Your search keyword '"Levy AA"' showing total 12 results

1. Use of multicopy transposons bearing unfitness genes in weed control: four example scenarios.

Author

Gressel J and Levy AA

Subjects

Amaranthus drug effects, Gene Flow, Hybridization, Genetic drug effects, Lolium drug effects, Oryza genetics, Plants, Genetically Modified, Sorghum genetics, Transgenes, Crops, Agricultural genetics, DNA Transposable Elements genetics, Herbicide Resistance genetics, Herbicides pharmacology, Plant Weeds physiology, Weed Control methods

Abstract

We speculate that multicopy transposons, carrying both fitness and unfitness genes, can provide new positive and negative selection options to intractable weed problems. Multicopy transposons rapidly disseminate through populations, appearing in approximately 100% of progeny, unlike nuclear transgenes, which appear in a proportion of segregating populations. Different unfitness transgenes and modes of propagation will be appropriate for different cases: (1) outcrossing Amaranthus spp. (that evolved resistances to major herbicides); (2) Lolium spp., important pasture grasses, yet herbicide-resistant weeds in crops; (3) rice (Oryza sativa), often infested with feral weedy rice, which interbreeds with the crop; and (4) self-compatible sorghum (Sorghum bicolor), which readily crosses with conspecific shattercane and with allotetraploid johnsongrass (Sorghum halepense). The speculated outcome of these scenarios is to generate weed populations that contain the unfitness gene and thus are easily controllable. Unfitness genes can be under chemically or environmentally inducible promoters, activated after gene dissemination, or under constitutive promoters where the gene function is utilized only at special times (e.g. sensitivity to an herbicide). The transposons can be vectored to the weeds by introgression from the crop (in rice, sorghum, and Lolium spp.) or from planted engineered weed (Amaranthus spp.) using a gene conferring the degradation of a no longer widely used herbicide, especially in tandem with an herbicide-resistant gene that kills all nonhybrids, facilitating the rapid dissemination of the multicopy transposons in a weedy population., (© 2014 American Society of Plant Biologists. All Rights Reserved.)

Published

2014

2. Structure and evolution of the hAT transposon superfamily.

Author

Rubin E, Lithwick G, and Levy AA

Subjects

Base Sequence, DNA genetics, Database Management Systems, Phylogeny, Sequence Analysis, DNA, Sequence Homology, Nucleic Acid, Zea mays genetics, DNA Transposable Elements genetics, Evolution, Molecular, Transposases genetics

Abstract

The maize transposon Activator (Ac) was the first mobile DNA element to be discovered. Since then, other elements were found that share similarity to Ac, suggesting that it belongs to a transposon superfamily named hAT after hobo from Drosophila, Ac from maize, and Tam3 from snapdragon. We addressed the structure and evolution of hAT elements by developing new tools for transposon mining and searching the public sequence databases for the hallmarks of hAT elements, namely the transposase and short terminal inverted repeats (TIRs) flanked by 8-bp host duplications. We found 147 hAT-related sequences in plants, animals, and fungi. Six conserved blocks could be identified in the transposase of most hAT elements. A total of 41 hAT sequences were flanked by TIRs and 8-bp host duplications and, out of these, 34 sequences had TIRs similar to the consensus determined in this work, suggesting that they are active or recently active transposons. Phylogenetic analysis and clustering of hAT sequences suggest that the hAT superfamily is very ancient, probably predating the plant-fungi-animal separation, and that, unlike previously proposed, there is no evidence that horizontal gene transfer was involved in the evolution of hAT elements.

Published

2001

3. Analysis of extrachromosomal Ac/Ds transposable elements.

Author

Gorbunova V and Levy AA

Subjects

Plants, Genetically Modified, DNA Transposable Elements, DNA, Plant, Zea mays genetics

Abstract

The mechanism of transposition of the maize Ac/Ds elements is not well understood. The true transposition intermediates are not known and it has not been possible to distinguish between excision models involving 8-bp staggered cuts or 1-bp staggered cuts followed by hairpin formation. In this work, we have analyzed extrachromosomal excision products to gain insight into the excision mechanism. Plasmid rescue was used to demonstrate that Ds excision is associated with the formation of circular molecules. In addition, we present evidence for the formation of linear extrachromosomal species during Ds excision. Sequences found at the termini of circular and linear elements showed a broad range of nucleotide additions or deletions, suggesting that these species are not true intermediates. Additional nucleotides adjacent to the termini in extrachromosomal elements were compared to the sequence of the original donor site. This analysis showed that: (1) the first nucleotide adjacent to the transposon end was significantly more similar to the first nucleotide flanking the element in the donor site than to a random sequence and (2) the second and farther nucleotides did not resemble the donor site. The implications of these findings for excision models are discussed.

