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Effects of dietary microencapsulated sodium butyrate on growth, intestinal mucosal morphology, immune response and adhesive bacteria in juvenile common carp (Cyprinus carpio) pre-fed with or without oxidised oil

Published online by Cambridge University Press:  28 April 2014

Wenshu Liu
Affiliation:
Key Laboratory for Feed Biotechnology of the Ministry of Agriculture, Feed Research Institute, Chinese Academy of Agricultural Sciences, No. 12 Zhongguancun South Street, Beijing100081, People's Republic of China
Yanou Yang
Affiliation:
Science of Animal and Technology College, Anhui Agricultural University, Hefei230036, People's Republic of China
Jianli Zhang
Affiliation:
Science of Animal and Technology College, Anhui Agricultural University, Hefei230036, People's Republic of China
Delbert M. Gatlin*
Affiliation:
Department of Wildlife and Fisheries Sciences, Texas A&M University System, College Station, TX77843-2258, USA
Einar Ringø
Affiliation:
Norwegian College of Fishery Science, Faculty of Biosciences, Fisheries and Economics, University of Tromsø, Tromsø, Norway
Zhigang Zhou*
Affiliation:
Key Laboratory for Feed Biotechnology of the Ministry of Agriculture, Feed Research Institute, Chinese Academy of Agricultural Sciences, No. 12 Zhongguancun South Street, Beijing100081, People's Republic of China
*
*Corresponding author: D. M. Gatlin, email [email protected]; Z. Zhou, fax +86 10 82106054, email [email protected]
*Corresponding author: D. M. Gatlin, email [email protected]; Z. Zhou, fax +86 10 82106054, email [email protected]
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Abstract

The aim of the present study was to investigate the effects of different dietary sustained-release microencapsulated sodium butyrate (MSB) products (0 (non-supplement), 1·5 and 3·0 h) for a control or oxidised soyabean oil (SBO) diet on fish production, intestinal mucosal condition, immunity and intestinal bacteria in juvenile common carp (Cyprinus carpio). Dietary MSB increased weight gain and reduced the feed conversion ratio within the control and oxidised SBO groups. Gut mucosa was damaged in the oxidised SBO group fed without MSB, in contrast to a normal appearance found in fish fed the MSB1·5 and MSB3·0 diets in the oxidised SBO group. Microvillus density increased in fish fed the MSB1·5 and MSB3·0 diets in the oxidised SBO group (P< 0·001); however, microvillus density was affected by the different pre-fed diets in the midgut (P< 0·001) and by the different sustained-release times of MSB in the distal gut (DG) (P= 0·003). The interaction between the pre-fed diets and the sustained-release times of dietary MSB was significant for the relative gene expression levels of gut heat shock protein-70 (HSP70), pro-inflammatory cytokines (IL-1β and TNF-α) and anti-inflammatory cytokines (transforming growth factor-β) within each gut segment, except for HSP70 in the DG and IL-1β in the foregut. Modulation of adherent bacterial communities within each gut segment investigated was not obvious when the common carp were fed the diets with MSB, as similarity coefficients of >0·79 were observed. These results indicated that MSB can be used as a dietary supplement to repair or prevent intestinal damage in carp fed oxidised SBO.

Type
Full Papers
Copyright
Copyright © The Authors 2014 

The use of antibiotics as growth promoters is a subject of debate in animal production as well as in feed and food industries. Their application in animal feed creates the possibility of building resistance to antibiotics used against bacterial pathogens in animals and humans( Reference Khachatourians 1 , Reference Cassone and Giordano 2 ) as well as in fish( Reference Cabello, Godfrey and Tomova 3 ). In 2006, the European Union banned the use of antibiotics in animal feed as growth promoters (European Parliament and Council Regulation no. 1831/2003). Another issue of concern with fish diets is that lipids are rapidly oxidised during storage due to the high content of PUFA, even though synthetic antioxidants such as butylated hydroxyanisole, butylated hydroxytoluene and tert-butyl hydroquinone are supplemented. Furthermore, some plant extracts are used as feed additives in many countries to retard or prevent oxidative deterioration of oil( Reference Cortesi and Privett 4 ). The products of lipid oxidation such as SCFA, aldehydes and ketones do not only decrease the nutritive value of the feed but also react with cellular membrane components such as protein and DNA( Reference Koshio, Ackman and Lall 5 ). Several studies have reported undesirable effects of feeding oxidised oil in fish, such as Atlantic salmon (Salmo salar), catfish (Clarias gariepinus), Atlantic cod (Gadus morhua) and Japanese sea bass (Lateolabrax japonicas)( Reference Baker 6 Reference Zhang, Yang and Zu 11 ).

Thus, it is imperative to define alternative dietary strategies to support aquaculture productivity. One promising group of feed additives is organic acids, which are low-molecular-weight aldehyde-containing compounds with one or more carboxyl groups( Reference Jones 12 ). During the last two decades, the scientific community has carefully examined the roles and effects of organic acids and their salts on animal production. To our knowledge, the first study in aquaculture evaluating the effects of dietary lactate, acetate and propionate supplementation on growth, composition of the digesta and chemical composition has been carried out by Ringø( Reference Ringø 13 , Reference Ringø 14 ) and Ringø et al. ( Reference Ringø, Olsen and Castell 15 ). Since then, several studies have addressed the effects of organic acids and their salts on feed digestibility, growth, immune response and gut microbiota in aquaculture species( Reference Gislason, Olsen and Ringø 16 Reference Morken, Kraugerud and Barrowsb 20 ). Butyric acid and butyrate have been shown to provide energy for epithelial growth( Reference Topping and Clifon 21 ) and influence a wide array of cellular functions relevant to gut health such as inhibition of inflammation and carcinogenesis, reinforcement of various components of the colonic defence barrier and reduction of oxidative stress( Reference Hamer, Jonkers and Venema 22 ). Based on these findings, butyric acid and butyrate may exert a positive effect on the gut.

To our knowledge, information regarding the effects of butyric acid and butyrate on the common carp (Cyprinus carpio) is lacking. Furthermore, no information is available on the effects of butyric acid and butyrate on fish after feeding oxidised oil that may induce stress and gut damage. Accordingly, the objectives of the present study were to investigate the effects of two types of microencapsulated sodium butyrate products (1·5 h (MSB1·5) and 3·0 h (MSB3·0) sustained release) on (1) growth performance, (2) intestinal mucosal morphology, (3) intestinal immune response and (4) modulation of intestinal adherent (autochthonous) bacterial communities in the common carp when pre-fed a control diet or a oxidised soyabean oil (SBO) diet for 2 weeks followed by the supplementation of MSB diets for 8 weeks. The experiment was designed as a 2 × 3 factorial with two pre-fed treatments (control v. oxidised SBO) and three different sustained-release times of MSB (0 (non-supplement) v. 1·5 and 3·0 h). Due to the short gastrointestinal emptying time in the common carp( Reference Hertrampf and Piedad-Pascual 23 ), we put forward the hypothesis that the MSB1·5-supplemented diet could be highly efficient in preventing or repairing pre-fed oxidised SBO-induced stress and gut damage in the fish. Heat shock protein (HSP)-70 was chosen as a stress marker because HSP70 expression has been reported to be related to stressful conditions in aquaculture, such as temperature oscillations, crowding, insufficient water quality and improper diet( Reference Rollo, Sulpizio and Nardi 24 ). Pro-inflammatory cytokines, including IL-1β and TNF-α, and the anti-inflammatory cytokine transforming growth factor-β (TGF-β) have been commonly used as the reference genes in the studies of immune regulation( Reference Scheiermann, Ott and Hoegl 25 , Reference Liu, Ren and He 26 ).

