Molecular analysis of paramutant plants of Antirrhinum majus and the involvement of transposable elements

Paramutation is observed when the Antirrhinum majus lines 44 and 53 are crossed. These two lines both have insertions at the nivea locus, which encodes chalcone synthase (chs). The allele niv-53 carries the transposable element Tam1 in the promoter region of the chs gene; niv-44 carries the element Tam2 within the gene. The Tam1 element has previously been extensively characterised. Here the Tam2 element is further characterised, and the arrangement of the nivea locus in paramutant plants is analysed. The complete sequence of Tam2, and that of a partial cDNA complementary to it, have been determined. The cDNA is probably transcribed from a different copy of Tam2 from that present at the nivea locus, and does not encode a functional protein. Genomic Southerns of F1 plants from the 53/44 cross show that no major rearrangements are consistently associated with paramutation at the nivea locus of A. majus. The isolation from a paramutant plant arising from a 53/44 cross of an allele (niv-4432) resulting from the excision of Tam2 is reported. The excision of Tam2 resulted in a 32 bp deletion of chs gene sequences. Plants homozygous for the new niv-4432 allele have white flowers and are still paramutagenic, demonstrating that Tam2 need not be present at the nivea locus for paramutation to occur. Different interactions between Tam1 and Tam2 are discussed, and a possible model for paramutation is presented.     

Molecular Analysis of a Transposon-Induced Deletion of the Nivea Locus in Antirrhinum Majus

The transposable element Tam3 of Antirrhinum majus is capable of causing large-scale chromosomal restructuring. It induced a large deletion at the nivea locus, to produce the allele niv-:529. The deletion removed the entire nivea coding region while the element remains intact with the potential to induce further rearrangements. Genetic experiments showed that the endpoint of the deletion (called x) is closely linked to nivea. The DNA sequences of niv-:529, a genomic excision of Tam3 from niv-:529, and the original genomic position of x have been determined. These data suggest that the deletion could have resulted from an abortive transposition or through breakage and religation.     

Allelic interactions at the nivea locus of Antirrhinum.

Most null alleles at the nivea (niv) locus are recessive to Niv+ and, when homozygous, give white flowers rather than the red of the wild type. In contrast, the niv-571 allele is semidominant; although it gives white flowers when homozygous, very pale flowers result when this allele is heterozygous with NIV+. We showed that in heterozygotes, niv-571 acts in trans to inhibit expression of its Niv+ homology 25-fold to 50-fold. The inhibition is reversible after meiosis and partially reversible somatically. The niv-571 allele carries a transposable element Tam3 insertion and three truncated copies of the niv gene, one copy being in inverse orientation. Analysis of two further niv alleles, niv-572 and niv-527, showed that excision of Tam3 from niv-571 does not affect the ability of the allele to repress Niv+ and that one truncated niv copy alone is insufficient to confer semidominance. The detailed structures of various semidominant niv alleles suggest that their effects in trans are not readily explained by production of antisense RNA but are more easily reconciled with a direct recognition/interaction between homologous genes, reminiscent of cosuppression and transvection phenomena described in other systems.     

Resistance to gap repair of the transposon Tam3 in Antirrhinum majus: a role of the end regions

The extremely homogeneous organization of the transposon family Tam3 in Antirrhinum majus is in sharp contrast to the heterogeneity of the copies constituting many other transposon families. To address the issue of the Tam3 structural uniformity, we examined two possibilities: (1) recent invasion of Tam3 and (2) failure of gap repair, which is involved in conversion from autonomous forms to defective forms. The phylogenetic analysis of 17 Tam3 copies suggested that the invasion of Tam3 into the Antirrhinum genome occurred at least 5 mya, which is sufficiently long ago to have produced many aberrant copies by gap repair. Thus, we investigated gap repair events at the nivea(recurrens:Tam3) (niv(rec)::Tam3) allele, where Tam3 is actively excised. We show here that the gap repair of de novo somatic Tam3 excision was arrested immediately after initiation of the process. All of the identified gap repair products were short stretches, no longer than 150 bp from the ends. The Tam3 ends have hairpin structures with low free energies. We observed that the gap repair halted within the hairpin structure regions. Such small gap repair products appear to be distributed in the Antirrhinum genome, but are unlikely to be active. Our data strongly suggest that the structural homogeneity of Tam3 was caused by immunity to gap repair at the hairpins in both of the end regions. The frequency of extensive gap repair of de novo excision products in eukaryotic transposons was found to be correlated with the free energies of the secondary structures in the end regions. This fact suggests that the fates of transposon families might depend on the structures of their ends.     