Published

2000

4. Technical advance: a high throughput system for transposon tagging and promoter trapping in tomato.

Author

Meissner R, Chague V, Zhu Q, Emmanuel E, Elkind Y, and Levy AA

Subjects

Genes, Reporter, Glucuronidase genetics, Luciferases genetics, DNA Transposable Elements, Solanum lycopersicum genetics, Promoter Regions, Genetic

Abstract

We describe new tools for functional analysis of the tomato genome based on insertional mutagenesis with the maize Ac/Ds transposable elements in the background of the miniature cultivar Micro-Tom. 2932 F3 families, in which Ds elements transposed and were stabilized, were screened for phenotypic mutations. Out of 10 families that had a clear mutant phenotype, only one mutant was Ds-tagged. In addition, we developed promoter trapping using the firefly luciferase reporter gene and enhancer trapping, using beta-glucuronidase (GUS). We show that luciferase can be used as a non-invasive reporter to identify, isolate and regenerate somatic sectors, to study the time course of mutant expression, and to identify inducible genes. Out of 108 families screened for luciferase activity 55% showed expression in the flower, 11% in the fruit and 4% in seedlings, suggesting a high rate of Ds insertion into genes. Preferential insertion into genes was supported by the analysis of Ds flanking sequences: 28 out of 50 sequenced Ds insertion sites were similar to known genes or to ESTs. In summary, the 2932 lines described here contain 2-3 Ds inserts per line, representing a collection of approximately 7500 Ds insertions. This collection has potential for use in high-throughput functional analysis of genes and promoter isolation in tomato.

Published

2000

5. A nuclear protein that binds specifically to several maize transposons is not essential for Ds1 excision.

Author

Gorbunova V, Ramos C, Hohn B, and Levy AA

Subjects

DNA-Binding Proteins metabolism, Models, Genetic, Mutagenesis, Nuclear Proteins genetics, Plasmids, Protein Binding, DNA Transposable Elements, Nuclear Proteins metabolism, Zea mays genetics

Abstract

Specific binding of plant nuclear proteins to GGTAAA-like motifs in the terminal regions of the transposable elements Ac and Mu1 has been detected in several laboratories. However, the role of these proteins in transposition remains unknown. To test the hypothesis that this binding activity is necessary for transposition, we identified and mutagenized all the binding motifs within the Ds1 element. This analysis enabled us to define more precisely the requirements for binding of the host protein. We then tested the ability of the mutated elements to excise from the maize streak virus (MSV) genome. We found that mutated Ds1 elements that do not bind the host proteins, as determined by gel-shift competition assay, are still capable of undergoing excision in maize, although for one of the maize lines the rate of excision was reduced. Excision of mutated Ds1 elements generated typical excision footprints. These data indicate that binding of host protein(s) to the GGTAAA-like motifs is not essential for Ds1 excision; however, it may contribute to the efficiency of the process.

Published

2000

6. Abortive gap repair: underlying mechanism for Ds element formation.

Author

Rubin E and Levy AA

Subjects

Models, Genetic, Plants, Genetically Modified, Plants, Toxic, Polymerase Chain Reaction, Recombination, Genetic, Sequence Analysis, DNA, Sequence Deletion, Nicotiana genetics, DNA Repair genetics, DNA Transposable Elements genetics, Zea mays genetics

Abstract

The mechanism by which the maize autonomous Ac transposable element gives rise to nonautonomous Ds elements is largely unknown. Sequence analysis of native maize Ds elements indicates a complex chimeric structure formed through deletions of Ac sequences with or without insertions of Ac-unrelated sequence blocks. These blocks are often flanked by short stretches of reshuffled and duplicated Ac sequences. To better understand the mechanism leading to Ds formation, we designed an assay for detecting alterations in Ac using transgenic tobacco plants carrying a single copy of Ac. We found frequent de novo alterations in Ac which were excision rather than sequence dependent, occurring within Ac but not within an almost identical Ds element and not within a stable transposase-producing gene. The de novo DNA rearrangements consisted of internal deletions with breakpoints usually occurring at short repeats and, in some cases, of duplication of Ac sequences or insertion of Ac-unrelated fragments. The ancient maize Ds elements and the young Ds elements in transgenic tobacco showed similar rearrangements, suggesting that Ac-Ds elements evolve rapidly, more so than stable genes, through deletions, duplications, and reshuffling of their own sequences and through capturing of unrelated sequences. The data presented here suggest that abortive Ac-induced gap repair, through the synthesis-dependent strand-annealing pathway, is the underlying mechanism for Ds element formation.

