Abstract
This study investigated the effects of fermented cottonseed meal (FCSM) on lipid metabolites, lipid metabolism-related gene expression in liver tissues and abdominal adipose tissues, and hepatic metabolomic profiling in broiler chickens. One hundred and eighty 21-d-old broiler chickens were randomly divided into three diet groups with six replicates of 10 birds in each group. The three diets consisted of a control diet supplemented with unfermented cottonseed meal, an experimental diet of cottonseed meal fermented by Candida tropicalis, and a second experimental diet of cottonseed meal fermented by C. tropicalis plus Saccharomyces cerevisae. The results showed that FCSM intake significantly decreased the levels of abdominal fat and hepatic triglycerides (P<0.05 for both). Dietary FCSM supplementation down-regulated the mRNA expression of fatty acid synthase and acetyl CoA carboxylase in liver tissues and the lipoprotein lipase expression in abdominal fat tissues (P<0.05 for both). FCSM intake resulted in significant metabolic changes of multiple pathways in the liver involving the tricarboxylic acid cycle, synthesis of fatty acids, and the metabolism of glycerolipid and amino acids. These findings indicated that FCSM regulated lipid metabolism by increasing or decreasing the expression of the lipid-related gene and by altering multiple endogenousmetabolites. Lipid metabolism regulation is a complex process, this discovery provided new essential information about the effects of FCSM diets in broiler chickens and demonstrated the great potential of nutrimetabolomics in researching complex nutrients added to animal diets.
概要
目的
旨在研究发酵棉粕对肉鸡脂类代谢的影响。
创新点
将荧光定量聚合酶链反应PCR和代谢组学方法相结合, 就采食发酵饲料 (发酵棉粕) 肉鸡的组织脂类代谢相关基因及肝脏代谢谱进行分析, 发现发酵棉粕具有调控肉鸡脂类代谢的作用。该研究为研究日粮中复杂营养素对动物机体代谢的调控提供了新思路。
方法
将180 只21 日龄肉鸡随机分为三组, 每组6 个重复, 每个重复10 只鸡。对照组饲喂未发酵棉粕底物, 试验组分别饲喂热带假丝酵母发酵棉粕和热带假丝酵母与酿酒酵母复合发酵棉粕。饲喂21 天后, 采集肉鸡腹部脂肪和肝脏进行组织基因表达和肝脏代谢组学分析。
结论
发酵棉粕可通过下调肝脏FAS、ACC 和腹脂LPL等基因的表达, 改变肝脏多种内源性代谢的代谢途径, 进而降低肉鸡腹部脂肪沉积和肝脏甘油三酯含量。
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1 Introduction
Cottonseed meal (CSM), a major protein source used in animal feed for many years in China, has good nutritive value (Yin et al., 1993; 1994). The utilization of CSM is limited in poultry diets due to the presence of gossypol, a toxic polyphenol. However, to solve this problem, solid-state fermentation is an effective option (Zhang et al., 2006; 2007). Additionally, CSM by solid-state fermentation improves nutrition characteristics (Zhang et al., 2006; Sun et al., 2012; Yang et al., 2012) and produces many essential nutrients such as amino acids, small-size peptides, vitamins, and oligosaccharides (Tang et al., 2012). Yeast, a unicellular fungus, can be used as a microbial feed additive for preventing disease and encouraging growth (Koh et al., 2002). Candida tropicalis and Saccharomyces cerevisae were used in CSM fermentation by Zhang et al. (2007), who found that the two yeast strains were very effective in detoxifying free gossypol in CSM. In addition, CSM fermented by C. tropicalis increased the levels of total amino acids, essential amino acids, and in vitro digestible crude protein and amino acids (Zhang et al., 2007). Koh et al. (2002) reported that S. cerevisae and fermented rice bran resulted in various biological activities in feed additives such as strengthening the immune system and reinforcing stress-fighting capabilities. Some studies have reported that fermented CSM (FCSM) improves growth performance (Tang et al., 2012) and gut microbes (Sun et al., 2013) in broiler chickens. However, little information is known about the influence of fermented CSM on lipid metabolism in broilers.