Transposon mutagenesis in halophilic eubacteria: conjugal transfer and insertion of transposon Tn5 and Tn1732 in Halomonas elongata

Abstract Molecular genetic studies of halophilic eubacteria have been limited by the lack of a suitable method for mutagenesis. To overcome this, we established a transposon mutagenesis procedure for the ectoine-producing, halophilic bacterium Halomonas elongata . We used suicide plasmids pSUP101 and pSUP102-Gm to introduce the transposons Tn5 and Tn7732 respectively into H. elongata via Escherichia coli SM10 mediated conjugation. Our finding that H. elongata is sensitive to aminoglycoside antibiotics at low salinity enabled us to apply transposons that mediate kanamycin resistance. The insertions of transposon In 1732 occurred at different sites in the chromosome of H. elongata , as proved by Southern hybridization analysis. Phenotypic analysis revealed that different auxotrophic and salt sensitive mutants were generated by mutagenesis with transposon Tn 1732 . To our knowledge this is the first report of a successful application of a transposon for direct generalized mutagenesis in a halophilic eubacterium.     

The <Emphasis Type="Italic">piggyBac</Emphasis> Transposon as a Tool in Genetic Engineering

Transposons are mobile genetic elements that are part of the genomic DNA of numerous organisms and belong to two classes. Unlike class I transposons, class II DNA transposons do not use the stage of RNA synthesis in their transition; they perform it by the cut-and-paste mechanism or with a replicative transposition. The integration of a DNA transposon in a new site results in the duplication of a target sequence on either side of a transposon, and its excision is, as a rule, associated with insertions and deletions. The piggyBac transposon isolated from the Trichoplusia ni moth differs from other mobile elements of its class. Due to its unique ability to leave no traces after excision from an insertion site and to perform successful transposition and transference of large DNA fragments, piggyBac is a convenient tool for the development of gene engineering approaches. The TTAA sequence serves as a target site for transposon integration: insertion in the AT-rich DNA regions is more frequent. The ability of piggyBac to be transferred to a new area independently of the cell apparatus and to restore a DNA site without error after excision lies in the mechanism of its transposition, which is discussed in detail in the present review. Along with other transposons and viruses, the piggyBac transposon is widely used in the transgenesis of various organisms; it also finds application in insertion mutagenesis and gene therapy.     

Tam3 in Antirrhinum majus is exceptional transposon in resistant to alteration by abortive gap repair: identification of nested transposons

Most transposon families consist of heterogeneous copies with varying sizes. In contrast, the Tam3 copies in Antirrhinum majus are known to have exceptionally conserved structures of uniform size. Gap repair has been reported to be involved in the structural alteration of copies from several transposon families. In this study, we have asked whether or not gap repair has affected Tam3 copies. Five Tam3 copies carrying aberrant sequences were selected from 40 independent Tam3 clones and their sequences were analyzed. Two of the five copies contain insertions in the Tam3 sequence. These two insertions, designated Tam356 and Tam661, are typical transposon-like sequences, which have terminal inverted repeats and cause target site duplication. These nested transposons were obviously associated with transpositional events, and did not originate from the gap-repair process. The remaining three copies had lost large parts of the Tam3 sequence. We could not find any relationship between the deletions of Tam3 sequence in the three copies and gap repair. PCR analysis of a Tam3 excision site in the nivea ^{recurrence:Tam3} mutant also showed that most of the repair events after the Tam3 excision involved end-joining. In addition to the results obtained here, among the other clones isolated, we could not find any of the internally deleted copies that comprise a major part of other transposon families. All of these data suggest that some feature of the Tam3 structure suppresses the structural alterations that are otherwise generated during the gap repair process.     

Shotgun cloning of transposon insertions in the genome of Caenorhabditis elegans

We present a strategy to identify and map large numbers of transposon insertions in the genome of Caenorhabditis elegans. Our approach makes use of the mutator strain mut-7, which has germline-transposition activity of the Tc1/mariner family of transposons, a display protocol to detect new transposon insertions, and the availability of the genomic sequence of C. elegans. From a pilot insertional mutagenesis screen, we have obtained 351 new Tc1 transposons inserted in or near 219 predicted C. elegans genes. The strategy presented provides an approach to isolate insertions of natural transposable elements in many C. elegans genes and to create a large-scale collection of C. elegans mutants.     

