Soluble isoforms of starch synthase and starch-branching enzyme also occur within starch granules in developing pea embryos

Developing wild-type pea embryos contain two major isoforms of starch synthase and two isoforms of starch-branching enzyme. One of the starch synthases and both starch-branching enzymes occur both in the soluble fraction and tightly bound to starch granules. The other starch synthase, which is very similar to the waxy proteins of other species, is exclusively granule-bound. It is inactive when solubilized in a native form from starch granules, but activity is recovered when the SDS-denatured protein is reconstituted from polyacrylamide gels.
Evidence is presented which indicates that all of these proteins become incorporated within the structure of the granule as it grows. It is proposed that the granule-bound waxy protein is active in vivo at the granule surface, whereas the remaining proteins are active in the soluble fraction of the amyloplast. The proteins become trapped within the granule matrix as the polymers they synthesize crystallize around them, and they probably play no further part in polymer synthesis.     

Evidence that the “waxy” protein of pea (Pisum sativum L.) is not the major starch-granule-bound starch synthase

The aim of this work was to identify the starch-granule-bound starch synthase of developing pea embryos. When starch-granule-bound proteins were solubilised by digestion of granules with α-amylase and fractionated on a Mono Q anion-exchange column, activity of starch synthase eluted as three peaks. The distribution of activity in fractions from the column coincided with that of a 77-kDa protein. An antibody to this protein inhibited starch-synthase activity both in solubilised, starch-granule-bound protein and on intact starch granules. Recoveries of activity through extraction, solubilisation and chromatography indicate that this protein is the major, if not the only, form of starch synthase on the starch granule. The major, 59-kDa protein of the pea starch granule is antigenically related to the product of thewaxy locus of potato, which has previously been identified as the starch-granule-bound starch synthase of the tuber. However, the distribution of the 59-kDa protein did not coincide with that of starch-synthase activity in fractions from the Mono Q column. An antibody to the 59-kDa protein did not inhibit starch-synthase activity. The results raise questions about the relationship between “waxy” proteins and starch-granule-bound starch synthases generally. I am grateful to my colleagues Kay Denyer, Ian Dry (CSIRO, Adelaide, Australia), Rob Ireland (Mount Allison University, New Brunswick, Canada), Cathie Martin and Steve Rawsthorne for useful discussions during the course of this work, Cliff Hedley for the gift of pea seeds, and Ian Bedford for preparing pea starch and gels of starch-granule-bound proteins. This work was supported by the Agriculture and Food Research Council via a grant-in-aid to the John Innes Institute.     

Characterization of a Granule-Bound Starch Synthase Isoform Found in the Pericarp of Wheat

Waxy wheat (Triticum aestivum L.) lacks the waxy protein, which is also known as granule-bound starch synthase I (GBSSI). The starch granules of waxy wheat endosperm and pollen do not contain amylose and therefore stain red-brown with iodine. However, we observed that starch from pericarp tissue of waxy wheat stained blue-black and contained amylose. Significantly higher starch synthase activity was detected in pericarp starch granules than in endosperm starch granules. A granule-bound protein that differed from GBSSI in molecular mass and isoelectric point was detected in the pericarp starch granules but not in granules from endosperm. This protein was designated GBSSII. The N-terminal amino acid sequence of GBSSII, although not identical to wheat GBSSI, showed strong homology to waxy proteins or GBSSIs of cereals and potato, and contained the motif KTGGL, which is the putative substrate-binding site of GBSSI of plants and of glycogen synthase of Escherichia coli. GBSSII cross-reacted specifically with antisera raised against potato and maize GBSSI. This study indicates that GBSSI and GBSSII are expressed in a tissue-specific manner in different organs, with GBSSII having an important function in amylose synthesis in the pericarp.     