Published

1997

7. The maize transposable element Ac induces recombination between the donor site and an homologous ectopic sequence.

Author

Shalev G and Levy AA

Subjects

Base Sequence, DNA, Plant, Molecular Sequence Data, DNA Transposable Elements, Genes, Plant, Recombination, Genetic, Zea mays genetics

Abstract

The prominent repair mechanism of DNA double-strand breaks formed upon excision of the maize Ac transposable element is via nonhomologous end joining. In this work we have studied the role of homologous recombination as an additional repair pathway. To this end, we developed an assay whereby beta-Glucuronidase (GUS) activity is restored upon recombination between two homologous ectopic (nonallelic) sequences in transgenic tobacco plants. One of the recombination partners carried a deletion at the 5' end of GUS and an Ac or a Ds element inserted at the deletion site. The other partner carried an intact 5' end of the GUS open reading frame and had a deletion at the 3' end of the gene. Based on GUS reactivation data, we found that the excision of Ac induced recombination between ectopic sequences by at least two orders of magnitude. Recombination events, visualized by blue staining, were detected in seedlings, in pollen and in protoplasts. DNA fragments corresponding to recombination events were recovered exclusively in crosses with Ac-carrying plants, providing physical evidence for Ac-induced ectopic recombination. The occurrence of ectopic recombination following double-strand breaks is a potentially important factor in plant genome evolution.

Published

1997

8. Circularized Ac/Ds transposons: formation, structure and fate.

Author

Gorbunova V and Levy AA

Subjects

Chromosomes metabolism, DNA Nucleotidyltransferases metabolism, DNA, Circular metabolism, DNA, Plant metabolism, DNA, Recombinant metabolism, Genes, Reporter, Mutagenesis, Insertional, Plant Proteins metabolism, Plants, Genetically Modified, Plasmids, Sequence Deletion, Transposases, DNA Transposable Elements genetics, DNA, Circular genetics, DNA, Plant genetics, DNA, Recombinant genetics, Plants, Toxic, Nicotiana genetics

Abstract

The maize Ac/Ds transposable elements are thought to transpose via a cut-and-paste mechanism, but the intermediates formed during transposition are still unknown. In this work we present evidence that circular Ac molecules are formed in plants containing actively transposing elements. In these circles, transposon ends are joined head-to-head. The sequence at the ends' junction is variable, containing small deletions or insertions. Circles containing deleted Ac ends are probably unable to successfully reintegrate. To test the ability of circles with intact transposon ends to integrate into the genome, an artificial Ds circle was constructed by cloning the joined ends of Ac into a plasmid carrying a plant selectable marker. When such a circular Ds was introduced into tobacco protoplasts in the presence of Ac-transposase, no efficient transposase-mediated integration was observed. Although a circular transposition intermediate cannot be ruled out, the findings of circles with deleted transposon ends and the absence of transposase-mediated integration of the circular Ds suggest that some of the joined-ends-carrying elements are not transposition intermediates, but rather abortive excision products. The formation of Ac circles might account for the previously described phenomenon of Ac-loss. The origin of Ac circles and the implications for models of Ac transposition are discussed.

Published

1997

9. Binding of Nicotiana nuclear proteins to the subterminal regions of the Ac transposable element.

Author

Levy AA, Fridlender M, Rubin UH, and Sitrit Y

Subjects

Base Sequence, Binding Sites, DNA, Plant metabolism, Molecular Sequence Data, Plant Proteins metabolism, Sequence Homology, Nucleic Acid, Substrate Specificity, Nicotiana chemistry, DNA Transposable Elements, Nuclear Proteins metabolism, Plants, Toxic, Nicotiana genetics

Abstract

Specific binding of Nicotiana nuclear protein(s) to subterminal regions of the Ac transposable element was detected using gel mobility shift assays. A sequence motif (GGTAAA) repeated in both terminal regions of Ac, was identified as the protein binding site. Mutation of two nucleotides in this motif was sufficient to abolish binding. Based on a series of competition assays, it is deduced that there is cooperative binding between two repeats, each similar to the GGTAAA motif. The binding protein is probably similar to a previously characterized maize protein which binds to a GGTAAA-containing motif located in the ends of Mutator. Moreover, we show that DNA from Ds1 competes for protein binding to Ac termini, and we show, by sequence analysis, that GGTAAA binding sites are present in the terminal region of Tgm1, Tpn1, En/Spm, Tam3, and Ds1-like elements. This suggests that the binding protein(s) might be involved in the transposition process.

