Distribution and mapping of an active autonomous <Emphasis Type="Italic">aDart</Emphasis> element responsible for mobilizing nonautonomous <Emphasis Type="Italic">nDart1</Emphasis> transposons in cultivated rice varieties

An endogenous 0.6-kb rice DNA transposon, nDart1, has been identified as a causative element of a spontaneous mutable virescent allele pyl-v conferring pale-yellow leaves with dark-green sectors in the seedlings, due to somatic excision of nDart1 integrated into the OsClpP5 gene encoding the nuclear-coded chloroplast protease. As the transposition of nDart1 depends on the presence of an active autonomous aDart element in the genome, the plants exhibiting the leaf variegation carry the active aDart element. As several mutable alleles caused by nDart1 insertions have subsequently been identified, nDart1-promoted gene tagging has been proven to be an effective system. At present, the nDart/aDart system appears to be the only endogenous rice DNA transposon system whose transposition activity can be controlled under natural growth conditions without any artificial treatments, including tissue cultures. To apply the nDart/aDart tagging system in various cultivated rice varieties, we explored the presence and distribution of an active autonomous aDart element in 19 temperate japonica, 30 tropical japonica, and 51 indica varieties. Only eight temperate japonica varieties were found to bear a single copy of an active aDart element, and no aDart activity could be detected in the indica varieties examined. Six of seven japonica varieties appear to carry the active aDart element at the identical site on chromosome 6, whereas the remaining one contains aDart on chromosome 5. Leaf variegations in the plants with the mutable pyl-v allele and the excision frequencies of endogenous nDart1 elements indicated that the aDart element on chromosome 6 is more active than that on chromosome 5. The findings described here are an important step in the development of a new and efficient nDart1-promoted gene-tagging system in various rice cultivars. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Site specific cytosine methylation in rice nonautonomous transposable element <Emphasis Type="Italic">nDart</Emphasis>

The mobile nonautonomous element nDart, which is active in intact rice plants, exhibits locus specific transposition. Due to the high homogeneity of nDart elements, the locus specificity of nDart transposition might be controlled by factors other than genetic differences. In this study, we elucidated the regulation of the locus specificity of nDart transposition. The difference of transpositional activities in 10 nDart elements among rice varieties exhibiting nDart transposition was clearly correlated with the methylation state of nDart elements. Both hyper- and hypo-methylated nDart elements were inactive, while site specific methylation in both subterminal regions was identified in active nDart loci. The specific methylation sites contain the pentamer motif GCC/ACG. The repeated motifs in the subterminal region of nDart elements may contribute to the stable secondary structure of nDart elements with low free energy. Our results suggested that site specific cytosine methylation may loosen the stable secondary structure of the nDart element to allow it to bind TPase, which then perform the excision of nDart elements from genomic loci.     

Identification of an active <Emphasis Type="Italic">Mutator</Emphasis>-like element (MULE) in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis>)

Transposable elements (TEs) represent an important fraction of plant genomes and play a significant role in gene and genome evolution. Among all TE superfamilies discovered in plants, Mutator from maize (Zea mays) is the most active and mutagenic element. Mutator-like elements (MULEs) were identified in a wide range of plants. However, only few active MULEs have been reported, and the transposition mechanism of the elements is still poorly understood. In this study, an active MULE named Os3378 was discovered in rice (Oryza sativa) by a combination of computational and experimental approaches. The four newly identified Os3378 elements share more than 98% sequence identity between each other, and all of them encode transposases without any deletion derivatives, indicating their capability of autonomous transposition. Os3378 is present in the rice species with AA genome type but is absent in other non-AA genome species. A new insertion of Os3378 was identified in a rice somaclonal mutant Z418, and the element remained active in the descendants of the mutant for more than ten generations. Both germinal and somatic excision events of Os3378 were observed, and no footprint was detected after excision. Furthermore, the occurrence of somatic excision of Os3378 appeared to be associated with plant developmental stages and tissue types. Taken together, Os3378 is a unique active element in rice, which provides a valuable resource for further studying of transposition mechanism and evolution of MULEs.     

