Extraction and composition of rice endosperm glutelin

“Crude” glutelin was prepared from milled rice (Oryza sativa) flour by sequential extraction of the albumin-globulin fraction with 0.5 M NaCl and prolamin with 70% ethanol-0.6% β-mercaptoethanol. The solvent, 0.5% sodium dodecyl sulphate (SDS)-0.6% β-mercaptoethanol, extracted 91% of the endosperm glutelin without gelatinizing starch granules, whereas chaotropic solvents such as urea and guanidine caused extensive gelatinization. The S-cyanoethyl glutelin (Ce-glutelin) prepared by SDS extraction of the “crude” glutelin (9.5% protein) of IR480-5-9 rice gave three major subunits with MW 38000, 25000 and 16000 in the ratio 2:1:1 as determined by SDS polyacrylamide gel electrophoresis. A similar preparation from “crude” glutelin of a lower protein containing rice had the corresponding subunits in the ratio of 16:3:1. The MW 38000 subunit was unique to glutelin and was not present in C3-albumin-globulin or prolamin; the subunits were only partially purified by SDS Sephadex G-150 gel-filtration. The C3-glutelin was also prepared from a crude glutelin-prolamin preparation from IR480-5-9 by NaOH extractions followed by precipitation at pH 10 and ethanol extraction of the precipitate (C3-glutelin). This preparation had the same three major subunits and in the same ratio as C3-glutelin prepared by the SDS method. The subunits of the former preparation were separated by carboxymethyl Sephadex C-50 chromatography; the MW 38000 subunit eluted between pH 6.2–8.5, the MW 25000 in an impure state at pH values above 9, and the MW 16000 subunit was eluted at pH 8.6—9.2. Amino acid composition of the Ce-glutelin preparations were similar to each other. The MW 38000 and 16000 subunits had lower lysine contents than whole C3-glutelin, whereas the MW 25000 subunit had a higher lysine content.     

The purification and partial amino acid sequence of a polypeptide from the glutelin fraction of rice grains; homology to pea legumin

The glutelin fraction was extracted from grain meals of rice (Oryzea sativa) with 50 mM Tris-HCl buffer (pH 8.8) containing 6 M urea and 10 mM 2-mercaptoethanol. Polypeptides of glutelin were separated and purified by ion-exchange chromatography under denaturing conditions. Analysis by two-dimensional gel electrophoresis showed that 2 major polypeptides of the rice glutelin fraction, M_r 36 000 and 22 000, were linked in disulphide bonded pairs containing one M_r 36 000 and one M_r 22 000 subunit. A partial amino acid sequence of the purified M_r 22 000 glutelin subunit showed it to be homologous to the β-subunit of pea legumin, a storage protein which also contains disulphide-linked subunit pairs (M_r 38 000 and M_r 22 000). It is therefore proposed that the major component of rice glutelin is a legumin-like protein.     

Changes in salt-soluble proteins of rice during grain development

Salt-soluble proteins, albumin and globulin, were prepared from dehulled rice (Oryza sativa L., line IR1541-76-3) during grain development. Albumin and globulin progressively increased during grain development up to about 12 days after flowering (DAF) and then decreased slightly during grain desiccation. Free amino N was maximum at 10 DAF. Total protein and glutelin-prolamin (by difference) continued to increase up to 20 DAF. Aminogram of total protein and globulin showed a progressive decrease in lysine and threonine among the essential amino acids. Albumin showed a similar trend except for the lesser change in lysine content. Disc gel electrophoresis showed a maximum of four major and six minor protein bands for albumin and only one major and three minor bands for globulin. Sodium dodecyl sulfate-gel electrophoresis revealed three major polypeptide subunits for albumin with MW of 11 000, 8 500 and 16 000, and two for globulin with MW of 20 000 and 12 000.     

Comparison of the protein fractions of finger millet

Sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) has been employed to resolve protein subunits of finger millet (Eleusine coracana) varieties according to their MW. These studies have established that varietal differences exist in the protein composition of finger millet varieties. The MW distribution of the protein subunits in the albumin-globulin, prolamin and glutelin fractions show many differences between the parental and cross-bred varieties and these differences are greater in the albumin-globulin and glutelin fractions than in the prolamin fraction. The amino acid compositions of the protein fractions show some differences between varieties.     

