1. Lucas A. Programming by Early nutrition an experimental approach[J]. J Nutr, 1998;128:401S-406S.
2. Reynolds C M, Gray C, Li M, Segovia S A, Vickers M H. Early life nutrition and energy balance disorders in offspring in later life[J]. Nutrients, 2015;7:8090-8111.
3. Geurden I, Aramendi M, Zambonino-Infante J, Panserat S. Early feeding of carnivorous rainbow trout (Oncorhynchus mykiss) with a hyperglucidic diet during a short period: effect on dietary glucose utilization in juveniles[J]. Am J Physiol Regul Integr Comp Physiol, 2007;292:R2275-2283.
4. Vagner M, Robin J H, Zambonino Infante J L, Person-Le Ruyet J. Combined effects of dietary HUFA level and temperature on sea bass (Dicentrarchus labrax) larvae development[J]. Aquaculture, 2007; 266:179-190.
5. Vagner M, Robin J H, Zambonino-Infante J L, Tocher D R, Person-Le Ruyet J. Ontogenic effects of early feeding of sea bass (Dicentrarchus labrax) larvae with a range of dietary n-3 highly unsaturated fatty acid levels on the functioning of polyunsaturated fatty acid desaturation pathways[J]. Br J Nutr, 2009;101:1452-1462.
6. Fang L, Liang X F, Zhou Y, Guo X Z, He Y, Yi T L, Liu L W, Yuan X C, Tao Y X. Programming effects of high-carbohydrate feeding of larvae on adult glucose metabolism in zebrafish, Danio rerio[J]. Br J Nutr, 2014;111(5): 808-818.
7. McMillen I C, Robinson J S. Developmental origins of the metabolic syndrome: prediction, plasticity, and programming[J]. Physiol Rev, 2005;85:571-633.
8. Luo L, Wei H, Ai L, Liang X, Wu X, Xing W, Chen P, Xue, M. Effects of early long-chain n-3HUFA programming on growth, antioxidant response and lipid metabolism of Siberian sturgeon (Acipenser baerii Brandt) [J]. Aquaculture, 2019;509:96-103.
9. Geurden I, Mennigen J, Plagnes-Juan E, Veron V, Cerezo T, Mazurais D, Zambonino-Infante J, Gatesoupe J, Skiba-Cassy S, Panserat S. High or low dietary carbohydrate:protein ratios during first-feeding affect glucose metabolism and intestinal microbiota in juvenile rainbow trout[J]. J Exp Biol, 2014;217:3396-3406.
10. Liu J, Dias K, Plagnes-Juan E, Veron V, Panserat S, Marandel L. Long-term programming effect of embryonic hypoxia exposure and high-carbohydrate diet at first feeding on glucose metabolism in juvenile rainbow trout[J]. J Exp Biol, 2017;220:3686-3694.
11. Li F, Yin Y, Tan B, Kong X, Wu G. Leucine nutrition in animals and humans: mTOR signaling and beyond[J]. Amino Acids, 2011;41:1185-1193.
12. Ahmed I, Khan M A. Dietary branched-chain amino acid valine, isoleucine and leucine requirements of fingerling Indian major carp, Cirrhinus mrigala (Hamilton) [J]. Br J Nutr, 2006;96:450-460.
13. Abidi S F, Khan M A. Dietary leucine requirement of fingerling Indian major carp, Labeo rohita (Hamilton) [J]. Aquaculture Research, 2007;38:478-486.
14. Deng Y P, Jiang W D, Liu Y, Jiang J, Kuang S Y, Tang L, Wu P, Zhang Y A, Feng L, Zhou X Q. Differential growth performance, intestinal antioxidant status and relative expression of Nrf2 and its target genes in young grass carp (Ctenopharyngodon idella) fed with graded levels of leucine[J]. Aquaculture, 2014;434:66-73.
15. Comesana S, Velasco C, Ceinos R M, Lopez-Patino M A, Miguez J M, Morais S, Soengas J L. Evidence for the presence in rainbow trout brain of amino acid-sensing systems involved in the control of food intake[J]. Am J Physiol Regul Integr Comp Physiol, 2018;314:R201-R215.
16. Lansard M, Panserat S, Plagnes-Juan E, Seiliez I, Skiba-Cassy S. Integration of insulin and amino acid signals that regulate hepatic metabolism-related gene expression in rainbow trout: role of TOR[J]. Amino Acids, 2010;39: 801-810.
17. Lansard M, Panserat S, Plagnes-Juan E, Dias K, Seiliez I, Skiba-Cassy S. L-leucine, L-methionine, and L-lysine are involved in the regulation of intermediary metabolism-related gene expression in rainbow trout hepatocytes[J]. J Nutr, 2011;141:75-80.
