Insertion and excision of Caenorhabditis elegans transposable element Tc1.

The transposable element Tc1 is responsible for most spontaneous mutations that occur in Caenorhabditis elegans variety Bergerac. We investigated the genetic and molecular properties of Tc1 transposition and excision. We show that Tc1 insertion into the unc-54 myosin heavy-chain gene was strongly site specific. The DNA sequences of independent Tc1 insertion sites were similar to each other, and we present a consensus sequence for Tc1 insertion that describes these similarities. We show that Tc1 excision was usually imprecise. Tc1 excision was imprecise in both germ line and somatic cells. Imprecise excision generated novel unc-54 alleles that had amino acid substitutions, amino acid insertions, and, in certain cases, probably altered mRNA splicing. The DNA sequences remaining after Tc1 somatic excision were the same as those remaining after germ line excision, but the frequency of somatic excision was at least 1,000-fold higher than that of germ line excision. The genetic properties of Tc1 excision, combined with the DNA sequences of the resulting unc-54 alleles, demonstrated that excision was dependent on Tc1 transposition functions in both germ line and somatic cells. Somatic excision was not regulated in the same strain-specific manner as germ-line excision was. In a genetic background where Tc1 transposition and excision in the germ line was not detectable, Tc1 excision in the soma still occurred at high frequency.     

Differences in the floral anthocyanin content of red petunias and Petunia exserta

In order to resolve a conflict between previous papers regarding the floral anthocyanins of red flowers of Petunia exserta, a naturally occurring species, the HPLC profile of this species was compared with that of commercial red garden petunias. Both HPLC profiles extremely superficially resemble each other in terms of relative amounts and retention times of the major anthocyanins. However, co-elution on HPLC of the mixed sample resulted in clear separation of the components. Three major anthocyanins in red petunias were determined to be cyanidin 3-sophoroside, cyanidin 3-glucoside and peonidin 3-glucoside, which exhibited similar behaviors on HPLC to delphinidin 3-glucoside. delphinidin-3-rutinoside and petunidin 3-rutinoside, respectively, the major floral anthocyanins of P. exserta.     

Insertion of the Drosophila transposable element copia generates a 5 base pair duplication

To examine the details of insertion for the D. malanogaster transposable element copia, we have isolated three independent pairs of genomic fragments which correspond to occupied and unoccupied target sites for insertion. Restriction endonuclease analysis suggests that sites with and without an element differ by a simple 5000 bp insertion. Direct DNA sequence analysis demonstrates that a 5 bp sequence, present once in the target DNA at the site of insertion, is found on both sides of the element after insertion. The 5 bp sequences which are duplicated are different in each case. Moreover, there does not appear to be any sequence homology among these three independent insertion sites     

Somatic excision of the Mu1 transposable element of maize.

The Mu transposons of the Robertsons's Mutator transposable element system in maize are unusual in many respects, when compared to the other known plant transposon systems. The excision of these elements occurs late in somatic tissues and very rarely in the germ line. Unlike the other plant transposons, there is no experimental evidence directly linking Mu element excision and integration. We have analyzed the excision products generated by a Mu1 transposon inserted into the bronze 1 locus of maize. We find that the excision products or 'footprints' left by the Mu1 element resemble those of the other plant transposable elements, rather than those of the animal transposable element systems. We also find some novel types of footprints resembling recombinational events. We suggest that the Mu1 element can promote intrachromosomal crossovers and conversions near its site of insertion, and that this may be another mechanism by which transposons can accelerate the evolution of genomes.     

Engineering variegated floral patterns in tobacco plants using the Arabidopsis transposable element Tag1

Variegated flower phenotypes were generated using the Arabidopsis transposon Tag1 and the maize R regulatory gene. Tag1 was inserted between the CaMV 35S promoter and the maize R gene and transformed into tobacco plants. In half of the transgenic plants, variegated flower patterns were observed. Each line had a different pattern, with varying intensities with three lines showing only tiny sectors indicative of late excision and one showing large sectors indicative of earlier excision.     

