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.     

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.     

Using Heading date 1 preponderant alleles from indica cultivars to breed high‐yield,high‐quality japonica rice varieties for cultivation in south China

Heading date 1 (Hd1) is an important gene for the regulation of flowering in rice, but its variation in major cultivated rice varieties, and the effect of this variation on yield and quality, remains unknown. In this study, we selected 123 major rice varieties cultivated in China from 1936 to 2009 to analyse the relationship between the Hd1 alleles and yield‐related traits. Among these varieties, 19 haplotypes were detected in Hd1, including two major haplotypes (H8 and H13) in the japonica group and three major haplotypes (H14, H15 and H16) in the indica group. Analysis of allele frequencies showed that the secondary branch number was the major aimed for Chinese indica breeding. In the five major haplotypes, SNP₃₁₆(C‐T) was the only difference between the two major japonica haplotypes, and SNP₄₉₅(C‐G) and SNP₆₁₄(G‐A) are the major SNPs in the three indica haplotypes. Association analysis showed that H16 is the most preponderant allele in modern cultivated Chinese indica varieties. Backcrossing this allele into the japonica variety Chunjiang06 improved yield without decreasing grain quality. Therefore, our analysis offers a new strategy for utilizing these preponderant alleles to improve yield and quality of japonica varieties for cultivation in the southern areas of China.     

Selecting genetic transformants of indica and indica-derived rice cultivars using bispyribac sodium and a mutated ALS gene

Bispyribac sodium (BS), a pyrimidinyl carboxy herbicide, is a well-known inhibitor of acetolactate synthase (ALS) activity. ALS is an enzyme in the biosynthetic pathway for branched-chain amino acids. A mutant form of rice ALS (OsmALS [W548L/S627I]) that confers resistance to BS can be used as an in vitro selection marker gene for plant transformation. Since indica and indica-derived cultivars are thought to have lower BS sensitivity than japonica rice, the application of BS as a selectable reagent for genetic transformation in indica and indica-derived cultivars is more challenging than for japonica cultivars. In this study, callus and seedlings of eight different rice cultivars (five indica-derived cultivars, two indica cultivars and one japonica cultivar) were tested for BS sensitivity. Our study indicates for the first time that callus shows a higher sensitivity to BS than seedlings in indica and indica-derived cultivars. We used BS with OsmALS [W548L/S627I] to select transformed calli, and transgenic rice plants from indica and indica-derived cultivars were successfully obtained.     

Detection of allelic variation at the Wx locus with single-segment substitution lines in rice (Oryza sativa L.)

Apparent amylose content (AAC) is a key determinant of eating and cooking quality in rice and it is mainly controlled by the Wx gene which encodes a granule-bound starch synthase (GBSS). In this study, sixteen single-segment substitution lines harboring the Wx gene from 16 different donors and their recipient HJX74 were used to detect the naturally occurring allelic variation at the Wx locus. The AAC in the materials varied widely and could be grouped into glutinous, low, intermediate, and two high AAC sub-classes, high I (24.36?C25.20%) and high II (25.81?C26.19%), under different experimental environments, which showed a positive correlation with the enzymatic activity of GBSS. One insertion/deletion (InDel) and three single nucleotide polymorphisms in the Wx gene were detected and their combinations resulted in the variation of five classes of AAC. Based on the results of AAC phenotypes, GBSS activities and cDNA sequences, five Wx alleles, wx, Wx ^t, Wx ^g1, Wx ^g2, and Wx ^g3, were identified, two of which, Wx ^g2 and Wx ^g3, are separated for the first time in this study. Under different cropping seasons, the AAC differed significantly for the Wx ^t and Wx ^g1 alleles, with higher AAC in the fall season than in the spring season, but did not differ significantly for the wx, Wx ^g2, and Wx ^g3 alleles. In conclusion, the present results might contribute to our understanding of the naturally occurring allelic variation at the Wx locus and will facilitate the improvement of rice quality by marker-assisted selection.     

Two distinct <Emphasis Type="Italic">waxy</Emphasis> alleles impact the granule-bound starch synthase in sorghum

