An Evaluation of Replacing Fish Meal with Fermented Soybean Meal in Diet of Hybrid Snakehead (<i>Channa argus × Channa maculata</i>): Growth, Nutrient Utilization, Serum Biochemical Indices, Intestinal Histology, and Microbial Community

Duan, Zhipeng; Zhang, Chunyan; Huang, Lingling; Lan, Qing; Hu, Jie; Li, Xiaoqin; Leng, Xiangjun

doi:https://doi.org/10.1155/2022/2964779

Aquaculture Nutrition

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Abstract Introduction Materials and Methods Results Discussion Conclusion Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2022 | Article ID 2964779 | https://doi.org/10.1155/2022/2964779

An Evaluation of Replacing Fish Meal with Fermented Soybean Meal in Diet of Hybrid Snakehead (Channa argus × Channa maculata): Growth, Nutrient Utilization, Serum Biochemical Indices, Intestinal Histology, and Microbial Community

Zhipeng Duan,^1,2,3Chunyan Zhang,^1,4Lingling Huang,⁴Qing Lan,⁴Jie Hu,⁴Xiaoqin Li,^1,2,3and Xiangjun Leng^1,2,3

Academic Editor: Mansour Torfi Mozanzadeh

Received07 Nov 2021

Revised09 Jan 2022

Accepted13 Jan 2022

Published17 Feb 2022

Abstract

The present study investigated the effect of fish meal (FM) replacement with fermented soybean meal (FSM) on growth performance, nutrient utilization, serum biochemical indices, intestinal histology, and microbial community of hybrid snakehead. Five isonitrogenous diets were formulated with FSM inclusion to decrease dietary FM from 350 g/kg (the control diet) to 300, 250, 200, and 150 g/kg, referring to CON, FM-30, FM-25, FM-20, and FM-15, respectively, and then fed to hybrid snakehead with initial body weight of for 60 days. The control group showed the best growth with a weight gain rate (WGR) of 417.0% and a feed conversion ratio (FCR) of 0.84, but the WGR in FM-25, FM-20, and FM-15 groups was decreased by 26.25%, 40.60%, and 42.23% and FCR was increased by 0.24, 0.45, and 0.45, respectively, when compared to those in the CON group (). The apparent digestibility coefficients of dry matter and crude protein, the protein efficiency and retention, the serum total cholesterol content, and the intestinal muscle thickness in FM-20 and FM-15 groups and the villus height in all FSM groups were significantly lower than those in the CON group (). Intestinal microbiota analysis indicated that the main microorganisms included Proteobacteria, Firmicutes, and Actinobacteria. At the genus level, Plesiomonas was the dominant genus with the highest relative abundance in the FM-20 group. In summary, in a diet containing 350 g/kg FM, FSM can successfully replace 50 g/kg dietary FM without negative effects on growth performance, nutrient utilization, serum biochemical indices, and intestinal health of hybrid snakehead juvenile.

1. Introduction

The rapid development of aquaculture has led to an increasing demand for fish meal (FM), but the global FM resources are limited and FM price kept rising in recent years. Therefore, seeking new protein sources to reduce the use of FM has become the focus of aquaculture nutrition and feeds. Soybean meal (SBM) is an important protein source in aquatic feed due to its abundant resources, relatively balanced nutrient composition, and relatively low price [1]. However, SBM contains a variety of antinutritional factors, such as glycinin, β-conglycinin, trypsin inhibitor, and soybean lectin, negatively affecting the digestion and absorption of aquatic animals ([2–4]. In the last decades, fermentation technology has been widely used in the feed industry. After fermenting with microbes, a large number of antinutritional factors in SBM were degraded, while the contents of crude protein, free amino acid, active components such as small peptides, and soybean isoflavones were increased [5–7]. He et al. [8, 9] reported that fermented soybean meal (FSM) successfully replaced 105 g/kg of FM in a diet containing 350 g/kg FM without negative effects on the growth performance, intestinal histology, and microbiota of largemouth bass (Micropterus salmoides). Choi et al. [10] found that the replacement of 100 g/kg FM with FSM in a diet containing 250 g/kg FM did not adversely affect the growth and feed utilization of rainbow trout (Oncorhynchus mykiss). In black sea bream (Acanthopagrus schlegelii), the partial replacement of dietary FM with FSM showed no significant effects on growth, antioxidant activity, and digestive enzyme activity [11]. In addition, FSM has also effectively partially replaced FM in the diets of Japanese sea bass (Lateolabrax japonicus) [12] and turbot (Scophthalmus maximus) [13].

