Mutation loci and intragenic selection marker of the granule-bound starch synthase gene in waxy maize

Four pairs of specific PCR primers have been designed on the basis of the sequence of the granule-bound starch synthase gene (GBSS; dominant non-waxy gene Wx) and used to amplify its homologous sequence from thirteen waxy and two non-waxy inbred lines. Results from electrophoresis indicated that the recessive waxy gene was wx, derived from the dominant non-waxy gene Wx by mutation at its 3′ end. The sequence of the mutated 3′ end was amplified by the TAIL-PCR technique. Sequence alignment showed that the mutation of the wx gene was caused by transposition of the aldehyde dehydrogenase gene rf2. Two pairs of specific primers were designed on the basis of the sequence difference between the dominant gene Wx and its mutated recessive allele wx and used as intragenic selection markers to identify individual plants of genotypes WxWx, Wxwx, and wxwx by PCR amplification from the segregating population of the F₂ generation crossed between waxy and non-waxy inbred lines. Iodine solution staining and starch component assay showed that all the 35 F₂ plants identified as genotype WxWx produced non-waxy kernels of the F₃ generation and that all 33 F₂ plants identified as genotype wxwx produced waxy kernels of the F₃ generation. This result can be used to improve the selection efficiency of waxy maize breeding and for selection of other single genes and major polygenes.     

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.     

Differential regulation of waxy gene expression in rice endosperm

Summary In order to examine the effects of different alleles on the gene expression at the waxy locus, the Wx gene product which controls the synthesis of amylose was isolated from endosperm starch of rice plants and analysed by electrophoretic techniques. The major protein bound to starch granules was absent in most of waxy strains and increased with the number of Wx alleles in triploid endosperms, suggesting that the major protein is the Wx gene product. In addition to wx alleles which result in the absence or drastic reduction of the Wx gene product and amylose, differentiation of Wx alleles seemed to have occurred among nonwaxy rice strains. At least two Wx alleles with different efficiencies in the production of the major protein as well as amylose were detected. These alleles are discussed in relation to regulation of the gene expression.     

The function of the Waxy locus in starch synthesis in maize endosperm

The soluble adenosine diphosphate glucose-starch glucosyltransferase of maize (Zea mays L.) endosperm uses adenosine diphosphate glucose as a sole substrate, but the starch granule-bound nucleoside diphosphate glucose-starch glucosyltransferase utilizes both adenosine diphosphate glucose and uridine diphosphate glucose. The soluble glucosyltransferase can be bound to added amylose or to maize starch granules that contain amylose. However, binding of the soluble enzyme to the starch granules does not change its substrate specificity to that of the natural starch granule-bound glucosyltransferase. Furthermore, the soluble glucosyltransferase bound to starch granules can be removed by repeated washing without a change in specificity. The bound glucosyltransferase can be released by mechanical disruption of starch granules, and the released enzyme behaves in a manner similar to that of the bound enzyme in several respects. These observations suggest that the soluble and bound glucosyltransferases are different enzymes. The starch granule-bound glucosyltransferase activity is linearly proportional to the number of Wx alleles present in the endosperm. This is compatible with the hypothesis that the Wx allele is a structural gene coding for the bound glucosyltransferase, which is important for the normal synthesis of amylose.Journal Paper No. 4818 of the Purdue University Agricultural Experiment Station.     

Genetic control of amylose content in wheat endosperm starch and differential effects of three Wx genes

The endosperm starch of the wheat grain is composed of amylose and amylopectin. Genetic manipulation of the ratio of amylose to amylopectin or the amylose content could bring about improved texture and quality of wheat flour. The chromosomal locations of genes affecting amylose content were investigated using a monosomic series of Chinese Spring (CS) and a set of Cheyenne (CNN) chromosome substitution lines in the CS genetic background. Trials over three seasons revealed that a decrease in amylose content occurred in monosomic 4A and an increase in monosomic 7B. Allelic variation between CS and CNN was suggested for the genes on chromosomes 4A and 7B. To examine the effects of three Waxy (Wx) genes which encode a granule-bound starch synthase (Wx protein), the Wx proteins from CS monosomics of interest were analyzed using SDS-PAGE. The amount of the Wx protein coded by the Wx-B1 gene on chromosome arm 4AL was reduced in monosomic 4A, and thus accounted for its decreased amylose content. The amounts of two other Wx proteins coded by the Wx-A1 and Wx-D1 genes on chromosome arms 7AS and 7DS, respectively, showed low levels of protein in the monosomics but no effect on amylose content. The effect of chromosome 7B on the level of amylose suggested the presence of a regulator gene which suppresses the activities of the Wx genes.     