18. Nijland M J, Mitsuya K, Li C, Ford S, McDonald T J, Nathanielsz P W, Cox L A. Epigenetic modification of fetal baboon hepatic phosphoenolpyruvate carboxykinase following exposure to moderately reduced nutrient availability[J]. J Physiol, 2010;588:1349-1359.
19. Burdge G C, Hoile S P, Uller T, Thomas N A, Gluckman P D, Hanson M A, Lillycrop K A. Progressive, transgenerational changes in offspring phenotype and epigenotype following nutritional transition[J]. PLoS One, 2011;6(11): e28282.
20. He X J, Chen T, Zhu J K. Regulation and function of DNA methylation in plants and animals[J]. Cell Res, 2011;21:442-465.
21. Smith Z D, Meissner A. DNA methylation: roles in mammalian development[J]. Nat Rev Genet, 2013;14:204-220.
22. Waterland R, Jirtle R. Early nutrition, epigenetic changes at transposons and imprinted genes, and enhanced susceptibility to adult chronic diseases[J]. Nutrition, 2004;20:63-68.
23. Zeisel S H. Epigenetic mechanisms for nutrition determinants of later health outcomes[J]. Am J Clin Nutr, 2009;89:1488S-1493S.
24. Veron V, Marandel L, Liu J, Velez E J, Lepais O, Panserat S, Skiba S, Seiliez I. DNA methylation of the promoter region of bnip3 and bnip3l genes induced by metabolic programming[J]. BMC Genomics, 2018;19:677.
25. Goetz F W, Donaldson E M, Hunter G A, Dye H M. Effects of estradiol-17β and 17α-methyltestosterone on gonadal differentiation in the coho salmon, Oncorhynchus kisutch[J]. Aquaculture, 1979;17:267-278.
26. Zeng Y H, Cai W S, Shao X G. Quantitative analysis of 17 amino acids in tobacco leaves using an amino acid analyzer and chemometric resolution[J]. J Separation Sci, 2015;38(12):2053-2058.
27. Horwitz W. Official methods of analysis of the Association of Official Analytical Chemists[J]. J Pharm Sci. 1975;60:414.
28. Livak K J, Schmittgen T D. Analysis of relative gene expression data using real-time quantitative PCR and the 2−ΔΔCT method[J]. Methods, 2001; 25:402-408.
29. Demmelmair H, von Rosen J, Koletzko B. Long-term consequences of early nutrition[J]. Early Hum Dev, 2006;82:567-574.
30. Hall W. Weaning and growth of artificially reared rats[J]. Science, 1975;190:1313-1315.
31. Patel M S, Srinivasan M, Laychock S G. Metabolic programming: Role of nutrition in the immediate postnatal life[J]. J Inherit Metab Dis, 2009;32:218-228.
32. Escobar J, Frank J W, Suryawan A, Nguyen H V, Davis T A. Amino acid availability and age affect the leucine stimulation of protein synthesis and eIF4F formation in muscle[J]. Am J Physiol Endocrinol Metab, 2007;293:E1615-1621.
33. Suryawan A, Jeyapalan A S, Orellana R A, Wilson F A, Nguyen H V, Davis T A. Leucine stimulates protein synthesis in skeletal muscle of neonatal pigs by enhancing mTORC1 activation[J]. Am J Physiol Endocrinol Metab, 2008;295:E868-875.
34. Rocha F, Dias J, Engrola S, Gavaia P, Geurden I, Dinis M T, Panserat S. Glucose metabolism and gene expression in juvenile zebrafish (Danio rerio) challenged with a high carbohydrate diet: effects of an acute glucose stimulus during late embryonic life[J]. Br J Nutr, 2015;113:403-413.
35. Liu J, Plagnes-Juan E, Geurden I, Panserat S, Marandel L. Exposure to an acute hypoxic stimulus during early life affects the expression of glucose metabolism-related genes at first-feeding in trout[J]. Sci Rep, 2017;7:363.
36. Rocha F, Dias J, Geurden I, Dinis M T, Panserat S, Engrola S. Dietary glucose stimulus at larval stage modifies the carbohydrate metabolic pathway in gilthead seabream (Sparus aurata) juveniles: An in vivo approach using (14)C-starch[J]. Comp Biochem Physiol A Mol Integr Physiol, 2016;201:189-199.
37. Guertin D A, Guntur K V, Bell G W, Thoreen C C, Sabatini D M. Functional genomics identifies TOR-regulated genes that control growth and division[J]. Curr Biol, 2006;16:958-970.
