Ohlrogge JB. Design of new plant products:engineering of fatty acid metabolism[J]. Plant Physiology, 1994, 104(3):821.
[4]
Bates PD, Johnson SR, Cao X, et al. Fatty acid synthesis is inhibited by inefficient utilization of unusual fatty acids for glycerolipid assembly[J]. Proceedings of the National Academy of Sciences USA, 2014, 111(3):1204-1209.
[5]
Hills MJ. Control of storage-product synthesis in seeds[J]. Current Opinion in Plant Biology, 2004, 7(3):302-308.
[6]
Bonaventure G, Ohlrogge JB. Differential regulation of mRNA levels of acyl carrier protein isoforms in Arabidopsis[J]. Plant Physiology, 2002, 128(1):223-235.
[7]
Suh MC, Kim MJ, Hur CG, et al. Comparative analysis of expressed sequence tags from Sesamum indicum and Arabidopsis thaliana developing seeds[J]. Plant Molecular Biology, 2003, 52(6):1107-1123.
[8]
Natarajan P, Parani M. De novo assembly and transcriptome analysis of five major tissues of Jatropha curcas L. using GS FLX titanium platform of 454 pyrosequencing[J]. BMC Genomics, 2011, 12(1):191.
[9]
Chen H, Wang FW, Dong YY, et al. Sequence mining and transcript profiling to explore differentially expressed genes associated with lipid biosynthesis during soybean seed development[J]. BMC Plant Biology, 2012, 12(1):122.
[10]
Wang L, Yu S, Tong C, et al. Genome sequencing of the high oil crop sesame provides insight into oil biosynthesis[J]. Genome Biology, 2014, 15(2):R39.
Koo AJ, Fulda M, Browse J, et al. Identification of a plastid acyl-acyl carrier protein synthetase in Arabidopsis and its role in the activation and elongation of exogenous fatty acids[J]. The Plant Journal, 2005, 44(4):620-632.
[14]
Zhang M, Fan J, Taylor DC, et al. DGAT1 and PDAT1 acyltransfe-rases have overlapping functions in Arabidopsis triacylglycerol biosynthesis and are essential for normal pollen and seed development[J]. Plant Cell, 2009, 21(12):3885-3901.
[15]
Mhaske V, Beldjilali K, Ohlrogge J, et al. Isolation and characteri-zation of an Arabidopsis thaliana knockout line for phospholipid:diacylglycerol transacylase gene(At5g13640)[J]. Plant Physiology and Biochemistry, 2005, 43(4):413-417.
[16]
Shen Q, Han H, Qin X, et al. Important roles of transcription factors in regulating seed oil biosynthesis to increase plant storage lipid content[J]. Agricultural Science & Technology, 2013, 14(1):30-34.
[17]
Millar AA, Smith MA, Kunst L. All fatty acids are not equal:discrimination in plant membrane lipids[J]. Trends in Plant Science, 2000, 5(3):95-101.
[18]
Ruuska SA, Girke T, Benning C, et al. Contrapuntal networks of gene expression during Arabidopsis seed filling[J]. Plant Cell, 2002, 14(6):1191-1206.
[19]
Mu J, Tan H, Zheng Q, et al. LEAFY COTYLEDON1 is a key regulator of fatty acid biosynthesis in Arabidopsis[J]. Plant Physiology, 2008, 148(2):1042-1054.
[20]
Shen B, Allen WB, Zheng P, et al. Expression of ZmLEC1 and ZmWRI1 increases seed oil production in maize[J]. Plant Physiology, 2010, 153(3):980-987.
[21]
Cernac A, Benning C. WRINKLED1 encodes an AP2/EREB domain protein involved in the control of storage compound biosynthesis in Arabidopsis[J]. The Plant Journal, 2004, 40(4):575-585.
[22]
Liu J, Hua W, Zhan G, et al. Increasing seed mass and oil content in transgenic Arabidopsis by the overexpression of wri1-like gene from Brassica napus[J]. Plant Physiology and Biochemistry, 2010, 48(1):9-15.
[23]
Baud S, Mendoza MS, To A, et al. WRINKLED1 specifies the regulatory action of LEAFY COTYLEDON2 towards fatty acid metabolism during seed maturation in Arabidopsis[J]. The Plant Journal, 2007, 50(5):825-838.
Goffman FD, Ruckle M, Ohlrogge J, et al. Carbon dioxide concentrations are very high in developing oilseeds[J]. Plant Physiology and Biochemistry, 2004, 42(9):703-708.
[26]
Ruuska SA, Schwender J, Ohlrogge JB. The capacity of green oilseeds to utilize photosynthesis to drive biosynthetic processes[J]. Plant Physiology, 2004, 136(1):2700-2709.