Differential effects of the null alleles at the three Wx loci on the starch-pasting properties of wheat

The amylose/amylopectin ratio and the pasting properties of wheat starch are important in producing marketable flour products, especially Japanese noodles. To determine if null mutations at the three Wx loci confer differences in starch-pasting viscosity, we analyzed the variation associated with the null mutations in three separate sets of recombinant substitution lines of chromosomes 7A, 4A and 7D produced from crosses between Chinese Spring and three single-chromosome substitution lines carrying the null Wx alleles. Differential effects of null alleles at the three Wx loci on starch-pasting properties were revealed. With respect to chromosome 4A, the effect of the Wx-B1b allele, giving a higher peak and breakdown viscosity, was unambiguous. In addition, a QTL of minor effect was identified near the centromere on the short arm. The presence or absence of the Wx-A1 protein gave some variation in peak and breakdown viscosity, but the effects of Wx-Alb were much smaller than those of the Wx-Blb allele. Associated effects of the Wx-D1 locus were detected for the breakdown viscosity as the null Wx-D1b allele produced a higher viscosity than the wild-type Wx-D1a. While negative correlations between amylose content and breakdown viscosity were common in the three populations, the null mutations at the Wx loci produced some variation independent of amylose content. The genetic variation detected for breakdown viscosity was more evident than that for peak viscosity in all three recombinant populations. Received: 20 July 1999 / Accepted: 7 October 1999     

Identification of SNPs in the<Emphasis Type="Italic"> waxy</Emphasis> gene among glutinous rice cultivars and their evolutionary significance during the domestication process of rice

Common non-waxy (Wx) rice cultivars contain two different alleles at the waxy locus, designated Wx ^a and Wx ^b, which encode different levels of granule-bound starch synthases and are hence involved in the control of endosperm amylose content. The Wx ^a allele was predominant in non-waxy indica cultivars, whereas the Wx ^b allele was common to the non-waxy japonica variety. Recently, some of the molecular mechanisms underlying the differentiation of Wx ^a from Wx ^b have been characterized. One structural difference between these two alleles was shown to be due to alternative splicing caused by a single-base substitution (AGGT to AGTT) at a donor site of the first intron within the Wx gene. In the case of waxy (wx) rice, it was not possible to distinguish whether the each wx allele was derived from Wx ^a or Wx ^b alleles by phenotypic analysis. However, we succeeded in developing a derived cleaved amplified polymorphic sequence (dCAPS) marker for the detection of the one-base splicing mutation without the need for sequencing. A mismatch primer was used to generate a restriction site in the Wx ^a allele (AGGT) but not in the Wx ^b allele (AGTT). Three hundred fifty-three waxy rice strains that are widely found in Asia were then employed for analysis using this dCAPS marker. Our findings suggested that waxy rice strains have both Wx ^a- and Wx ^b-derived alleles, but that the Wx ^b-derived allele was predominant, and its distribution was independent of indica-japonica differentiation. The wild relatives of cultivated rice all possessed the AGGT allele. It was concluded that the waxy mutations, and the corresponding rice cultivation, originated from japonica during the evolution and domestication process of rice and was preferentially selected by most Asian peoples.Communicated by J. Heslop-Harrison     

Modulation of amylose content by structure‐based modification of OsGBSS1 activity in rice (Oryza sativa L.)

The rice Waxy (Wx) gene encodes granule‐bound starch synthase 1 (EC 2.4.1.242), OsGBSS1, which is responsible for amylose synthesis in rice seed endosperm. In this study, we determined the functional contribution of eight amino acids on the activity of OsGBSS1 by introducing site‐directed mutated Wx gene constructs into the wx mutant glutinous rice. The eight amino acid residues are suspected to play roles in OsGBSS1 structure maintenance or function based on homologous enzyme sequence alignment and homology modelling. Both OsGBSS1 activity and amylose content were analysed in homozygous transgenic lines carrying the mutated OsGBSS1 (Wx) genes. Our results indicate that mutations at diverse sites in OsGBSS1 reduces its activity by affecting its starch‐binding capacity, its ADP‐glucose‐binding capability or its protein stability. Our results shed new light on the structural basis of OsGBSS1 activity and the mechanisms of OsGBSS1 activity on amylose synthesis in vivo. This study also demonstrates that it is feasible to finely modulate amylose content in rice grains by modifying the OsGBSS1 activity.     