38. Ren M, Habte-Tsion H-M, Liu B, Miao L, Ge X, Xie J, Liang H, Zhou Q, Pan L. Dietary leucine level affects growth performance, whole body composition, plasma parameters and relative expression of TOR and TNF-ɑ in juvenile blunt snout bream, Megalobrama amblycephala[J]. Aquaculture, 2015;448:162-168.
39. Liang H, Mokrani A, Chisomo-Kasiya H, Ji K, Ge X, Ren M, Liu B, Xi B, Sun A. Dietary leucine affects glucose metabolism and lipogenesis involved in TOR/PI3K/Akt signaling pathway for juvenile blunt snout bream Megalobrama amblycephala[J]. Fish Physiol Biochem, 2019;45:719-732.
40. Ramaswamy M, Thangavel P, Selvam N. Glutamic oxaloacetic transaminase (GOT) and glutamic pyruvic transaminase (GPT) enzyme activities in different tissues of Sarotherodon mossambicus (Peters) exposed to a carbamate pesticide, carbaryl[J]. Pesticide Science, 1999;55:1217-1221.
41. Michel M, Page-McCaw P S, Chen W, Cone R D. Leptin signaling regulates glucose homeostasis, but not adipostasis, in the zebrafish[J]. Proc Natl Acad Sci U S A, 2016;113:3084-3089.
42. Düvel K, Yecies J L, Menon S, Raman P, Lipovsky A I, Souza A L, Triantafellow E, Ma Q, Gorski R, Cleaver S, Vander Heiden M G, MacKeigan J P, Finan P M, Clish C B, Murphy L O, Manning B D. Activation of a metabolic gene regulatory network downstream of mTOR complex 1[J]. Molecular cell, 2010;39:171-183.
43. Sun L X, Wang Y Y, Zhao Y, Wang H, Li N, Ji X S. Global DNA methylation changes in Nile Tilapia gonads during high Temperature-Induced Masculinization[J]. PLoS One, 2016;11:e0158483.
44. Xu N, Chua A K, Jiang H, Liu N A, Goodarzi M O. Early embryonic androgen exposure induces transgenerational epigenetic and metabolic changes[J]. Mol Endocrinol, 2014;28:1329-1336.
45. Potok M E, Nix D A, Parnell T J, Cairns B R. Reprogramming the maternal zebrafish genome after fertilization to match the paternal methylation pattern[J]. Cell, 2013;153:759-772.
46. Chatterjee A, Stockwell P A, Horsfield J A, Morison I M, Nakagawa S. Base-resolution DNA methylation landscape of zebrafish brain and liver[J]. Genom Data, 2014;2:342-344.
47. Wan Z Y, Xia J H, Lin G, Wang L, Lin V C, Yue G H. Genome-wide methylation analysis identified sexually dimorphic methylated regions in hybrid tilapia[J]. Sci Rep, 2016;6:35903.
48. Tokunaga C, Yoshino K, Yonezawa K. mTOR integrates amino acid and energy-sensing pathways[J]. Biochem Biophys Res Commun, 2004;313: 443-446.
49. Liu B, Liu F. Feedback regulation of mTORC1 by Grb10 in metabolism and beyond[J]. Cell Cycle, 2014;13:2643-2644.
50. Yoshizawa F, Sekizawa H, Hirayama S, Hatakeyama A, Nagasawa T, Sugahara K. Time Course of Leucine-induced 4E-BP1 and S6K1 Phosphorylation in the Liver and Skeletal Muscle of Rats[J]. J Nutr Sci Vitaminol, 2001;47:311-315.
51. Wang Y Y, Sun L X, Zhu J J, Zhao Y, Wang H, Liu H J, Ji X S. Epigenetic control of cyp19a1a expression is critical for high temperature induced Nile tilapia masculinization[J]. J Therm Biol, 2017;69:76-84.
52. Jones P A. Functions of DNA methylation: islands, start sites, gene bodies and beyond[J]. Nat Rev Genet, 2012;13:484-492.
53. Wang Z, Wu X, Wu Z, An H, Yi B, Wen J, Ma C, Shen J, Fu T, Tu J. Genome-Wide DNA methylation comparison between Brassica napus genic male sterile line and restorer line[J]. Int J Mol Sci, 2018;19:2689.
54. Ma X, Yang Q, Wilson KT, Kundu N, Meltzer S J, Fulton A M. Promoter methylation regulates cyclooxygenase expression in breast cancer[J]. Breast Cancer Research, 2004;6:R316.