Seed Storage Glutelin α-2 Subunit Lacking Mutants in Rice

Nine rice Oryza sativa L.） mutant lines lacking the seed storage glutelin α-2 subunit were obtained from the progenies of fertilized egg cells treated with N-methy-N-nitrosourea (MNU). The mutants could be classified into three types: the α-1 subunit increased type (α-1H/α-2L), decreased the β-2 subunit decreased type (β-2L/α-2L) and the α-3 subunit increased type (α-3H/α-2L) according to their SDS-PAGE profiles. Two-dimensional electrophoresis analysis revealed that all of the mutants lacked a polypeptide of pI 6.71/α-2, while new polypeptides of pI 6.50/α-1 and pI 6.90/α-3 formed in α-1H/α-2L and α-3H/α-2L mutants respectively. Although the β-2L/α-2L mutants did not form new polypeptide, their pI 8.74/β-2 polypeptide was also decreased, suggesting that the two polypeptides decreased in β-2L/α-2L mutants might derive from the same glutelin precursor. These mutant lines are very useful in studying genetic characterisation,the mechanism of genetic regulation on biosynthesis, gene function and proteomics of rice seed storage glutelin.     

Inheritance of alleles for glutelin alpha-2 subunit genes in rice and identification of their corresponding cDNA clone

Rice glutelins consist of acidic (alpha) and basic (beta) subunits which are further separated into three polypeptide components assigned as alpha-1, alpha-2, and alpha-3 subunit components and beta-1, beta-2 and beta-3 subunit components. Nine rice mutant lines with a decreased amount of the glutelin alpha-2 subunit component (alpha-2L) were obtained by screening about 6,800 potential mutant lines derived from the fertilized egg treatment with N-methyl-N-nitrosourea (MNU) using the SDS-PAGE method. The mutants were classified into three types of the increased alpha-1 subunit (alpha-1H/alpha-2L), the decreased beta-2 subunit (beta-2L/alpha-2L) and the increased alpha-3 subunit (alpha-3H/alpha-2L) represented by EM278, CM1707 and EM659, respectively. Iso-electric focus (IEF) analysis revealed that all of the mutants had an extremely low amount of a polypeptide with a 6.71 pI value, whereas a polypeptide with either a 6.50 pI value or with a 6.90 pI value increased significantly in alpha-1H/alpha-2L mutants or in alpha-3H/alpha-2L mutants, respectively. The beta-2L/alpha-2L mutants had a decreased amount of a basic polypeptide with a 8.74 pI value. Genetic analysis revealed that the three types of mutants were controlled by a single incomplete dominant gene respectively, and the three are alleles. The gene was temporarily named glu4, which was found to be located on chromosome 1 linked with the eg and spl6 genes. Two-dimensional electrophoresis analysis revealed that the glu4 encoded polypeptides of pI 6.71/alpha-2 and pI 8.74/beta-2. Amino acid sequence analysis suggested that the mutated acidic polypeptide was the product of a GluA subfamily gene. Northern and RT-PCR analyses revealed that glu4 corresponded to the GluA-1 gene.     

新的水稻谷蛋白α—1亚基缺失突变体

从水稻受精卵MNU处理后代中获得4个谷蛋白α－1亚基缺失突变品系。SDS－PAGE和IEF分析表明这些突变体在共同缺失1条pI6.82多肽的同时,或形成新的多肽,或其他多肽表现量增加,这些突变体是由结构基因控制的,IEF分析同时显示2条多肽pI6.82和pI8.58源自同一条谷蛋白前驱体。这4个突变体对于改良水稻谷蛋白品质、研究谷蛋白生物合成遗传调控机制以及揭示谷蛋白基因功能是不可多得的研究材料。     

Biochemical and molecular characterization of a rice glutelin allele for the GluA-1 gene