Materials and methods

Diets

Table 1 presents the formulation and chemical compositions of the basal (control) and experimental diets. Oxidised SBO (2 %) was prepared according to the method described by Ren et al. ( Reference Ren, Huo and Zeng 27 ). Briefly, Fe3+ (30 mg/kg), Cu2+ (15 mg/kg) and H2O2 (600 mg/kg) were added to commercially produced SBO (Jinlongyu) bought from a supermarket. The mixture was stirred at 37 ± 1°C for 48 h. Peroxide values including, acid-, iodine- and thiobarbituric acid-reactive substance values, of the oil were determined as described elsewhere( 28 ). The respective values for fresh and oxidised SBO were as follows: acid value, 1·84 (se 0·21) v. 3·46 (se 0·28) mg KOH/g; iodine value, 137 (se 14·3) v. 148 (se 10·6) 0·01 g I/g; thiobarbituric acid-reactive substance value, 19·6 (se 3·54) v. 2018 (se 148) mg malonaldehyde/kg. All ingredients that were ground into fine powder through a 200 μm mesh were thoroughly mixed with SBO, and an appropriate volume of water was added to produce a stiff dough. The dough was then pelleted with an experimental feed processing machine (Changxing Machine Factory) and air-dried for 24 h at room temperature. Thereafter, the pellets were smashed into pieces, and then proper particles were collected by sieving and stored at − 20°C until further use.

Table 1 Formulation and chemical compositions of the basal and experimental diets (%)*

SBO, soyabean oil.

* See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

During the subsequent 8 weeks, two different sustained-release types of MSB products (MSB1·5 and MSB3·0; Hangzhou King Techina Feed Company Limited) were prepared as feed supplements at a dose of 300 mg/kg basal diet (based on a preliminary test) and administered to the fish that were pre-fed with either a control or an oxidised SBO diet for 2 weeks, which has previously been reported to induce intestinal stress and mucosal morphology damage in the common carp( Reference Ren, Huo and Zeng 27 , Reference Yao and Ye 29 ). The dissolution rate of MSB along with the reaction time was measured using a dissolution test and HPLC (Fig. 1). Briefly, MSB (1 g) was added into 200 ml water at room temperature, and at the scheduled time durations (15, 30, 45, 60, 90, 120, 150 and 180 min), 20 ml of the sample were withdrawn and immediately replaced with an identical volume of fresh water. Thereafter, the concentration of sodium butyrate in each sample solution was determined. The control diet was prepared for comparison.

Fig. 1 Dissolution rates of the two types of sustained-release microencapsulated sodium butyrate products (1·5 h () and 3·0 h () sustained release).

Fish husbandry

Juvenile common carp were obtained from an aquaculture farm in Foshan City, Guangdong Province, China. Fish were acclimatised to the experimental tanks (60·0 × 60·0 × 80·0 cm) in a recirculating aquaculture system for 2 weeks at Anhui Agricultural University (Hefei City, Anhui Province, China) before the feeding trial.

Experimental design and treatments are described in Table 2. A total of twenty-four tanks of six treatments (C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0) with four replicate tanks per treatment were used. Each tank contained twenty fish of uniform size (6·22 (se 0·03) g). Each treatment was randomly assigned to four tanks. The feeding trial was carried out in two stages. The first stage lasted for 2 weeks during which the fish in the treatments C-0, C-1·5 and C-3·0 were fed the control diet, and those in the treatments Oxi-0, Oxi-1·5 and Oxi-3·0 were fed a diet supplemented with oxidised SBO. From week 3 to 10, the fish in the treatments C-0, C-1·5 and C-3·0 were fed the control, MSB1·5 and MSB3·0 diets, respectively, as were those in the treatments Oxi-0, Oxi-1·5 and Oxi-3·0. The fish were fed to apparent satiation twice per day (09.00 and 15.00 hours), and the feeding rate was approximately 3 % at the beginning of the trial and thereafter adjusted weekly by weighing all fish in one tank per treatment. Water quality parameters including pH (6·6–7·1), dissolved oxygen (>6·05 mg O/l), temperature (25·0 ± 0·8 °C) and nitrate ( < 0·11 mg N/l) were monitored each day.

Table 2 Experimental treatments as well as feeding regimens

MSB, microencapsulated sodium butyrate.

Growth performance, body index, hepatosomatic index and intestinal index of weight

At the end of week 2, all the fish were weighed in batch. Thereafter, at the end of the 10-week feeding trial, all the fish were weighed in batch and fourteen randomly sampled fish from each treatment group were anaesthetised with MS-222 (50·0 mg/l) and measured individually, weighed and dissected, and the intestine and liver were sampled. The intestine was gently agitated three times in PBS (pH 7·2) for 1 min to remove the digesta, and then weighed and separated into the following three segments: foregut (FG); midgut (MG); distal gut (DG). The intestinal segments were divided as described elsewhere( Reference Cai, Wang and Ye 30 ). Survival rate (SR), weight gain (WG), specific growth rate (SGR), feed conversion ratio (FCR), body index (BI), hepatosomatic index (HSI) and intestinal index of weight (WII) were calculated as follows:

$$\begin{eqnarray} SR\,(\%) = (no.\,of\,fish\,counted/no.\,of\,stocked\,fish)\times 100, \end{eqnarray}$$
$$\begin{eqnarray} WG\,(\%) = \frac {final\,weight\,(g) - initial\,weight\,(g)}{initial\,weight\,(g)}\times 100, \end{eqnarray}$$
$$\begin{eqnarray} SGR\, (\%/d) = \frac {ln\,final\,weight\,(g) - ln\,initial\,weight\,(g)}{days}\times 100, \end{eqnarray}$$
$$\begin{eqnarray} FCR = (total\,feed\,consumption\,(total\,feed\,casting - total\,food\,residue)\,(g))/(total\,final\,weight\,(g) - total\,initial\,weight\,(g) + total\,mortality\,weight\,(g))\times 100, \end{eqnarray}$$
$$\begin{eqnarray} BI = (body\,weight\,(g))/(body\,length\,(cm)\times body\,height\,(cm)\times body\,thickness\,(cm)\times 1000), \end{eqnarray}$$
$$\begin{eqnarray} HSI = \frac {hepatopancreas\,weight\,(g)}{body\,weight\,(g)}\times 100, \end{eqnarray}$$
$$\begin{eqnarray} WII = \frac {intestinal\,weight\,(g)}{body\,weight\,(g)}\times 100. \end{eqnarray}$$

The experimental protocol was performed in accordance to the guidelines approved by the Animal Ethics Committee of the Feed Research Institute, Chinese Academy of Agricultural Sciences (2012-ZZG-ZF-001).

