An atypical HLH protein OsLF in rice regulates flowering time and interacts with OsPIL13 and OsPIL15.

In plants, flowering as a crucial developmental event is highly regulated by both genetic programs and environmental signals. Genetic analysis of flowering time mutants is instrumental in dissecting the regulatory pathways of flowering induction. In this study, we isolated the OsLF gene by its association with the T-DNA insertion in the rice late flowering mutant named A654. The OsLF gene encodes an atypical HLH protein composed of 419 amino acids (aa). Overexpression of the OsLF gene in wild type rice recapitulated the late flowering phenotype of A654, indicating that the OsLF gene negatively regulates flowering. Flowering genes downstream of OsPRR1 such as OsGI and Hd1 were down regulated in the A654 mutant. Yeast two hybrid and colocalization assays revealed that OsLF interacts strongly with OsPIL13 and OsPIL15 that are potentially involved in light signaling. In addition, OsPIL13 and OsPIL15 colocalize with OsPRR1, an ortholog of the Arabidopsis APRR1 gene that controls photoperiodic flowering response through clock function. Together, these results suggest that overexpression of OsLF might repress expression of OsGI and Hd1 by competing with OsPRR1 in interacting with OsPIL13 and OsPIL15 and thus induce late flowering.

Overexpression of ACL1 (abaxially curled leaf 1) increased Bulliform cells and induced Abaxial curling of leaf blades in rice.

Understanding the genetic mechanism underlying rice leaf-shape development is crucial for optimizing rice configuration and achieving high yields; however, little is known about leaf abaxial curling. We isolated a rice transferred DNA (T-DNA) insertion mutant, BY240, which exhibited an abaxial leaf curling phenotype that co-segregated with the inserted T-DNA. The T-DNA was inserted in the promoter of a novel gene, ACL1 (Abaxially Curled Leaf 1), and led to overexpression of this gene in BY240. Overexpression of ACL1 in wild-type rice also resulted in abaxial leaf curling. ACL1 encodes a protein of 116 amino acids with no known conserved functional domains. Overexpression of ACL2, the only homolog of ACL1 in rice, also induced abaxial leaf curling. RT-PCR analysis revealed high expressions of ACLs in leaf sheaths and leaf blades, suggesting a role for these genes in leaf development. In situ hybridization revealed non-tissue-specific expression of the ACLs in the shoot apical meristem, leaf primordium, and young leaf. Histological analysis showed increased number and exaggeration of bulliform cells and expansion of epidermal cells in the leaves of BY240, which caused developmental discoordination of the abaxial and adaxial sides, resulting in abaxially curled leaves. These results revealed an important mechanism in rice leaf development and provided the genetic basis for agricultural improvement.

Overexpression of transcription factor OsLFL1 delays flowering time in Oryza sativa.

Flowering time is regulated by genetic programs and environment signals in plants. Genetic analysis of flowering time mutants is instrumental in dissecting the regulatory pathways of flower induction. Genotype W378 is a rice (Oryza sativa) late-flowering mutant selected from our collections of T-DNA insertion line. The T-DNA flanking gene in mutant W378 codes OsLFL1 (O. sativa LEC2 and FUSCA3 Like 1), a putative B3 DNA-binding domain-containing transcription factor. In wild-type rice OsLFL1 is expressed exclusively in spikes and young embryos, while in mutant W378 it is ectopically expressed. Introduction of OsLFL1-RNAi into mutant W378 successfully down-regulated OsLFL1 expression and restored flowering to almost normal time, indicating that overexpression of OsLFL1 confers late flowering for mutant W378. The flowering-promoting gene Ehd1 and its downstream genes are all down-regulated in W378. Thus, overexpression of OsLFL1 might delay the flowering of W378 by repressing the expression of Ehd1.

The expression pattern of a rice proteinase inhibitor gene OsPI8-1 implies its role in plant development.