Allelic diversification at the <Emphasis Type="Italic">wx</Emphasis> locus in landraces of Asian rice

To examine continuous variation of amylose levels in Asian rice (Oryza sativa) landraces, the five putative alleles (Wx ^a , Wx ⁱⁿ , Wx ^b , Wx ^op , and wx) at the wx locus were investigated in near-isogenic lines (NILs). Apparent amylose levels ranged from 0.5 to 29.9% in the NILs, showing a positive relation with the levels of Wx gene product, granule-bound starch synthase (GBSS) as well as the enzymatic activity per milligram starch granule. Only opaque (Wx ^op ) accessions had an enzymatic activity per GBSS that was reduced to half the level of the others. Nucleotide sequences in the Wx gene were compared among 18 accessions harboring the five different alleles. Each of the Wx alleles had a unique replacement, frame-shift or splice donor site mutation, suggesting that these nucleotide changes could be reflected in phenotype alterations. A molecular phylogenetic tree constructed using the Wx gene indicated that ssp. japonica forms a distinct clade, whereas ssp. indica forms different clades together with the wild progenitor. Unexpectedly, the wx allele of 160 (indica from Taiwan) joined the japonica lineage; however, comparisons using linked genes for two Taiwanese accessions revealed that the wx gene was the product of gene flow from japonica to indica. Therefore, the japonica lineage frequently included Wx ⁱⁿ , Wx ^b and wx, while Wx ^a and Wx ^op were found in the other lineages, strongly suggesting that allelic diversification occurred after divergence of the two subspecies. The present results were discussed in relation to the maintenance of agronomically valuable genes in various landraces.     

Microsatellites and a single-nucleotide polymorphism differentiate apparentamylose classes in an extended pedigree of US rice germ plasm

 The Waxy gene (Wx) encodes the granule-bound starch synthase responsible for the synthesis of amylose in rice (Oryza sativa). Recently, a polymorphic microsatellite sequence closely linked to the Wx gene was reported. To determine whether polymorphism in this sequence correlates with variation in apparent amylose content, we tested an extended pedigree of 92 current and historically important long-, medium- and short-grain US rice cultivars representing the efforts of many breeders over more than 80 years. Seven Wx microsatellite alleles were identified which together explained 82.9% of the variation in apparent amylose content of the 89 non-glutinous rice cultivars tested. Similar results were also obtained with 101 progenyof a cross between low- and intermediate-amylose breeding lines. An additional, unique microsatelliteallele, (CT)₁₆, was detected in one glutinous cultivar,CI 5309. However, the other glutinous cultivars,Calmochi 101 and Tatsumi mochi, were in the (CT)₁₇ class along with three other cultivars that contained15–16.5% amylose. We sequenced a 200-bp PCR-amplified fragment containing the CT microsatellite and the putative 5′ splice site of the Wx leader intron from a subset of 42 cultivars representing all eight microsatellite alleles. All of the cultivars with 18% or less amylose had the sequence AGTTATA at the putative leader intron 5′ splice site, while all cultivars with a higher proportionof amylose had AGTTATA. This single nucleotidesubstitution could also be assayed by AccI digestion of the amplified fragment. Overall, this single nucleotide polymorphism could explain 79.7% of the variation in the apparent amylose content of the 89 non-glutinous cultivars tested. Interestingly, cultivars in the (CT)₁₉ microsatellite classes that differed substantially in amylose content still showed the correlation between this G-T polymorphism and apparent amylose content. The G-T polymorphism at this site was not, however, able to explain the very low amylose contents of the three glutinous cultivars tested, all of which had the sequence AGTTATA. Received: 31 July 1996 / Accepted: 22 November 1996     

Microsatellites, single nucleotide polymorphisms and a sequence tagged site in starch-synthesizing genes in relation to starch physicochemical properties in nonwaxy rice (Oryza sativa L.)

