ltd in Qingdao, China.
Ingredients were ground into fine powder through 150 μm nylon mesh. Then, the mesh of all ingredients was thoroughly mixed with water and fish oil to produce stiff dough. Extrude and round the dough with axial single screw spherical extruder and spheronization to obtain the pellet. Then the pellet was dried at 60°C in a constant temperature for 24 hours. After drying, the microdiets were ground into 250 to 380 μm and 380 to 500 μm particle sizes. Subsequently, the microdiets were packed in transparent and sealed plastic bags, respectively, and stored at -20°C until use. The particle size of the formulated diets ranged from 250 to 380 μm for fish from 15 to 25 days after hatch (DAH) and 380 to 500 μm for fish thereafter.
2.2. Feeding Trial
All larvae in this trial were purchased from Marine and Fishery Science and Technology Innovation Base, Zhejiang, China. Before the feeding trial, the larvae were acclimatized for 3 days by feeding live copepods and microdiets to adapt to the trial feed. Larvae were fed with rotifers (Brachionus plicatilis) (3-7 DAH), brine shrimp (Artemia nauplii) (5-10 DAH), copepods (Calanus sinicus) (8-14 DAH), and microdiets from (12-14 DAH). During the experimental period of 15 to 45 DAH, larvae were completely fed with experimental diet, respectively. Larvae with the initial weight of mg and the initial body length of mm were randomly distributed into 12 breeding plastic tanks (water volume 220 L), and each tank had 2500 larvae. Each diet was randomly assigned to triplicate cages (3 biological repetitions). During the experiment, larvae were fed seven times (06 : 30, 09 : 30, 12 : 30, 15 : 30, 18 : 30, 21 : 30, and 23 : 30) daily. The water temperature was maintained between 23 to 25°C by heating rods and temperature controllers, the pH was maintained between 7.80 to 8.20 and the salinity was maintained between 23 to 27 g/L by renewed water in tanks. The concentration of dissolved oxygen in aquaculture waters should be kept at about 6 mg/L by the gas stones. The daily aquaculture water renewed was maintained between 100 to 200% in each tank.
2.3. Sample Collection
Before the feeding trial, fifty larvae of 15 DAH were collected to measure the initial body length (IBL), initial body weight (IBM) by vernier calipers, and microbalance. After the feeding trial, the survival rate (SR) was calculated by counting the surviving larvae in each tank. Meanwhile fifty larvae of 45 DAH were collected to measure the final body length (FBL) and final body weight (FBL) by vernier calipers and microbalance. The remaining larvae were sampled after 24 hours of fasting to the empty intestine. Thirty larvae from each tank were dissected on ice to separate the head segment (HS) and visceral mass (VM) containing a crude mixture of pancreas, liver, heart, spleen, and intestine. The HS and VM were put into 2.0 ml RNase-free Cryogenic Vials then immediately frozen in liquid nitrogen for gene expression assays. The pancreatic segments (PS) and intestine segment (IS) were separated maintained at 0°C under a dissecting microscope and placed on a glass plate for the assay of activities of digestive enzymes. The remaining larvae in each tank were immediately frozen for body composition analysis.
2.4. Analytical Methods
2.4.1. Body and Diet Composition Analysis
The samples of diet and larvae were laid inside an oven at 105°C for about 24 hours and dried to constant weight for moisture calculation. The crude protein and lipid contents of diet samples and larvae samples were measured by the method of AOAC (2003) with automatic Kjeldahl apparatus (Kjeltec TM 8400, FOSS, Tecator, Sweden) and Soxhlet extraction apparatus (B-801, Switzerland).