Germline excision of the transposable element Tc1 in C. elegans.

We have examined eight germline revertants generated by the excision of Tc1 from a site within the unc-22 gene of Caenorhabditis elegans. A rich variety of rearrangements accompanied Tc1 excision at this site, including transposon 'footprints', deletions of sequences flanking the insertion site and direct nontandem duplications of flanking DNA. With only modest modification the double-strand gap repair model for transposition, recently proposed by Engles and coworkers (Cell 62: 515-525 1990), can explain even the most complex of these rearrangements. In light of this model rearrangements of the target site accompanying transposition/excision may not be the end result of imprecise excision of the element. Instead, these rearrangements may be the result of imprecise repair of the double-strand gap by the host replication and repair machinery. Sequences surrounding an insertion site influence the fidelity of gap repair by this machinery. This may lead to a number of possible resolutions of a double-strand gap as documented here for a Tc1 site in unc-22.     

Analysis of the cis-acting DNA elements required for piggyBac transposable element excision

The terminal DNA sequence requirements for piggyBac transposable element excision were explored using a plasmid-based assay in transfected, cultured insect cells. A donor plasmid containing duplicate 3′piggyBac terminal inverted repeats was constructed that allowed individual nucleotides or groups of nucleotides within one of the 3′ repeats to be mutated. The relative extent of excision using the mutated end versus the wild-type end was then assayed. Removal of even one of the terminal 3′ G nucleotides from the piggyBac inverted repeat, or removal of the dinucleotide AA from the flanking TTAA target site prevents excision of piggyBac at the mutated terminus. Incorporation of an asymmetric TTAC target site at the 3′ end does not prevent excision from the mutated end. Thus, both piggyBac DNA and flanking host DNA appear to play crucial roles in the excision process.     

Factors affecting the excision frequency of the maize transposable element Ds in Arabidopsis thaliana

A two-element transposon system based on the maize elements Ac and Ds is currently being used for insertional mutagenesis in Arabidopsis. With the aim of making this system as efficient as possible we have continued to analyse several parameters which affect Ds activity in Arabidopsis. The influence of genomic position on Ds excision has been analysed in five lines carrying Ds integrated in different genomic locations. Differences in both somatic and germinal excision were observed between the different lines. The relationship between somatic and germinal excision, the timing of excision events and environmental influences on transposition frequency have been investigated. The effect of varying dosage of the different elements was also analysed. A strong positive dosage effect was observed for the transposase source, but not for the Ds element. Analysis of germinal excision events showed that the majority of them occurred very late in the development of the plant, resulting in the majority of Ds transpositions being independent events.     

The hobo transposable element has transposase-dependent and-independent excision activity in drosophilid species

Mobility of the hobo transposable element was determined for several strains of Drosophila melanogaster and several Drosophila species. Mobility was assessed by use of an in vivo transient assay in the soma of developing embryos, which monitored hobo excision from injected indicator plasmids. Excision was detected in a D. melanogaster strain (cn; ry ⁴²) devoid of endogenous hobo elements only after co-injection of a helper plasmid containing functional hobo transposase under either heat shock or normal promoter regulation. Excision was also detected in D. melanogaster without helper in strains known to contain genomic copies of hobo. In Drosophila species confirmed not to contain hobo, hobo excision occurred at significant rates both in the presence and absence of co-injected helper plasmid. In four of the seven species tested, excision frequencies were two- to fivefold lower in the presence of plasmid-borne hobo. hobo excision donor sites were sequenced in indicator plasmids extracted from D. melanogaster cn; ry ⁴² and D. virilis embryos. In the presence of hobo transposase, the predominant excision sites were identical in both species, having breakpoints at the hobo termini with an inverted duplication of proximal insertion site DNA. However, in the absence of hobo transposase in D. virilis, excision breakpoints were apparently random and occurred distal to the hobo termini. The data indicate that hobo is capable of functioning in the soma during embryogenesis, and that its mobility is unrestricted in drosophilids. Furthermore, drosophilids not containing hobo are able to mobilize hobo, presumably by a hobo-related cross-mobilizing system. The cross-mobilizing system in D. virilis is not functionally identical to hobo with respect to excision sequence specificity.     