Intestinal mucosal morphology

The processing of intestinal segments for scanning electron microscopy was carried out as described elsewhere( Reference Ringø, Salinas and Olsen 31 ). Briefly, one segment of the FG, MG and DG of each sampled fish (n 3 fish per treatment) was fixed with 2·5 % glutaraldehyde. The segments were washed twice in phosphate buffer (pH 7·2) and then post-fixed in OsO4 (1 % in phosphate buffer, pH 7·2, 2 h). After a series of dehydration steps in alcohol from 30 to 100 %, the segments were critical-point dried (CPD030; BAL-TEC), mounted on Al stubs, sputter-coated with gold by using a high-resolution fine coater (SCD005; BAL-TEC), and then examined under a Jeol JSM-6301 scanning microscope (JEOL). The appearance of the intestinal mucosal and microvillus morphology was observed. Scanning electron microscopic images ( × 20 magnification) were analysed to measure the microvillus density on the enterocytes.

Intestinal immune responses

Gene expression of cytokines was assessed from the same intestinal segment from three fish in each treatment group. Total RNA from three segments was extracted using TRIzol reagent (Promega), and RNA quality was analysed by agarose gel (1·2 %) electrophoresis. RNA was dissolved in 50 μl RNase-free water and stored at − 80°C until further use. Complementary DNA was synthesised for quantitative RT-PCR (RT-qPCR) using a ReverTra Ace-α-RT-PCR kit (TOYOBO). qPCR primers were designed using Primer 5.0 software based on cytokine sequences available in the GenBank database (Table 3). Additional dissociation curve analysis was performed and showed a single melting curve in all cases. qPCR was performed with the SYBR Green Premix Ex Taq TMII (TaKaRa) in an iQ5 multicolour real-time PCR detection system (Bio-Rad). The total volume of the PCR was 20 μl and consisted of 10 μl SYBR Green Premix Ex TaqII (2 × ), 1 μl of each primer, 2 μl complementary DNA and 6 μl distilled/deionised water. The cycling conditions were as follows: 95°C for 3 min and then forty cycles of 95°C for 20 s, 55°C for 20 s and 72°C for 20 s. All qPCR experiments were performed three times. Data were analysed using the 2− ΔΔC T method( Reference Livak and Schmittgen 32 ), and β-actin, elongation factor 1a (EF-1a) and 18S( Reference Tang, Yu and Xu 33 ) were amplified as internal standards.

Table 3 Sequences of oligonucleotide primers for quantitative RT-PCR

EF-1a, elongation factor 1a; HSP70, heat shock protein 70; TGF-β, transforming growth factor-β.

Autochthonous gut bacterial communities

Because inter-individual variations in fish gut microbiota have been reported( Reference Spanggaard, Huber and Nielsen 34 , Reference Liu, Zhou and Yao 35 ), the same intestinal segment from the sampled fish in each treatment group was pooled with equal wet weight for the analysis of intestinal adherent bacterial communities. DNA was extracted from the pooled samples according to the methods described by Yu & Morrison( Reference Yu and Morrison 36 ) with some modifications as described by He et al. ( Reference He, Zhou and Liu 37 ). The V3 region of the 16S rRNA gene was amplified with the primers 338-GC-f (5′-CGCCCGCCGCGCGCGGCGGGCGGGGCGGGGGCACGGGGGGACTCCTACGGGAGGCAGCAG-3′) and 519r (5′-ATTACCGCGGCTGCTGG-3′). PCR-denaturing gradient gel electrophoresis was performed according to the method described by Liu et al. ( Reference Liu, Zhou and Yao 35 ) and Zhou et al. ( Reference Zhou, Liu and He 38 ) using the DCode Universal Mutation System (Bio-Rad). Purified PCR products were loaded onto denaturing gradient gels ranging from 40 to 60 % polyacrylamide, and then electrophoresis was conducted at a constant voltage of 60 V for 16 h in 1 ×  Tris–acetate–EDTA buffer (provided by Bio-Rad) at 60°C. The gels were stained with ethidium bromide (0·5 μg/ml in Tris–acetate–EDTA buffer), rinsed in distilled water for 20 min, and viewed with UV transillumination. The appropriate bands were excised, re-amplified, purified (Tiangen) and sequenced. Principal component analysis was performed for the microbial communities based on the denaturing gradient gel electrophoresis (DGGE) fingerprints using SPSS 17.0 (SPSS, Inc.) as described previously( Reference Gremion, Chatzinotas and Kaufmann 39 ). Pairwise similarity coefficient (C s) matrices were analysed based on the DGGE fingerprints using NTSYS 2.10e software (Exeter Software).

Statistical analysis

Data were analysed with SPSS 17.0 (SPSS, Inc.). For each outcome variable, a repeated-measures ANOVA was carried out with pre-fed diet (control and oxidised SBO) and sustained-release time of MSB (0, 1·5 and 3·0) considered as within-subject factors. Polynomial contrasts (linear and quadratic) were calculated separately for the control and oxidised SBO treatments and for the arithmetic means of both treatments at the sustained-release time of MSB. In case of a significant interaction between the pre-fed diets and the sustained-release times of dietary MSB, both the P values of the polynomial contrasts for the control and oxidised SBO treatments are given and the contrasts for the averaged measurements are omitted. If the interaction is not significant, only the polynomial contrasts for the averaged measurements are specified. Data are presented as means with their standard errors. The level of significance was α = 0·05, and 95 % confidence intervals were used.

Results

Growth performance, body index, hepatosomatic index and intestinal index of weight

All the fish survived during the experiment, and no effects of the pre-fed diets on the initial body weight at the end of week 2 were observed (interaction P= 0·610; diet P= 0·794; Table 4).

Table 4 Effects on weight gain (WG, g), specific growth rate (SGR, %/d), feed conversion ratio (FCR), body index (BI, %), hepatosomatic index (HSI, %) and intestinal index of weight (WII, %) in carp at the end of the different experimental treatments (from week 3 to week 10)

MSB, microencapsulated sodium butyrate; SBO, soyabean oil; IBW, initial body weight; FBW, final body weight.

* The interaction term drives the other contrasts as follows: when the interaction is not significant, only the P values for linear and quadratic contrasts for pre-fed treatments (main-effect means averaged over the sustained-release time of MSB) and the P value for the sustained-release time of MSB are given. When the interaction is significant, only the P values for linear and quadratic contrasts for individual pre-fed treatments (control and oxidised SBO) are given.

From week 3 until the end of the feeding period, growth performance parameters including final body weight, WG and SGR were found to be upward trend for the control as well as the oxidised SBO groups. However, the interaction between the different pre-fed diets and sustained-release times of dietary MSB was not found to be significant for the final body weight (P= 0·367), WG (P= 0·367), SGR (P= 0·305) and FCR (P= 0·528), as well as for the BI (P= 0·672), HSI (P= 0·507) and WII (P= 0·353). All these parameters were not affected by the sustained-release times of dietary MSB (P>0·05), and no significant differences were observed between the control and oxidised SBO groups (diet P>0·05).

Despite the fact that there were no statistically significant effects on growth performance when the fish were fed the diets containing different sustained-release times of MSB, it was observed that the MSB1·5 diet increased the WG from 13·4 (95 % CI 4·18, 22·6) to 18·9 (95 % CI 4·52, 33·2) g by 41·0 % when compared with the non-MSB-supplemented diet within the control groups; however, this effect was not observed when supplemented with the MSB3·0 diet. Within the oxidised SBO groups, dietary MSB1·5 increased the WG from 8·96 (95 % CI 4·12, 13·8) to 14·4 (95 % CI 12·9, 15·8) g by 60·7 % when compared with the non-MSB supplement, while the Oxi-3·0 diet increased to 15·2 (95 % CI 6·78, 23·7) g by 69·6 %. Consequently, dietary MSB1·5 reduced the FCR by 16·5, 20·3 and 22·5 % within the control, Oxi-1·5 and Oxi-3·0 groups, respectively. These results showed that dietary MSB1·5 had the potential for improving growth performance within the control groups. In addition, the supplementation of both dietary MSB1·5 and MSB3·0 was beneficial within the oxidised SBO groups.