Properties of prolamin in mature and developing rice grain

A procedure was developed for preparing lipid- and phenol-free prolamin directly from IR480-5-9 milled rice (Oryza sativa L.).The preparation consisted mainly of one protein band on analytical and SDS-polyacrylamide disc gel electrophoresis with subunit MW of 17000 and a minor fraction with subunit MW 23000. The prolamin eluted as a single peak on SDS-Sephadex G-75 gel filtration and on DEAE-cellulose column chromatography. Prolamin was poor in lysine, histidine, cystine, and methionine but rich in glutamic acid, tyrosine and proline. In dehulled developing grain of two different rices, changes in the aminogram of the prolamin fraction coincided with the start of endosperm protein body synthesis and the appearance from 7 days after flowering of a second prolamin subunit with MW 23 000.     

The suppression of the glutelin storage protein gene in transgenic rice seeds results in a higher yield of recombinant protein

Glutelin is a major seed storage protein, accounting for 60?C80?% of the total endosperm protein content in rice. To test whether we could augment the expression of an introduced recombinant protein in rice by suppressing the glutelin gene, we generated transgenic glutelin RNAi (glu RNAi) rice seeds. RNA gel blot analyses confirmed that the endogenous glutelin gene was severely suppressed in these transgenic rice lines. RT-PCR analysis further revealed that all the members of glutelin multigene family were downregulated. Transgenic glu RNAi rice seeds expressing a recombinant red fluorescent protein (RFP) showed stronger fluorescence than seeds transformed with the RFP gene only. Western blot analysis further revealed that the relative accumulation of RFP in glu RNAi seeds was twofold higher than that in the RFP-only transgenic seeds. These results suggest that RNAi targeting of an endogenous storage protein could be of great utility in obtaining higher transgene expression in genetically engineered rice and other plant lines.     

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 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     

Influence of opaque-2 and floury-2 genes on formation of proteins in particulates of corn endosperm

Protein-rich subcellular particulates were isolated by zonal centrifugation from homogenates of endosperms of normal, opaque-2, and floury-2 mutant corn (Zea maize) kernels at different stages of development. In early stages the high lysine mutants vary from normal corn by greater production of a glutelin protein not associated with the matrix. This protein is high in lysine and may become a component of matrix glutelin at later stages of maturity. Differences in size and structure of zein-rich protein bodies were observed in the mutant strains when compared with normal corn. Enhanced production of nonmatrix glutelin as well as the reduction in synthesis of lysine-deficient zein is responsible for the improved lysine content of the mutant endosperms at early stages of development.     

Urease of Spirulina maxima

Urease (EC 3.5.1.5) was purified from Spirulina maxima by ammonium sulfate precipitation, DEAE-cellulose chromatography and gel filtration on Sephadex G-200. The enzyme had maximum activity at pH 8.7, a K_m for urea of 0.12 mM and a MW of ca 232 000. A MW of 38 000 was determined for the subunits. The enzyme was inactivated by p-hydroxymercuribenzoate.     

Accumulation of Soybean Glycinin and Its Assembly with the Glutelins in Rice

Saline-soluble glycinins and insoluble glutelins are the major storage proteins in soybean (Glycine max) and rice (Oryza sativa), respectively. In spite of their differences in solubility properties, both proteins are members of the 11S globulin gene family based on their similarities in primary sequences and processing of the coded protein. Wild-type and methionine-modified glycinin coding sequences were expressed in transgenic rice plants under the control of the rice glutelin GluB-1 promoter. Glycinins were specifically synthesized in the endosperm tissue and co-localized with glutelins in type II protein bodies. They assembled into 7S and 11S species, similar to what was observed in developing soybean seeds. This pattern was quite different from that displayed by the rice glutelins in untransformed plants, in which processed subunits sedimenting at 2S were apparent. In glycinin-expressing transgenic plants, however, glutelins were observed sedimenting at 7S and 11S with lesser amounts in the 2S region. A portion of the glycinins was also found associated in the insoluble glutelin fraction. Renaturation experiments suggested that the hybrid glycinin-glutelin oligomers were formed through specific interactions. Overall, these results indicate that despite significant differences in the assembly of soybean glycinin and rice glutelin, both proteins can assemble with each other to form soluble hexameric oligomers or insoluble aggregates.     

