1. PR Shewry. Seed proteins. In: M Black, JD Bewley, eds. Seed Technology and its Biological Basis. Sheffield, UK: Sheffield Academic Press, 2000, pp 4284.

2. JB Beccari. De Frumento. De Bononiensi Scientiarum et Artium Instituto atque Academia Commentarii, II Part 1, 1745, pp 122-127.

3. CJ Leaver. Genome Organization and Expression in Plants. New York: Plenum, 1980, p 607.

4. JD Bewley, M Black. Physiology and Biochemistry of Seeds in Relation to Germination. 1. Development, Germination, and Growth. Berlin: Springer-Verlag, 1978.

5. TB Osborne. The Vegetable Proteins. 2nd ed. London: Longmans, Green, 1924, p 154.

6. R Casey. Distribution and some properties of seed globulins. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 159-169.

7. M Delseny, M Raynal. Globulin storage proteins in crucifers and non-legume dicotyledonous families. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 427-452.

8. AL Kriz. 7S globulins of cereals. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 477-498.

9. MA Shotwell. Oat globulins. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 389-400.

10. F Takaiwa, M Ogawa, TW Okita. Rice glutelins. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 401-425.

11. S Utsumi, AB Gidamis, Y Takenaka, N Maruyama, M Adachi, B Mikami. Crystallization and X-ray analysis of normal and modified recombinant soybean proglycinins. Three-dimensional structure of normal proglycinin at 6 A resolution. In: N Parris, A Kato, LK Creamer, J Pearce, eds. Macromolecular Interactions in Food Technology. Washington, DC: American Chemical Society, 1996, pp 257-270.

12. MC Lawrence. Structural relationships of 7S and 1 IS globulins. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 517-541.

13. AD Shutov, H Baumlein. Origin and evolution of seed globulins. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 543-561.

14. JM Dunwell. Cupins: a new superfamily of functionally diverse proteins that include germins and plant storage proteins. Biotechnol and Genet Eng Rev 5: 1-32, 1998.

15. PR Shewry, AS Tatham. The characteristics, structures and evolutionary relationships of prolamins. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 11-33.

16. PR Shewry, AS Tatham, NG Halford. The prolamins of the Triticeae. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 35-78.

17. CE Coleman, BA Larkins. Prolamins of maize. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 109-139.

18. A Leite, GC Neto, AL Vettore, J A Yunes, P Arruda. The prolamins of sorghum, Coix and millets. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 141-157.

19. PR Shewry. Avenins: the prolamins of oats. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 79-92.

20. PR Shewry, MJ Pandya. The 2S albumins storage proteins. In: PR Shewiy, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 563-586.

21. ET Mertz, LS Bates, OE Nelson. Mutant gene that changes protein composition and increases lysine content of maize endosperm. Science 145:279-280, 1964.

22. OE Nelson, ET Mertz, LS Bates. Second mutant gene affecting the amino acid pattern of maize endosperm proteins. Science 150:1469-1470, 1965.

23. L Munck, KE Karlsson, A Hagberg, BO Eggum. Gene for improved nutritional value in barley seed protein. Science 168:985-987, 1970.

24. R Singh, JD Axtell. High lysine mutant gene (hi) that improves protein quality and biological value of grain sorghum. Crop Sci 3:535-539, 1973.

25. JD Axtell, SW Van Scoyoc, PJ Christensen, G Ejeta. Current status of protein quality improvement in grain sorghum. In Seed Protein Improvement in Cereals and Grain Legumes. Vol 1. Vienna: IAEA, 1979, pp 357-365.

26. H Doll. Barley seed proteins and possibilities for their improvement. In: W Gottschalk, HP Muller, eds. Seed Proteins: Biochemistry, Genetics, Nutritive Value. The Hague: Martinus Nijhof, 1983, pp 205-223.

27. PR Shewry, MS Williamson, M Kreis. Effects of mutant genes on the synthesis of storage components in developing barley endosperms. In: H Thomas, D Grierson, eds. Mutant Genes That Affect Plant Development. Cambridge: Cambridge University Press, 1987, pp 95-118.

28. J Kohno-Murase, M Murase, H Ichikawa, J Imamura. Effects of an antisense napin gene on seed storage compounds in transgenic Brassica napus seeds. Plant Mol Biol 26:1115-1124, 1994.

29. J Kohno-Murase, M Murase, H Ichikawa, J Imamura. Improvement in the quality of seed storage protein by transformation of Brassica napus with an antisense gene for cruciferin. Theor Appl Genet 91:627-631, 1995.