Lipid metabolism is closely associated with the nutritional value of meat, the yield of lean meat, or efficient feed utilization (de Genova Gaya et al., 2005; Zhao et al., 2007). Furthermore, excess fat deposition results in waste for consumers or economic loss for producers. Previous studies have indicated that fermented products can decrease fat deposition and improve lipid profiles (Park et al., 2012; Cha et al., 2013). In broiler chickens, the liver is the most important organ for lipid metabolism, and lipids are primarily stored in adipose tissue (Huang et al., 2008). Fat deposition results from a complex interactive process that involves genetic and environmental factors (Hausman et al., 2009; An et al., 2013). Metabolomics can comprehensively reveal the change rule and related mechanism of the biosystem affected by exogenous substances (Patti et al., 2012); thus, it is useful to understand the lipid metabolism of broilers when fermented feed is added to their diets. Metabolomics has been successfully applied to better understand the effects of organic feed on chickens (Huber et al., 2010), and has also been used to research the metabolism of adipose tissue of chickens (Ji et al., 2012).
This study investigated the effects of fermented CSM on lipid-related gene expression in tissue and liver metabolomics changes based on gas chromatography time-of-flight mass spectrometry (GC-TOF/MS) in yellow-feathered broiler chickens. This valuable commercial broiler species has good meat quality and its production approaches three billion animals every year in China (Tang et al., 2012). The aim of this study was to understand the effects of fermented CSM intake on the lipid metabolism of broiler chicken tissue and its mechanisms.
2 Materials and methods
2.1 Substrate treatment and strains
The CSM used in this study was obtained from the Shihezi District (Xinjiang Uygur Autonomous Region of China). The substrate treatment material was performed according to the methods of Zhang et al. (2007). The strains C. tropicalis and S. cerevisae were bred and collected by the Feed Science Institute of Zhejiang University (Hangzhou, China). These two strains were maintained in yeast extract peptone dextrose medium.
2.2 Preparation of fermented CSMs
The treated substrate (1000 g) was inoculated with 80 ml of liquid yeast inocula (108 cells/ml) of C. tropicalis or both strains (the ratio of C. tropicalis to S. cerevisae was 3:7). Every inoculated substrate was blended evenly, encased in a plastic container (50 cm×30 cm×12 cm) and incubated at 30 °C for 48 h in an incubator. After fermentation, the substrate was dried at 40 °C for 48 h in a draught drying cabinet. The same treatment process was performed for the unfermented CSM except that the same volume of sterile culture medium was inoculated. The chemical compositions of the unfermented CSM, the CSM fermented by C. tropicalis (Ct CSM), and the CSM fermented by C. tropicalis plus S. cerevisae (Ct-Sc CSM) were analyzed (AOAC, 1999) on a dry matter basis as follows: dry matter, 953, 946, and 947 g/kg; crude protein, 342, 376, and 375 g/kg; ether extract, 7.1, 7.2, and 7.4 g/kg; crude ash, 53.2, 57.6, and 58.5 g/kg in unfermented CSM, Ct CSM, and Ct-Sc CSM, respectively. The free gossypol contents, determined by a standard method (AOCS, 2009), were 126.7, 44.9, and 33.0 mg/kg, respectively. The concentration of free gossypol was less than 30 mg/kg in the diet and had no effect on the broilers’ health (Özdo>gan et al., 2012; Tang et al., 2012).
2.3 Broiler breeding
The animal care and use protocol was approved by the Animal Welfare Committee of Shihezi University (Xinjiang Uygur Autonomous Region of China). A total of 300 1-d-old Chinese yellow-feathered chickens were raised in a brooder house for 14 d fed a commercial diet. Then, the birds were fed the control diet for 7 d to acclimatize the feeds because the trial diets were afforded in mash form. Next, the birds underwent fasting for 12 h and were then weighed. After that, 180 birds were chosen from the 300 total birds according to their similar weight and randomly divided into three groups, each with 60 chickens. The chickens were raised in wire-floored cages (120 cm× 80 cm×50 cm) located in the same room. Ten chickens were kept in each cage of six cages from each group, and each cage was equipped with two nipple water bottles and one feeder. The diets of the three groups included the unfermented CSM (control group, Con), the Ct CSM (treatment group 1, Ct), and the Ct-Sc CSM (treatment group 2, Ct-Sc). The yeast levels were 2×106 colony-forming units (CFU) per g in the FCSM diet. Composition of the diets and nutrient levels are presented in Table 1. The birds were housed in conditions with continuous light and ad libitum access to feed and water throughout the rearing period, and the temperature was maintained at 23 to 25 °C during the ages of 21 to 42 d.