Characterization and genetic analysis of a low-temperature-sensitive mutant, <Emphasis Type="Italic">sy</Emphasis>-<Emphasis Type="Italic">2</Emphasis>, in <Emphasis Type="Italic">Capsicum chinense</Emphasis>

A temperature-sensitive mutant of Capsicum chinense, sy-2, shows a normal developmental phenotype when grown above 24°C. However, when grown at 20°C, sy-2 exhibits developmental defects, such as chlorophyll deficiency and shrunken leaves. To understand the underlying mechanism of this temperature-dependent response, phenotypic characterization and genetic analysis were performed. The results revealed abnormal chloroplast structures and cell collapse in leaves of the sy-2 plants grown at 20°C. Moreover, an excessive accumulation of reactive oxygen species (ROS) resulting in cell death was detected in the chlorophyll-deficient sectors of the leaves. However, the expression profile of the ROS scavenging genes did not alter in sy-2 plants grown at 20°C. A further analysis of fatty acid content in the leaves showed the impaired pathway of linoleic acid (18:2) to linolenic acid (18:3). Additionally, the Cafad7 gene was downregulated in sy-2 plants. This change may lead to dramatic physiological disorder and alteration of leaf morphology in sy-2 plants by losing low-temperature tolerance. Genetic analysis of an F₂ population from a cross between C. chinense ‘sy-2’ and wild-type C. chinense ‘No. 3341’ showed that the sy-2 phenotype is controlled by a single recessive gene. Molecular mapping revealed that the sy-2 gene is located at a genomic region of the pepper linkage group 1, corresponding to the 300 kb region of the Ch1_scaffold 00106 in tomato chromosome 1. Candidate genes in this region will reveal the identity of sy-2 and the underlying mechanism of the temperature-dependent plant response.     

Marker-assisted breeding of a photoperiod-sensitive male sterile <Emphasis Type="Italic">japonica</Emphasis> rice with high cross-compatibility with <Emphasis Type="Italic">indica</Emphasis> rice

The incomplete fertility of japonica × indica rice hybrids has inhibited breeders’ access to the substantial heterotic potential of these hybrids. As hybrid sterility is caused by an allelic interaction at a small number of loci, it is possible to overcome it by simple introgression at the major sterility loci. Here we report the use of marker-assisted backcrossing to transfer into the elite japonica cv. Zhendao88 a photoperiod-sensitive male sterility gene from cv. Lunhui422S (indica) and the yellow leaf gene from line Yellow249 (indica). The microsatellite markers RM276, RM455, RM141 and RM185 were used to tag the fertility genes S5, S8, S7 and S9, respectively. Line 509S is a true-breeding photoperiod-sensitive male sterile plant, which morphologically closely resembles the japonica type. Genotypic analysis showed that the genome of line 509S comprises about 92% japonica DNA. Nevertheless, hybrids between line 509S and japonica varieties suffer from a level of hybrid sterility, although the line is highly cross-compatible with indica types, with the resulting hybrids expressing a significant degree of heterosis. Together, these results suggest that segment substitution on fertility loci based on known information and marker-assisted selection are an effective approach for utilizing the heterosis of rice inter-subspecies.     

Molecular evolution of the clustered <Emphasis Type="Italic">MIC</Emphasis>-<Emphasis Type="Italic">3</Emphasis> multigene family of <Emphasis Type="Italic">Gossypium</Emphasis> species

The Gossypium MIC-3 (Meloidogyne Induced Cotton-3) gene family is of great interest for molecular evolutionary studies because of its uniqueness to Gossypium species, multi-gene content, clustered localization, and root-knot nematode resistance-associated features. Molecular evolution of the MIC-3 gene family was studied in 15 tetraploid and diploid Gossypium genotypes that collectively represent seven phylogenetically distinct genomes. Synonymous (d_S) and non-synonymous (d_N) nucleotide substitution rates suggest that the second of the two exons of the MIC-3 genes has been under strong positive selection pressure, while the first exon has been under strong purifying selection to preserve function. Based on nucleotide substitution rates, we conclude that MIC-3 genes are evolving by a birth-and-death process and that a ‘gene amplification’ mechanism has helped to retain all duplicate copies, which best fits with the “bait and switch” model of R-gene evolution. The data indicate MIC-3 gene duplication events occurred at various rates, once per 1 million years (MY) in the allotetraploids, once per ~2 MY in the A/F genome clade, and once per ~8 MY in the D-genome clade. Variations in the MIC-3 gene family seem to reflect evolutionary selection for increased functional stability, while also expanding the capacity to develop novel “switch” pockets for responding to diverse pests and pathogens. Such evolutionary roles are congruent with the hypothesis that members of this unique resistance gene family provide fitness advantages in Gossypium.     