Starch characteristics determine the quality of various products of rice, e.g., eating, cooking and processing qualities. Our previous study indicated that molecular markers inside or close to starch synthesizing genes can differentiate the starch properties of 56 waxy rices. Here we report microsatellite (or simple sequence repeat, SSR) polymorphism in the Waxy (Wx) gene, soluble starch synthase I gene (SS1) and starch branching enzyme 1 gene (SBE1), single nucleotide polymorphism (SNP) in Wx and starch branching enzyme 3 gene (SBE3), and a sequence tagged site (STS) in starch branching enzyme 1 gene (SBE1) among 499 nonwaxy rice samples and their relationships with starch physicochemical properties. The nonwaxy rice samples consist of landraces (n = 172) obtained from germplasm centers and cultivars and breeding lines (n = 327) obtained from various breeding programs. Ten (CT) _n microsatellite alleles, (CT)₈, (CT)₁₀, (CT)₁₁, (CT)_12, (CT)₁₇, (CT)₁₈, (CT)₁₉, (CT)₂₀, (CT)₂₁, and (CT)₂₂, were found at the Wx locus, of which (CT)₁₁ was the most frequent, and (CT)₁₂, (CT)₂₁ and (CT)₂₂ were identified for the first time. Four (CT) _n microsatellite alleles were found at the SBE1 locus, (CT)₈, (CT)₉, and (CT)₁₀ together with an insertion sequence of CTCTCGGGCGA, and (CT)₈ alone without the insertion, of which (CT)₉ and the insertion was a new allele identified in only one rice, IR1552. Multiple microsatellites clustered at the SS1 locus, and in addition to the three alleles previously detected (SSS-A = (AC)₂...TCC(TC)₁₁...(TC)₅C(ACC)₁₁, SSS-B = (AC)₃...TCT(TC)₆...(TC)₄C(ACC)₉, and SSS-C = (AC)₃...TCT(TC)₆...(TC)₄C(ACC)₈), one new allele (SSS-D = (AC)₂...TCC(TC)₁₀...(TC)₄C(ACC)₉) was found. Analysis of the starch physicochemical properties of the samples with different microsatellites, SNPs and STS groups indicated that these molecular markers can differentiate almost all the physicochemical properties examined, e.g., apparent amylose content (AAC), pasting viscosity characteristics, and gel textural properties. Wx SSR and Wx SNP alone explained more variations for all physicochemical properties than the other molecular markers. The total six markers could explain 92.2, 81 and 86% of total variation of AAC, gel hardness (HD), and gel cohesiveness (COH), respectively, and they could explain more than 40% of the total variation of hot paste viscosity (HPV), cool paste viscosity (CPV), breakdown viscosity (BD), setback viscosity (SB) and gel adhesiveness (ADH). However, only 29% of the total variation of peak viscosity (PV) and 37% of pasting temperature (PT) could be explained by all the molecular markers. Some of these markers can differentiate the starch physicochemical properties among the rice samples with the same Wx allele, indicating that the variation within Wx allele classes can be explained by other starch synthesizing genes. These SSRs, SNPs and STS are useful in marker-assisted breeding for the improvement of starch quality of rice.Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

Dosage effects of the three Wx genes on amylose synthesis in wheat endosperm

Amylose synthesis in wheat endosperm is mainly controlled by the granule-bound starch synthase of about 60 kDa, the so-called waxy (Wx) protein. The Wx proteins are the product of the Wx genes at a triplicate set of single-copy homoeoloci located on chromosomes 7A (Wx-A1), 4A (Wx-B1) and 7D (Wx-D1). Using Chinese Spring and its aneuploid lines, including nullisomic-tetrasomics, tetrasomics, ditelosomics and deletion stocks, together with single-chromosome substitution lines for these chromosomes, the effects of varying the dosage of whole chromosomes and chromosome arms, as well as the effects of null alleles, upon amylose synthesis were investigated. Nullisomic 4A and the deletion of chromosome segments carrying the Wx-B1 gene reduced the amylose content by more than 3%. A reasonable agreement was found in the substitution lines. This confirms that the absence of the Wx-B1 gene, or else substitution of this gene by its null allele, has the most striking effect on decreasing amylose synthesis. The removal of chromosomes carrying either the Wx-A1 or the Wx-D1 gene reduces the amylose content by less than 2%. A similar reduction was revealed by substitution of these two genes by the null alleles. Double dosages of chromosomes 7A, 4A and 7D did not increase amylose content, while the tetrasomic chromosomes produced more of the respective Wx proteins. This suggests that a certain level of Wx gene activity or of the Wx proteins led to the maximum amount of amylose.     