2.4 Sample collection
Six birds near the average weight (1276.81 g) were randomly selected from each group, and the 18 birds were killed by cervical dislocation to sample the abdominal fat (from the gizzard to the cloaca) and livers. Abdominal fat was calculated as the percentage of abdominal fat weight relative to the total weight of the carcass. About 5 g abdominal fat pared from the left sides and liver tissues sampled from left lobes were collected from birds, immediately frozen in liquid nitrogen, and then stored at -80 °C for further analysis.
2.5 Lipid metabolite assays of the livers
The concentrations of triglycerides (TG), total cholesterol (TC), and total protein in the livers were measured using commercial assay kits (Nanjing Jiancheng Bioengineering Institute, Nanjing, China) according to the manufacturer’s instructions with a microplate reader (Thermo Labsystems MK3, Helsinki, Finland). Total protein content was used to calculate the concentrations of TG and TC.
2.6 RNA isolation and real-time quantitative polymerase chain reaction (qPCR) analysis
Total RNAs of the livers and abdominal fat were isolated using TRIzol reagent (Invitrogen, Carlsbad, CA, USA) according to the manufacturer’s protocol. RNA concentrations were measured using a NanoDrop ND-1000 spectrophotometer (NanoDrop, Wilmington, DE, USA) and electrophoresed on a 1% (0.01 g/ml) denaturing agarose gel to test the integrity. All RNA samples were adjusted to the same concentration. The RNA was reverse transcribed to complementary DNA (cDNA) by PrimeScript™ RT reagent kits (TaKaRa, Shiga, Japan) according to the instructions. A real-time quantitative PCR was carried out in a 7500 Real Time PCR systems (Applied Biosystems, Foster City, CA, USA) using a SYBR-Green PCR kit (Roche Diagnostics, Laval, Quebec, Canada) according to optimized PCR protocols. The PCR programme was as follows: 95 °C for 2 min, followed by 32 cycles of 95 °C for 30 s, 55 °C for 30 s, 72 °C for 30 s, and 72 °C for 10 min.
The gene primers of fatty acid synthase (FAS), lipoprotein lipase (LPL), acetyl CoA carboxylase (ACC), peroxisome proliferator-activated receptor a (PPAR-α), peroxisome proliferator-activated receptor γ. (PPAR-γ), and β-actin were designed as described by Wu (2012), and liver fatty acid-binding protein (L-FABP) was designed as the chicken sequences from GenBank. The sequences of the primers were follows: FAS forward, 5'-TCAGGGTGTTCTGGAA TGCAA-3', reverse, 5'-AATCCTGGTGGGCAATC GTAG-3'; LPL forward, 5'-AGTCAGAGTGAAGTC AGGCGAAAC-3', reverse, 5'-CTGCTCCAGGCA CTTCACAAATA-3'; ACC forward, 5'-CTGATGG TCTTTGCCAACTGGA-3', reverse, 5'-CACGATGT AGGCACCAAACTTGA-3'; PPAR-α forward, 5'-TG CACTGGAACTGGATGATAGTGA-3', reverse, 5'-T CCTACATTTACAAGACCAGGACGA-3'; PPAR-γ. forward, 5'-TGTGAAGTTCAACGCACTGGAATT A-3', reverse, 5'-GGAGCTCCAAAGCTTGCAACA-3'; L-FABP forward, 5'-ATGAGCTTCACTGGAAAGT ACGAG-3', reverse, 5'-TCTTGATGTCCTTACCCT TCTGG-3'; β-actin forward, 5'-ATTGTCCACCGCA AATGCTTC-3', reverse, 5'-AAATAAAGCCATGC CAATCTCGTC-3'. All samples were analyzed in triplicate and results were expressed as
according to a previous method (Livak and Schmittgen, 2001).
2.7 Liver metabolomics profiling analysis
The samples of liver tissues (100 mg) were weighed in 2-ml tubes. Chilled extraction liquid (400 μl, the volume ratio of methanol to chloroform was 3:1) at -80 °C and internal standard L-2-chlorophenylalanine (50 μl, 0.1 mg/ml) were added to each tube and homogenized in a ball mill for 5 min at 70 Hz. Then, the mixture was centrifuged at 12 000g for 15 min at 4 °C and 0.35 ml of supernatant was transferred into a fresh 2-ml GC vial, followed by evaporation to dryness under vacuum in a speedvac concentrator (Thermo Fisher Scientific, Asheville, USA). Methoxyamine (80 μl) in pyridine (20 mg/ml) was added to the dried residue and vigorously vortex-mixed for 2 min. Methoximation reaction was performed at 37 °C for 2 h, followed by trimethylsilylation for 1 h by adding 100 μl of bis(trimethylsilyl) trifluoroacetamide (BSTFA) with 1% trimethylchlorosilane as catalyst. At last, the solution was shaken for 1 h at 70 °C and cooled to room temperature.