2.4.2. Activities of Digestive Enzymes Assay
About 0.1 g PS or IS of larvae were weighed, separately homogenized in 1 ml PBS and centrifugated with a high-speed freezing centrifuge. The supernatant was prepared for the assay of α-amylase, trypsin, and lipase. The brush border membranes (BBM) of the intestine of larvae were extracted by the method of Crane et al. [36]. The BBM were prepared for the determination of alkaline phosphatase activity (AKP) and leucine-aminopeptidase (LAP). Activities of α-amylase, trypsin, and LAP were detected by a colorimetry, while activities of lipase and AKP were detected by a microplate reader. The unit of α-amylase was (U/mg·prot), 1 U/mg · prot was defined as 10 mg starch hydrolyzed per mg protein at 37°C for 10 minutes. The unit of trypsin was (U/mg · prot), 1 U/mg · prot was defined as producing 1 μg of tyrosine at 37°C for 1 minute. The unit of lipase was (U/g · prot). 1 U/g·prot was defined as in this reaction system. 1 μmol substrate was consumed by reacting with the substrate for 1 minute. The unit of AKP was (K/g · prot). 1 K/g·prot was defined as 1 mg phenol produced per g protein at 37°C for 15 minutes. The unit of LAP was (U/L. 1 U/L) was defined as 1 nmol p-nitroaniline produced per L at 37°C for 1 minute. Activities of α-amylase, trypsin, lipase, and AKP were determined in strict accordance with the instructions of assay kit (Nanjing Jiancheng Institute of Biological Engineering, China), and the activity of LAP was determined by the method of Maroux et al. [37]. Three replicates were made for each sample.
2.4.3. Activity of Antioxidant and Innate Immune Enzymes Assay
About 0.1 g VM of larvae were weighed, separately homogenized in 1 ml PBS and centrifugated with a high-speed freezing centrifuge. The supernatant was prepared to detect activities of antioxidant and innate immune enzymes. Activities of superoxide dismutase (SOD), total antioxidant capacity (T-AOC), content of malondialdehyde (MDA), total glutathione (T-GSH), glutathione (GSH), and nitric oxide (NO) were detected by a microplate reader, activities of catalase (CAT), glutathione peroxidase (GSH-Px), total nitric oxide synthase (T-NOS), and inducible nitric oxide synthase (iNOS) was detected by a colorimetry. The unit of SOD was (U/mg · prot). The amount of enzyme corresponding to the sod inhibition rate of 50% in this reaction system was 1 activity unit. The unit of CAT was (mmol/g · prot). 1 mmol/g · prot was defined as the amount of 1 μmol H2O2 decomposed per mg protein per second. The unit of T-AOC was (mmol/g · prot), which was defined as total antioxidant per g protein. The unit of MDA was (nmol/mg · prot), which was defined as the content of MDA per mg protein. The unit of GSH-Px was (U/mg · prot). 1 U/mg · prot was defined as reducing 1 μmol/L GSH in the reaction system (deduct nonenzymatic reaction) per mg protein for 1 minute. The unit of T-GSH and GSH was (μmol/L). The unit of NO was (μmol/g · prot), which was defined as the content of NO per g protein. The unit of T-NOS and iNOS was (U/mg · prot). 1 U/mg · prot was defined as producing 1 nmol NO per mg protein for 1 minute. All of above enzymes were determined in strict accordance with the instructions of assay kit (Nanjing Jiancheng Institute of Biological Engineering, China). Three replicates were made for each sample.
2.5. RNA Extraction and RT-qPCR
About 0.03 g HS or VM of larvae were weighed and separately added into 1 ml Trizol reagent (Takara, Japan). Total RNA was extracted according to the manufacturer’s protocol. The integrity of RNA was evaluated by electrophoresis. After that, the total concentration of extracted RNA was measured by Nano Drop® 2000 spectrophotometer (Thermo Fisher Scientific, USA). Then, the RNA was reversed to cDNA with Prime Script-RT reagent kit (Takara, Japan). Finally, the RT-qPCR was carried out by a quantitative thermal cycler (CFX96TM Real-Time System, BIO-RAD, USA). The reference gene in this experiment was β-actin. All of the primer sequences in this study were synthesized or designed on the basis of the published sequences from Huang et al. [38], Wu et al. [39], and GenBank (Table 2). The reaction system of qPCR was 20 μl in total containing 10 μl SYBR® Premix Ex Taq™ II (Takara, Japan), 7 μl of RNase-free water, 2 μl of cDNA, 0.5 μl of upstream, and downstream primers. The program of qPCR was as follows: 95°C for 2 mins, followed by 39 cycles of 95°C for 10 s, 59°C for 10 s, and 72°C for 20 s. The mRNA expression of genes was calculated with the previous method (2–ΔΔCT) [40]. Three replicates were made for each sample.
2.6. Calculation and Statistical Analysis
SPSS Statistics 19.0 was used to conduct all data in this study, and then one-way analysis of variance (ANOVA) and Tukey’s test were used to analyze the data. The significance level was selected as P <0.05. All results were presented as (standard error of the mean).