The rice ( Oryza sativa L.) mutant of glu4a, lacking the glutelin alpha-2 subunit while the alpha-1 subunit increased (alpha-1H/alpha-2L), was used in this study. Two-dimensional electrophoresis analysis revealed that the mutant lacked the polypeptide pI6.71/alpha-2 encoded by glu4 while forming a new polypeptide of pI6.50/alpha-1. Experiments were conducted to identify the relationships between the mutated polypeptides of the mutant and to illustrate the mutation mechanism of the allele. Peptide mapping and amino-acid sequence analyses revealed that the newly formed glu4a encoded polypeptide pI6.50/alpha-1 of high homology with the deleted pI6.71/alpha-2 polypeptide which was encoded by glu4 (GluA-1). The nucleotide sequence revealed that the iso-electric point variation of the pI6.50/alpha-1 polypeptide was caused by a point mutation with nucleotide replacement at the variable region of the gene. These results suggested the possibility of altering glutelin quality by using single gene mutation.     

Biosynthesis of storage proteins in developing rice seeds

Sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis of the starchy endosperm protein of rice (Oryza sativa L. Japonica cv Koshihikari) during seed development confirmed that storage protein begins to accumulate about 5 days after flowering. Two polypeptide groups, 22 to 23 and 37 to 39 kilodaltons, the components of glutelin, the major storage protein in rice seed, appeared 5 days after flowering. A 26-kilodalton polypeptide, the globulin component, also appeared 5 days after flowering. Smaller polypeptides (10- to 16-kilodaltons) including prolamin components, appeared about 10 days after flowering. In contrast, the levels of the 76- and 57-kilodalton polypeptides were fairly constant throughout seed development. Transmission electron microscopy and fractionation by sucrose density gradient centrifugation of the starchy endosperms at various stages of development showed that protein body type II, the accumulation site of glutelin and globulin, was formed faster than protein body type I, the accumulation site of prolamin.

The 57-kilodalton polypeptide but not the glutelin subunits was labeled in a 2-hour treatment with [¹⁴C]leucine given between 4 and 12 days after flowering to developing ears. In vivo pulse-chase labeling studies showed the 57-kilodalton polypeptide to be a precursor of the 22 to 23 and 37 to 39 kilodalton subunits. The 57-kilodalton polypeptide was salt-soluble, but the mature glutelin subunits were almost salt insoluble.

In vitro protein synthesis also showed that the mRNAs directly coding the 22 to 23 and 37 to 39 kilodalton components were absent in developing seeds and that the 57-kilodalton polypeptide was the major product. Thus, it was concluded that the two subunits of rice glutelin are formed through post-translational cleavage of the 57-kilodalton polypeptide.

     

Mutants for rice storage proteins

Summary To obtain genetic materials to breed qualitatively improved rice storage proteins, we screened about 3,000 mutant lines induced by the treatment of rice fertilized egg cell with N-methyl-N-nitrosourea (MNU). The screening was performed by comparing the profiles of sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) with that of the original variety, Kinmaze, especially focussing on the changes in polypeptides present in two kinds of protein bodies, PB-I and PB-II. We selected 17 mutant lines and classified them into 4 types on the basis of variations of the relative contents of the polypeptides. Determination of extracted protein in the starchy endosperm of the mutants revealed changes in the content of prolamin and glutelin but not globulin. In some mutants there was marked accumulation of 57 kDa polypeptide concomitant with the remarkable reduction of glutelin subunits. Treatment of the fertilized egg cell with MNU was found to be an effective method to induce mutations for storage proteins in protein bodies of rice.     