A rice proteinase inhibitor (PI) gene OsPI8-1 was identified. Belonging to the potato inhibitor I family, this gene contains a 201bp coding region with no introns and encodes a deduced protein of 66 amino acids which holds a PI domain. There are two uniform gene copies, OsPI8-1a and OsPI8-1b, with direct-repeat arrangement and an interval span of 13 kb on rice chromosome 8, corresponding to the site of BAC clone P0528B09 (Accession No. AP004703). Reverse transcription polymerase chain reaction (RT-PCR) assays showed that both OsPI8-1a and OsPI8-1b can be expressed in wild-type 'Zhonghua No.11'. To investigate the physiological functions of OsPI8-1 in plant development, we analyzed the expression patterns of the reporter gene beta-glucuronidase (GUS) driven by OsPI8-1 promoter at different developmental stages and tissues. It was demonstrated that no GUS signals were detected in the roots. Despite that very high GUS expression was examined in the shoot apical meristem, no detectable GUS activity in the developmental domains of leaf primordium was observed. OsPI8-1 promoter showed an obvious wound-induced response in mature leaves. Little GUS activity was detected in young nodes and internodes at the seedling stage, but active GUS expression was observed near the nodes on mature culms. In the developing stage of the anther, GUS signal was specifically located in the middle layer and the endothecium between the epidermis and tapetum. In the germinating seed, GUS expression was gradually accumulated in the side of scutellar epithelium close to the embryo. These tissue-specific accumulations suggested that OsPI8-1 has multiple endogenous roles on developmental regulation. In this report, the inhibitor function of OsPI8-1 to proteolytic enzymes and the potential influence of their poise on plant development (such as seed germination, tapetum degeneration, programmed cell death, etc.) were discussed.

Ectopic expression of OsLFL1 in rice represses Ehd1 by binding on its promoter.

B3 domain was identified as a novel DNA-binding motif specific to higher plant species. The B3 proteins play important roles in plant development. In the mutant W378, the mutant gene coding OsLFL1, a putative B3 transcription factor gene, was ectopically expressed. In this study, it was found that the flowering promoting gene Ehd1 and its putative downstream genes were all repressed by OsLFL1. Electrophoretic mobility shift assays (EMSA) and chromatin immunoprecipitation (ChIP) analyses suggest that OsLFL1 binds to the RY cis-elements (CATGCATG) in the promoter of the Ehd1 gene. Thus, ectopically expressed OsLFL1 might repress Ehd1 via binding directly to the RY cis-elements in its promoter.

[Transpositional behaviour analysis of Ds element from different insertion sites on chromosome 4 in rice].

Transgenic plants with Ds element distributed over different loci on chromosome 4 (Fig. 1) and the homozygous transformants with Ac transposase gene were established through Agrobacterium-mediated approach. In this study, the plants carrying Ds element from different loci were crossed with the plant carrying Ac transposase individually. The plants of F(1) generation carrying both Ds element and Ac transposase were used to produce the F(2) populations (Table 1). Analysis of the F(2) generation by the PCR method revealed that the excision frequencies of Ds element were higher in the telomeric region of chromosome 4 than in the centromeric region (Fig. 4). These results showed that the insertion site of Ds element has strong effect on its excision frequency. We suggest that the special construct of chromosome near the insertion site of Ds element is related to the excision frequency of the Ds element.

[Genetic analysis of a heading-delayed mutant by T-DNA insertion in rice (Oryza sativa L.)].

Transposon tagging was used to isolate genes in higher plant. In this study, a delayed heading mutant caused by T-DNA insertion in rice was identified. Genetic analysis of the mutant showed that the three types of phenotype, normal heading, delayed heading and overly delayed heading in the segregating populations derived from the T-DNA heterozygotes fit the ratio of 1:2:1. Test for Basta resistance showed the delayed heading plants were all resistant while the normal heading plants were susceptible, and the ratio of resistant and susceptible plants was 3:1, which indicated that the delayed heading mutant was co-segregated with Basta resistance. The delayed heading mutant caused by T-DNA insertion was confirmed by T-DNA detection using PCR method. This delayed heading mutant will be used for isolation of the tagged gene in rice.

[Structure and expression analysis of the gama-glutamylcysteine synthetase gene in rice].

Gama-glutamylcysteine synthetase (GCS) is a rate-limiting enzyme in GSH biosynthesis. The GCS gene has been cloned in Arabidopsis thaliana and other plants, but has still not been reported in rice. From rice mutant population generated from T-DNA insertion, we cloned the rice GCS gene from mutant L395 by T-DNA tag cloning method, and named it OsGCS (Genbank accession No. AJ508915). Full length OsGCS cDNA clones were obtained from a rice cDNA library by the PCR method. A comparison of the genome and cDNA sequence (Genbank accession No. AJ508916) shows that OsGCS gene is composed of 15 exons and 14 introns and coding a 493-amino acid protein. The OsGCS gene is highly homologous with the AtGCS gene in the coding region but completely different in the promoter region. The putative transcription start site (TSS) confirmed by RT-PCR was located 211 bp upstream of the translation start codon "ATG". In mutant L395, a single T-DNA copy was integrated between the second intron and second exon of OsGCS gene, causing one nucleotide deletion in the second exon and two nucleotide deletions in the second intron. No significant differences were found in Cd(2+) stress tolerance, rice GCS gene expression level and GSH content between mutant L395 and Zhonghua 11. It is possible that another GCS gene on chromosome 7 might complement function of OsGCS gene on chromosome 5.

