用无启动子的GUS报告基因捕获水稻基因启动子

构建了嵌合质粒p13DGUTs,它是在Ds转座子中插入了无启动子的B．葡萄糖醛酸酶报告基因(GUS),用于分离水稻基因启动子。将p13DGUTs转化粳稻品种中花11的胚性愈伤组织,获得了496个转基因植株。抗性愈伤组织与转基因植株的GUS染色与PCR分析表明整合在水稻染色体上的Ds因子都发生了随机跳跃。转基因植株T0代与部分T1代的GUS染色结果表明,M92转基因植株中Ds转座子整合位置上游的水稻基因启动子指导GUS基因的表达及表达的特性是可遗传的。文章对此方法在分离水稻基因启动子与基因上的应用进行了讨论。     

Distribution of T-DNA carrying a Ds element on rice chromosomes

Over 3000 rice plants with T-DNA carrying a Ds element were constructed by Agrobacterium tumefaciens mediation. Using inverse PCR methodology, 590 unique right flanking sequences of T-DNA (Ds) were retrieved from independent transformants and classified into six main types on the basis of the origin of filler DNA between the right border of T-DNA and flanking sequence of rice genome. Type I sequences were the most common and showed canonical integration that T-DNA right border was followed by rice genome sequence with or without filler DNA of no more than 50 bp, while type II sequences displayed a vector-genome combination that T-DNA right border was followed by a vector fragment and then connected with rice genome sequence. The location and distribution of 340 type I and II flanking sequences on the rice chromosome were determined using BLAST analysis. The 340 Ds insertions at an average interval of 0.8 megabase (Mb) constructed a basic framework of Ds starter points on whole rice chromosomes. The frequency of T-DNA (Ds) inserted into the exons of predicted genes on chromosome one was 21%. Knowledge of T-DNA (Ds) locations on chromosomes will prove to be a useful resource for isolating rice genes by Ds transposon tagging as these Ds insertions can be used as starting lines for further mutagenesis.     

Non-random distribution of T-DNA insertions at various levels of the genome hierarchy as revealed by analyzing 13 804 T-DNA flanking sequences from an enhancer-trap mutant library

We isolated 13 804 T-DNA flanking sequence tags (FSTs) from a T-DNA insertion library of rice. A comprehensive analysis of the 13 804 FSTs revealed a number of features demonstrating a highly non-random distribution of the T-DNA insertions in the rice genome: T-DNA insertions were biased towards large chromosomes, not only in the absolute number of insertions but also in the relative density; within chromosomes the insertions occurred more densely in the distal ends, and less densely in the centromeric regions; the distribution of the T-DNA insertions was highly correlated with that of full-length cDNAs, but the correlations were highly heterogeneous among the chromosomes; T-DNA insertions strongly disfavored transposable element (TE)-related sequences, but favored genic sequences with a strong bias toward the 5' upstream and 3' downstream regions of the genes; T-DNA insertions preferentially occurred among the various classes of functional genes, such that the numbers of insertions were in excess in certain functional categories but were deficient in other categories. The analysis of DNA sequence compositions around the T-DNA insertion sites also revealed several prominent features, including an elevated bendability from -200 to 200 bp relative to the insertion sites, an inverse relationship between the GC and TA skews, and reversed GC and TA skews in sequences upstream and downstream of the insertion sites, with both GC and TA skews equal to zero at the insertion sites. It was estimated that 365 380 insertions are needed to saturate the genome with P = 0.95, and that the 45 441 FSTs that have been isolated so far by various groups tagged 14 287 of the 42 653 non-TE related genes.     

Development of enhancer trap lines for functional analysis of the rice genome

Enhancer trapping has provided a powerful strategy for identifying novel genes and regulatory elements. In this study, we adopted an enhancer trap system, consisting of the GAL4/VP16-UAS elements with GUS as the reporter, to generate a trapping population of rice. Currently, 31 443 independent transformants were obtained from two cultivars using Agrobacterium-mediated T-DNA insertion. PCR tests and DNA blot hybridization showed that about 94% of the transformants contained T-DNA insertions. The transformants carried, on average, two copies of the T-DNA, and 42% of the transformants had single-copy insertions. Histochemical assays of approximately 1000 T0 plants revealed various patterns of the reporter gene expression, including expression in only one tissue, and simultaneously in two or more tissues. The expression pattern of the reporter gene in T1 families corresponded well with the T0 plants and segregated in a 3 : 1 Mendelian ratio in majority of the T1 families tested. The frequency of reporter gene expression in the enhancer trap lines was much higher than that in gene trap lines reported previously. Analysis of flanking sequences of T-DNA insertion sites from about 200 transformants showed that almost all the sequences had homology with the sequences in the rice genome databases. Morphologically conspicuous mutations were observed in about 7.5% of the 2679 T1 families that were field-tested, and segregation in more than one-third of the families fit the 3 : 1 ratio. It was concluded that GAL4/VP16-UAS elements provided a useful system for enhancer trap in rice.     