Snakehead (Channa argus) is a carnivorous fish widely cultured in Asia, including China, Vietnam, Thailand, and India. In 2020, the aquaculture production of snakehead (including hybrid snakehead) reached 501095 tonnes in China [14]. In the market, hybrid snakehead (Channa argus♂× C. maculata♀) is the most commonly cultured species, which was obtained from the hybridization of snakehead as the male parent and blotched snakehead (Channa maculata) as the female parent, both belonging to Perciformes, Channidae, Channa. Compared with its parents, hybrid snakehead has higher survival and better stress resistance and growth performance. Generally, the commercial diets for hybrid snakehead contain high level of animal protein ingredients up to 400~500 g/kg, including FM, chicken meal, and meat and bone meal.

At present, the previous studies have reported the replacement of FM with SBM [15], soybean protein concentrate [16], and corn protein concentrate [17] in the diets of snakehead or hybrid snakehead, but FSM was not tried. Therefore, in this study, FSM was used to replace different proportions of FM in the diet of hybrid snakehead, and the growth performance, nutrient utilization, serum biochemical index, intestinal histology, and microbiota community were investigated to direct the application of FSM in carnivorous fish feeds.

2. Materials and Methods

2.1. Ethics Statement

All the procedures were strictly carried out in accordance with the Regulations of the Experimental Animal Ethics Committee of Shanghai Ocean University and in compliance with regulations by the Institutional Animal Care and Use Committee.

2.2. Experiment Diets and Design

The basal diet (control diet, CON) was designed to contain 350 g/kg FM; then, dietary FM was decreased by FSM to 300, 250, 200, and 150 g/kg (FM-30, FM-25, FM-20, and FM-15), respectively, to form five isonitrogenous diets. The main ingredients were crushed and sieved through 60 mesh. All solid ingredients, including 0.5 g/kg yttrium oxide, were mixed firstly; then, liquid ingredients such as fish oil, soybean oil, and soybean lecithin were added and mixed; then, the mixture was sieved through 40 mesh to distribute components evenly. Finally, 230 g/kg water was added and sieved through 10 mesh. The mixture was extruded to form sinking pellet (diameter of 2 mm) with a single screw extruder (SLP-45, Fisheries Machinery Instrument Research Institute of Chinese Academy of Fisheries Sciences). The extruding temperature was . After pelleting, all experimental diets were air-dried naturally in a ventilated and cool place to maintain suitable moisture content and stored in plastic bags at 4°C until further use. Yttrium oxide was added in all diets as an inert marker to determine the apparent digestibility of nutrients. The feed formula and proximate composition are shown in Table 1.

FSM was provided by Yihai Kerry (Fangchenggang) Biotechnology Co., Ltd. (Shanghai, China). It was a commercial product obtained from the anaerobic fermentation of lactic acid bacteria such as Lactobacillus plantarum and sterilized soybean meal for 72 hours. The FSM product contained 500.0 g/kg crude protein and 10.0 g/kg crude lipid. The proximate composition and amino acid profile of FSM are shown in Table 2.

