Analysis of developmentally interesting genes cloned from higher plants by insertional mutagenesis

The ability of transposable elements to generate gene mutations by excising from one site in the genome and reintegrating into new, different sites elsewhere in the genome has led to the development of procedures whereby the elements can be used to tag specific gene sequences for eventual isolation and analysis through gene cloning. This transposon tagging strategy is particularly useful in those situations where limited knowledge of the biochemistry of the target gene precludes gene cloning by conventional strategies. This approach, in conjunction with the more general insertional mutagenesis approach using T-DNA, has led to the cloning and subsequent analysis of several genes from higher plants involved in particular developmental processes. Studies of this nature should eventually shed light on the precise molecular mechanisms utilized to regulate and control cellular differentiation in plants.     

Rapid identification of Arabidopsis insertion mutants by non-radioactive detection of T-DNA tagged genes

To assist in the analysis of plant gene functions we have generated a new Arabidopsis insertion mutant collection of 90 000 lines that carry the T-DNA of Agrobacterium gene fusion vector pPCV6NFHyg. Segregation analysis indicates that the average frequency of insertion sites is 1.29 per line, predicting about 116 100 independent tagged loci in the collection. The average T-DNA copy number estimated by Southern DNA hybridization is 2.4, as over 50% of the insertion loci contain tandem T-DNA copies. The collection is pooled in two arrays providing 40 PCR templates, each containing DNA from either 4000 or 5000 individual plants. A rapid and sensitive PCR technique using high-quality template DNA accelerates the identification of T-DNA tagged genes without DNA hybridization. The PCR screening is performed by agarose gel electrophoresis followed by isolation and direct sequencing of DNA fragments of amplified T-DNA insert junctions. To estimate the mutation recovery rate, 39 700 lines have been screened for T-DNA tags in 154 genes yielding 87 confirmed mutations in 73 target genes. Screening the whole collection with both T-DNA border primers requires 170 PCR reactions that are expected to detect a mutation in a gene with at least twofold redundancy and an estimated probability of 77%. Using this technique, an M2 family segregating a characterized gene mutation can be identified within 4 weeks.     

T-DNA mediated disruption of essential gametophytic genes in Arabidopsis is unexpectedly rare and cannot be inferred from segregation distortion alone

Many genes are thought to be expressed during the haploid phase in plants, however, very few haploid-specific genes have been isolated so far. T-DNA insertion mutagenesis is a powerful tool for generating mutations that affect gametophyte viability and function, as disruption of a gene essential for these processes should lead to a defect in the transmission of the gametes. Mutants can therefore be screened on the basis of segregation distortion for a reporter resistance gene contained in the T-DNA. We have screened the Versailles collection of Arabidopsis transformants for 1:1 Kan^R:Kan^S segregation after selfing, focussing on gametophyte mutations which show normal transmission through one gametophyte and cause lethality or dysfunction of the other. Only 1.3% (207) of the 16,000 lines screened were scored as good candidates. Thorough genetic analysis of 38 putative T-DNA transmission defect lines (Ttd) identified 8 defective gametophyte mutants, which all showed 0 to 1% T-DNA transmission through the pollen. During the screen, we observed a high background of low-penetrance mutations, often affecting the function of both gametophytes, and many lines which were likely to carry chromosomal rearrangements. The reasons for the small number of retained lines (all male gametophytic) are discussed, as well as the finding that, for most of them, residual T-DNA transmission is obtained through the affected gametophyte.     

T-DNA mediated disruption of essential gametophytic genes in Arabidopsis is unexpectedly rare and cannot be inferred from segregation distortion alone

Many genes are thought to be expressed during the haploid phase in plants, however, very few haploid-specific genes have been isolated so far. T-DNA insertion mutagenesis is a powerful tool for generating mutations that affect gametophyte viability and function, as disruption of a gene essential for these processes should lead to a defect in the transmission of the gametes. Mutants can therefore be screened on the basis of segregation distortion for a reporter resistance gene contained in the T-DNA. We have screened the Versailles collection of Arabidopsis transformants for 1:1 Kan^R:Kan^S segregation after selfing, focussing on gametophyte mutations which show normal transmission through one gametophyte and cause lethality or dysfunction of the other. Only 1.3% (207) of the 16,000 lines screened were scored as good candidates. Thorough genetic analysis of 38 putative T-DNA transmission defect lines (Ttd) identified 8 defective gametophyte mutants, which all showed 0 to 1% T-DNA transmission through the pollen. During the screen, we observed a high background of low-penetrance mutations, often affecting the function of both gametophytes, and many lines which were likely to carry chromosomal rearrangements. The reasons for the small number of retained lines (all male gametophytic) are discussed, as well as the finding that, for most of them, residual T-DNA transmission is obtained through the affected gametophyte. Received: 27 July 1998 / Accepted: 16 September 1998     

Complementation analysis of Agrobacterium tumefaciens Ti plasmid mutations affecting oncogenicity

A wide host range cosmid vector has been constructed by insertion of the lambda cos site into the plasmid pRK2501. This cosmid, which is maintained in Agrobacterium tumefaciens and is compatible with the Ti plasmid, has been used to make a clone bank of the A. tumefaciens pTiA6 plasmid. Several pTiA6 cosmids have been used to complement Tn5-induced Ti plasmid mutations. Five avirulent mutations which map outside of the region of the plasmid maintained in plant tumours (T-DNA) could be complemented in a trans orientation. Two mutations which are located on a single HpaI restriction fragment outside of the T-DNA, as well as three mutations which map within the T-DNA region, could not be complemented in a trans orientation in a REC- host.     

