Efficient insertional mutagenesis in rice using the maize En/Spm elements

We have developed a novel system for insertional mutagenesis in rice (Oryza sativa) based on the maize (Zea mays) enhancer/suppressor mutator (En/Spm) element. In this system, a single T-DNA construct with Spm-transposase and the non-autonomous defective suppressor mutator (dSpm) element is used in conjunction with green fluorescent protein (GFP) and Discosoma sp. Red Fluorescence Protein (DsRed) fluorescent markers to select unlinked stable transpositions of dSpm. Using this system, we could demonstrate high frequencies of unlinked germinal transposition of dSpm in rice. Analysis of dSpm flanking sequences from 353 stable insertion lines revealed that the dSpm insertions appear to be widely distributed on rice chromosomes with a preference for genic regions (70%). The dSpm insertions appear to differ from Activator-Dissociation (Ac-Ds) elements in genomic distribution and exhibit a greater fraction of unlinked transpositions when compared with Ds elements. The results obtained in this study demonstrate that the maize En/Spm element can be used as an effective tool for functional genomics in rice and can complement efforts using other insertional mutagens. Further, the efficacy of the non-invasive fluorescence-based selection system is promising for its application to other crops.     

A four-element based transposon system for allele specific tagging in plants—Theoretical considerations

The two-element transposon constructs, utilizing either Ac/Ds or Spm/dSpm, allow random tagging of genes in heterologous model species, but are inadequate for directed tagging of specific alleles of agronomic importance. We propose the use of Ac/Ds in conjunction with Spm/dSpm to develop a four-element system for directed tagging of crop-specific alleles. The four-element based construct would include both Ds and dSpm along with relevant marker genes and would function in two steps. In the first step dSpm(Ds) stocks (a minimum of two) would be crossed to a line containing transposases of Spm and unlinked integrations would be selected from segregating population by the use of a negative selection marker to develop stocks representing integration of dSpm(Ds) at a large number of locations in the genome. Selections would be made for a line in which dSpm(Ds) shows partial or complete linkage to the allele of interest. In the second step selected line would be crossed to a line containing Ac transposase to induce transpositions of Ds element to linked sites thereby exploiting the natural tendency of Ds element to jump to linked sites. Unlinked jumps of dSpm(Ds) and linked jumps of Ds could be monitored by appropriate marker genes. The proposed model would allow tagging of allele of interest in chromosome addition lines and also help in the efficient use of genic male sterility systems for hybrid seed production by tightly marking the fertility restorer gene with a negative selection marker.     

Systematic reverse genetic screening of T-DNA tagged genes in rice for functional genomic analyses: MADS-box genes as a test case

We have generated 47 DNA pools and 235 subpools from 21,049 T-DNA insertion lines of rice. DNA pools of 500-1,000 lines were adequate for screening a T-DNA insertion within a 2-kb region. To examine the efficacy of the DNA pools, we selected MADS-box genes, which play an important role in controlling various aspects of plant development. A total of 34 MIKC-type MADS-box genes have now been identified from rice sequence databases. Our PCR screening for T-DNA insertions within 12 MADS-box genes resulted in the identification of five insertions in four different genes. These DNA pools will be valuable when isolating T-DNA insertional mutants in various rice genes. The DNA pool screening service and the mutant seeds are available upon request to genean@postech.ac.kr.     

Efficient Identification of Arabidopsis Knock-Out Mutants Using DNA-Arrays of Transposon Flanking Sequences

Abstract: Mutants obtained by insertional mutagenesis are widely used for determining gene-phenotype relationships. In Arabidopsis thaliana, several populations mutagenized either by T-DNA or transposon insertion are available for screening for knockout mutants in genes of interest. We have so far screened our Arabidopsis population mutagenized with the Zea mays transposon En-1/Spm for insertion mutations in 718 genes, using PCR on DNA pools. Although successful, this common approach is too time consuming for use in systematic screening of all 25 498 predicted genes of the Arabidopsis genome. We therefore investigated the use of DNA arrays for the direct identification of mutants in our population. All transposon-flanking regions from individual plants are amplified by PCR and subsequently spotted at high density onto nylon membranes. A single hybridization experiment with a gene-specific probe then allows one to identify candidate mutant plants. The efficiency of each separate step was determined and optimized. Screening of filters representing 2880 plants for insertions in 144 genes and subsequent investigation of some of the potential insertion mutants suggest that an overall screening efficiency of 50 % is attained.     