3. Results
3.1. Survival, Growth Performance and Body Composition
With increasing GL supplementation, the SR, FBL, FBW, WGR, and SGR in larvae increased firstly and then decreased (Table 3). The SR of larvae fed diets with GL was significantly higher than larvae fed the control diet (). Compared with the control, the FBL, FBW, WGR, and SGR were significantly increased in larvae fed diets with GL (). Furthermore, the FBW and SGR of larvae fed the diet with 0.005% GL were significantly higher than larvae fed diets with 0.01% and 0.02% GL (P <0.05). There were no significant differences among dietary treatments in the body composition () (Table 4).
3.2. The mRNA Expression of Orexigenic and Anorexigenic Factor Genes
For the orexigenic factor genes, with GL level in the micro-diet increasing from 0% to 0.02%, the mRNA expression of npy and agrp increased followed by decreased (Figure 1). The mRNA expression of npy and agrp were remarkedly increased in larvae fed the diet with 0.005% GL compared with the control (). For the anorexigenic factor genes, with the increase of GL from 0% to 0.02%, the mRNA expression of trh, lepr, and cck showed a decreasing trend. The mRNA expression of trh and lepr of larvae fed diets with GL was significantly lower than the control, while the mRNA expression of cck in larvae fed the diet with 0.02% GL was significantly lower than the control (). The mRNA expression of cart was significantly decreased in larvae fed diets with GL compared with the control (). No significant differences were found among dietary treatments in gene expression of ghrelin, pomc, and leptin ().
3.3. Digestive Enzymes Activities and Intestinal Development Index
For digestive enzymes activities, with the increase of GL in diets, activities of trypsin, α-amylase, and lipase in both PS and IS of larvae increased firstly and then decreased (Table 5). Larvae fed the diet with 0.005% GL had significantly higher activity of trypsin in PS and IS than the control (). Meanwhile, larvae fed the diet with 0.005% GL had significantly higher activity of α-amylase and lipase in IS than the control (). However, no significant differences were found among dietary treatments in activities of α-amylase and lipase in larval PS (). For intestinal development index, larvae fed diets with GL had significantly higher activity of AKP in brush border membranes than the control (P <0.05). No significant differences were detected in the activity of LAP among dietary treatments (P >0.05).
3.4. Antioxidant Capacity
With the increase of GL supplementation from 0% to 0.02%, activities of SOD and GSH-Px in larvae showed increasing followed by decreasing trends (Figures 2(a)–2(e)). Compared with the control, larvae fed diets with GL had significantly higher activity of SOD (). The activity of GSH-Px in larvae fed the diet with 0.01% GL was remarkedly increased compared with the control (). The content of T-GSH in larvae fed diets with 0.01% and 0.02% GL was significantly higher than the control () (Figure 2(f)). However, no statistical discrepancy was found among dietary treatments in T-AOC, CAT, MDA. and GSH (P >0.05) (Figures 2(b), 2(c), 2(d), and 2(g)).
(a)
(b)
(c)
(d)
(e)
(f)
(g)
3.5. Inflammation-Related Indexes
With the increase of GL from 0% to 0.02%, the NO content, T-NOS activity, and iNOS activity in larvae ascended firstly and then descended (Figures 3(a)–3(c)). The content of NO in larvae fed the diet with 0.01% GL was remarkedly increased compared with the control. () (Figure 3(a)). Larvae fed diets with 0.005% and 0.01% GL had significantly higher activity of T-NOS than the control (). However, there were no significant differences among dietary treatments in iNOS (). For the proinflammatory cytokine genes, with increasing GL supplementation, the mRNA expression of thf-α, inf-γ, il-1β, and il-6 showed decreasing trends, while the mRNA expression of il-8 increased firstly and then decreased (Figure 4). The mRNA expression of il-1β and il-6 in larvae fed the diet with 0.02% GL were remarkedly decreased compared with the control (). However, the mRNA expression of tnf-a, ifn-γ, and il-8 showed no significant difference among different treatments (P >0.05). For the anti-inflammatory cytokine genes, larvae fed diets with GL had significantly higher mRNA expression of il-10 than the control (P <0.05).