Each sample (1 μl) was injected into an Agilent 7890 GC with an Agilent 7683 Series autosampler (Agilent, Atlanta, GA, USA). Mass spectra were detected and obtained by using Pegasus HT TOF/MS (LECO Corporation, St. Joseph, MI, USA). Helium served as the carrier gas through the column. The optimized GC/MS operating conditions were as follows: the front inlet purge flow was 3 ml/min, and the gas flow rate through the column was 1 ml/min. The initial temperature was kept at 80 °C for 0.2 min, increased to 180 °C at a rate of 10 °C/min, then increased to 240 °C at a rate of 5 °C/min and finally increased to 280 °C at a rate of 20 °C/min for 18.8 min. The injection, transfer line, and ion source temperatures were 280, 270, and 220 °C, respectively. The MS data were acquired in full scan mode over the range between 35 and 600 m/z at a rate of 100 spectra/s.
2.8 Data collection and processing
ChromaTOF 4.3X software (LECO, St. Joseph, MI, USA) and Leco-Fiehn Rtx5 database were used for raw peaks extracting, the data baselines filtering and calibration of the baseline, peak alignment, de-convolution analysis, peak identification, and integration of the peak area (Kind et al., 2009). In addition, an internal standard normalization method was employed in the data analysis. The normalized peak area was fed to SIMCA-P 11.5 software (Umetrics, AB, Sweden) for the orthogonal partial least squares-discriminant analysis (OPLS-DA). Both the variable importance in the projection (VIP) values (VIP>1) obtained from the OPLS-DA and the Student’s t-test (P<0.05) were employed to find differentially expressed metabolites between the two comparison groups. The LECO/Fiehn Metabolomics Library for GC/MS metabolome date (similarity value of 70%) was used for discriminating compound annotation.
One-way analysis of variance was performed for the data of body weight, lipid content, and gene expression via statistical software SPSS 16.0 (SPSS Inc., Chicago, IL, USA). Differences among means were tested using Duncan’s multiple range tests. A significance level of 0.05 was used.
3 Results
3.1 Effects of FCSM on body weight and lipid metabolite contents
All the broiler chickens remained healthy in appearance throughout the experimental period of the FCSM-supplemented diet. The contents of abdominal fat and hepatic TG were significantly lower in the treatment groups than in the control group (P<0.05 for both; Table 2). However, the body weights and TC concentrations in the liver tissues did not change after adding FCSM to the diet (P>0.05 for both).
3.2 Effects of FCSM on gene expression related to lipid metabolism
Fig. 1 presents the results of gene expression. The gene expression of hepatic ACC and FAS in the treatment groups was significantly decreased compared with that in the controls (P<0.05). The FCSM-supplemented diet significantly decreased the LPL mRNA level in abdominal fat tissues (P<0.05). However, the expression levels of L-FABP, PPAR-α, and LPL in liver tissue, and PPAR-γ in abdominal fat tissues showed no significant changes among the three groups (P>0.05 for all).
3.3 Effects of FCSM on metabolomics profiling in liver tissue
FCSM intake caused metabolic changes of endogenous metabolites in the liver tissues of broiler chickens. Results indicated that FCSM supplementation significantly increased the levels of 1-monopalmitin, ethanolamine, and O-phosphoserine but decreased the levels of 2-mono-olein and myo-inositol (P<0.05 for all; Tables 3 and 4). The levels of arachidonic acid and glutamine were higher in the Ct group than in the Con group (P<0.05 for both; Table 3), while the levels of citric acid and prostaglandin E2 in the Ct group increased compared with the Con group (P<0.05 for both; Table 3). The Ct-Sc CSM group showed significantly elevated levels of fructose-6-phosphate and glycine, while the levels of 3-hydroxypyruvate and mannose declined (P<0.05 for all; Table 4).