Ac/Ds(GUS)结构介导的水稻启动子捕获系统的建立

构建了基于Activator/Dissociation(β-glucuronidase)[简称Ac/Ds(GUS)]结构的捕获质粒p13B,用于分离水稻基因启动子.以此质粒用衣杆菌介导的方法转化粳稻品种中花11的胚性愈伤组织,对获得的18个独立转化株的T2代植株进行了抗除草剂筛选,从141个抗除草剂转基因植株中用PCR方法检测到其中37株是Ds因子发生了转座的植株,而且这种转座到新位置上的Ds因子是遗传的.初步观察到其中5株的GUS染色呈阳性.     

Reverse Genetic Approaches for Functional Genomics of Rice

T-DNA and transposable elements e.g., Ds and Tos17, are used to generate a large number of insertional mutant lines in rice. Some carry the GUS or GFP reporter for gene trap or enhancer trap. These reporter systems are valuable for identifying tissue- or organ-preferential genes. Activation tagging lines have also been generated for screening mutants and isolating mutagenized genes. To utilize these resources more efficiently, tagged lines have been produced for reverse genetic approaches. DNA pools of the T-DNA tagged lines and Tos17 lines have been prepared for PCR screening of insertional mutants in a given gene. Tag end sequences (TES) of the inserts have also been produced. TES databases are beneficial for analyzing the function of a large number of rice genes.     

Establishing a gene trap system mediated by T-DNA(GUS) in rice

Two plasmids, p13GUS and p13GUS2, were constructed to create a gene trap system containing the promoterless β-glucuronidase (GUS) reporter gene in the T-DNA region. Transformation of these two plasmids into the rice variety Zhonghua 11 (Oryza sativa ssp. japonica cv.), mediated by Agrobacterium tumefaciens, resulted in 942 independent transgenic lines. Histochemical GUS assays revealed that 31 To plants had various patterns of the reporter gene expression, including expression in only one tissue, and simultaneously in two or more tissues. Hygromycin-resistant (hygr) homozygotes were screened and the copy number of the T-DNA inserts was determined in the GUS-positivs transgenic plants. The flanking sequences of the T-DNA were isolated by inverse-polymerase chain reaction and the insert positions on the rice genome of T-DNA were determined by a basic local alignment search tool in the GUS-positive transgenic plants transformed with plasmid p13GUS. Moreover, calii induced from the seeds of the T1 generation of 911 GUS-negative transgenic lines were subjected to stress and hormone treatments. Histochemical GUS assays were carried out on the calli before and after treatment. The results revealed that calli from 21 lines displayed differential GUS expression after treatment. All of these data demonstrated that this trap system is suitable for identifying rice genes, including those that are sensitive to induction.     

Distribution of T-DNA carrying a Ds element on rice chromosomes

Rice is one of the most important crops in the world, and is widely studied as a model for cereal ge-nomics because of its small genome size (about 430 Mbp), and its colinearity at the sequence level with limited regions of other cereal genomes. In addition, there are a large number of rice databases document-ing molecular markers, genome sequences, EST se-quences and trait mutants[1—4]. Functional genomic studies of rice are increasing with the availability of the complete genome sequence. …     

A rice gene activation/knockout mutant resource for high throughput functional genomics