2.3. Fish and Feeding Management

Hybrid snakehead juveniles were purchased from Ruihai Aquaculture Farm (Guangdong, China). After 2 weeks of temporary stocking, 345 fish with an average weight of were randomly divided into 5 treatments with 3 replicates per treatment and 23 fish per replicate. The feeding trial was carried out in 15 tanks (), and all tanks were individually aerated with air stone in a recirculating system without direct sunshine. The circulating water passed through the physical filter such as filter stone, filter cloth, and filter cotton and then flowed into each tank with a flowing velocity of 1.2 L/min. During the feeding period, the fish were fed twice a day (09:00 and 16:00) with a feeding rate of 30 g/kg-40 g/kg of body weight, which was adjusted according to the feeding behavior to ensure no feed residue in 5 min after feeding. The feces at the bottom of the tank were siphoned out every day, and the water was renewed 1/4 with aerated tap water every two days. The water temperature (22–28°C), dissolved oxygen (>6 mg/L), pH (7.5-8.0), ammonia nitrogen (<0.01 mg/L), and nitrite (<0.1 mg/L) were monitored daily during the feeding period. The feeding trial was performed in the indoor culture system of the Fish Nutrition Laboratory of Shanghai Ocean University and lasted for 60 d.

2.4. Sample Collection

Before the feeding trial, ten fish were collected and stored at -20°C as initial samples. In the last two weeks of the feeding trial, the intact feces were collected by siphoning between the 2^nd and the 3^rd hour after feeding and then stored at -20°C for the digestibility measurement. At the end of the feeding trial, all fish were deprived of diets for 24 hours and then counted and weighed. Nine fish were randomly selected from each tank, and three fish were stored at -20°C for the proximate composition analysis of the whole body. Another three fish were measured in terms of body length, body weight, and visceral weight. The liver was collected and preserved at -80°C to determine liver antioxidant parameters. After the intestinal mesentery was removed and the intestinal contents were washed off with 8.6 g/L normal saline, the foregut was collected and preserved at -80°C to determine the activity of digestive enzymes. Blood was taken from the caudal vein of the remaining three fish and centrifuged at for 15 min at 4°C; then, the supernatant was stored at -80°C for the determination of biochemical indexes. The foregut was sampled and fixed in Bouin’s fixative solution for the intestinal tissue section. After being rinsed with aseptic saline, the hindgut was preserved in liquid nitrogen for intestinal microbiological analysis.

2.5. Measurement Indicators and Methods

2.5.1. Growth Performance and Physique Index

Weight gain rate (WGR), survival, specific growth rate (SGR), feed conversion ratio (FCR), condition factor (), and viscerosomatic index (VSI) were calculated as follows:

2.5.2. Proximate Composition of Diets, Whole Body, and Amino Acid Profiles of FSM

Proximate composition of diets and whole body was analyzed according to the Association of Official Analytical Chemists method [18]. Moisture was determined by oven-drying samples at 105°C to constant weight. Crude protein was measured by the Kjeldahl method (2300 Auto analyzer, FOSS Tecator, AB, Hoganas, Sweden). Crude ash was measured by the high-temperature burning method at 550°C in a muffle furnace (SXL-1008, Shanghai Jinghong Experimental Equipment Company, China). Crude lipid was determined by the chloroform-methanol extraction method at 50°C to constant weight with a vacuum drying oven (DZF-6050, Shanghai Huitai Instrument Manufacturing Company, China).

FSM was hydrolyzed with 6 mol/L hydrochloric acid at 110°C for 24 h. In addition, some samples were hydrolyzed with 4 mol/L lithium hydroxide at 110°C for 24 h for the determination of tryptophan. Then, use the automatic amino acid analyzer (S-433D, Germany) to determine the amino acid content of FSM.

2.5.3. Serum and Liver Parameters

Serum alanine aminotransferase (ALT), aspartate aminotransferase (AST), glucose (GLU), triglyceride (TG), and total cholesterol (TCHO) were determined by using an automatic biochemical analyzer (Chemray 800), and the corresponding kits were produced by Shanghai Haling Biotechnology Co., Ltd. (Shanghai, China).

Frozen liver samples were thawed at 4°C, then homogenized with nine times volume () of ice-cold saline (8.6 g/L NaCl), and centrifuged at for 15 min at 4°C. The supernatant was collected to analyze antioxidant parameters. Malondialdehyde (MDA) and total antioxidant capacity (T-AOC) were determined using the kit (Nanjing Jiancheng Biological Co., Ltd.).