Biochemical and molecular characterization of a novel starch synthase from potato tubers

An isoform of starch synthase from potato tubers which is present both in the stroma of the plastid and tightly bound to starch granules has been identified biochemically and a cDNA has been isolated. The protein encoded by the cDNA is 79.9 kDa and has a putative transit peptide and a distinct N-terminal domain which is predicted to be highly flexible. It is similar in both amino acid sequence and predicted structure to the granule-bound starch synthase II (GBSSII) of pea embryos. When expressed in Escherichia coli, the mature protein has starch synthase activity. The importance of the isoform has been assessed by biochemical measurements and antisense transformation experiments in which the amount of the isoform in the tuber is severely and specifically reduced. Both approaches indicate that the isoform contributes a maximum of 15% of the total starch synthase activity of the tuber. It is suggested that this isoform and the GBSSII of pea embryos represent a widely distributed class of isoforms of starch synthase. The contribution to total starch synthase activity of members of this class probably varies considerably from one type of storage organ to another.     

Evidence that a 77-kilodalton protein from the starch of pea embryos is an isoform of starch synthase that is both soluble and granule bound.

In this paper we provide further evidence about the nature of a 77-kD starch synthase (SSII) that is both soluble and bound to the starch granules in developing pea (Pisum sativum L.) embryos. Mature SSII gives rise to starch synthase activity when expressed in a strain of Escherichia coli lacking glycogen synthase. In transgenic potatoes (Solanum tuberosum L.) expressing SSII, the protein is both soluble and bound to the starch granules. These results confirm that SSII is a starch synthase and indicate that partitioning between the soluble and granule-bound fraction of storage organs is an intrinsic property of the protein. A 60-kD isoform of starch synthase found both in the soluble and granule-bound fraction of the pea embryos is probably derived by the processing of SSII and is a different gene product from GBSSI, the exclusively granule-bound 59-kD isoform of starch synthase that is similar to starch synthases encoded by the waxy genes of cereals and the amf gene of potatoes. Consistent with this, expression in E. coli of an N-terminally truncated version of SSII gives rise to starch synthase activity.     

Solubilization of the starch-granule-bound starch synthase of normal maize kernels

The starch-granule-bound starch synthase from Zea mays has been solubilized with a recovery of between 50 and 84%. Chromatography of the solubilized enzyme on DEAE-Sepharose resolves two fractions of activity which may be distinguished by their response to citrate. Neither solubilized isoenzyme displays any significant activity with UDPglucose.     

Waxy基因的RNA沉默使转基因小麦种子中直链淀粉含量下降

通过RNAi策略转化小麦,以降低小麦种子中直链淀粉的含量。小麦中直链淀粉合成的关键酶是颗粒结合型淀粉合成酶（Granule—bound starch synthase l,GBSSI,即WAXY蛋白）,通过RT—PCR方法从小麦种子中分离出Waxy基因。Southern杂交分析表明,在基因组中存在3个Waxy基因。Northern杂交分析显示出在授粉后的小麦种子中检测到Waxy mRNA。利用RNA沉默策略,将Waxy编码区683bp的正向和反向片段以及150bp内含子,连接于表达载体pCAMBIA3300中玉米ubil启动子下游。以扬麦10号授粉后15d的幼胚为外植体,利用农杆菌介导的方法进行转化。通过PCR、RT-PCR和叶片离体褪绿实验鉴定出4株转基因植株。小麦胚乳I2-KI染色和直链淀粉含量测定表明这4株转基因植株直链淀粉含量明显下降。研究结果表明Waxy基因的RNA沉默使转基因小麦种子直链淀粉的含量下降。     

In vitro stabilization and minimum active component of polygalacturonic acid synthase involved in pectin biosynthesis

Polygalacturonic acid (PGA) synthase successively transfers galacturonic acid to oligogalacturonic acid by an alpha1,4-linkage to synthesize PGA, the backbone of plant pectic homogalacturonan. PGA synthase has not been purified to date due to its instability in vitro. In this study, we found stable conditions in vitro and separated a minimum active component of the enzymes from pea and azuki bean epicotyls. The PGA synthase lost its activity in 500 mM of sodium chloride or potassium chloride, while it was relatively stable at low salt concentrations. Under low salt concentrations, three peaks bearing PGA synthase activity were separated, by gel filtration and sucrose density gradient centrifugation. The molecular masses of these enzymes solubilized with 3-[(3-cholamidopropyl)dimethyl-ammonio]propanesulfonic acid were estimated to be 21,000, 5,000, and 590 kDa. The two higher molecular mass PGA synthases converted to smaller PGA synthase proteins when treated with high salt concentrations, while retaining their activity, indicating that PGA synthase has a minimum active component for its activity.     