The granule-bound starch synthase (GBSS) is the enzyme responsible for amylose synthesis in starch granules. Loss of GBSS activity results in starch granules containing mostly amylopectin and little or no amylose, a phenotype described as waxy. Previously, two phenotypic classes of waxy alleles were identified in sorghum (Sorghum bicolor L. Moench) characterized by the absence (waxy ^a ; wx ^a ) or presence (waxy ^b ; wx ^b ) of the GBSS protein in the endosperm. To characterize these alleles, we examined endosperm architecture using scanning electron microscopy (SEM), assayed GBSS enzymatic activities, and identified DNA lesions associated with the mutations in the GBSS (Sb10g002140) gene. wx ^a , the allele present in B Tx630 and R Tx2907, contained a large insertion in the third exon, which was consistent with the absence of the GBSS protein previously observed. wx ^b , the allele present in B 9307 and B TxARG1, contained a missense mutation that resulted in conversion of glutamine 268 to histidine in a conserved domain in starch synthases. In wx ^b , GBSS activity was less than 25% that of the non-waxy line B Wheatland, and GBSS activity was not detected in wx ^a . SEM showed that endosperm architecture was very similar in both wx ^a and wx ^b alleles, but altered in comparison to non-waxy lines R Tx430 and B Wheatland. Both alleles may have a range of potential applications in grain sorghum because of low amylose content in their starch and the presence or absence of the GBSS protein. PCR based markers were developed for both the wx ^a and the wx ^b alleles to aid in molecular breeding of low amylose sorghum.     

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.     

Identification of neutral alleles at pollen sterility gene loci of cultivated rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) from wild rice (<Emphasis Type="Italic">O. rufipogon</Emphasis> Griff.)

Oryza rufipogon Griff. is the ancestor of Asian cultivated rice (O. sativa L.) and possesses valuable genes for rice breeding. Pollen abortion is one of the major causes of indica–japonica hybrid sterility in rice and it happens due to allelic interaction at the pollen sterility gene loci. A total of six loci (Sa, Sb, Sc, Sd, Se, and Sf) have been found to be associated with F₁ pollen sterility between indica and japonica rice, and five of them (all except Sf) have been mapped. Neutral alleles (S ⁿ ) at each locus have the potential to overcome the pollen sterility associated with the respective locus. Therefore, exploitation and utilization of neutral alleles have significant importance in overcoming indica–japonica hybrid sterility. In this study, an accession (IRW28) of O. rufipogon, native to China, was selected as paternal to cross with typical japonica (Taichung 65) and indica (Guanglu’ai 4) tester lines, and two F₂ populations were developed. The simple sequence repeat markers tightly linked to five pollen sterility loci were applied for genotyping the F₂ populations. Chi-squared tests were applied to examine the normal segregation/distortion at each locus. The expected and observed pollen sterility for each locus were estimated. As a result, the genotypes at five pollen sterility gene loci for IRW28 were identified as: Sa ⁱ⁻¹/Sa ⁱ⁻¹, Sb ⁿ /Sb ⁿ , Sc ⁱ⁻²/Sc ⁱ⁻², Sd ⁿ /Sd ⁿ and Se ⁿ /Se ⁿ . Our results suggest that IRW28 (O. rufipogon) has the neutral alleles for pollen fertility at the Sb, Sd and Se loci, and these alleles have a good affinity with indica and japonica rice. These neutral alleles provide valuable gene resources to overcome the inter-subspecific hybrid pollen sterility in rice.     

The Spm (En) transposable element controls the excision of a 2-kb DNA insert at the wx allele of Zea mays

The waxy (Wx) locus of Zea mays was cloned from strains carrying the wild-type and wx^m-8 mutant alleles. The receptor component of the Suppressor-Mutator (Spm) controlling element system in the wx^m-8 allele was shown to be a 2 kb long insertion within the transcribed region of the Wx gene. The insertion, termed Spm-I8, is excised during somatic reversion events induced by the autonomous controlling element Enhancer (En), which is an equivalent to Spm. Integration of Spm-I8 into the Wx gene generates a 3-bp target site duplication. Spm-I8 has a 13 bp long inverted repeat at its termini. The ends of the element can be further folded to build a large double-stranded structure consisting of five perfectly matching double-stranded regions of 9–13 bp in length, interrupted by single-stranded loops. A comparison of the wild-type and wx^m-8 alleles revealed two additional insertions 6 (insert-1) and 0.25 (insert-2) kb in length. No En-induced excision of insert-1 and insert-2 could be detected so far. There is remarkable structure and sequence homology between Spm-I8 and the transposable elements Tam1 and Tam2 of Antirrhinum majus at their termini, reflecting a possible evolutionary and/or functional relationship between transposons in different plant species.     