Using transfer DNA (T-DNA) with functions of gene trap and gene knockout and activation tagging, a mutant population containing 55,000 lines was generated. Approximately 81% of this population carries 1–2 T-DNA copies per line, and the retrotransposon Tos17 was mostly inactive in this population during tissue culture. A total of 11,992 flanking sequence tags (FSTs) have been obtained and assigned to the rice genome. T-DNA was preferentially (∼80%) integrated into genic regions. A total of 19,000 FSTs pooled from this and another T-DNA tagged population were analyzed and compared with 18,000 FSTs from a Tos17 tagged population. There was difference in preference for integrations into genic, coding, and flanking regions, as well as repetitive sequences and centromeric regions, between T-DNA and Tos17; however, T-DNA integration was more evenly distributed in the rice genome than Tos17. Our T-DNA contains an enhancer octamer next to the left border, expression of genes within genetics distances of 12.5 kb was enhanced. For example, the normal height of a severe dwarf mutant, with its gibberellin 2-oxidase (GA2ox) gene being activated by T-DNA, was restored upon GA treatment, indicating GA2ox was one of the key enzymes regulating the endogenous level of GA. Our T-DNA also contains a promoterless GUS gene next to the right border. GUS activity screening facilitated identification of genes responsive to various stresses and those regulated temporally and spatially in large scale with high frequency. Our mutant population offers a highly valuable resource for high throughput rice functional analyses using both forward and reverse genetic approaches. Electronic Supplementary Material Supplementary material is available in the online version of this article at and is accessible for authorized users. Yue-Ie Hsing, Chyr-Guan Chern, and Ming-Jen Fan have contributed equally.     

Generation of a flanking sequence-tag database for activation-tagging lines in japonica rice

We have generated 47,932 T-DNA tag lines in japonica rice using activation-tagging vectors that contain tetramerized 35S enhancer sequences. To facilitate use of those lines, we isolated the genomic sequences flanking the inserted T-DNA via inverse polymerase chain reaction. For most of the lines, we performed four sets of amplifications using two different restriction enzymes toward both directions. In analyzing 41,234 lines, we obtained 27,621 flanking sequence tags (FSTs), among which 12,505 were integrated into genic regions and 15,116 into intergenic regions. Mapping of the FSTs on chromosomes revealed that T-DNA integration frequency was generally proportional to chromosome size. However, T-DNA insertions were non-uniformly distributed on each chromosome: higher at the distal ends and lower in regions close to the centromeres. In addition, several regions showed extreme peaks and valleys of insertion frequency, suggesting hot and cold spots for T-DNA integration. The density of insertion events was somewhat correlated with expressed, rather than predicted, gene density along each chromosome. Analyses of expression patterns near the inserted enhancer showed that at least half the test lines displayed greater expression of the tagged genes. Whereas in most of the increased lines expression patterns after activation were similar to those in the wild type, thereby maintaining the endogenous patterns, the remaining lines showed changes in expression in the activation tagged lines. In this case, ectopic expression was most frequently observed in mature leaves. Currently, the database can be searched with the gene locus number or location on the chromosome at http://www.postech.ac.kr/life/pfg/risd. On request, seeds of the T(1) or T(2) plants will be provided to the scientific community.     

Insights into recognition of the T-DNA border repeats as termination sites for T-strand synthesis by Agrobacterium tumefaciens

The recognition of the T-DNA left border (LB) repeat is affected by its surrounding sequences. Here, the LB regions were further characterized by molecular analysis of transgenic plants, obtained after Agrobacterium tumefaciens-mediated transformation with T-DNA vectors that had been modified in this LB region. At least the 24-bp LB repeat by itself was insufficient to terminate the T-strand synthesis. Addition of the natural inner and/or outer border regions to at least the LB repeat, even when present at a distance, enhanced the correct recognition of the LB repeat, reducing the number of plants containing vector backbone sequences. In tandem occurrence of both the octopine and nopaline LB regions with their repeats terminated the T-strand synthesis most efficiently at the LB, yielding a reproducibly high number of plants containing only the T-DNA. Furthermore, T-strand synthesis did not terminate efficiently at the right border (RB) repeat, which might indicate that signals in the outer RB region inhibit the termination of T-strand synthesis at the RB repeat.     

A complete sequence of the pGA1611 binary vector

We report the nucleotide sequence of the binary vector pGA1611, which is used for the transformation of foreign DNA into rice. This vector is 13,476 bp long. The 5577- bp T- DNA region consists of a 1987- bp ubiquitine promoter region, 45 bp for the multiple cloning site, a 253- bpnos terminator region, and the 2045- bpCaMV35S- hph- T7 chimaeric gene. The vector backbone (7004 bp) carriesoriT,traJ,trfA,tetA,tetR, andoriV. An 892- bp RB region and the 489- bp LB region are also present The T- DNA possesses 15 unique sites, six of which are at the multiple cloning site. This information will be valuable for cloning foreign DNA and modifying the vector.     