Characterization of cDNAs encoding two isoforms of granule-bound starch synthase which show differential expression in developing storage organs of pea and potato

We have isolated cDNA clones to two isoforms of granule-bound starch synthase (GBSS) from pea embryos and potato tubers. The sequences of both isoforms are related to that of glycogen synthase from E. coli and one, GBSSI, is very similar to the waxy protein of maize and other species. In pea, GBSSII carries a novel 203-amino-acid domain at its N-terminus. Genes encoding both proteins are expressed during pea embryo development, but GBSSII is most highly expressed earlier in development than GBSSI. Similarly, GBSSI and GBSSII are differentially expressed in developing potato tubers. Expression of both isoforms is much lower in other organs of pea than in embryos. GBSSII is expressed in every organ tested while GBSSI is not expressed in roots, stipules or flowers. The possible consequences of this differential use of GBSS isoforms are discussed.     

The isolation and characterization of novel low-amylose mutants of Pisum sativum L.

Mutants of Pisum sativum L. with seeds containing low-amylose starch were isolated by screening a population derived from chemically mutagenized material. In all of the mutant lines selected, the low-amylose phenotype was caused by a recessive mutation at a single locus designated lam. In embryos of all but one mutant line, the 59 kDa granule-bound starch synthase (GBSSI) was absent or greatly reduced in amount. The granule-bound starch synthase activity in developing embryos of the mutants was reduced but not eliminated. These results provide further evidence that amylose synthesis is unique to GBSSI. Other granule-bound isoforms of starch synthase cannot substitute for this protein in amylose synthesis. Examination of iodine-stained starch granules from mutant embryos by light microscopy revealed large, blue-staining cores surrounded by a pale-staining periphery. In this respect, the low-amylose mutants of pea differ from those of other species. The differential staining may indicate that the structure of amylopectin varies between the core and peripheral regions.     

Soluble starch synthases and starch branching enzymes from cotyledons of smooth- and wrinkled-seeded lines of Pisum sativum L.

Soluble starch synthase and branching enzyme were purified from 18-day-old cotyledons of the smooth-seeded pea cultivar Alaska (RR) and wrinkled-seeded pea cultivar Progress #9 (rr) by DEAE-cellulose chromatography. Two coeluting peaks of primed and citrate-stimulated starch synthase activity and a major and minor peak of branching enzyme activity were observed in Alaska. However, in Progress #9, only one peak of synthase activity was found. When crude extracts of Progress #9 were centrifuged, over 70% of the starch synthase activity was recovered in the pelleted fraction, and additional washings of the pellet released no further activity. The addition of purified starch granules to Alaska crude extracts also resulted in the recovery of a greater proportion of synthase activity in pelleted fractions. The two peaks of branching enzyme activity in Alaska differed in their stimulation of phosphorylase, amylose branching activity, and activity in various buffers. The DEAE-cellulose profile of Progress #9 showed no distinct peak of branching enzyme and less than 10% of the total activity found in Alaska. The association of one form of soluble starch synthase with the pelleted fraction and the greatly reduced levels of branching enzyme provide a partial explanation for the appearance of high-amylose starch in Progress #9 cotyledons.     

Production of waxy (amylose-free) wheats

The Waxy (Wx) protein has been identified as granule-bound starch synthase (GBSS; EC 24.1.21), which is involved in amylose synthesis in plants. Although common wheat (Triticum aestivum L.) has three Wx proteins, partial waxy mutants lacking one or two of the three proteins have been found. Using such partial waxy mutants, tetra- and hexaploid waxy mutants with endosperms that are stained red-brown by iodine were produced. Both mutants showed loss of Wx protein and amylose. This is the first demonstration of genetic modification of wheat starch.     