Published

1996

10. Molecular analysis of the loss of somatic instability in the bz2::mu1 allele of maize.

Author

Levy AA and Walbot V

Subjects

Alleles, Anthocyanins genetics, Base Sequence, Blotting, Southern, Chromosome Deletion, Crosses, Genetic, Methylation, Molecular Sequence Data, Restriction Mapping, DNA Transposable Elements genetics, Mutagenesis genetics, Zea mays genetics

Abstract

Multiple genetic and epigenetic changes were detected within one plant generation at the bz2::mu1 mutable allele in a population of 118 plants. Loss of somatic instability in bz2::mu1 was usually correlated with methylation of the Mu1 transposable element; in 6 plants, somatic instability was lost as a result of mutations in bz2::mu1. This is a surprisingly high frequency of mutation per allele (2.5%) for the Mutator family, for which germinal revertants occur at a frequency of about 10(-4) per gamete. One germinal excision event was found that contained an 8 bp deletion, frameshift mutation in Bronze-2. The three other mutants described occurred as a result of abortive transposition, in which 75-77 bp deletions were generated at the junction between Bronze-2 and Mu1. We discuss the possible mechanisms, and the role of host factors in abortive transposition in maize.

Published

1991

11. Regulation of the timing of transposable element excision during maize development.

Author

Levy AA and Walbot V

Subjects

Alleles, Anthocyanins biosynthesis, Anthocyanins genetics, Cell Division, Mutation, Zea mays growth & development, DNA Transposable Elements genetics, Zea mays genetics

Abstract

The ability of transposable elements (TEs) to insert into or excise out of a genetic locus can be regulated by genetic, environmental, and developmental factors. Tissue- or organ-specific activity of TEs is a frequent and well-characterized example of spatial, developmental regulation. Regulation of the timing of TE activity during ontogeny is less well understood. To analyze timing, TE-induced variegation was quantified in the aleurone of maize kernels, a tissue composed of only a single layer of cells, and sector sizes were assigned to specific cell divisions in aleurone development. Three TE families, Mu, Spm, and Ac/Ds, were studied at two genetic loci. It was found that the frequency of transposon excision changes drastically (up to 30-fold increase or equivalent decrease) during the proliferation of the aleurone. Moreover, these changes occur at the same cell divisions in all three TE families. These results suggest that the timing of TE excision during maize development can be controlled by the host.

Published

1990

12. Developmental and genetic aspects of Mutator excision in maize.

Author

Levy AA, Britt AB, Luehrsen KR, Chandler VL, Warren C, and Walbot V

Subjects

Alleles, Crosses, Genetic, Mutation, Phenotype, Pollen, Video Recording, Zea mays growth & development, DNA genetics, DNA Transposable Elements genetics, Zea mays genetics

Abstract

The regulation of excision of Mu elements of the Mutator transposable element family of maize is not well understood. We have used somatic instability of Mu receptor elements from the Bronze 1 and Bronze 2 loci to monitor the frequency and the timing of excision of Mu elements in several tissues. We show that spot size in the aleurone of a bz2::mu1 stock varies between one to approximately 256 cells. This indicates that excision events begin eight divisions prior to full aleurone differentiation and end after the last division of the aleurone. We show that excision is equally biased for late events in all other tissues studied. A locus on chromosome 5 has been identified that affects spot size, possibly by altering the timing of Mu excision. Using somatic excision as an assay of Mutator activity, we found that activity can change in small sectors of the tassel; however, there are no overall activity changes in the tassel during the period of pollen shedding. We also report the recovery of germinal revertants for the bz1::mu1 and bz2::mu1 alleles. One of these revertant alleles was characterized by Southern blot analysis and found to be similar to the progenitor of the mutable allele.

Published

1989