Enrichment of cereal protein lysine content by altered tRNA(lys) coding during protein synthesis

The world's major crops are deficient in lysine and several other amino acids essential for human and animal nutrition. Increasing the content of these amino acids in cereals, our major source of dietary energy, can help feed a global population whose reliance upon dietary protein is growing faster than crop yields. Here we document the heritable expression in rice, the world's major cereal crop, of tRNA(lys) species that introduce lysine at alternative codons during protein synthesis, resulting in a significant enrichment of the lysine content of proteins in rice seeds without changing the types or quantities of the seed storage proteins.     

Variation in the primary structure ofwaxy proteins (granule-bound starch synthase) in diploid cereals

The molecular weights ofwaxy proteins, by SDS-PAGE, and the N-terminal amino acid sequences of mature protein and of V8 protease-induced fragments were determined in diploid cereals. The homology of the primary structure was relatively high among cereals examined here, and there appeared to be a common sequence, V-F-V-G-A-E-M-A, in the vicinity of the N terminus. Based on the amino acid sequences, these cereals could be divided into two groups, including corn and rice in one and diploid wheat, fourAegilops species, rye, and barley in the other. In diploid wheat andAegilops species there were substitutions of amino acids in the primary structure. Variations of this sort suggest that the primary structure ofwaxy proteins would provide clues to the phylogenetic relations in the wheat group.     

水稻谷蛋白GluA-2基因在小麦胚乳中的表达(英文)

水稻(Oryza sativa L.)谷蛋白(Glutelin)约占水稻储藏蛋白总量的80％,谷蛋白赖氨酸含量较高并易于被人体消化吸收。为了提高小麦(Triticum aestivum L. )的营养品质,将水稻谷蛋白GluA-2基因的cDNA序列导入小麦栽培品种Bobwhite(T. aestivum cv. Bobwhite)。共轰击了600个小麦幼胚,经PCR和Southern杂交鉴定,共获得4棵转GluA-2基因小麦;SDS-PAGE分析表明,GluA-2基因在3棵转基因植株及其后代中表达,在1棵转基因植株中未表达,但其内源的高分子量麦谷蛋白亚基Bx7和By9含量显著降低,并且可遗传至T_代。     

水稻谷蛋白GluA-2基因在小麦胚乳中的表达

水稻(Oryza sativa L.)谷蛋白(Glutelin)约占水稻储藏蛋白总量的80%,谷蛋白赖氨酸含量较高并易于被人体消化吸收.为了提高小麦(Triticum aestivum L.)的营养品质,将水稻谷蛋白GluA-2基因的cDNA序列导人小麦栽培品种Bobwhite(T. aestivum cv.Bobwhite).共轰击了600个小麦幼胚,经PCR和Southern杂交鉴定,共获得4棵转GluA-2基因小麦;SDS-PAGE分析表明,GluA-2基因在3棵转基因植株及其后代中表达,在1棵转基因植株中未表达,但其内源的高分子量麦谷蛋白亚基Bx7和By9含量显著降低,并且可遗传至T1代.     

Free and bound amino acids and proteins in developing grains of rice with enhanced lysine/proteins

 Free amino acids were determined in developing seed of a rice mutant with enhanced grain lysine. This phenotype frequently has enhanced protein. Some free amino acids of developing seed are inversely related to the level of total amino acids in proteins of the mature grain. Amino acids that were enhanced in protein, including aspartic acid, threonine, methionine and lysine, were notably lower in the free amino-acid pool. Our conclusion is that mutant-developing grains process aspartate amino acids more rapidly than the controls. Conversely, arginine, valine and glutamic acid/glutamine accumulate as free amino acids with mutant/control ratios of 1.39, 1.29 and 1.12, respectively. Glutamic acid/glutamine in proteins of mature seeds is lower in the mutant than the control. ³H-lysine incorporation showed enhanced isotope incorporation into at least four proteins. One mutant protein was less actively labelled than analogous controls. The ³Hlysine pattern indicates processing modifications in this useful rice mutant. Received: 14 October 1996/Accepted: 8 November 1996     

Variability for protein and oil quality in Lupinus albus

Amino acid composition and fatty acid composition were determined on seed samples of a range of white lupin (Lupinus albus) cultivars and accessions grown in either of two environments.Variability between genotypes was found for lysine, arginine and glutamic acid content, but not for the concentrations of other amino acids. The deficiency in sulphurcontaining amino acids, typical of legume proteins, was evident, with methionine and cyst(e)ine totalling only 2.2% of the protein. Variability was limited, indicating that improvement by breeding would be impracticable. Lupinus albus differed slightly from other lupin species in amino acid composition, having higher levels of threonine, tyrosine and isoleucine, but a lower level of glutamic acid than both L. angustifolius and L. luteus. Four low-alkaloid lines of L albus each had higher lysine content than the high-alkaloid line, but ‘Kiev Mutant’, despite earlier claims, had a lysine level no higher than the other three low-alkaloid lines.Fatty acid composition of the seed oil varied considerably between genotypes. Oleic acid ranged from 43.6 to 54.4% and linolenic acid from 6.7 to 15.2%, these two fatty acids being negatively correlated at one site. Linoleic acid content varied between 17.2 and 26.9% and was not correlated with other fatty acids. Total oil content averaged 9.6% with little variability between lines.It is concluded that, relative to other lupin species, L. albus has a more favourable amino acid profile for its utilisation in cereal-based diets for animals, particularly if the energy source is wheat, which is deficient in threonine. The higher oil content would be an important energy benefit to such diets and may allow their protein/energy balance to be maintained at higher levels of incorporation of L. albus seed meal than is possible with other lupin species.     