Eye color pigment granules in Drosophila mauritiana: mosaics produced by excision of a transposable element

Compound eyes of the white-peach (wpch) mutant strain of Drosophila mauritiana have some pigment and receptor cells with wild-type eye color pigmentation. These eyes are mosaic, because excision of a transposable element reverts wpch to wild type during the development of somatic cells. Wild-type patches have three types of pigment granule residing in three respective cell types: primary pigment cells, secondary pigment cells, and retinula (visual receptor) cells. Most aspects of these granules, as well as all other aspects of compound eye ultrastructure, are exactly as in the better studied sibling species D. melanogaster. In the wpch parts of the eye, small and giant unpigmented "pigment granules" reside in secondary pigment cells. These white granules are just like the corresponding granules of w mutant D. melanogaster. Small vs. large patches of pigmented cells likely represent excision events occurring late vs. early respectively during development. Mosaics of eye color markers have been important in developmental analyses; the ease of constructing mosaics of D. mauritiana gives this preparation advantages for mosaic analyses.     

The role of subterminal sites of transposable element Ds of Zea mays in excision

Transposition depends on DNA sequences located at or near the termini of the transposon. In the maize transposable element Ds, these sequences were studied by site-directed mutagenesis followed by a transient excision assay in Petunia protoplasts. The transposase-binding AAACGG motifs found in large numbers in the element are important, but none of them is in itself indispensable, for excision. However, mutation of an isolated motif at the 3′ end considerably reduced excisability. The inverted termini were confirmed to be indispensable. Point mutations in regions outside the inverted termini of Ds and not located in the transposase-binding motifs had, in some cases, a pronounced effect on excision frequency. The implications of these findings are discussed.     

Analysis of the cis-acting DNA elements required for piggyBac transposable element excision

The terminal DNA sequence requirements for piggyBac transposable element excision were explored using a plasmid-based assay in transfected, cultured insect cells. A donor plasmid containing duplicate 3′piggyBac terminal inverted repeats was constructed that allowed individual nucleotides or groups of nucleotides within one of the 3′ repeats to be mutated. The relative extent of excision using the mutated end versus the wild-type end was then assayed. Removal of even one of the terminal 3′ G nucleotides from the piggyBac inverted repeat, or removal of the dinucleotide AA from the flanking TTAA target site prevents excision of piggyBac at the mutated terminus. Incorporation of an asymmetric TTAC target site at the 3′ end does not prevent excision from the mutated end. Thus, both piggyBac DNA and flanking host DNA appear to play crucial roles in the excision process. Received: 9 July 1996 / Accepted: 6 May 1997     

Somatic excision of transposable element Tc1 from the Bristol genome of Caenorhabditis elegans.

We investigated the ability of the transposable element Tc1 to excise from the genome of the nematode Caenorhabditis elegans var. Bristol N2. Our results show that in the standard lab strain (Bristol), Tc1 excision occurred at a high frequency, comparable to that seen in the closely related Bergerac strain BO. We examined excision in the following way. We used a unique sequence flanking probe (pCeh29) to investigate the excision of Tc1s situated in the same location in both strains. Evidence of high-frequency excision from the genomes of both strains was observed. The Tc1s used in the first approach, although present in the same location in both genomes, were not known to be identical. Thus, a second approach was taken, which involved the genetic manipulation of a BO variant, Tc1(Hin). The ability of this BO Tc1(Hin) to excise was retained after its introduction into the N2 genome. Thus, we conclude that excision of Tc1 from the Bristol genome occurs at a high frequency and is comparable to that of Tc1 excision from the Bergerac genome. We showed that many Tc1 elements in N2 were apparently functionally intact and were capable of somatic excision. Even so, N2 Tc1s were prevented from exhibiting the high level of heritable transposition displayed by BO elements. We suggest that Bristol Tc1 elements have the ability to transpose but that transposition is heavily repressed in the gonadal tissue.     

