Regulation of Legumin Levels in Developing Pea Seeds under Conditions of Sulfur Deficiency: Rates of Legumin Synthesis and Levels of Legumin mRNA

It was shown previously that when peas (Pisum sativum L.) are grown with suboptimal sulfur supply the level of legumin (the more S-rich of the two major seed storage proteins) in the mature seed is selectively reduced (Randall, Thomson, Schroeder, 1979 Aust J Plant Physiol 6: 11-24). This paper reports a study of the cellular mechanisms involved in regulating legumin synthesis under these conditions. Pulse and pulse-chase labeling experiments were carried out with excised, immature cotyledons from normal and S-deficient plants. Legumin was isolated from cotyledon extracts by immunochromatography, and the proportion of legumin synthesis relative to total protein synthesis was determined. Results showed that reduced legumin accumulation could largely be accounted for by a greatly reduced level of legumin synthesis (80-88% reduction) rather than by a major increase in legumin breakdown.

Legumin mRNA levels were assayed by two methods. In vitro translation of polysomal RNA from cotyledons of normal and S-deficient plants indicated a reduction of 60 to 70% in synthesis of legumin-related products by preparations from S-deficient plants. A legumin cDNA clone was constructed, characterized, and used to measure the levels of legumin mRNA in polysomal and total RNA preparations from developing cotyledons. Legumin mRNA levels were reduced by 90% in preparations from S-deficient plants.

When restored to an adequate S supply, S-deficient plants (or pods taken from such plants) recovered normal levels of legumin synthesis (in vivo and in vitro) and of legumin mRNA. These results indicate that reduced legumin accumulation under conditions of S deficiency is primarily a consequence of reduced levels of legumin mRNA.

     

Modulation by abscisic acid of storage protein accumulation in Vicia Faba L. cotyledons cultured in vitro

The effects of abscisic acid (ABA), high osmotica, fluridone (an inhibitor of carotenoid biosynthesis), gibberellic acid (GA₃) and an inhibitor of gibberellin biosynthesis, paclobutrazol (1-(4-chlorophenyl)-4,4-dimethyl-2-(1-24-triazol-1-yl)pentan-3-ol) on storage protein accumulation were studied in developing Vicia faba L. cotyledons cultured for 2 or 3 days in vitro. Extracts of these cotyledons were separated by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) under reducing conditions. ABA stimulated the accumulation of vicilin and legumin polypeptides. GA₃ did not noticeably stimulate the accumulation of any polypeptide. There was stimulation of vicilin and legumin polypeptide accumulation by high osmoticum (18% sucrose), which was further enhacedd by ABA and inhibited by fluridone. The fluridone inhibition was reversed by ABA addition.The data provides evidence that ABA modulates the synthesis of V. faba storage proteins.     

Legumin of Vicia faba major: accumulation in developing cotyledons,purification, mRNA characterization and chromosomal location of coding genes

Summary Experiments were carried out on Vicia faba major involving (1) determination of the pattern of legumin accumulation during seed development, (2) protein purification from mature cotyledons, (3) the characterization of legumin mRNA, and (4) the chromosomal localization of the genes coding for legumins. In developing cotyledons the synthesis of legumin begins 28 days after petal desiccation (DAPD), and 4 days after initiation of vicilin synthesis. The two subunits (_A and _A) of legumin A appear 2 days earlier than those (_B and _B) of legumin B. While the accumulation of vicilin peaks on the 30th DAPD, that of legumin continues during further seed development, and the synthesis of legumin mRNA peaks on the 37th DAPD. Northern blot hybridizations using two DNA plasmids containing cDNA inserts with sequence homology to the A- and B-type legumin genes, respectively, indicated that legumin mRNAs extracted from cotyledons 36 DAPD band below the 18S RNA band. In addition, a faint band below that of the 25S RNA band can be observed in legumin mRNAs extracted from cotyledons at an earlier developmental stage (30 DAPD). By means of polyacrylamide gel electrophoresis in the presence or absence of SDS and 2-mercaptoethanol, two fractions could be eluted after zonal isoelectric precipitation of the globulins from mature seeds: one fraction contains mainly vicilin, the other, legumin. In situ hybridization showed that legumin genes are arranged in two clusters: the genes coding for legumin A are located in the longer arm of the one between the two shortest subtelocentric chromosome pairs whose centromere is in a less terminal position; those coding for legumin B are located in the non-satellited arm of the longer submetacentric pair.     