Transgenic approaches to improve the nutritional quality of plant proteins

Summary Plant proteins, when used as dietary protein, are generally incomplete in nutrition due to their deficiency in several essential amino acids, for example, lysine and tryptophan in cereals and methionine and cysteine in legumes. Attempts to breed crops with increased levels of lysine and methionine have been less than satisfactory. Modern biotechnology offers alternative approaches for rectifying this nutrition deficiency. In the past decade, several transgenic strategies aimed at modifying the amino acid composition of plant proteins and enhancing the content of specific essential amino acid(s) for nutrition improvement have been developed and tested. These include synthetic proteins, modification of protein sequences, over-expression of heterologous or homologous proteins, and metabolic engineering of the free essential amino acid pool and protein sink. The progress and potential of these approaches and studies are reviewed. As plant proteins are the primary source of all dietary protein consumed by humans and animals and are inexpensive to produce in comparison with meat, improving their quality will make a significant contribution to our future food needs. The research and development in this area of interest is making promising progress towards this endeavor.     

Identification, cDNA cloning, and gene expression of soluble starch synthase in rice (Oryza sativa L.) immature seeds.

Three forms of soluble starch synthase were resolved by anion-exchange chromatography of soluble extracts from immature rice (Oryza sativa L.) seeds, and each of these forms was further purified by affinity chromatograph. The 55-, 57-, and 57-kD proteins in the three preparations were identified as candidates for soluble starch synthase by western blot analysis using an antiserum against rice granule-bound starch synthase. It is interesting that the amino-terminal amino acid sequence was identical among the three proteins, except that the 55-kD protein lacked eight amino acids at the amino terminus. Thus, these three proteins are products of the same gene. The cDNA clones coding for this protein have been isolated from an immature rice seed library in lambda gt11 using synthetic oligonucleotides as probes. The deduced amino acid sequence of this protein contains a lysine-X-glycine-glycine consensus sequence for the ADP-glucose-binding site of starch and glycogen synthases. Therefore, we conclude that this protein corresponds to a form of soluble starch synthase in immature rice seeds. The precursor of the enzyme contains 626 amino acids, including a 113-residue transit peptide at the amino terminus. The mature form of soluble starch synthase shares a significant but low sequence identity with rice granule-bound starch synthase and Escherichia coli glycogen synthase. However, several regions, including the substrate-binding site, are highly conserved among these three enzymes. Blot hybridization analysis demonstrates that the gene encoding soluble starch synthase is a single-copy gene in the rice genome and is expressed in both leaves and immature seeds. These results suggest that soluble and granule-bound starch synthases play distinct roles in starch biosynthesis of plant.     

Immunological relationships among the major seed proteins of cereals

The structural relationships among the major seed proteins of cereals was evaluated by Western blot analyses using antibodies raised against the wheat gliadin, rice glutelin acidic and basic subunits, and rice prolamine polypeptide. Consitent with the conservation of the primary sequences of these proteins, antibodies to the acidic and basic glutelin subunits cross-reacted with homologous polypeptides from oat as well as pea. The rice glutelin antibodies did not react with the major seed proteins from barley, rye, maize and sorghum. Antibodies raised against the acidic glutelin subunit reacted with the wheat glutenins but antibodies to the basic glutelin subunit did not. A comparison of the published primary sequences of a high molecular weight glutenin and rice glutelin showed little similarity except for a conserved peptide with the motif arg-gln-leu-gln-cys. The possible significance of this conserved element shared by these widely different proteins is discussed. Similar studies with the wheat gliadin antibody showed immunologically related components in plants of the subfamily Festucoideae except for rice. Antibodies raised against the rice prolamine recognized only the rice prolamine, indicating that this polypeptide was structurally distinct from other cereal prolamines. Overall, these results support and help clarify the evolutionary relationship of the cereals.     

Amino Acid and Peptide uptake in the scutella of germinating grains of barley, wheat, rice, and maize

Scutella separated from germinating grains of barley (Hordeum vulgare L.), wheat (Triticum aestivum L.), rice (Oryza sativa L.), and maize (Zea mays L.) took up the four amino acids and the three peptides tested from incubation media. The uptake of amino acids by wheat scutella was similar to that of barley scutella and was via at least four uptake systems: two nonspecific amino acid uptake systems, one system specific for proline, and another system specific for basic amino acids. The scutellum of rice apparently has two nonspecific systems and a system specific for the basic amino acids, but the proline-specific system is lacking. The scutellum of maize seems to have the same systems as the scutellum of rice, but one (or both) of the nonspecific systems differs from that of the other species studied in taking up arginine only slowly. No great differences were observed in the uptake of peptides in the four species studied. The rates of uptake of different amino acids and peptides were of the same order of magnitude in the four cereals. The fact that carboxypeptidase activities in the endosperms of wheat and barley are 20-to 100-fold higher than those in rice and maize, does thus not seem to be reflected in the uptake properties of the scutella.     