<Emphasis Type="Italic">osa</Emphasis>-<Emphasis Type="Italic">MIR393</Emphasis>: a salinity- and alkaline stress-related microRNA gene

Salinity and alkalinity are the two main environmental factors that limit rice production. Better understanding of the mechanisms responsible for salinity and alkaline stress tolerance would allow researchers to modify rice to increase its resistance to salinity and alkaline stress. MicroRNAs (miRNAs) are ~21-nucleotide RNAs that are ubiquitous regulators of gene expression in eukaryotic organisms. Some miRNAs acts as an important endogenous regulator in plant responses to abiotic stressors. miR393 is a conservative miRNA family that occurs in a variety of different plants. The two members of the miR393 family found in rice are named osa-MIR393 and osa-MIR393b. We found that the osa-MIR393 expression level changed under salinity and alkaline stress, whereas that of osa-MIR393b did not. Target genes of osa-MIR393 were predicted, and some of these putative targets are abiotic related genes. Furthermore, we generated transgenic rice and Arabidopsis thaliana that over-expressed osa-MIR393, and the phenotype analysis showed that these transgenic plants were more sensitive to salt and alkali treatment compared to wild-type plants. These results illustrate that over-expression of osa-MIR393 can negatively regulate rice salt-alkali stress tolerance.     

Phylogenetic analyses of <Emphasis Type="Italic">Uromyces viciae-fabae</Emphasis> and its varieties on <Emphasis Type="Italic">Vicia</Emphasis>, <Emphasis Type="Italic">Lathyrus</Emphasis>, and <Emphasis Type="Italic">Pisum</Emphasis> in Japan

A pea rust fungus, Uromyces viciae-fabae, has been classified into two varieties, var. viciae-fabae and var. orobi, based on differences in urediniospore wall thickness and putative host specificity in Japan. In principal component analyses, morphological features of urediniospores and teliospores of 94 rust specimens from Vicia, Lathyrus, and Pisum did not show definite host-specific morphological groups. In molecular analyses, 23 Uromyces specimens from Vicia, Lathyrus, and Pisum formed a single genetic clade based on D1/D2 and ITS regions. Four isolates of U. viciae-fabae from V. cracca and V. unijuga could infect and sporulate on P. sativum. These results suggest that U. viciae-fabae populations on different host plants are not biologically differentiated into groups that can be recognized as varieties.Contribution no. 184, Laboratory of Plant Parasitic Mycology, Institute of Agriculture and Forestry, University of Tsukuba, Japan     

Transpositional activation of <Emphasis Type="Italic">mPing</Emphasis> in an asymmetric nuclear somatic cell hybrid of rice and <Emphasis Type="Italic">Zizania latifolia</Emphasis> was accompanied by massive element loss

We have reported previously that the most active miniature inverted terminal repeat transposable element (MITE) of rice, mPing, was transpositionally mobilized in several rice recombinant inbred lines (RILs) derived from an introgressive hybridization between rice and wild rice (Zizania latifolia Griseb.). To further study the phenomenon of hybridization-induced mPing activity, we undertook the present study to investigate the element’s behavior in a highly asymmetric somatic nuclear hybrid (SH6) of rice and Z. latifolia, which is similar in genomic composition to that of the RILs, though probably contains more introgressed alien chromatins from the donor species than the RILs. We found that mPing, together with its transposase-donor, Pong, underwent rampant transpositional activation in the somatic hybrid (SH6). Because possible effects of protoplast isolation and cell culture can be ruled out, we attribute the transpositional activation of mPing and Pong in SH6 to the process of asymmetric somatic hybridization, namely, one-step introgression of multiple chromatin segments of the donor species Z. latifolia into the recipient rice genome. A salient feature of mPing transposition in the somatic hybrid is that the element’s activation was accompanied by massive loss of its original copies, i.e., abortive transpositions, which was not observed in previously reported cases of mPing activity. These data not only corroborated our earlier finding that wide hybridization and introgression may trigger transpositional activation of otherwise quiescent transposable elements, but also suggest that transpositional mobilization of a MITE like mPing can be accompanied by dramatic reduction of its original copy numbers under certain conditions, thus provide novel insights into the dynamics of MITEs in the course of genome evolution.     