Transgene structures in T-DNA-inserted rice plants

T-DNA is commonly used for delivery of foreign genes and as an insertional mutagen. Although ample information exists regarding T-DNA organization in dicotyledonous plants, little is known about the monocot rice. Here, we investigated the structure of T-DNA in a large number of transgenic rice plants. Analysis of the T-DNA borders revealed that more than half of the right ends were at the cleavage site, whereas the left ends were not conserved and were deleted up to 180 bp from the left border (LB) cleavage site. Three types of junctions were found between T-DNA and genomic DNA. In the first, up to seven nucleotide overlaps were present. The frequency of this type was much higher in the LB region than at the right border (RB). In the second type, which was more frequent in RB, the link was direct, without any overlaps or filler DNA. Finally, the third type showed filler DNA between T-DNA and the plant sequences. Out of 171 samples examined, 77 carried the vector backbone sequence, with the majority caused by the failure of T-strand termination at LB. However, a significant portion also resulted from co-integration of T-DNA and the vector backbone to a single locus. Most linkages between T-DNA and the vector backbone were formed between two 3 ends or two 5 ends of the transferred DNAs. The 3 ends were mostly linked through 3–6 bp of the complementing sequence, whereas the 5 ends were linked through either precise junctions or imprecise junctions with filler DNA.     

A Novel Two T-DNA Binary Vector Allows Efficient Generation of Marker-free Transgenic Plants in Three Elite Cultivars of Rice (Oryza sativa L.)

A pilot binary vector was constructed to assess the potential of the 2 T-DNA system for generating selectable marker-free progeny plants in three elite rice cultivars (ZhongZuo321, Ariete and Khao Dawk Mali 105) known to exhibit contrasting amenabilities to transformation. The first T-DNA of the vector, delimited by Agrobacterium tumefaciens borders, contains the hygromycin phosphotransferase (hpt) selectable gene and the green fluorescent protein (gfp) reporter gene while the second T-DNA, delimited by Agrobacterium rhizogenes borders, bears the phosphinothricin acetyl transferase (bar) gene, featuring the gene of interest. 82-90% of the hygromycin-resistant primary transformants exhibited tolerance to ammonium glufosinate mediated by the bar gene suggesting very high co-transformation frequency in the three cultivars. All of the regenerated plants were analyzed by Southern blot which confirmed co-integration of the T-DNAs at frequencies consistent with those of co-expression and allowed determination of copy number for each gene as well as detection of two different vector backbone fragments extending between the two T-DNAs. Hygromycin susceptible, ammonium glufosinate tolerant phenotypes represented 14.4, 17.4 and 14.3% of the plants in T1 progenies of ZZ321, Ariete and KDML105 primary transformants, respectively. We developed a statistical model for deducing from the observed copy number of each T-DNA in T0 plants and phenotypic segregations in T1 progenies the most likely constitution and linkage of the T-DNA integration locus. Statistical analysis identified in 40 out of 42 lines a most likely linkage configuration theoretically allowing genetic separation of the two T-DNA types and out segregation of the T-DNA bearing the bar gene. Overall, though improvements of the technology would be beneficial, the 2 T-DNA system appeared to be a useful approach to generate selectable marker-free rice plants with a consistent frequency among cultivars.     

Structure and expression of a rice hsp70 gene

A genomic hsp70 gene was isolated from a rice IR36 genomic library and 4 794 bp of the gene have been sequenoed. The 5' flanking region of the gene contained a putative TATA box and a typical heat shock element sequence 5'-CTcgGAAccTTCgAG-3'. The amino acid sequence of the rice HSP70 deduced from the coding region shared 84%-92% homologies with those of HSP70s from other plant species. An intron 1939bp long was identified in the coding region at the codon specifying amino acid 72 (Asp), the similar position introns occurring in other intron-containing hsp70 genes. In addition, another intron of 57 bp was found in the 3'-untranslated region in the rice hsp70 gene. Southern blot hybridization showed that rice hsp70 gene family contained at least three members. Analysis of the RNA leveis with the gene-specific and non-specific probes revealed that the rice hsp70 gene expressed at normal temperature and the expression was enhanced by heat shock treatment.