Intestinal mucosal morphology

There were no differences observed in the epithelial mucosa of the FG in the C-0, C-1·5 and C-3·0 groups, with all showing a normal appearance (Fig. 2(a)–(c)). However, at a higher magnification, damaged epithelial cell surface and disintegrated microvilli were observed in fish pre-fed with oxidised SBO in the Oxi-0 group (Fig. 2(d)). In the Oxi-1·5 and Oxi-3·0 groups, the fish fed the MSB supplements showed normal intestinal epithelial morphology, indicating that both dietary MSB1·5 and MSB3·0 treatments prevented or repaired intestinal damage caused by pre-fed oxidised SBO (Fig. 2(e) and (f)). Similar results were observed in the MG and DG (Figs. 3 and 4, respectively).

Fig. 2 Scanning electron microscopy of histological changes in the foregut of the carp at the end of the different experimental treatments: (a) C-0, (b) C-1·5, (c) C-3·0, (d) Oxi-0, (e) Oxi-1·5 and (f) Oxi-3·0. MV, microvilli; MD, mechanical damage; ED, experimental damage; DC, dead/dying cell. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

Fig. 3 Scanning electron microscopy of histological changes in the midgut of the carp at the end of the different experimental treatments: (a) C-0, (b) C-1·5, (c) C-3·0, (d) Oxi-0, (e) Oxi-1·5 and (f) Oxi-3·0. MV, microvilli; ED, experimental damage; DC, dead/dying cell. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

Fig. 4 Scanning electron microscopy of histological changes in the distal gut of the carp at the end of the different experimental treatments: (a) C-0, (b) C-1·5, (c) C-3·0, (d) Oxi-0, (e) Oxi-1·5 and (f) Oxi-3·0. MV, microvilli; ED, experimental damage; DC, dead/dying cell. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

The interaction between the different pre-fed diets and the sustained-release times of dietary MSB was found to be significant for microvillus density (P< 0·001) in the FG (Table 5). The dependence of microvillus density on the sustained-release times of dietary MSB differed between the control and oxidised SBO groups. In the control groups, no significant effects were observed (P= 0·551 and P= 0·215 for the linear and quadratic contrasts, respectively), whereas in the oxidised SBO groups, an increase in microvillus density was observed in the FG (P= 0·006 and P= 0·001 for the linear and quadratic contrasts, respectively).

Table 5 Effects on the density of intestinal microvilli of carp at the end of the different experimental treatments

MSB, microencapsulated sodium butyrate; SBO, soyabean oil; FG, foregut; MG, midgut; DG, distal gut.

* The interaction term drives the other contrasts as follows: when the interaction is not significant, only the P values for linear and quadratic contrasts for pre-fed treatments (main-effect means averaged over the sustained-release time of MSB) and the P value for the sustained-release time of MSB are given. When the interaction is significant, only the P values for linear and quadratic contrasts for individual pre-fed treatments (control and oxidised SBO) are given.

The analysis of microvillus density revealed that there were no significant differences between the different pre-fed diets and the sustained-release times of dietary MSB in the MG (P= 0·423) as well as in the DG (P= 0·242). Although no significant effects were observed during the sustained-release times of dietary MSB (h of MSB: P= 0·314 and P= 0·325 for the linear and quadratic contrasts, respectively), microvillus density was significantly higher in the MG of the control groups than that of the oxidised SBO groups (diet P< 0·001). In the DG, a significant effect was observed during the sustained-release times of dietary MSB (P= 0·003 for the quadratic contrast), but there was no difference observed between the control and oxidised SBO groups. Moreover, the interaction was observed to be significant for microvillus density between the treatments and the gut sites (P< 0·001).

Intestinal immune responses

The expression stability of each internal standard gene in different RNA samples was evaluated by C T values. The C T values of the β-actin, EF-1a and 18S genes were found to be 24·6 (se 0·47), 28·6 (se 1·0) and 20·1 (se 0·83), respectively. Based on these results, we chose the widely used gene β-actin as the internal standard and the C T value of the FG of the C-0 group as the control to calculate the expression levels of the target genes. The effects on the expression levels of intestinal HSP70, IL-1β, TGF-β and TNF-α are shown in Table 6.

Table 6 Effects on the relative expression levels of intestinal heat shock protein (HSP)-70 and cytokines in carp at the end of the different experimental treatments

MSB, microencapsulated sodium butyrate; SBO, soyabean; FG, foregut; MG, midgut; DG, distal gut; TGF-β, transforming growth factor-β.

* The interaction term drives the other contrasts as follows: when the interaction is not significant, only the P values for linear and quadratic contrasts for pre-fed treatments (main-effect means averaged over the sustained-release time of MSB) and the P value for the sustained-release time of MSB are given. When the interaction is significant, only the P values for linear and quadratic contrasts for individual pre-fed treatments (control and oxidised SBO) are given.

The interaction between the different pre-fed diets and the sustained-release times of dietary MSB was found to be significant for the expression levels of HSP70 in the FG (P= 0·010), and the expression levels of HSP70 were dependent on the sustained-release times of dietary MSB in both the control and oxidised SBO groups (P< 0·05). Expression levels of HSP70 were V-shaped in the oxidised SBO groups, with the Oxi-1·5 group being close to the C-0 group. Meanwhile, a significant interaction between the different pre-fed diets and the sustained-release times of dietary MSB for the expression levels of HSP70 in the MG (P< 0·001) was observed, but the dependence was only observed in the control group. There was no interaction observed between the different pre-fed diets and the sustained-release times of dietary MSB for the expression levels of HSP70 in the DG (P= 0,106); however, significant effects were observed between the sustained-release times of dietary MSB and the pre-fed diets (linear contrast: P= 0·018 and salt: P= 0·018). Moreover, the interaction between the treatments and the different gut segments was found to be significant for the expression levels of HSP70 (P< 0·001).

There was no interaction observed between the different pre-fed diets and the sustained-release times of dietary MSB for the expression levels of IL-1β in the FG (P= 0·066). However, expression levels of IL-1β were affected by the sustained-release times of dietary MSB (linear contrast: P= 0·001; quadratic contrast: P< 0·001) but not by the pre-fed diets (P= 0·289). Expression levels of IL-1β were found to be V-shaped during the sustained-release time of dietary MSB, and the dietary MSB1·5 group showed a minimum value. The interaction between the different pre-fed diets and the sustained-release times of dietary MSB was found to be significant for the expression levels of IL-1β in the MG and DG (P= 0·030 and P< 0·001, respectively). The dependence was only present in the oxidised SBO group in the MG (linear contrast: P= 0·046) while both present in the control (quadratic contrast: P= 0·010) and oxidised SBO (quadratic contrast: P= 0·001) groups in the MG. In addition, expression levels of IL-1β were V shaped in both the MG and DG of the oxidised SBO groups, with the Oxi-1·5 group having a minimum value. Moreover, the interaction between the treatments and the gut segments was significant for the expression levels of IL-1β (P< 0·001).