2.5.4. Nutrient Retention and Apparent Digestibility Coefficient

After the burning at 900°C for 1 hour, feces samples were dissolved in the solution of nitric acid and hydrogen peroxide. Then, yttrium was analyzed by inductivity-coupled plasma optical emission spectroscopy (ICP-OES; Vista MPX; VARIAN) [10].

The apparent digestibility coefficient (ADC) of dry matter (DM) and crude protein (CP), protein retention (PR), and protein efficiency rate (PER) were calculated according to the following formulas:

2.5.5. Intestinal Digestive Enzyme Activity

Frozen anterior intestine samples were thawed at 4°C, then homogenized with nine times volume () of ice-cold saline (8.6 g/L NaCl), and centrifuged at for 15 min at 4°C. The supernatant was collected to analyze digestive enzyme activity in 24 h. Protease activity was measured according to Su et al. [19], where one unit was defined as 1 μg tyrosine released per minute by hydrolyzing casein in phosphate buffer at pH value of 7.2 and reaction temperature of 37°C (1 mg tissue protein). Amylase was determined by the iodine-starch colorimetric method with a kit produced by Nanjing Jiancheng Bioengineering Institute, and one unit (U/mg prot) was defined as 10 mg of starch hydrolyzed in the reaction with 1 mg tissue protein acting on the substrate for 30 min at 37°C.

2.5.6. Intestinal Histology

The tissue was dehydrated in a series of alcohol solutions and embedded in paraffin. Then, sections (5–6 μm) were cut and stained with haematoxylin-eosin and sealed with a neutral gum. The morphological structure of the tissue was observed using an imaging microscope (Nikon YS100), including villus width, height, and muscle thickness. The image was analyzed with the ImageJ 14.0 image analysis software.

2.5.7. Intestinal Microbiota

The intestinal samples were sent to Shanghai Majorbio Bio-Pharm Technology Co., Ltd. for extraction of DNA and PCR amplification by the Illumina MiSeq Sequencing platform. The V3-V4 variable regions of the 16S rRNA gene were amplified by PCR with primers 338F (5-ACTCCTACGGGAGGCAGCAG-3) and 806R (5-GGACTACHVGGGTWTCTAAT-3). Purified amplicons were pooled in equimolar and paired-end sequenced () on the Illumina MiSeq platform (Illumina) according to the standard protocols by Majorbio Bio-Pharm Technology Co., Ltd. Operational taxonomic units (OTUs) were clustered with 97% similarity cut-off using UPARSE (version 7.1 http://drive5.com/uparse/) with a novel “greedy” algorithm that performs chimera filtering and OTU clustering simultaneously. The community composition and community abundance at phylum and genus levels were analyzed on the free online platform of Majorbio Cloud Platform (https://www.majorbio.com).

2.5.8. Statistical Analysis

Excel 2003 and SPSS software (SPSS Inc., Michigan Avenue, Chicago, IL, USA) were used for statistical analysis. The data were expressed in the form of (SD). Arcsine transformations were conducted on all data expressed as percentages to achieve homogeneity of variance before statistical analysis. One-way ANOVA was performed at a significance level of 0.05 following confirmation of normality (one-sample Kolmogorov-Smirnov test) and homogeneity of variance (Levene’s test). Tukey’s procedure was used for multiple comparisons.

3. Results

3.1. Growth Performance

As shown in Table 3, the FM-30 group showed the similar WGR, FCR, and SGR to the CON group (), while the WGR and SGR of FM-25, FM-20, and FM-15 groups were significantly lower and the FCR was significantly higher than those of the CON group (). No significant differences were found in survival, , and VSI among all the groups ().

3.2. Whole Body Composition

In Table 4, the moisture content in the FM-25 group was significantly lower than that in FM-20 and FM-15 groups (), and the crude lipid content in FM-20 and FM-15 groups was significantly lower than that in the CON group (). No significant differences were found in crude ash and crude protein contents among all the groups ().

