Transcriptome Analysis Reveals Differential Expression of Genes Regulating Hepatic Triglyceride Metabolism in Pekin Ducks During Dietary Threonine Deficiency

Jiang, Yong; Xie, Ming; Fan, Wenlei; Xue, Jiajia; Zhou, Zhengkui; Tang, Jing; Guo-hong, Chen; Hou, Shuisheng

doi:10.3389/fgene.2019.00710

Cited by 12 publications

(18 citation statements)

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“…Recently, in our laboratory, it was evaluated that threonine requirement is 0.61% for Pekin duck from 1 to 21 D of age. Meanwhile, we also observed that dietary threonine deficiency would increase hepatic total lipids of Pekin ducks ( Jiang et al., 2017 , Jiang et al., 2019a ) and hepatic fatty acid profile contents ( Jiang et al., 2019b ). Whether dietary threonine supplementation affects fatty acid profile contents of breast muscle and responses of fatty-type duck to dietary threonine levels are similar to those of lean-type duck is still unknown.…”

Section: Introductionmentioning

confidence: 80%

“…Meanwhile, dietary threonine deficiency increased plasma HDLC and TCHO concentrations. A previous study from our laboratory showed that dietary threonine deficiency increased the gene expression related to fatty acid and triglyceride synthesis, and reduced the gene expression involving in fatty acid oxidation and triglyceride degradation ( Jiang et al., 2019b ), although it did not detect the changes of genes related to lipid transportation to extrahepatic tissue, we speculated that threonine deficiency influences the transfer of lipid from liver to blood by decreasing the protein synthesis in lean-type ducks, hence the lipid was deposited in the liver. Whereas, threonine-deficient diet reduced hepatic total lipids in rat ( Ross-Inta et al., 2009 ).…”

Section: Discussionmentioning

confidence: 99%

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Effects of genetic selection and threonine on meat quality in Pekin ducks

et al. 2020

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The present study was conducted to investigate the effects of genetic selection and threonine levels on meat quality in Pekin ducks. At 15 D of age, 192 lean ducks and 192 fatty ducks were selected and allotted to one of three treatments with 8 replicates with similar BW (8 ducks/cage), respectively. All ducks were fed the experimental diets (0.00, 0.15, and 0.30% added threonine) for 21 D from 15 to 35 D of age. The results showed that fatty ducks had higher ( P < 0.001) feed intake, feed/gain ratio, abdominal fat percentage, and sebum percentage and lower ( P = 0.001) breast muscle percentage compared with that of lean ducks. The fatty-type and lean-type ducks had similar weight gain and BW. Dietary threonine supplementation improved ( P < 0.05) growth performance and increased breast muscle percentage in lean-type ducks, but it did not affect ( P > 0.05) those indices in fatty-type ducks. Lean ducks had higher ( P < 0.001) hepatic contents of total lipids, triglyceride, cholesterol, and plasma low-density lipoprotein cholesterol concentration, and dietary threonine supplementation decreased ( P < 0.05) hepatic total lipid, cholesterol, and triglyceride contents in lean ducks, but it had no influence on hepatic lipids in fatty ducks ( P > 0.05). Lean ducks had higher ( P < 0.05) concentrations of monounsaturated fatty acid ( MUFA ), and C18-polyunsaturated fatty acid ( PUFA ) in the liver, PUFA in the breast muscle, and C18:3n6 and C18:3n3 in plasma and lower C20-PUFA and C22-PUFA in the liver and MUFA in plasma, compared with fatty ducks. Threonine supplementation increased PUFA, N3-PUFA, and n6-PUFA in plasma and hepatic fatty acids profiles in lean ducks ( P > 0.05) but had on influence on total MUFA and total PUFA in the liver, breast muscle, and plasma in fatty ducks ( P > 0.05). In conclusion, genetic selection toward meat production and threonine supplementation increases meat production and PUFA contents, which would influence eating quality, but it is benefit for human health.

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Section: Introductionmentioning

confidence: 80%

Section: Discussionmentioning

confidence: 99%

Effects of genetic selection and threonine on meat quality in Pekin ducks

et al. 2020

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“…In addition, Thr may also regulate lipid metabolism, by reducing plasma triglyceride level when supplemented at 64% ADF Thr-to-Lys ratio compared to the other Thr levels in the present study. Jiang et al., 2017 , Jiang et al., 2019 suggested that dietary Thr supplementation improved hepatic lipid metabolism of Pekin ducks by regulating lipid synthesis, transport and oxidation. Similar observations were found in mammals ( Yoshida et al., 1961 ; Xiao et al., 2016 ).…”

Section: Discussionmentioning

confidence: 99%

Production performance and plasma metabolite concentrations of broiler chickens fed low crude protein diets differing in Thr and Gly