The interaction between the different pre-fed diets and the sustained-release times of dietary MSB was found to be significant for the expression levels of TGF-β in the FG (P< 0·010), and expression levels of TGF-β were dependent on the sustained-release times of dietary MSB in both the control and oxidised SBO groups (P< 0·05). Meanwhile, the interaction between the different pre-fed diets and the sustained-release times of dietary MSB was found to be significant for the expression levels of TGF-β in the MG and DG (P= 0·009 and P= 0·011, respectively), and the dependence on the sustained-release times of dietary MSB was observed only in the MG and DG of the control group (P< 0·05). Moreover, the interaction between the treatments and the gut sites was significant for the expression levels of TGF-β (P< 0·001).

Expression levels of TNF-α were dependent on the sustained-release times of dietary MSB only in the FG of the oxidised SBO group (interaction: P= 0·002). A sharp significant interaction between the different pre-fed diets and the sustained-release times of dietary MSB for the expression levels of TNF-α were observed in the MG and DG (P< 0·001), and expression levels of TNF-α were dependent on the sustained-release times of dietary MSB in both the control and oxidised SBO groups (P< 0·05). Expression levels of TNF-α were found to be lower in the Oxi-1·5 and Oxi-3·0 groups than in the Oxi-0 group. Moreover, the interaction between the treatments and the gut sites was found to be significant for the expression levels of TNF-α (P< 0·001).

Autochthonous gut bacterial communities

Adherent gut bacterial communities in fish fed the different treatments and principal component analysis of the band patterns are shown in Fig. 5(a) and (b), respectively. Representatives of the adherent bacterial communities identified are listed in Table 7. The principal component analysis score plot revealed that principal component 1 accounts for 53·5 % of the total variation and principal component 2 accounts for 29·5 %. It is notable that the samples of the FG and DG were distributed separately. The predominant autochthonous bacterial species (approximately 89·7 %) were members of the Proteobacteria, with Acinetobacter being the most dominant OTU (operational taxonomic units) with five bands (1, 4, 7, 8 and 10). Aeromonas sp. (band 2) was one of the most predominant adherent bacterial species in the intestine of the common carp. In addition, the relative abundance of an unidentified anaerobic bacterium (band 14) was higher in the MG of the Oxi-0 group (Oxi0M) and in the DG of the Oxi-1·5 group (Oxi1·5D) and the Oxi-3·0 group (Oxi3·0D). Pairwise similarity coefficient (C s) matrices of the adhesive gut bacterial communities are shown in Table 8. The C s value showed that the three intestinal segments differed, ranging from 0·64 to 1·00. However, the influence of dietary MSB on gut bacterial communities in each region appeared to be less significant: the lowest C s value was 0·79, which was observed between the C0M or C1·5M and C3·0M, Oxi0M, Oxi1·5M or Oxi3·0M regions.

Fig. 5 Denaturing gradient gel electrophoresis fingerprints (a) and principal component (PC) analysis of the 16S rDNA V3 region (b) of the adhesive gut bacterial communities in carp at the end of the different experimental treatments: C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0. F, foregut; M, midgut; D, distal gut. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

Table 7 Representatives of intestinal adhesive bacterial communities and their relative abundance (%) obtained from the BLAST (Basic Local Alignment Search Tool) search in denaturing gradient gel electrophoresis fingerprints

F, foregut; M, midgut; D, distal gut.

Table 8 Pairwise similarity coefficient matrix for the intestinal adhesive bacterial communities of carp at the end of the different experimental treatments

F, foregut; M, midgut; D, distal gut.

Discussion

Inclusion of organic acids in feed can positively affect the production of the host animal( Reference Lückstädt 40 ). Ringø( Reference Ringø 13 ) and Ringø et al. ( Reference Ringø, Olsen and Castell 15 ) reported that supplementation of 1 g/kg of lactate to the diet of Arctic charr (Salvelinus alpinus L.) increases growth and feed efficiency. In a more recent study, Liebert et al. ( Reference Liebert, Mohamed and Lückstädt 41 ) observed that when tilapia (Oreochromis niloticus) fingerlings were fed 0·3 g/kg of sodium diformate, the protein efficiency ratio and protein retention were significantly improved. However, hybrid tilapia (O. niloticus female × O. aureus male) fed diets supplemented with five levels (0, 3, 6, 9 and 12 g/kg) of potassium diformate showed no significant effect on growth and the FCR( Reference Zhou, Liu and He 38 ). Furthermore, digestibility of proteins, lipids and amino acids increased when rainbow trout (Oncorhynchus mykiss Walbaum) were fed a diet supplemented with 1 % sodium diformate( Reference Morken, Kraugerud and Barrowsb 20 ). However, information on the use of butyric acid and butyrate in aquaculture is scarce. In a study with Atlantic salmon (S. salar L.), Bjerkeng et al. ( Reference Bjerkeng, Storebakken and Wathne 42 ) did not observe significant effects of a mixture of SCFA (Na salts of acetic, propionic and butyric acids (5:5:2, by weight), 0·5 and 2 g/kg) on growth, organ indices including the HSI and WII, feed utilisation and apparent digestibility coefficients. Owen et al. ( Reference Owen, Waines and Bradley 43 ) tested 0·2 g/kg of sodium butyrate as a feed additive for African catfish (C. gariepinus) in two diets differing only in their major protein sources; fishmeal v. full-fat soya. The SGR and FCR in each treatment showed non-significant differences compared with the control. In a recent study, Gao et al. ( Reference Gao, Storebakken and Shearer 18 ) reported that supplementing diets with 10 g acid moiety/kg of a sodium formate and butyrate blend (ratio 2:1 on the acid-moiety weight basis) did not improve the growth rate or feed utilisation of rainbow trout. In the present study, the effect of diets containing different sustained-release times of MSB on the growth performance of the common carp was not statistically improved, although some improved effects were observed. In the control group, the effect of the MSB1·5 diet seemed to be better than that of the MSB3·0 diet on growth performance, which is consistent with our hypothesis, but in the oxidised SBO groups both the MSB diets improved the growth performance of the carp. The different results of growth performance observed when the fish were fed the butyric acid and butyrate additives may be related to the dosage form used. Sodium butyrate as a fat-soluble substance could be quickly absorbed and utilised as an energy source by enteric epithelial cells( Reference Roediger 44 ). The results in the present study might be due to the use of microencapsulated dosage form of sodium butyrate and the sustained release along the intestine of the common carp. Similar to the study of Bjerkeng et al. ( Reference Bjerkeng, Storebakken and Wathne 42 ), in the present study, sodium butyrate did not affect the organ indices.