[27]
Alonso AP, Goffman FD, Ohlrogge JB, et al. Carbon conversion efficiency and central metabolic fluxes in developing sunflower(Helianthus annuus L. )embryos[J]. The Plant Journal, 2007, 52(2):296-308.
[28]
Baud S, Lepiniec L. Physiological and developmental regulation of seed oil production[J]. Progress in Lipid Research, 2010, 49(3):235-249.
[29]
Nikolau BJ, Ohlrogge JB, Wurtele ES. Plant biotin-containing carboxylases[J]. Archives of Biochemistry and Biophysics, 2003, 414(2):211-222.
[30]
Klaus D, Ohlrogge JB, Neuhaus HE, et al. Increased fatty acid pro-duction in potato by engineering of acetyl-CoA carboxylase[J]. Planta, 2004, 219(3):389-396.
[31]
Roesler K, Shintani D, Savage L, et al. Targeting of the Arabidopsis homomeric acetyl-coenzyme A carboxylase to plastids of rapeseeds[J]. Plant Physiology, 1997, 113(1):75-81.
[32]
Schwender J, Ohlrogge JB, Shachar-Hill Y. A flux model of glycolysis and the oxidative pentosephosphate pathway in developing Brassica napus embryos[J]. Journal of Biological Chemistry, 2003, 278(32):29442-29453.
[33]
Bafor M, Jonsson L, Stobart AK, et al. Regulation of triacylglycerol biosynthesis in embryos and microsomal preparations from the developing seeds of Cuphea lanceolata[J]. Biochem J, 1990, 272:31-38.
[34]
Bao X, Ohlrogge J. Supply of fatty acid is one limiting factor in the accumulation of triacylglycerol in developing embryos[J]. Plant Physiology, 1999, 120(4):1057-1062.
[35]
Lu J, Zhang C, Baulcombe DC, et al. Maternal siRNAs as regulators of parental genome imbalance and gene expression in endosperm of Arabidopsis seeds[J]. Proceedings of the National Academy of Sciences USA, 2012, 109(14):5529-5534.
[36]
Huh JH, Bauer MJ, Hsieh TF, et al. Endosperm gene imprinting and seed development[J]. Current Opinion in Genetics & Development, 2007, 17(6):480-485.
[37]
Constância M, Kelsey G, Reik W. Resourceful imprinting[J]. Nature, 2004, 432(7013):53-57.
[38]
Berger F, Chaudhury A. Parental memories shape seeds[J]. Trends in Plant Science, 2009, 14(10):550-556.
[39]
Schilmiller AL, Koo AJK, Howe GA. Functional diversification of acyl-coenzyme A oxidases in jasmonic acid biosynthesis and action[J]. Plant Physiology, 2007, 143(2):812-824.
[40]
Weber H, Borisjuk L, Heim U, et al. Seed coat-associated invertases of fava bean control both unloading and storage functions:cloning of cDNAs and cell type-specific expression[J]. Plant Cell, 1995, 7(11):1835-1846.
[41]
D’Hooghe P, Dubousset L, Gallardo K, et al. Evidence for proteomic and metabolic adaptations associated to alterations of seed yield and quality in sulphur-limited Brassica napus L[J]. Molecular & Cellular Proteomics, 2014:mcp. M113. 034215.
Chapman KD, Ohlrogge JB. Compartmentation of triacylglycerol accumulation in plants[J]. Journal of Biological Chemistry, 2012, 287(4):2288-2294.
[44]
Baud S, Lepiniec L. Compared analysis of the regulatory systems controlling lipogenesis in hepatocytes of mice and in maturing oilseeds of Arabidopsis[J]. Comptes Rendus Biologies, 2008, 331(10):737-745.
[45]
Bates PD, Durrett TP, Ohlrogge JB, et al. Analysis of acyl fluxes through multiple pathways of triacylglycerol synthesis in developing soybean embryos[J]. Plant Physiology, 2009, 150(1):55-72.
[46]
Bourgis F, Kilaru A, Cao X, et al. Comparative transcriptome and metabolite analysis of oil palm and date palm mesocarp that differ dramatically in carbon partitioning[J]. Proceedings of the National Academy of Sciences USA, 2011, 108(30):12527-12532.
[47]
Mekhedov S, de Ilárduya OM, Ohlrogge J. Toward a functional catalog of the plant genome. A survey of genes for lipid biosynthesis[J]. Plant Physiology, 2000, 122(2):389-402.
[48]
White JA, Todd J, Newman T, et al. A new set of Arabidopsis expressed sequence tags from developing seeds. The metabolic pathway from carbohydrates to seed oil[J]. Plant Physiology, 2000, 124(4):1582-1594.
[49]
Troncoso-Ponce MA, Kilaru A, Cao X, et al. Comparative deep transcriptional profiling of four developing oilseeds[J]. The Plant Journal, 2011, 68(6):1014-1027.