Sequestration of pea reserve proteins by rough microsomes

Free polysomes, polysomes released from membranes, and rough microsomal vesicles isolated from developing cotyledons of Pisum sativum L. cv. Burpeeana were used to direct cell-free protein synthesis in a wheat germ system. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis demonstrated that the polypeptide products had molecular weights ranging from 12,000 to 74,000. Some of the polypeptides migrated during electrophoresis with the same mobility as polypeptides present in legumin and vicilin preparations. By the use of rabbit antibodies raised against pea reserve proteins it was established that polysomes released from membranes and rough microsomes directed the synthesis of polypeptides that were related to reserve proteins whereas free polysomes did not.     

Correlated in situ hybridisation and immunochemical studies of legumin storage protein deposition in pea (Pisum sativum L.)

Legumin and vicilin are the major globulin seed storage proteins of pea. They are synthesised predominantly in the cotyledons where they are sequestered within membrane-bounded vacuolar protein bodies. In situ hybridisation histochemistry, with both biotinylated and ³⁵S-labelled cDNA probes, has been used to visualise the temporal and spatial patterns of distribution of legumin and vicilin mRNAs during seed development. These patterns have been compared with those of storage protein deposition which have been determined by immunocytochemistry. Results indicate that within the cotyledons high levels of legumin and civilin mRNAs are restricted to the storage parenchyma tissues, whilst the epidermal cells and vascular parenchyma do not show such accumulation. The tissues of the embryo axis also show differential levels of expression, although where present the levels of mRNAs appear much lower than in the cotyledons. Throughout the embryo the patterns shown by in situ hybridisation are similar to those shown by immunocytochemistry, although the transient endosperm of early seed development does not show such a correlation.     

Glycoprotein Metabolism in the Cotyledons of Pisum sativum during Development and Germination

The glycoprotein nature of legumin and vicilin, the reserve globulins in the cotyledons of Pisum sativum was studied. Legumin from mature seed was found to contain 1% neutral sugars (mannose and glucose) and 0.1% amino sugar (glucosamine), whereas vicilin contained 0.3% neutral sugar (mannose) and 0.2% amino sugar (glucosamine). On the basis of the incorporation of ¹⁴C-labeled glucosamine, it appeared that not all of the component subunits of the reserve proteins are glycosylated to the same extent. In addition, it has been established that glycosylation occurs after peptide synthesis. During seed development there was a change in neutral sugars and amino sugar ratio in vicilin. During germination, the neutral sugars and the amino sugar content of the glycoproteins declined. These findings are discussed in relation to the synthesis and degradation of the glycosyl component of the glycoproteins.     

Influence of Sulfur Nutrition on Developmental Patterns of Some Major Pea Seed Proteins and Their mRNAs

In addition to the marked reduction in legumin synthesis and legumin mRNA levels reported earlier (Chandler, Higgins, Randall, Spencer 1983 Plant Physiol 71: 47-54), pulse labeling of S-deficient Pisum sativum L. seeds showed that a high relative level of total vicilin (vicilin plus convicilin) synthesis was maintained throughout the entire phase of protein accumulation, whereas in nondeficient seeds vicilin synthesis is largely confined to the first half of this phase. Fractionation of pulse-labeled proteins on Na-dodecylsulfate-polyacrylamide gels showed that the synthesis of the M_r 50,000 family of vicilin polypeptides was increased and greatly extended in S-deficient seeds whereas that of convicilin was slightly reduced. Other changes apparent from pulse-labeling experiments include a depression, to different degrees, in the synthesis of three major albumin polypeptides.

The level of the mRNAs for seven major seed proteins was followed throughout development of control and sulfur-deficient seeds. In all cases, the changes in each mRNA closely reflected the pattern of synthesis of its corresponding polypeptide seen by pulse labeling. S-deficient seeds showed an elevated level of M_r 50,000 vicilin mRNA which remained high throughout seed formation, whereas legumin mRNA levels were greatly reduced at all stages of development.