Contribution of sucrose synthase, ADP-glucose pyrophosphorylase and starch synthase to starch synthesis in developing pea seeds

Using genetic variability existing amongst nine pea genotypes (Pisum sativum L.), the biochemical basis of sink strength in developing pea seeds was investigated. Sink strength was considered to be reflected by the rate of starch synthesis (RSS) in the embryo, and sink activity in the seed was reflected by the relative rate of starch synthesis (RRSS). These rates were compared to the activities of three enzymes of the starch biosynthetic pathway [sucrose synthase (Sus), ADP-glucose pyrophosphorylase and starch synthase] at three developmental stages during seed filling (25, 50 and 75% of the dry seed weight). Complete sets of data collected during seed filling for the nine genotypes showed that, for all enzyme activities (expressed on a protein basis), only Sus in the embryo and seed coat was linearly and significantly correlated to RRSS. The contribution of the three enzyme activities to the variability in RSS and RRSS was evaluated by multiple regression analysis for the first two developmental stages. Only Sus activity in the embryo could explain, at least in part, the significant variability observed for both the RSS and the RRSS at each developmental stage. We conclude that Sus activity is a reliable marker of sink activity in developing pea seeds.     

The purification and characterisation of the two forms of soluble starch synthase from developing pea embryos

Soluble starch synthase was purified 10000-fold from developing embryos of pea (Pisum sativum L.). The activity was resolved into two forms which together account for most if not all of the soluble starchsynthase activity in the embryo. The two isoforms differ in their molecular weights but are similar in many other respects. Their kinetic properties are similar, neither isoform is active in the absence of primer, and both are unstable at high temperatures, the activity being abolished by a 20-min incubation at 45° C. Both isoforms are recognised by antibodies raised to the granule-bound starch synthase of pea. Isoform II, which has the same molecular weight (77 kDa) as the granulebound enzyme, is recognised more strongly than Isoform I.     

Biochemical characterization of the Arabidopsis biotin synthase reaction. The importance of mitochondria in biotin synthesis.

Biotin synthase, encoded by the bio2 gene in Arabidopsis, catalyzes the final step in the biotin biosynthetic pathway. The development of radiochemical and biological detection methods allowed the first detection and accurate quantification of a plant biotin synthase activity, using protein extracts from bacteria overexpressing the Arabidopsis Bio2 protein. Under optimized conditions, the turnover number of the reaction was >2 h(-1) with this in vitro system. Purified Bio2 protein was not efficient by itself in supporting biotin synthesis. However, heterologous interactions between the plant Bio2 protein and bacterial accessory proteins yielded a functional biotin synthase complex. Biotin synthase in this heterologous system obeyed Michaelis-Menten kinetics with respect to dethiobiotin (K(m) = 30 microM) and exhibited a kinetic cooperativity with respect to S-adenosyl-methionine (Hill coefficient = 1.9; K(0.5) = 39 microM), an obligatory cofactor of the reaction. In vitro inhibition of biotin synthase activity by acidomycin, a structural analog of biotin, showed that biotin synthase reaction was the specific target of this inhibitor of biotin synthesis. It is important that combination experiments using purified Bio2 protein and extracts from pea (Pisum sativum) leaf or potato (Solanum tuberosum) organelles showed that only mitochondrial fractions could elicit biotin formation in the plant-reconstituted system. Our data demonstrated that one or more unidentified factors from mitochondrial matrix (pea and potato) and from mitochondrial membranes (pea), in addition to the Bio2 protein, are obligatory for the conversion of dethiobiotin to biotin, highlighting the importance of mitochondria in plant biotin synthesis.     