Changes in protein fractions and leucine-[14C] incorporation during Sorghum grain development

Incorporation of leucine and changes in different protein fractions have been studied during Sorghum grain development. Most of the label from the injected leucine-[¹⁴C] was found in glutelin and residue fraction towards later stages of maturity. The label in albumin, globulin and prolamin decreased with a concomitant increase in label in glutelin and residue proteins. The concentration of lysine, aspartic acid and glycine decreased while that of leucine, proline, alanine, tyrosine, phenylalanine, and cystine increased during grain development. Increase in serine, methionine, valine and isoleucine was only marginal. The proportion of glutamic acid was high at all stages of grain development. Glutelin fraction resolved into two peaks on gel chromatography, only one of which with higher MW was labelled, while in albumin both the peaks were found to be labelled. Tannin content also increased during grain development.     

Structural Relationship among the Rice Glutelin Polypeptides

When the glutelin protein fraction of rice (Oryza sativa L.) seeds was fractionated by sodium dodecyl sulfate polyacrylamide gel electrophoresis, three size classes of proteins, 51 kilodaltons (kD), 34 to 37 kD, and 21 to 22 kD, as well as a contaminating prolamine polypeptide of 14 kD were detected. Antibodies were raised against these proteins and employed in studies to determine whether a precursor-product relationship existed among the glutelin components. Antibodies of the 34 to 37 kD and 21 to 22 kD polypeptides strongly reacted with the 51 kD protein, and conversely, anti-51 kD protein cross reacted with both of the putative subunits. Immunoprecipitation of in vitro translated products resulted in the synthesis of only the precursor form, indicating that the α and β subunits are proteolytic products of the 51 kD precursor protein. The poly(A)⁺ RNA directed in vitro translated product was about 2000 daltons larger than both the authentic glutelin precursor and the in vitro translated product from polysome run-off synthesis. Western blot analysis of the 34 to 37 kD and 21 to 22 kD polypeptides partially digested with Staphylococcus aureus V8 protease revealed distinct patterns indicating that these proteins are structurally unrelated. As observed for the glutelins, the rice prolamines are also synthesized as a precursor of 16 kD, 2000 daltons larger than the mature polypeptide. Addition of dog pancreatic microsomal membranes to a wheat germ protein translation system resulted in the processing of the prolamine preprotein but not the preproglutelin to the mature form.     

Association analysis of the glutelin synthesis genes <Emphasis Type="Italic">GluA</Emphasis> and <Emphasis Type="Italic">GluB1</Emphasis> in a <Emphasis Type="Italic">Japonica</Emphasis> rice collection

Glutelin is the most significant seed storage protein and is regarded as an important nutrient quality trait in rice. Research on the genetic basis of the glutelin content distinction in rice will provide more choices for the diets of people with kidney disease and diabetes. The GluA and GluB1 genes play important roles in the process of glutelin synthesis. In this study, 128 Japonica rice accessions with wide geographic distributions were collected to construct the association panel. Among all the 128 accessions, both sequences of the GluA and GluB1 genes were obtained, and nucleotide polymorphisms were detected. A total of 46 SNPs and eight InDels, six SNPs and four InDels were found in the GluA and GluB1 gene sequences, respectively. Eight haplotypes and two haplotypes were classified based on the SNPs in the coding region of the GluA and GluB1 genes, respectively. Moreover, the association of the polymorphic sites in the two genes with glutelin content in the tested population was estimated. The results revealed that five SNPs in the GluA gene, one SNP and one InDel in the GluB1 gene were associated with glutelin content at a significant level (P < 0.01). Corresponding markers were also designed to check the alleles of GluA and GluB1 genes. These results suggested that polymorphisms in the GluA and GluB1 genes in rice could be utilized in molecular marker-assisted selection to improve the nutrient quality of rice breeding programmes.     