The En/Spm transposable element of Zea mays contains splice sites at the termini generating a novel intron from a dSpm element in the A2 gene

The A2 locus of Zea mays, identified as one of the genes affecting anthocyanin biosynthesis, was cloned using the transposable elements rcy and dSpm as gene tags. The A2 gene encodes a putative protein of 395 amino acids and is devoid of introns. Two a2-m1 alleles, containing dSpm insertions of different sizes, were characterized. The dSpm element from the original state allele has perfect termini and undergoes frequent transposition. The element from the class II state allele is no longer competent to transpose. It has retained the 13 bp terminal inverted repeat but has lost all subterminal sites at the 5' end, which are recognized by tnpA protein, the most abundant product of the En/Spm transposable element system. The relatively high A2 gene expression of one a2-m1 allele is due to removal of almost all dSpm sequences by splicing. The slightly altered A2 enzyme is still functional as shown by complementation of an a2 mutant with the corresponding cDNA. The 5' and 3' splice sites are constituted by the termini of the dSpm element; it therefore represents a novel intron of the A2 gene.     

Transposon tagging in diploid strawberry

Fragaria vesca was transformed with a transposon tagging construct harbouring amino terminally deleted maize transposase and EGFP (Ac element), NPTII, CaMV 35S promoter (P35S) driving transposase and mannopine synthase promoter (Pmas) driving EGFP (Ds element). Of 180 primary transgenics, 48 were potential launch pads, 72 were multiple insertions or chimaeras, and 60 exhibited somatic transposition. T(1) progeny of 32 putative launch pads were screened by multiplex PCR for transposition. Evidence of germ-line transposition occurred in 13 putative launch pads; however, the transposition frequency was too low in three for efficient recovery of transposants. The transposition frequency in the remaining launch pads ranged from 16% to 40%. After self-pollination of the T(0) launch pads, putative transposants in the T(1) generation were identified by multiplex PCR. Sequencing of hiTAIL-PCR products derived from nested primers within the Ds end sequences (either P35S at the left border or the inverted repeat at the right border) of T(1) plants revealed transposition of the Ds element to distant sites in the strawberry genome. From more than 2400 T(1) plants screened, 103 unique transposants have been identified, among which 17 were somatic transpositions observed in the T(0) generation. Ds insertion sites were dispersed among various gene elements [exons (15%), introns (23%), promoters (30%), 3' UTRs (17%) as well as intergenically (15%)]. Three-primer (one on either side of the Ds insertion and one within the Ds T-DNA) PCR could be used to identify homozygous T(2) transposon-tagged plants. The mutant collection has been catalogued in an on-line database.     

Activity of the corn Spm transposon system in transgenic plants Orychophragmus violaceus (L.) O.E. Schulz obtained by both direct transfer of DNA to protoplasts and agrobacterial transformation of root explants

Transposon mediated insertional mutagenesis is one of the approaches for the unique gene cloning. A wild species of Cruciferae family Orychophragmus violaceus (L.) O.E. Schulz, which is of interest for practical breeding as a donor of improved plant oil, was an object of the investigation. Plasmid construction used in the experiments included selective NPT II gene, reported GUS gene serving as an excision marker, structural BAR gene located within the dSpm element and Spm transposase. The GUS gene of this plasmid had not his own promoter and became functional only after Spm-transposition. Transformed Orychophragmus violaceus (L.) O.E. Schulz. plants were obtained by direct mesophyll protoplast transformation as well as Agrobacterium tumefaciens-mediated root explant transformation. Gene transfer and the transposition event were confirmed by the GUS activity and the PCR analysis. Relative transformation efficiency using protoplasts was 5.8%.     