In a study by Biagi et al. ( Reference Biagi, Piva and Moschini 45 ), it was shown that intestinal mucosal morphology was not affected when weanling pigs were fed sodium butyrate at the dose levels of 1, 2 or 4 g/kg for 6 weeks, but oral butyrate supplementation at the dose level of 3 g/kg for 6 weeks reduced intestinal mucosal weight in pigs( Reference Gall, Gallois and Seve 46 ). In rainbow trout, the presence of an organic acid salt blend (10 g acid moiety/kg of a sodium formate and butyrate blend, ratio 2:1) in diets did not significantly alter the mucosal folds of the distal intestine( Reference Gao, Storebakken and Shearer 18 ). Similarly, the present study showed that the intestinal mucosal morphology of the C-0, C-1·5 and C-3·0 groups was not generally affected, although some differences were observed in microvillus height. We put forward the hypothesis that the ability of sodium butyrate to provide energy for epithelial growth may not be essential when the intestine of the host is ‘normal’. Therefore, the observation of the Oxi-0, Oxi-1·5 and Oxi-3·0 treatments to detect the effects of oral sodium butyrate when the fish were pre-fed with oxidised SBO supplement was negligible. Oxidised oil containing primary and secondary oxidation products reduces production performance, damages intestinal mucosa, and influences the activity of anti-oxidases and co-enzymes in aquaculture animals( Reference Hamre, Kolas and Sandnes 8 , Reference Agerbo, Jørgensen and Jensen 47 , Reference Huang and Huang 48 ). In the present study, even after returning to the basal diet for 8 weeks, seriously damaged intestinal mucosa and decreased density of intestinal microvilli were observed in the Oxi-0 group at week 10. An interesting observation was that supplementation of both dietary MSB1·5 and MSB3·0 seemed to prevent or repair intestinal mucosal damage and increase the density of microvilli to the normal level. As the actual mechanisms have not been elucidated, the topic merits further investigation. The density of microvilli is related to nutrient absorptivity( Reference Buret, O'Laughlin and Curtis 49 , Reference Ryan, Miller and Seydel 50 ). In the present study, intestinal mucosal morphology and microvillus morphology data are consistent with the results of growth performance. To our knowledge, the present study is the first to report on the use of sodium butyrate as a dietary supplement to prevent or repair intestinal mucosal damage caused by oxidised oil.

Anuta et al. ( Reference Anuta, Buentello and Patnaik 19 ) reported that Pacific white shrimp (Litopenaeus vannamei) fed acidic calcium sulphate as 1·2 and 2·0 % of diet showed significantly reduced stress and enhanced immune responses including haemocyte phagocytic capacity, haemolymph protein concentration, hyaline cell counts and haemolymph glucose levels. To our knowledge, there have been no reports regarding the ability of sodium butyrate to stimulate the immune response of cytokine genes in the intestine as detected with qPCR in aquaculture research. In a piglet trial, the examined genes (cyclophilin A, IL-1β, IL-18 and TNF-α) showed no significant difference in the proximal and distal segments of the intestine as a result of feeding sodium butyrate at dose levels of 1, 2 or 4 g/kg for 6 weeks( Reference Biagi, Piva and Moschini 45 ). In this context, the interaction between the different pre-fed diets and the sustained-release times of dietary MSB was found to be significant for the relative gene expression levels of gut HSP70, pro-inflammatory cytokines (IL-1β and TNF-α) and anti-inflammatory cytokines (TGF-β), as well as between the treatments and the gut segments. Generally, within the oxidised SBO groups, the expression levels of these genes were found to be lower in the Oxi-1·5 group but significantly higher in the Oxi-3·0 group, and thus we suggested that the MSB1·5 diet appeared to induce less stress. The reason for the different stress and immunity responses caused by the two types of MSB products can most probably be attributed to the coated material and the releasing time. The difference between the gut segments might be ascribed to the gut morphology, but the exact mechanism should be further studied.

Hybrid tilapia (O. niloticus female × O. aureus male) fed diets supplemented with five levels (0, 3, 6, 9 and 12 g/kg) of potassium diformate have been reported to show different effects on the gut microbiota( Reference Zhou, Liu and He 38 ). In a study with red hybrid tilapia (Oreochromis sp.), Ng et al. ( Reference Ng, Koh and Sudesh 51 ) fed the fish with diets supplemented with a blend consisting of six organic acids and showed that the total bacteria and adherent gut bacteria per g faeces were significantly reduced. De Schryver et al. ( Reference De Schryver, Sinha and Kunwar 52 ) reported that diets supplemented with 2–10 % poly-β-hydroxy butyrate modulated the intestinal microbiota of European sea bass (Dicentrarchus labrax). Pacific white shrimp fed diets containing 0·4–2 % acid in the form of calcium sulphate also showed changes in the gut microbiota compared with those fed a basal diet with a similarity coefficient of 64·9 %( Reference Anuta, Buentello and Patnaik 19 ). Sodium butyrate supplementation appears to increase the proportion of Gram-positive bacteria in the hindgut of African catfish (C. gariepinus), although the increase was not statistically significant( Reference Owen, Waines and Bradley 43 ). Similarly, it has been reported in mammals that bacterial counts in the jejunum, ileum and caecum of piglets are not affected by feeding sodium butyrate for 6 weeks( Reference Biagi, Piva and Moschini 45 ). In the present study, within each gut region, the effects of sodium butyrate on the gut microbiota were slight (C s>0·79). Sodium butyrate may not have significantly affected the microbial communities because butyrate is a metabolite produced by butyrate-producing bacteria( Reference Cummings and Macfarlane 53 ). The slight differences in the microbial communities may have been caused by the changes in intestinal mucosal morphology and immune responses.

In conclusion, the data revealed that oral supplementation of dietary MSB1·5 or MSB3·0 can stimulate immune responses and improve the intestinal condition of the common carp. Particularly, the function of improving the intestinal condition was more outstanding when the fish were pre-fed with oxidised oil.

Acknowledgements

The authors are indebted to Chunli Li for providing the scanning electron microscopic photographs. The authors are grateful to Yang Deng for his excellent technical assistance.

The present study was supported by the National Natural Science Foundation of China (31272672), the National Science and Technology Support Program Project of China (2012BAD25B02) and the Beijing Earmarked Fund for Modern Agro-industry Technology Research System (SCGWZJ 20121104-4).

W. L. performed the DGGE, qPCR and scanning electron microscopy and wrote a draft of the manuscript. Y. Y. and J. Z. managed the feeding trial and chemical position analysis. D. M. G. and Z. Z. designed and guided the experimental performance and helped in the writing of the manuscript. E. R. improved the manuscript by critical comments and suggestions.

There are no conflicts of interest.