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Tesseraud

Tol³

et al. 2021

Animal Nutrition

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The aim of the study was to test the interaction between Thr and Gly in low crude protein (CP) diets in 7 to 28 d broilers on production performance and plasma metabolites. A total of 2,040 broilers were allocated to 17 treatments. A positive control (PC) diet (20.5% CP) was formulated to be adequate in dietary Thr and Gly. A negative control (NC) diet (18.5% CP, deficient in Thr and Gly) was supplemented with crystalline l -Thr and Gly to obtain a 4 Thr × 4 Gly design. Dietary Thr was tested at an apparent faecal digestibility (AFD) Thr-to-Lys ratio, which was 55%, 58%, 61% or 64%, and dietary Gly was tested at an AFD (Gly + Ser)-to-Lys ratio, which was 135%, 142%, 149% or 156%. Plasma samples were collected at 28 d. The low CP diet, formulated at 64% Thr and 156% Gly, resulted in a higher body weight gain (BWG) ( P < 0.01) and similar feed conversion ratio (FCR) as the high CP treatment (PC). FCR was improved (P < 0.001) by l -Thr supplementation. Quadratic response to dietary Thr was significant for feed intake (FI), BWG and FCR ( P < 0.01). A near-significant interaction for Thr × Gly was observed for FI and BWG ( P linear = 0.091 and P = 0.074, respectively). Gly did not affect production performance. An interaction between Thr × Gly on plasma free AA level was observed ( P < 0.05). Free AA concentration in plasma linearly decreased with increase in AFD Thr-to-Lys ratio, and increased with increase in AFD (Gly + Ser)-to-Lys ratio. Plasma uric acid concentration was higher in PC than in all of the other diets, and plasma triglyceride concentration was decreased by l -Thr supplementation, but not by Gly. In conclusion, Gly was not limiting for growth at low dietary CP level unless Thr was deficient, showing that adequate amounts of Thr in broiler diets can overcome marginal supply of Gly and Ser and allow reduction of dietary CP from 20.5% to 18.5% for broilers from 7 to 28 d of age.

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“…Essential amino acids have a close connection with the lipid metabolism, whereby certain amino acids (methionine, leucine, and isoleucine) can affect lipid deposition [ 23 ]. Thr similarly takes part in regulating lipid metabolism and deposition [ 24 ]. Thr supplementation has been shown to enhance hepatic lipid metabolism, while Thr deficiency may induce hepatic triglycerides accumulation, as shown in previous research [ 8 ].…”

Section: Role Of Thr In Nutrition Metabolismmentioning

confidence: 99%

“…Research on Pekin ducks found that dietary Thr shortage increased the expression of genes encoding 3-oxoacyl-ACP synthase ( OXSM ), very-long-chain fatty acids protein 7 ( ELOVL7 ), and long-chain fatty acyl-CoA ligase ( ACSBG2 ), which were related to fatty acid and triglyceride synthesis. However, genes participating in fatty acid oxidation, such as acyl-CoA dehydrogenase, acyl-CoA dehydrogenase family member 11 ( ACAD11 ) and cytochrome P450 ( CYP4B ), as well as genes associated with fatty acid and triglyceride transport, acyl-CoA binding protein ( DBI ), apolipoprotein D ( APOD ), and microsomal triglyceride transfer protein ( MTTP ), were downregulated under Thr deficiency in Pekin ducks [ 24 ]. The equilibrium between lipogenesis and lipolysis determines lipid homeostasis [ 25 ].…”

Section: Role Of Thr In Nutrition Metabolismmentioning

confidence: 99%

Physiological Functions of Threonine in Animals: Beyond Nutrition Metabolism

Tang

Tan

et al. 2021

Nutrients

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Threonine (Thr), an essential amino acid for animals and the limiting amino acid in swine and poultry diets, which plays a vital role in the modulation of nutritional metabolism, macromolecular biosynthesis, and gut homeostasis. Current evidence supports that the supplementation of Thr leads to benefits in terms of energy metabolism. Threonine is not only an important component of gastrointestinal mucin, but also acts as a nutritional modulator that influences the intestinal immune system via complex signaling networks, particularly mitogen-activated protein kinase (MAPK) and the target of the rapamycin (TOR) signal pathway. Threonine is also recognized as an indispensable nutrient for cell growth and proliferation. Hence, optimization of Thr requirement may exert a favorable impact on the factors linked to health and diseases in animals. This review focuses on the latest reports of Thr in metabolic pathways and nutritional regulation, as well as the relationship between Thr and relevant physiological functions.

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Transcriptome Analysis Reveals Differential Expression of Genes Regulating Hepatic Triglyceride Metabolism in Pekin Ducks During Dietary Threonine Deficiency

Cited by 12 publications

References 101 publications

Effects of genetic selection and threonine on meat quality in Pekin ducks

Effects of genetic selection and threonine on meat quality in Pekin ducks

Production performance and plasma metabolite concentrations of broiler chickens fed low crude protein diets differing in Thr and Gly

Physiological Functions of Threonine in Animals: Beyond Nutrition Metabolism

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