Characterization of T-DNA insertion sites in Arabidopsis thaliana and the implications for saturation mutagenesis

A key component of a sound functional genomics infrastructure is the availability of a knockout mutant for every gene in the genome. A fruitful approach to systematically knockingout genes in the plant Arabidopsis thaliana has been the use of transferred-DNA (T-DNA) from Agrobacterium tumefaciens as an insertional mutagen. One of the assumptions underlying the use of T-DNA as a mutagen is that the insertion of these DNA elements into the Arabidopsis genome occurs at randomly selected locations. We have directly investigated the distribution of T-DNA insertions sites in populations of transformed Arabidopsis using two different approaches. To begin with, we utilized a polymerase chain reaction (PCR) procedure to systematically catalog the precise locations of all the T-DNA elements inserted within a 65 kb segment of chromosome IV. Of the 47 T-DNA insertions identified, 30% were found within the coding regions of genes. We also documented the insertion of T-DNA elements within the centromeric region of chromosome IV. In addition to these targeted T-DNA screens, we also mapped the genomic locations of 583 randomly chosen T-DNA elements by sequencing the genomic DNA flanking the insertion sites from individual T-DNA-transformed lines. 35% of these randomly chosen T-DNA insertions were located within the coding regions of genes. For comparison, coding sequences account for 44% of the Arabidopsis genome. Our results demonstrate that there is a small bias towards recovering T-DNA insertions within intergenic regions. However, this bias does not limit the utility of T-DNA as an effective insertional mutagen for use in reverse-genetic strategies.     

Flanking sequence tags in Arabidopsis thaliana T-DNA insertion lines: a pilot study

Eight hundred and fifty Arabidopsis thaliana T-DNA insertion lines have been selected on a phenotypic basis. The T-DNA flanking sequences (FST) have been isolated using a PCR amplification procedure and sequenced. Seven hundred plant DNA sequences have been obtained revealing a T-DNA insertion in, or in the immediate vicinity of 482 annotated genes. Limited deletions of plant DNA have been observed at the site of insertion of T-DNA as well as in its left (LB) and right (RB) T-DNA signal sequences. The distribution of the T-DNA insertions along the chromosomes shows that they are essentially absent from the centrometric and pericentrometric regions.     

Obtaining of intertribal Brassica juncea+Arabidopsis thaliana somatic hybrids and study of transgenic trait behaviour

Intertribal somatic hybridization between wild type Brassica juncea (L.) Czern. & Coss. and transgenic A. thaliana L. has been carried out. Genome of A. thaliana plants contained heterologous transposable element Spm/dSpm, reporter GUS gene, selective genes for kanamycin- (npt II) and phosphinothricin (bar) resistance. Hybrid nature of obtained plants was confirmed with their morphology, GUS hystochemical assay, PCR-RFLP, RAPD and isozyme analyses. It was determined that heterologous transposable element Spm/dSpm is able to function in hybrid plants. There was no complete elimination of A. thaliana genetic material in the hybrids and the transgenes were stably maintained.     

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.     

Large-scale T-DNA mutagenesis in Arabidopsis for functional genomic analysis

In planta Agrobacterium-mediated transformation combined with a soil-based herbicide selection for transgenic plants was used to recover large numbers of transgenic Arabidopsis plants for functional genomic studies. A tissue-culture-free system for generating transgenic plants was achieved by infiltrating Arabidopsis plants with Agrobacterium tumefaciens harboring a binary T-DNA vector containing the phosphinothricin acetyltransferase gene from Streptomyces hygroscopicus, and by selecting transgenic Arabidopsis growing in soil by foliar application of the herbicide Finale (phosphinothricin). Analysis of herbicide-resistant plants indicated that all were transgenic and that the T-DNA transformation process occurred late during flower development, resulting in a preponderance of independently derived T-DNA insertions. T-DNA insertions were usually integrated in a concatenated, rearranged form, and using linkage analysis, we estimated that T1 plants carried between one and five T-DNA loci. Using pooling strategies, both DNA and seed pools were generated from about 38,000 Arabidopsis plants representing over 115,000 independent T-DNA insertions. We show the utility of these transgenic lines for identifying insertion mutations using gene sequence and PCR-based screening. Electronic Publication     