References

1 Khachatourians, GG (1998) Agricultural use of antibiotics and the evolution and transfer of antibiotic-resistant bacteria. CMAJ 159, 11291136.Google ScholarPubMed
2 Cassone, M & Giordano, A (2009) Resistance genes traveling the microbial internet: down the drain, up the food chain? Expert Rev Anti Infect Ther 7, 637639.Google Scholar
3 Cabello, FC, Godfrey, HP, Tomova, A, et al. (2013) Antimicrobial use in aquaculture re-examined: its relevance to antimicrobial resistance and to animal and human health. Environ Microbial 15, 19171942.CrossRefGoogle ScholarPubMed
4 Cortesi, R & Privett, OS (1972) Toxicity of fatty ozonides and peroxides. Lipids 7, 715721.Google Scholar
5 Koshio, S, Ackman, G & Lall, SP (1994) Effects of oxidised herring and canola oils in diets on growth, survival, and flavor of Atlantic salmon Salmo salar . J Agr Food Chem 42, 11641169.CrossRefGoogle Scholar
6 Baker, RTM (1997) The effects of dietary α-tocopherol and oxidised lipid on post-thaw drip from catfish muscle. Anim Feed Sci Tech 65, 3543.CrossRefGoogle Scholar
7 Baker, RTM & Davies, SJ (1997) Modulation of tissue α-tocopherol in African catfish, Clarias gariepinus (Burchell), fed oxidised oils, and the compensatory effect of supplemental dietary vitamin E. Aquaculture 3, 9197.Google Scholar
8 Hamre, K, Kolas, K, Sandnes, K, et al. (2001) Feed intake and absorption of lipid oxidation products in Atlantic salmon (Salmo salar) fed diets coated with oxidised fish oil. Fish Physiol Biochem 25, 209219.CrossRefGoogle Scholar
9 Zhang, Y, Lall, SP & Shahidi, F (2007) Effects of oxidised dietary oil and vitamin E supplementation on lipid profile and oxidation of muscle and liver of juvenile Atlantic cod (Gadus morhua). J Agr Food Chem 55, 63796386.Google Scholar
10 Gao, J, Koshio, S, Ishikawa, M, et al. (2012) Effects of dietary palm oil supplements with oxidised and non-oxidised fish oil on growth performances and fatty acid compositions of juvenile Japanese sea bass, Lateolabrax japonicas . Aquaculture 324–325, 97103.Google Scholar
11 Zhang, Y, Yang, L, Zu, YG, et al. (2010) Oxidative stability of sunflower oil supplemented with carnosic acid compared with synthetic antioxidants during accelerated storage. Food Chem 118, 656662.Google Scholar
12 Jones, DL (1998) Organic acids in the rhizosphere: a critical review. Plant Soil 205, 2544.Google Scholar
13 Ringø, E (1991) Effects of dietary lactate and propionate on growth and digesta in Arctic charr, Salvelinus alpinus (L.). Aquaculture 96, 321333.CrossRefGoogle Scholar
14 Ringø, E (1992) Effects of dietary formate and acetate on growth and lipid digestibility in Arctic charr, Salvelinus alpinus (L.). Fisk Dir Skr Ser Ernæring 5, 1724.Google Scholar
15 Ringø, E, Olsen, RE & Castell, JD (1994) Effect of dietary lactate on growth and chemical composition of Arctic charr Salvelinus alpinus . J World Aquac Soc 25, 483486.Google Scholar
16 Gislason, G, Olsen, RE & Ringø, E (1996) Comparative effects of dietary Na+-lactate on Arctic char, Salvelinus alpinus L., and Atlantic salmon, Salmo salar L. Aquac Res 27, 429435.Google Scholar
17 Zhou, ZG, He, SX, Liu, YC, et al. (2009) The effects of dietary yeast culture or short-chain fructo-oligosaccharides on the intestinal autochthonous bacterial communities in juvenile hybrid tilapia, Oreochromis niloticus♀ × Oreochromis aureus. J World Aquacult Soc 40, 450459.CrossRefGoogle Scholar
18 Gao, YL, Storebakken, T, Shearer, KD, et al. (2011) Supplementation of fishmeal and plant protein-based diets for rainbow trout with a mixture of sodium formate and butyrate. Aquaculture 311, 233240.Google Scholar
19 Anuta, DJ, Buentello, A, Patnaik, S, et al. (2011) Effect of dietary supplementation of acidic calcium sulfate (Vitoxal) on growth, survival, immune response and gut microbiota of the Pacific white shrimp, Litopenaeus vannamei . J World Aquacult Soc 42, 834844.Google Scholar
20 Morken, T, Kraugerud, OF, Barrowsb, FT, et al. (2011) Sodium diformate and extrusion temperature affect nutrient digestibility and physical quality of diets with fish meal and barley protein concentrate for rainbow trout (Oncorhynchus mykiss). Aquaculture 317, 138145.Google Scholar
21 Topping, DL & Clifon, PM (2001) Short chain fatty acids and human colonic function: roles of resistant starch and non-starch polysaccharides. Physiol Rev 81, 10311064.CrossRefGoogle Scholar
22 Hamer, HM, Jonkers, D, Venema, K, et al. (2008) Review Article: the role of butyrate on colonic function. Aliment Pharmacol Ther 27, 104119.Google Scholar
23 Hertrampf, JW & Piedad-Pascual, F (2000) Handbook on Ingredients for Aquaculture Feeds, 624 pp. Dordrecht, the Netherlands: Kluwer Academic Publishers.CrossRefGoogle Scholar
24 Rollo, A, Sulpizio, R, Nardi, M, et al. (2006) Live microbial feed supplement in aquaculture for improvement of stress tolerance. Fish Physiol Biochem 32, 167177.Google Scholar
25 Scheiermann, P, Ott, J, Hoegl, S, et al. (2011) Effects of short-term infusion of lipid emulsions on pro-inflammatory cytokines and lymphocyte apoptosis in septic and non-septic rats. Br J Nutr 106, 2732.CrossRefGoogle ScholarPubMed
26 Liu, WS, Ren, PF, He, SX, et al. (2013) Comparison of adhesive gut bacteria, immunity, and disease resistance in juvenile hybrid tilapia fed different Lactobacillus strains. Fish Shellfish Immun 35, 5462.Google Scholar
27 Ren, ZL, Huo, QG, Zeng, H, et al. (2001) Effect of oxidised fish oil on the performance and muscular histological structure of carps. Acta Zoonutrimenta Sinica 13, 5964 (in Chinese).Google Scholar
28 Association of Official Analytical Chemists (1984) Official Methods of Analysis of the Association of Official. Analytical Chemists , 14th ed., 1141 pp. Arlington, VA: Association of Official Analytical Chemists.Google Scholar
29 Yao, SB & Ye, YT (2012) Damage effects of oxidised soybean oil on primary cultured intestinal epithelial cells from Ctenopharyngodon idellus and its protection. MSc Thesis, Suzhou University..Google Scholar
30 Cai, CF, Wang, WJ, Ye, YT, et al. (2012) Effect of soybean meal, raffinose and stachyose on the growth, body composition, intestinal morphology and intestinal microflora of juvenile allogynogenetic silver crucian carp (Carassius auratus). Aquac Res 43, 128138.Google Scholar
31 Ringø, E, Salinas, I, Olsen, RE, et al. (2007) Histological changes in Atlantic salmon (Salmo salar L.) intestine following in vitro exposure to pathogenic and probiotic bacterial strains. Cell Tissue Res 328, 109116.Google Scholar
32 Livak, KJ & Schmittgen, TD (2001) Analysis of relative gene expression data using real-time quantitative PCR and the 2− ΔΔCT method. Methods 25, 402408.Google Scholar
33 Tang, YK, Yu, JH, Xu, P, et al. (2012) Identification of housekeeping genes suitable for gene expression analysis in Jian carp (Cyprinus carpio var. jian). Fish Shellfish Immunol 33, 775779.Google Scholar
34 Spanggaard, B, Huber, I, Nielsen, J, et al. (2000) The microflora of rainbow trout intestine: a comparison of traditional and molecular identification. Aquaculture 182, 115.Google Scholar
35 Liu, Y, Zhou, Z, Yao, B, et al. (2008) The effect of intraperitoneal injection of immune stimulatory substances on allochthonous gut microbiota of Atlantic salmon (Salmo salar L.) determined using denaturing gradient gel electrophoresis. Aquac Res 39, 635646.Google Scholar
36 Yu, Z & Morrison, M (2004) Improved extraction of PCR-quality community DNA from digesta and fecal samples. Biotechniques 36, 808812.CrossRefGoogle ScholarPubMed
37 He, S, Zhou, Z, Liu, Y, et al. (2009) Effects dietary yeast culture (DVAQUA) on growth performance, intestinal autochthonous bacterial community and non-specific immunity of hybrid tilapia (Oreochromis niloticus♀ × O. aureus♂) cultured in cages. Aquaculture 294, 99107.CrossRefGoogle Scholar
38 Zhou, Z, Liu, Y, He, S, et al. (2009) Effects of dietary potassium diformate (KDF) on growth performance, feed conversion and intestinal bacterial community of hybrid tilapia (Oreochromis niloticus♀ × O. aureus♂). Aquaculture 291, 8994.CrossRefGoogle Scholar
39 Gremion, F, Chatzinotas, A, Kaufmann, K, et al. (2004) Impacts of heavy metal contamination and phytoremediation on a microbial community during a twelve-month microcosm experiment. FEMS Microbiol Ecol 48, 273283.Google Scholar
40 Lückstädt, C (2008) The use of acidifiers in fish nutrition. CAB reviews: perspectives in agriculture, veterinary science. Nutr Nat Resour 3, 18.Google Scholar
41 Liebert, F, Mohamed, K & Lückstädt, C (2010) Effects of diformates on growth and feed utilization of all male Nile tilapia fingerlings (Oreochromis niloticus) reared in tank culture. XIV International Symposium on Fish Nutrition and Feeding, Qingdao, China, Book of Abstracts, 190 pp..Google Scholar
42 Bjerkeng, B, Storebakken, T & Wathne, E (1999) Cholesterol and short-chain fatty acids in diets for Atlantic salmon Salmo salar (L.): effects on growth, organ indices, macronutrient digestibility, and fatty acid composition. Aquac Nutr 5, 181191.Google Scholar
43 Owen, MAG, Waines, P & Bradley, G, et al. (2006) The effect of dietary supplementation of sodium butyrate on the growth and microflora of Clarias gariepinus (Burchell 1822). Abstract from the XIV International Symposium on Fish Nutrition and Feeding, May 28–June 1, Biarritz, France..Google Scholar
44 Roediger, WE (1980) The colonic epithelium in ulcerative colitis: an energy-deficiency disease? Lancet 316, 712715.Google Scholar
45 Biagi, G, Piva, A, Moschini, M, et al. (2007) Performance, intestinal microflora, and wall morphology of weanling pigs fed sodium butyrate. J Anim Sci 85, 11841191.CrossRefGoogle ScholarPubMed
46 Gall, ML, Gallois, M, Seve, B, et al. (2009) Comparative effect of orally administered sodium butyrate before or after weaning on growth and several indices of gastrointestinal biology of piglets. Br J Nutr 102, 12851296.CrossRefGoogle ScholarPubMed
47 Agerbo, P, Jørgensen, BM, Jensen, B, et al. (1992) Enzyme inhibition by secondary lipid autoxidation products from fish oil. J Nutr Biochem 3, 549553.Google Scholar
48 Huang, CH & Huang, SL (2004) Effect of dietary vitamin E on growth, tissue lipid peroxidation, and liver glutathione level of juvenile hybrid tilapia, Oreochromis niloticus× O. aureus, fed oxidised oil. Aquaculture 237, 381389.Google Scholar
49 Buret, A, O'Laughlin, EV, Curtis, GH, et al. (1990) Effect of acute Yersinia enterocolitica infection on small intestinal ultrastructure. Gastroenterology 98, 14011407.CrossRefGoogle ScholarPubMed
50 Ryan, CK, Miller, JH, Seydel, AS, et al. (1997) Epidermal growth factor and neurotensin induce microvillus hypertrophy following massive enterectomy. J Gastrointest Surg 1, 467473.Google Scholar
51 Ng, WK, Koh, CB, Sudesh, K, et al. (2009) Effects of dietary organic acids on growth, nutrient digestibility and gut microflora of red hybrid tilapia, Oreochromis sp., and subsequent survival during a challenge test with Streptococcus agalactiae . Aquac Res 40, 14901500.CrossRefGoogle Scholar
52 De Schryver, P, Sinha, AK, Kunwar, PS, et al. (2010) Poly-β-hydroxybutyrate (PHB) increases growth performance and intestinal bacterial range-weighted richness in juvenile European sea bass, Dicentrarchus labrax . Appl Microbiol Biotechnol 86, 15351541.CrossRefGoogle ScholarPubMed
53 Cummings, JH & Macfarlane, GT (1991) The control and consequences of bacterial fermentation in the human colon. J Appl Bacteriol 70, 443459.Google Scholar
Figure 0