Mutants lacking glutelin subunits in rice: mapping and combination of mutated glutelin genes

Nine mutant lines lacking glutelin subunits were selected from M₂ seeds of about 10000 M₁ plants mutagenized with gamma rays or EMS and from 1400 mutant lines selected originally for morphological characters. There were three types of mutants, one line lacking the largest subunit among four minor bands of glutelin acidic subunits (Type 1), five lines lacking the second largest subunit band (Type 2), and three lines lacking the third largest subunit band (Type 3). Mutants lacking the smallest subunit band were not found. Type 1 lacked 2 of the 10 spots of glutelin acidic subunits separated by two-dimensional electrophoresis and 1 of the 11 spots of the 57-kDa glutelin precursor. Type 2 lacked 2 spots of acidic subunits and 1 spot of the 57-kDa glutelin precursor, and had low amounts of 1 of the 8 spots of glutelin basic subunits. Type 3 mutants lacked each of 1 spot of the acidic subunits and glutelin precursor and had low amount of 1 spot of the basic subunits. Genetic analysis of the mutated genes showed that these mutant characters were controlled by single recessive genes named glu-1, glu-2, and glu-3, respectively. Mutated genes of different lines of the same type were found to be at the same locus. RFLP analysis of F₂ plants between the mutant lines and cv `Kasalath' indicated that glu-1 is on chromosome 2, glu-2 on chromosome 10, and glu-3 on chromosome 1. These mutant genes were combined by crossing, and a line lacking the 3 minor bands of the glutelin acidic subunits was developed. However, the total glutelin content of this line was not remarkably reduced, showing a only 13% decrease. Received: 1 April 1996 / Accepted: 14 June 1996     

Mutants having a low content of 16-kDa allergenic protein in rice (Oryza sativa L.)

Summary Rice mutants containing low levels of the 16-kDa allergenic protein, which is the main allergen in the rice grain for patients of atopic dermatitis due to the intake of rice, were screened, and 4 independent mutant lines with small amounts of this protein were found by SDS gel electrophoresis and immunoblot analysis. These mutants were grouped into two types. Two mutant lines, 85KG-4 and 86RG-18, contained low levels of the 16k-Da and 26-kDa polypeptides and a high level of the 57-kDa polypeptide. The 16-kDa polypeptide content of these mutants was about half that of the original cultivars. Homozygous lines were developed, and these showed normal growth and seed set. The other 2 mutant lines, 87KG-970 and 89WPKE-149, showed traces of the 16-kDa and 26 kDa polypeptides and contained a high level of the 13 kDa polypeptide. The homozygous plants of this type were sterile. All of the mutant lines had floury endosperms. Genetic analysis suggested that low 16-kDa polypeptide content is controlled by a single recessive gene. Attempts to separate of the genes for low 16-kDa polypeptide content and floury endosperm by crossing with the original cultivar were unsuccessful, suggesting the tight linkage of these two genes or pleiotropism of a single mutated gene. The relationship between low 16-kDa polypeptide content and the floury character and the possible use of the mutant as a low allergen rice are discussed.     

P61 Protein from a Male Sterile Mutant of Rice is an Isoform of the Chloroplast ATPase β Subunit

P61 was a protein identified from chloroplasts of Nongken 58S, a male sterile mutant of rice (Oryza sativa L. ssp. japonica). Microsequence analysis has revealed that its N-terminal sequence was identical to N-termini of ATPase β subunits of chloroplasts from rice and barley. The antiserum produced using ATPase β subunit from maize specifically recognized P61. P61 had the same molecular weight as the chloroplast ATPase β subunit of wild-type rice “Nongken 58”, but had different isoelectric point (pI) from this β　subunit. P61 was more basic than this β subunit. Thus, P61 would be identified as an isoform of the chloroplast ATPase β subunit of rice, named β1. Genetic analysis with a F2 population of Nongken 58SדNongken 58” showed that a single recessive genic gene regulated the formation of β1.     

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.     