3.3. Nutrient Utilization

With the increasing replacement of fish meal with FSM, the ADCDM, ADCCP, PER, and PR tended to decrease. The FM-30 group showed the similar levels to the CON group (), while other groups had significantly lower ADCDM, PER, and PR than the CON group (). In FM-20 and FM-15 groups, the ADCCP was also significantly lower than that of the CON group () (Table 5).

3.4. Serum and Liver Biochemical Indices

As shown in Table 6, serum TCHO content tended to decrease with the decrease in dietary FM, and FM-20 and FM-15 groups showed significantly lower values than the CON group (). There was no significant difference in the activities of ALT and AST and the contents of GLU and TG among all the groups (). In the liver, the MDA content in FM-30, FM-20, and FM-15 groups was significantly lower, while the T-AOC was significantly higher than those in the CON group ().

3.5. Intestinal Digestive Enzyme Activity

As shown in Table 7, intestinal protease activity decreased with the decrease in FM content in diet, and the protease activity in FM-25, FM-20, and FM-15 groups was significantly lower than that in the CON group (). No significant difference was found in amylase activity among all the groups ().

3.6. Intestinal Morphology

The intestinal morphology is shown in Table 8 and Figure 1. The intestinal muscle thickness and villus height decreased with the decrease in the FM inclusion in diet, and muscle thickness in FM-20 and FM-15 groups and villus height in FM-30, FM-25, FM-20, and FM-15 groups were significantly lower than those in the CON group (). No significant difference was found in villus width among all the groups ().

3.7. Intestinal Microbial Community

As shown in Table 9, the coverage index was close to 1, which indicated that the bacterial community had been fully sampled and the data could represent the bacterial population.

The Venn diagram of OTUs is shown in Figure 2, and the number of OTUs ranged from 1368 to 1536. The number of common OTUs in CON, FM-30, FM-25, and FM-20 groups was 359, and the number of unique OTUs in CON, FM-30, FM-25, and FM-20 groups was 636, 627, 558, and 516, respectively.

At the phylum level, the intestinal microbiota of all groups was mainly composed of Proteobacteria, Firmicutes, and Actinobacteria (Figure 3). In the CON group, the dominant bacteria were Proteobacteria, accounting for 39.84% of the total bacteria, followed by Firmicutes (22.04%) and Actinobacteria (12.20%). With the increase in replacement of FM with FSM, the relative abundance of Proteobacteria decreased at first and then increased, while Actinobacteria showed an opposite trend.

At the genus level, intestinal microorganisms mainly included Plesiomonas, Rhodococcus, Thiopseudomonas, Bacillus, Bacteroides, and Cetobacterium (Figure 4). Rhodococcus (5.26%) and Thiopseudomonas (10.95%) were the dominant bacteria in the CON group. Compared with the three groups of CON, FM-30, and FM-25, the FM-20 group showed great difference in Plesiomonas, which was the dominant genus in the FM-20 group, accounting for 27.42% of the total.