4 Discussion
In the present study, the CSM fermented with yeast (C. tropicalis and S. cerevisiae) decreased the abdominal fat levels of the broiler chickens, which may have been caused by the fermented products and yeast probiotics of the CSM. Similar results of decreased abdominal fat by adding fermented products and yeast in the broiler chicken diets have been reported by Yamamoto et al. (2007) and Aluwong et al. (2013), respectively. A diet containing 1.5%–2.0% yeast (Aluwong et al., 2013) or 1% Koji-feed (fermented distillery by-product) (Yamamoto et al., 2007) resulted in significantly lower amounts of abdominal fat in broiler chickens.
The decreased content of abdominal fat resulted from a decrease of TG synthesis and/or enhancement of TG hydrolysis. The decreased concentrations of hepatic TG revealed that lipid synthesis was reduced when the broilers were fed the FCSM-supplemented diet, which can be associated with the reduction of abdominal fat. This notion is supported by a decrease of fatty acid synthesis because of the down-regulated mRNA expression of FAS and ACC. ACC, a rate-limiting enzyme of lipogenesis, plays a key role in the regulation of fatty acid synthesis (Numa et al., 1971). All the steps of conversion from malonyl-CoA to palmitate were catalyzed by FAS, and the FAS gene was a critical target in the control of lipogenesis (Joseph et al., 2002). The ACC and FAS have the highest correlation among lipogenic genes linked in lipogenesis (Huang et al., 2008). In addition, FCSM intake was not found to alter the lipid transport and lipid oxidation in the present study because L-FABP is involved with lipid transport, and PPAR-α highly expressed in the liver plays a major role in the regulation of peroxisomal β-oxidation (Lee et al., 1995). PPAR-. is expressed at the highest level in adipose tissue and promotes adipocyte differentiation (Mandrup and Lane, 1997), and its expression did not change after adding FCSM in the broiler chickens’ diet. LPL, a critical enzyme in the hydrolysis of TG, catalyzes TG from circulating chylomicrons and very-low-density lipoprotein in adipose tissue (Zhao et al., 2013). In the present study, the down-regulated mRNA level of LPL in abdominal fat was associated with a decreased fatty acid synthesis, hepatic TG content, and fat deposition in abdominal fat in the chickens fed the diet containing FCSM. Voshol et al. (2001) reported that overexpression of muscle LPL enhances the accumulation of intramuscular TG and fat in mammals. However, FCSM supplementation did not alter the hepatic LPL expression in the broilers, which may be the result of the decreased fatty acid synthesis. A more specific reason requires further research.
Lipid metabolism is a complex process regulated by multiple metabolic pathways, such as the tricarboxylic acid (TCA) cycle, glycolysis, β-oxidation, lipogenesis, and metabolism of amino acids, which can be comprehensively revealed by metabolomics analysis (An et al., 2013; Shi et al., 2013). Metabolomics, as a systems approach, has been used to understand the lipid metabolism in the process of fat deposition in animal growth (He et al., 2012). Comprehensive analysis of metabolite changes in liver metabolic profiling was performed to reveal alterations of the lipid metabolism when broilers were on the FCSM diet in this study. The metabolites involve a variety of metabolic pathways including the TCA cycle, fatty acid synthesis, and metabolism of glycerolipids and amino acids.
The levels of citric acids were clearly lower in the Ct group, and the increased levels of fructose-6-phosphate with decreased levels of mannose were observed in the Ct-Sc group compared wtih those in the Con group. Citric acid and fructose-6-phosphate are important intermediates which entered into the TCA cycle and gluconeogenesis to produce energy (Yang et al., 2006; Pilvi et al., 2008). Citric acid also plays an important role in biosynthesis routes, such as fatty acid biosynthesis in the liver (Liu et al., 2011). Mannose is converted into fructose-6-phosphate, which is an immediate precursor to glucose-6-phosphate in gluconeogenesis, and it also further metabolizes to enter the pentose phosphate pathway. This suggested that energy metabolism was altered by adding FCSM to the birds’ diets. However, differences of energy metabolism were also observed between the Ct and Ct-Sc groups associated with CSM fermented by different strains. FCSM was shown to improve the intestinal bacterial microbiota (Sun et al., 2013) and further regulate energy metabolism by the gut microbiome (Donohoe et al., 2011; Velagapudi et al., 2010).