黄皮种子蛋白质营养价值的评价研究

在对黄皮种子氨基酸的组成及蛋白质的含量进行分析的基础上,应用模糊识别法和氨基酸比值系数法,对其营养价值进行了全面评价,并与8种植物种子蛋白质进行对照比较。结果表明:黄皮种子(干品)蛋白质含量为8.625%,含有17种氨基酸,种类齐全,其含量为762.2 mg.g-1蛋白质,必需氨基酸(EAA)占总氨基酸量的35.5%,第一限制性氨基酸为含硫氨基酸(M et+Cys),贴近度为0.8536,营养价值与高粱米、西瓜子等接近。     

Correlation of carnitine levels to methionine and lysine intake

Plasma carnitine levels were measured in two alternative nutrition groups--strict vegetarians (vegans) and lactoovovegetarians (vegetarians consuming limited amounts of animal products such as milk products and eggs). The results were compared to an average sample of probands on mixed nutrition (omnivores). Carnitine levels were correlated with the intake of essential amino acids, methionine and lysine (as substrates of its endogenous synthesis), since the intake of carnitine in food is negligible in the alternative nutrition groups (the highest carnitine content is in meat, lower is in milk products, while fruit, cereals and vegetables contain low or no carnitine at all). An average carnitine level in vegans was significantly reduced with hypocarnitinemia present in 52.9% of probands. Similarly, the intake of methionine and lysine was significantly lower in this group due to the exclusive consumption of plant proteins with reduced content of these amino acids. Carnitine level in lactoovovegetarians was also significantly reduced, but the incidence of values below 30 micromol/l was lower than in vegans representing 17.8% vs. 3.3% in omnivores. Intake of methionine and lysine was also significantly reduced in this group, but still higher compared to vegans (73% of protein intake covered by plant proteins). Significant positive correlation of carnitine levels with methionine and lysine intake in alternative nutrition groups indicates that a significant portion of carnitine requirement is covered by endogenous synthesis. Approximately two thirds of carnitine requirement in omnivores comes from exogenous sources. The results demonstrate the risks of alternative nutrition with respect to the intake of essential amino acids, methionine and lysine, and with respect to the intake and biosynthesis of carnitine.     

Thioredoxin and germinating barley: targets and protein redox changes

The endosperm and embryo of barley ( Hordeum vulgare L.) grain were investigated to relate thioredoxin h and disulfide changes to germination and seedling development. The disulfide proteins of both tissues were found to undergo reduction following imbibition. Reduction reached a peak 1 day earlier in the embryo than in the endosperm, day 1 vs. day 2. The profile in both cases resembled those observed with wheat and rice, i.e., the reduction of the storage proteins increased initially and then declined during the period of seedling growth. The extent of the increase in reduction observed with barley endosperm was, however, less pronounced than with the other cereals. Also, unlike wheat and rice, the storage proteins of the endosperm were highly reduced in the dry seed and the sulfhydryl content of glutelins showed no appreciable change during this period. The relative abundance of thioredoxin h during germination and early seedling growth differed in the embryo and endosperm: a progressive decrease in the endosperm (as seen with wheat) vs. an increase in the embryo. Thioredoxin h was found in the major seed tissues in characteristic forms. Three forms were found in the scutellum and aleurone, whereas two, which may represent isoforms, were identified in the root and the shoot. Using a recently developed strategy based on two-dimensional gel electrophoresis, several proteins were identified as specific targets for thioredoxin in the embryo following oxidation with H(2)O(2), among them barley embryo globulin 1, peroxiredoxin and acidic ribosomal protein P(3). The results confirm earlier findings with the endosperm of other cereals and extend the importance of thioredoxin-linked redox change to the germinating embryo for functions that potentially include dormancy, protection against reactive oxygen species, translation and the mobilization of storage proteins.     

水稻、小麦、油菜和烟草细胞质雄性不育系统中组分Ⅰ蛋白的比较分析

组分Ⅰ蛋白(RuBP羧化酶/加氧酶)的生物合成系由叶绿体基因和细胞核基因共同控制,所以,被作为研究细胞质遗传的标记。本实验用免疫化学和氨基酸成分分析等方法,对水稻(珍汕97)、小麦(繁7)、油菜(湘矮早)和烟草(G28)的细胞质雄性不育系及其保持系的组分Ⅰ蛋白作了比较,同时对不同作物的组分Ⅰ蛋白也作了免疫鉴定。结果表明,细胞质雄性不育系及其保持系的组分Ⅰ蛋白差异不大,但是,四种不同作物的组分Ⅰ蛋白之间有明显差异。