30. JC Wallace, G Galili, EE Kawata, RE Cuellar, MA Shotwell, BA Larkins. Aggregation of lysine-containing zeins into protein bodies in Xenopus oocytes. Science 240:662-664, 1988.

31. J Hejgaard, S Boisen. High lysine proteins in Hiproly barley breeding: identification, nutritional significance and new screening methods. Hereditas 93: 311-320, 1980.

32. PR Shewry. Barley seed proteins. In: J MacGregor, R Bhatty, eds. Barley: Chemistry and Technology. St. Paul, MN: AACC, pp 131-197.

33. MS Williamson, J Forde, B Buxton, M Kreis. Nucleotide sequence of barley chymotrypsin inhibitor-2 (CI-2) and its expression in normal and high-lysine barley. Eur J Biochem 165:99-106, 1987.

34. K Stott, M Blackburn, PJG Butler, M Perutz. Incorporation of glutamine repeats makes protein oligomerize: implications for neurodegenerative diseases. Proc Natl Acad Sci USA 92:6509-6513, 1995.

35. MF Perutz. Glutamine repeats and inherited neurodegenerative diseases: molecular aspects. Curr Opin Struct Biol 6:848-858, 1996.

36. KR Roesler, AG Rao. Conformation and stability of barley chymotrypsin inhibitor-2 (CI-2) mutants containing multiple lysine substitutions. Protein Eng 12:967-973, 1999.

37. F García-Olmedo. Thionins. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 709-726.

38. AG Rao, M Hassan, JC Hempel. Structure-function validation of high lysine analogs of a-hordothionin designed by protein modelling. Protein Eng 7:14851493, 1994.

39. E Derbyshire, DJ Wright, D Boulter. Legumin and vicilin, storage proteins of legume seeds. Phytochemistry 15:3-24, 1976.

40. AS Sindhu, Z Sheng, N Murai. The pea seed storage protein legumin was synthesized, processed, and accumulated stably in transgenic rice endosperm. Plant Sci 130:189-196, 1997.

41. SJ Keeler, CL Maloney, PY Webber, C Patterson, LT Hirata, SC Falco, JA Rice. Expression of de novo high-lysine a-helical coiled-coil proteins may significantly increase the accumulated levels of lysine in mature seeds of transgenic tobacco plants. Plant Mol Biol 34:15-29, 1997.

42. SC Falco, T Guida, M Locke, J Mauvais, C Sanders, RT Ward, P Webber. Transgenic canola and soybean seeds with increased lysine. Biotechnology 13: 577-582, 1995.

43. SC Falco. Chimeric genes and methods for increasing the lysine and threonine content of the seeds of plants. U.S. Patent 5,773,691, 1998.

44. C-F Chui, SC Falco. A new methionine-rich seed storage protein from maize. Plant Physiol 107:291, 1995.

45. DG Muench, M Ogawa, TW Okita. The prolamins of rice. In: PR Shewry, R Casey, eds. Seed Proteins. Boston: Kluwer Academic Publishers, 1999, pp 93108.

46. J Anthony, W Brown, D Buhr, G Ronhovde, D Genovesi, T Lane, R Yingling, K Aves, M Rosato, P Anderson. Transgenic maize with elevated 10 kD zein and methionine. In: WJ Cram, LJ De Kok, I Stulen, C Brunold, H Rennenberg, eds. Sulphur Metabolism in Higher Plants. Leiden, The Netherlands: Backhuys Publishers, 1997, pp 295-297.

47. RJ Youle, AHC Huang. Occurrence of low molecular weight and high cysteine containing albumin storage proteins in oilseeds of diverse species. Am J Bot 68:44-48, 1981.

48. C Ampe, J van Damme, LAB de Castro, MJAM Sampaio, M van Montagu, J Vanderkerckhove. The amino-acid sequence of the 2S sulfur-rich proteins from seeds of Brazil nut (Bertholletia excelsa H.B.K.). Eur J Biochem 159:597604, 1986.

49. SB Altenbach, KW Pearson, FW Leun, SSM Sun. Cloning and sequence analysis of a cDNA encoding a Brazil nut protein exceptionally rich in methionine. Plant Mol Biol 8:239-250, 1987.

50. SB Altenbach, KW Pearson, G Meecker, LC Staraci, SSM Sun. Enhancement of the methionine content of seed proteins by the expression of a chimeric gene encoding a methionine-rich protein in transgenic plants. Plant Mol Biol 13:513-522, 1989.

51. SB Altenbach, C-C Kuo, LC Staraci, KW Pearson, C Wainwright, A Georgescu, J Townsend. Accumulation of a Brazil nut albumin in seeds of transgenic canola results in enhanced levels of seed protein methionine. Plant Mol Biol 18:235-245, 1992.