Table 1 Formulation and chemical compositions of the basal and experimental diets (%)*

Figure 1

Fig. 1 Dissolution rates of the two types of sustained-release microencapsulated sodium butyrate products (1·5 h () and 3·0 h () sustained release).

Figure 2

Table 2 Experimental treatments as well as feeding regimens

Figure 3

Table 3 Sequences of oligonucleotide primers for quantitative RT-PCR

Figure 4

Table 4 Effects on weight gain (WG, g), specific growth rate (SGR, %/d), feed conversion ratio (FCR), body index (BI, %), hepatosomatic index (HSI, %) and intestinal index of weight (WII, %) in carp at the end of the different experimental treatments (from week 3 to week 10)

Figure 5

Fig. 2 Scanning electron microscopy of histological changes in the foregut of the carp at the end of the different experimental treatments: (a) C-0, (b) C-1·5, (c) C-3·0, (d) Oxi-0, (e) Oxi-1·5 and (f) Oxi-3·0. MV, microvilli; MD, mechanical damage; ED, experimental damage; DC, dead/dying cell. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

Figure 6

Fig. 3 Scanning electron microscopy of histological changes in the midgut of the carp at the end of the different experimental treatments: (a) C-0, (b) C-1·5, (c) C-3·0, (d) Oxi-0, (e) Oxi-1·5 and (f) Oxi-3·0. MV, microvilli; ED, experimental damage; DC, dead/dying cell. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

Figure 7

Fig. 4 Scanning electron microscopy of histological changes in the distal gut of the carp at the end of the different experimental treatments: (a) C-0, (b) C-1·5, (c) C-3·0, (d) Oxi-0, (e) Oxi-1·5 and (f) Oxi-3·0. MV, microvilli; ED, experimental damage; DC, dead/dying cell. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

Figure 8

Table 5 Effects on the density of intestinal microvilli of carp at the end of the different experimental treatments

Figure 9

Table 6 Effects on the relative expression levels of intestinal heat shock protein (HSP)-70 and cytokines in carp at the end of the different experimental treatments

Figure 10

Fig. 5 Denaturing gradient gel electrophoresis fingerprints (a) and principal component (PC) analysis of the 16S rDNA V3 region (b) of the adhesive gut bacterial communities in carp at the end of the different experimental treatments: C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0. F, foregut; M, midgut; D, distal gut. See Table 2 for details of the treatments C-0, C-1·5, C-3·0, Oxi-0, Oxi-1·5 and Oxi-3·0.

Figure 11

Table 7 Representatives of intestinal adhesive bacterial communities and their relative abundance (%) obtained from the BLAST (Basic Local Alignment Search Tool) search in denaturing gradient gel electrophoresis fingerprints

Figure 12

Table 8 Pairwise similarity coefficient matrix for the intestinal adhesive bacterial communities of carp at the end of the different experimental treatments