Downregulation of a chloroplast-targeted beta-amylase leads to a starch-excess phenotype in leaves

A functional screen in Escherichia coli was established to identify potato genes coding for proteins involved in transitory starch degradation. One clone isolated had a sequence very similar to a recently described chloroplast-targeted beta-amylase of Arabidopsis. Expression of the gene in E. coli showed that the protein product was a functional beta-amylase that could degrade both starch granules and solubilized amylopectin, while import experiments demonstrated that the beta-amylase was imported and processed into pea chloroplasts. To study the function of the protein in transitory starch degradation, transgenic potato plants were generated where its activity was reduced using antisense techniques. Analysis of plants reduced in the presence of this beta-amylase isoform showed that their leaves had a starch-excess phenotype, indicating a defect in starch degradation. In addition, it was shown that the antisense plants degraded only 8-30% of their total starch, in comparison with 50% in the wild type, over the dark period. This is the first time that a physiological role for a beta-amylase in plants has been demonstrated.     

Multiple, distinct isoforms of sucrose synthase in pea

Genes encoding three isoforms of sucrose synthase (Sus1, Sus2, and Sus3) have been cloned from pea (Pisum sativum). The genes have distinct patterns of expression in different organs of the plant, and during organ development. Studies of the isoforms expressed as recombinant proteins in Escherichia coli show that they differ in kinetic properties. Although not of great magnitude, the differences in properties are consistent with some differentiation of physiological function between the isoforms. Evidence for differentiation of function in vivo comes from the phenotypes of rug4 mutants of pea, which carry mutations in the gene encoding Sus1. One mutant line (rug4-c) lacks detectable Sus1 protein in both the soluble and membrane-associated fractions of the embryo, and Sus activity in the embryo is reduced by 95%. The starch content of the embryo is reduced by 30%, but the cellulose content is unaffected. The results imply that different isoforms of Sus may channel carbon from sucrose towards different metabolic fates within the cell.     

Discrete forms of amylose are synthesized by isoforms of GBSSI in pea

Amyloses with distinct molecular masses are found in the starch of pea embryos compared with the starch of pea leaves. In pea embryos, a granule-bound starch synthase protein (GBSSIa) is required for the synthesis of a significant portion of the amylose. However, this protein seems to be insignificant in the synthesis of amylose in pea leaves. cDNA clones encoding a second isoform of GBSSI, GBSSIb, have been isolated from pea leaves. Comparison of GBSSIa and GBSSIb activities shows them to have distinct properties. These differences have been confirmed by the expression of GBSSIa and GBSSIb in the amylose-free mutant of potato. GBSSIa and GBSSIb make distinct forms of amylose that differ in their molecular mass. These differences in product specificity, coupled with differences in the tissues in which GBSSIa and GBSSIb are most active, explain the distinct forms of amylose found in different tissues of pea. The shorter form of amylose formed by GBSSIa confers less susceptibility to the retrogradation of starch pastes than the amylose formed by GBSSIb. The product specificity of GBSSIa could provide beneficial attributes to starches for food and nonfood uses.     

Molecular identification and comparison of the starch synthase bound to starch granules between endosperm and leaf blades in rice plants

Normal (nonglutinous) rice plants (Oryza sativa andO. glaberrima) contain more than 18% amylose in endosperm starch, whilewaxy (glutinous) plants lack it in this starch. In contrast, leaf starch contained more than 3.6% amylose even inwaxy plants. SDS-PAGE analysis of proteins bound to endosperm starch granules in the normal plants revealed a single band with aMr of 60 kd, whereaswaxy plants did not exhibit a similar band. The activity of starch synthase (NDP-glucose-starch glucosyltransferase) was completely inhibited by antibody against the 60-kd protein. Thus, we conclude that the 60-kd protein is thewaxy protein encoded by theWx allele, which also plays a role in the synthesis of nonglutinous starch in endosperm tissue. In leaf blades, the proteins bound to starch granules separated into five bands withMr's of 53.6 to 64.9 kd on SDS-PAGE. Analysis of these proteins by immunoblotting using antiserum againstWx protein and inhibition of starch synthase activity by the synthase antibody revealed that none of these proteins was homologous toWx protein. We suggest that the synthesis of amylose in leaf blades is brought about by a protein encoded by a gene(s) different from theWx gene expressed in the endosperm.