Multiple independent defective suppressor-mutator transposon insertions in Arabidopsis: a tool for functional genomics.

A new system for insertional mutagenesis based on the maize Enhancer/Suppressor-mutator (En/Spm) element was introduced into Arabidopsis. A single T-DNA construct carried a nonautonomous defective Spm (dSpm) element with a phosphinothricin herbicide resistance (BAR) gene, a transposase expression cassette, and a counterselectable gene. This construct was used to select for stable dSpm transpositions. Treatments for both positive (BAR) and negative selection markers were applicable to soil-grown plants, allowing the recovery of new transpositions on a large scale. To date, a total of 48,000 lines in pools of 50 have been recovered, of which approximately 80% result from independent insertion events. DNA extracted from these pools was used in reverse genetic screens, either by polymerase chain reaction (PCR) using primers from the transposon and the targeted gene or by the display of insertions whereby inverse PCR products of insertions from the DNA pools are spotted on a membrane that is then hybridized with the probe of interest. By sequencing PCR-amplified fragments adjacent to insertion sites, we established a sequenced insertion-site database of 1200 sequences. This database permitted a comparison of the chromosomal distribution of transpositions from various T-DNA locations.     

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.     

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.     

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.     

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.     

Creation and analysis of Brassica napus + Arabidopsis thaliana somatic hybrids possessing maize Spm/dSpm heterologous transposable system

Functionally asymmetric somatic hybrids possessing heterologous transposable element Spm/dSpm were obtained following intertribal somatic hybridization between Brassica napus and transgenic Arabidopsis thaliana. Mobile genetic elements actively transposed in the hybrid genomes. Complete elimination of A. thaliana genome was not observed.     

The behaviour of the autonomous maize transposable element En/Spm in Arabidopsis thaliana allows efficient mutagenesis

The behavior of the autonomous maize transposable element En/Spm of maize was studied in Arabidopsis. Transgenic Arabidopsis plants carrying En-1 elements were propagated for 12 generations using a single seed descent procedure. The distribution and activity of the En-1 element was monitored using Southern DNA hybridisations in generations 1, 6 and 12. In the first generation the highest number of En-1 insertions per line was 7, which increased to 20 in generation 12. The average number of En-1 insertions increased only slightly in the population, due to a gradual accumulation of segregants that lost the transposable element. During the development of the En-1 mutagenised population the element remained active even in the high-copy lines. In situ hybridisation demonstrated that multiple En-1 insertions were distributed over all Arabidopsis chromosomes. From the initial En-1 mutagenised populations many unstable gene mutations were recovered, indicating that En-1 can be used as a efficient tool for gene tagging in Arabidopsis.     

Phosphinothricin-resistant somatic hybrids Brassica napus + Orychophragmus violaceus

Phosphinothricin (PPT) resistant hybrid plants between Brassica napus L. cv. Kalinovsky and Orychophragmus violaceus (L.) O.E. Shulz. were obtained as a result of somatic hybridization experiments. The hybrids inherited PPT resistance from O. violaceus plants which were previously transformed by the vector containing Spm/dSpm Zea mays transposon system with bar gene located within the nonautonomous transposon. The obtained plants had intermediate morphology. Their hybrid nature has been confirmed by isozyme (esterase and amilase activity) and PCR (bar, gus, Spm/dSpm integration) analyses. The hybrids combined B. napus plastom and O. violaceus mithochondrion that was revealed by PCR-RFLP. The hybrid plants might be included to rapeseed breeding programme after examination of their oil quality as well as to chloroplast transformation experiments that is still urgent for B. napus.     

Applications of biotechnology and genomics in potato improvement

Potato is the third most important global food crop and the most widely grown noncereal crop. As a species highly amenable to cell culture, it has a long history of biotechnology applications for crop improvement. This review begins with a historical perspective on potato improvement using biotechnology encompassing pathogen elimination, wide hybridization, ploidy manipulation and applications of cell culture. We describe the past developments and new approaches for gene transfer to potato. Transformation is highly effective for adding single genes to existing elite potato clones with no, or minimal, disturbances to their genetic background and represents the only effective way to produce isogenic lines of specific genotypes/cultivars. This is virtually impossible via traditional breeding as, due to the high heterozygosity in the tetraploid potato genome, the genetic integrity of potato clones is lost upon sexual reproduction as a result of allele segregation. These genetic attributes have also provided challenges for the development of genetic maps and applications of molecular markers and genomics in potato breeding. Various molecular approaches used to characterize loci, (candidate) genes and alleles in potato, and associating phenotype with genotype are also described. The recent determination of the potato genome sequence has presented new opportunities for genomewide assays to provide tools for gene discovery and enabling the development of robustly unique marker haplotypes spanning QTL regions. The latter will be useful in introgression breeding and whole‐genome approaches such as genomic selection to improve the efficiency of selecting elite clones and enhancing genetic gain over time.     