When S-deficient plants were given an adequate supply of sulfate midway through seed development, there was a shift toward the protein synthesis profile characteristic of healthy plants. The synthesis of legumin and two albumins rapidly increased and the synthesis of M_r 50,000 vicilin declined more slowly. Similar responses were seen in detached, S-deficient seeds supplied directly with adequate sulfate.

     

Construction and Screening of Chickpea cDNA Library with Heterologous Legumin cDNA Probe

A cDNA library was constructed from developing chickpea cotyledons in the expression vector λ gt 11. The library when plated on X-gal and IPTG showed about 35% recombinants. These recombinants were screened using pea legumin cDNA probe. Of a total of 4 × 10⁴ cDNA clones screened, 20 clones showed homology to legumin probe. The presence of cDNA insert in these clones was further confirmed by Southern blot hybridization.     

Pulse-labeling Studies on Protein Synthesis in Developing Pea Seeds and Evidence of a Precursor Form of Legumin Small Subunit

Intact cotyledons were taken from pea seeds at various stages during seed development and pulse-labeled with ¹⁴C-amino acids. Salt-soluble proteins then were extracted and fractionated on Na dodecyl sulfate-polyacrylamide gels. Storage proteins in these extracts were identified by their binding to immunoaffinity columns. The labeling studies showed that the synthesis of storage protein polypeptides accounts for a major part of total protein synthesis of developing cotyledons between 10 and 22 days after flowering. The distribution of the incorporated radioactivity between individual storage protein polypeptides varied with stage of development. For example, the synthesis of the 50 kilodalton complex of vicilin subunits dominated the early stages of protein accumulation but was a negligible proportion of the total incorporation in the later stages. On the other hand, the 75 kilodalton vicilin subunit was synthesized throughout this entire period. The major small subunit of legumin (20 kilodaltons) was not detected by either Coomassie blue staining or by 2-hour labeling during this period. It was found to arise during the desiccation phase of seed maturation from a long-lived precursor with a relative electrophoretic mobility equivalent to 19 kilodaltons.     

Deoxyribonucleic Acid and Ribonucleic Acid Synthesis during the Cell Expansion Phase of Cotyledon Development in Vicia faba L

In Vicia faba L., the tissue specific proteins, legumin and vicilin, are synthesized during the cell expansion phase of cotyledon development. During this growth period, RNA and nuclear DNA increase 8- to 10-fold. ³H-Uridine and ³H-adenosine are incorporated into ribosomal RNA, both 25S and 18S, and into transfer RNA. DNA isolated from cotyledons in the cell division phase of growth has been compared with DNA isolated from cotyledons undergoing expansion growth. Results indicate that the DNA increase involves replication of the whole genome (endoreduplication).     

Isolation of prolegumin from developing pea seeds: its binding to endomembranes and assembly into prolegumin hexamers in the protein storage vacuole

A fraction enriched in endoplasmic reticulum and Golgi membranesfrom developing cotyledons of Pisum sativum L. has proved tobe a convenient source for the isolation of prolegumin, theprecursor of the major 11S storage globulin of pea seeds. Twopro-proteins were isolated with molecular masses of 60 kDa and75 kDa, respectively. A monoclonal antibody, designated 2B1,against prolegumin was raised using the in vitro immunizationtechnique. This antibody recognizes the 60 kDa precursor polypeptide,but only the 20 kDa ß-subunit of mature legumin. Prolegumin,like the ß-subunit of the mature legumin, is a hydrophobicprotein. After import into the protein storage vacuole, andafter formation of the protein bodies trimeric 9S proleguminassembles into 12S hexamers without prior processing of theprecursor. Since prolegumin in vitro does not oligomerize intomore than 9S tnmers these results suggest that a protein-mediatedassembly of 9S prolegumin trimers into 12S prolegumin hexamersprobably occurs in the lumen of the protein storage vacuole.Prolegumin, but not mature legumin, binds very tightly to membranes.This property points to a possible way of identifying a putativeprolegumin receptor. Key words: Calcium, Endoplasmic reticulum, Golgi apparatus, legumim, monoclonal antibody, pea cotyledons     