[Genetic analysis of a rolled-leaf mutant in rice population of T-DNA insertion].

A rolled-leaf mutant was obtained in a T-DNA(containing bar gene and Ds element) insertion population, which consist of transgenic japonica rice Zhonghua 11 mediated by Agrobacterium tumefaciens. Through self-hybridization of three generations, one of trait-purified mutants (R1-A2) was obtained and used as parent to cross with variety Zhonghua 11. The leaves of 36 F1 plants investigated were rolled and resistant to herbicide Basta. Among 852 F2 plants, the segregation ratio of rolled leaves to normal leaves(645:207) was consistent with 3:1. All rolled-leaf plants were resistant to herbicide Basta, and all normal leaf plants were sensitive to herbicide Basta. These results showed that the trait of rolled-leaf is co-segregated with Basta resistance. The total DNA of 45 rolled-leaf plants and 30 normal leaf plants in F2 population were amplified to test the presence of T-DNA by Ds primers. The results showed that the positive band were amplified in all rolled-leaf plants, but not in every normal leaf plant. In F1B1 progenies, all plants which derived from backcross parent R1-A2 were rolled leaves; while variety Zhonghua 11 was used as backcross parent, the segregation ratio of rolled-leaf to normal leaf was consistent with 1:1. Taking these data together, it indicated that the rolled-leaf mutant was co-segregation with T-DNA and controlled by single dominant gene.

The OsEBP-89 gene of rice encodes a putative EREBP transcription factor and is temporally expressed in developing endosperm and intercalary meristem.

The AP2/EREBP transcription factors play important roles in plant development and in the responses of plants to biotic and abiotic stresses. All members of the EREBP subfamily described to date are from dicotyledonous plants. In this paper, we describe the cloning and characterization of a rice gene, OsEBP-89, encoding a protein 326 amino acids long with a typical EREBP domain; this is the first report of an EREBP transcription factor in a monocotyledonous plant. Except for the EREBP domain, the OsEBP-89 protein does not have substantial sequence similarities to other members of the subfamily. The DNA-binding activity of the EREBP domain was confirmed by electrophoretic mobility-shift assays. An activation domain rich in acidic amino acids was identified by using a yeast one-hybrid system. Two putative nuclear-localization signals were also identified. The results of northern blot hybridization experiments showed that the transcript of the OsEBP-89 gene accumulates primarily in immature seeds, roots, and leaves (low levels). More detailed information about the pattern of OsEBP-89 gene expression was obtained by histochemical studies of transgenic rice plants carrying an OsEBP-89 5'/GUS reporter gene. The reporter gene was expressed in the endosperm starting at 7 days after pollination and in the intercalary meristem of plants. Expression of OsEBP-89 was induced in roots of rice seedlings by treatment with ACC, NaCl, or 2,4-D. Two cis-acting elements, an endosperm motif and a primary PERE, are present upstream of the OsEBP-89 coding region and may be involved in regulating its expression. Collectively, these results suggest that the OsEBP-89 gene is a new member of the EREBP subfamily and may be involved in ethylene-dependent seed maturation and shoot development of rice.

[The morphology observation, mechanics intensity test and genetic analysis of brittle culm mutant bcm581-1 in rice].

A rice brittle culm mutant bcm581-1 which derived from the Ds transposone transformation population was found, but the mutant was identified that it was not to be induced by Ds transposone insertion through PCR. The examination of the vascular bundle and cortical fibre cells in culm under the light and electron microscope showed that, the number of cortical vascular bundle of mutant was much more, the hollow among the cortical vascular bundle was deeper, and the cell walls of cortical fibre cells were thinner than the normal. The test of culm mechanics intensity showed that the load, elongation, strain, and stress of bcm581-1 were 5-9 times lower than normal. The moisture content and the wide fibre content of culm were test, the former was 3.5% higher, but the latter was 8.12% lower than normal. The analysis of genetic segregation in F2 and F1B1 population indicated that the brittle culm mutant was controlled by one recessive gene.