Assignment of 44 Ds Insertions to the Linkage Map of Arabidopsis

Transposon tagging is a useful tool for biological studies. Transposon insertions have been used to obtain new mutants which are extremely helpful in understanding gene function. These insertions immediately provide a means to isolate the corresponding genes. Transposon tagging has also been used to clone genes previously defined by point mutations. In addition, transposon insertions into cloned genes that lack mutations can be generated to facilitate functional analysis. The maize Ac/Ds transposon elements are known to transpose to local sites with high frequencies and have been shown to function in several dicots. To generate a collection of Ds elements for the purpose of targeted insertional mutagenesis of mapped genes in Arabidopsis, we have mapped 44 Ds insertions by simple sequence length polymorphism (SSLP). Because the Arabidopsis genome project is advancing rapidly, many genes will be discovered whose functions are unknown. The mapped 44 Ds insertions will be a useful resource for post-genome analysis of gene functions in Arabidopsis.     

Efficient screening of Arabidopsis T-DNA insertion lines using degenerate primers

The sequencing of the Arabidopsis plant genome is providing a fuller understanding of the number and types of plant genes. However, in most cases we do not know which genes are responsible for specific metabolic and signal transduction pathways. Analysis of gene function is also often confounded by the presence of multiple isoforms of the gene of interest. Recent advances in PCR-based reverse genetic techniques have allowed the search for plants carrying T-DNA insertions in any gene of interest. Here we report preliminary screening results from an ordered population of nearly 60,470 independently derived T-DNA lines. Degenerate PCR primers were used on large DNA pools (n = 2,025 T-DNA lines) to screen for more than one gene family member at a time. Methods are presented that facilitated the identification and isolation of isoform-specific mutants in almost all members of the Arabidopsis H(+)-proton ATPase gene family. Multiple mutant alleles were found for several isoforms.     

Gene Marker Loss Induced by the Transposable Element, En, in Maize

The En/Spm transposable element system in maize includes the functional element, En/Spm and the receptor element I/dSpm. An En receptor has been found that shows En-induced breakage. This En-responsive receptor (designated 1836518) is located on the short arm of chromosome 9, proximal to Wx. In the presence of En, markers distal to the receptor show a loss of gene expression. Kernels heterozygous for aleurone and endosperm marker genes have a variegated appearance. The hypothesis is advanced that this variegation represents a physical loss of the chromosome segments carrying the genes distal to the receptor position. It is the first case of an En-controlled breakage event.     

Generating and maintaining diversity at the elite level in crop breeding

Most breeding programs develop elite genotypes that are well adapted to the normal range of environmental conditions in the target production region. These elite lines have similar essential alleles for desirable end use characteristics, agronomics, disease resistance, and adaptation in the target region. The genetic makeup of these elite lines is complex. Intermating among the elite lines will often produce new variability through recombination with minimal risk of introducing new undesirable features, and is the source of most new cultivars. Eventually, this variation will be exhausted and new alleles must be introduced into the elite breeding population. Introducing desirable alleles from exotic germplasm may "pollute" the elite gene pool with undesirable alleles. Exotic germplasm may also disrupt essential allele combinations for adaptation, quality, and agronomic performance. New desirable alleles from exotic germplasm can be introgressed into an elite population in a systematic way through limited backcrossing with a minimal disturbance to the finely tuned elite background. Combining recurrent selection within elite germplasm with a systematic introgression from exotic germplasm in the recurrent introgressive population enrichment (RIPE) system has created an open-ended, continually improving, and sustainable elite population breeding system, which is simple, effective, and a regular source of new cultivars.     

Perspectives on Systematic Analyses of Gene Function in Arabidopsis thaliana: New Tools, Topics and Trends

Since the sequencing of the nuclear genome of Arabidopsis thaliana ten years ago, various large-scale analyses of gene function have been performed in this model species. In particular, the availability of collections of lines harbouring random T-DNA or transposon insertions, which include mutants for almost all of the ~27,000 A. thaliana genes, has been crucial for the success of forward and reverse genetic approaches. In the foreseeable future, genome-wide phenotypic data from mutant analyses will become available for Arabidopsis, and will stimulate a flood of novel in-depth gene-function analyses. In this review, we consider the present status of resources and concepts for systematic studies of gene function in A. thaliana. Current perspectives on the utility of loss-of-function and gain-of-function mutants will be discussed in light of the genetic and functional redundancy of many A. thaliana genes.