[50]
O’Hara P, Slabas AR, Fawcett T. Fatty acid and lipid biosynthetic genes are expressed at constant molar ratios but different absolute levels during embryogenesis[J]. Plant Physiology, 2002, 129(1):310-320.
[51]
Song QX, Li QT, Liu YF, et al. Soybean GmbZIP123 gene enhances lipid content in the seeds of transgenic Arabidopsis plants[J]. Journal of Experimental Botany, 2013:ert238.
Milcamps A, Tumaney AW, Paddock T, et al. Isolation of a gene encoding a 1, 2-diacylglycerol-sn-acetyl-CoA acetyltransferase from developing seeds of Euonymus alatus[J]. Journal of Biological Chemistry, 2005, 280(7):5370-5377.
[57]
Ramli U, Baker D, Quant P, et al. Control analysis of lipid biosynthesis in tissue cultures from oil crops shows that flux control is shared between fatty acid synthesis and lipid assembly[J]. Biochem J, 2002, 364:393-401.
[58]
Ohlrogge JB, Jaworski JG. Regulation of fatty acid synthesis[J]. Annual Review of Plant Biology, 1997, 48(1):109-136.
[59]
Baud S, Lepiniec L. Regulation of de novo fatty acid synthesis in maturing oilseeds of Arabidopsis[J]. Plant Physiology and Biochemistry, 2009, 47(6):448-455.
[60]
Lotan T, Ohto M, Yee KM, et al. Arabidopsi LEAFY COTYLEDON1 is sufficient to induce embryo development in vegetative cells[J]. Cell, 1998, 93(7):1195-1205.
[61]
Focks N, Benning C. wrinkled1:a novel, low-seed-oil mutant of Arabidopsis with a deficiency in the seed-specific regulation of carbohydrate metabolism[J]. Plant Physiology, 1998, 118(1):91-101.
[62]
Cernac A, Andre C, Hoffmann-Benning S, et al. WRI1 is required for seed germination and seedling establishment[J]. Plant Physiology, 2006, 141(2):745-757.
Baud S, Wuillème S, To A, et al. Role of WRINKLED1 in the transcriptional regulation of glycolytic and fatty acid biosynthetic genes in Arabidopsis[J]. The Plant Journal, 2009, 60(6):933-947.
[65]
Wang H, Guo J, Lambert KN, et al. Developmental control of Arabidopsis seed oil biosynthesis[J]. Planta, 2007, 226(3):773-783.
[66]
Fan J, Yan C, Andre C, et al. Oil accumulation is controlled by carbon precursor supply for fatty acid synthesis in Chlamydomonas reinhardtii[J]. Plant and Cell Physiology, 2012, 53(8):1380-1390.
[67]
Goffman FD, Alonso AP, Schwender J, et al. Light enables a very high efficiency of carbon storage in developing embryos of rapeseed[J]. Plant Physiology, 2005, 138(4):2269-2279.
[68]
Allen DK, Ohlrogge JB, Shachar-Hill Y. The role of light in soybean seed filling metabolism[J]. The Plant Journal, 2009, 58(2):220-234.
[69]
Lardizabal K, Effertz R, Levering C, et al. Expression of Umbelopsis ramanniana DGAT2A in seed increases oil in soybean[J]. Plant Physiology, 2008, 148(1):89-96.
[70]
Taylor DC, Zhang Y, Kumar A, et al. Molecular modification of triacylglycerol accumulation by over-expression of DGAT1 to produce canola with increased seed oil content under field conditions[J]. Botany, 2009, 87(6):533-543.
[71]
Reik W, Dean W. DNA methylation and mammalian epigenetics [J]. Electrophoresis, 2001, 22(14):2838-2843.
[72]
Gregg C, Zhang J, Weissbourd B, et al. High-resolution analysis of parent-of-origin allelic expression in the mouse brain[J]. Science, 2010, 329(5992):643-648.
[73]
Hsieh TF, Shin J, Uzawa R, et al. Regulation of imprinted gene expression in Arabidopsis endosperm[J]. Proceedings of the National Academy of Sciences USA, 2011, 108(5):1755-1762.
[74]
Durrett TP, McClosky DD, Tumaney AW, et al. A distinct DGAT with sn-3 acetyltransferase activity that synthesizes unusual, reduced-viscosity oils in Euonymus and transgenic seeds[J]. Proceedings of the National Academy of Sciences USA, 2010, 107(20):9464-9469.
[75]
Yang Y, Yu X, Song L, et al. ABI4 activates DGAT1 expression in Arabidopsis seedlings during nitrogen deficiency[J]. Plant Physiology, 2011, 156(2):873-883.
[76]
孙远, 刘文彬, 周铁柱, 等. Fe 3+ 对小球藻的生长及油脂含量的影响[J]. 生物技术通报, 2014(4):181-186.