水稻种子贮藏谷蛋白的微细异质性

利用灵敏的等聚焦与SDS－PAGE合的双向电泳分析方法,从水稻（Oryza sativa L.)种子贮藏谷蛋白中至少可以分离为13条酸性和19条碱性多 肽,依据谷蛋白多肽的表现量推测,水稻谷蛋白主要由约6个主效基因控制,肽图谱与N－端氨基酸序列分析可清晰将谷蛋白酸性多肽分为两组,此两组恰好与谷蛋白GluA和GluB两个cDNA克隆组相吻合。     

水稻种子贮藏谷蛋白的改良电泳分析法

利用15％－25％丙烯酰胺梯度凝胶的SDS－PAGE分析法可将水稻种子贮藏谷蛋白分离为3个酸性（α）亚基和3个碱性（β）亚基,通过调节两性电解质比例对现有等用点了和焦电泳分析法进行改良,可将谷蛋白酸性亚基和碱性亚基分别分划为13和14条多肽带,将上述两种方法结合起来的双向电泳分析法可以高清晰度地离析谷蛋白并获得单一多肽,此改良的电泳分析系统有助于确定水稻谷蛋白变异及谷蛋白的生化研究。     

An analysis of the subunit structure of the crystalloid protein complex from castor bean endosperm

Chromatographic and electrophoretic studies have shown that the subunits of the crystalloid protein, isolated from mature castor bean (Ricinus communis L. cv Hale) seed endosperm protein bodies, are heterogeneous with molecular weights in the range 49 to 53.5 kilodaltons (kD), and are quantitatively in unequal amounts. Each subunit comprises an αβ polypeptide pair which are reduced by 2-mercaptoethanol in two subgroups with molecular weights in the 29 to 34 kD and 20.5 to 23.5 kD ranges. Subunits and corresponding polypeptide pairs are also seen to be heterogeneous in pI following isoelectric focusing. In general, large polypeptides are acidic (pI 4.8-6.2) and small polypeptides basic (pI 7.4-9.4), although overlap of some isoelectric isomers does occur, notably in polypeptides derived from subunits which are quantitatively present in smaller amounts.     

Enhanced methionine and cysteine levels in transgenic rice seeds by the accumulation of sesame 2S albumin

A chimeric gene encoding a precursor polypeptide of sesame 2S albumin, a sulfur-rich seed storage protein, was expressed in transgenic rice plants under the control of the glutelin promoter with the aim of improving the nutritive value of rice. Rice grains harvested from the first generation of ten different transformed lines inherited the transgene, and the accumulated sesame 2S albumin was presumably processed correctly as its mature form in sesame seed. This transgene was specifically expressed in maturing rice seeds with its encoded sesame 2S albumin exclusively accumulated in the seeds. The crude protein content in rice grains from five putative homozygous lines was increased by 0.64-3.54%, and the methionine and cysteine contents of these transgenic rice grains were respectively elevated by 29-76% and 31-75% compared with those of wild-type rice grains.     

Subunit E isoform 1 of vacuolar H+-ATPase OsVHA enables post-Golgi trafficking of rice seed storage proteins

Dense vesicles (DVs) are Golgi-derived plant-specific carriers that mediate post-Golgi transport of seed storage proteins in angiosperms. How this process is regulated remains elusive. Here, we report a rice (Oryza sativa) mutant, named glutelin precursor accumulation8 (gpa8) that abnormally accumulates 57-kDa proglutelins in the mature endosperm. Cytological analyses of the gpa8 mutant revealed that proglutelin-containing DVs were mistargeted to the apoplast forming electron-dense aggregates and paramural bodies in developing endosperm cells. Differing from previously reported gpa mutants with post-Golgi trafficking defects, the gpa8 mutant showed bent Golgi bodies, defective trans-Golgi network (TGN), and enlarged DVs, suggesting a specific role of GPA8 in DV biogenesis. We demonstrated that GPA8 encodes a subunit E isoform 1 of vacuolar H⁺-ATPase (OsVHA-E1) that mainly localizes to TGN and the tonoplast. Further analysis revealed that the luminal pH of the TGN and vacuole is dramatically increased in the gpa8 mutant. Moreover, the colocalization of GPA1 and GPA3 with TGN marker protein in gpa8 protoplasts was obviously decreased. Our data indicated that OsVHA-E1 is involved in endomembrane luminal pH homeostasis, as well as maintenance of Golgi morphology and TGN required for DV biogenesis and subsequent protein trafficking in rice endosperm cells.