The initiation of legumin synthesis in immature embryos of Pisum sativum L. grown in vivo and in vitro

A highly sensitive immunoassay has been used for the detection of a major storage protein, legumin, in embryos of Pisum sativum L.; with this technique nanogram quantities could be measured. In the two varieties tested, legumin could be detected in embryos in vivo, when they had attained a fresh weight of 2·10^-3 g and 3·10^-3 g, respectively. Contrary to earlier claims, embryos cultured in vitro were shown to be capable of initiating legumin synthesis. This capacity to initiate legumin synthesis was confirmed by two-dimensional isoelectric focusing-electrophoresis and fluorography; embryos harvested before initiation of legumin synthesis and cultured in radioactive medium were shown to have synthesized legumin subunits. The amounts of legumin and total protein synthesized per unit fresh weight were consistently greater in vitro than in equivalent embryos grown in vivo.Abbreviations ELISA Enzyme-linked immunosorbent assay - BSA bovine serum albumin - IgG immunoglobulin - SDS sodium dodecyl sulphate - DSP Pisum cv. Dark Skinned Perfection     

Different functions of vicilin and legumin are reflected in the histopattern of globulin mobilization during germination of vetch (Vicia sativa L.)

The temporal and spatial patterns of storage-globulin mobilization were immunohistochemically pursued in the embryonic axis and cotyledons of vetch seed (Vicia sativa L.) during germination and early seedling growth. Embryonic axes as well as cotyledons of mature seeds contain protein bodies with stored globulins. Prevascular strands of axes and cotyledons, the radicle and epidermal layers of axis organs were nearly exclusively stained by vicilin antibodies whereas the cotyledonous storage mesophyll gave similar staining for vicilin and legumin. Globulin breakdown started locally where growth and differentiation commenced in the axis. There, vicilin mobilization preceded legumin mobilization. Thus vicilin represents the initial source of amino acids for early growth and differentiation processes in vetch. Legumin presumably only serves as a bulk amino acid source for subsequent seedling growth during postgerminative globulin degradation. During the first 2–3 d after the start of imbibition the axis was depleted of globulins whereas no decrease in immunostainability was detected in the cotyledons except in their vascular strands where immunostainability was almost completely lost at this time. Continuous vascular strands were established at the third day when globulin breakdown was finished in the axis but had just started in the cotyledon mesophyll. Protein mobilization proceeded in a small zone from the epidermis towards the vascular strands in the center of the cotyledons. In this zone the storage cells, which initially appeared densely packed with starch grains and protein bodies, concomitantly transformed into cells with a large central vacuole and only a thin cytoplasmic layer attached to the cell wall. These results agree well with the hypothesis that during the first 2 d after imbibition the axis is autonomous in amino acid provision. After the endogenous reserves of the axis are depleted and the conductive tissue has differentiated, globulins are mobilized in the cotyledons, suggesting that then the amino acid supply is taken over by the cotyledons. For comparison with other degradation patterns we used garden bean (Phaseolus vulgaris L) and rape (Brassica napus L.) as reference plants. Received: 3 August 1999 / Accepted: 11 December 1999     

Different legumin protein domains act as vacuolar targeting signals.

Legumin subunits are synthesized as precursor polypeptides and are transported into protein storage vacuoles in field bean cotyledons. We expressed a legumin subunit in yeast and found that in these cells it is also transported into the vacuoles. To elucidate vacuolar targeting information, we constructed gene fusions of different legumin propolypeptide segments with either yeast invertase or chloramphenicol acetyltransferase as reporters for analysis in yeast or plant cells, respectively. In yeast, increasing the length of the amino-terminal segment increased the portion of invertase directed to the vacuole. Only the complete legumin alpha chain (281 amino acids) directed over 90% to the vacuole. A short carboxy-terminal legumin segment (76 amino acids) fused to the carboxy terminus of invertase also efficiently targeted this fusion product to yeast vacuoles. With amino-terminal legumin-chloramphenicol acetyltransferase fusions expressed in tobacco seeds, efficient vacuolar targeting was obtained only with the complete alpha chain. We conclude that legumin contains multiple targeting information, probably formed by higher structures of relatively long peptide sequences.     