<Emphasis Type="Italic">CDPK</Emphasis> gene expression in somatic embryos of <Emphasis Type="Italic">Panax ginseng</Emphasis> expressing <Emphasis Type="Italic">rolC</Emphasis>

A somatic embryogenesis protocol for plant regeneration of northern red oak (Quercus rubra) was established from immature cotyledon explants. Embryogenic callus cultures were induced on Murashige and Skoog medium (MS) containing 3% sucrose, 0.24% Phytagel™, and various concentrations of 2,4-dichlorophenoxyacetic acid (2,4-d) after 4 weeks of culture in darkness. A higher response (66%) of embryogenic callus was induced on 0.45 μM 2,4-d. Higher numbers of globular- (31), heart- (17), torpedo- (12), and cotyledon-stage (8) embryos per explant were obtained by culturing embryogenic callus on MS with 3% sucrose, 0.24% Phytagel™, and devoid of growth regulators after 8 weeks culture in darkness. Continuous sub-culturing of embryogenic callus on medium containing 2,4-d yielded only compact callus. Desiccation of embryos for 3 days in darkness at 25 ± 2°C followed by cold storage at 4°C in darkness for 8 weeks favored embryo germination and development of plantlets. Cotyledon-stage embryos subjected to desiccation and chilling treatment cultured on MS with 3% sucrose, 0.24 Phytagel™, 0.44 μM 6-benzylaminopurine (BA), and 0.29 μM gibberellic acid germinated at a higher frequency (61%) than with 0.44 μM BA alone and control cultures. Germinated plantlets developed a shoot and root, were acclimatized successfully, and maintained in a growth room for plantlet development.     

<Emphasis Type="Italic">MDM</Emphasis>-1 and <Emphasis Type="Italic">MDM</Emphasis>-2: Two <Emphasis Type="Italic">Mutator</Emphasis>-Derived MITE Families in Rice

Abstract Numerous miniature inverted repeat transposable elements (MITEs) are present in the rice genome but their transposition mechanisms are unknown. In this report, we present evidence that two novel MITE families may have arisen from Mutator-related transposable elements and thus may use a transposition mechanism similar to that of Mutator elements. Two families of novel MITEs, namely, MDM-1 and MDM-2, were identified by searching for MITEs nested with Kiddo, a previously identified MITE family. MDM-1 and MDM-2 bear hallmarks of Mutator elements, such as long terminal inverted repeats (LTIRs), 9-bp target-site duplications (TSDs), and putative transposase binding sites. Strikingly, the MDM-1 family has a 9-bp terminus identical to that of a rice Mutator-like element (MULE-9) and the MDM-2 family has an 8-bp terminus identical to that of the maize autonomous Mutator element MuDR. A putative transposase homologous to MURA protein is identified for the MDM-2 family. Thus, these two novel MITE families, with a total copy number of several hundred in rice, are designated Mutator-derived MITEs (MDMs). Interestingly, sequence decay analysis of MDM families revealed a number of insertion site duplications (ISDs) in the alignment gaps, and widespread historical nesting events are proposed to account for the existence of these ISDs. In addition to its value for discovering new MITEs, the nesting analysis approach used in this study simultaneously identifies MITE insertion polymorphisms.     