Searching for tagged male-sterile mutants of arabidopsis

Although many male-sterile mutants have been identified inArbidopsis thaliana, few of the corresponding genes have been cloned. In order to facilitate cloning of a male sterility gene, 23 of Feldmann's T-DNA-generated, reduced-fertility lines were screened to identify a tagged male-sterile mutation. Malesterile mutants were identified, as well as mutants that were both male and female sterile. Segregation of the kanamycin marker gene in the progeny of 15 of these lines was studied. Forty percent had functional T-DNAs (encoding resistance to kanamycin) inserted at a single locus, the remainder segregating for two or more functional T-DNA inserts. Linkage between T-DNA inserts and mutant phenotype was tested for six lines. In three of these lines, mutations were not linked to a T-DNA insert. In three lines, the mutation segregated with a T-DNA insert.     

Agrobacterium tumefaciens-mediated transformation of Beauveria bassiana using an herbicide resistance gene as a selection marker

Beauveria bassiana has been investigated for use in the biological control of several insects in agricultural practice. To understand the molecular basis of virulence and host specificity and to improve the entomopathogenicity of B. bassiana, we have developed a simple, highly efficient and reliable Agrobacterium-mediated transformation method for B. bassiana using a phosphinothricin acetyltransferase (bar) gene as a selectable marker. Most transformants contained single copies of T-DNA and the T-DNA inserts were stably inherited after five generations. With this highly efficient transformation method for B. bassiana, we also obtained two putative T-DNA-tagged mutants that may have altered growth habits or virulence. Thus, the described protocol could provide a useful tool to manipulate the genetic make-up and to tag genes that may be important for virulence or growth and development of B. bassiana.     

An adapter ligation-mediated PCR method for high-throughput mapping of T-DNA inserts in the Arabidopsis genome

Agrobacterium transfer DNA (T-DNA) is an effective plant mutagen that has been used to create sequence-indexed T-DNA insertion lines in Arabidopsis thaliana as a tool to study gene function. Creating T-DNA insertion lines requires a dependable method for locating the site of insertion in the genome. In this protocol, we describe an adapter ligation-mediated PCR method that we have used to screen a mutant library and identify over 150,000 T-DNA insertional mutants; the method can also be applied to map individual mutants. The procedure consists of three steps: a restriction enzyme-mediated ligation of an adapter to the genomic DNA; a PCR amplification of the T-DNA/genomic DNA junction with primers specific to the adapter and T-DNA; and sequencing of the T-DNA/genomic junction to enable mapping to the reference genome. In most cases, the sequenced genomic region extends to the T-DNA border, enabling the exact location of the insert to be identified. The entire process takes 2 weeks to complete.     

Non-oncogenic T-region mutants ofAgrobacterium tumefaciens do transfer,T-DNA into plant cells

A new procedure for site-directed mutagenesis has been applied to the shooting and rooting loci of T-DNA of an octopine Ti-plasmid ofAgrobacterium tumefaciens. Mutants have been obtained which induced tumours that either developed shoots or produced more roots than normally observed. Double mutations, in which both types of T-DNA loci were affected, resulted in non-oncogenic strains. Indications have been obtained, showing that T-DNA coded oncogenic functions can be eliminated without affecting T-DNA transfer into plant cells.     

Arabidopsis gene knockout: phenotypes wanted

Gene knockout is considered to be a major component of the functional genomics toolbox, and is aimed at revealing the function of genes discovered through large-scale sequencing programs. In the past few years, several Arabidopsis populations mutagenized with insertion elements, such as the T-DNA of Agrobacterium or transposons, have been produced. These large populations are routinely screened for insertions into specific genes, allowing mass-isolation of knockout lines. Although many Arabidopsis knockouts have already been obtained, few of them have been reported to present informative phenotypes that provide a direct clue to gene function. Although functional redundancy explains the lack of phenotypical alterations in some cases, it also appears that many mutations are conditional and/or do not alter plant morphology even in the presence of severe physiological defects. Consequently, gene knockout per se is not sufficient to assess gene function and must be integrated into a more global approach for determining biological functions.     