Molecular mapping and location of QTLs for drought-resistance traits in <Emphasis Type="Italic">indica</Emphasis> rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.) lines adapted to target environments

Drought is a major limitation for rice production in rainfed ecosystems. Identifying quantitative trait loci (QTLs) linked to drought resistance provides opportunity to breed high yielding rice varieties suitable for drought-prone areas. Although considerable efforts were made in mapping QTLs associated with drought-resistance traits in rice, most of the studies involved indica × japonica crosses and hence, the drought-resistance alleles were contributed mostly by japonica ecotypes. It is desirable to look for genetic variation within indica ecotypes adapted to target environment (TE) as the alleles from japonica ecotype may not be expressed under lowland conditions. A subset of 250 recombinant inbred lines (RILs) of F₈ generation derived from two indica rice lines (IR20 and Nootripathu) with contrasting drought-resistance traits were used to map the QTLs for morpho-physiological and plant production traits under drought stress in the field in TE. A genetic linkage map was constructed using 101 polymorphic PCR-based markers distributed over the 12 chromosomes covering a total length of 1,529 cM in 17 linkage groups with an average distance of 15.1 cM. Composite interval mapping analysis identified 22 QTLs, which individually explained 4.8–32.2% of the phenotypic variation. Consistent QTLs for drought-resistance traits were detected using locally adapted indica ecotypes, which may be useful for rainfed rice improvement.     

Major QTLs reduce the deleterious effects of high temperature on rice amylose content by increasing splicing efficiency of Wx pre-mRNA

Key message

We discovered four QTLs that maintain proper rice amylose content at high temperature by increasing the splicing efficiency of Wx gene.

Abstract

Amylose content mainly controlled by Wx gene is a key physicochemical property for eating and cooking quality in rice. During the grain filling stage, high temperature can harm rice grain quality by significantly reducing the amylose content in many rice varieties. Here, we provide genetic evidences between Wx gene expression and rice amylose content at high temperature, and identified several quantitative trait loci (QTLs) in this pathway. We performed a genome-wide survey on a set of chromosome segment substitution lines (CSSLs) which carried chromosomal segments from the heat resistant indica 9311 in the heat-sensitive japonica Nipponbare background. Four QTLs, qHAC4, qHAC8a, qHAC8b and qHAC10, which can reduce the deleterious effects of amylose content at high temperature, were identified and mapped to chromosome 4, 8, 8 and 10, respectively. The major QTL qHAC8a, with the highest LOD score of 6.196, was physically mapped to a small chromosome segment (~300 kb). The CSSLs carrying the qHAC8a, qHAC8b and/or qHAC4 from 9311 have the high pre-mRNA splicing efficiency of Wx gene and likely lead to stable amylose content at high temperature. Thus, increasing pre-mRNA processing efficiency of Wx gene could be an important regulation mechanism for maintaining stable amylose content in rice seeds at high temperature. In addition, our results provide a theoretical basis for breeding heat-stable grain in rice.     

Single-seeded InDel fingerprints in rice:An effective tool for indica-japonica rice classification and evolutionary studies

Asian cultivated rice(Oryza sativa L.),an important cereal crop worldwide,was domesticated from its wild ancestor 8000 years ago.During its long-term cultivation and evolution under diverse agroecological conditions, Asian cultivated rice has differentiated into indica and japonica subspecies.An effective method is required to identify rice germplasm for its indica and japonica features,which is essential in rice genetic improvements.We developed a protocol that combined DNA extraction from a single rice seed and the insertion/deletion(InDel) molecular fingerprint to determine the indica and japonica features of rice germplasm.We analyzed a set of rice germplasm,including 166 Asian rice varieties,two African rice varieties,30 accessions of wild rice species,and 42 weedy rice accessions,using the single-seeded InDel fingerprints(SSIF).The results show that the SSIF method can efficiently determine the indica and japonica features of the rice germplasm.Further analyses revealed significant indica and japonica differentiation in most Asian rice varieties and weedy rice accessions.In contrast,African rice varieties and nearly all the wild rice accessions did not exhibit such differentiation.The pattern of cultivated and wild rice samples illustrated by the SSIF supports our previous hypothesis that indica and japonica differentiation occurred after rice domestication under different agroecological conditions.In addition,the divergent pattern of rice cultivars and weedy rice accessions suggests the possibility of an endoferal origin(from crop)of the weedy rice included in the present study.     

Global dissemination of a single mutation conferring white pericarp in rice

Here we report that the change from the red seeds of wild rice to the white seeds of cultivated rice (Oryza sativa) resulted from the strong selective sweep of a single mutation, a frame-shift deletion within the Rc gene that is found in 97.9% of white rice varieties today. A second mutation, also within Rc, is present in less than 3% of white accessions surveyed. Haplotype analysis revealed that the predominant mutation originated in the japonica subspecies and crossed both geographic and sterility barriers to move into the indica subspecies. A little less than one Mb of japonica DNA hitchhiked with the rc allele into most indica varieties, suggesting that other linked domestication alleles may have been transferred from japonica to indica along with white pericarp color. Our finding provides evidence of active cultural exchange among ancient farmers over the course of rice domestication coupled with very strong, positive selection for a single white allele in both subspecies of O. sativa.