Production of novel allelic variation for genes involved in starch biosynthesis through mutagenesis

Given the important role that starch plays in food and non-food uses of many crops, particularly wheat, efforts are being made to manipulate its composition through modification of the amylose/amylopectin ratio. Approaches used to achieve this goal include the manipulation of the genes involved in the starch biosynthetic pathway using natural or induced mutations and transgenic methods. The use of mutagenesis to produce novel allelic variation represents a powerful tool to increase genetic diversity and this approach seems particularly appropriate for starch synthase genes for which limited variation exists. In this work, an EMS-mutagenised population of bread wheat cv. Cadenza has been screened by combining SDS–PAGE analysis of granule bound starch proteins with a TILLING (Targeting Induced Local Lesions IN Genomes) approach at the gene level. In particular we have focused on two groups of synthase genes, those encoding the starch synthase II (Sgp-1) and those corresponding to the waxy proteins (Wx). SDS–PAGE analysis of granule bound proteins allowed the identification of single null genotypes associated with each of the three homoeologous loci. Molecular characterization of induced mutants has been performed using genome specific primer pairs for Sgp-1 and Wx genes. Additional novel allelic variation has also been detected at the different Sgp-1 homoeoloci by using a reverse genetic approach (TILLING). In particular single nucleotide substitutions, introducing a premature stop codon and creating amino acid substitutions, have been identified.     

Variability of grain quality in sorghum: association with polymorphism in Sh2, Bt2, SssI, Ae1, Wx and O2

To ensure food security in Africa and Asia, developing sorghum varieties with grain quality that matches consumer demand is a major breeding objective that requires a better understanding of the genetic control of grain quality traits. The objective of this targeted association study was to assess whether the polymorphism detected in six genes involved in synthesis pathways of starch (Sh2, Bt2, SssI, Ae1, and Wx) or grain storage proteins (O2) could explain the phenotypic variability of six grain quality traits [amylose content (AM), protein content (PR), lipid content (LI), hardness (HD), endosperm texture (ET), peak gelatinization temperature (PGT)], two yield component traits [thousand grain weight (TGW) and number of grains per panicle (NBG)], and yield itself (YLD). We used a core collection of 195 accessions which had been previously phenotyped and for which polymorphic sites had been identified in sequenced segments of the six genes. The associations between gene polymorphism and phenotypic traits were analyzed with Tassel. The percentages of admixture of each accession, estimated using 60 RFLP probes, were used as cofactors in the analyses, decreasing the proportion of false-positive tests (70%) due to population structure. The significant associations observed matched generally well the role of the enzymes encoded by the genes known to determine starch amount or type. Sh2, Bt2, Ae1, and Wx were associated with TGW. SssI and Ae1 were associated with PGT, a trait influenced by amylopectin amount. Sh2 was associated with AM while Wx was not, possibly because of the absence of waxy accessions in our collection. O2 and Wx were associated with HD and ET. No association was found between O2 and PR. These results were consistent with QTL or association data in sorghum and in orthologous zones of maize. This study represents the first targeted association mapping study for grain quality in sorghum and paves the way for marker-aided selection.     

Expression of a cassava granule-bound starch synthase gene in the amylose-free potato only partially restores amylose content

Granule-bound starch synthase I (GBSS I) is responsible for the synthesis of amylose in starch granules. A heterologous cassava GBSS I gene was tested for its ability to restore amylose synthesis in amylose-free (amf) potato mutants. For this purpose, the cassava GBSS I was equipped with different transit peptides. In addition, a hybrid containing the potato transit peptide, the N-terminal 89 amino acids of the mature potato GBSS I, and the C-terminal part of cassava GBSS I was prepared. The transgenic starches were first analysed by iodine staining. Only with the hybrid could full phenotypic complementation of the amf mutation be achieved in 13% of the plants. Most transformants showed partial complementation, but interestingly the size of the blue core was similar in all granules derived from one tuber of a given plant. The amylose content was only partially restored, up to 60% of wild-type values or potato GBSS I-complemented plants; however, the GBSS activity in these granules was similar to that found in wild-type ones. From this, and the observation that the hybrid protein (a partial potato GBSS I look-alike) performs best, it was concluded that potato and cassava GBSS I have different intrinsic properties and that the cassava enzyme is not fully adapted to the potato situation.