A subunit of the vacuolar H⁺-ATPase regulating endomembrane luminal pH homeostasis plays a fundamental role in post-Golgi trafficking of rice seed storage proteins.     

Knockout of glutelin genes which form a tandem array with a high level of homology in rice by gamma irradiation

In the course of evolution, a gene is often duplicated in tandem, resulting in a functional redundancy. The analysis of function of these genes by raising double mutant might be difficult because they are very tightly linked. We described here a mutant of such a tandem duplicated gene. glu1 is a gamma-ray-induced rice mutant, which lacks an acidic subunit of glutelin, a major seed storage protein. We found that glu1 harbors a 129.7-kb deletion involving two highly similar and tandem repeated glutelin genes, GluB5 and GluB4. The deletion eliminated the entire GluB5 and GluB4 gene except half of the first exon of GluB5. GluB5 and GluB4 have the same amino acid sequence in the acidic subunit, suggesting that only the mutation involving both GluB5 and GluB4 results in the lack of the glutelin acidic subunit deleted in glu1. Our finding suggests that gamma-ray can be an effective mutagen to analyze tandem repeated and functionally redundant genes.     

Electrophoretic profiles and amino acid composition of rice endosperm proteins of a mutant with enhanced lysine and total protein after backcrosses for germplasm improvements

 Seed storage proteins from in vitro-derived rice mutants improved by several backcrosses to ‘Calrose 76’ and BC₂ and BC₃ were characterized for changes in five different solubility classes. Albumins, rsealb (water-soluble globulins), true salt-soluble globulins, prolamins and glutelins were SDS-PAGE separated in a single dimension, and some two-dimensionally, to identify protein modifications. The genetic transmission of the enhanced-lysine mutants in backcrosses and the linkage of lysine with grain chalkiness were confirmed. Advanced lines had altered globulin profiles similar to those of unimproved lines. Chalky/ enhanced-lysine phenotypes had similar prolamin and glutelin profiles in the mutant and controls at the same protein level. Mutants had increased levels of globulins at 50 kDa and 33 kDa but had substantially less protein at 25 kDa than the controls. High protein in the mutant contributed to an increase in prolamins and the major storage proteins in both the globulins and glutelins. A significant decrease in low-molecular-weight, 15- to 18-kDa albumins was associated with the chalky/enhanced-lysine mutant phenotype. Two proteins in the 15- to 18-kDa group were amino acid sequenced, and database comparisons identified these proteins as allergens. Advanced lines downregulated for allergens and with enhanced-lysine/protein but with normal fertility and seed weight should be useful in breeding programs for nutritional quality. Received: 14 October 1996 / Accepted: 8 November 1996     

Starch biosynthesis in rice endosperm requires the presence of either starch synthase I or IIIa

Starch synthase (SS) I and IIIa are the first and second largest components of total soluble SS activity, respectively, in developing japonica rice (Oryza sativa L.) endosperm. To elucidate the distinct and overlapping functions of these enzymes, double mutants were created by crossing the ss1 null mutant with the ss3a null mutant. In the F(2) generation, two opaque seed types were found to have either the ss1ss1/SS3ass3a or the SS1ss1/ss3ass3a genotype. Phenotypic analyses revealed lower SS activity in the endosperm of these lines than in those of the parent mutant lines since these seeds had different copies of SSI and SSIIIa genes in a heterozygous state. The endosperm of the two types of opaque seeds contained the unique starch with modified fine structure, round-shaped starch granules, high amylose content, and specific physicochemical properties. The seed weight was ～90% of that of the wild type. The amount of granule-bound starch synthase I (GBSSI) and the activity of ADP-glucose pyrophosphorylase (AGPase) were higher than in the wild type and parent mutant lines. The double-recessive homozygous mutant prepared from both ss1 and ss3a null mutants was considered sterile, while the mutant produced by the leaky ss1 mutant×ss3a null mutant cross was fertile. This present study strongly suggests that at least SSI or SSIIIa is required for starch biosynthesis in rice endosperm.