Purine synthesis and catabolism in soybean seedlings : the biogenesis of ureides

The ureides, allantoin and allantoic acid, are the major nitrogenous substances transported within the xylem of N₂-fixing soybeans (Glycine max L. Merr. cv Amsoy 71). The ureides accumulated in the cotyledons, roots and shoots of soybean seedlings inoculated with Rhizobium or grown in the presence of 10 millimolar nitrate. The patterns of activity for uricase and allantoinase, enzymes involved in ureide synthesis, were positively correlated with the accumulation of ureides in the roots and cotyledons. Allopurinol and azaserine inhibited ureide production in 3-day-old cotyledons while no inhibition was observed in the roots. Incubation of 4-day-old seedlings with [¹⁴C]serine indicated that in the cotyledons ureides arose via de novo synthesis of purines. The source of ureides in both 3- and 4-day-old roots was probably the cotyledons. The inhibition of ureide accumulation by allopurinol but not azaserine in 8-day-old cotyledons suggested that ureides in these older cotyledons arose via nucleotide breakdown. Incubation of 8-day-old plants with [¹⁴C]serine suggested that the roots had acquired the capability to synthesize ureides via de novo synthesis of purines. These data indicate that both de novo purine synthesis and nucleotide breakdown are involved in the production of ureides in young soybean seedlings.     

Changes in the levels of major sulfur metabolites and free amino acids in pea cotyledons recovering from sulfur deficiency

Changes in levels of sulfur metabolites and free amino acids were followed in cotyledons of sulfur-deficient, developing pea seeds (Pisum sativum L.) for 24 hours after resupply of sulfate, during which time the legumin mRNA levels returned almost to normal. Two recovery situations were studied: cultured seeds, with sulfate added to the medium, and seeds attached to the intact plant, with sulfate added to the roots. In both situations the levels of cysteine, glutathione, and methionine rose rapidly, glutathione exhibiting an initial lag. In attached but not cultured seeds methionine markedly overshot the level normally found in sulfur-sufficient seeds. In the cultured seed S-adenosylmethionine (AdoMet), but not S-methylmethionine, showed a sustained rise; in the attached seed the changes were slight. The composition of the free amino acid pool did not change substantially in either recovery situation. In the cultured seed the large rise in AdoMet level occurred equally in nonrecovering seeds. It was accompanied by 6-fold and 10-fold increases in γ-aminobutyrate and alanine, respectively. These effects are attributed to wounding resulting from excision of the seed. ³⁵S-labeling experiments showed that there was no significant accumulation of label in unidentified sulfur-containing amino compounds in either recovery situation. It was concluded from these results and those of other workers that, at the present level of knowledge, the most probable candidate for a `signal' compound, eliciting recovery of legumin mRNA level in response to sulfur-feeding, is cysteine.     

The Influence of Axis Removal on Protein Metabolism in Cotyledons of Pisum sativum L

The protein metabolism of cotyledons attached to the embryonic axis has been compared with that in cotyledons removed from the axis at the initiation of a 6-day imbibition. Total protein declined in the attached but not in the detached cotyledons. Concurrent with the decline in protein level in the intact cotyledons there was an increased capacity to incorporate exogenously supplied leucine into protein. In contrast, detached cotyledons showed a restricted capacity for protein synthesis. It was demonstrated that ribosomal preparations from cotyledons of intact seedlings contained an increasing proportion of polyribosomes as germination progressed and such ribosomes were active in in vitro amino acid incorporation. Ribosomal preparations from detached cotyledons contained few polyribosomes and had a restricted capacity to incorporate amino acids in vitro. The in vitro incorporation of phenylalanine was stimulated by polyuridylic acid with the stimulation being greatest in ribosomal preparations from detached cotyledons. The results suggest that an axis component may regulate the availability of messenger RNA in the cotyledons during germination.