The hobo transposable element has transposase-dependent and-independent excision activity in drosophilid species

Mobility of the hobo transposable element was determined for several strains of Drosophila melanogaster and several Drosophila species. Mobility was assessed by use of an in vivo transient assay in the soma of developing embryos, which monitored hobo excision from injected indicator plasmids. Excision was detected in a D. melanogaster strain (cn; ry ⁴²) devoid of endogenous hobo elements only after co-injection of a helper plasmid containing functional hobo transposase under either heat shock or normal promoter regulation. Excision was also detected in D. melanogaster without helper in strains known to contain genomic copies of hobo. In Drosophila species confirmed not to contain hobo, hobo excision occurred at significant rates both in the presence and absence of co-injected helper plasmid. In four of the seven species tested, excision frequencies were two- to fivefold lower in the presence of plasmid-borne hobo. hobo excision donor sites were sequenced in indicator plasmids extracted from D. melanogaster cn; ry ⁴² and D. virilis embryos. In the presence of hobo transposase, the predominant excision sites were identical in both species, having breakpoints at the hobo termini with an inverted duplication of proximal insertion site DNA. However, in the absence of hobo transposase in D. virilis, excision breakpoints were apparently random and occurred distal to the hobo termini. The data indicate that hobo is capable of functioning in the soma during embryogenesis, and that its mobility is unrestricted in drosophilids. Furthermore, drosophilids not containing hobo are able to mobilize hobo, presumably by a hobo-related cross-mobilizing system. The cross-mobilizing system in D. virilis is not functionally identical to hobo with respect to excision sequence specificity.     

Identification of a defective transposable element in tobacco

A putative defective transposable element has been identified in tobacco. This element has been found and characterised in two separate parts of the tobacco genome, specifically within the 3rd intron of the pollen-specific polygalacturonase gene (Npg1) and upstream of the endochitinase gene (Chn50). The element is ca. 0.4 kb in length and is bounded by conserved inverted repeats and putative target site duplications. It appears to fall into the category of non-autonomous transposable elements.     

High-frequency excision of transposable element Tc 1 in the nematode Caenorhabditis elegans is limited to somatic cells

Tc 1 transposable elements in the nematode Caenorhabditis elegans undergo excision at high frequency. We show here that this excision occurs primarily or entirely in the somatic tissues of the organism. Absence of germ-line excision is demonstrated by showing that Tc 1 elements are genetically stable; elements at particular genomic sites, as well as the overall number of elements in the genome, were stably maintained during a year of continuous, nonselective propagation. Somatic excision is demonstrated by showing that empty Tc 1 sites arise during a single generation of growth of a synchronous population and are not inherited by the next generation. These results suggest that excision of Tc 1 elements is under the control of tissue-specific factors.     

Factors affecting the excision frequency of the maize transposable element Ds in Arabidopsis thaliana

A two-element transposon system based on the maize elements Ac and Ds is currently being used for insertional mutagenesis in Arabidopsis. With the aim of making this system as efficient as possible we have continued to analyse several parameters which affect Ds activity in Arabidopsis. The influence of genomic position on Ds excision has been analysed in five lines carrying Ds integrated in different genomic locations. Differences in both somatic and germinal excision were observed between the different lines. The relationship between somatic and germinal excision, the timing of excision events and environmental influences on transposition frequency have been investigated. The effect of varying dosage of the different elements was also analysed. A strong positive dosage effect was observed for the transposase source, but not for the Ds element. Analysis of germinal excision events showed that the majority of them occurred very late in the development of the plant, resulting in the majority of Ds transpositions being independent events.