52. A de S Concei§ao, A Van Vliet, E Krebbers. Unexpectedly high expression levels of a chimeric 2S albumin seed protein transgene from a tandem array construct. Plant Mol Biol 26:1001-1005, 1994.

53. I Saalbach, T Pickardt, F Machemehl, G Saalbach, O Schieder, K Müntz. A chimeric gene encoding the methionine-rich 2S albumins of the Brazil nut (Bertholletia excelsa H.B.K.) is stably expressed and inherited in transgenic grain legumes. Mol Gen Genet 242:226-236, 1994.

54. VMM Melo, J Xavier-Filho, MS Lima, A Prouvost-Danon. Allergenicity and tolerance to proteins from brazil nut (Bertholletia excelsa H.B.K.) Food Agric Immunol 6:185-195, 1994.

55. JA Nordlee, SL Taylor, JA Townsend, LA Thomas, RK Bush. Identification of Brazil nut allergen in transgenic soybeans. N Engl J Med 334:688-692, 1996.

56. L Molvig, LM Tabe, BO Eggum, AM Moore, S Graig, D Spencer, TJV Hig-gins. Enhanced methionine levels and increased nutritive value of seeds of transgenic lupins (Lupinus angustifolius L.) expressing a sunflower seed albumin gene. Proc Natl Acad Sei USA 94:8393-8398, 1997.

57. G Saalbach, R Jung, G Kunze, R Manteuffel, I Saalbach, K Müntz. Expression of modified legume storage protein genes in different systems and studies on intracellular targeting of Vicia faba legumin in yeast. Proceedings of the 49th Nottingham Easter School: Genetic Engineering of Crop Plants. London: Butterworth, 1990, pp 151-158.

58. G Saalbach, V Christov, R Jung, I Saalbach, R Manteuffel, G Kunze, K Bram-barov, K Müntz. Stable expression of vicilin from Vicia faba with eight additional single methionine residues but failure of accumulation of legumin with attached peptide segment in tobacco seeds. Mol Breed 1:245-258, 1995.

59. R Jung, MP Scott, Y-W Nam, TW Beaman, R Bassüner, I Saalbach, K Müntz, NC Nielsen. Processing and assembly of IIS seed storage globulins in vitro and in trangenic tobacco seeds: specificity of limited proteolysis and its role in IIS globulin assembly. Plant Cell 10:343-357, 1998.

60. T Katsube, N Kurisaka, M Ogawa, N Maruyama, R Ohtsuka, S Utsumi, F Takaiwa. Accumulation of soybean glycinin and its assembly with the glutelins in rice. Plant Physiol 120:1063-1073, 1999.

61. K Momma, W Hashimoto, S Ozawa, S Kawai, T Katsube, F Takaiwa, M Kito, S Utsumi, K Murata. Quality and safety evaluation of genetically engineered rice with soybean glycinin: analyses of the grain composition and digestibility of glycinin in transgenic rice. Biosci Biotechnol Biochim 63:314-318, 1999.

62. A De Clercq, M Vandewiele, J Van Damme, P Guerche, M Van Montagu, J Vanderkerckhove, E Krebbers. Stable accumulation of modified 2S albumin seed storage proteins with higher methionine contents in transgenic plants. Plant Physiol 94:970-979, 1990.

63. S Kjemtrup, EM Herman, MJ Chrispeels. Correct post-translational modification and stable vacuolar accumulation of phytohemagglutinin engineering to contain multiple methionine residues. Eur J Biochem 226:385—391, 1994.

64. JE Kinsella. Functional properties of soy proteins. J Am Oil Chem Soc 56: 242-258, 1979.

65. S Utsumi. Plant food protein engineering. Adv Food Nutr Res 36:89-208, 1992.

66. T Katsube, N Maruyama, F Takaiwa, S Utsumi. Food protein engineering of soybean proteins and the development of soy-rice. In: PR Shewry, JA Napier, PJ Davis, eds. Engineering Crop Plants for Industrial End Uses. London: Portland Press, 1998, pp 65-76.

67. F Takaiwa, T Katsube, S Kitagawa, T Hisaga, M Kito, S Utsumi. High level accumulation of soybean glycinin in vacuole-derived protein bodies in the endosperm tissue of transgenic tobacco seed. Plant Sci 111:39-49, 1995.

68. PR Shewry, AS Tatham, F Barro, P Barcelo, P Lazzeri. Biotechnology of bread-making: unravelling and manipulating the multi-protein gluten complex. Biotechnology 13:1185-1190, 1995.