Studies on Rice Glutelin

The complete amino acid analysis of the whole glutelin preparation from rice endosperm was performed. The recoveries were 101.59% for amino acid residues and 101.68% for nitrogen, and the standard deviations for four determinations on the 22 and 70 hr hydrolyzates were very small. The features of the amino acid composition of the protein were as follows; (1) the high contents of dicarboxylic amino acids, particularly glutamic acid, (2) about 60% of these dicarboxylic amino acids was in the amide form, and (3) the significantly low contents of tryptophan, methionine and half cystine. The amino acid analyses of the two kinds of the subunits of glutelin, the neutral major one and the basic minor one, were also carried out. There were some significant differences between the two subunits, for instance, in the contents of glutamic acid, tryptophan, glycine, half cystine, methionine and lysine. However, the composition of whole glutelin seemed to be settled predominantly by that of the major subunit.     

Properties of a major α-globulin of rice endosperm

Globulin was isolated from milled rice (Oryza sativa, line IR480-5-9) by 5% NACl extraction and was precipitated by (NH₄)₂SO₂ or by dialysis against water. The extract was purified by repeated isoelectric precipitation at pH 4.5. The major globulin fraction (40%) exhibited one band by electrophoresis at pH 4.5 but two bands at pH 8.3. Similarly, one sharp peak was shown by sedimentation corresponding to 1.41S (α-globulin) in acetic acid (pH 2) and NaOH (pH 11.7) but a broad asymmetric peak was obtained at pH 6.7, 8.3 and 8.9. Gel filtration of the α-globulin at pH 6.5 exhibited 2 proteins with MW 20 000 and 98 000. The results suggest a pH dependent aggregation phenomenon. The two proteins could not be separated by DEAE-cellulose chromatography. SDS-polyacrylamide electrophoresis of α-globulin revealed one subunit with MW 18 000. This α-globulin is poorer in lysine and histidine but richer in cystine, methionine, arginine, tyrosine and glutamic acid than whole milled rice proteinfa]Taken part from the M.S. thesis of AAP from the University of the Philippine at Los Baños (1977).     

Properties of albumins of milled rice

Extraction studies on IR36 milled rice showed that albumins solubilized by 0.1–0.15 M (NH₄)₂SO₄ consisted of about 20% high(～5%) lysine, fast-migrating proteins on electrophoresis at pH 8.3 and about 80% lower ～2%) lysine proteins of slower mobility. The 2%-lysine albumins were insoluble in 1.8 M (NH₄)₂SO₄ while the higher lysine albumins required 4 M (NH₄)₂SO₄ to precipitate. The 2%-lysine albumins were not fractionated by gel filtration and gave only one major fraction with MW 19 000. SDS-polyacrylamide gel electrophoresis confirmed the major subunit to be of MW 17 000. These albumins were separated by DEAE-Sephacel chromatography at pH 8.5 into three fractions of similar aminograms but differing in analytical get electrophoretic and isoelectric focusing patterns.     

Biochemical characterization of rice glutelin

The two major subunits of rice glutelin, the acidic (α) and basic (β) polypeptides were purified by chromatofocusing and cation exchange chromatography, respectively. The molecular weight range of the α polypeptides was 28.5 to 30.8 kilodaltons and the molecular weight range of the β polypeptides was 20.6 to 21.6 kilodaltons. Electrofocusing in polyacrylamide gels showed that the isoelectric points of the α and β polypeptides were 6.5 to 7.5 and 9.4 to 10.3, respectively. At least 12 polypeptides of the α-group and nine polypeptides of the β-group could be separated by electrofocusing. The amino acid compositions of whole glutelin, and the purified α and β subunits were analyzed. The α subunit contained more glutamic acid/glutamine, serine, and glycine, and less alanine, lysine, aspartic acid/asparagine, and isoleucine than the β subunit. A comparison of the amino acid composition of rice glutelin subunits with those of the 11S proteins from eight other plant species indicated that there is more similarity between the β subunits than the α subunits of several diverse plant species.