BayGenomics: a resource of insertional mutations in mouse embryonic stem cells

The BayGenomics gene-trap resource (http://baygenomics.ucsf.edu) provides researchers with access to thousands of mouse embryonic stem (ES) cell lines harboring characterized insertional mutations in both known and novel genes. Each cell line contains an insertional mutation in a specific gene. The identity of the gene that has been interrupted can be determined from a DNA sequence tag. Approximately 75% of our cell lines contain insertional mutations in known mouse genes or genes that share strong sequence similarities with genes that have been identified in other organisms. These cell lines readily transmit the mutation to the germline of mice and many mutant lines of mice have already been generated from this resource. BayGenomics provides facile access to our entire database, including sequence tags for each mutant ES cell line, through the World Wide Web. Investigators can browse our resource, search for specific entries, download any portion of our database and BLAST sequences of interest against our entire set of cell line sequence tags. They can then obtain the mutant ES cell line for the purpose of generating knockout mice.     

Insertional mutagenesis in Arabidopsis thaliana: isolation of a T-DNA-linked mutation that alters leaf morphology

Summary We investigated the potential of the Agrobacterium tumefaciens T-DNA as an insertional mutagen in Arabidopsis thaliana. Arabidopsis lines transformed with different T-DNA vectors were generated using a leaf disc infection procedure adapted for efficient selection on either kanamycin or hygromycin medium. A standardized screening procedure was developed for the detection of recessive mutations in T2 populations of regenerated and/or transformed lines. Recessive mutations originating from the tissue culture procedure occurred at a low frequency — between 2% and 5%. Within 110 transformed lines that contained a total of about 150 T-DNA inserts, one recessive mutation, named pfl, cosegregated with a specific T-DNA copy. This pfl mutation mainly affected the morphology of the first seedling leaves under normal growth conditions and was mapped to chromosome 1. No recombination between the pfl locus and the kanamycin resistance marker on the T-DNA was detected when screening F2 and F3 populations of a mutant crossed to the wild type. The maximal genetic distance between the pfl locus and the kanamycin resistance gene, determined as 0.4±0.4 cMorgan, strongly suggests that the pfl mutation is induced by the insertion of the T-DNA. Our finding of one T-DNA-linked recessive mutation in 110 transgenic lines indicates that T-DNA can be used for mutagenization of the Arabidopsis genome under tissue culture conditions.     

Activation tagging using the En-I maize transposon system in Arabidopsis

A method for the generation of stable activation tag inserts was developed in Arabidopsis using the maize (Zea mays) En-I transposon system. The method employs greenhouse selectable marker genes that are useful to efficiently generate large populations of insertions. A population of about 8,300 independent stable activation tag inserts has been produced. Greenhouse-based screens for mutants in a group of plants containing about 2,900 insertions revealed about 31 dominant mutants, suggesting a dominant mutant frequency of about 1%. From the first batch of about 400 stable insertions screened in the greenhouse, four gain-in-function, dominant activation-tagged, morphological mutants were identified. A novel gain-in-function mutant called thread is described, in which the target gene belongs to the same family as the YUCCA flavin-mono-oxygenase that was identified by T-DNA activation tagging. The high frequency of identified gain-in-function mutants in the population suggests that the En-I system described here is an efficient strategy to saturate plant genomes with activation tag inserts. Because only a small number of primary transformants are required to generate an activation tag population, the En-I system appears to be an attractive alternative to study plant species where the present transformation methods have low efficiencies.     

Detection of mutations using microarrays of poly(C)10-poly(T)10 modified DNA probes immobilized on agarose films

Allele-specific hybridization to a DNA microarray can be a useful method for genotyping patient DNA. In this article, we demonstrate that 13- to 17-base oligonucleotides tagged with a poly(T)10-poly(C)10 tail (TC tag), but otherwise unmodified, can be crosslinked by UV light irradiation to an agarose film grafted onto unmodified glass. Microarrays of TC-tagged probes immobilized on the agarose film can be used to diagnose mutations in the human beta-globin gene, which encodes the beta-chains in hemoglobin. Although the probes differed widely regarding melting point temperature ( approximately 20 degrees C), a single stringency wash still gave sufficiently high discrimination signals between perfect match and mismatch probes to allow robust mutation detection. In all, 270 genotypings were performed on patient materials, and no genotype was incorrectly classified. Quality control experiments conducted using a target DNA specific for the TC tag of the immobilized probes showed that the spotting and hybridization procedure had a variance of 20%, indicating that signal differences as low as twofold could be detected between perfect match and mismatch. Together, our results show that the use of microarrays of TC-tagged probes that have been immobilized on agarose films grafted onto glass is a robust and inexpensive genotyping method.     

Screening for mutations affecting sexual reproduction after activation tagging inArabidopsis thaliana

In this work, a seed-set-based screening was performed on 70 lines of Arabidopsis thaliana after activation tagging mutagenesis to identify mutations in reproductive mechanisms. Five mutants showed significantly lower seed set than the wild type and confirmed the phenotype in the progeny. This phenotype was linked with the marker gene bar carried by T-DNA conferring glufosinate resistance. Genetic analysis revealed that the mutation inheritance was sporophytic in 3 mutants and gametophytic in 2 mutants. In addition, 2 mutants had an extra T-DNA copy. Thus activation tagging can be an effective strategy to identify new mutations affecting sporogenesis or gametogenesis.