4. Discussion

4.1. Growth Performance and Nutrient Utilization

In the present study, the replacement of 50 g/kg FM with FSM in diet did not affect the growth and feed utilization of juvenile hybrid snakehead, but when the FM replacement level reached 100 g/kg, a significant decrease in growth was observed. FSM lacks some active substances such as taurine, trimethylamine oxide, and unknown growth factors rich in FM, and the decrease in FM inclusion in diet also reduced the palatability of the feed. Although the dietary requirement of taurine has not been determined, supplementing taurine (1 g/kg) to the diet of hybrid snakehead increased the inclusion level of SBM to replace FM [20]. Dietary supplementation of taurine also improved the resisting ability against ammonia stress in hybrid snakehead [21]. In addition, a small amount of antinutritional factors such as saponins and phytin may exist in FSM, although most of them have been degraded by microorganism during the fermentation. Thus, in this study, when FM was replaced by FSM up to 100 g/kg, the feed intake of hybrid snakehead was significantly decreased and the FCR was significantly increased, leading to a significant decrease in WGR. In rainbow trout, FSM successfully replaced 100 g/kg FM in a diet containing 250 g/kg FM without adverse effects on the growth and feed efficiency, but higher FM replacement (150 g/kg) decreased the growth [10]. He et al. [8, 9] found that FSM could replace 105 g/kg FM in a diet containing 350 g/kg FM without significant effects on the WGR and feed utilization of largemouth bass. In the present study, the proportion of FSM replacing FM was lower than that of rainbow trout and largemouth bass reported by Choi et al. [10] and He et al. [8, 9], which may be related to the small size of fish used in this study and to the high dependence of hybrid snakehead on animal protein, especially FM. For juvenile rockfish (Sebastes schlegeli) with body weight of 1.2 g, FSM could replace 58 g/kg of dietary FM, while for young rockfish with body weight of 148.2 g, the replacement proportion of FM reached 232 g/kg [22], which indicated that the tolerance of juvenile rockfish to FSM was lower than that of bigger fish. The replacement level of FM with FSM depends on dietary FM level, fish species, growth stage, and the supplementation of essential nutrients and active ingredients [23].

In the present study, when the replacement of FM with FSM reached 100 g/kg, the nutrient digestibility and retention of juvenile hybrid snakehead were decreased significantly. In largemouth bass and rainbow trout, when the FSM inclusion level was 235.2 g/kg and 210 g/kg, the nutrient digestibility and retention also decreased significantly (He et al., [8–10]). This may be related to the lack of active substances such as taurine and unknown growth factors in FSM, which reduced the nourishing effect on the intestinal tract. It has been found that taurine can not only promote the secretion of some hormones and enzymes related to digestion in fish but also make more sulfur-containing amino acids participate in protein synthesis [24]. In addition, the crude fiber content in FSM is much higher than that in FM, which is an important antinutritional factor for carnivorous fish. Cherbut et al. [25] found that the decrease in nutrient digestibility caused by plant protein may be related to the increase in cellulose content. High cellulose inclusion in diet will accelerate the emptying rate of chyme in the digestive tract, resulting in the insufficient absorption of nutrients in diets.

4.2. Body Composition and Serum and Liver Biochemical Indices

The present results indicated that the replacement of FM with FSM did not significantly affect the moisture, crude protein, and ash contents in the whole body of juvenile hybrid snakehead, which was similar to the report in rockfish [22]. However, the high replacement of FM with FSM decreased crude lipid content of juvenile black sea bream [26] and the serum TCHO and TG contents of largemouth bass (He et al., [8, 9]). In this study, the crude lipid content of fish and the contents of serum TCHO decreased with the increasing proportion of FSM replacing FM, which may be related to the bioactive peptides existing in FSM. In the process of fermentation, the content of soybean bioactive peptides was increased, which could promote lipid catabolism and inhibit lipid synthesis and storage [27, 28]. In addition, with the increase in the proportion of FSM replacing FM, the feed intake and growth performance of juvenile hybrid snakehead decreased, which also reduced the lipid deposition in the body.

Serum TAOC is a comprehensive index to evaluate the function of the antioxidant system. Lipid peroxidation is the main problem caused by the imbalance of the antioxidant system. MDA, as the final product of lipid peroxidation, has some toxic effects on cells [29]. In the present study, the liver MDA content in FM-30, FM-20, and FM-15 groups was significantly lower, while the TAOC was higher than those in the CON group. Ding et al. [30] also found that the replacement of FM with FSM significantly improved the TAOC in the hepatopancreas of Macrobrachium nipponense. FSM contains plenty of isoflavones, which could scavenge free radicals, inhibit lipid peroxidation, and enhance antioxidant capacity [31]. Zhou et al. [32] once reported that dietary supplementation of 40 mg/kg soybean isoflavones increased the total antioxidant capacity and decreased the MDA content in the liver of golden pompano (Trachinotus ovatus).