69. PI Payne. Genetics of wheat storage proteins and the effect of allelic variation on breadmaking quality. Annu Rev Plant Physiol 38:141-153, 1987.

70. PR Shewry, NG Halford, AS Tatham. The high molecular weight subunits of wheat, barley and rye: genetics, molecular biology, chemistry and role in wheat gluten structure and functionality. In: BJ Miflin, ed. Oxford Surveys of Plant Molecular and Cell Biology. Vol 6. Oxford: Oxford University Press, 1989, pp 163-219.

71. PR Shewry, NG Halford, AS Tatham. The high molecular weight subunits of wheat glutenin. J Cereal Sci 15:105-120, 1992.

72. G Branlard, JC Autran, P Monneveaux. High molecular weight glutenin sub-units of durum wheat (T. durum). Theor Appl Genet 78:353-358, 1989.

73. W Seilmeier, H-D Belitz, H Wieser. Separation and quantitative determination of high-molecular-weight subunits of glutenin from different wheat varieties and genetic variants of the variety Sicco. Z Lebensm Unters Forsch 192:124129, 1991.

74. NG Halford, JM Field, H Blair, P Urwin, K Moore, L Robert, R Thompson, RB Flavell, AS Tatham, PR Shewry. Analysis of HMW glutenin subunits encoded by chromosome 1A of bread wheat (Triticum aestivum L.) indicates quantitative effects on grain quality. Theor Appl Genet 83:373-378, 1992.

75. AE Blechl, OD Anderson. Expression of a novel high-molecular-weight glutenin subunit gene in transgenic wheat. Nat Biotechnol 14:875-879, 1996.

76. E Altpeter, V Vasil, E Stoeger, IK Vasil. Accelerated production of transgenic wheat (Triticum aestivum L.) plants. Plant Cell Rep 16:12-17, 1996.

77. F Barro, L Rooke, F Bekes, P Gras, AS Tatham, R Fido, PA Lazzeri, PR Shewry, P Barcelo. Transformation of wheat with high molecular weight subunit genes results in improved functional properties. Nat Biotechnol 15:12951299, 1997

78. AE Blechl, HQ Le, OD Anderson. Engineering changes in wheat flour by genetic transformation. J Plant Physiol 152:703-707, 1998.

79. ML Alvarez, S Guelman, NG Halford, S Lustig, MI Reggiardo, N Ryabush-kina, P Shewry, J Stein, RH Vallejos. Silencing of HMW glutenins in transgenic wheat expressing extra HMW subunits. Theor Appl Genet 100:319-327, 2000.

80. GY He, L Rooke, S Steele, F Bekes, P Gras, AS Tatham, R Fido, P Barcelo, PR Shewry, PA Lazzeri. Transformation of pasta wheat (Triticum turgidum L. var. durum) with high-molecular-weight glutenin subunit genes and modification of dough functionality. Mol Breed 5:377-386, 1999.

81. L Rooke, F Bekes, R Fido, F Barro, P Gras, AS Tatham, P Barcelo, P Lazzeri, PR Shewry. Overexpression of a gluten protein in transgenic wheat results in highly elastic dough. J Cereal Sci 30:115-120, 1999.

82. CA McPhalen, I Svendsen, I Jonassen, MNG James. Crystal and molecular structure of chymotrypsin inhibitor 2 from barley seeds in complex with sub-tilisin Novo. Proc Natl Acad Sci USA 82:7242-7246, 1985.

83. FAO Amino Acid Content of Foods and Biological Data on Proteins. Rome: FAO, 1970.

84. I Koshiyama. Chemical and physical properties of a 7S protein in soybean globulins. Cereal Chem 45:394-404, 1968.

85. RA Badley, D Atkinson, H Hauser, D Oldani, JP Green, JM Stubbs. The structure, physical and chemical properties of the soybean protein glycinin. Biochim Biophys Acta 412:214-228, 1975.

86. JAD Ewart. Amino acid analyses of glutenins and gliadins. J Sci Food Agric 18:111-116, 1967.

87. PS Misra, ET Mertz. Studies on corn proteins. IX. Comparison of the amino acid composition of Landry-Moureaux and Paulis-Wall endosperm fractions. Cereal Chem 5:699-704, 1976.

88. JAD Ewart. Amino acid analyses of cereal flour proteins. J Sci Food Agric 18: 548-552, 1967.

89. U Singh, LVS Sastry. Studies on the proteins of the mutants of barley grain. 2. Fractionation and characterization of the alcohol-soluble proteins. J Agric Food Chem 25:912-917, 1977.

90. FAO Energy and Protein Requirements. FAO Nutritional Meeting Report Series No 52, WHO Technical Report Series No 552, Rome, 1973.

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