(a)
(b)
(c)
4. Discussion
The main components of many Chinese herbal medicines can be used as feed additives to improve the survival and growth performance of cultured animals [8, 10, 32]. The result of this study demonstrated that GL supplementation could increase the survival rate, specific growth rate, and weight gain rate of large yellow croaker larvae. Similarly, the promoting effect of growth performance was also reported in white shrimp [23] and yellow catfish (Pelteobagrus fulvidraco) [41]. These results were probably due to the positive effect of GL supplementation on appetite, digestive enzymes activities, antioxidant capacity, and anti-inflammatory capacity.
In the early stage of growth, appetite stimulation plays a vital role in increasing the survival and growth performance of larvae [42, 43]. The appetite of larvae can be regulated by orexigenic factor genes (npy, agrp, and ghrelin) and anorexigenic factor genes (cart, pomc, trh, leptin, lepr, and cck) [44–46]. The data showed that the supplementation of 0.005% GL could increase the mRNA expression of npy and agrp, while GL supplementation could decrease the mRNA expression of trh, cart, and lepr. Similarly, licorice extract supplementation had been confirmed to increase the growth performance in poultry by stimulating digestion and appetite [47]. In general, GL supplementation might stimulate the larval appetite by regulating the mRNA expression of orexigenic and anorexigenic factors, which might increase the growth performance of large yellow croaker larvae.
Digestive enzymes activities are widely used as an index to study the nutritional status of fish larvae. [48–52]. In this study, the supplementation of 0.005% GL could increase the trypsin activity in both pancreatic and intestinal segments, the α-amylase activity, and the lipase activity in intestinal segments. Similarly, silver carp (Hypophthalmichthys molitrix) fed the diet with GL had higher digestive enzymes activities [24]. Especially, 0.01% GL supplementation could significantly enhance the activities of AKP, which was consistent with previous study of silver carp (Hypophthalmichthys molitrix) [24]. In summary, GL supplementation could enhance the digestive capacity of large yellow croaker larvae by increasing digestive enzymes activities.
Larvae are in a period of rapid growth and are prone to oxidative stress, which will produce oxygen free radicals, eventually leading to body damage [53–56]. The antioxidant system of fish can resist oxidative damage and maintain body health [57]. In this study, GL supplementation could increase the SOD activity, which was similar to the results of white shrimp and yellow catfish treated with GL supplementation [23, 41]. This study also demonstrated that the supplementation of 0.01% GL could increase the content of T-GSH and the activity of GSH-Px, which agreed with the previous study on silver carp [24]. In general, GL supplementation could improve antioxidant capacity of large yellow croaker larvae by increasing antioxidant enzymes activities.
The immune system of larvae was undeveloped, which lead to high mortality in the larval stage [58–60]. In the present study, the supplementation of 0.01% GL could increase the NO content and the T-NOS activity of larvae, which was consistent with the survival rate. A similar result also can be found in the study of white shrimp [23]. Cytokines plays a vital role in innate immunity and inflammatory responses [61]. Many studies have proved that GL can stimulate anti-inflammatory factor production and suppress pro-inflammatory factor production from macrophages [61–63]. In this study, the supplementation of 0.02% GL could decrease the mRNA expression of proinflammatory factors (il-1β and il-6) and increase the mRNA expression of anti-inflammatory factor (il-10), which probably due to the higher proportion of GL supplementation could better reflect the anti-inflammatory capacity of GL. Similar results have been confirmed in studies of silver carp [24], Asian seabass [21], blunt snout bream [22], and yellow catfish [41]. In summary, the supplementation of 0.02% GL could alleviate the inflammation of large yellow croaker larvae.
5. Conclusion
In conclusion, results of the present study confirmed that the supplementation of 0.005% -0.01% GL could enhance the expression of orexigenic factor genes, activities of digestive enzymes, and antioxidant capacity, while the supplementation of 0.02% GL might alleviate inflammation.
Data Availability
The data that support the findings of this study are available from the corresponding author upon reasonable request.
Ethical Approval
All experiments were in line with the Management Rules of Laboratory Animals (Chinese Order No. 676 of the State Council, revised 1 March 2017).
Conflicts of Interest
The authors declare that there are no conflicts of interest.
Acknowledgments
This research was financially supported by the China Agriculture Research System of MOF and MARA (CARS-47) and Leading Talent of Technological Innovation of Ten-Thousands Talents Program (Grant NO. 2018-29).