4.3. Intestinal Morphology and Digestive Enzyme Activity

The ability of an aquatic species to digest and utilize nutrients is mainly determined by the innate digestive capacity such as gut morphology and digestive enzyme activities. The digestive enzyme activity in the intestine is an important index to reflect the digestive ability of fish, and the height and width of the intestinal villus determine the contact area between mucosal epithelial cells and chyme. The increase in intestinal muscle thickness is beneficial to the mechanical digestion [33]. The high replacement of FM with FSM significantly decreased intestinal protease activity, muscle thickness, and villus height in the present study, which was similar to the findings in orange-spotted grouper (Epinephelus coioides) [34]. Choi et al. [10] also found that the intestinal protease activity tended to decrease with the increasing FSM, which may be associated with the injured intestinal structure. High levels of FSM in diet altered the structural integrity of the intestinal mucosa and, consequently, resulted in epithelial damage and the reduction of intestinal epithelium absorption capacity. The lack of taurine and bioactive peptides in high FSM diets may be connected with such results. Taurine can promote the secretion of some digestion-related enzymes in fish [24]. It has been reported that the supplementation of taurine in diets increased the trypsin activity of juvenile cobia (Rachycentron canadum) [35] and improved the intestinal structure of black carp (Mylopharyngodon piceus) [36]. In addition, Knudsen et al. [37] suggested that soya saponins were involved in triggering the enteritis response, which may be another reason contributing to the lowered protease activity and damaged intestinal structure.

4.4. Intestinal Microbiota

The stability of intestinal microbiota affects the digestion and absorption, the immunity, and the growth of fishes [38]. In the present study, with the increase in FSM replacing FM, the species richness of intestinal microbiota tended to decrease, but no significant effect on the composition of intestinal microbiota was found. In the study of replacing FM and fish oil with mixed plant protein sources and vegetable oils, no significant change in the intestinal microbial composition was observed in European sea bass (Dicentrarchus labrax) [39]. Similarly, the replacement of FM with hydrolyzed wheat protein powder and mixed animal protein did not significantly affect the intestinal microbiota of Asian seabass (Lates calcarifer) [40], and the similar result was also reported in white shrimp (Litopenaeus vannamei) [41].

At the phylum level, the major intestinal microbiota of hybrid snakehead was Proteobacteria, Firmicutes, and Actinobacteria, which was similar to the intestinal microbiota composition of northern snakehead [15]. At the genus level, the intestinal microbiota of hybrid snakehead mainly included Plesiomonas, Rhodococcus, and Thiopseudomonas. Compared with the control group, the relative abundance of Plesiomonas in the FM-20 group increased significantly, reaching 27.42%. Plesiomonas shigelloides is a conditional pathogen, which is considered to be a new pathogen of digestive tract inflammation in many aquatic animals. The reason for the changes may be related to the decrease in species richness and to the insufficient content of taurine in FSM. During intestinal inflammation and immune responses, it has been speculated that dietary FM deficiency induces gut mucosal secretion due to proinflammatory responses that coincide with ex vivo and in vivo gut bacterial translocation. The replacement of dietary FM with FSM might result in gut bacterial translocation due to the inflammatory responses, high mucosal secretion, and structural changes in the gut membrane. Thus, the capacity of firm adhesion of certain bacterial species and their ability to physically cross the gut barrier would be lowered, resulting in the decrease in gut microbiota richness. Taurine has also been shown to regulate gut microecology by inhibiting the growth of harmful bacteria, accelerating the production of short-chain fatty acids, and reducing lipopolysaccharide concentration [42].

5. Conclusion

In a basal diet containing 350 g/kg FM, FSM can effectively replace 50 g/kg FM. Higher proportion of replacement will reduce the growth performance and nutrient utilization and produce adverse effects on the intestinal health of hybrid snakehead.

Data Availability

All data generated or analyzed during this study are included in this article.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Authors’ Contributions

The first author is Zhipeng Duan, and the co-first author is Chunyan Zhang. These authors contribute equally to this work.

Acknowledgments

This study was financially supported by Wilmar (Shanghai) Biotechnology Research & Development Center Co., Ltd.

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