Rye-derived powdery mildew resistance gene <Emphasis Type="Italic">Pm8</Emphasis> in wheat is suppressed by the <Emphasis Type="Italic">Pm3</Emphasis> locus

Genetic suppression of disease resistance is occasionally observed in hexaploid wheat or in its interspecific crosses. The phenotypic effects of genes moved to wheat from relatives with lower ploidy are often smaller than in the original sources, suggesting the presence of modifiers or partial inhibitors in wheat, especially dilution effects caused by possible variation at orthologous loci. However, there is little current understanding of the underlying genetics of suppression. The discovery of suppression in some wheat genotypes of the cereal rye chromosome 1RS-derived gene Pm8 for powdery mildew resistance offered an opportunity for analysis. A single gene for suppression was identified at or near the closely linked storage protein genes Gli-A1 and Glu-A3, which are also closely associated with the Pm3 locus on chromosome 1AS. The Pm3 locus is a complex of expressed alleles and pseudogenes embedded among Glu-A3 repeats. In the current report, we explain why earlier work indicated that the mildew suppressor was closely associated with specific Gli-A1 and Glu-A3 alleles, and predict that suppression of Pm8 involves translated gene products from the Pm3 locus.     

Isolation and <Emphasis Type="Italic">S</Emphasis>-genotyping application of <Emphasis Type="Italic">S</Emphasis>-allelic polymorphic <Emphasis Type="Italic">MdSLFB</Emphasis>s in apple (<Emphasis Type="Italic">Malus domestica</Emphasis> Borkh.)

Apple (Malus domestica Borkh.) possesses gametophytic self-incompatibility (GSI) which is controlled by S-RNase in the pistil as well as a pollen S-determinant that has not been well characterized. The identification of S-locus F-box brother (SFBB) genes, which are good candidates for the pollen S-determinant in apple and pear, indicated the presence of multiple S-allelic polymorphic F-box genes at the S-locus. In apple, two SFBB gene groups have been described, while there are at least three groups in pear. In this report, we identified five MdSLFB (S-RNase-linked F-box) genes from four different S-genotypes of apple. These genes showed pollen- and S-allele-specific expression with a high polymorphism among S-alleles. The phylogenetic tree suggested that some of them belong to SFBBα or β groups as described previously, while others appear to be different from SFBBs. In particular, the presence of MdSLFB3 and MdSLFB9 suggested that there are more S-allelic polymorphic F-box gene groups in the S-locus besides α and β. Based on the sequence polymorphism of MdSLFBs, we developed an S-genotyping system for apple cultivars. In addition, we isolated twelve MdSLFB-like genes, which showed pollen-specific expression without S-allelic polymorphism.     

Development and characterization of microsatellite markers for <Emphasis Type="Italic">Prunus verecunda</Emphasis> and <Emphasis Type="Italic">Prunus grayana</Emphasis> (Rosaceae)

Simple sequence repeat (SSR) markers were developed for Prunus verecunda and Prunus grayana to help understand the seed dispersal pattern of each species. We isolated and characterized nine microsatellite loci (four from P. verecunda and five from P. grayana). In P. verecunda, the number of alleles detected and the expected heterozygosity of five loci ranged from 11 to 24 and 0.59 to 0.92, respectively. In P. grayana, the number of alleles detected and the expected heterozygosity of five loci ranged from 4 to 14 and 0.62 to 0.86, respectively. These results show that the markers described here will be useful in studying the seed dispersal pattern of Prunus species.     

Identification of Three <Emphasis Type="Italic">Superoxide dismutase</Emphasis> Genes from a <Emphasis Type="Italic">Geobacillus</Emphasis> sp.

We report the characterization of three Superoxide dismutase (sod) genes isolated from a bacterium in the Geobacillus genus. We isolated the bacterium from high-temperature pond mud and used 16S rRNA gene sequence to confirm its identity in the Geobacillus genus. The three genes Mn-sod, Fe/Mn-sod, and Cu/Zn-sod were cloned and analyzed. Their open reading frames are Mn-sod: 615 bp encoding a 204 amino acid protein; Fe/Mn-sod: 1,236 bp encoding a 411 amino acid protein; Cu/Zn-sod: 522 bp encoding a 173 amino acid protein. When these sod genes were expressed in Escherichia coli, only Mn-SOD was able to be purified. The activity of the purified Mn-SOD we got was about 2,730 U/mg. Studies of this Mn-SOD showed that it was thermostable at 60°, had 70% activity at 80° after 2.5 h, and still had 30% activity at 90° after 2.5 h. Mn-SOD activity required the ion Mn²⁺. Based on gel electrophoresis, we deduced that this Mn-SOD was a homotetramer. No activity was detected after the other two genes (Fe/Mn-sod, Cu/Zn-sod) were expressed in Escherichia coli, but activities were detected when expressed in Pichia pastoris.     