Isolation and Characterization of Escherichia Coli Mutants with Altered Rates of Deletion Formation

Using site-specific mutagenesis in vitro we constructed a genetic system to detect mutants with altered rates of deletion formation between short repeated sequences in Escherichia coli. After in vivo mutagenesis with chemical mutagens and transposons, the system allowed the identification of mutants with either increased or decreased deletion frequencies. One mutational locus, termed mutR, that results in an increase in deletion formation, was studied in detail. The mutR gene maps at 38.5 min on the E. coli genetic map. Since the precise excision of many transposable elements is also mediated at short repeated sequences, we investigated the effects of the mutant alleles, as well as recA, on precise excision of the transposon Tn9. Neither mutR nor recA affect precise excision of the transposon Tn9, from three different insertions in lacI, whereas these alleles do affect other spontaneous deletions in the same system. These results indicate that deletion events leading to precise excision occur principally via a different pathway than other random spontaneous deletions. It is suggested that, whereas precise excision occurs predominantly via a pathway involving replication enzymes (for instance template strand slippage), deletions on an F'factor are stimulated by recombination enzymes.     

Tam3 in Antirrhinum majus is exceptional transposon in resistant to alteration by abortive gap repair: identification of nested transposons

Most transposon families consist of heterogeneous copies with varying sizes. In contrast, the Tam3 copies in Antirrhinum majus are known to have exceptionally conserved structures of uniform size. Gap repair has been reported to be involved in the structural alteration of copies from several transposon families. In this study, we have asked whether or not gap repair has affected Tam3 copies. Five Tam3 copies carrying aberrant sequences were selected from 40 independent Tam3 clones and their sequences were analyzed. Two of the five copies contain insertions in the Tam3 sequence. These two insertions, designated Tam356 and Tam661, are typical transposon-like sequences, which have terminal inverted repeats and cause target site duplication. These nested transposons were obviously associated with transpositional events, and did not originate from the gap-repair process. The remaining three copies had lost large parts of the Tam3 sequence. We could not find any relationship between the deletions of Tam3 sequence in the three copies and gap repair. PCR analysis of a Tam3 excision site in the nivea ^{recurrence:Tam3} mutant also showed that most of the repair events after the Tam3 excision involved end-joining. In addition to the results obtained here, among the other clones isolated, we could not find any of the internally deleted copies that comprise a major part of other transposon families. All of these data suggest that some feature of the Tam3 structure suppresses the structural alterations that are otherwise generated during the gap repair process. Received: 22 April 1998 / Accepted: 15 June 1998     

Helicobacter pylori mutagenesis by mariner in vitro transposition

We have developed a method for generating transposon insertion mutants using mariner in vitro mutagenesis. The gene of interest was PCR-amplified and cloned. A kanamycin-marked mariner transposon was randomly inserted into the purified plasmid in an in vitro transposition reaction. After repair and propagation in Escherichia coli, purified mutagenized plasmid was introduced into Helicobacter pylori by natural transformation. Transformants were selected by plating on kanamycin. Mutants were predominantly the result of double homologous recombination, and multiple mutants (with insertions in distinct positions) were often obtained. The site of insertion was determined by PCR or sequencing. We have made mutations in known or potential virulence genes, including ureA, hopZ, and vacA, using kanamycin- and kanamycin/lacZ-marked transposons. Colonies carrying a kanamycin/lacZ transposon appeared blue on medium containing the chromogenic agent X-gal, allowing discrimination of mutant and wild-type H. pylori in mixed competition experiments.     

Genome juggling by transposons: Tam3-induced rearrangements in Antirrhinum majus

Transposable elements are well known for their ability to generate large- and small-scale rearrangements of the sequences flanking their insertion sites. These include deletions, inversions, and duplications. Tam3, a transposon from the Snapdragon (Antirrhinum majus), is highly active in the generation of such rearrangements. We have analysed a number of Tam3-induced rearrangements at the nivea (niv) locus by Southern blotting, cloning, and sequence determination. The data obtained from these analyses have led to an understanding of the mechanisms by which these complex alleles were formed. We have shown that the primary rearrangements usually occur without excision of the element and therefore result from aberrant transposition attempts. Subsequent rearrangements may occur on excision of the element. Finally, we suggest how the analysis of such rearrangements may not only provide information about Tam3 transposition but also show how transposon-induced rearrangements may influence the structure and function of the genome as a whole.     

Tn1721 derivatives for transposon mutagenesis, restriction mapping and nucleotide sequence analysis

New derivatives of the tetracycline-resistance transposon Tn1721 that carry resistances to chloramphenicol, tetracycline, kanamycin and streptomycin are described. These elements are provided on various plasmid vehicles and as chromosomal insertions to extend the range of targets for Tn mutagenesis. Single EcoRI sites at the ends of these transposons proved most useful for physical mapping, for the generation of new EcoRI sites in cloning experiments, for end-labelling and for sequencing of DNA adjacent to an insertion.     