The decreased levels of 2-mono-olein and myo-inositol were accompanied by increased levels of ethanolamine and 1-monopalmitin in the treatment groups compared with the Con group. The 2-mono-olein and 1-monopalmitin are monoacylglycerols formed by glycerol combined with a fatty acid molecule, and these changes are believed to be associated with fatty acid synthesis or absorption. Myo-inositol and ethanolamine are the key materials needed for the synthesis of glycerol phospholipid (phosphatidylinositol or phosphatidylethanolamine). The results indicated that the FCSM-supplemented diets caused the complex metabolic effects on the lipids due to the nutritional properties of fermented CSM (Sun et al., 2012) or microbial metabolism within the host (Velagapudi et al., 2010). A previous study showed that the addition of FCSM in broiler chickens’ diets increased the metabolites of glycerol phospholipids in their plasma, such as phosphatidylcholine, phophatidylethanolamine, cholesterol ester, and sphingomyelin, analyzed by metabolomics technology (Nie et al., 2013). He et al. (2012) reported that the serum of lean pigs had lower myo-inositol levels than that in obese pigs. Similarly, distinct variations of phospholipids and fatty acids were found in blood and liver tissues between obese and lean mice (Kim et al., 2011). Moreover, the idea that Ct CSM caused the up-regulation of arachidonic acid is supported by the metabolic differences. Arachidonic acid is a fatty acid combined into phospholipids of the cell membrane (Khairallah et al., 2012) or a precursor substance that forms prostaglandin E2 (Lukivskaya et al., 2001). Arachidonic acid suppresses liver fat by influencing the gene expression or activity of lipogenic enzymes (Oikawa et al., 2009), and prostaglandin E2 protects the liver against damage from alcohol use (Lukivskaya et al., 2001).
A novel finding from this work was that amino acids (glutamine and glycine) and amino acid products (3-hydroxypyruvate and O-phosphoserine) were altered in the broiler chickens’ livers while on the FCSM-supplemented diet. O-phosphoserine is a product of carbon metabolism, and it is a precursor substance that forms many amino acids, such as glycine, serine, threonine, cysteine, and methionine. The significant elevation of O-phosphoserine in the treatment groups showed that broilers fed the control diet needed to generate more amino acid by endogenous metabolism; that was different from the FCSM diet, which included lots of amino acid via microbial fermentation (Zhang et al., 2006; Tang et al., 2012). This was further supported by the decrease of 3-hydroxypyruvate and increase of glutamine or glycine. The 3-hydroxypyruvate can be converted to O-phosphoserine, which is catalyzed by phosphoserine aminotransferase. Comparison analysis of serum metabolomics indicated that obese pigs show signs of distinct metabolism of proteins and amino acids compared with lean pigs (He et al., 2012). Furthermore, it has been found that amino acid supplementation in weaned piglets’ diets can alter multiple metabolite pathways associated with lipid metabolism based on serum metabolomic methods (Xiao et al., 2012).
5 Conclusions
This study has shown that dietary FCSM supplementation reduced the levels of abdominal fat and liver TG by down-regulating the expression of hepatic lipogenetic genes (ACC and FAS) and LPL in abdominal fat tissue. Moreover, liver metabolomics profiling analysis indicated that dietary FCSM supplementation resulted in the multiple pathway alterations in the chickens’ metabolism including the TCA cycle, fatty acid synthesis, and metabolism of glycerolipid and amino acids. Thus, the regulation of lipid metabolism was found to be a complex process involving multiple pathways.
Compliance with ethics guidelines
Cun-xi NIE, Wen-ju ZHANG, Yong-qiang WANG, Yan-feng LIU, Wen-xia GE, and Jian-cheng LIU declare that they have no conflict of interest.
All institutional and national guidelines for the care and use of laboratory animals were followed.
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Acknowledgements
We are grateful to Dr. Jun-liang DENG (Biotree Biotechnology Co., Ltd., Shanghai, China) for providing helps in metabolomics data analysis.
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Project supported by the National Natural Science Foundation of China (No. 31360564) and the Graduate Research & Innovation Project of Xinjiang Uygur Autonomous Region of China (No. XJGRI2013059)
ORCID: Cun-xi NIE, http://orcid.org/0000-0003-3320-2840; Wen-ju ZHANG, http://orcid.org/0000-0002-5314-9904
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Nie, Cx., Zhang, Wj., Wang, Yq. et al. Tissue lipid metabolism and hepatic metabolomic profiling in response to supplementation of fermented cottonseed meal in the diets of broiler chickens. J. Zhejiang Univ. Sci. B 16, 447–455 (2015). https://doi.org/10.1631/jzus.B1400255
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DOI: https://doi.org/10.1631/jzus.B1400255