Identification and characterization of the duplicate rice sucrose synthase genes <Emphasis Type="Italic">OsSUS5</Emphasis> and <Emphasis Type="Italic">OsSUS7</Emphasis> which are associated with the plasma membrane

Systematic searches using the complete genome sequence of rice (Oryza sativa) identified OsSUS7, a new member of the rice sucrose synthase (OsSUS) gene family, which shows only nine single nucleotide substitutions in the OsSUS5 coding sequence. Comparative genomic analysis revealed that the synteny between OsSUS5 and OsSUS7 is conserved, and that significant numbers of transposable elements are scattered at both loci. In particular, a 17.6-kb genomic region containing transposable elements was identified in the 5′ upstream sequence of the OsSUS7 gene. GFP fusion experiments indicated that OsSUS5 and OsSUS7 are largely associated with the plasma membrane and partly with the cytosol in maize mesophyll protoplasts. RT-PCR analysis and transient expression assays revealed that OsSUS5 and OsSUS7 exhibit similar expression patterns in rice tissues, with the highest expression evident in roots. These results suggest that two redundant genes, OsSUS5 and OsSUS7, evolved via duplication of a chromosome region and through the transposition of transposable elements.     

The<Emphasis Type="Italic"> Rxo1</Emphasis>/<Emphasis Type="Italic">Rba1</Emphasis> locus of maize controls resistance reactions to pathogenic and non-host bacteria

The genetic mechanism underlying six palatability properties of cooked rice and three physico-chemical traits was dissected in 66 BC₃F₂ chromosome segment substitution lines (CSSLs), using a complete linkage map in three successive years. The CSSLs showed transgressive segregation for all traits studied. Significant correlation was detected among most palatability traits. A total of 25 QTLs for the nine traits were identified on nine chromosomes, and many QTLs affecting different quality traits were mapped in the same regions. Six QTLs—qLT-8 for luster, qTD-6 and qTD-8 for tenderness, qIVOE-6 and qIVOE-8 for integrated value of organoleptic evaluation, and qAC-8 for amylose content—were repeatedly detected across the 3 years. Phenotypic values were significantly different between the recurrent parent, cultivar Asominori, and the CSSLs harboring any of the six QTL alleles across the three environments, indicating that these six QTLs were non-environment-specific and could be used for marker-assisted selection in rice quality improvement.     

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.     

Knockout of a starch synthase gene <Emphasis Type="Italic">OsSSIIIa</Emphasis>/<Emphasis Type="Italic">Flo5</Emphasis> causes white-core floury endosperm in rice (<Emphasis Type="Italic">Oryza sativa</Emphasis> L.)

To elucidate the role of SSIIIa during starch synthesis in rice (Oryza sativa L.) endosperm, we characterized null mutants of this gene, generated by T-DNA insertions. Scanning electron microscope (SEM) analysis revealed that the starch granules in these mutants are smaller and rounder compared with the wild type controls, and that the mutant endosperm is characterized by a loosely packed central portion exhibiting a floury-like phenotype. Hence, the OsSSIIIa (Oryza sativa SSIIIa) mutations are referred to as white-core floury endosperm 5-1 (flo5-1) and flo5-2. Based upon their X-ray diffraction patterns, the crystallinity of the starch in the flo5 mutant endosperm is decreased compared with wild type. Through determination of the chain-length distribution of the mutant endosperm starch, we found that flo5-1 and flo5-2 mutants have reduced the content of long chains with degree of polymerization (DP) 30 or greater compared with the controls. This suggests that OsSSIIIa/Flo5 plays an important role in generating relatively long chains in rice endosperm. In addition, DP 6 to 8 and DP 16 to 20 appeared to be reduced in endosperm starch of flo5-1 and flo5-2, whereas DP 9 to 15 and DP 22 to 29 were increased in these mutants. By the use of differential scanning calorimetry (DSC), the gelatinization temperatures of endosperm starch were found to be 1–5°C lower than those of the control. We propose a distinct role for OsSSIIIa/Flo5 and the coordinated action of other SS isoforms during starch synthesis in the seed endosperm of rice.