An Arabidopsis thaliana T-DNA mutagenized population (GABI-Kat) for flanking sequence tag-based reverse genetics

The GABI-Kat population of T-DNA mutagenized Arabidopsis thaliana lines with sequence-characterized insertion sites is used extensively for efficient progress in plant functional genomics. Here we provide details about the establishment of the material, demonstrate the population's functionality and discuss results from quality control studies. T-DNA insertion mutants of the accession Columbia (Col-0) were created by Agrobacterium tumefaciens-mediated transformation. To allow selection of transformed plants under greenhouse conditions, a sulfadiazine resistance marker was employed. DNA from leaves of T1 plants was extracted and used as a template for PCR-based amplification of DNA fragments spanning insertion site borders. After sequencing, the data were placed in a flanking sequence tag (FST) database describing which mutant allele was present in which line. Analysis of the distribution of T-DNA insertions revealed a clear bias towards intergenic regions. Insertion sites appeared more frequent in regions in front of the ATG and after STOP codons of predicted genes. Segregation analysis for sulfadiazine resistance showed that 62% of the transformants contain an insertion at only one genetic locus. In quality control studies with gene-specific primers in combination with T-DNA primers, 76% of insertions could be confirmed. Finally, the functionality of the GABI-Kat population was demonstrated by exemplary confirmation of several new transparent testa alleles, as well as a number of other mutants, which were identified on the basis of the FST data.     

<Emphasis Type="Italic">Agrobacterium</Emphasis>-mediated <Emphasis Type="Italic">in planta</Emphasis> transformation of maize germ cells

A transfer DNA (T-DNA) carrying the marker gene nptII was detected in the genomes of diploid and haploid maize plants obtained after the treatment of pistil filaments with a suspension of Agrobacterium during artificial pollination. PCR analysis of total DNA isolated from 155 canamycin-resistant diploid F1 seedlings revealed T-DNA insertions in the genomes of 111 plants (32.7% of the total number of analyzed seeds). The example of matroclinal haploids was used to demonstrate that T-DNA may be transported to the egg cell by the growing pollen tube (PT). Twelve out of 16 analyzed haploid plants contained the T-DNA insertion. The possible mechanism of the transfer of the Agrobacterium T-DNA to the maize genome during pollination is discussed.     

An Inverse Pcr Screen for the Detection of P Element Insertions in Cloned Genomic Intervals in Drosophila Melanogaster

We developed a screening approach that utilizes an inverse polymerase chain reaction (PCR) to detect P element insertions in or near previously cloned genes in Drosophila melanogaster. We used this approach in a large scale genetic screen in which P elements were mobilized from sites on the X chromosome to new autosomal locations. Mutagenized flies were combined in pools, and our screening approach was used to generate probes corresponding to the sequences flanking each site of insertion. These probes then were used for hybridization to cloned genomic intervals, allowing individuals carrying insertions in them to be detected. We used the same approach to perform repeated rounds of sib-selection to generate stable insertion lines. We screened 16,100 insert bearing individuals and recovered 11 insertions in five intervals containing genes encoding members of the kinesin superfamily in Drosophila melanogaster. In addition, we recovered an insertion in the region including the Larval Serum Protein-2 gene. Examination by Southern hybridization confirms that the lines we recovered represent genuine insertions in the corresponding genomic intervals. Our data indicates that this approach will be very efficient both for P element mutagenesis of new genomic regions and for detection and recovery of ``local' P element transposition events. In addition, our data constitutes a survey of preferred P element insertion sites in the Drosophila genome and suggests that insertion sites that are mutable at a rate of ~10(-4) are distributed every 40-50 kb.