Phylogenetic and functional characterization of the hAT transposon superfamily

Transposons are found in virtually all organisms and play fundamental roles in genome evolution. They can also acquire new functions in the host organism and some have been developed as incisive genetic tools for transformation and mutagenesis. The hAT transposon superfamily contains members from the plant and animal kingdoms, some of which are active when introduced into new host organisms. We have identified two new active hAT transposons, AeBuster1, from the mosquito Aedes aegypti and TcBuster from the red flour beetle Tribolium castaneum. Activity of both transposons is illustrated by excision and transposition assays performed in Drosophila melanogaster and Ae. aegypti and by in vitro strand transfer assays. These two active insect transposons are more closely related to the Buster sequences identified in humans than they are to the previously identified active hAT transposons, Ac, Tam3, Tol2, hobo, and Hermes. We therefore reexamined the structural and functional relationships of hAT and hAT-like transposase sequences extracted from genome databases and found that the hAT superfamily is divided into at least two families. This division is supported by a difference in target-site selections generated by active transposons of each family. We name these families the Ac and Buster families after the first identified transposon or transposon-like sequence in each. We find that the recently discovered SPIN transposons of mammals are located within the family of Buster elements.     

Comparison of genetic behaviour of the transposable element Tam3 at two unlinked pigment loci in Antirrhinum majus

Summary In Antirrhinum majus the transposable element Tam3 has been described at two unlinked loci pallida and nivea, both of which are required for the production of anthocyanin pigment in flowers. In each case the element is inserted in the promoter region and gives a variegated phenotype. We show that the rate of Tam3 excision at both loci is greatly affected by temperature, being approximately 1000-fold higher at 15°C compared with 25°C. Tam3 is also controlled by an unlinked gene Stabiliser, which considerably reduces excision rate. We show that the high degree of sensitivity to temperature and Stabiliser is an intrinsic property of Tam3 which is not shared by an unrelated element, Tam1. The Tam3 insertion at nivea gives rise to a series of alleles which confer reduced pigmentation, novel spatial patterns and changed instability. These are probably a result of imprecise excision and rearrangements of the Tam3 element.     

Mutagenesis by imprecise excision of the piggyBac transposon in Drosophila melanogaster

Mutagenesis by transposon-mediated imprecise excision is the most extensively used technique for mutagenesis in Drosophila. Although P-element is the most widely used transposon in Drosophila to generate deletion mutants, it is limited by the insertion coldspots in the genome where P-elements are rarely found. The piggyBac transposon was developed as an alternative mutagenic vector for mutagenesis of non-P-element targeted genes in Drosophila because the piggyBac transposon can more randomly integrate into the genome. Previous studies suggested that the piggyBac transposon always excises precisely from the insertion site without initiating a deletion or leaving behind an additional footprint. This unique characteristic of the piggyBac transposon facilitates reversible gene-transfer in several studies, such as the generation of induced pluripotent stem (iPS) cells from fibroblasts. However, it also raised a potential limitation of its utility in generating deletion mutants in Drosophila. In this study, we report multiple imprecise excisions of the piggyBac transposon at the sepiapterin reductase (SR) locus in Drosophila. Through imprecise excision of the piggyBac transposon inserted in the 5'-UTR of the SR gene, we generated a hypomorphic mutant allele of the SR gene which showed markedly decreased levels of SR expression. Our finding suggests that it is possible to generate deletion mutants by piggyBac transposon-mediated imprecise excision in Drosophila. However, it also suggests a limitation of piggyBac transposon-mediated reversible gene transfer for the generation of induced pluripotent stem (iPS) cells.     

Transposon mutagenesis of coryneform bacteria

The Corynebacterium glutamicum insertion sequence IS31831 was used to construct two artificial transposons: Tn31831 and miniTn31831. The transposition vectors were based on a gram-negative replication origin and do not replicate in coryneform bacteria. Strain Brevibacterium flavum MJ233C was mutagenized by miniTn31831 at an efficiency of 4.3 x 10⁴ mutants per microgram DNA. Transposon insertions occurred at different locations on the chromosome and produced a variety of mutants. Auxotrophs could be recovered at a frequency of approximately 0.2%. Transposition of IS31831 derivatives led not only to simple insertion, but also to cointegrate formation (5%). No multiple insertions were observed. Chromosomal loci of B. flavum corresponding to auxotrophic and pigmentation mutants could be rescued in Escherichia coli, demonstrating that these transposable elements are useful genetic tools for studying the biology of coryneform bacteria.